Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-27T02:38:18.427Z Has data issue: false hasContentIssue false

Genomic and neuroimaging approaches to bipolar disorder

Published online by Cambridge University Press:  01 February 2022

Mojtaba Oraki Kohshour
Affiliation:
Institute of Psychiatric Phenomics and Genomics, University Hospital LMU Munich, Germany; and Department of Immunology, School of Medicine, Ahvaz Jundishapur University of Medical Sciences, Iran
Sergi Papiol
Affiliation:
Institute of Psychiatric Phenomics and Genomics, University Hospital LMU Munich, Germany; and Department of Psychiatry and Psychotherapy, University Hospital LMU Munich, Germany
Christopher R. K. Ching
Affiliation:
Imaging Genetics Center, Mark and Mary Stevens Neuroimaging and Informatics Institute, Keck School of Medicine, University of Southern California, USA
Thomas G. Schulze*
Affiliation:
Institute of Psychiatric Phenomics and Genomics, University Hospital LMU Munich, Germany; and Department of Psychiatry and Behavioral Sciences, SUNY Upstate Medical University, USA
*
Correspondence: Thomas G. Schulze. Email: thomas.schulze@med.uni-muenchen.de
Rights & Permissions [Opens in a new window]

Abstract

Background

To date, besides genome-wide association studies, a variety of other genetic analyses (e.g. polygenic risk scores, whole-exome sequencing and whole-genome sequencing) have been conducted, and a large amount of data has been gathered for investigating the involvement of common, rare and very rare types of DNA sequence variants in bipolar disorder. Also, non-invasive neuroimaging methods can be used to quantify changes in brain structure and function in patients with bipolar disorder.

Aims

To provide a comprehensive assessment of genetic findings associated with bipolar disorder, based on the evaluation of different genomic approaches and neuroimaging studies.

Method

We conducted a PubMed search of all relevant literatures from the beginning to the present, by querying related search strings.

Results

ANK3, CACNA1C, SYNE1, ODZ4 and TRANK1 are five genes that have been replicated as key gene candidates in bipolar disorder pathophysiology, through the investigated studies. The percentage of phenotypic variance explained by the identified variants is small (approximately 4.7%). Bipolar disorder polygenic risk scores are associated with other psychiatric phenotypes. The ENIGMA-BD studies show a replicable pattern of lower cortical thickness, altered white matter integrity and smaller subcortical volumes in bipolar disorder.

Conclusions

The low amount of explained phenotypic variance highlights the need for further large-scale investigations, especially among non-European populations, to achieve a more complete understanding of the genetic architecture of bipolar disorder and the missing heritability. Combining neuroimaging data with genetic data in large-scale studies might help researchers acquire a better knowledge of the engaged brain regions in bipolar disorder.

Type
Review
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - ND
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (https://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is unaltered and is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use or in order to create a derivative work.
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press on behalf of the Royal College of Psychiatrists

Bipolar disorder, a severe psychiatric condition

Bipolar disorder is a chronic, disabling and severe mental health condition that is defined by recurrent acute manic and depressive mood states, and affects >1% of the global population.Reference Vieta, Berk, Schulze, Carvalho, Suppes and Calabrese1 It is considered as one of the most heritable mental illnesses, with heritability estimates of approximately 80%, and is thought to be influenced by gene×environment interactions. Bipolar disorder ranks as the sixth most common cause of disability-adjusted life-years in human populations (9.9 million years worldwide), and is associated with a higher risk for severe conditions such as suicidality and social and cognitive functional disability.Reference Leboyer and Kupfer2Reference Amare, Schubert, Hou, Clark, Papiol and Cearns4

Psychiatric genetics, formed in the 20th century, is a branch of behavioural genetics that investigates the role of genetics in the onset and progression of mental illnesses. Attempts to use genomic data for prediction and risk stratification have been classically hampered by the highly polygenic and pleiotropic nature of psychiatric genetics.Reference Rees and Owen5 Current models suggest that bipolar disorder is a heterogeneous and multifactorial disease, which probably involves several pathogenic pathways orchestrated by numerous common and rare genetic factors, environmental factors and epigenetic influences.Reference Ludwig and Dwivedi6 Over the past several decades, many genetic studies have been performed to uncover the genetic underpinnings of bipolar disorder. For complex disorders like bipolar disorder, association studies are expected to be more informative than linkage studies because of their higher statistical power to capture modest genetic effects. However, initial candidate gene approaches suffered a challenging lack of replicability of the results that raised questions regarding the actual utility of association studies in psychiatric genetics.Reference Tabor, Risch and Myers7

Genome-wide association studies (GWASs), which were introduced as a powerful alternative to linkage and a hypothesis-free extension of candidate gene studies, have emerged as a revolutionary approach in research on complex genetic disorders. GWASs aim to reveal genotype-phenotype associations by testing the association between millions of common genetic variants distributed across the human genome with the phenotype of interest. GWASs have provided compelling evidence of the ability to unravel the genetic underpinnings of complex traits.Reference Tam, Patel, Turcotte, Bossé, Paré and Meyre8Reference Witte12 One important lesson from GWASs is that the cumulative number of loci to be discovered in GWASs is growing in line with the increasing sample size.Reference Park, Wacholder, Gail, Peters, Jacobs and Chanock13 According to an estimate in 2013, >63 000 case–control samples would be required to identify the approximately 105 bipolar disorder risk loci discoverable by GWAS, and these would explain <6% of the inherited risk.Reference Chen, Jiang, Akula, Shugart, Wendland and Steele14 Recently, the decreasing cost of genotyping technology is encouraging the development of new, large GWASs through the formation of multinational research consortia.Reference Park, Wacholder, Gail, Peters, Jacobs and Chanock13

The first GWAS ever published, a case versus control association study including 92 788 gene-based single-nucleotide polymorphism (SNP) markers, was performed in Japan in 2002.Reference Ozaki, Ohnishi, Iida, Sekine, Yamada and Tsunoda15 By genotyping 94 individuals of Japanese descent with myocardial infarction, and comparing the results with allelic frequencies found in 658 healthy individuals at first, and then following the results in the expanded sample size (1133 cases and 1006 controls), Ozaki et al reported a candidate locus on chromosome 6p21 to be associated with susceptibility to myocardial infarction.Reference Ozaki, Ohnishi, Iida, Sekine, Yamada and Tsunoda15 The first GWAS on bipolar disorder was published in 2007, and >20 GWASs to date have followed this initial study.Reference Gordovez and McMahon16 These studies have reported >120 lead SNPs (P < 5 × 10−8) contributing to bipolar disorder risk located on almost all human chromosomes, and have mapped the genes in their corresponding loci.Reference Gordovez and McMahon16,Reference Mullins, Forstner, O'Connell, Coombes, Coleman and Qiao17 In GWASs, genotype imputation is used to expand the number of tested variants, complete fine-mapping, and permit meta-analysis with different arrays by harmonising data-sets, increasing the power of association. Imputation is an in silico method and can be performed throughout the entire genome, or in a more targeted area with the aim of predicting genotypes at the SNPs that are not genotyped directly in the samples.Reference Marchini and Howie18,Reference Porcu, Sanna, Fuchsberger and Fritsche19 Most of the top associated variants identified by GWASs are located in non-coding regions of the genome, suggesting that many of them might be involved in regulatory mechanisms of gene expression (expression quantitative trait loci) rather than directly affecting the amino acid sequence of proteins.Reference Truvé, Parris, Vizlin-Hodzic, Salmela, Berger and Ågren20

Over the past decade, significant advances and cost reductions in sequencing technology have made it possible to sequence the whole exome and genome of a large number of patients with bipolar disorder and controls.Reference Kato21 Based on the National Human Genome Research Institute data, in mid-2015, constructing a high-quality, whole human genome sequencing draft costed slightly over $4000. By the end of 2015, it had dropped to <$1500. Today, whole-exome and whole-genome sequences are frequently available for <$1000 on the commercial market. Whole-exome sequencing (WES) is less costly than whole-genome sequencing (WGS), but it has the disadvantage that it sequences only about 1% of the genome because it focuses on protein-coding regions (exons) to find variations that affect gene structures and functions.Reference Monson, Pirooznia, Parla, Kramer, Goes and Gaine22,Reference Zhang, Hou, Chen, McMahon, Wang and Rice23 The complementary approach, WGS, is a novel but still relatively costly technique that captures all allelic variation throughout the entire genome. It allows for the exploration of the non-coding genome, which can lead to a high level of understanding of developmental stages, brain regions, cell types and biological functions.Reference Sanders, Neale, Huang, Werling, An and Dong24 Nevertheless, sequencing the whole genome and exome in considerable numbers of patients with bipolar disorder may lead to the identification of new rare and very rare genetic variants associated with bipolar disorder, characterised by larger effect sizes than common variants.

In genetic association studies, which investigate many genetic variants to detect disease-associated ones, appropriate adjustment for multiple comparison is needed for distinguishing true association and avoiding a flood of false-positive cases.Reference Yi, Xu, Lou and Mallick25 The effectiveness of genetic association studies to discover causative genes of complex disorders requires a sample size with appropriate statistical power, which will be influenced significantly by disease prevalence, disease allele frequency, linkage disequilibrium, inheritance models and effect size of the genetic variants. The smallest sample size required to generate appropriate statistical power (e.g. 80% power) is known as an effective sample size. In large-scale association studies, the statistical power of 80% is widely used to eliminate false-negative associations and establish the most cost-effective sample size.Reference Hong and Park26

The evidence collected over the past years indicates that bipolar disorder has an extremely polygenic architecture, with many genetic variants shaping the individual genetic vulnerability for this disorder. Polygenic risk scores (PRS), also referred to as polygenic scores, provide an estimate of this genetic vulnerability and represent a genetic tool with the potential to identify people who are at risk for bipolar disorder or for a worse course of the disease.Reference Eeltink, van der Horst, Zinkstok, Aalfs and Luykx27

Although the notion of endophenotypes has not yet proven to be as successful as expected for identifying genetic factors underlying the clinical heterogeneity of patients with bipolar disorder, it still holds interest in the context of large genomic surveys, particularly in the case of brain imaging. Magnetic resonance imaging (MRI) is a powerful, non-invasive method that allows researchers to survey brain morphology and function, to discover candidate endophenotypes and perhaps delineate pathways between genetic risk factors in bipolar disorder, alterations in the brain and the clinical manifestation of this disorder, including response to treatment.Reference Ching, Hibar, Gurholt, Nunes, Thomopoulos and Abé28

In this narrative review article, we provide an overview of genetic and neuroimaging studies on bipolar disorder by highlighting their significant results. The review includes GWASs and studies on WES and WGS that were identified in the PubMed database, as well as PRS and brain imaging sections. The definition of the key terms and abbreviations for genes are presented in the Supplementary Tables 1 and 2 available at https://doi.org/10.1192/bjo.2021.1082 (Glossary of Key Terms and Genes Abbreviation); however, readers who are unfamiliar with all of the terms, or who want to know more, are recommended to study the methodological details and technical points at,Reference Uffelmann, Huang, Munung, de Vries, Okada and Martin29,Reference Ku, Naidoo and Pawitan30 and.Reference Ng and Kirkness31

GWASs

In GWASs that are carried out following a case–control study design, cases fulfil the clinical criteria for a given disorder but controls do not. Following genotyping of a large number of genetic variants encompassing the whole genome in all samples, each SNP will be tested for disease association by statistically comparing allele frequencies in the group of cases versus the group of controls (Fig. 1). A significant difference of a particular SNP or locus indicates that it may play an aetiological role. Here, a typical type 1 error threshold for genome-wide significance is often considered 5 × 10−8, providing a multiple-testing correction threshold suitable in a genomic context that involves the analysis of several millions of genetic variants.Reference Sullivan32

Fig. 1 Genome-Wide Association Studies (GWASs). SNP, single nucleotide polymorphism.

We queried PubMed with the search string ‘genome-wide association studies and bipolar disorder’, and then searched for the original articles that reported on GWASs on data from patients with bipolar disorder and had significant results (P < 5 × 10−8). These studies are described in the following paragraphs. Although the first GWAS on bipolar disorder did not generate results that were significant at the specified threshold, we start our overview with a brief description of its findings.

The first GWAS on bipolar disorder was published in 2007 and included approximately 2000 British patients and 3000 controls. This GWAS did not find a genome-wide significant SNP for bipolar disorder and only identified rs420259 (P = 6.3 × 10−8) on chromosome 16p12 as the SNP with the strongest association. PALB2, NDUFAB1 and DCTN5 are located at this locus. PALB2 plays a role in the stability of critical nuclear structures, NDUFAB1 encodes a subunit of complex I of the mitochondrial respiratory chain and DCTN5 encodes a protein that is involved in intracellular transport.33

In 2008, Baum et al published another of the first GWASs on bipolar disorder. The combined sample, which included a test sample (National Institute of Mental Health: 413 cases, 563 controls) and replication sample (Germany: 772 cases, 876 controls), comprised 1185 cases and 1439 controls. The group identified rs1012053 in the first intron of DGKH (P = 1.5 × 10−8; odds ratio 1.59) as an SNP with a strong significant association with bipolar disorder. DGKH is located within the bipolar disorder linkage region on chromosome 13q14 and encodes diacylglycerol kinase eta, an important protein in the lithium-sensitive phosphatidylinositol pathway.Reference Baum, Akula, Cabanero, Cardona, Corona and Klemens10

Also in 2008, Sklar et al reported on a GWAS on 1461 patients with bipolar disorder and 2008 controls. The authors did not detect SNPs that met the threshold for genome-wide significance, but haplotype analysis identified a haplotype in MYO5B on chromosome 18 that reached the genome-wide significance threshold (haplotypic P = 2.04 × 10−8; odds ratio 1.51). In this region, rs4939921 in the intronic region of MYO5B was the SNP with the strongest evidence for association. MYO5B is a large and brain-expressed gene that is involved in vesicle trafficking regulation, and encodes a multifunctional protein in dendritic spines and other brain structures.Reference Sklar, Smoller, Fan, Ferreira, Perlis and Chambert34

Also in 2008, Ferreira et al published a collaborative GWAS in which they combined their data-set (ED-DUB-STEP2: Included additional samples from the Systematic Treatment Enhancement Program for Bipolar Disorder study as well as cases and controls from the University of Edinburgh and Trinity College Dublin) with two other data-sets (from the Wellcome Trust Case-Control Consortium and Systematic Treatment Enhancement Program-University College London studies) to obtain a larger sample size (4387 cases, 6209 controls) to improve the power for identifying risk alleles of modest effect. The analysis detected the imputed SNP rs10994336 (P = 9.1 × 10−9; odds ratio 1.45) in ANK3 on chromosome 10q21 as the strongest finding that surpassed the genome-wide significance threshold. The ANK3 protein was first found at the axonal initial segment and is involved in the regulation of voltage-gated sodium channels. The authors also reported on another variant in the third intron of the CACNA1C on chromosome 12p13 as the second strongest region of association (rs1006737; P = 7.0 × 10−8; odds ratio 1.181). They concluded that bipolar disorder pathogenesis may be caused by ion channelopathies.Reference Ferreira, O'Donovan, Meng, Jones, Ruderfer and Jones35

In 2010, Wang et al published a meta-analysis on 653 cases of bipolar disorder and 1034 controls, and 1172 cases of schizophrenia and 1379 controls. In their combined analysis of both disorders (1825 cases and 2413 controls), they detected two genome-wide significant SNPs that did not reach the threshold before in either of the two separate samples. One of the SNPs, rs11789399 (P = 5.56 × 10−9) on chromosome 9q33.1, is close to ASTN2, which is associated with schizophrenia, and the other, rs12201676 (P = 3.88 × 10−8) on chromosome 6q15, is near to GABRR1 and GABRR2. ASTN2 is involved in promoting the migrations of neuronal precursors and modulating synaptic activity,Reference Bauleo, Montesanto, Pace, Brando, De Stefano and Puntorieri36 and GABRR1 and GABRR2 are two components of gamma-aminobutyric acid (GABA)-type alpha receptor complex that have important roles in many physiological functions in the brain.Reference Jiménez-Jiménez, Esguevillas, Alonso-Navarro, Zurdo, Turpín-Fenoll and Millán-Pascual37 The results of the meta-analysis and haplotype analyses of the detected loci represented further evidence of the overlap in genetic risk between schizophrenia and bipolar disorder.Reference Wang, Liu and Aragam38

In 2011, Cichon et al published a GWAS and two follow-up replication studies. The best result in their GWAS on 682 patients with bipolar disorder and 1300 controls was a P-value of 3.42 × 10−6 and an odds ratio of 1.53 for rs1064395 in NCAN on chromosome 19p13.11. After combining this primary analysis with replication samples, this SNP reached genome-wide significance. For rs1064395, the first combined study (GWAS plus replication study 1: 2411 cases, 3613 controls) found a P-value of 3.02 × 10−8 and an odds ratio of 1.31, and the second combined study (GWAS plus replication studies 1 and 2: 8441 cases, 35 362 controls) found a P-value of 2.14 × 10−9 and an odds ratio of 1.17. The researchers concluded that the results support the idea that genetic variation in NCAN, which is highly expressed in the brain, is involved in the aetiology of bipolar disorder. Neurocan is an extracellular matrix glycoprotein that is thought to play a role in cell adhesion and migration. Laboratory mice showed localised expression of NCAN in the cortex and hippocampus of the brain, and unusual changes in these regions have been reported in patients with bipolar disorder.Reference Cichon, Mühleisen, Degenhardt, Mattheisen, Miró and Strohmaier9

Also in 2011, Kerner et al presented a GWAS on 1000 White patients with bipolar disorder and 1034 controls. Most of the patients in this study had one or more comorbidities, such as substance misuse, obsessive–compulsive disorder, attention-deficit hyperactivity disorder, alcohol misuse and substance dependence. The study identified two genome-wide significant SNPs: rs1039002 and rs2727943. rs1039002 (P = 1.7 × 10−8) is a low-frequency variant on chromosome 6q27 that is associated with bipolar disorder in patients with psychosis and/or substance misuse in the absence of alcohol dependence. The gene with a known function that is nearest to this variant is PDE10A, which is highly expressed in the brain and plays a role in the elimination of cyclic adenosine monophosphate (cAMP) and cyclic guanosine monophosphate (cGMP); the inhibition of this gene seems to have therapeutic effects on psychotic symptoms. rs2727943 (P = 3.3 × 10−8) is on chromosome 3p26.3 and is associated with bipolar disorder in patients with alcohol dependence and other comorbidities. It is located in the intergenic region between BIG-2 and CNTN6, and the encoded proteins may be involved in axon connections in the brain.Reference Kerner, Lambert and Muthén39

As described in their 2011 publication, Sklar et al, as part of the Psychiatric GWAS Consortium Bipolar Disorder Working Group, performed a GWAS on primary samples (7481 bipolar disorder cases, 9250 controls), analysed the results in the replication sample (4493 independent cases, 42 542 independent controls) and performed a meta-analysis in the combined samples (11 974 cases, 51 792 controls). In the primary GWAS, rs10994397 (P genomic control = 7.1 × 10−9; odds ratio 1.35) in ANK3 on chromosome 10q21, and rs9371601 (P genomic control = 4.3 × 10−8; odds ratio 1.15) in SYNE1 on chromosome 6q25, were significant. Because of population substructure or cryptic relatedness, false associations might occur in case–control studies, increasing the variance of the trend test. The genomic control approach is used to calculate the variance inflation factor and adjust the test statistic. In the combined analysis (primary GWAS and replication samples), these two variants did not reach the genome-wide significance threshold (P = 1.52 × 10−7 and P = 6.14 × 10−8, respectively), but four other SNPs did: rs4765913 (P = 1.82 × 10−9; odds ratio 1.14) in CACNA1C on chromosome 12; rs10896135 (P = 2.77 × 10−8; odds ratio 0.89) in a region of linkage disequilibrium (the non-random association of alleles at different loci in a given population) on chromosome 11, which contains 33 genes; rs12576775 (P = 6.32 × 10−9; odds ratio 0.88) in ODZ4 on chromosome 11; and rs7296288 (P = 8.6 × 10−9; odds ratio 0.90) in a region of linkage disequilibrium of approximately 100 kb on chromosome 12, which contains seven genes. These results confirmed the evidence for an association of both CACNA1C and ODZ4 with bipolar disorder. CACNA1C encodes an alpha-1 subunit of a voltage-dependent calcium channel, which is a key component in neuronal plasticity, and the protein encoded by ODZ4 is one of the teneurins, a conserved family of cell-surface transmembrane proteins that plays a role in intercellular signalling, neuronal pathfinding and proper connectivity throughout development.40,Reference Zheng, Freidlin, Li and Gastwirth41

In a study reported in 2012, Green et al, in a combined analysis of their independent UK samples (1527 cases, 1579 controls) with the Psychiatric Genomics Consortium Bipolar Disorder Working Group (PGC-BD) data, found genome-wide significant evidence for the association of rs9371601 with bipolar disorder (P = 2.9 × 10−8; odds ratio 1.104). rs9371601 is located in intron 16 of SYNE1, which encodes nesprin-1 as a part of the complex that links the nucleoskeleton to the cytoskeleton. Some mutations in SYNE1 cause neurodegenerative and neuromuscular dystrophy disorders, and increase risk for recurrent depression.Reference Green, Grozeva, Forty, Gordon-Smith, Russell and Farmer42

In 2013, Chen et al published a GWAS meta-analysis of samples of European and Asian ancestry (6658 cases and 7155 controls). In phase 2 of their analysis, which tested the most significant findings from phase 1, the researchers examined an extended sample of 7773 cases and 9883 controls. They reported five significant SNPs (P < 5 × 10–8) for bipolar disorder in five regions; two of them had been reported before (rs7618915 within the 3p21 region and rs4948418 near ANK3), but three of them were novel: rs9834970 near TRANK1, rs2271893 near LMAN2L and rs4650608 near PTGFR. TRANK1 on chromosome 3p22.2 encodes a P-loop containing nucleoside triphosphate hydrolase, which is associated with DNA/ATP binding or DNA repair; relevant cell line experiments suggest that the causal variant(s) in TRANK1 result in loss of function. LMAN2L on chromosome 2 may be an ERGIC-53 (ER-Golgi intermediate compartment 53) regulator and play a role in the regulation of glycoprotein export from the endoplasmic reticulum. In addition, PTGFR on chromosome 1p31.1 is a member of the G-protein-coupled receptor (GPCR) family. All three of these genes have high expression in the brain.Reference Chen, Jiang, Akula, Shugart, Wendland and Steele14

Also in 2013, Green et al published a meta-analysis of a combination of their independent sample data (1218 cases, 2913 controls) and a PGC-BD data-set (7481 bipolar disorder cases, 9250 controls). The analysis found four SNPs that surpassed the genome-wide significance threshold. Two of these, rs12576775 in ODZ4 (P = 6.20 × 10−9; odds ratio 0.88) on chromosome 11 and rs4765913 in CACNA1C (P = 9.78 × 10−10; odds ratio 1.14) on chromosome 12, had been reported before; however, the other two, rs7296288 (P = 8.97 × 10−9; odds ratio 0.90) in the intergenic region between RHEBL1 and DHH on chromosome 12q13.1 and rs3818253 (P = 3.88 × 10−8; odds ratio 1.16) in the intronic part of TRPC4AP on chromosome 20q11.2, represented novel findings.Reference Green, Hamshere, Forty, Gordon-Smith, Fraser and Russell43

In 2014, Mühleisen et al reported on a GWAS on 9747 cases and 14 278 controls. The authors reported 56 genome-wide significant SNPs in five regions: ANK3 on chromosome10q21.2 with 26 SNPs (top SNP: rs10994415-C, P genomic control = 6.88 × 10−11; odds ratio 1.27), TRANK1 on chromosome 3p22.2 with 14 SNPs (top SNP: rs6550435-G, P genomic control = 2.05 × 10−8; odds ratio 1.13), ODZ4 on chromosome 11q14.1 with ten SNPs (top SNP: rs12290811-A, P genomic control = 1.09 × 10−9; odds ratio 1.19), MIR2113-POU3F2 region on chromosome 6q16.1 with four SNPs (top SNP: rs12202969-A, P genomic control = 1.08 × 10−8; odds ratio 1.12) and ADCY2 on chromosome 5p15.31 with two SNPs (top SNP: rs17826816-G, P genomic control = 9.89 × 10−9; odds ratio 1.14). This GWAS confirmed three previous loci (ANK3, ODZ4 and TRANK1) and identified two novel loci (ADCY2 and the region between MIR2113 and POU3F2). ADCY2 is a cell-membrane-bound key enzyme in cAMP signalling and is involved in cAMP-dependent GPCR pathways. Although no specific gene can be considered for the region between MIR2113 and POU3F2 on chromosome 6q16.1, rs1906252 (one of the four SNPs in this region with genome-wide significance in this study) was found to be correlated with speed of information processing and cognitive phenotype in a GWAS on information processing speed.Reference Mühleisen, Leber, Schulze, Strohmaier, Degenhardt and Treutlein44

In 2016, in the context of a lithium pharmacogenomics study, Song et al published a GWAS that was based on Swedish and UK patients with bipolar disorder, and compared lithium responders with non-responders and lithium responders with healthy controls. The latter comparison, which analysed objective criteria (387 responders and 6684 controls), reported a variant with genome-wide significance, rs146727601 (P = 1.22 × 10−9; odds ratio 4.12) in PTS on chromosome 11q22.4. PTS encodes 6-pyruvoyltetrahydropterin synthase, which acts as a catalyst in the regulation of serotonin biosynthesis and nitric oxide synthase activity that, in turn, have been suggested as potential therapeutic targets for lithium. rs146727601, which is a two-base deletion, is also close to the PLET1. Song et al concluded that focusing on bipolar disorder subtypes could facilitate discovering the aetiology of bipolar disorder.Reference Song, Bergen, Di Florio, Karlsson, Charney and Ruderfer45,Reference Song, Bergen, Di Florio, Karlsson, Charney and Ruderfer46

Also in 2016, Hou et al published one of the largest GWASs, on 9784 patients with bipolar disorder and 30 471 controls. In their study, six autosomal loci surpassed the genome-wide significance threshold. Multiple SNPs in high linkage disequilibrium in several discovered loci were identified, but approximate conditional analysis with genome-wide complex trait analysisReference Yang, Lee, Goddard and Visscher47 confirmed that each of the six loci was consistent with just one specific signal. Of the six significant loci, four had been reported before, but two were novel. The most significant SNP in one of these new loci was rs2517959 (P = 4.53 × 10−9; odds ratio 1.13) on chromosome 17q12, which is in an intronic part of the ERBB2; this gene is expressed in the brain and encodes a member of the epidermal growth factor family of receptor tyrosine kinases that acts as a cell-surface receptor for neuregulins. The most significant SNP in the other novel locus was rs12553324 (P = 5.87 × 10−9; odds ratio 1.12), which is located in the intergenic region on chromosome 9p21.3, where an SNP (rs10965780) with moderate linkage disequilibrium (r2 = 0.6) is related to the ELAVL2, which encodes a neuron-specific RNA binding protein for development of neurons. The four SNPs that had been previously reported were rs4236274 (P = 8.49 × 10−12; odds ratio 0.87) on chromosome 7p22.3, which was the most significant variant in the study and is located in an intron of MAD1L1; rs9834970 (P = 4.83 × 10−10; odds ratio 0.88) on chromosome 3p22.2, which was the second most significant finding in this study and is related to a region close to TRANK1; rs1054442 (P = 1.20 × 10−8; odds ratio 1.13) on chromosome 12q13.1 in DDN, which encodes a synapse-related cytoskeletal protein (Dendrin); and rs1487441 (P = 2.58 × 10−8; odds ratio 1.12) on chromosome 6q16.1, in an intergenic region between MIR2113 and POU3F2. This study did not find any significant X-chromosome associations, which the authors suggested was because of the low roles of X-linked markers in the heritability of bipolar disorder. Hou et al also concluded that the highly polygenic background of bipolar disorder will require larger sample sizes to detect more involved variants.Reference Hou, Bergen, Akula, Song, Hultman and Landén48

In 2017, Charney et al published a GWAS on 6447 cases of bipolar disorder and 12 639 controls from the International Cohort Collection for Bipolar Disorder. They found two regions that met the genome-wide significance threshold (P < 5 × 10−8): one was a two-base-pair deletion on chromosome 9 (P = 2.48 × 10−8; odds ratio 1.14), and the other was a locus on chromosome 10 that includes rs10884920 (P = 1.20 × 10−8; odds ratio 1.17). ADD3 and XPNPEP1 are the genes that are located in strong linkage disequilibrium with the reported locus on chromosome 10. A non-coding RNA sequence (LOC100505933) that is annotated as an anti-sense ADD3 RNA is also located in this region. ADD3 encodes a ubiquitously expressed cytoskeletal protein implicated in cerebral palsy that is responsible for assembling and disassembling actin filaments, and for the binding of actin to spectrin in the brain and other tissues. Aminopeptidase P is involved in the degradation and maturation of neuropeptides and mediates the proteolytic cleavage of the N-terminal amino acid in peptides with proline, such as oxytocin, corticotropin-releasing hormone, neuropeptide Y and substance P. The researchers also performed a meta-analysis of their data and the data from the meta-analysis by the PGC-BD, with a total of 13 902 cases and 19 279 controls, and found eight significant regions. The index SNPs from each independent locus and the related gene or genes in linkage disequilibrium (R 2 > 0.25) include rs56361249 (P = 3.19 × 10−10; odds ratio 1.12; LMAN2L, FER1L5, CNNM4) on chromosome 2, rs9834970 (P = 1.59 × 10−10; odds ratio 0.90; TRANK1) on chromosome 3, rs2302417 (P = 2.75 × 10−9; odds ratio 1.11; many genes) on chromosome 3, rs1203233 (P = 4.46 × 10−8; odds ratio 0.91; SYNE1) on chromosome 6, rs10994299 (P = 1.28 × 10−9; odds ratio 0.81; ANK3) on chromosome 10, rs10884920 (P = 3.28 × 10−8; odds ratio 1.12; ADD3, LOC100505933, XPNPEP1) on chromosome 10, rs4765913 (P = 3.12 × 10−9; odds ratio 1.13; CACNA1C family) on chromosome 12 and rs10459221 (P = 2.33 × 10−8; odds ratio 0.91; many genes) on chromosome 12. Regarding the heritability and genetic correlation of bipolar disorder subtypes, the authors reported a significant difference in the heritability: bipolar disorder type 1 SNP h2 = 0.35 and bipolar disorder type 2 SNP h2 = 0.25, with a genetic correlation between these subtypes of 0.78.Reference Charney, Ruderfer, Stahl, Moran, Chambert and Belliveau49

In their 2018 publication, Ikeda et al described a GWAS on 2964 bipolar disorder cases and 61 887 controls from the Japanese population. They reported a significant locus on chromosome 11q12.2, a region known to contain regulatory genes FADS1/2/3 for blood lipid traits and levels. Here, the top SNP was rs28456 (P = 6.4 × 10−9; odds ratio 1.18), which is located in FADS2. Subsequently, they performed a meta-analysis of the Japanese and PGC-BD data-sets, with a total of 10 445 cases and 71 137 controls. In this meta-analysis, again they found rs174576 (P = 1.34 × 10−10; odds ratio 1.13) as the most significant signal from the same region as identified in their first GWAS. According to the GTEx (Genotype-Tissue Expression) and The Brain eQTL Almanac data-sets, rs174576 is an expression quantitative trait loci of FADS1 and FADS2 in the cerebellum and temporal cortex, respectively. All quantitative trait loci SNPs for lipid traits (igh Density Lipoprotein cholesterol/Low Density Lipoprotein cholesterol/Triglyceride/Total-Cholesterol), n−3/n−6 polyunsaturated fatty acids) around the FADS region were in strong linkage disequilibrium with the index SNP (rs174576) and, because of this, the authors suggested the involvement of lipid abnormalities in pathophysiological mechanisms of bipolar disorder. This meta-analysis detected another novel association with bipolar disorder, NFIX, with the best signal from rs4926298 (P = 5.8 × 10−10; odds ratio 1.13), and also replicated three regions previously implicated in susceptibility to bipolar disorder, including MAD1L1 (best: rs4332037; P = 1.9 × 10−9; odds ratio 1.17), TRANK1 (best: rs9834970; P = 2.1 × 10−9; odds ratio 1.12) and ODZ4 (best: rs12576775; P = 3.3 × 10−9; odds ratio 1.18). NFIX is a member of the nuclear factor one (NF1) family, and is involved in transcription and replication. Mutations in this gene can cause some syndromes associated with intellectual disability. ODZ4 (also known as TENM4) encodes teneurin transmembrane protein 4, which plays a role in neuronal connectivity during development. MAD1L1 encodes MAD1 mitotic arrest deficient-like 1, which is involved in regulating the cell cycle.Reference Ikeda, Takahashi, Kamatani, Okahisa, Kunugi and Mori50

In 2019, Stahl et al presented the findings from one of the largest GWASs in bipolar disorder so far, which included 20 352 cases and 31 358 controls of European descent (with a follow-up analysis of 822 variants with P < 1 × 10−4 in an additional sample of 9412 cases and 137 760 controls). In the combined GWAS plus follow-up analysis, the researchers identified 30 loci with genome-wide significance, 20 of which were novel. Twelve previously reported loci did not reach genome-wide significance in this GWAS meta-analysis. The strongest association signals were found for rs9834970 at the TRANK1 locus (P combined = 5.7 × 10−12; odds ratio 0.93) and rs2302417 at the ITIH1 locus (P combined = 6.6 × 10−11; odds ratio 0.93). Five other top significant signals out of the 30 loci are: rs11647445 at the GRIN2A locus on chromosome 16 (P combined = 1.1 × 10−10; odds ratio 0.93), rs10744560 at the CACNA1C locus on chromosome 12 (P combined = 3.6 × 10−10; odds ratio 1.076), rs201231874 at the MRPS33 locus on chromosome 7 (P combined = 6.2 × 10−10; odds ratio 0.92), rs61332983 at the intergenic locus (nearest gene: PCGEM1) on chromosome 2 (P combined = 7.9 × 10−10; odds ratio 0.93) and rs12226877 at the FADS2 locus on chromosome 11 (P combined = 9.9 × 10−10; odds ratio 1.085). The identified loci include genes that encode ion channels and transporters (CACNA1C, SCN2A and SLC4A1), neurotransmitter receptors (GRIN2A) and synaptic components (RIMS1 and ANK3). Regulation of insulin secretion and endocannabinoid signalling are two out of nine significant enriched gene-sets that resulted from pathway analysis. Stahl et al concluded that brain calcium channels and regulation of neurotransmitters play roles in the aetiology of bipolar disorder. In addition, they mentioned that discordance of results within and across GWASs could be a result of the intricate genetic architecture and phenotypic heterogeneity of bipolar disorder as a complex psychiatric disorder with a highly polygenic background.Reference Stahl, Breen, Forstner, McQuillin, Ripke and Trubetskoy51

In 2021, Mullins et al reported on the largest GWAS to date, with 41 917 patients with bipolar disorder and 371 549 controls of European ancestry (57 bipolar disorder cohorts collected in Europe, North America and Australia). This GWAS meta-analysis detected 64 independent loci associated with bipolar disorder at genome-wide significance (P < 5 × 10−8), 33 of which were new. Among the 64 loci, the ten top associations were as follows: rs983 4970 (P = 6.6 × 10−19; odds ratio 1.087) located in TRANK1 on chromosome 3, rs1487445 (P = 1.5 × 10−15; odds ratio 1.078) located in POU3F2 on chromosome 6, rs11062170 (P = 1.9 × 10−15; odds ratio 1.081) located in CACNA1C on chromosome 12, rs13195402 (P = 5.8 × 10−15; odds ratio 1.146) located in MHC on chromosome 6, rs174592 (P = 9.9 × 10−14; odds ratio 1.074) located in FADS2 on chromosome 11, rs113779084 (P = 1.4 × 10−13; odds ratio 1.079) located in THSD7A on chromosome 7, rs2336147 (P = 3.6 × 10−13; odds ratio 1.070) located in ITIH1 on chromosome 3, rs10994415 (P = 1.1 × 10−11; odds ratio 1.125) located in ANK3 on chromosome 10, rs2273738 (P = 1.6 × 10−11; odds ratio 1.096) located in ADD3 on chromosome 10 and rs62489493 (P = 2.6 × 10−11; odds ratio 1.094) located in miR124-1 on chromosome 8. The genes encoding targets for antipsychotics, calcium channel blockers, anti-epileptics, and anaesthetics were shown to have significant signal enrichment.Reference Mullins, Forstner, O'Connell, Coombes, Coleman and Qiao17

Polygenicity and polygenic scores

One of the main lessons from the aforementioned GWASs is the extensive polygenicity that characterises the genetic architecture of bipolar disorder. This fact implies that the genetic factors that shape the individual vulnerability to bipolar disorder (and most human complex traits) involve hundreds to thousands of common genetic variants that are frequently found in humans, and each contribute to vulnerability with a discrete effect size.

Nowadays, the individual polygenic risk load in each individual can be estimated by using PRS. In general, PRS are calculated as a sum of an individual's phenotype-associated alleles (i.e. in the present context, alleles associated with bipolar disorder) weighted by the effect size of each variant. The effect sizes are derived from large GWASs. PRS provide a quantitative measure of the risk burden in each individual.

One of the main advantages of PRS are their usefulness as genetic tools for genetic analyses, because they summarise the global genomic risk rather than focusing on specific variants. The sample size required to evaluate the role of polygenic risk on a certain trait is substantially smaller than the one needed to quantify the genetic contribution of each genetic variant contributing to such PRS (discovery GWAS).Reference Uffelmann, Huang, Munung, de Vries, Okada and Martin29 Thus, they hold great potential as a risk predictor for preventive approaches or for stratifying patients according to the likelihood that they will respond better to a given clinical intervention.Reference Eeltink, van der Horst, Zinkstok, Aalfs and Luykx27

PRS have shown fairly good replicability across independent samples if the discovery GWAS was well powered. In the particular case of bipolar disorder, leave-one-out analyses showed that the association of bipolar disorder-PRS with risk of bipolar disorder is consistent in each independent sample.Reference Mullins, Forstner, O'Connell, Coombes, Coleman and Qiao17 The same study showed that in European samples of patients with bipolar disorder, bipolar disorder PRS explained approximately 4.57% of phenotypic variance in bipolar disorder on the liability scale. Moreover, although they explained less phenotypic variance, bipolar disorder PRS were also significantly associated with bipolar disorder risk in people of African and East Asian ancestries.

Given the pleiotropic effect of most variants (i.e. their simultaneous effect on the expression of several traits and/or disorders), PRS can also help to unravel genetic similarities between various traits and disorders. The first large GWAS on schizophrenia published in 2009 already showed that patients with bipolar disorder have a higher genetic load for schizophrenia (schizophrenia PRS) than the general population, a finding that aligned with previous clinical and epidemiological evidence of a large overlap between both disorders.Reference Purcell, Wray, Stone, Visscher, O'Donovan and Sullivan52

Among the ever-increasing findings on PRS–phenotype associations, several results are particularly interesting for our understanding of the genetic architecture of bipolar disorder. First, patients with bipolar disorder not only have a higher genetic risk for bipolar disorder than healthy controls, but they also have an increased genetic risk load for schizophrenia (schizophrenia PRS) and major depression (major depressive disorder PRS).Reference Andlauer, Guzman-Parra, Streit, Strohmaier, González and Gil Flores53 Second, a comparison of bipolar disorder types 1 and 2 showed that these two groups do not have a similar profile of polygenic risk, at least regarding the risk of depression.Reference Guzman-Parra, Streit, Forstner, Strohmaier, González and Gil Flores54 Third, bipolar disorder PRS are associated not only with other psychiatric phenotypes, but also with several clinical features and potential biomarkers in different psychiatric conditions.Reference Mistry, Harrison, Smith, Escott-Price and Zammit55 Finally, certain clinically relevant features in bipolar disorder, such as response to lithium treatment or age at onset, are not associated with bipolar disorder PRS but are associated with other psychiatric PRS.Reference Amare, Schubert, Hou, Clark, Papiol and Cearns4,Reference Hou, Heilbronner, Degenhardt, Adli, Akiyama and Akula56,Reference Amare, Schubert, Hou, Clark, Papiol and Heilbronner57

WES

WES analysis on bipolar disorder samples can reveal the contribution of rare variants to the genetic architecture of this heritable complex disorder.Reference Toma, Shaw, Allcock, Heath, Pierce and Mitchell58 WES is an economical approach for looking into the genetic variations that are most likely to have an effect on gene structure and function. Although it may be advantageous to have a more confined data-set for clinical applications, one of the key drawbacks of WES is that it only sequences roughly 1% of the genome. WES cannot check large portions of the genome that we do not already recognise as protein-coding regions, and so nucleotides in other regions will be ignored. As a result, for example, if a high-impact variant is in a distal regulatory element or in 5′ and 3′ untranslated regions, it will go unnoticed.Reference Monson, Pirooznia, Parla, Kramer, Goes and Gaine22,Reference Biesecker, Shianna and Mullikin59 We queried PubMed with the search string ‘whole exome sequencing and bipolar disorder’ to identify studies that performed WES in bipolar disorder samples.

In 2013, Chen et al published a study that used a new hybrid likelihood model (burden or mutation position test) to examine WES data from 191 cases of bipolar disorder and 107 controls, and identified seven gene-sets related to bipolar disorder. The MAPK signalling pathway (defined by the KEGG Pathway Database) was the most significant gene-set and reached trend-level significance after multiple testing correction (nominal P = 0.0065; false discovery rate 0.095). This highly conserved pathway included 267 genes such as DUSP6, CACNA1C and the phospholipase A2 family of genes.Reference Chen, Carter, Parla, Kramer, Goes and Pirooznia60

In 2016, Kataoka et al published a trio-based WES study on bipolar disorder that examined 237 samples (79 affected probands and their unaffected parents), and identified 71 de novo point mutations in 70 genes and one de novo copy number variation (a deletion located upstream of the 3q29 deletion syndrome locus with a reported association with bipolar disorder) in 79 probands with bipolar disorder. Each proband had zero to four mutations, and 42 probands had at least one mutation. The researchers reported that EHD1, KLF4, KMT2C, MACF1, UNC13B and XPO4 were detected as being intolerant to a functional variation hit by de novo loss-of-function mutations from WES, and can be considered as bipolar disorder susceptibility gene candidates. Gene ontology enrichment analysis with the Database for Annotation, Visualization and Integrated Discovery (version 6.7) resulted in no significant gene ontology term after correction for multiple testing.Reference Kataoka, Matoba, Sawada, Kazuno, Ishiwata and Fujii61

In 2017, Lescai et al presented the results of WES of an isolated population (Faroese) that included 28 patients with bipolar disorder and 214 controls, and then tried to replicate the results in a British sample (2025 cases and 1358 controls). In the discovery step, they reported 17 exome-wide significant variants in 16 genes in the single-variant analysis and three significant genes in the gene-based statistics. NOS1 (rs79487279 as a mis-sense variant) and NCL (gene-based test) were present in the British replication samples, but PITPNM2 (12:123489064_C as a mis-sense variant) and PIK3C2A were absent. Both PITPNM2 and PIK3C2A are components of the phosphatidylinositol pathway, which has been linked to psychiatric disorders. The only statistically significant variable after Bonferroni correction (P = 0.002, P corrected = 0.032) was rs79487279 in NOS1, which encodes neuronal nitric oxide synthase. This enzyme catalyses the production of nitric oxide, which, as a neurotransmitter, has interactions with the dopaminergic and serotonergic systems.Reference Lescai, Als, Li, Nyegaard, Andorsdottir and Biskopstø62

Also in 2017, Monson et al published the findings of WES for approximately 19 000 genes of 1018 patients with bipolar disorder (387 people with a history of suicide attempt and 631 people without such a history), but they did not find any individual suicide-associated significant variant or gene at study-wide significance.Reference Monson, Pirooznia, Parla, Kramer, Goes and Gaine22

In a study published in 2018, Cruceanu et al sequenced whole exomes of 186 patients with bipolar disorder or related individuals from 40 multiplex families and approximately 800 controls. The authors postulated the causality of deleterious rare variants in disease transmission across generations. By following a variant filtration approach and focusing on potential pathogenic variants, they identified rare variants in many genes and brain-related pathways. GPCR family genes, which are involved in regulating brain functions and are also considered as drug targets, were enriched in the identified rare variants among most of the studied families (in 38 out 40 families, with a mean of five variants per family). CRHR2, HTR1B, GRM1, GRM4 and DRD5 are some of the GPCR genes with flagged mutations. The identified non-sense mutation (R384X: arginine to stop codon) in CRHR2 (which plays a role in stress response) removes the last 28 amino acids, resulting in impaired complex formation, with regulators leading to increased signal transduction and effects on several downstream cellular functions. In GRM1, which is involved in synaptic plasticity-related learning and memory, a mis-sense mutation (exon6:c.T1524G, p.D508E) occurred that had no effect on receptor function, but may have had an effect on the kinetics of GPCR activation.Reference Cruceanu, Schmouth, Torres-Platas, Lopez, Ambalavanan and Darcq63

In 2018, Salvoro et al published WES results on 17 patients (including six cases of bipolar disorder) from a familial sample (including 90 cases of schizophrenia, 50 cases of bipolar disorder and 21 cases of schizophrenia) in combination with identity-by-descent (IBD) mapping data to identify risk loci in a related closed population. They identified a total of 13 330 rare (minor allele frequency [MAF] <0.01) and 3903 novel variants. After mapping and phasing into the total list (IBDtot) haplotypes and checking for sharing in whole sample, 1393 variants (1052 rare and 341 novel) were identified as IBDrisk haplotypes. Pathway and gene-set enrichment analysis indicated the involvement of extracellular matrix interactions, axon guidance and synaptic functions (development of neuronal connectivity) in the aetiology of and susceptibility to bipolar disorder.Reference Salvoro, Bortoluzzi, Coppe, Valle, Feltrin and Mostacciuolo64

In 2018, Zhang et al reported the results of WES and linkage analysis of six related patients with bipolar disorder. They identified six variants in five candidate genes (GRID1, CDHR1, DYDC2, GHITM and MINPP1) with potential effects on the onset and development of bipolar disorder. Among these six variants, rs2306265 (p.V529I) in GRID1 and rs45584033 (p.P812S) in CDHR1 were flagged as damaging (by Sorting Intolerant From Tolerant [SIFT], a program that predicts effects of amino acid changes on protein function) or probably damaging (by Polyphen-2, or Polymorphism Phenotyping version 2, a program for predicting the possible impact of amino acid substitutions on stability and function of proteins). GRID1 maps to chromosome 10 and encodes a subunit of glutamate receptor channels, which are involved in synaptic plasticity and transmission in the central nervous system. CDHR1 is located also on chromosome 10 and encodes a photoreceptor-specific cadherin protein that is involved in outer segment disc morphogenesis.Reference Zhang, Hou, Chen, McMahon, Wang and Rice23

In 2018, Toma et al published findings of WES of 117 members (72 with bipolar disorder and 45 unaffected by bipolar disorder) of 15 European-origin multiplex and extended families from Australia. In addition, they performed linkage analysis and haplotype reconstruction on WES-derived data, and copy number variation analysis to enrich, validate and improve the outputs as much as possible. They identified 532 potentially aetiologic and 541 likely neutral variants. Enrichment analysis results showed that the potentially aetiologic variants were overrepresented in postsynaptic density genes, which are extremely sequence conserved and include scaffolding proteins. The likely neutral variants were not enriched for any gene-sets. The authors discovered that the number of brain-expressed likely gene-disruptive variants was negatively associated with the age at onset, but they did not observe any differences in the total number of de novo variants between affected and unaffected offspring (32 sequenced parent–child trios: 22 parents with bipolar disorder and ten unaffected offspring). Combining rare variants of all classes with linkage evidence for each family resulted in a protein-truncating mutation in the X-linked gene IRS4, as a plausible new candidate for bipolar disorder. PCDHA gene cluster, which is expressed in serotonergic neurons, and PRODH which encodes a nuclear-encoded mitochondrial protein, both of which act as neuromodulators of dopaminergic synaptic transmission, are two of the genes with several rare recurrent variations identified in this study. Toma et al concluded that cumulative rare pathogenic variants in several postsynaptic density genes could disrupt synaptic homeostasis, with consequences in a variety of psychiatric disorders, such as bipolar disorder.Reference Toma, Shaw, Allcock, Heath, Pierce and Mitchell58

As described in their 2018 publication, Ganna et al investigated the effect of rare protein-truncating variants (PTVs) on 13 quantitative traits and ten diseases, including bipolar disorder, by analysing WES data from 100 296 individuals (1201 with bipolar disorder) from a combination of cohort and case–control disease studies. The authors focused on PTVs that occur in a set of 3172 PTV-intolerant genes, and showed an association with early-onset neurodevelopmental and psychiatric disorders (for bipolar disorder: P = 8 × 10−4; odds ratio 1.2). They reported that genes intolerant to PTVs are well-suited to capture the effect of rare to ultra-rare PTVs on the cognitive, behavioural and developmental spectra.Reference Ganna, Satterstrom, Zekavat, Das, Kurki and Churchhouse65

In 2018, Maaser et al reported the results of WES of 15 cases of bipolar disorder from two large Cuban families. Four people from family 1 (pedigree 1) and 11 from family 2 (pedigrees 2–4) were selected. The analysis detected 17 rare and non-synonymous frameshift-causing variants (14 mis-sense and 3 small insertions and deletions) in 17 genes that were shared by all patients with bipolar disorder within the related pedigree. Of 17 recognised genes harbouring these variants, according to the GTEx database, 13 genes (SERPING1, TMEM220, MYH7, THYN1, ATR, CSNK1G3, ZNF433, OLFML2B, CAPN2, RCCD1, DNAH7, SELENOO and COL3A1) are expressed in the brain. The variant rs141075266 in SERPING1 (p.L349F) was considered as the most interesting variant in this study. SERPING1, which was previously reported as a risk gene for schizophrenia with genome-wide significance, encodes the serpin peptidase inhibitor clade G member 1, which plays an important role in the regulation of complement activation.Reference Maaser, Forstner, Strohmaier, Hecker, Ludwig and Sivalingam66

Also in 2018, Husson et al published results of WES of 92 patients with bipolar 1 disorder (positive family history, 63% early onset) and 1051 controls of French ancestry. The authors were in search of rare predicted damaging variants (MAF < 0.01), but no gene in this study met the exome-wide P-value threshold (2.5 × 10−6) or the false discovery rate threshold (10%); however, they reported 13 genes (as top hits for rare variants) with P < 10−3 and a high odds ratio (range: 3–23.7) that are expressed in the brain. Among these genes, PLCXD3, ARHGAP9 and TCF7L1 have been reported to have potential roles in the therapeutic effect of lithium treatment.Reference Husson, Duboc, Quenez, Charbonnier, Rotharmel and Cuenca67

In 2019, Han et al described their WES study in 53 patients with bipolar disorder and 82 healthy controls. In the study, they also applied structural MRI data to find variants associated with cortical grey matter thickness and the integrity of white matter. They detected 122 bipolar disorder-related genes (such as KMT2C, AHNAK and CDH23) and 27 recurrent copy number alteration regions. In their paper, they mentioned the probable role of rs4639425 in KMT2C, which plays a role in chromatin remodelling via regulation of histone H3 lysine 4 (H3K4) methylation, in microstructural alterations of white matter tracts of the brain.Reference Han, Han, Kim, Kang, Kang and Kang68

In 2019, Ganesh et al presented the results of WES of 32 patients with severe mental illness (26 with bipolar disorder, four with schizophrenia, one with schizophrenia-like psychosis and one with schizoaffective disorder) from eight multiplex families and 33 Indian healthy controls. This study detected 42 rare, non-synonymous deleterious variants in 42 genes (approximately five per pedigree) in the form of a familiar private mutational profile. Twelve of the variants were novel, 20 were previously reported to be involved in different neuropsychiatric syndromes and nine had been reported in Mendelian syndromes with early-onset neurodevelopmental features. Two of the newly identified variants were c.A565G (p.S189G) and c.A4496C (p.Q1499P; segregating with bipolar disorder in a pedigree) in GRM1 and NIPBL, respectively. GRM1, which is involved in spinocerebellar ataxia, encodes metabotropic glutamate receptor 1, and pathogenic mutation in this gene causes early age at disease onset and associated intellectual disability. NIPBL encodes cohesin loading factor, which plays a role in cortical neuronal migration and causes Cornelia de Lange syndrome. MDN1, which plays a role in ribosomal large subunit assembly, and WDFY4, which acts as an integral component of membrane, are two reported bipolar disorder-related genes that were identified in this study as harbouring two detected rare variants (rs148868949 and rs571808731, respectively).Reference Ganesh, Ahmed P, Nadella, More, Seshadri and Viswanath69

Also in 2019, Szatkiewicz et al reported on WES of 25 patients with bipolar disorder (12 with bipolar disorder type 1 and 13 with bipolar disorder type 2) from a dense multiplex Swedish pedigree. First, they identified 129 651 variants (1.4% of which were novel) and, after some annotation filtering such as selecting variants with unknown or highest allele frequency; predicted as high impact; or those located in brain-expressed genes, 102 variants remained; however, they did not detect any shared strong predictions for more than half of the cases.Reference Szatkiewicz, Crowley, Adolfsson, Åberg, Alaerts and Genovese70

In 2020, Anjanappa et al published the results of WES of 11 patients with bipolar disorder from a four-generation Indian family and, based on the linkage investigations, focused on two genomic intervals on chromosome 1 and 6. They reported two rare variants: a rare, non-synonymous, heterozygous variant that was present in seven patients (rs776739426; p.D821Y) in KANK4 on chromosome 1p31.1–13.2, and a variant that was present in ten patients (rs910586667; in the 5′ untranslated region) in CAP2 on chromosome 6p22.3–22.2. KANK4 encodes a protein with KN motif that has potential nuclear localisation and export signal. CAP2 encodes one of the cyclase-associated proteins, which play a role in the regulation of actin dynamics. The authors suggested that KANK4 and CAP2, which are also expressed in the brain, alone or together are involved in bipolar disorder in the investigated family.Reference Anjanappa, Nayak, Moily, Manduva, Nadella and Viswanath71

In their 2020 publication, Forstner et al described their findings from WES of 81 patients with bipolar disorder from 23 Spanish and four German multigenerational, multiply affected families (three members from each family). The analysis considered only variants shared by all three investigated family members. The researchers identified 378 rare, non-synonymous and potentially functional variants in 368 genes. Eight of these genes (ADGB, DCAF5, NCKAP5, PKHD1L1, AOAH, CAND2, DIDO1 and RGS12) were shared by at least two independent families. All of the genes except for PKHD1L1 and ADGB are expressed in the brain, and five of them (ADGB, DCAF5, NCKAP5, PKHD1L1 and RGS12) had complete or nearly full penetrance in the extended segregation analysis. NCKAP5 and RGS12 had already been suggested by candidate gene studies as being associated with bipolar disorder. Although the role of NCKAP5, which is located on chromosome 2q21.2, is unknown, RGS12 is a member of the GTPase activating protein family mapping to chromosome 4p16.3, and is involved in regulation of GPCR signalling. The 368 genes identified in this study include 19 overlapping genes, e.g. ANK3, MACF1, MYO10 and SYNE1 (cytoskeleton-associated genes), with the previously reported genes from bipolar disorder GWASs and sequencing studies, highlighting the potential role of cytoskeletal pathways in the aetiology of bipolar disorder.Reference Forstner, Fischer, Schenk, Strohmaier, Maaser-Hecker and Reinbold72

Also in 2020, Jacobs et al presented the results of WES of five family members (two monozygotic twins with bipolar disorder and an unaffected brother and parents) that identified seven variants in six genes mostly involved in GABA/glutamatergic pathways. These six genes and their identified variants were as follows: NF1 on chromosome 17q11.2, a non-synonymous single nucleotide variation (nsSNV; c.3200A > T; p.Asp1067-Val) and a frameshift mutation owing to a deletion (c.3198CAGAG/Del; p.Asp1067fs); GGA3 on chromosome 17q25.1, a stop-loss mutation (c.672T > C); DISC1 on chromosome 1q42.2, an nsSNV (c.1694G > T; p.Cys565Phe); NMUR2 on chromosome 5q33.1, an nsSNV (c.617T > A; p.Val206Asp); HIP1R on chromosome 12q24.31, an nsSNV (c.1495G > A; Val499Met); and BOD1 on chromosome 5q35.2, an nsSNV (c.6C > T).Reference Jacobs, Hagin, Shugol, Shomron, Pillar and Fananas73

Also in 2020, Courtois et al published results of WES of 34 patients with bipolar disorder from eight multiplex families of French ancestry that included at least two people with bipolar disorder. After filtration of variants, they detected a total of 34 rare deleterious mutations in 34 genes (29 of which are expressed in neurons) that are involved in neuronal development, morphogenesis and regulation of neuronal gene expression. Among these genes, SMARCC2 (involved in transcription), HELLS (involved in genome-wide methylation), UPF2 (involved in proper development of synapse architecture and synaptic vesicle efficacy) and WDR37 (unknown function) showed a higher mutation rate in patients with bipolar disorder than in the Exome Aggregation Consortium (ExAC) population after correction for multiple testing. An analysis of the clinical profile of patients with these four genes revealed that mutated SMARCC2 caused a trend to more manic episodes, whereas mutated HELLS increased the chances of mixed episodes.Reference Courtois, Schmid, Wajsbrot, Barau, Le Corvoisier and Aouizerate74

In 2020, Engelbrecht et al described the findings of WES of eight Afrikaner family members (five members with bipolar disorder and three unaffected members) and identified two rare mis-sense variants in FAM71B and SLC26A9 that were shared by all five affected members, but were not present in any of the unaffected members. The authors mentioned that these variants were located in genes involved in signal transduction and synaptic transmission.Reference Engelbrecht, Dalvie, Agenbag, Stein and Ramesar75

In 2021, Umehara et al published the findings of WES of two patients with bipolar disorder from a Japanese family with a high frequency of bipolar disorder and recurrent major depressive disorder. In these two cases and four additional patients with bipolar disorder, two individuals of unknown status and ten healthy controls from this family, genome-wide linkage analysis were conducted before WES to restrict the linkage regions. Then, after performing different filtering steps on detected variants, they finally observed a rare heterozygous mutation in exon 31 of DOCK5 (c.3170A > G, p.E1057G). DOCK5 is involved in producing an atypical Rho guanine nucleotide exchange factor for Rac and/or Cdc42 GTPases. It is also an essential factor in transmitting glycogen synthase kinase 3 beta signals in mast cells in allergic reactions, and could play a role in microglial activation.Reference Umehara, Nakamura, Nagai, Kato, Ueno and Sano76

Also in 2021, Toma et al described the results of WES and linkage analysis of 117 members (50 patients with bipolar disorder) from 15 Australian families with a high density of mood disorders. After quality control and family gene-based segregation test, three brain-expressed genes containing rare mis-sense variants were identified on chromosome 10: ANK3, NRBF2 and PCDH15. For bipolar disorder, 10q11.23-q21.3 is an important locus in that it explains part of the related genetic risk. By using combined annotation dependent depletion and deleterious annotation of genetic variants using neural networks scoring tools to assay the protein-disrupting or -altering pathogenicity of detected rare variants in these genes, the researchers revealed the high rankings of these variants in the human genome (top 1 to 0.01% of the deleterious variants). PCDH15 is involved in neuronal differentiation and synapse formation, and NRBF2 plays a role in autophagy that is essential for neuronal survival and function.Reference Toma, Shaw, Heath, Pierce, Mitchell and Schofield77

Looking at the detected variants and related genes and loci throughout WES in different studies, some well-known candidate pathways and genes, such as MAPK signalling, phosphatidylinositol, cytoskeletal and GABA/glutamatergic pathways, as well as the GPCR family and some other genes, are identified. Most of these pathways and genes are responsible for several important neuronal-related properties such as development, morphogenesis, differentiation, survival, connectivity and axon guidance; regulation of gene expression; extracellular matrix interactions; signal transduction; synapse formation, plasticity and homeostasis; and synaptic transmission. Cumulative pathogenic variations in these genes, which can disrupt the important neuronal cellular and molecular processes, may put individuals at risk for mental disorders like bipolar disorder.Reference Zhang, Hou, Chen, McMahon, Wang and Rice23,Reference Toma, Shaw, Allcock, Heath, Pierce and Mitchell58,Reference Chen, Carter, Parla, Kramer, Goes and Pirooznia60,Reference Lescai, Als, Li, Nyegaard, Andorsdottir and Biskopstø62Reference Salvoro, Bortoluzzi, Coppe, Valle, Feltrin and Mostacciuolo64,Reference Forstner, Fischer, Schenk, Strohmaier, Maaser-Hecker and Reinbold72Reference Engelbrecht, Dalvie, Agenbag, Stein and Ramesar75

WGS

By scanning the complete genome (coding and non-coding regions), WGS has the potential to discover every allelic variant, and especially rare variants. Additional risk loci for neuropsychiatric disorders may be discovered through further analysis of the entire genome and within regulatory regions near candidate genes. However, because sample size is one of the most critical criterion in psychiatric genetic investigations, WGS remains expensive and technically challenging for very large sample sizes.Reference Monson, Pirooznia, Parla, Kramer, Goes and Gaine22,Reference Sanders, Neale, Huang, Werling, An and Dong24 Despite such economical constrains, a very recent UK Biobank release already includes WGS data of >150 000 participants.Reference Halldorsson, Eggertsson, Moore, Hauswedell, Eiriksson and Ulfarsson78 To obtain the results of WGS studies on bipolar disorder, we queried PubMed with the search string ‘whole-genome sequencing and bipolar disorder’.

As described in a 2014 publication, Fiorentino et al sequenced the whole genome of 99 patients with bipolar disorder. After filtering of the detected variants, ten SNPs remained for CACNA1C and three SNPs for ANK3. Then, the identified filtered SNPs were genotyped in 1510 cases with bipolar disorder and 1095 controls. The two variants ultimately identified in this study as being associated with bipolar disorder were rs79398153 in intron 3 of CACNA1C (P = 0.015), which is located in an Encyclopedia of DNA Elements (ENCODE)-defined region for H3K4me1, H3K27ac and H3Kme3; and rs139972937 in exon 34 of ANK3 (P = 0.042), which causes a non-conservative amino acid change from asparagine to serine (N2643S). Because these two novel variants are not in linkage disequilibrium with the previous bipolar disorder-associated variants in ANK3 and CACNA1C, and are independent, the authors pointed out that if these variants can alter the expression and function of ANK3 and CACNA1C, they could explain the ‘missing heritability’.Reference Fiorentino, O'Brien, Locke, McQuillin, Jarram and Anjorin79

Also in 2014, Georgi et al published a study that combined the data from WGS of 50 members (23 affected individuals with bipolar disorder type 1 or 2) with high-density SNP-array genotypes and microsatellite genotypes of 388 members of a large Old Order Amish pedigree (a genetic isolate of European ancestry currently residing in North America). WGS detected a total of 11.1 million variants (within the 97% called genome fraction), and approximately 3.79 million SNPs and insertions and deletions in each individual, 20 000 of which were located within exons. The group searched for exonic mis-sense variants that were common in the 23 patients with bipolar disorder and rare variants (MAF < 2%) in 1000 Genomes Project data, the exome variant server database, and a set of 54 HapMap WGS. The authors found none of the resulting 514 damaging/deleterious variants (predicted by both Polyphen-2 and SIFT) were both present in all bipolar disorder samples and absent or rare in the 1000 Genomes Project data. Many of the detected non-synonymous exonic, putative damaging variants are common in European populations (in SNTG2, TTC15, POLN and EVC), and some of them are rare or novel (in LAMB1, MKL2, ZNF732, ZAN and ANKS4B). Also, ANK3, ODZ2, ODZ4 and ITIH3 were identified to have rare and putative damaging variants. Georgi et al concluded that there is no evidence from their study for implication of specific set of risk loci or common pathways for bipolar disorder.Reference Georgi, Craig, Kember, Liu, Lindquist and Nasser80

In 2016, Ross et al described their WGS of three patients with bipolar disorder type 1 from a multiplex pedigree of European ancestry with seven members with bipolar disorder type 1. The authors reported 115 heterozygous rare variants in 113 genes shared by all three patients. Among all of these genes, the authors focused more on CACNA1D (ranked 24th genome-wide under the dominant mode of inheritance). In this gene, one of the detected variants is G-to-C nucleotide transversion, which causes substitution of proline for alanine at position 1751 (A1751P). Co-segregation of this variant with another four people with bipolar disorder type 1 in the pedigree was confirmed by Sanger sequencing. Also, the researchers detected a transition mutation in this gene in one patient that was a conversion of C to T, causing substitution of tryptophan for arginine (R1771W). Because of the role of CACNA1D in calcium signalling, the authors concluded that changes in this sequence may indirectly lead to bipolar disorder.Reference Ross, Gedvilaite, Badner, Erdman, Baird and Matsunami81

Also in 2016, Fiorentino et al published their WGS data on 99 patients with bipolar disorder type 1 in whom they searched for variations in potential miR-708 binding sites by using Targetscan 6.2 to find bipolar disorder-associated variants. They reported four non-reference (GRCh37/hg19) and non-aetiological allelic variants in APOC3 (rs5128), GALNT13 (rs707082), ST6GALNAC4 (rs1043026) and SLC22A23 (rs5873874). APOC3 and SLC22A23 have been reported to be involved in response to antipsychotic treatments.Reference Fiorentino, O'Brien, Sharp, Curtis, Bass and McQuillin82

In their 2017 publication, Bouwkamp et al presented WGS findings in a patient from a family with a high incidence of affective psychosis (bipolar disorder type 1 or schizoaffective disorder, bipolar type). By using WGS, they discovered a breakpoint of a balanced translocation (detected by karyotyping and fluorescence in situ hybridisation) between chromosomes 6 and 15. The breakpoint is located in intron 11 of PNLDC1 on the long arms of chromosome 6 and intron 1 of BCL2L10 on chromosome 15. PNLDC1 encodes a protein containing an RNaseH-like domain and RNAse_CAF1 domain, and BCL2L10 encodes an intracellular membrane-associated BCL2 family protein that is localised in mitochondria of brain cells.Reference Bouwkamp, Kievit, Olgiati, Breedveld, Coesmans and Bonifati83

Also in 2017, Steinberg et al reported the results of WGS of one patient with bipolar disorder and six patients with schizophrenia and schizoaffective disorder in an Icelandic family with enriched psychosis burden. c.2377G > T (P = 2.2 × 10−4), which is located in the exon of RBM12 on chromosome 20q11, was found in all of the patients. The protein that results from this non-sense mutation is a truncated version without RNA-recognition motif. By using PRS, the authors found that patients with psychosis with c.2377G > T had higher scores for bipolar disorder than non-psychotic carriers.Reference Steinberg, Gudmundsdottir, Sveinbjornsson, Suvisaari, Paunio and Torniainen-Holm84

Also in 2017, Sharp et al published an imputation analysis on a WGS sample of 99 patients with bipolar affective disorder that detected eight significant bipolar disorder-associated SNPs in the CPG2 region of SYNE1 on chromosome 6q25.2; CPG2 is a brain-specific splice variant of SYNE1.Reference Sharp, Lange, Kandaswamy, Daher, Anjorin and Bass85

In 2019, Szatkiewicz et al described the results of WGS of ten patients with bipolar disorder from a large pedigree in Northern Sweden, but they did not identify any high-impact variants.Reference Szatkiewicz, Crowley, Adolfsson, Åberg, Alaerts and Genovese70

In 2021, Goes et al presented their findings from WGS of 97 trios of Ashkenazi Jewish descent without first-degree family history of bipolar disorder, and reported 6882 de novo variants, including 107 variants within protein-coding genes. Twenty loss-of-function and 77 mis-sense damaging de novo variants were identified by combining the findings on exon-related variations with the findings of a previously published study (exome analysis) on trios. The detected variants were significantly enriched in genes related to postsynaptic density. The phosphoinositides pathway, which is hypothesised to participate in the mechanism of action of lithium, is one of the pathways for the identified variants and involved genes.Reference Goes, Pirooznia, Tehan, Zandi, McGrath and Wolyniec86

In 2020, Nakajima et al published the results of WGS of a proband from a family in which bipolar disorder co-segregated with a Mendelian kidney disorder. WGS detected a damaging mis-sense mutation in NTRK1 on chromosome 1q22 that encodes Tropomyosin-related kinase A (TrkA). This mutation causes a substitution of glutamate to lysine at the 492 residue of TrkA protein (E492 K). TrKA participates in cholinergic neurotransmission, and this mutation might potentially interfere in its function, leading to an increased risk for bipolar disorder.Reference Nakajima, Miranda, Craig, Shekhtman, Kmoch and Bleyer87

Also in 2020, Truvé et al reported on the findings of WGS of six unrelated patients with bipolar disorder and three healthy controls that extracted a list of 105 candidate SNPs for genotyping. After genotyping of these 105 SNPs in 47 unrelated cases and 44 controls and by focusing on the rarest genetic variants, NEK3, ANK3 and TUBB1 were introduced as the genes with the most associated variants. NEK3, which harboured the most associated SNPs in this study, encodes a protein kinase, which plays a role in neuronal morphogenesis and microtubule polarity. TUBB1 encodes beta-1 chain of tubulin as the major constituent of the microtubules. Normal microtubules play roles in axon structure and transport, and respond to cellular and environmental stress; the mutant and unregulated microtubules cannot be effective players in stressful conditions, and may result in the triggering of mood episodes in patients with bipolar disorder.Reference Truvé, Parris, Vizlin-Hodzic, Salmela, Berger and Ågren20

Finally, in 2020, Sul et al published high-coverage WGS of 449 individuals from 26 Colombian and Costa Rican determined pedigrees for bipolar disorder type 1, to detect associated rare and common variants, but they did not identified rare variants co-segregating in these pedigrees.Reference Sul, Service, Huang, Ramensky, Hwang and Teshiba88

Like WES, the majority of sample sizes in WGS studies are also small (<100), and this, coupled with the expenses, might be a disadvantage of such investigations. In the WGS researches in our survey, some rare and very rare novel variants in different genes have been reported. These variants are more linked with or play roles in the phosphoinositides pathway, calcium signalling, cholinergic neurotransmission, mitochondrial-related events, response to antipsychotic treatments, neuronal morphogenesis and microtubule polarity.Reference Truvé, Parris, Vizlin-Hodzic, Salmela, Berger and Ågren20,Reference Ross, Gedvilaite, Badner, Erdman, Baird and Matsunami81Reference Bouwkamp, Kievit, Olgiati, Breedveld, Coesmans and Bonifati83,Reference Goes, Pirooznia, Tehan, Zandi, McGrath and Wolyniec86,Reference Nakajima, Miranda, Craig, Shekhtman, Kmoch and Bleyer87 Furthermore, several WGS studies found no high-impact rare variants or revealed no evidence of implication of specific set of risk loci or common pathways that may be used to explain the ‘missing heritability’ of bipolar disorder.Reference Szatkiewicz, Crowley, Adolfsson, Åberg, Alaerts and Genovese70,Reference Georgi, Craig, Kember, Liu, Lindquist and Nasser80,Reference Sul, Service, Huang, Ramensky, Hwang and Teshiba88

MRI neuroimaging

MRI is a widely used tool for studying human brain structure and function, with the goal of establishing links, or endophenotypes, between behavioural symptoms in mental disorders and underlying pathophysiology and genomic risk. Over the past several decades, researchers have found many associations between MRI-derived brain markers and bipolar disorder, with a growing body of evidence showing that bipolar disorder is associated with alterations in the neuroanatomical structures of emotion and reward processing.Reference Phillips and Swartz89

MRI is a versatile tool that is capable of measuring different features of brain structure and function. Studies of grey matter have reported lower volumes in subcortical structures, such as the thalamus, amygdala and hippocampus,Reference Hajek, Kopecek, Kozeny, Gunde, Alda and Höschl90,Reference Rimol, Hartberg, Nesvåg, Fennema-Notestine, Hagler and Pung91 and abnormalities in temporal, frontal and insular cortices.Reference Hajek, Kopecek, Höschl and Alda92Reference Hanford, Nazarov, Hall and Sassi94 Studies with specialised diffusion-weighted MRI sequences, which are used to quantify white matter integrity, have found disrupted widespread alterations in bipolar disorder, including in fronto-limbic connections.Reference Phillips and Swartz89 Furthermore, functional MRI, which takes advantage of the magnetic properties of oxygenated/deoxygenated blood flow to infer neural activity, has shown alterations in frontal, temporal and striatal networks that regulate emotion and reward regulation in bipolar disorder.Reference Phillips and Swartz89 However, variable and sometimes conflicting results are not uncommon across neuroimaging studies of bipolar disorder. MRI studies can be expensive to perform, and many include <100 participants. In addition, patient heterogeneity (e.g. age at onset, duration/severity of illness and treatment regimen), coupled with the relatively subtle effect of bipolar disorder on MRI-derived brain measures, represents a significant challenge to improving the replication and reproducibility of neuroimaging findings in bipolar disorder.

One effort to improve the replication, reproducibility and generalisability of neuroimaging makers across bipolar disorder (and many other brain disorders) is the Enhancing Neuro Imaging Genetics through Meta Analysis Consortium (ENIGMA). Founded in 2009 to support GWASs on MRI-derived brain measures, ENIGMA now consists of >2000 scientists who collaborate across 50 working groups to study a range of brain illnesses and genetic risk factors by implementing standardising processing and analysis methods for large-scale, multisite neuroimaging studies (http://enigma.ini.usc.edu/).Reference Thompson, Jahanshad, Ching, Salminen, Thomopoulos and Bright95

The ENIGMA Bipolar Disorder Working Group (ENIGMA-BD; http://enigma.ini.usc.edu/ongoing/enigma-bipolar-working-group) is a growing collaboration of 150 investigators across 55 international research institutions who are working to pool data and resources to enable the largest neuroimaging studies of bipolar disorder ever conducted to be performed.Reference Ching, Hibar, Gurholt, Nunes, Thomopoulos and Abé28 By applying standardised processing and quality control protocols to existing, independently collected MRI study samples from around the world, ENIGMA-BD aims to build more ecologically valid samples and revive old data-sets to identify new, more generalisable bipolar disorder biomarkers. The standardisation of brain measures across large, multisite MRI samples boosts the power to detect subtle bipolar disorder-specific brain alterations and makes transdiagnostic studies possible across the ENIGMA psychiatric working group samples (e.g. major depression, schizophrenia and obsessive–compulsive disorder). ENIGMA-BD has published the largest studies of cortical and subcortical brain structure,Reference Hibar, Westlye, van Erp, Rasmussen, Leonardo and Faskowitz96,Reference Hibar, Westlye, Doan, Jahanshad, Cheung and Ching97 white matter integrity,Reference Favre, Pauling, Stout, Hozer, Sarrazin and Abé98 hippocampal subfields,Reference Haukvik, Gurholt, Nerland, Elvsåshagen, Akudjedu and Alda99 bipolar disorder familial riskReference de Zwarte, Brouwer, Agartz, Alda, Aleman and Alpert100,Reference de Zwarte, Brouwer, Agartz, Alda, Alonso-Lana and Bearden101 and machine learning for bipolar disorder classification.Reference Nunes, Schnack, Ching, Agartz, Akudjedu and Alda102

The ENIGMA-BD studies show a replicable pattern of lower cortical thickness, altered white matter integrity and smaller subcortical volumes in bipolar disorder. Common medications such as lithium show normalising associations with brain structure, whereas anticonvulsants appear to show the opposite effect and, in some cases, are associated with thinner or smaller brain structures. Importantly, and in line with prior reports, bipolar disorder appears to be associated with small-to-moderate effect sizes on MRI-derived brain markers.Reference Ching, Hibar, Gurholt, Nunes, Thomopoulos and Abé28

Recent work has linked ENIGMA-standardised brain MRI phenotypes to underlying neurobiological mechanisms and genetic factors. One study showed that case–control brain differences across ENIGMA psychiatric working groups (including ENIGMA-BD) partially mirrored known genetic correlations between disorders.Reference Radonjić, Hess, Rovira, Andreassen, Buitelaar and Ching103 Another study showed that a convergent pattern of underlying cell-specific gene expression could be used to partially explain patterns of common cortical thickness alterations across psychiatric illnesses.Reference Patel, Parker, Shin, Howard, French and Thomopoulos104 ENIGMA-BD and the PGC-BD are working together to study how PRS derived from large-scale Psychiatric Genomics Consortium GWASs modulate brain structure and function in bipolar disorder. Finally, ENIGMA GWASs are mapping genetic correlations between variants that modulate brain structure and those that modulate psychiatric and cognitive traits, and results show that MRI-derived brain measures represent an endophenotype on the causal pathway between the genome and cognition.Reference Grasby, Jahanshad, Painter, Colodro-Conde, Bralten and Hibar105

Replicated gene candidates

Among the various GWASs and WES and WGS studies that were performed to understand the genetic architecture of bipolar disorder, five genes – ANK3, CACNA1C, SYNE1, ODZ4 and TRANK1 – have been remarkably replicated in a significant number of these studies in different populations (Table 1), and can most likely be considered as reliable bipolar disorder-related gene candidates.

Table 1 Replicated gene candidates for bipolar disorder identified through various genomic approaches

GWAS, genome-wide association study; WES, whole-exome sequencing; WGS, whole-genome sequencing.

a. Primary GWAS.

b. Combined analysis.

One of the most important identified genes is ANK3, which belongs to the ankyrin repeat domain containing (ANKRD) gene group. Ankyrin 3, or ankyrin G, is a protein-coding gene located on chromosome 10q21.2 that encodes ankyrin G protein. Results from the GTEx data-set (www.gtexportal.org) indicate that, in the brain, ankyrin G protein is expressed more in the cerebellar hemisphere and cerebellum, is positioned mainly at the nodes of Ranvier and the axon initial segment, and plays roles in stabilising sodium channels and potential propagation. Some ANK3 risk variants have major effects on sustained attention and cognitive function, and polymorphisms in this gene were reported to be linked to an increased risk of mental illnesses, including bipolar disorder.Reference Iqbal, Vandeweyer, van der Voet, Waryah, Zahoor and Besseling106 Gene ontology annotations (www.genecards.org) related to this gene include ‘structural constituent of cytoskeleton’ and ‘protein binding, bridging’.Reference Stelzer, Rosen, Plaschkes, Zimmerman, Twik and Fishilevich107

Another outstanding detected gene is CACNA1C, which belongs to the calcium voltage-gated channel alpha-1 subunit gene group. CACNA1C is located on chromosome 12p13.33, encodes a protein that has an important role in regulating calcium influx in cells and is essential for normal brain development and plasticity. Gene ontology annotations related to this gene, which is a well-known candidate risk gene for a variety of neuropsychiatric disorders, including bipolar disorder, include ‘enzyme binding’ and ‘ion channel activity’.Reference Stelzer, Rosen, Plaschkes, Zimmerman, Twik and Fishilevich107,Reference Kabir, Martínez-Rivera and Rajadhyaksha108

SYNE1 is another replicated gene in bipolar disorder genetic research and belongs to the spectrin repeat containing nuclear envelope family gene group. The GTEx data-set indicates that, in the brain, SYNE1, which is located on chromosome 6q25.2, is expressed more in the cerebellar hemisphere and cerebellum. Its related gene ontology annotation is ‘nucleotide binding’.Reference Stelzer, Rosen, Plaschkes, Zimmerman, Twik and Fishilevich107 Human SYNE1 has 145 exons and encodes multiple proteins, such as CPG2, a brain-specific protein found mainly in excitatory postsynaptic regions, where it influences synaptic plasticity and function.Reference Li, Yang, Luo, Zhang, Song and Li109 A significant decrease in the expression level of this gene in the post-mortem brains of patients with bipolar disorder has been reported.Reference Rathje, Waxman, Benoit, Tammineni, Leu and Loebrich110

ODZ4 (TENM4) is another important identified gene related to bipolar disorder and belongs to the tenascin family (teneurin subfamily). ODZ4, which is located on chromosome 11q14.1, encodes a transmembrane protein that is expressed predominantly in neurons, and is involved in neural development and regulating the establishment of proper connectivity within the nervous system.Reference Hor, Francescatto, Bartesaghi, Ortega-Cubero, Kousi and Lorenzo-Betancor111 According to the GTEx data-set, in the brain it is expressed more in the frontal cortex, nucleus accumbens, cortex and hypothalamus; its related gene ontology annotation is ‘protein homodimerization activity’.Reference Stelzer, Rosen, Plaschkes, Zimmerman, Twik and Fishilevich107

TRANK1 (LBA1), a replicated gene in GWASs on bipolar disorder, is located on chromosome 3p22.2. According to the GTEx data-set, it is more expressed in the cerebellum and cerebellar hemisphere. Valproic acid, a mood stabiliser, was found to have a significant effect on the expression of TRANK1, a finding that introduced it as a potential target for bipolar disorder treatment. Gene ontology annotations related to TRANK1 include ‘hydrolase activity’. Some studies reported that TRANK1 dysregulation has the potential to disrupt the expression of genes involved in neuronal development and differentiation, and in synaptic plasticity.Reference Chang, Cai, Yang, Xiao and Li112

Future research perspective

In the previous decade, a large number of genetic studies on patients with bipolar disorder of various diverse ancestries have been conducted around the world, and the rate at which new discoveries are being made is rapidly growing. Most of the GWASs of bipolar disorder are still primarily in European ancestry samples, and we need to strive for more diverse cohorts to improve our generalisability in non-European cohorts. More than 78% of the reported GWAS participants are European, indicating a dearth of internationally representative samples. As a result, most PRS perform significantly worse in other groups, particularly in people of African heritage. To fully realise the global potential of genetics research and precision medicine, it is becoming more vital to invest in policies and processes that promote the involvement of a wide range of study participants. The use of cross-ancestry meta-analysis findings and sample diversity helps us to get a better knowledge of genetic architecture and the relevance of genetic research to all populations, as well as improving overall prediction.Reference Peterson, Kuchenbaecker, Walters, Chen, Popejoy and Periyasamy113 Indeed, technological advancements coupled with consortium efforts that combine data and resources from many research centres have led to the development of more effective analytical methodologies for prioritising major phenotype-associated variants, and investigating new molecular pathways implicated in this complex disorder. On the other hand, defining better strategies for considering molecular and environmental bases through gene×environment interactions could lead to better understanding of brain health and disorders, in particular psychiatric disorders.

Increasing the sample size of GWASs over the past decade has helped to shed more light on the genetics of bipolar disorder. However, because of the high level of phenotypic and genotypic heterogeneity of this disorder, even the most recent GWAS, which was the largest one to date and included approximately 42 000 bipolar disorder cases and identified 64 associated genomic loci, found fewer loci with genome-wide significance than a similar study on schizophrenia, and still the proportion of phenotypic variance explained by these discovered variants is low (approximately 4.7%); this result shows the need for more studies with large sample sizes able to obtain a better comprehensive picture of the genetic architecture of bipolar disorder.Reference Mullins, Forstner, O'Connell, Coombes, Coleman and Qiao17 Likewise, well-powered GWASs in bipolar disorder can improve bipolar disorder PRS as a reliable genetic risk-predictor tool for preventive and prognostic approaches through providing well-replicated results across independent samples.

WES and WGS can contribute more substantially to the decoding of the major genetic foundations of neuropsychiatric disorders, including other complex genetic disorders, through improvement of technology and analytical and quality control methods.

Although neuroimaging research faces some challenges, such as patient heterogeneity and the relatively subtle effect of bipolar disorder on MRI-derived brain measures, integration of neuroimaging data with genomic data in large-scale studies can help to obtain a greater knowledge of the brain regions that mediate the link between genetic risk and behavioural manifestations of bipolar disorder.Reference Ching, Hibar, Gurholt, Nunes, Thomopoulos and Abé28 It will be advantageous to develop more genomic approaches to different complex disorders such as bipolar disorder in the near future, which will hopefully uncover the precise role of the genetic risk loci, especially the regulatory and non-coding elements, in the presentation of these disorders. By developing more advanced DNA analysis technologies and making them more accurate (to avoid ambiguous variant interpretations) and accessible at lower costs, we can achieve high-resolution insight into bipolar disorder genetic risk, and pave the way for further major discoveries that account for the missing heritability of bipolar disorder.Reference Sanders, Neale, Huang, Werling, An and Dong24

To summarise, one of the most comprehensively replicated outcomes of the genomic approach in bipolar disorder is the high heterogeneity and polygenic background of the disorder. Although a large range of diverse genetic studies have been performed on bipolar disorder, the precise genetic underpinnings of the disorder are still unknown and need to be further explored. Some gene candidates have been identified more often in large genetic studies on bipolar disorder, indicating that they might be potential risk genes for bipolar disorder. The top five gene candidates discovered more through all investigated GWASs and WES and WGS studies are ANK3, CACNA1C, SYNE1, ODZ4 and TRANK1. In the field of psychiatric genetics, where the environment has strong effects on the form and development of a disorder, it is critical to pay more attention to the issue of gene×environment interactions and sample heterogeneity. Bipolar disorder PRS in European patients explained approximately 4.57% of the phenotypic variances, and there is some shared risk loci between bipolar disorder and schizophrenia and major depressive disorder. Large-scale collaborative neuroimaging studies show a replicable pattern of lower cortical thickness, altered white matter integrity and smaller subcortical volumes in bipolar disorder. Common medications such as lithium show normalising associations with brain structure, whereas anticonvulsants appear to show the opposite effect and, in some cases, are associated with thinner or smaller brain structures. Importantly, and in line with prior reports, bipolar disorder appears to be associated with small-to-moderate effect sizes on MRI-derived brain markers. Replicating the findings on potential predictors in independent, well-defined large cohorts may ultimately lead to the discovery of most reliable biomarkers for this disorder.

Supplementary material

Supplementary material is available online at https://doi.org/10.1192/bjo.2021.1082.

Data availability

Data availability is not applicable to this article as no new data were created or analysed in this review.

Acknowledgements

The authors thank Jacquie Klesing, Board-certified Editor in the Life Sciences, for editing assistance with the manuscript.

Author contributions

M.O.K., S.P. and T.G.S. designed the review. M.O.K., S.P., C.R.K.C., and T.G.S. contributed to writing and revising the manuscript and approved the final version. M.O.K. designed the table and figure.

Funding

Thomas G. Schulze is supported by German Research Foundation (Deutsche Forschungsgemeinschaft; DFG) within the framework of the projects www.kfo241.de and www.PsyCourse.de (Grant Numbers SCHU 1603/4-1, 5-1, 7-1; FA241/16-1). He is further supported by the Dr Lisa Oehler Foundation (Kassel, Germany).

Declaration of interest

T.G.S. is a member of the BJPsych Editorial Board and did not take part in the review or decision-making process for this paper. All other authors report no conflicts of interest.

References

Vieta, E, Berk, M, Schulze, TG, Carvalho, AF, Suppes, T, Calabrese, JR, et al. Bipolar disorders. Nat Rev Dis Primers 2018; 4: 18008.CrossRefGoogle Scholar
Leboyer, M, Kupfer, DJ. Bipolar disorder: new perspectives in health care and prevention. J Clin Psychiatry 2010; 71(12): 1689–95.CrossRefGoogle ScholarPubMed
Jain, R. Managing bipolar disorder from urgent situations to maintenance therapy. J Clin Psychiatry 2007; 9(5): 367–80.Google Scholar
Amare, AT, Schubert, KO, Hou, L, Clark, SR, Papiol, S, Cearns, M, et al. Association of polygenic score for major depression with response to lithium in patients with bipolar disorder. Mol Psychiatry 2021; 26(6): 2457–70.CrossRefGoogle ScholarPubMed
Rees, E, Owen, MJ. Translating insights from neuropsychiatric genetics and genomics for precision psychiatry. Genome Med 2020; 12: 43.CrossRefGoogle ScholarPubMed
Ludwig, B, Dwivedi, Y. Dissecting bipolar disorder complexity through epigenomic approach. Mol Psychiatry 2016; 21(11): 1490–8.CrossRefGoogle ScholarPubMed
Tabor, HK, Risch, NJ, Myers, RM. Candidate-gene approaches for studying complex genetic traits: practical considerations. Nat Rev Genet 2002; 3(5): 391–7.CrossRefGoogle ScholarPubMed
Tam, V, Patel, N, Turcotte, M, Bossé, Y, Paré, G, Meyre, D. Benefits and limitations of genome-wide association studies. Nat Rev Genet 2019; 20(8): 467–84.CrossRefGoogle ScholarPubMed
Cichon, S, Mühleisen, TW, Degenhardt, FA, Mattheisen, M, Miró, X, Strohmaier, J, et al. Genome-wide association study identifies genetic variation in neurocan as a susceptibility factor for bipolar disorder. Am J Hum Genet 2011; 88(3): 372–81.CrossRefGoogle ScholarPubMed
Baum, AE, Akula, N, Cabanero, M, Cardona, I, Corona, W, Klemens, B, et al. A genome-wide association study implicates diacylglycerol kinase eta (DGKH) and several other genes in the etiology of bipolar disorder. Mol Psychiatry 2008; 13(2): 197207.CrossRefGoogle ScholarPubMed
Risch, N, Merikangas, K. The future of genetic studies of complex human diseases. Science 1996; 273(5281): 1516–7.CrossRefGoogle ScholarPubMed
Witte, JS. Genome-wide association studies and beyond. Annu Rev Public Health 2010; 31: 920. 4 p following 20.CrossRefGoogle ScholarPubMed
Park, J-H, Wacholder, S, Gail, MH, Peters, U, Jacobs, KB, Chanock, SJ, et al. Estimation of effect size distribution from genome-wide association studies and implications for future discoveries. Nat Genet 2010; 42(7): 570–5.CrossRefGoogle ScholarPubMed
Chen, DT, Jiang, X, Akula, N, Shugart, YY, Wendland, JR, Steele, CJM, et al. Genome-wide association study meta-analysis of European and Asian-ancestry samples identifies three novel loci associated with bipolar disorder. Mol Psychiatry 2013; 18(2): 195205.CrossRefGoogle ScholarPubMed
Ozaki, K, Ohnishi, Y, Iida, A, Sekine, A, Yamada, R, Tsunoda, T, et al. Functional SNPs in the lymphotoxin-alpha gene that are associated with susceptibility to myocardial infarction. Nat Genet 2002; 32(4): 650–4.CrossRefGoogle ScholarPubMed
Gordovez, FJA, McMahon, FJ. The genetics of bipolar disorder. Mol Psychiatry 2020; 25(3): 544–59.CrossRefGoogle ScholarPubMed
Mullins, N, Forstner, AJ, O'Connell, KS, Coombes, B, Coleman, JRI, Qiao, Z, et al. Genome-wide association study of more than 40,000 bipolar disorder cases provides new insights into the underlying biology. Nat Genet 2021; 53(6): 817–29.CrossRefGoogle ScholarPubMed
Marchini, J, Howie, B. Genotype imputation for genome-wide association studies. Nat Rev Genet 2010; 11(7): 499511.CrossRefGoogle ScholarPubMed
Porcu, E, Sanna, S, Fuchsberger, C, Fritsche, LG. Genotype imputation in genome-wide association studies. Curr Protoc Hum Genet 2013; Chapter 1(suppl 78): Unit 1.25.1–1.25.14. (2013)CrossRefGoogle ScholarPubMed
Truvé, K, Parris, TZ, Vizlin-Hodzic, D, Salmela, S, Berger, E, Ågren, H, et al. Identification of candidate genetic variants and altered protein expression in neural stem and mature neural cells support altered microtubule function to be an essential component in bipolar disorder. Transl Psychiatry 2020; 10: 390.CrossRefGoogle ScholarPubMed
Kato, T. Whole genome/exome sequencing in mood and psychotic disorders. Psychiatry Clin Neurosci 2015; 69(2): 6576.CrossRefGoogle ScholarPubMed
Monson, ET, Pirooznia, M, Parla, J, Kramer, M, Goes, FS, Gaine, ME, et al. Assessment of whole-exome sequence data in attempted suicide within a bipolar disorder cohort. Mol Neuropsychiatry 2017; 3(1): 111.CrossRefGoogle ScholarPubMed
Zhang, T, Hou, L, Chen, DT, McMahon, FJ, Wang, J-C, Rice, JP. Exome sequencing of a large family identifies potential candidate genes contributing risk to bipolar disorder. Gene 2018; 645: 119–23.CrossRefGoogle ScholarPubMed
Sanders, SJ, Neale, BM, Huang, H, Werling, DM, An, J-Y, Dong, S, et al. Whole genome sequencing in psychiatric disorders: the WGSPD Consortium. Nat Neurosci 2017; 20(12): 1661–8.CrossRefGoogle ScholarPubMed
Yi, N, Xu, S, Lou, X-Y, Mallick, H. Multiple comparisons in genetic association studies: a hierarchical modeling approach. Stat Appl Genet Mol Biol 2014; 13(1): 3548.CrossRefGoogle ScholarPubMed
Hong, EP, Park, JW. Sample size and statistical power calculation in genetic association studies. Genomics Inform 2012; 10(2): 117–22.CrossRefGoogle ScholarPubMed
Eeltink, E, van der Horst, MZ, Zinkstok, JR, Aalfs, CM, Luykx, JJ. Polygenic risk scores for genetic counseling in psychiatry: lessons learned from other fields of medicine. Neurosci Biobehav Rev 2021; 121: 119–27.CrossRefGoogle ScholarPubMed
Ching, CRK, Hibar, DP, Gurholt, TP, Nunes, A, Thomopoulos, SI, Abé, C, et al. What we learn about bipolar disorder from large-scale neuroimaging: findings and future directions from the ENIGMA bipolar disorder working group. Hum Brain Mapp 2022; 43(1): 56–82.CrossRefGoogle ScholarPubMed
Uffelmann, E, Huang, QQ, Munung, NS, de Vries, J, Okada, Y, Martin, AR, et al. Genome-wide association studies. Nat Rev Methods Primers 2021; 1: 59.CrossRefGoogle Scholar
Ku, C-S, Naidoo, N, Pawitan, Y. Revisiting Mendelian disorders through exome sequencing. Hum Genet 2011; 129(4): 351–70.CrossRefGoogle ScholarPubMed
Ng, PC, Kirkness, EF. Whole genome sequencing. Methods Mol Biol 2010; 628: 215–26.CrossRefGoogle ScholarPubMed
Sullivan, PF. The Psychiatric GWAS Consortium: big science comes to psychiatry. Neuron 2010; 68(2): 182–6.CrossRefGoogle ScholarPubMed
The Wellcome Trust Case Control Consortium. Genome-wide association study of 14,000 cases of seven common diseases and 3,000 shared controls. Nature 2007; 447(7145): 661–78.CrossRefGoogle Scholar
Sklar, P, Smoller, JW, Fan, J, Ferreira, MAR, Perlis, RH, Chambert, K, et al. Whole-genome association study of bipolar disorder. Mol Psychiatry 2008; 13(6): 558–69.CrossRefGoogle ScholarPubMed
Ferreira, MAR, O'Donovan, MC, Meng, YA, Jones, IR, Ruderfer, DM, Jones, L, et al. Collaborative genome-wide association analysis supports a role for ANK3 and CACNA1C in bipolar disorder. Nat Genet 2008; 40(9): 1056–8.CrossRefGoogle ScholarPubMed
Bauleo, A, Montesanto, A, Pace, V, Brando, R, De Stefano, L, Puntorieri, D, et al. Rare copy number variants in ASTN2 gene in patients with neurodevelopmental disorders. Psychiatr Genet 2021; 31(6): 239–45.CrossRefGoogle ScholarPubMed
Jiménez-Jiménez, FJ, Esguevillas, G, Alonso-Navarro, H, Zurdo, M, Turpín-Fenoll, L, Millán-Pascual, J, et al. Gamma-aminobutyric acid (GABA) receptors genes polymorphisms and risk for restless legs syndrome. Pharmacogenomics J 2018; 18(4): 565–77.CrossRefGoogle ScholarPubMed
Wang, K-S, Liu, X-F, Aragam, N. A genome-wide meta-analysis identifies novel loci associated with schizophrenia and bipolar disorder. Schizophr Res 2010; 124(1–3): 192–9.CrossRefGoogle ScholarPubMed
Kerner, B, Lambert, CG, Muthén, BO. Genome-wide association study in bipolar patients stratified by co-morbidity. PLoS One 2011; 6(12): e28477.CrossRefGoogle ScholarPubMed
Psychiatric GWAS Consortium Bipolar Disorder Working Group. Large-scale genome-wide association analysis of bipolar disorder identifies a new susceptibility locus near ODZ4. Nat Genet 2011; 43(10): 977–83.CrossRefGoogle Scholar
Zheng, G, Freidlin, B, Li, Z, Gastwirth, JL. Genomic control for association studies under various genetic models. Biometrics 2005; 61(1): 186–92.CrossRefGoogle ScholarPubMed
Green, EK, Grozeva, D, Forty, L, Gordon-Smith, K, Russell, E, Farmer, A, et al. Association at SYNE1 in both bipolar disorder and recurrent major depression. Mol Psychiatry 2013; 18(5): 614–7.CrossRefGoogle ScholarPubMed
Green, EK, Hamshere, M, Forty, L, Gordon-Smith, K, Fraser, C, Russell, E, et al. Replication of bipolar disorder susceptibility alleles and identification of two novel genome-wide significant associations in a new bipolar disorder case-control sample. Mol Psychiatry 2013; 18(12): 1302–7.CrossRefGoogle Scholar
Mühleisen, TW, Leber, M, Schulze, TG, Strohmaier, J, Degenhardt, F, Treutlein, J, et al. Genome-wide association study reveals two new risk loci for bipolar disorder. Nat Commun 2014; 5: 3339.CrossRefGoogle ScholarPubMed
Song, J, Bergen, SE, Di Florio, A, Karlsson, R, Charney, A, Ruderfer, DM, et al. Genome-wide association study identifies SESTD1 as a novel risk gene for lithium-responsive bipolar disorder. Mol Psychiatry 2016; 21(9): 1290–7.CrossRefGoogle ScholarPubMed
Song, J, Bergen, SE, Di Florio, A, Karlsson, R, Charney, A, Ruderfer, DM, et al. Genome-wide association study identifies SESTD1 as a novel risk gene for lithium-responsive bipolar disorder. Mol Psychiatry 2017; 22(8): 1223.CrossRefGoogle ScholarPubMed
Yang, J, Lee, SH, Goddard, ME, Visscher, PM. GCTA: a tool for genome-wide complex trait analysis. Am J Hum Genet 2011; 88(1): 7682.CrossRefGoogle ScholarPubMed
Hou, L, Bergen, SE, Akula, N, Song, J, Hultman, CM, Landén, M, et al. Genome-wide association study of 40,000 individuals identifies two novel loci associated with bipolar disorder. Hum Mol Genet 2016; 25(15): 3383–94.CrossRefGoogle ScholarPubMed
Charney, AW, Ruderfer, DM, Stahl, EA, Moran, JL, Chambert, K, Belliveau, RA, et al. Evidence for genetic heterogeneity between clinical subtypes of bipolar disorder. Transl Psychiatry 2017; 7: e993.CrossRefGoogle ScholarPubMed
Ikeda, M, Takahashi, A, Kamatani, Y, Okahisa, Y, Kunugi, H, Mori, N, et al. A genome-wide association study identifies two novel susceptibility loci and trans population polygenicity associated with bipolar disorder. Mol Psychiatry 2018; 23(3): 639–47.CrossRefGoogle ScholarPubMed
Stahl, EA, Breen, G, Forstner, AJ, McQuillin, A, Ripke, S, Trubetskoy, V, et al. Genome-wide association study identifies 30 loci associated with bipolar disorder. Nat Genet 2019; 51(5): 793803.CrossRefGoogle ScholarPubMed
Purcell, SM, Wray, NR, Stone, JL, Visscher, PM, O'Donovan, MC, Sullivan, PF, et al. Common polygenic variation contributes to risk of schizophrenia and bipolar disorder. Nature 2009; 460(7256): 748–52.Google ScholarPubMed
Andlauer, TFM, Guzman-Parra, J, Streit, F, Strohmaier, J, González, MJ, Gil Flores, S, et al. Bipolar multiplex families have an increased burden of common risk variants for psychiatric disorders. Mol Psychiatry 2021; 26(4): 1286–98.CrossRefGoogle ScholarPubMed
Guzman-Parra, J, Streit, F, Forstner, AJ, Strohmaier, J, González, MJ, Gil Flores, S, et al. Clinical and genetic differences between bipolar disorder type 1 and 2 in multiplex families. Transl Psychiatry 2021; 11: 31.CrossRefGoogle ScholarPubMed
Mistry, S, Harrison, JR, Smith, DJ, Escott-Price, V, Zammit, S. The use of polygenic risk scores to identify phenotypes associated with genetic risk of bipolar disorder and depression: a systematic review. J Affect Disord 2018; 234: 148–55.CrossRefGoogle ScholarPubMed
Hou, L, Heilbronner, U, Degenhardt, F, Adli, M, Akiyama, K, Akula, N, et al. Genetic variants associated with response to lithium treatment in bipolar disorder: a genome-wide association study. Lancet 2016; 387(10023): 1085–93.CrossRefGoogle ScholarPubMed
Amare, AT, Schubert, KO, Hou, L, Clark, SR, Papiol, S, Heilbronner, U, et al. Association of polygenic score for schizophrenia and HLA antigen and inflammation genes with response to lithium in bipolar affective disorder: a genome-wide association study. JAMA Psychiatry 2018; 75(1): 6574.Google ScholarPubMed
Toma, C, Shaw, AD, Allcock, RJN, Heath, A, Pierce, KD, Mitchell, PB, et al. An examination of multiple classes of rare variants in extended families with bipolar disorder. Transl Psychiatry 2018; 8: 65.CrossRefGoogle ScholarPubMed
Biesecker, LG, Shianna, KV, Mullikin, JC. Exome sequencing: the expert view. Genome Biol 2011; 12(9): 128.CrossRefGoogle ScholarPubMed
Chen, Y-C, Carter, H, Parla, J, Kramer, M, Goes, FS, Pirooznia, M, et al. A hybrid likelihood model for sequence-based disease association studies. PLoS Genet 2013; 9(1): e1003224.CrossRefGoogle ScholarPubMed
Kataoka, M, Matoba, N, Sawada, T, Kazuno, A-A, Ishiwata, M, Fujii, K, et al. Exome sequencing for bipolar disorder points to roles of de novo loss-of-function and protein-altering mutations. Mol Psychiatry 2016; 21(7): 885–93.CrossRefGoogle ScholarPubMed
Lescai, F, Als, TD, Li, Q, Nyegaard, M, Andorsdottir, G, Biskopstø, M, et al. Whole-exome sequencing of individuals from an isolated population implicates rare risk variants in bipolar disorder. Transl Psychiatry 2017; 7: e1034.CrossRefGoogle ScholarPubMed
Cruceanu, C, Schmouth, J-F, Torres-Platas, SG, Lopez, JP, Ambalavanan, A, Darcq, E, et al. Rare susceptibility variants for bipolar disorder suggest a role for G protein-coupled receptors. Mol Psychiatry 2018; 23(10): 2050–6.CrossRefGoogle ScholarPubMed
Salvoro, C, Bortoluzzi, S, Coppe, A, Valle, G, Feltrin, E, Mostacciuolo, ML, et al. Rare risk variants identification by identity-by-descent mapping and whole-exome sequencing implicates neuronal development pathways in schizophrenia and bipolar disorder. Mol Neurobiol 2018; 55(9): 7366–76.CrossRefGoogle ScholarPubMed
Ganna, A, Satterstrom, FK, Zekavat, SM, Das, I, Kurki, MI, Churchhouse, C, et al. Quantifying the impact of rare and ultra-rare coding variation across the phenotypic spectrum. Am J Hum Genet 2018; 102(6): 1204–11.CrossRefGoogle ScholarPubMed
Maaser, A, Forstner, AJ, Strohmaier, J, Hecker, J, Ludwig, KU, Sivalingam, S, et al. Exome sequencing in large, multiplex bipolar disorder families from Cuba. PLoS One 2018; 13(10): e0205895.CrossRefGoogle ScholarPubMed
Husson, T, Duboc, J-B, Quenez, O, Charbonnier, C, Rotharmel, M, Cuenca, M, et al. Identification of potential genetic risk factors for bipolar disorder by whole-exome sequencing. Transl Psychiatry 2018; 8: 268.CrossRefGoogle ScholarPubMed
Han, M-R, Han, K-M, Kim, A, Kang, W, Kang, Y, Kang, J, et al. Whole-exome sequencing identifies variants associated with structural MRI markers in patients with bipolar disorders. J Affect Disord 2019; 249: 159–68.CrossRefGoogle ScholarPubMed
Ganesh, S, Ahmed P, H, Nadella, RK, More, RP, Seshadri, M, Viswanath, B, et al. Exome sequencing in families with severe mental illness identifies novel and rare variants in genes implicated in Mendelian neuropsychiatric syndromes. Psychiatry Clin Neurosci 2019; 73(1): 11–9.CrossRefGoogle ScholarPubMed
Szatkiewicz, J, Crowley, JJ, Adolfsson, AN, Åberg, KA, Alaerts, M, Genovese, G, et al. The genomics of major psychiatric disorders in a large pedigree from Northern Sweden. Transl Psychiatry 2019; 9: 60.CrossRefGoogle Scholar
Anjanappa, RM, Nayak, S, Moily, NS, Manduva, V, Nadella, RK, Viswanath, B, et al. A linkage and exome study implicates rare variants of KANK4 and CAP2 in bipolar disorder in a multiplex family. Bipolar Disord 2020; 22(1): 70–8.CrossRefGoogle Scholar
Forstner, AJ, Fischer, SB, Schenk, LM, Strohmaier, J, Maaser-Hecker, A, Reinbold, CS, et al. Whole-exome sequencing of 81 individuals from 27 multiply affected bipolar disorder families. Transl Psychiatry 2020; 10: 57.CrossRefGoogle ScholarPubMed
Jacobs, A, Hagin, M, Shugol, M, Shomron, N, Pillar, N, Fananas, L, et al. The black sheep of the family- whole-exome sequencing in family of lithium response discordant bipolar monozygotic twins. Eur Neuropsychopharmacol 2020; 34: 19-27.CrossRefGoogle ScholarPubMed
Courtois, E, Schmid, M, Wajsbrot, O, Barau, C, Le Corvoisier, P, Aouizerate, B, et al. Contribution of common and rare damaging variants in familial forms of bipolar disorder and phenotypic outcome. Transl Psychiatry 2020; 10: 124.CrossRefGoogle ScholarPubMed
Engelbrecht, H-R, Dalvie, S, Agenbag, G, Stein, DJ, Ramesar, RS. Whole-exome sequencing in an Afrikaner family with bipolar disorder. J Affect Disord 2020; 276: 6975.CrossRefGoogle Scholar
Umehara, H, Nakamura, M, Nagai, M, Kato, Y, Ueno, S-I, Sano, A. Positional cloning and comprehensive mutation analysis of a Japanese family with lithium-responsive bipolar disorder identifies a novel DOCK5 mutation. J Hum Genet 2021; 66(3): 243–9.CrossRefGoogle ScholarPubMed
Toma, C, Shaw, AD, Heath, A, Pierce, KD, Mitchell, PB, Schofield, PR, et al. A linkage and exome study of multiplex families with bipolar disorder implicates rare coding variants of ANK3 and additional rare alleles at 10q11-q21. J Psychiatry Neurosci 2021; 46(2): E247–57.CrossRefGoogle ScholarPubMed
Halldorsson, BV, Eggertsson, HP, Moore, KHS, Hauswedell, H, Eiriksson, O, Ulfarsson, MO, et al. The sequences of 150,119 genomes in the UK Biobank. BioRxiv [Preprint] 2021. Available from: https://www.biorxiv.org/content/10.1101/2021.11.16.468246v1 [cited 20 Nov 2021].Google Scholar
Fiorentino, A, O'Brien, NL, Locke, DP, McQuillin, A, Jarram, A, Anjorin, A, et al. Analysis of ANK3 and CACNA1C variants identified in bipolar disorder whole genome sequence data. Bipolar Disord 2014; 16(6): 583–91.CrossRefGoogle ScholarPubMed
Georgi, B, Craig, D, Kember, RL, Liu, W, Lindquist, I, Nasser, S, et al. Genomic view of bipolar disorder revealed by whole genome sequencing in a genetic isolate. PLoS Genet 2014; 10(3): e1004229.CrossRefGoogle Scholar
Ross, J, Gedvilaite, E, Badner, JA, Erdman, C, Baird, L, Matsunami, N, et al. A rare variant in CACNA1D segregates with 7 bipolar I disorder cases in a large pedigree. Mol Neuropsychiatry 2016; 2(3): 145–50.CrossRefGoogle Scholar
Fiorentino, A, O'Brien, NL, Sharp, SI, Curtis, D, Bass, NJ, McQuillin, A. Genetic variation in the miR-708 gene and its binding targets in bipolar disorder. Bipolar Disord 2016; 18(8): 650–6.CrossRefGoogle ScholarPubMed
Bouwkamp, CG, Kievit, AJA, Olgiati, S, Breedveld, GJ, Coesmans, M, Bonifati, V, et al. A balanced translocation disrupting BCL2L10 and PNLDC1 segregates with affective psychosis. Am J Med Genet B Neuropsychiatr Genet 2017; 174(3): 214–9.CrossRefGoogle ScholarPubMed
Steinberg, S, Gudmundsdottir, S, Sveinbjornsson, G, Suvisaari, J, Paunio, T, Torniainen-Holm, M, et al. Truncating mutations in RBM12 are associated with psychosis. Nat Genet 2017; 49(8): 1251–4.CrossRefGoogle ScholarPubMed
Sharp, SI, Lange, J, Kandaswamy, R, Daher, M, Anjorin, A, Bass, NJ, et al. Identification of rare nonsynonymous variants in SYNE1/CPG2 in bipolar affective disorder. Psychiatr Genet 2017; 27(3): 81–8.CrossRefGoogle ScholarPubMed
Goes, FS, Pirooznia, M, Tehan, M, Zandi, PP, McGrath, J, Wolyniec, P, et al. De novo variation in bipolar disorder. Mol Psychiatry 2021; 26: 4127–36.CrossRefGoogle ScholarPubMed
Nakajima, K, Miranda, A, Craig, DW, Shekhtman, T, Kmoch, S, Bleyer, A, et al. Ntrk1 mutation co-segregating with bipolar disorder and inherited kidney disease in a multiplex family causes defects in neuronal growth and depression-like behavior in mice. Transl Psychiatry 2020; 10: 407.CrossRefGoogle Scholar
Sul, JH, Service, SK, Huang, AY, Ramensky, V, Hwang, S-G, Teshiba, TM, et al. Contribution of common and rare variants to bipolar disorder susceptibility in extended pedigrees from population isolates. Transl Psychiatry 2020; 10: 74.CrossRefGoogle ScholarPubMed
Phillips, ML, Swartz, HA. A critical appraisal of neuroimaging studies of bipolar disorder: toward a new conceptualization of underlying neural circuitry and a road map for future research. Am J Psychiatry 2014; 171(8): 829–43.CrossRefGoogle Scholar
Hajek, T, Kopecek, M, Kozeny, J, Gunde, E, Alda, M, Höschl, C. Amygdala volumes in mood disorders–meta-analysis of magnetic resonance volumetry studies. J Affect Disord 2009; 115(3): 395410.CrossRefGoogle ScholarPubMed
Rimol, LM, Hartberg, CB, Nesvåg, R, Fennema-Notestine, C, Hagler, DJJ, Pung, CJ, et al. Cortical thickness and subcortical volumes in schizophrenia and bipolar disorder. Biol Psychiatry 2010; 68(1): 4150.CrossRefGoogle ScholarPubMed
Hajek, T, Kopecek, M, Höschl, C, Alda, M. Smaller hippocampal volumes in patients with bipolar disorder are masked by exposure to lithium: a meta-analysis. J Psychiatry Neurosci 2012; 37(5): 333–43.CrossRefGoogle ScholarPubMed
Rimol, LM, Nesvåg, R, Hagler, DJJ, Bergmann, O, Fennema-Notestine, C, Hartberg, CB, et al. Cortical volume, surface area, and thickness in schizophrenia and bipolar disorder. Biol Psychiatry 2012; 71(6): 552–60.CrossRefGoogle ScholarPubMed
Hanford, LC, Nazarov, A, Hall, GB, Sassi, RB. Cortical thickness in bipolar disorder: a systematic review. Bipolar Disord 2016; 18(1): 418.CrossRefGoogle ScholarPubMed
Thompson, PM, Jahanshad, N, Ching, CRK, Salminen, LE, Thomopoulos, SI, Bright, J, et al. ENIGMA and global neuroscience: a decade of large-scale studies of the brain in health and disease across more than 40 countries. Transl Psychiatry 2020; 10: 100.CrossRefGoogle ScholarPubMed
Hibar, DP, Westlye, LT, van Erp, TGM, Rasmussen, J, Leonardo, CD, Faskowitz, J, et al. Subcortical volumetric abnormalities in bipolar disorder. Mol Psychiatry 2016; 21(12): 1710–6.CrossRefGoogle ScholarPubMed
Hibar, DP, Westlye, LT, Doan, NT, Jahanshad, N, Cheung, JW, Ching, CRK, et al. Cortical abnormalities in bipolar disorder: an MRI analysis of 6503 individuals from the ENIGMA Bipolar Disorder Working Group. Mol Psychiatry 2018; 23(4): 932–42.CrossRefGoogle ScholarPubMed
Favre, P, Pauling, M, Stout, J, Hozer, F, Sarrazin, S, Abé, C, et al. Widespread white matter microstructural abnormalities in bipolar disorder: evidence from mega- and meta-analyses across 3033 individuals. Neuropsychopharmacology 2019; 44(13): 2285–93.CrossRefGoogle ScholarPubMed
Haukvik, UK, Gurholt, TP, Nerland, S, Elvsåshagen, T, Akudjedu, TN, Alda, M, et al. In vivo hippocampal subfield volumes in bipolar disorder-a mega-analysis from The Enhancing Neuro Imaging Genetics through Meta-Analysis Bipolar Disorder Working Group. Hum Brain Mapp 2022; 43(1): 385–98.CrossRefGoogle ScholarPubMed
de Zwarte, SMC, Brouwer, RM, Agartz, I, Alda, M, Aleman, A, Alpert, KI, et al. The association between familial risk and brain abnormalities is disease specific: an ENIGMA-relatives study of schizophrenia and bipolar disorder. Biol Psychiatry 2019; 86(7): 545–56.CrossRefGoogle ScholarPubMed
de Zwarte, SMC, Brouwer, RM, Agartz, I, Alda, M, Alonso-Lana, S, Bearden, CE, et al. Intelligence, educational attainment, and brain structure in those at familial high-risk for schizophrenia or bipolar disorder. Hum Brain Mapp 2022; 43(1): 414–30.CrossRefGoogle ScholarPubMed
Nunes, A, Schnack, HG, Ching, CRK, Agartz, I, Akudjedu, TN, Alda, M, et al. Using structural MRI to identify bipolar disorders - 13 site machine learning study in 3020 individuals from the ENIGMA bipolar disorders working group. Mol Psychiatry 2020; 25(9): 2130–43.CrossRefGoogle ScholarPubMed
Radonjić, NV, Hess, JL, Rovira, P, Andreassen, O, Buitelaar, JK, Ching, CRK, et al. Structural brain imaging studies offer clues about the effects of the shared genetic etiology among neuropsychiatric disorders. Mol Psychiatry 2021; 26(6): 2101–10.CrossRefGoogle ScholarPubMed
Patel, Y, Parker, N, Shin, J, Howard, D, French, L, Thomopoulos, SI, et al. Virtual histology of cortical thickness and shared neurobiology in 6 psychiatric disorders. JAMA Psychiatry 2021; 78(1): 4763.Google ScholarPubMed
Grasby, KL, Jahanshad, N, Painter, JN, Colodro-Conde, L, Bralten, J, Hibar, DP, et al. The genetic architecture of the human cerebral cortex. Science 2020; 367(6484): eaay6690.CrossRefGoogle ScholarPubMed
Iqbal, Z, Vandeweyer, G, van der Voet, M, Waryah, AM, Zahoor, MY, Besseling, JA, et al. Homozygous and heterozygous disruptions of ANK3: at the crossroads of neurodevelopmental and psychiatric disorders. Hum Mol Genet 2013; 22(10): 1960–70.CrossRefGoogle ScholarPubMed
Stelzer, G, Rosen, N, Plaschkes, I, Zimmerman, S, Twik, M, Fishilevich, S, et al. The GeneCards suite: from gene data mining to disease genome sequence analyses. Curr Protoc Bioinformatics 2016; 54: 1.30.1–33.CrossRefGoogle ScholarPubMed
Kabir, ZD, Martínez-Rivera, A, Rajadhyaksha, AM. From gene to behavior: L-type calcium channel mechanisms underlying neuropsychiatric symptoms. Neurotherapeutics 2017; 14(3): 588613.CrossRefGoogle ScholarPubMed
Li, W, Yang, Y, Luo, B, Zhang, Y, Song, X, Li, M, et al. Association of SYNE1 locus with bipolar disorder in Chinese population. Hereditas 2019; 156: 19.CrossRefGoogle ScholarPubMed
Rathje, M, Waxman, H, Benoit, M, Tammineni, P, Leu, C, Loebrich, S, et al. Genetic variants in the bipolar disorder risk locus SYNE1 that affect CPG2 expression and protein function. Mol Psychiatry 2021; 26(2): 508–23.CrossRefGoogle ScholarPubMed
Hor, H, Francescatto, L, Bartesaghi, L, Ortega-Cubero, S, Kousi, M, Lorenzo-Betancor, O, et al. Missense mutations in TENM4, a regulator of axon guidance and central myelination, cause essential tremor. Hum Mol Genet 2015; 24(20): 5677–86.CrossRefGoogle ScholarPubMed
Chang, H, Cai, X, Yang, Z-H, Xiao, X, Li, M. Regulation of TRANK1 by GSK-3 in the brain: unexpected interactions. Mol Psychiatry [Epub ahead of print] 30 Apr 2021. Available from: https://doi.org/10.1038/s41380-021-01120-2.CrossRefGoogle ScholarPubMed
Peterson, RE, Kuchenbaecker, K, Walters, RK, Chen, C-Y, Popejoy, AB, Periyasamy, S, et al. Genome-wide association studies in ancestrally diverse populations: opportunities, methods, pitfalls, and recommendations. Cell 2019; 179(3): 589603.CrossRefGoogle Scholar
Figure 0

Fig. 1 Genome-Wide Association Studies (GWASs). SNP, single nucleotide polymorphism.

Figure 1

Table 1 Replicated gene candidates for bipolar disorder identified through various genomic approaches

Supplementary material: File

Oraki Kohshour et al. supplementary material

Oraki Kohshour et al. supplementary material

Download Oraki Kohshour et al. supplementary material(File)
File 27.1 KB
Submit a response

eLetters

No eLetters have been published for this article.