Parental polymorphism for molecular and morphological markers

In the present study, it was observed that phi 112 marker exhibited dominant behaviour between QPM and non-QPM lines. The phi 112 allele was only observed in normal maize as it is O2O2 and was absent in QPM lines. Therefore, this marker cannot be used in a conversion programme but it is usable in determining the purity of QPM varieties. The markers phi057 and umc1066 exhibited co dominant polymorphism between IML-187, BML6 and DQL-779-2-9, DQL-2029-1. The marker phi057 amplified at 160 bp in IML-187(P₁) and 160 bp in BML-6 (P₂) whereas an allele size of 170 bp was observed in DQL-2029-1 (P₃) and DQL-779-2-9 (P₄) (online Supplementary Table S3 and Fig. S1) and the occurrence of polymorphic alleles at o2 locus clearly distinguishes these lines from one another on the basis of opaque gene. Similar results have been reported earlier by Bantte and Prasanna (Reference Bantte and Prasanna2003) who noted clear and discrete polymorphism at o2 locus. Therefore the use of phi 057 marker in identifying the desired o2 individuals in the F₁ and subsequent backcross progenies is advisable (Shetty et al. (Reference Shetty, Sagare, Surender and Reddy2020)). The polymorphism of 40 background SSR markers for each parent is depicted in the online Supplementary Table S3 and Figs. 2–10. Out of these 25 markers were found to be polymorphic. Kostadinovic et al. (Reference Kostadinovic, Nikolic, Ristic, Bozinovic, Melnik, Micic and Vancetovic2019) used 30 SSR markers for background selection during introgression of favourable alleles in 12 maize inbred lines to determine genetic similarity and percentage of recurrent parent genome. They were able to obtain genetic similarity values ranging from 79 to 99. 48% of progenies had above theoretical values and were self-pollinated for allele fixation. Parental polymorphism on the basis of DUS descriptors/morphological markers was also determined prior to the inception of breeding programme. Phenotypic selection coupled with marker assisted selection results in maximum gain in terms of recurrent parent similarity. The phenotypic trait expression of the parents is described in the online Supplementary Table S1.

Selection of plants from BC₁F₁ to generate BC₂F₁

The F₁ hybrids were crossed with recurrent parents to generate BC₁F₁ (A) and BC₁F₁ (B). And seeds were sown to raise BC₁F₁ plant populations. Initially 50 plant populations from each of the BC₁F₁ (A) and BC₁F₁ (B) seeds were obtained, however seeds of 25 and 28 plants were retained from BC₁F₁(A) and BC₁F₁ (B) respectively. These BC₁F₁s were sown in 4 m row pattern to raise approximately 200 plants each, along with two rows of recurrent parents. However, only 96 plants from BC₁F₁ (A) and 100 plants from BC₁F₁ (B) were genotyped to determine the heterozygosity using phi 057 SSR primer (online Supplemantary Figs. 11 and 12). Significant χ ² values were observed in both the crosses indicating Mendelian test cross ratio of 1:1. The number of heterozygote plants is mentioned in online Supplementary Table S4. However due to poor seed set and phenotypic selection pressure, only 20 and 23 plants from BC₁F₁(A) and BC₁F₁ (B) respectively were backcrossed to generate BC₂F₁ seeds. Magulama and Sales (Reference Magulama and Sales2009) noted polymorphism at o2 locus with phi057 and umc1066 however they applied only phi057 in marker assisted selection for the development of BC populations. Because of the reliability and discrete polymorphism, phi057 SSR marker has also been used in marker assisted backcrossing studies earlier by Manna et al. (Reference Manna, Okello, Imanyhowa, Pixley and Edema2005) and Danson et al. (Reference Danson, Mbogori, Kimani, Lagat, Kuria and Diallo2006). The results of Jompuk et al. (Reference Jompuk, Cheuchart, Jompuk and Apisitwanich2011) were also on the same line as observed in the present investigation since genotyping of o2 locus using phi057 exhibited allele size of 160 and 170 bp in o2 and non-opaque-2 maize lines, respectively. However, Gupta et al. (Reference Gupta, Raman, Agrawal, Mahajan, Hossain and Thirunavukkarasu2013) used umc1066 successfully in foreground selection for o2 allele. The allele size they observed was 460 bp in normal maize line whereas allele of 480 bp was found in QPM donor line using marker umc1066.

Selection of plants from BC₂F₁ to generate BC₂F₂

Total of 200 seeds each from selected BC₂F₁ (A) from BC₂F₁ (B) were sown separately. One row of recurrent parent was sown after every two rows of BC₂F₁ plants to facilitate selection of plants similar to recurrent parents. The plants left in the field after pre-flowering screening were tagged and leaf samples from individual plant were collected and genotyped for o2 locus using phi-057 SSR marker (online Supplementary Figs. 13 and 14). The genotyping at o2 locus helped in identifying plants heterozygous for o2 locus since population in BC₂F₁ consisted of both heterozygous and homozygous plants in 1:1 ratio. Significant χ ² values were observed in both the crosses indicating Mendelian test cross ratio of 1:1. 36 and 44 plants were observed to be heterozygous at o2 locus from BC₂F₁ (A) and BC₂F₁ (B) respectively (online Supplementary Table S5). The heterozygous plants were also genotyped for recurrent parent genome using 25 polymorphic SSR markers. At flowering, plants were again screened for phenotypic traits mentioned in online Supplementary Table S1 (as in the previous generation) similar to recurrent parents and off types were rogued out. The final number of plants selfed (18 and 16) to produce BC₂F₂ (A and B) for each progeny after phenotyping and genotyping are presented in online Supplementary Table S5. As stated earlier by Babu et al. (Reference Babu, Nair, Kumar, Venkatesh, Sekhar and Singh2005), identification of heterozygotes in the seedling stage prior to pollination aids in the rejection of non-target BC progenies, resulting in substantial saving of labour and material resources. Magulama and Sales (Reference Magulama and Sales2009) developed the two BC populations to employ marker assisted selection for o2 gene. Gupta et al. (Reference Gupta, Raman, Agrawal, Mahajan, Hossain and Thirunavukkarasu2013) identified heterozygous (O2o2) progenies that occurred with 50% frequency in a given backcross population.

Approximate percentage genome similarity to recurrent parents in selected lines using polymorphic background SSR markers

The 18 and 16 plants of BC₂F₁ (A) and (B) were selfed after foreground and background selection in previous generation. Their seeds (BC₂F₂) were harvested and sown in 4 m row system. 100 BC₂F₂ plants were raised each from both progenies were first studied for marker segregation at o2 locus (online Supplementary Figs. 15 and 16) to performforeground selection for recessive homozygotes. The marker segregation ratio at this locus was close to Mendelian monohybrid genotypic ratio of 1:2:1 (using X ² test). The selected recessive homozygotes were subjected to study recurrent parent genome similarity which is called as background selection. Background genome recovery among the BC₂F₂ progenies of both the crossing schemes was performed using 25 polymorphic SSR markers. In the present study we selected those entry numbers, or plants which had recurrent parent similarity for at least 20 background markers. The entry number selected were IML-187 × DQL-2029-1/BC₂F₂-1,2,3,36,15,6,7,8,31,19,11,29,27,14,5,16,17 and 23 and for BC₂F₂ (B) were BML-6 × DQL-779-2-9/BC₂F₂-1, 3,7,44,31,28,27,18,13,10,23,8,20,4,14 and 22 (Table 1). Only these entries were selfed to generate BC₂F₃ seeds. Including a selection step on non-carrier chromosomes is more effective in later backcross generations (BC₃ or BC₄) than in early generations. Although this may be counter intuitive, it is based on the facts that in early generations, few recombination have occurred to break up introgressed segments from the donor thus, few markers are needed, and that most of the donor material will be removed in subsequent backcrosses. Therefore a smaller number of background markers can suffice in early backcross generations such as BC₂F₁ and BC₂F₂. Also, the 15 SSR markers being non polymorphic mean that genome of recurrent and donor parents is similar at these loci. Thus selection for the areas related to non-polymorphic markers is already been done by nature. Therefore the overall genome selected will be more than what noticed on the basis of 25 polymorphic markers. Our selection procedure was assisted by phenotypic selection as well. Those traits have also assisted in selection as phenotypic markers. In later generations, the donor regions will be smaller, and hence more markers will be needed. Selection against donor alleles in the region of the target i.e. reducing the linkage block surrounding the target has been discussed by numerous authors (Frisch et al., Reference Frisch, Bohn and Melchinger1999; Reyes-Valdés, Reference Reyes-Valdés2000; Frisch and Melchinger, Reference Frisch and Melchinger2001; Hospital, Reference Hospital2001). The goal is to reduce the size of the donor DNA segment surrounding the target gene to as small as possible in the backcrossing programme. Marker assisted background analysis of the BC/recombinant progenies is useful in determining the relative contribution of donor parent. Availability of robust anchored marker maps in maize renders application of marker aided background selection an easy and attractive proposition. However, the cost of employing background selection in each BC generation could be prohibitive to many public sector breeding programmes. The earlier simulation studies of Frisch et al. (Reference Frisch, Bohn and Melchinger1999) have indicated that application of background selection in one later generation along with foreground selection in each BC generations could be efficient and cost-effective. Chandran et al. (Reference Chandran, Pukalenthy, Adhimoolam, Manickam, Sampathrajan, Chocklingam, Eswaran, Arunachalam, Joikumar, Rajasekaran, Muthusamy, Hossain and Natesan2019) utilized genome wide SSR markers to recover background genome in BC₂F₂ population. Hospital et al. (Reference Hospital, Chevalet and Mulsant1992) stated that care needs to be taken in a practical MAS programme to avoid sampling error and exaggerated estimates of recurrent parent genome associated with smaller number of marker data points.

Table 1. Percentage genome similarity of BC₂F₂ (A) with IML-187 and BC₂F₂ (B) with BML-6 based on 25 polymorphic SSRs

Phenotyping of BC₂F₃ seeds for endosperm modification using light box

The BC₂F₃ seeds harvested from selfing of BC₂F₂ plants in previous generation were kept separate as entries and were screened for vitreous endosperm. Screening of kernels in light box categorized four degrees of opaqueness viz. <25, 25–50, 50–75 and 75–100% Krishna et al. (Reference Krishna, Reddy and Satyanarayana2017) (online Supplementary Fig. S12). The number of plants used for screening in light box and finally selected is presented in online Supplementary Table S6. The screening of the seeds was done using light box having fluorescent light with endospermic region upside down in the dark room. The high lysine and tryptophan in QPM is due to the presence of opaque 2 gene in homozygous recessive state. The endosperm of opaque 2 maize has variable degree of opaqueness and this trait is governed by endosperm modifiers. The inheritance of endosperm modifiers is polygenic in nature and there is no reliable molecular marker to accurately genotype these genes. These modifier genes do not have effect of their own but have an interaction effect on opaque mutants and thus modify kernel opaqueness (Vasal et al., Reference Vasal, Villegas, Bjarnason, Gelaw, Goertz, Pollmer and Phillips1980). Lopes and Larkins (Reference Lopes and Larkins1995) showed that kernel modification in QPM is governed by more than one minor gene. As a result, each kernel has different degree of modification due to action of many genes with small effect. Of the differentially modified kernels, those exhibited less than 25% opaqueness were selected from each ear whereas kernels over 25–50% and more than 50% opaqueness were rejected due to soft nature and dull appearance of kernels (Vasal et al., Reference Vasal, Srinivasan, Pandey, González, Crossa and Beck1993). Thus the screening of seeds using a light box is a high throughput and easy way to differentiate kernels on the basis of extent of opaqueness. This helps to select QPM kernels with endosperm similar to normal parents.

Determination of protein, tryptophan and lysine content in the BC₂F₃ seeds

The seeds from the selfed BC₂F₂ population of the selected lines were harvested as BC₂F₃ seeds after undergoing endosperm modification screening were analysed individually along with their parental lines for estimation of protein, tryptophan and lysine content. The estimated per cent (%) value of nitrogen obtained using Rapid N-cube Analyzer instrument was used to determine the protein content in per cent (Elementar Analysensysteme GmbH, web: www.elementar.de, D 63452 Hanau, Germany). The estimated per cent protein, tryptophan and lysine content values of the converted lines developed from the IML-187 × DQL-2029-1 BC₂F₃ and BML-6 × DQl-779-2-9 BC₂F₃ are given in the online Supplementary Table S7. The results indicated the lowest tryptophan value of 0.047% in IML-187 × DQL-2029-1 BC₂F₃:12 line while the maximum value of 0.117% was found in BML-6 × DQl-779-2-9:12. The four parents namely IML-187, BML-6, DQL-2029-1, and DQL-779-2-9 used in conversion programme had 0.045, 0.042, 0.074 and 0.090% tryptophan, respectively (online Supplementary Table S7). Thus, wide variation for tryptophan content was observed in recombinant BC₂F₃ lines. The criteria used in QPM breeding for selection or rejection of breeding lines include tryptophan content which should be 0.075% or more on whole grain sample basis and quality index (QI) of 0.8% or more (Vivek et al., Reference Vivek, Krivanek, Palacios-Rojas, Twumasi-Afriyie and Diallo2008). The quality index is the tryptophan-to-protein ratio in the sample, expressed as a percentage. Values lower than this indicate a non QPM cultivar. Using this yardstick, eight lines namely {IML-187 × DQL-2029-1- BC₂F₃:06}, {IML-187 × DQL-2029-1- BC₂F₃:07}, {IML-187 × DQL-2029-1- BC₂F₃: 23} and {BML-6 × DQL-779-2-9: 02}, {BML-6 × DQL-779-2-9: 04}, {BML-6 × DQL-779-2-9: 09}, {BML-6 × DQL-779-2-9: 20} and {BML-6 × DQL-779-2-9: 13} were identified to have tryptophan higher than 0.075%. Line {IML-187 × DQL-2029-1- BC₂F₃:23} was selected due to better lysine and overall protein content despite having 0.074% tryptophan content. Studies by Gupta et al. (Reference Gupta, Raman, Agrawal, Mahajan, Hossain and Thirunavukkarasu2013) pointed out that the o2 allele when present in homozygous condition reduces the production of zeins, particularly the α-zeins, through which it increases the level of lysine and tryptophan. The presence of o2 modifiers will contribute to the recovery of hard endosperm. This supposition is because of experimentally and statistically well proven and well established relationship between the tryptophan and lysine. Lysine and tryptophan levels are highly correlated and as such an assay for either amino acid can be used for analysing protein quality, although in practice the latter is most often chosen due to lower laboratory costs (Hernandez and Bates, Reference Hernandez and Bates1969; Villegas et al., Reference Villegas, Vasal, Bjarnason and Mertz1992). Lysine and tryptophan concentration in maize kernels of agronomically advanced QPM lines are highly correlated. A 4:1 ratio of lysine to tryptophan has been reported in normal and QPM (Bjarnason and Vasal, Reference Bjarnason, Vasal and Janick1992; Vivek et al., Reference Vivek, Krivanek, Palacios-Rojas, Twumasi-Afriyie and Diallo2008).

Crossing between converted BC₂F₃ progenies to produce QPM version of SMH-5

The selected BC₂F₃ entries were sown in kharif 2022 and crosses were made between converted progenies of IML-187 and BML-6. The crosses were made in a Line × Tester pattern using three selected entries from IML-187 progeny as female tester parents and five selected entries of that of BML-6 progeny as male lines. Crosses were evaluated in kharif- 2023 at Dryland Agricultural Research Station, Rangreth SKUAST-Kashmir (33°99′04″N and 74°80′65″E). The crosses and their performance for protein, tryptophan and yield/ha is presented in online Supplementary Table S8.

The varietal development programmes take several years. The marker assisted backcross breeding with two generations per year is a useful tool in transferring single or a few traits to the adapted elite lines. This procedure reduces the time taken in the development of improved versions of existing varieties/inbred lines by half. Thus, hastening the hybrid development programmes. In the present study, three improved versions of IML-187 and five versions of BML-6 were developed with a genome recovery of 90% based on 25 polymorphic SSR markers. It should be noted that 15 additional loci were similar to recurrent types due to monomorphism. Finally, 15 improved versions of SMH-5 were developed in the present study as presented in online Supplementary Table S8. Hybrids, {IML-187: BC₂F₃:6 × BML-6: BC₂F₃:2},{IML-187: BC₂F₃:6 × BML-6: BC₂F₃:13}, {IML-187: BC₂F₃:6 × BML-6: BC₂F₃:20}, {IML-187: BC₂F₃:7 × BML-6: BC₂F₃:9}, {IML-187: BC₂F₃:23 × BML-6: BC₂F₃:2}, {IML-187: BC₂F₃:23 × BML-6: BC₂F₃:4} are being considered for release in the early maturity group in northern hill zone of India, indicating Marker assisted shuttle backcross breeding is a reliable, rapid and convenient tool in development of biofortified elite adapted crop varieties.