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Low soil phosphorus availability has limited effects on wood traits in young plants of five eucalypt species

Published online by Cambridge University Press:  27 May 2024

Franklin Magnum de Oliveira Silva
Affiliation:
Department of Plant Biology, Institute of Biology, State University of Campinas, Campinas, Brazil
Helena Augusto Gioppato
Affiliation:
Department of Plant Biology, Institute of Biology, State University of Campinas, Campinas, Brazil
Alexandre Augusto Borghi
Affiliation:
Department of Plant Biology, Institute of Biology, State University of Campinas, Campinas, Brazil
Sara Adrián López Andrade
Affiliation:
Department of Plant Biology, Institute of Biology, State University of Campinas, Campinas, Brazil
Paulo Mazzafera*
Affiliation:
Department of Plant Biology, Institute of Biology, State University of Campinas, Campinas, Brazil
*
Corresponding author: Paulo Mazzafera; Email: pmazza@unicamp.br
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Summary

Plant-derived products rely heavily on the availability of phosphorus (P) in the soil. With reserves of P-rocks being limited, there is a growing demand to enhance the efficiency of P utilization by crops. Eucalypts, an important economic crop in many countries, is a source of timber, coal, essence oils, and cellulose. After identifying low P tolerant and susceptible species in a previous study, we explored the various physiological and biochemical responses of these same species to low P availability. The aim was to expand our understanding of how different P-nutrition responses might impact eucalypt wood production and traits related to its quality. Our results indicate that low soil P minimally affects physiological wood parameters in the young trees of Eucalyptus acmenoides, Corymbia maculata, E. grandis, E. globulus, and E. tereticornis. Decreases in cellulose contents and increases in lignin content and syringyl and guaiacyl (S/G) ratios were observed under low P and only in E. acmenoides plants. Wood density remained unaffected in all species. Additionally, bark, stem, and root P concentrations increased under sufficient P conditions in E. globulus, E. grandis, and E. tereticornis. These findings suggest that these plant parts may act as reserve pools of this nutrient.

Type
Research Article
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

Phosphorus (P) is an essential nutrient for all life forms on Earth. In plants, it plays a fundamental role in several physiological processes, including energy metabolism, cell division and the synthesis of crucial molecules such as nucleic acids, phospholipids, and ATP (White and Hammond, Reference White, Hammond, White and Hammond2008; Lambers and Plaxton, Reference Lambers and Plaxton2015; Xu et al., Reference Xu, Zhu, Nikonorova and de Smet2019).

P entry into the food chain occurs through plants, with fertilizers frequently serving as the primary source for cultivated plants due to the low P availability of most agricultural soils and the relatively high plant demands. The inorganic P used as a fertilizer is derived from the extraction of phosphate rock reserves, with the largest reserves located in Morocco, China, South Africa, and the USA. Projections based on current global phosphate rock usage estimate a depletion of these reserves in approximately 90 years (Vaccari, Reference Vaccari2009; Veneklaas et al., Reference Veneklaas, Lambers, Bragg, Finnegan, Lovelock, Plaxton, Price, Scheible, Shane, White and Raven2012). These raise significant concerns about the sustainability of P availability for agriculture, given that P reserves are non-renewable. Consequently, identifying mechanisms to enhance P-use efficiency is essential and ranks high in the actions of agricultural science (Vaccari, Reference Vaccari2009; van de Wiel et al., Reference van de Wiel, van der Linden and Scholten2016). Although alternative approaches are conceivable, such as recovering P from human-generated waste, they still encounter substantial technical and cost challenges (Vaccari, Reference Vaccari2009; Pavinato et al., Reference Pavinato, Cherubin, Soltangheisi, Rocha, Chadwick and Jones2020).

Because of the high adsorption of P in soil oxides, predominantly found in tropical soils, it is estimated that only 20% of the P present in applied fertilizers is absorbed by crops (Mclaughlin et al., Reference Mclaughlin, Alston and Martin1988; Zhang et al., Reference Zhang, Ma, Ji, Fan, Oenema and Zhang2008). The primary chemical form absorbed by plants is the orthophosphate ion (PO4 2-), and in weathered soils, it strongly binds with Fe and Al oxides/hydroxides, rendering it unavailable. Additionally, part of the soil P can be immobilized in organic forms. In both scenarios, P retained by oxides and in organic compounds can be released into the soil solution through the action of organic acids and enzymes exuded by plants and microorganisms, making it available to plants (Lambers, Reference Lambers, Rengel, Cakmak and White2023).

Throughout evolution, plants have developed various mechanisms to obtain P from the soil or to increase its use efficiency by recycling and remobilizing it within cellular metabolism (White and Hammond, Reference White, Hammond, White and Hammond2008; Bulgarelli et al., Reference Bulgarelli, de Oliveira Silva, Bichara, Andrade and Mazzafera2019; de Oliveira Silva et al., Reference de Moraes Gonçalves, Stape, Laclau, Smethurst and Gava2022). These mechanisms collectively contribute to the P-use efficiency, defined as the amount of biomass produced per unit of absorbed P. (Baker et al., Reference Baker, Ceasar, Palmer, Paterson, Qi, Muench and Baldwin2015)

The availability of P in tropical forests is a crucial determinant for wood production and the subsequent increase in productivity, responding to total soil P contents (Jucker et al., Reference Horikawa2016; de Andrade et al., Reference Keith, Raison and Jacobsen2024). In these highly weathered soils, characterized by low P availability, the growth and productivity of eucalypt plantations are significantly restricted (de Moraes Gonçalves et al., Reference de Andrade, de Oliveira, Mazzafera and Antonio2004). Studies have demonstrated notable effects of P fertilization on eucalypt plantations. For example, the application of superphosphate fertilizer in E. urophylla plantations resulted in a higher percentage of stem wood and a lower relative allocation of biomass to the roots compared to unfertilized treatments (Xu et al., Reference Xu, Dell, Malajczuk and Gong2002). Similarly, in native stands of E. tereticornis, P fertilization led to an increase in stem basal area growth (Crous et al. Reference Crous, Ósvaldsson and Ellsworth2015). The impact of low P availability extends to wood formation by disrupting processes such as photosynthesis and leading to a shift in carbon allocation towards root growth (Jucker et al., Reference Horikawa2016). Nevertheless, the addition of nitrogen and P fertilizers may adversely affect certain wood traits, such as density and fibre length, depending on the soil and climatic conditions. This phenomenon has been observed in E.globulus plantations (Raymond and Muneri, Reference Raymond and Muneri2000). A correlation between wood density and P soil supply was identified in E. grandis seedlings. Low P supplies were associated with increased wood density, which was linked to the inhibition of stem cambial activity (Thomas et al., Reference Thomas, Montagu and Conroy2005).

Eucalyptus, the world’s most extensively cultivated hardwood tree (Carnus et al., Reference Carnus, Parrotta, Brockerhoff, Arbez, Jactel, Kremer, Lamb, O’Hara and Walters2006; Valadares et al., Reference Valadares, Neves, Leite, de Barros, Cropper and Gerber2020), encompasses over 700 species, providing a large genetic variability in response to P availability. In previous work, we categorized 25 eucalypt species into four groups based on their responsiveness and tolerance to low soil P availability (Bulgarelli et al., Reference Bulgarelli, de Oliveira Silva, Bichara, Andrade and Mazzafera2019). This information provides an opportunity to explore P allocation strategies in response to different soil P conditions, as these species exhibit variations in their ability to acquire, allocate, and utilize P. Ultimately, these factors influence their overall performance and survival in P-limited environments.

Here, we examined five eucalyptus species – Eucalyptus acmenoides, Corymbia maculata, E. grandis, E. globulus, and E. tereticornis – selected based on their differing abilities to use P (Bulgarelli et al., Reference Bulgarelli, de Oliveira Silva, Bichara, Andrade and Mazzafera2019) Our investigation aimed to explore the following hypothesis: (i) the availability of P in the soil affects wood compositional traits and density; (ii) species differing in P-use efficiency adjust their photosynthetic rates to optimize P utilization; (iii) stem and bark serve as potential sites for long-term P storage.

Materials and Methods

Plant material and experimental design

The experiment utilized outdoor cultivation in 50-L plastic pots equipped with a dipping water supply system. Seeds of the species E. acmenoides, Corymbia maculata, E. grandis, E. globulus, and E. tereticornis were obtained from a clonal garden (Caiçara Sementes – https://sementescaicara.com/) and germinated in seedbeds containing a mixture of commercial substrate and soil. When the seedlings reached two months of age, they were transferred into the 50 L pots, each featuring two levels of available soil P: low P (4 mg kg-1) and sufficient P (25 mg kg-1). The transplantation took place in September 2020, and the plants were collected 18 months later. The experimental setup followed a 5 × 2 factorial design, comprising five eucalyptus species and two P levels, with four biological replicates.

Soil preparation

The substrate for plant growth was prepared by mixing soil and coarse sand in a 1:1 (v:v) ratio. The soil employed was a ferrosol (IUSS Working Group WRB, 2015); its chemical composition can be found in Table S1A (Supplementary material). Potassium phosphate (KH2PO4) was incorporated into the substrate to achieve the desired P level in the treatment with sufficient P. No additional P was added for the low P treatment. Additionally, in both P treatments we adjusted the concentrations of copper (Cu), magnesium (Mg), zinc (Zn), manganese (Mn), and boron (B) to levels suitable for forest species at a medium fertility level in the state of São Paulo, Brazil (van Raij et al., Reference van Raij, Cantarella, Quaggio and Furlani1996). Specific amounts of each nutrient (B, Cu, Mn, Zn, and Mg) added to the soil in milligrams per kilogram (mg kg-1) were as follows: B (H3BO3) – 2.25, Cu (CuCl2) – 2.7, Mn (MnSO4) – 15.6, Zn (ZnCl2) – 52.7, and Mg (MgSO4) – 418.3. Nutrient salts were solubilized in water and slowly added to the soil-sand mixture using a concrete mixer. Following the preparation, the soil-sand substrate was stored for 20 days, after which a sample was taken for soil chemical analysis (Table S1B, supplementary material). Additionally, N, in the form of NH4NO3, was added to the soil at 125 mg kg-1. This N was applied in three separate fertilizations during the experiment, at seedlings transplantation, and after one and two months.

Dry mass accumulation and nutrient analysis

At the end of the experiment, leaves and stems (including branches) were separately collected and air-dried at 60°C until a constant dry mass was achieved. The roots were washed under tap water and also dried at 60°C. Following dry mass determination, the dried material was used for nutrient analysis. A section of the main stem was used for nutritional analysis, and bark was separated from the stem in this section using a blade. Concentrations of P and other macronutrients were analysed in samples of the leaves, stems, bark, and roots using inductively coupled plasma optical emission spectrometry (ICP-OES; Varian Vista MPX, Palo Alto, CA, USA), following nitro-perchloric digestion of the samples.

Determination of gas exchange parameters

Physiological parameters related to leaf gas exchange were assessed in 18-month-old plants using an infrared gas analyser IRGA (Li 6400R, Li-Cor, Lincoln, USA). Measurements of photosynthetic rate (A), stomatal conductance (gs), and intracellular CO2 concentration (Ci) were conducted on young fully expanded leaves between 9 h and 14 h. The measurements were taken under ambient CO2 concentration (approximately 400 ppm) and a light intensity of 1,500 µmol photons m-2 s-1, with 10% blue light supplied by the equipment.

Wood parameters

Cellulose content was determined using the protocol of Chen et al. (Reference Chen, Auh, Chen, Cheng, Aljoe, Dixon and Wang2002). Lignin content was determined using the acetyl bromide method (Fukushima et al., Reference de Oliveira Silva, Bulgarelli, Mubeen, Caldana, Andrade and Mazzafera2015). The lignin syringyl/guaiacyl (S/G) ratio was determined according to Mokochinski et al. (Reference Mokochinski, Bataglion, Kiyota, de Souza, Mazzafera and Sawaya2015). Wood density was determined using Archimedes’ principle (Hacke et al., Reference González-Vila, Almendros, del Rio, Martıín, Gutiérrez and Romero2000).

Statistical analysis

The influence of soil P availability and eucalypt species on growth variables, leaf and stem nutrient concentration, gas exchange parameters, and biochemical traits was evaluated using a two-factor analysis of variance (two-way ANOVA). Mean values were compared using the Tukey’s test at a significance level of p ≤ 0.05, employing the Rbio software (Bhering, Reference Bhering2017).

Results

Macronutrient concentrations

The concentrations of nutrients other than P (N, Ca, K, Mg, and S) were determined in roots, stems, bark, and leaves, and values can be found in Table S2 (supplementary material). A concise overview of the significant differences between low and sufficient P treatments in each species is shown in Figure 1. Minimal alterations were observed, and no distinct pattern emerged regarding species or organs/tissues. Most of the significant changes were identified in the bark, where, when significantly altered, N concentrations consistently increased while K decreased (Figure 1). In the stems, N concentrations increased in E. acmenoides and E. globulus plants when compared to plants under sufficient P conditions (Figure 1). However, in the leaves, only minor alterations in nutrient concentrations were observed in some species (Figure 1).

Figure 1. Schematic presentation of significant changes in nutrient concentrations in tissues of five Eucalyptus species. The blue arrow up indicates a significant increase of the nutrient in the low P treatment in relation to the sufficient P treatment, and the red down arrows indicate a significant decrease.

Figure 2 shows the P concentrations in each tissue/organ. E. grandis roots exhibited higher P concentrations in both low and sufficient P treatments than the other species. Notably, E. globulus was the sole species showing a significant difference between plants subjected to low P and sufficient P conditions. Compared to low P conditions, plants of E. globulus, E. grandis, and E. tereticornis receiving sufficient P showed higher P concentrations in the bark and stem. Conversely, in the leaves, E. acmenoides showed the highest P concentrations among the studied eucalypt species (Figure 2), while only in C. maculata were P concentrations significantly higher under sufficient compared to low P conditions (Figure 2).

Figure 2. Phosphorus concentrations in different tissues of five eucalyptus species subjected to low and sufficient P. Lowercase letters indicate statistical differences (p < 0.05, Tukey’s test) among species for the same P treatment, and asterisks indicate statistical differences between P treatments within the same species.

Plant growth

Plants of E. globulus, E. grandis, and E. tereticornis grown under low P and sufficient P exhibited comparable dry mass accumulation in all organs (Figure 3). However, plants of C. maculata and E. acmenoides showed better growth under sufficient P compared to low P. Specifically, under low P, E. tereticornis was the species accumulating the highest dry mass in all plant organs. Under low P conditions, root biomass production in C. maculata and E. acmenoides was higher compared to plants under sufficient P. For E. globulus and E. tereticornis, P did not significantly influence root biomass production, whereas for E. tereticornis, root biomass production was higher under low P conditions compared to sufficient P conditions (Figure 3a).

Figure 3. Dry mass of different tissues of five eucalyptus species subjected to low and sufficient P. Lowercase letters indicate statistical differences (p < 0.05, Tukey’s test) among species for the same P treatment, and an asterisk indicates statistical differences between P treatments within the same species.

Photosynthetic traits

Except for E. globulus, a clear pattern of reduced CO2 assimilation rates was evident in plants under low P conditions (Figure 4a); however, the only significant difference was observed in E. grandis plants. There were also minor alterations in stomatal conductance (Figure 4b) and internal leaf CO2 concentration (Figure 4c).

Figure 4. Photosynthesis (a), stomatal conductance (b), and leaf internal CO2 concentration of different tissues of five eucalyptus species. Lowercase letters indicate statistical differences (p < 0.05, Tukey’s test) among species for the same P treatment, and asterisk indicates statistical differences between P treatments in the same species.

Wood density, cellulose, lignin, and S/G ratio

Minimal alterations were observed in terms of wood traits due to low P availability and among eucalypt species (Figure 5). Under low P conditions, an interesting trade-off was identified in E. acmenoides plants, exhibiting reduced cellulose contents (Figure 5b) but increased lignin contents (Figure 5c). The S/G ratio also increased in plants of this species under low P compared to plants under sufficient P conditions (Figure 5d). Under sufficient P conditions, E. tereticornis exhibited the lowest lignin contents among the studied species, with levels up to four times lower than those observed in E. grandis plants (Figure 5c).

Figure 5. Wood density (a), cellulose (b), lignin (c) concentrations, and S/G ratios in the wood of five eucalyptus species subjected to low and sufficient P. Small letters indicate statistical differences (p < 0.05, Tukey’s test) among species for the same P treatment, and asterisk indicates statistical differences between P treatments within the same species.

Discussion

Phosphorus and plant growth

The importance of P in plants is highlighted by its essential role as a major component of vital molecules, such as ATP and sugar-phosphates. It participates in enzyme phosphorylation and contributes to the formation of cellular structures, such as the case of phospholipids in membranes. Deficiency in P strongly impacts plant growth and productivity (Hawkesford et al., Reference Hacke, Sperry and Pittermann2012).

Our investigation revealed that E. globulus, E. grandis, and E. tereticornis plants subjected to low P conditions had lower P concentrations in the stem and bark than plants under sufficient P (Figure 2). Surprisingly, we did not find a positive correlation between P concentrations and dry matter accumulation in these species. Conversely, C. maculata and E. acmenoides, despite not showing an increase in P concentration (Figure 2), were the species that accumulated more biomass (dry mass-basis) (Figure 3). Furthermore, plants of C. maculata and E. acmenoides under sufficient P did not show a significant increase in photosynthetic rates, although a noticeable trend was observed.

Previous studies with eucalypts, specifically E. tereticornis, showed that P enhances plant height and stem biomass over time with a stable photosynthetic capacity (Crous et al., Reference Crous, Ósvaldsson and Ellsworth2015). Similarly, P was found to lead to a 30 % increase in wood production in E. pauciflora, which was related to a reduction in photoassimilate allocation to roots rather than an improvement in canopy biomass (Keith et al., Reference Jucker, Sanchez, Lindsell, Allen, Amable and Coomes1997). In our study, only E. maculata and E. acmenoides exhibited increased root dry mass accumulation with P, although all studied species had the same or higher root mass than stem dry mass (Figure 3).

A previous study on beech trees, in which the impact of added P on forest soil was evaluated, revealed that new P was preferentially allocated aboveground. This resulted in increased bound P in xylem tissue and enhanced soluble P in bark, indicating increased storage and transport in sufficient P conditions (Keith et al., Reference Jucker, Sanchez, Lindsell, Allen, Amable and Coomes1997). Similarly, a study by Netzer et al. (Reference Netzer, Herschbach, Oikawa, Okazaki, Dubbert, Saito and Rennenberg2018) identified several processes and metabolites contributing to adequate phosphate supply in low P soil, including the accumulation of phospholipids and phosphates in the bark and storage of phosphate in the wood. Therefore, the higher P accumulation in the bark observed in our study for E. globulus, E. grandis, and E. tereticornis may suggest a strategy employed by eucalyptus species to store P for subsequent remobilization and use under low P conditions.

It is widely acknowledged that low P availability can disrupt the photosynthetic machinery and electron transport chain, redirecting assimilated carbon for root growth, contrary to the observations made by the species in this study (Lambers et al., Reference Lambers, Shane, Cramer, Pearse and Veneklaas2006; Carstensen et al., Reference Carstensen, Herdean, Schmidt, Sharma, Spetea, Pribil and Husted2018). However, the responses of several eucalypt species may vary considerably regarding their response to low P (Bulgarelli et al., Reference Bulgarelli, de Oliveira Silva, Bichara, Andrade and Mazzafera2019). Using responsiveness and use efficiency for P as traits to categorize species into four possible groups (responsive and tolerant to low P, responsive and non-tolerant, non-responsive and tolerant, and non-responsive and non-tolerant), most species were grouped in responsive and non-tolerant to low P and non-responsive and tolerant categories. C. maculata was distinctly positioned in the non-responsive and non-tolerant group, while E. acmenoides was typically positioned as responsive and non-tolerant. The distinctions among these two species, as well as the other three included in this study, may indicate different metabolic mechanisms in response to low P, as previously suggested (de Oliveira Silva et al., Reference de Moraes Gonçalves, Stape, Laclau, Smethurst and Gava2022), including the buffering of P deficiency in one organ by P accumulated in other organs, such as roots, as observed in other eucalyptus species (Mulligan, Reference Mulligan1988).

The dose of P supplied to the plants is also noteworthy for discussion. In this study, a high P dose of 25 mg P kg-1 soil was used, requiring the addition of 21 mg of P to reach this level compared to the low P treatment of 4 mg P kg-1 soil. In 50-L pots filled with substrate up to about 90% of their volume, which had approximately a 0.4 m2 diameter, the amount of P added was calculated considering a soil density of 1.3 g cm-3. This resulted in the addition of about 3 g of P per m2. For comparison, in a field with E. tereticornis plantation, (Crous et al., Reference Crous, Ósvaldsson and Ellsworth2015) applied 50 kg ha-1, equivalent to 5 g P per m2. Therefore, depending on the amount of P used, the nutrient accumulation may differ because of the plant species and the nutrient availability or supply.

Phosphorus and wood quality

Wood quality is a critical attribute in various industries, including timber production, construction, pulp, and paper manufacturing, and contributes to the economic value of tree stems (Lourenço et al., Reference Lourenço, Gominho, Marques and Pereira2013).

In E. grandis, a lack of P fertilization over 20 months resulted in a notable 50% decrease in wood volume (Rocha et al., Reference Rocha, de Moraes Gonçalves, de Vicente Ferraz, Poiati, Arthur Junior and Hubner2019). An earlier study on the effects of P limitation on E. grandis seedlings revealed that, although plant height, stem diameter, and total biomass increased with increasing P supply, stem wood density sharply decreased with increasing P supply until a threshold was reached, beyond which further P supply did not affect wood density (Thomas et al., Reference Thomas, Montagu and Conroy2005). The increase in wood density was primarily attributed to the increased thickening of secondary walls in stem fibre cells under low soil P supply, altering biomass partitioning within the stem in favour of secondary wall thickening (Thomas et al., Reference Thomas, Montagu and Conroy2005).

Changes in the metabolome of leaves, roots, and stems of seedlings from the same five eucalyptus species examined in this study (de Oliveira Silva et al., Reference de Moraes Gonçalves, Stape, Laclau, Smethurst and Gava2022) found substantial variation among species in concentrations of sugars, organic acids, amino acids, and lipids under low P supply. Some species exhibited a reduction in P-sugars and increased sulphur-lipids, indicative of enhanced P-use efficiency. In agreement with our study, irrespective of species and P treatment, stems accumulated more P than leaves and roots.

The physical and chemical properties of wood directly influence its utilization in various applications. When considering wood constituents, cellulose emerges as a primary component due to its unique characteristics. As the main component of the cell wall and wood, cellulose is a complex polysaccharide composed of repeating units of glucose molecules linked together by β-1,4-glycosidic bonds, forming long chains characterized by their high degree of polymerization and linear arrangement, which contributes to the strength and integrity of wood fibres (Mahood and Cable, Reference Mahood and Cable1922; Horikawa, Reference Hawkesford, Horst, Kichey, Lambers, Schjoerring, Møller, White and Marschner2022). These cellulose fibres are organized into crystalline structures known as microfibrils, which are assembled into oriented sheets stacked on top of each other, forming the cell wall. The density and orientation angle of these microfibrils influence wood stiffness and utility (Tabet and Aziz, Reference Tabet, Aziz, Van De Ven and Godbout2013; Horikawa, Reference Hawkesford, Horst, Kichey, Lambers, Schjoerring, Møller, White and Marschner2022).

Another crucial component significantly influencing wood quality is lignin, the second most abundant polymer in vascular plants, providing rigidity and strength to plant cell walls. Its composition and structure can vary among different plant species and even within different cell types within the same species (Vanholme et al., Reference Vanholme, Demedts, Morreel, Ralph and Boerjan2010; Liu et al., Reference Liu, Luo and Zheng2018).

Limited information is available about the effects of low P availability on cell wall components. A recent review showed that P deficiency may affect cellulose and lignin synthesis in the root cells, as roots alter growth patterns to increase P absorption from the soil (Ogden et al., Reference Ogden, Hoefgen, Roessner, Persson and Khan2018). At the molecular level, PAP1 (PRODUCTION OF ANTHOCYANIN PIGMENT1) may be affected by P nutrition. PAP1 may act as a positive or negative regulator of the lignin biosynthesis pathway. The transcript levels of PAP1, and its close homolog PAP2/MYB90, are strongly induced nitrogen and/or P limitation, promptly reversed by nitrate fertilization (Ogden et al., Reference Ogden, Hoefgen, Roessner, Persson and Khan2018).

A leaf metabolome analysis of young E. globulus plants grown at different P concentrations showed significant changes in metabolite profiles (Warren, Reference Warren2011). P-sugars like glucose-6-P and fructose-6-phosphate decreased with low P, indicating a reallocation of P pools. Minimal changes were observed regarding carbohydrates, organic acids of the tricarboxylic acid (TCA) cycle, and amino acids. However, low P led to a decrease in phenolic compounds, such as coumaroylquinic acid and catechin, suggesting a relation to increased lignin synthesis. P deficiency has been reported to increase lignification in proteoid roots of lupin (Uhde-Stone et al., Reference Uhde-Stone, Zinn, Ramirez-Yáñez, Li, Vance and Allan2003) and leaves of young cotton plants (Luo et al., Reference Luo, Li, Xiao, Ye, Nie, Zhang, Kong and Zhu2021).

In our study, low P availability did not affect the wood density of all species. However, it increased lignin content in E. acmenoides and decreased cellulose contents. This trade-off might explain why the relative wood density was not altered in this species. Additionally, in E. acmenoides, the ratio between syringyl (S) and guaiacyl (G) units increased under low P. A higher S/G ratio is particularly advantageous for pulp and paper manufacturing due to the easier S-lignin degradation, resulting in lower alkali consumption and higher pulp yield (González-Vila et al., Reference Fukushima, Kerley, Ramos, Porter and Kallenbach1999). Furthermore, the S/G ratio is an important factor in biomass recalcitrance to bioethanol production, with a higher S/G ratio leading to higher recalcitrance (Cesarino et al., Reference Cesarino, Araújo, Domingues and Mazzafera2012; Vicentini et al., Reference Vicentini, Bottcher, Brito, dos Santos, Creste, Landell, Cesarino and Mazzafera2015). For timber production and construction, however, a low S/G ratio is more desirable as it contributes to a denser and more compact wood structure, ideal for the furniture and civil construction market (Yoo et al., Reference Yoo, Dumitrache, Muchero, Natzke, Akinosho, Li, Sykes, Brown, Davison, Tuskan and Pu2018; Börcsök and Pásztory, Reference Börcsök and Pásztory2021).

Conclusion

This study explored biochemical and physiological responses associated with low P availability to determine if a low P supply might affect wood formation and quality in five eucalypt species. The observed effects were minimal and non-related to P availability or the ability of the species to respond or accumulate P. However, an interesting finding was that three species, E. globulus, E. grandis and E. tereticornis, accumulated more P in the stem and bark than in leaves, suggesting that these tissues may act as reserve pools of this nutrient.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0014479724000115

Data availability statement

The data that support the findings of this study are available from the corresponding author upon reasonable request.

Acknowledgments

FMOS and AAB thank the São Paulo Research Foundation (FAPESP) for student fellowships (grants 2018/09624-0 and 2019/10614-2, respectively), and PM thank the Brazilian National Council for Scientific and Technological Development (CNPq) for research fellowship. This work was supported by FAPESP (grant 2016/25498-0). The funders had no role in the study design, data collection, analysis, interpretation, manuscript writing, or decision to publish the results.

Authors contributions

FMOS: investigation, formal analysis, data curation, and writing – Original Draft; HAG: Data curation and writing – original draft; AAB: investigation and data curation; SALA: conceptualization, writing – original draft and reviewing, and supervision; PM: conceptualization, writing – original draft and reviewing, and supervision.

Competing interests

The authors declare no conflict of interest. The funders had no role in the study’s design, in the collection, analyses, or interpretation of data, in the writing of the manuscript, or in the decision to publish the results.

References

Baker, A., Ceasar, S.A., Palmer, A.J., Paterson, J.B., Qi, W., Muench, S.P. and Baldwin, S.A. (2015) Replace, reuse, recycle: improving the sustainable use of phosphorus by plants. Journal of Experimental Botany 66(12), 35233540. https://doi.org/10.1093/jxb/erv210 CrossRefGoogle ScholarPubMed
Bhering, L.L. (2017) Rbio: A tool for biometric and statistical analysis using the R platform. Crop Breeding and Applied Biotechnology 17, 187190.CrossRefGoogle Scholar
Börcsök, Z. and Pásztory, Z. (2021) The role of lignin in wood working processes using elevated temperatures: an abbreviated literature survey. European Journal of Wood and Wood Products 79, 511526.CrossRefGoogle Scholar
Bulgarelli, R.G., de Oliveira Silva, F.M., Bichara, S., Andrade, S.A.L. and Mazzafera, P. (2019) Eucalypts and low phosphorus availability: between responsiveness and efficiency. Plant and Soil 445, 349368.CrossRefGoogle Scholar
Carnus, J.-M., Parrotta, J., Brockerhoff, E., Arbez, M., Jactel, H., Kremer, A., Lamb, D., O’Hara, K. and Walters, B. (2006) Planted forests and biodiversity. Journal of Forestry 104, 6577.CrossRefGoogle Scholar
Carstensen, A., Herdean, A., Schmidt, S.B., Sharma, A., Spetea, C., Pribil, M. and Husted, S. (2018) The impacts of phosphorus deficiency on the photosynthetic electron transport chain. Plant Physiology 177, 271284.CrossRefGoogle ScholarPubMed
Cesarino, I., Araújo, P., Domingues, A.P. Jr. and Mazzafera, P. (2012) An overview of lignin metabolism and its effect on biomass recalcitrance. Revista Brasileira de Botânica 35, 303311.Google Scholar
Chen, L., Auh, C., Chen, F., Cheng, X., Aljoe, H., Dixon, R.A. and Wang, Z. (2002) Lignin deposition and associated changes in anatomy, enzyme activity, gene expression, and ruminal degradability in stems of tall fescue at different developmental stages. Journal of Agriculture and Food Chemistry 50, 55585565.CrossRefGoogle ScholarPubMed
Crous, K.Y., Ósvaldsson, A. and Ellsworth, D.S. (2015) Is phosphorus limiting in a mature Eucalyptus woodland? Phosphorus fertilisation stimulates stem growth. Plant and Soil 391, 293305.CrossRefGoogle Scholar
de Andrade, S.A.L., de Oliveira, V.H. and Mazzafera, P. (2024) Metabolomics of nutrient-deprived forest trees. In Antonio, C. (ed.), Monitoring Forest Damage with Mass Spectrometry-Based Metabolomics Methods. New York, NY: Wiley, pp. 235265.CrossRefGoogle Scholar
de Moraes Gonçalves, J.L., Stape, J.L., Laclau, J-P., Smethurst, P. and Gava, J.L. (2004) Silvicultural effects on the productivity and wood quality of eucalypt plantations. Forest Ecology and Management 193, 4561.CrossRefGoogle Scholar
de Oliveira Silva, F.M., Bulgarelli, R.G., Mubeen, U., Caldana, C., Andrade, S.A.L. and Mazzafera, P. (2022) Low phosphorus induces differential metabolic responses in eucalyptus species improving nutrient use efficiency. Frontiers in Plant Science 13, 989827.CrossRefGoogle Scholar
Fukushima, R.S., Kerley, M.S., Ramos, M.H., Porter, J.H. and Kallenbach, R.L. (2015) Comparison of acetyl bromide lignin with acid detergent lignin and Klason lignin and correlation with in vitro forage degradability. Animal Feed Science and Technology 201, 2537.CrossRefGoogle Scholar
González-Vila, F.J., Almendros, G., del Rio, J.C., Martıín, F., Gutiérrez, A. and Romero, J. (1999) Ease of delignification assessment of wood from different Eucalyptus species by pyrolysis (TMAH)-GC/MS and CP/MAS 13 C-NMR spectrometry. Journal of Analytical Applied Pyrolysis 49, 295305.CrossRefGoogle Scholar
Hacke, U.G., Sperry, J.S. and Pittermann, J. (2000) Drought experience and cavitation resistance in six shrubs from the Great Basin, Utah. Basic and Applied Ecology 1, 3141.CrossRefGoogle Scholar
Hawkesford, M., Horst, W., Kichey, T., Lambers, H., Schjoerring, J., Møller, I.S. and White, P. (2012) Functions of macronutrients. In Marschner, P. (ed.), Marschner’s Mineral Nutrition of Higher Plants. Amsterdam, Netherlands: Elsevier/Academic Press, pp. 135189.CrossRefGoogle Scholar
Horikawa, Y. (2022) Structural diversity of natural cellulose and related applications using delignified wood. Journal of Wood Science 68, 54.CrossRefGoogle Scholar
IUSS Working Group WRB (2015) World Reference Base for Soil Resources 2014, Update 2015. International Soil Classification System for Naming Soils and Creating Legends for Soil Maps. World Soil Resources Reports No. 106, Rome: FAO.Google Scholar
Jucker, T., Sanchez, A.C., Lindsell, J.A., Allen, H.D., Amable, G.S. and Coomes, D.A. (2016) Drivers of aboveground wood production in a lowland tropical forest of West Africa: teasing apart the roles of tree density, tree diversity, soil phosphorus, and historical logging. Ecology and Evolution 6, 40044017.CrossRefGoogle Scholar
Keith, H., Raison, R.J. and Jacobsen, K.L. (1997) Allocation of carbon in a mature eucalypt forest and some effects of soil phosphorus availability. Plant and Soil 196, 8199.CrossRefGoogle Scholar
Lambers, H. (2023) Nutrient-use efficiency. In Rengel, Z., Cakmak, I., White, P.J. (eds.), Marschner’s Mineral Nutrition of Plants. London: Elsevier, pp. 651664.CrossRefGoogle Scholar
Lambers, H. and Plaxton, W.C. (2015) Phosphorus: back to the roots. Annual Plant Reviews 48, 322.Google Scholar
Lambers, H., Shane, M.W., Cramer, M.D., Pearse, S.J. and Veneklaas, E.J. (2006) Root structure and functioning for efficient acquisition of phosphorus: matching morphological and physiological traits. Annals of Botany 98, 693713.CrossRefGoogle ScholarPubMed
Liu, Q., Luo, L. and Zheng, L. (2018) Lignins: biosynthesis and biological functions in plants. International Journal of Molecular Science 19, 335.CrossRefGoogle ScholarPubMed
Lourenço, A., Gominho, J., Marques, A.V. and Pereira, H. (2013) Variation of lignin monomeric composition during kraft pulping of Eucalyptus globulus heartwood and sapwood. Journal of Wood Chemistry and Technology 33, 118.CrossRefGoogle Scholar
Luo, X., Li, Z., Xiao, S., Ye, Z., Nie, X., Zhang, X., Kong, J. and Zhu, L. (2021) Phosphate deficiency enhances cotton resistance to Verticillium dahliae through activating jasmonic acid biosynthesis and phenylpropanoid pathway. Plant Science 302, 110724.CrossRefGoogle ScholarPubMed
Mahood, S.A. and Cable, D.E. (1922) The chemistry of wood. Journal of Industrial and Engineering Chemistry 14, 933934.CrossRefGoogle Scholar
Mclaughlin, M., Alston, A. and Martin, J. (1988) Phosphorus cycling in wheat pasture rotations. I. The source of phosphorus taken up by wheat. Soil Research 26, 323.CrossRefGoogle Scholar
Mokochinski, J.B., Bataglion, G.A., Kiyota, E., de Souza, L.M., Mazzafera, P. and Sawaya, A.C.H.F. (2015) A simple protocol to determine lignin S/G ratio in plants by UHPLC-MS. Analytical and Bioanalytical Chemistry 407, 72217227.CrossRefGoogle ScholarPubMed
Mulligan, D.R. (1988) Phosphorus concentrations and chemical fractions in Eucalyptus seedlings grown for a prolonged period under nutrient-deficient conditions. New Phytologist 110, 479486.CrossRefGoogle Scholar
Netzer, F., Herschbach, C., Oikawa, A., Okazaki, Y., Dubbert, D., Saito, K. and Rennenberg, H. (2018) Seasonal alterations in organic phosphorus metabolism drive the phosphorus economy of annual growth in F. sylvatica Trees on P-Impoverished Soil. Frontiers in Plant Science 9, 723. https://doi.org/10.3389/fpls.2018.00723 CrossRefGoogle ScholarPubMed
Ogden, M., Hoefgen, R., Roessner, U., Persson, S. and Khan, G. (2018) Feeding the walls: how does nutrient availability regulate cell wall composition? International Journal of Molecular Science 19, 2691.CrossRefGoogle ScholarPubMed
Pavinato, P.S., Cherubin, M.R., Soltangheisi, A., Rocha, G.C., Chadwick, D.R. and Jones, D.L. (2020) Revealing soil legacy phosphorus to promote sustainable agriculture in Brazil. Scientific Reports 10, 15615.CrossRefGoogle ScholarPubMed
Raymond, C.A. and Muneri, A. (2000) Effect of fertilizer on wood properties of Eucalyptus globulus . Canadian Journal of Forest Research 30, 136144.CrossRefGoogle Scholar
Rocha, J.H.T., de Moraes Gonçalves, J.L., de Vicente Ferraz, A., Poiati, D.A., Arthur Junior, J.C. and Hubner, A. (2019) Growth dynamics and productivity of an Eucalyptus grandis plantation under omission of N, P, K Ca and Mg over two crop rotation. Forest Ecology Management 447, 158168.CrossRefGoogle Scholar
Tabet, T.A. and Aziz, F.A. (2013) Cellulose microfibril angle in wood and its dynamic mechanical significance. In Van De Ven, T., Godbout, L. (eds.), Cellulose, Fundamental Aspects. London, UK: INTECH - Open Science, pp. 113142.Google Scholar
Thomas, D.S., Montagu, K.D. and Conroy, J.P. (2005) Why does phosphorus limitation increase wood density in Eucalyptus grandis seedlings? Tree Physiology 26, 3542.CrossRefGoogle Scholar
Uhde-Stone, C., Zinn, K.E., Ramirez-Yáñez, M., Li, A., Vance, C.P. and Allan, D.L. (2003) Nylon filter arrays reveal differential gene expression in proteoid roots of white lupin in response to phosphorus deficiency. Plant Physiology 131, 10641079.CrossRefGoogle Scholar
Vaccari, D.A. (2009) Phosphorus: a looming crisis. Scientific American 300, 5459.CrossRefGoogle ScholarPubMed
Valadares, S.V., Neves, J.C.L., Leite, H.G., de Barros, N.F., Cropper, W.P. and Gerber, S. (2020) Predicting phosphorus use efficiency and allocation in eucalypt plantations. Forest Ecology Management 460, 117859.CrossRefGoogle Scholar
van de Wiel, C.C.M., van der Linden, C.G. and Scholten, O.E. (2016) Improving phosphorus use efficiency in agriculture: opportunities for breeding. Euphytica 207, 122.CrossRefGoogle Scholar
van Raij, B., Cantarella, H., Quaggio, J.A. and Furlani, A.M.C. (1996) Recomendações de adubação e calagem para o Estado de São Paulo. Campinas: Instituto Agronômico de Campinas, pp. 285. (Boletim Técnico, 100).Google Scholar
Vanholme, R., Demedts, B., Morreel, K., Ralph, J. and Boerjan, W. (2010) Lignin biosynthesis and structure. Plant Physiology 153, 895905.CrossRefGoogle ScholarPubMed
Veneklaas, E.J., Lambers, H., Bragg, J., Finnegan, P.M., Lovelock, C.E., Plaxton, W.C., Price, C.A., Scheible, W.-R.R., Shane, M.W., White, P.J. and Raven, J.A. (2012) Opportunities for improving phosphorus-use efficiency in crop plants. New Phytologist 195, 306320.CrossRefGoogle ScholarPubMed
Vicentini, R., Bottcher, A., Brito, M.D.S., dos Santos, A.B., Creste, S., Landell, M.G.D.A., Cesarino, I. and Mazzafera, P. (2015) Large-scale transcriptome analysis of two sugarcane genotypes contrasting for lignin content. PLoS One 10, e0134909.CrossRefGoogle Scholar
Warren, C.R. (2011) How does P affect photosynthesis and metabolite profiles of Eucalyptus globulus? Tree Physiology 31, 727739.CrossRefGoogle Scholar
White, P.J. and Hammond, J.P. (2008) Phosphorus nutrition of terrestrial plants. In White, P.J., Hammond, J.P. (eds.), The Ecophysiology of Plant-Phosphorus Interactions. Dordrecht, the Netherlands: Springer, pp. 5181.CrossRefGoogle Scholar
Xu, D., Dell, B., Malajczuk, N. and Gong, M. (2002) Effects of P fertilisation on productivity and nutrient accumulation in a Eucalyptus grandis × E. urophylla plantation in southern China. Forest Ecology and Management 161, 89100. https://doi.org/10.1016/S0378-1127(01)00485-6 CrossRefGoogle Scholar
Xu, X., Zhu, T., Nikonorova, N. and de Smet, I. (2019) Phosphorylation-mediated signalling in plants. Annual Plant Reviews Online 2, 909932.CrossRefGoogle Scholar
Yoo, C.G., Dumitrache, A., Muchero, W., Natzke, J., Akinosho, H., Li, M., Sykes, R.W., Brown, S.D., Davison, B., Tuskan, G.A. and Pu, Y. (2018) Significance of lignin S/G ratio in biomass recalcitrance of Populus trichocarpa variants for bioethanol production. ACS Sustain Chem Eng 6, 21622168.CrossRefGoogle Scholar
Zhang, W., Ma, W., Ji, Y., Fan, M., Oenema, O. and Zhang, F. (2008) Efficiency, economics, and environmental implications of phosphorus resource use and the fertilizer industry in China. Nutr Cycl Agroecosyst 80, 131144.CrossRefGoogle Scholar
Figure 0

Figure 1. Schematic presentation of significant changes in nutrient concentrations in tissues of five Eucalyptus species. The blue arrow up indicates a significant increase of the nutrient in the low P treatment in relation to the sufficient P treatment, and the red down arrows indicate a significant decrease.

Figure 1

Figure 2. Phosphorus concentrations in different tissues of five eucalyptus species subjected to low and sufficient P. Lowercase letters indicate statistical differences (p < 0.05, Tukey’s test) among species for the same P treatment, and asterisks indicate statistical differences between P treatments within the same species.

Figure 2

Figure 3. Dry mass of different tissues of five eucalyptus species subjected to low and sufficient P. Lowercase letters indicate statistical differences (p < 0.05, Tukey’s test) among species for the same P treatment, and an asterisk indicates statistical differences between P treatments within the same species.

Figure 3

Figure 4. Photosynthesis (a), stomatal conductance (b), and leaf internal CO2 concentration of different tissues of five eucalyptus species. Lowercase letters indicate statistical differences (p < 0.05, Tukey’s test) among species for the same P treatment, and asterisk indicates statistical differences between P treatments in the same species.

Figure 4

Figure 5. Wood density (a), cellulose (b), lignin (c) concentrations, and S/G ratios in the wood of five eucalyptus species subjected to low and sufficient P. Small letters indicate statistical differences (p < 0.05, Tukey’s test) among species for the same P treatment, and asterisk indicates statistical differences between P treatments within the same species.

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