Yingying Hu, Man Zhang, Kangqi Wang, Peipei Tan, Si Jing, Wu Han, Shuwei Wang, Kaina Zhang, Xiaoming Zhao, Xiaohong Yang, Yi Wang
�
�
In graminaceous plants, nodes play vital roles in nutrient allocation, especially for preferential nutrient distribution to developing leaves and reproductive organs. However, the molecular mechanisms underlying this distribution remain poorly understood.
�
In this study, we identified a transporter named ZmNPF7.10 that is involved in potassium (K) and nitrogen (N) distribution in maize nodes. In Xenopus oocytes, ZmNPF7.10 showed NO3− and K+ transport activity in a pH-dependent manner. ZmNPF7.10 is predominantly expressed in the nodes at the reproductive growth stage, and preferentially expressed in the xylem parenchyma cells of enlarged vascular bundles (EVBs) in nodes. Disruption of ZmNPF7.10 resulted in the decline of K and N in leaves, but accumulation of K and N in nodes, suggesting ZmNPF7.10 conducts K and N distribution from nodes to leaves in maize.
�
We identified a natural variant of 7.1-kb InDel in the promoter region that was significantly associated with ZmNPF7.10 transcript level in nodes, leaf K and N concentration, as well as grain yield.
�
These findings demonstrate that ZmNPF7.10 functions as a dual role transporter that mediates K and N distribution in nodes. This study provides important insights into the molecular mechanisms of nutrient distribution in maize.
�
{"title":"ZmNPF7.10 confers potassium and nitrogen distribution from node to leaf in maize","authors":"Yingying Hu, Man Zhang, Kangqi Wang, Peipei Tan, Si Jing, Wu Han, Shuwei Wang, Kaina Zhang, Xiaoming Zhao, Xiaohong Yang, Yi Wang","doi":"10.1111/nph.20422","DOIUrl":"https://doi.org/10.1111/nph.20422","url":null,"abstract":"<p>\u0000</p><ul>\u0000<li>In graminaceous plants, nodes play vital roles in nutrient allocation, especially for preferential nutrient distribution to developing leaves and reproductive organs. However, the molecular mechanisms underlying this distribution remain poorly understood.</li>\u0000<li>In this study, we identified a transporter named ZmNPF7.10 that is involved in potassium (K) and nitrogen (N) distribution in maize nodes. In <i>Xenopus</i> oocytes, ZmNPF7.10 showed NO<sub>3</sub><sup>−</sup> and K<sup>+</sup> transport activity in a pH-dependent manner. <i>ZmNPF7.10</i> is predominantly expressed in the nodes at the reproductive growth stage, and preferentially expressed in the xylem parenchyma cells of enlarged vascular bundles (EVBs) in nodes. Disruption of <i>ZmNPF7.10</i> resulted in the decline of K and N in leaves, but accumulation of K and N in nodes, suggesting ZmNPF7.10 conducts K and N distribution from nodes to leaves in maize.</li>\u0000<li>We identified a natural variant of 7.1-kb InDel in the promoter region that was significantly associated with <i>ZmNPF7.10</i> transcript level in nodes, leaf K and N concentration, as well as grain yield.</li>\u0000<li>These findings demonstrate that ZmNPF7.10 functions as a dual role transporter that mediates K and N distribution in nodes. This study provides important insights into the molecular mechanisms of nutrient distribution in maize.</li>\u0000</ul><p></p>","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"16 1","pages":""},"PeriodicalIF":9.4,"publicationDate":"2025-01-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"143057032","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Santiago Priego-Cubero, Youming Liu, Tomonobu Toyomasu, Michael Gigl, Yuto Hasegawa, Hideaki Nojiri, Corinna Dawid, Kazunori Okada, Claude Becker
<h2> Introduction</h2>�<h3> Biosynthetic gene clusters and their evolution</h3>�<p>With more and more plant reference genome assemblies becoming available, biosynthetic gene clusters (BGCs), i.e., the co-localization of often phylogenetically unrelated genes that participate in the same biosynthetic cascade of specialized metabolites, have emerged as a common feature of genomic organization in plants (Polturak <i>et al</i>., <span>2022b</span>). BGCs are postulated to confer evolutionary advantages because they facilitate coordinated gene expression, enable the reliable coinheritance of genes involved in the same metabolic pathway (thereby preventing the accumulation of toxic intermediates), or facilitate the formation of metabolons (Nützmann <i>et al</i>., <span>2016</span>). However, the mechanisms by which such nonorthologous genes become localized in the same genomic region and act in the same biosynthetic pathway are still poorly understood. Currently, the most common model proposes that they have formed through a series of events that is driven by both positive- and negative-selection pressure, starting with gene duplication, followed by neofunctionalization, and ultimately relocation. In some cases, this process appears to have been mediated by transposable elements (Polturak <i>et al</i>., <span>2022b</span>; Smit & Lichman, <span>2022</span>).</p>�<h3> Biological functions of rice phytoalexins, labdane-related diterpenoids and momilactones</h3>�<p>Phytoalexins are low-molecular-mass specialized plant metabolites that are often produced under biotic and abiotic stress conditions (Ahuja <i>et al</i>., <span>2012</span>). In rice (<i>Oryza sativa</i>), the major phytoalexins are a group of labdane-related diterpenoids (reviewed in Toyomasu <i>et al</i>., <span>2020</span>), which derive from the cyclization of geranylgeranyl diphosphate (GGPP) into <i>ent</i>, <i>syn</i>, or normal stereoisomers of copalyl diphosphate (CDP) by the class II diterpene synthases Copalyl Diphosphate Synthases (CPSs). The biosynthesis of these metabolites has evolved from that of gibberellins (GAs), <i>ent</i> labdane-related diterpenoids themselves, through duplication and neofunctionalization of core biosynthetic enzymes (Zi <i>et al</i>., <span>2014</span>). Several <i>ent</i> and <i>syn</i> (but not normal) rice labdane-related diterpenoids have been identified, including momilactones A and B, phytocassanes A to F, and oryzalexins (A to F, and S) (Zi <i>et al</i>., <span>2014</span>; Toyomasu <i>et al</i>., <span>2020</span>). Notably, momilactone A and, more prominently, momilactone B have a strong allelopathic activity, that is they inhibit the germination and growth of nearby plants upon being released by the rice plants into the soil (Kato <i>et al</i>., <span>1973</span>; Kato-Noguchi <i>et al</i>., <span>2010</span>; Serra Serra <i>et al</i>., <span>2021</span>). Both compounds accumulate in rice husks but are also exuded from the roots (Kato-Noguc
{"title":"Evolution and diversification of the momilactone biosynthetic gene cluster in the genus Oryza","authors":"Santiago Priego-Cubero, Youming Liu, Tomonobu Toyomasu, Michael Gigl, Yuto Hasegawa, Hideaki Nojiri, Corinna Dawid, Kazunori Okada, Claude Becker","doi":"10.1111/nph.20416","DOIUrl":"https://doi.org/10.1111/nph.20416","url":null,"abstract":"<h2> Introduction</h2>\u0000<h3> Biosynthetic gene clusters and their evolution</h3>\u0000<p>With more and more plant reference genome assemblies becoming available, biosynthetic gene clusters (BGCs), i.e., the co-localization of often phylogenetically unrelated genes that participate in the same biosynthetic cascade of specialized metabolites, have emerged as a common feature of genomic organization in plants (Polturak <i>et al</i>., <span>2022b</span>). BGCs are postulated to confer evolutionary advantages because they facilitate coordinated gene expression, enable the reliable coinheritance of genes involved in the same metabolic pathway (thereby preventing the accumulation of toxic intermediates), or facilitate the formation of metabolons (Nützmann <i>et al</i>., <span>2016</span>). However, the mechanisms by which such nonorthologous genes become localized in the same genomic region and act in the same biosynthetic pathway are still poorly understood. Currently, the most common model proposes that they have formed through a series of events that is driven by both positive- and negative-selection pressure, starting with gene duplication, followed by neofunctionalization, and ultimately relocation. In some cases, this process appears to have been mediated by transposable elements (Polturak <i>et al</i>., <span>2022b</span>; Smit & Lichman, <span>2022</span>).</p>\u0000<h3> Biological functions of rice phytoalexins, labdane-related diterpenoids and momilactones</h3>\u0000<p>Phytoalexins are low-molecular-mass specialized plant metabolites that are often produced under biotic and abiotic stress conditions (Ahuja <i>et al</i>., <span>2012</span>). In rice (<i>Oryza sativa</i>), the major phytoalexins are a group of labdane-related diterpenoids (reviewed in Toyomasu <i>et al</i>., <span>2020</span>), which derive from the cyclization of geranylgeranyl diphosphate (GGPP) into <i>ent</i>, <i>syn</i>, or normal stereoisomers of copalyl diphosphate (CDP) by the class II diterpene synthases Copalyl Diphosphate Synthases (CPSs). The biosynthesis of these metabolites has evolved from that of gibberellins (GAs), <i>ent</i> labdane-related diterpenoids themselves, through duplication and neofunctionalization of core biosynthetic enzymes (Zi <i>et al</i>., <span>2014</span>). Several <i>ent</i> and <i>syn</i> (but not normal) rice labdane-related diterpenoids have been identified, including momilactones A and B, phytocassanes A to F, and oryzalexins (A to F, and S) (Zi <i>et al</i>., <span>2014</span>; Toyomasu <i>et al</i>., <span>2020</span>). Notably, momilactone A and, more prominently, momilactone B have a strong allelopathic activity, that is they inhibit the germination and growth of nearby plants upon being released by the rice plants into the soil (Kato <i>et al</i>., <span>1973</span>; Kato-Noguchi <i>et al</i>., <span>2010</span>; Serra Serra <i>et al</i>., <span>2021</span>). Both compounds accumulate in rice husks but are also exuded from the roots (Kato-Noguc","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"10 1","pages":""},"PeriodicalIF":9.4,"publicationDate":"2025-01-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"143056344","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Xiulin Gao, Charles D. Koven, Marcos Longo, Zachary Robbins, Polly Thornton, Alex Hall, Samuel Levis, Stefan Rahimi, Chonggang Xu, Lara M. Kueppers
<h2> Introduction</h2>�<p>Grasslands cover > 30% of the Earth surface; therefore, accurately representing grassland ecosystems in Earth System Models (ESMs) is important for understanding vegetation–climate–fire feedbacks (Blair <i>et al</i>., <span>2014</span>). Grasslands also store about one-third of global terrestrial carbon stocks, mostly in the form of soil organic matter, which may be more stable under changing climate and shifting disturbance regimes than living biomass (Bai & Cotrufo, <span>2022</span>; Wilcox <i>et al</i>., <span>2023</span>). Grasslands are one of the predominant vegetation types in arid and semiarid regions where tree cover is limited by climate and recurrent disturbances (Anderson, <span>2006</span>). Persistence of grasses in ecosystems such as grasslands and savannas depends on just-enough precipitation and periodic disturbances to prevent woody plant encroachment and maintain a dynamic equilibrium (Scholes & Archer, <span>1997</span>; Marañón <i>et al</i>., <span>2009</span>). However, anticipated changes in the frequency and intensity of precipitation extremes and fire disturbances will likely alter species composition and thus ecosystem structure and carbon dynamics in grasslands (Staver <i>et al</i>., <span>2011</span>; Yu <i>et al</i>., <span>2017</span>; D'Onofrio <i>et al</i>., <span>2019</span>). Yet, representing change in these grassy ecosystems in ESMs remains a modeling challenge due to the complexity introduced by climate–vegetation–fire feedbacks and limited investment in simulating herbaceous communities (Beckage <i>et al</i>., <span>2009</span>, Dantas <i>et al</i>., <span>2016</span>, Holdo & Nippert, <span>2023</span>).</p>�<p>In the last decade, dynamic vegetation demography models (VDMs) that capture size-dependent growth, mortality, and competition for water, nutrients and light have been a focus of development by the ESM community to better predict the role of vegetation dynamics on global carbon cycles (Fisher <i>et al</i>., <span>2018</span>). They are also useful tools for understanding the local and regional drivers of community structure and ecosystem function. However, most vegetation demographic models (e.g. LPJ-GUESS, ED2, and FATES but see aDGVM) were originally developed for closed-canopy forests with most model applications hitherto focused on tree-dominated systems, resulting in less developed model processes and poorly calibrated model parameters for grass plant functional types (PFTs) and open ecosystems (Sitch <i>et al</i>., <span>2003</span>; Medvigy <i>et al</i>., <span>2009</span>; Moncrieff <i>et al</i>., <span>2014</span>; Koven <i>et al</i>., <span>2020</span>). One of the fundamental differences between trees and grasses is the size-dependent carbon allocation to different plant structures (Niklas, <span>2004</span>), which is important for understanding plant–environment interactions and species competition (Shipley & Meziane, <span>2002</span>; Metcal
{"title":"California annual grass phenology and allometry influence ecosystem dynamics and fire regime in a vegetation demography model","authors":"Xiulin Gao, Charles D. Koven, Marcos Longo, Zachary Robbins, Polly Thornton, Alex Hall, Samuel Levis, Stefan Rahimi, Chonggang Xu, Lara M. Kueppers","doi":"10.1111/nph.20421","DOIUrl":"https://doi.org/10.1111/nph.20421","url":null,"abstract":"<h2> Introduction</h2>\u0000<p>Grasslands cover > 30% of the Earth surface; therefore, accurately representing grassland ecosystems in Earth System Models (ESMs) is important for understanding vegetation–climate–fire feedbacks (Blair <i>et al</i>., <span>2014</span>). Grasslands also store about one-third of global terrestrial carbon stocks, mostly in the form of soil organic matter, which may be more stable under changing climate and shifting disturbance regimes than living biomass (Bai & Cotrufo, <span>2022</span>; Wilcox <i>et al</i>., <span>2023</span>). Grasslands are one of the predominant vegetation types in arid and semiarid regions where tree cover is limited by climate and recurrent disturbances (Anderson, <span>2006</span>). Persistence of grasses in ecosystems such as grasslands and savannas depends on just-enough precipitation and periodic disturbances to prevent woody plant encroachment and maintain a dynamic equilibrium (Scholes & Archer, <span>1997</span>; Marañón <i>et al</i>., <span>2009</span>). However, anticipated changes in the frequency and intensity of precipitation extremes and fire disturbances will likely alter species composition and thus ecosystem structure and carbon dynamics in grasslands (Staver <i>et al</i>., <span>2011</span>; Yu <i>et al</i>., <span>2017</span>; D'Onofrio <i>et al</i>., <span>2019</span>). Yet, representing change in these grassy ecosystems in ESMs remains a modeling challenge due to the complexity introduced by climate–vegetation–fire feedbacks and limited investment in simulating herbaceous communities (Beckage <i>et al</i>., <span>2009</span>, Dantas <i>et al</i>., <span>2016</span>, Holdo & Nippert, <span>2023</span>).</p>\u0000<p>In the last decade, dynamic vegetation demography models (VDMs) that capture size-dependent growth, mortality, and competition for water, nutrients and light have been a focus of development by the ESM community to better predict the role of vegetation dynamics on global carbon cycles (Fisher <i>et al</i>., <span>2018</span>). They are also useful tools for understanding the local and regional drivers of community structure and ecosystem function. However, most vegetation demographic models (e.g. LPJ-GUESS, ED2, and FATES but see aDGVM) were originally developed for closed-canopy forests with most model applications hitherto focused on tree-dominated systems, resulting in less developed model processes and poorly calibrated model parameters for grass plant functional types (PFTs) and open ecosystems (Sitch <i>et al</i>., <span>2003</span>; Medvigy <i>et al</i>., <span>2009</span>; Moncrieff <i>et al</i>., <span>2014</span>; Koven <i>et al</i>., <span>2020</span>). One of the fundamental differences between trees and grasses is the size-dependent carbon allocation to different plant structures (Niklas, <span>2004</span>), which is important for understanding plant–environment interactions and species competition (Shipley & Meziane, <span>2002</span>; Metcal","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"23 1","pages":""},"PeriodicalIF":9.4,"publicationDate":"2025-01-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"143056873","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
H2S is a well-known gaseous signaling molecule that plays important roles in plant response to biotic stresses. Pseudomonas syringae pv tomato (Pst) could cause enormous loss, while whether H2S could modulate plant defense against Pst is still unclear.
�
By CRISPR/Cas9, the Sldcd1 gene editing mutant showed reduced endogenous H2S content and attenuated resistance, whereas treatment with exogenous H2S could enhance the resistance. A transcription factor, SlWRKY71, was screened and identified to promote the transcription of SlDCD1 via yeast one-hybrid, dual-luciferase reporter system, electrophoretic mobility shift assays, and transient overexpression.
�
Here, it was found that exogenous H2S relieved the symptoms of bacterial speck disease in tomato leaves, conferring tolerance to Pst. DC3000, and the expression of the H2S-producing enzyme SlDCD1 was significantly induced. The Slwrky71 mutant also showed reduced defense in tomato leaves against Pst. DC3000, whereas SlWRKY71-OE tomato leaves showed increased tolerance. Transient overexpression of SlDCD1 in the context of Slwrky71 with exogenous H2S treatment has stronger resistance, and the overexpression of SlWRKY71 in the context of Sldcd1 showed relatively weak disease resistance, and with the addition of H2S enhanced the effect.
�
Therefore, we concluded that SlWRKY71 could activate SlDCD1 expression and promote endogenous H2S production, thereby improving tomato leaves resistance to Pst. DC3000.
�
{"title":"A transcription factor SlWRKY71 activated the H2S generating enzyme SlDCD1 enhancing the response to Pseudomonas syringae pv DC3000 in tomato leaves","authors":"Yu-Qi Zhao, Chen Sun, Kang-Di Hu, Yue Yu, Zhi Liu, Ying-Chun Song, Ren-Jie Xiong, Yue Ma, Hua Zhang, Gai-Fang Yao","doi":"10.1111/nph.20431","DOIUrl":"https://doi.org/10.1111/nph.20431","url":null,"abstract":"<p>\u0000</p><ul>\u0000<li>H<sub>2</sub>S is a well-known gaseous signaling molecule that plays important roles in plant response to biotic stresses. <i>Pseudomonas syringae</i> pv tomato (<i>Pst</i>) could cause enormous loss, while whether H<sub>2</sub>S could modulate plant defense against <i>Pst</i> is still unclear.</li>\u0000<li>By CRISPR/Cas9, the <i>Sldcd1</i> gene editing mutant showed reduced endogenous H<sub>2</sub>S content and attenuated resistance, whereas treatment with exogenous H<sub>2</sub>S could enhance the resistance. A transcription factor, SlWRKY71, was screened and identified to promote the transcription of <i>SlDCD1</i> via yeast one-hybrid, dual-luciferase reporter system, electrophoretic mobility shift assays, and transient overexpression.</li>\u0000<li>Here, it was found that exogenous H<sub>2</sub>S relieved the symptoms of bacterial speck disease in tomato leaves, conferring tolerance to <i>Pst</i>. DC3000, and the expression of the H<sub>2</sub>S-producing enzyme <i>SlDCD1</i> was significantly induced. The <i>Slwrky71</i> mutant also showed reduced defense in tomato leaves against <i>Pst</i>. DC3000, whereas <i>SlWRKY71-</i>OE tomato leaves showed increased tolerance. Transient overexpression of <i>SlDCD1</i> in the context of <i>Slwrky71</i> with exogenous H<sub>2</sub>S treatment has stronger resistance, and the overexpression of <i>SlWRKY71</i> in the context of <i>Sldcd1</i> showed relatively weak disease resistance, and with the addition of H<sub>2</sub>S enhanced the effect.</li>\u0000<li>Therefore, we concluded that <i>SlWRKY71</i> could activate <i>SlDCD1</i> expression and promote endogenous H<sub>2</sub>S production, thereby improving tomato leaves resistance to <i>Pst</i>. DC3000.</li>\u0000</ul><p></p>","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"129 1","pages":""},"PeriodicalIF":9.4,"publicationDate":"2025-01-30","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"143057035","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
<h2> Introduction</h2>�<p>There is a general correlation between the chromosomal position of a DNA sequence, the epigenetic state of the chromatin as well as gene activity (Grewal & Moazed, <span>2003</span>; Liu <i>et al</i>., <span>2016</span>). Chromosome arms are euchromatin-enriched, whereas centromeric and pericentromeric regions are heterochromatic in many species (Roudier <i>et al</i>., <span>2009</span>). Euchromatin, which is the decondensed fraction of chromatin, contains mostly active genes (Strahl <i>et al</i>., <span>1999</span>). By contrast, heterochromatin, the condensed chromatin fraction, is poor in genes and gene activity (Fischer <i>et al</i>., <span>2006</span>; Liu <i>et al</i>., <span>2016</span>). The formation and maintenance of the chromatin status is regulated epigenetically by DNA methylation and post-translational histone modifications. Heterochromatin is enriched in hypermethylated DNA and dimethylated histone H3K9 (H3K9me2) (Soppe <i>et al</i>., <span>2002</span>). By contrast, euchromatin is linked with trimethylated H3K4 (H3K4me3) and less C-methylation of DNA.</p>�<p>Position effect variegation (PEV), discovered in the fruit fly <i>Drosophila melanogaster</i> (Gowen & Gay, <span>1934</span>) and humans (Finelli <i>et al</i>., <span>2012</span>), as well as the telomere position effect (TPE), discovered in budding yeast, are examples for possible effects of the chromosomal position on gene expression (Gottschling <i>et al</i>., <span>1990</span>). Genes undergo differential expression in PEV because chromosomal inversions create new heterochromatin–euchromatin borders, and euchromatic genes juxtaposed to heterochromatic regions undergo heterochromatin-induced gene silencing (Hessler, <span>1958</span>; Elgin & Reuter, <span>2013</span>). The impact of the chromosomal position on gene expression is well-studied in the case of the expression of the 45S rDNA loci in <i>Arabidopsis thaliana</i> (Mohannath <i>et al</i>., <span>2016</span>). Also, other studies suggest that changes in gene expression follow the introduction of chromosomal rearrangements, such as inversions or translocations, due to reorganization of large regulatory domains (Naseeb <i>et al</i>., <span>2016</span>). They are also reported to cause the modification of genetic regions adjacent to the breakpoints (Lavington & Kern, <span>2017</span>), the epigenetic environment of translocated and adjacent regions (Wesley & Eanes, <span>1994</span>; Fournier <i>et al</i>., <span>2010</span>), or to cause nuclear reorganization (Fournier <i>et al</i>., <span>2010</span>; Harewood <i>et al</i>., <span>2010</span>). However, it is unknown whether the reported gene expression and epigenetic changes occurred immediately after the introduction of the chromosomal rearrangements or whether they were established over time in subsequent generations.</p>�<p>To unravel the effect of chromosomal inversions on the epigenetic state of chromatin and t
{"title":"Epigenetic state and gene expression remain stable after CRISPR/Cas-mediated chromosomal inversions","authors":"Solmaz Khosravi, Rebecca Hinrichs, Michelle Rönspies, Reza Haghi, Holger Puchta, Andreas Houben","doi":"10.1111/nph.20403","DOIUrl":"https://doi.org/10.1111/nph.20403","url":null,"abstract":"<h2> Introduction</h2>\u0000<p>There is a general correlation between the chromosomal position of a DNA sequence, the epigenetic state of the chromatin as well as gene activity (Grewal & Moazed, <span>2003</span>; Liu <i>et al</i>., <span>2016</span>). Chromosome arms are euchromatin-enriched, whereas centromeric and pericentromeric regions are heterochromatic in many species (Roudier <i>et al</i>., <span>2009</span>). Euchromatin, which is the decondensed fraction of chromatin, contains mostly active genes (Strahl <i>et al</i>., <span>1999</span>). By contrast, heterochromatin, the condensed chromatin fraction, is poor in genes and gene activity (Fischer <i>et al</i>., <span>2006</span>; Liu <i>et al</i>., <span>2016</span>). The formation and maintenance of the chromatin status is regulated epigenetically by DNA methylation and post-translational histone modifications. Heterochromatin is enriched in hypermethylated DNA and dimethylated histone H3K9 (H3K9me2) (Soppe <i>et al</i>., <span>2002</span>). By contrast, euchromatin is linked with trimethylated H3K4 (H3K4me3) and less C-methylation of DNA.</p>\u0000<p>Position effect variegation (PEV), discovered in the fruit fly <i>Drosophila melanogaster</i> (Gowen & Gay, <span>1934</span>) and humans (Finelli <i>et al</i>., <span>2012</span>), as well as the telomere position effect (TPE), discovered in budding yeast, are examples for possible effects of the chromosomal position on gene expression (Gottschling <i>et al</i>., <span>1990</span>). Genes undergo differential expression in PEV because chromosomal inversions create new heterochromatin–euchromatin borders, and euchromatic genes juxtaposed to heterochromatic regions undergo heterochromatin-induced gene silencing (Hessler, <span>1958</span>; Elgin & Reuter, <span>2013</span>). The impact of the chromosomal position on gene expression is well-studied in the case of the expression of the 45S rDNA loci in <i>Arabidopsis thaliana</i> (Mohannath <i>et al</i>., <span>2016</span>). Also, other studies suggest that changes in gene expression follow the introduction of chromosomal rearrangements, such as inversions or translocations, due to reorganization of large regulatory domains (Naseeb <i>et al</i>., <span>2016</span>). They are also reported to cause the modification of genetic regions adjacent to the breakpoints (Lavington & Kern, <span>2017</span>), the epigenetic environment of translocated and adjacent regions (Wesley & Eanes, <span>1994</span>; Fournier <i>et al</i>., <span>2010</span>), or to cause nuclear reorganization (Fournier <i>et al</i>., <span>2010</span>; Harewood <i>et al</i>., <span>2010</span>). However, it is unknown whether the reported gene expression and epigenetic changes occurred immediately after the introduction of the chromosomal rearrangements or whether they were established over time in subsequent generations.</p>\u0000<p>To unravel the effect of chromosomal inversions on the epigenetic state of chromatin and t","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"124 1","pages":""},"PeriodicalIF":9.4,"publicationDate":"2025-01-29","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"143056432","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Kyounghee Lee, Hobin Yoon, Ok-Sun Park, Pil Joon Seo
<h2> Introduction</h2>�<p>Plants possess a remarkable ability to regenerate tissues, which enables the healing of wounds and the induction of <i>de novo</i> organogenesis. <i>In vitro</i> plant tissue culture techniques are based on the regenerative capacity of plants and facilitate the reprogramming of differentiated somatic cells into a new organ or even an entire plant (Sugimoto <i>et al</i>., <span>2010</span>). Differentiated plant tissues are used as explants to generate a pluripotent cell mass, called callus, on auxin-rich callus-inducing medium (CIM) (Ikeuchi <i>et al</i>., <span>2013</span>; Zhai & Xu, <span>2021</span>; Yin <i>et al</i>., <span>2024</span>). Subsequently, the callus undergoes <i>de novo</i> shoot regeneration on cytokinin-rich shoot-inducing medium (SIM) (Che <i>et al</i>., <span>2007</span>). A particular emphasis has been placed on <i>de novo</i> shoot organogenesis because the low shoot regeneration rate frequently limits <i>in vitro</i> plant regeneration in many species (Ijaz <i>et al</i>., <span>2012</span>; Zimik & Arumugam, <span>2017</span>).</p>�<p>Consistent with the fact that <i>de novo</i> shoot regeneration during <i>in vitro</i> tissue culture involves the conversion from callus cells to shoot meristem (Meng <i>et al</i>., <span>2017</span>; Ogura <i>et al</i>., <span>2023</span>), key regulators of shoot apical meristem (SAM) establishment are implicated in <i>de novo</i> shoot regeneration (Ikeuchi <i>et al</i>., <span>2016</span>; Eshed Williams, <span>2021</span>; Mathew & Prasad, <span>2021</span>). The <i>PLETHORA 3</i> (<i>PLT3</i>), <i>PLT5</i>, and <i>PLT7</i> genes, which are expressed in the whole process of plant regeneration, play a particular role in shoot progenitor formation. Upon transferring to SIM, they are specifically expressed in shoot progenitor cells and promote promeristem formation by activating <i>CUP-SHAPED COTYLEDON 1</i> (<i>CUC1</i>) and <i>CUC2</i> (Kareem <i>et al</i>., <span>2015</span>). The CUC1 and CUC2 proteins are involved in promoting <i>SHOOT MERISTEMLESS</i> (<i>STM</i>) expression and polarizing PIN-FORMED 1 (PIN1) localization to initiate shoot meristem development (Hibara <i>et al</i>., <span>2003</span>; Bilsborough <i>et al</i>., <span>2011</span>; Kamiuchi <i>et al</i>., <span>2014</span>; Kareem <i>et al</i>., <span>2015</span>). CUC2 also activates the expression of <i>XYLOGLUCAN ENDOTRANSGLUCOSYLASE</i>/<i>HYDROLASE 9</i> (<i>XTH9</i>) encoding a cell wall-loosening enzyme in nonprogenitor cells and contributes to establishing cell polarity for meristem formation (Varapparambath <i>et al</i>., <span>2022</span>). Additionally, the main cytokinin regulatory axis is linked to the establishment of shoot stem cells in callus. Type-B ARABIDOPSIS RESPONSE REGULATORs (ARRs), positive regulators of cytokinin signaling, directly promote the expression of <i>WUSCHEL</i> (<i>WUS</i>), which unequivocally regulates the formation of the shoot stem cell nic
{"title":"A positive feedback loop of cytokinin signaling ensures efficient de novo shoot regeneration in Arabidopsis","authors":"Kyounghee Lee, Hobin Yoon, Ok-Sun Park, Pil Joon Seo","doi":"10.1111/nph.20409","DOIUrl":"https://doi.org/10.1111/nph.20409","url":null,"abstract":"<h2> Introduction</h2>\u0000<p>Plants possess a remarkable ability to regenerate tissues, which enables the healing of wounds and the induction of <i>de novo</i> organogenesis. <i>In vitro</i> plant tissue culture techniques are based on the regenerative capacity of plants and facilitate the reprogramming of differentiated somatic cells into a new organ or even an entire plant (Sugimoto <i>et al</i>., <span>2010</span>). Differentiated plant tissues are used as explants to generate a pluripotent cell mass, called callus, on auxin-rich callus-inducing medium (CIM) (Ikeuchi <i>et al</i>., <span>2013</span>; Zhai & Xu, <span>2021</span>; Yin <i>et al</i>., <span>2024</span>). Subsequently, the callus undergoes <i>de novo</i> shoot regeneration on cytokinin-rich shoot-inducing medium (SIM) (Che <i>et al</i>., <span>2007</span>). A particular emphasis has been placed on <i>de novo</i> shoot organogenesis because the low shoot regeneration rate frequently limits <i>in vitro</i> plant regeneration in many species (Ijaz <i>et al</i>., <span>2012</span>; Zimik & Arumugam, <span>2017</span>).</p>\u0000<p>Consistent with the fact that <i>de novo</i> shoot regeneration during <i>in vitro</i> tissue culture involves the conversion from callus cells to shoot meristem (Meng <i>et al</i>., <span>2017</span>; Ogura <i>et al</i>., <span>2023</span>), key regulators of shoot apical meristem (SAM) establishment are implicated in <i>de novo</i> shoot regeneration (Ikeuchi <i>et al</i>., <span>2016</span>; Eshed Williams, <span>2021</span>; Mathew & Prasad, <span>2021</span>). The <i>PLETHORA 3</i> (<i>PLT3</i>), <i>PLT5</i>, and <i>PLT7</i> genes, which are expressed in the whole process of plant regeneration, play a particular role in shoot progenitor formation. Upon transferring to SIM, they are specifically expressed in shoot progenitor cells and promote promeristem formation by activating <i>CUP-SHAPED COTYLEDON 1</i> (<i>CUC1</i>) and <i>CUC2</i> (Kareem <i>et al</i>., <span>2015</span>). The CUC1 and CUC2 proteins are involved in promoting <i>SHOOT MERISTEMLESS</i> (<i>STM</i>) expression and polarizing PIN-FORMED 1 (PIN1) localization to initiate shoot meristem development (Hibara <i>et al</i>., <span>2003</span>; Bilsborough <i>et al</i>., <span>2011</span>; Kamiuchi <i>et al</i>., <span>2014</span>; Kareem <i>et al</i>., <span>2015</span>). CUC2 also activates the expression of <i>XYLOGLUCAN ENDOTRANSGLUCOSYLASE</i>/<i>HYDROLASE 9</i> (<i>XTH9</i>) encoding a cell wall-loosening enzyme in nonprogenitor cells and contributes to establishing cell polarity for meristem formation (Varapparambath <i>et al</i>., <span>2022</span>). Additionally, the main cytokinin regulatory axis is linked to the establishment of shoot stem cells in callus. Type-B ARABIDOPSIS RESPONSE REGULATORs (ARRs), positive regulators of cytokinin signaling, directly promote the expression of <i>WUSCHEL</i> (<i>WUS</i>), which unequivocally regulates the formation of the shoot stem cell nic","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"20 1","pages":""},"PeriodicalIF":9.4,"publicationDate":"2025-01-29","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"143056874","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Kristoffer Jonsson, Anne-Lise Routier-Kierzkowska, Rishikesh P. Bhalerao
Plant development depends on growth asymmetry to establish body plans and adapt to environmental stimuli. We explore how plants initiate, propagate, and regulate organ-wide growth asymmetries. External cues, such as light and gravity, and internal signals, including stochastic cellular growth variability, drive these asymmetries. The plant hormone auxin orchestrates growth asymmetry through its distribution and transport. Mechanochemical feedback loops, exemplified by apical hook formation, further amplify growth asymmetries, illustrating the dynamic interplay between biochemical signals and physical forces. Growth asymmetry itself can serve as a continuous cue, influencing subsequent growth decisions. By examining specific cellular programs and their responses to asymmetric cues, we propose that the decision to either amplify or dampen these asymmetries is key to shaping plant organs.
{"title":"The asymmetry engine: how plants harness asymmetries to shape their bodies","authors":"Kristoffer Jonsson, Anne-Lise Routier-Kierzkowska, Rishikesh P. Bhalerao","doi":"10.1111/nph.20413","DOIUrl":"https://doi.org/10.1111/nph.20413","url":null,"abstract":"Plant development depends on growth asymmetry to establish body plans and adapt to environmental stimuli. We explore how plants initiate, propagate, and regulate organ-wide growth asymmetries. External cues, such as light and gravity, and internal signals, including stochastic cellular growth variability, drive these asymmetries. The plant hormone auxin orchestrates growth asymmetry through its distribution and transport. Mechanochemical feedback loops, exemplified by apical hook formation, further amplify growth asymmetries, illustrating the dynamic interplay between biochemical signals and physical forces. Growth asymmetry itself can serve as a continuous cue, influencing subsequent growth decisions. By examining specific cellular programs and their responses to asymmetric cues, we propose that the decision to either amplify or dampen these asymmetries is key to shaping plant organs.","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"84 1","pages":""},"PeriodicalIF":9.4,"publicationDate":"2025-01-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"143050864","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
<div>Bolting, the phase transition from vegetative to reproductive development, is a critical step of flowering plants. Determining the timing of bolting is a pivotal life history trait that has evolved over time to optimize reproductive success across diverse environments (Jung & Müller, <span>2009</span>). In crops like lettuce (<i>Lactuca sativa</i> L.), which is primarily cultivated for its edible rosette leaves, bolting marks the end of vegetative leaf production and the onset of flowering (Van Treuren <i>et al</i>., <span>2012</span>). Premature bolting significantly reduces the biomass of vegetative growth in lettuce. Notably, the initiation of flower signaling causes biochemical changes that lead to the accumulation of latex in the leaves, resulting in an undesirable bitter taste and compromising crop quality (Simonne <i>et al</i>., <span>2002</span>). Therefore, unraveling the regulatory networks governing the vegetative–flowering transition would contribute to developing lettuce cultivars resistant to premature bolting. A new paper by Qi <i>et al</i>., recently published in <i>New Phytologist</i> (<span>2024</span>, doi: 10.1111/nph.20307), identified a key bolting regulator, the LsKN1 (KNOTTED 1) transcription factor, in this process. A natural variation allele of <i>LsKN1</i> can modulate the gibberellin (GA) pathway to delay bolting in modern lettuce. This discovery not only advances our understanding of lettuce bolting but also highlights the potential of leveraging natural genetic diversity to improve crop traits and deal with environmental challenges. <blockquote><p>‘Qi et al.'s research exemplifies the power of leveraging natural genetic diversity to address key agricultural challenges.’</p>�<div></div>�</blockquote>�</div>�<p>The vegetative–flowering transition is regulated by a complex network of genetic and environmental factors. Over the past decade, many genes have been implicated in the control of flowering time in <i>Arabidopsis thaliana</i> (Bouché <i>et al</i>., <span>2016</span>). Investigating homologous genes and their regulatory mechanisms has provided insights into the molecular mechanism of bolting in lettuce (Fukuda <i>et al</i>., <span>2011</span>, <span>2017</span>). However, lettuce has a more complex genome and unique features in terms of vegetable crop traits compared with Arabidopsis. Modern lettuce variants exhibit tremendous morphological variation, especially regarding the rate of transition to flowering (Ryder, <span>1988</span>; Zhang <i>et al</i>., <span>2017</span>). Genetic variation in lettuce not only serves as a crucial resource for breeding and improvement but also offers opportunities to identify key genes for bolting. In this study, Qi <i>et al</i>. generated a segregating population by crossing a crisphead-type cultivar with a stem-type cultivar to map the <i>LsKN1</i> allele. They demonstrate that the activated allele, LsKN1<sup>TP</sup>, resulting from a CACTA-like transposon insertion,
{"title":"When lettuce bolts: natural selection vs artificial selection and beyond","authors":"Dandan Yang, Cao Xu","doi":"10.1111/nph.20402","DOIUrl":"https://doi.org/10.1111/nph.20402","url":null,"abstract":"<div>Bolting, the phase transition from vegetative to reproductive development, is a critical step of flowering plants. Determining the timing of bolting is a pivotal life history trait that has evolved over time to optimize reproductive success across diverse environments (Jung & Müller, <span>2009</span>). In crops like lettuce (<i>Lactuca sativa</i> L.), which is primarily cultivated for its edible rosette leaves, bolting marks the end of vegetative leaf production and the onset of flowering (Van Treuren <i>et al</i>., <span>2012</span>). Premature bolting significantly reduces the biomass of vegetative growth in lettuce. Notably, the initiation of flower signaling causes biochemical changes that lead to the accumulation of latex in the leaves, resulting in an undesirable bitter taste and compromising crop quality (Simonne <i>et al</i>., <span>2002</span>). Therefore, unraveling the regulatory networks governing the vegetative–flowering transition would contribute to developing lettuce cultivars resistant to premature bolting. A new paper by Qi <i>et al</i>., recently published in <i>New Phytologist</i> (<span>2024</span>, doi: 10.1111/nph.20307), identified a key bolting regulator, the LsKN1 (KNOTTED 1) transcription factor, in this process. A natural variation allele of <i>LsKN1</i> can modulate the gibberellin (GA) pathway to delay bolting in modern lettuce. This discovery not only advances our understanding of lettuce bolting but also highlights the potential of leveraging natural genetic diversity to improve crop traits and deal with environmental challenges. <blockquote><p>‘Qi et al.'s research exemplifies the power of leveraging natural genetic diversity to address key agricultural challenges.’</p>\u0000<div></div>\u0000</blockquote>\u0000</div>\u0000<p>The vegetative–flowering transition is regulated by a complex network of genetic and environmental factors. Over the past decade, many genes have been implicated in the control of flowering time in <i>Arabidopsis thaliana</i> (Bouché <i>et al</i>., <span>2016</span>). Investigating homologous genes and their regulatory mechanisms has provided insights into the molecular mechanism of bolting in lettuce (Fukuda <i>et al</i>., <span>2011</span>, <span>2017</span>). However, lettuce has a more complex genome and unique features in terms of vegetable crop traits compared with Arabidopsis. Modern lettuce variants exhibit tremendous morphological variation, especially regarding the rate of transition to flowering (Ryder, <span>1988</span>; Zhang <i>et al</i>., <span>2017</span>). Genetic variation in lettuce not only serves as a crucial resource for breeding and improvement but also offers opportunities to identify key genes for bolting. In this study, Qi <i>et al</i>. generated a segregating population by crossing a crisphead-type cultivar with a stem-type cultivar to map the <i>LsKN1</i> allele. They demonstrate that the activated allele, LsKN1<sup>TP</sup>, resulting from a CACTA-like transposon insertion, ","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"6 1","pages":""},"PeriodicalIF":9.4,"publicationDate":"2025-01-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"143030977","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Philipp Wendering, Gregory M. Andreou, Roosa A. E. Laitinen, Zoran Nikoloski
<h2> Introduction</h2>�<p>Global food security depends on crop yields that are severely threatened by more fluctuating and increasing temperatures – a hallmark of future climate scenarios (Wheeler & von Braun, <span>2013</span>). Ambient temperature affects all aspects of the plant life cycle, from development and growth to reproduction (Casal & Balasubramanian, <span>2019</span>; Zhu <i>et al</i>., <span>2022</span>). Plant responses to temperature changes are most immediately observed at the level of metabolism, followed by changes in gene expression to reestablish homeostasis (Casal & Balasubramanian, <span>2019</span>). Considering that metabolism is tightly linked to plant growth (Meyer <i>et al</i>., <span>2007</span>; Pyl <i>et al</i>., <span>2012</span>), metabolic changes can facilitate rapid plant adaptation to temperature changes at a minimal growth penalty. While we understand that metabolic flexibility is achieved by rerouting nutrient flows within the plant metabolic network, we know little about (1) which enzymes limit plant metabolic changes in temperature? And (2) how these limits emerge from temperature-dependent biochemical constraints under which the metabolic network operates? The availability of a mathematical model that can accurately predict genetic and molecular determinants that affect plant temperature responses will address both questions.</p>�<p>A few metabolic models have already considered the effect of temperature on processes that directly affect plant growth (Clark <i>et al</i>., <span>2020</span>; Wendering & Nikoloski, <span>2023</span>). For instance, the classical mathematical model of C<sub>3</sub> photosynthesis (Farquhar <i>et al</i>., <span>1980</span>) – an indispensable metabolic pathway for photoautotrophic growth – has been extended to predict effects of temperature changes in net CO<sub>2</sub> assimilation (Scafaro <i>et al</i>., <span>2023</span>). However, this and other modeling efforts addressing responses of metabolic pathways to temperature change (Kannan <i>et al</i>., <span>2019</span>; Herrmann <i>et al</i>., <span>2020</span>; Inoue & Noguchi, <span>2021</span>) consider only a few, lumped metabolic reactions. As a result, these models cannot be used to identify all gene targets modulating plant thermal responses, thus restricting their capacity to predict mitigation strategies. In addition, they cannot be used to make predictions about plant growth responses, due to the limited focus on one selected metabolic pathway. By contrast, genome-scale metabolic models, representing the entirety of known metabolic reactions in a system, have been successfully used to predict growth-related phenotypes and genetic engineering strategies for their modulation using approaches from the constraint-based modeling framework (Herrmann <i>et al</i>., <span>2019</span>; Tong <i>et al</i>., <span>2023</span>; Wendering & Nikoloski, <span>2023</span>). These models allow the design of r
{"title":"Metabolic modeling identifies determinants of thermal growth responses in Arabidopsis thaliana","authors":"Philipp Wendering, Gregory M. Andreou, Roosa A. E. Laitinen, Zoran Nikoloski","doi":"10.1111/nph.20420","DOIUrl":"https://doi.org/10.1111/nph.20420","url":null,"abstract":"<h2> Introduction</h2>\u0000<p>Global food security depends on crop yields that are severely threatened by more fluctuating and increasing temperatures – a hallmark of future climate scenarios (Wheeler & von Braun, <span>2013</span>). Ambient temperature affects all aspects of the plant life cycle, from development and growth to reproduction (Casal & Balasubramanian, <span>2019</span>; Zhu <i>et al</i>., <span>2022</span>). Plant responses to temperature changes are most immediately observed at the level of metabolism, followed by changes in gene expression to reestablish homeostasis (Casal & Balasubramanian, <span>2019</span>). Considering that metabolism is tightly linked to plant growth (Meyer <i>et al</i>., <span>2007</span>; Pyl <i>et al</i>., <span>2012</span>), metabolic changes can facilitate rapid plant adaptation to temperature changes at a minimal growth penalty. While we understand that metabolic flexibility is achieved by rerouting nutrient flows within the plant metabolic network, we know little about (1) which enzymes limit plant metabolic changes in temperature? And (2) how these limits emerge from temperature-dependent biochemical constraints under which the metabolic network operates? The availability of a mathematical model that can accurately predict genetic and molecular determinants that affect plant temperature responses will address both questions.</p>\u0000<p>A few metabolic models have already considered the effect of temperature on processes that directly affect plant growth (Clark <i>et al</i>., <span>2020</span>; Wendering & Nikoloski, <span>2023</span>). For instance, the classical mathematical model of C<sub>3</sub> photosynthesis (Farquhar <i>et al</i>., <span>1980</span>) – an indispensable metabolic pathway for photoautotrophic growth – has been extended to predict effects of temperature changes in net CO<sub>2</sub> assimilation (Scafaro <i>et al</i>., <span>2023</span>). However, this and other modeling efforts addressing responses of metabolic pathways to temperature change (Kannan <i>et al</i>., <span>2019</span>; Herrmann <i>et al</i>., <span>2020</span>; Inoue & Noguchi, <span>2021</span>) consider only a few, lumped metabolic reactions. As a result, these models cannot be used to identify all gene targets modulating plant thermal responses, thus restricting their capacity to predict mitigation strategies. In addition, they cannot be used to make predictions about plant growth responses, due to the limited focus on one selected metabolic pathway. By contrast, genome-scale metabolic models, representing the entirety of known metabolic reactions in a system, have been successfully used to predict growth-related phenotypes and genetic engineering strategies for their modulation using approaches from the constraint-based modeling framework (Herrmann <i>et al</i>., <span>2019</span>; Tong <i>et al</i>., <span>2023</span>; Wendering & Nikoloski, <span>2023</span>). These models allow the design of r","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"13 1","pages":""},"PeriodicalIF":9.4,"publicationDate":"2025-01-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"143030729","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
Shan Huang, Sasa Zhang, Xuejing Ma, Xin Zheng, Yaojia Liu, Qinghua Zhu, Xiaoqin Luo, Jilai Cui, Chuankui Song
�
�
Glycosylation is a key modification that affects secondary metabolites under stress and is influenced by glycinebetaine (GB) to regulate plant stress tolerance. However, the complexity and detection challenges of glycosides hinder our understanding of the regulatory mechanisms of their metabolic interaction with GB during stress.
�
A glycoside-specific metabolomic approach utilizing cone voltage-induced in-source dissociation was developed, achieving precise and high-throughput detection of glycosides in tea plants by narrowing the target ion range by 94.3%. Combined with enzyme activity assays, exogenous spraying, and gene silencing, this approach helps investigate the role of GB-glycosides cascade effect in enhancing cold tolerance of tea plants.
�
Our method demonstrated that silencing betaine aldehyde dehydrogenase (CsBADH1) in tea plants altered 60 glycoside ions while reducing GB content and cold tolerance, indicating that glycosylation affects GB-mediated cold tolerance. By combining glycoside-specific with conventional metabolomics, isorhoifolin, a GB-regulated cold response metabolite was discovered, and its precursor apigenin was found to be a new cold tolerance metabolite that enhanced cold tolerance by scavenging reactive oxygen species.
�
This study reveals a new mechanism by which GB mediated cold tolerance in tea plants through regulating apigenin glycosylation, broadening our understanding of the role of glycosylation in plant cold tolerance.
�
{"title":"Glycoside-specific metabolomics reveals the novel mechanism of glycinebetaine-induced cold tolerance by regulating apigenin glycosylation in tea plants","authors":"Shan Huang, Sasa Zhang, Xuejing Ma, Xin Zheng, Yaojia Liu, Qinghua Zhu, Xiaoqin Luo, Jilai Cui, Chuankui Song","doi":"10.1111/nph.20410","DOIUrl":"https://doi.org/10.1111/nph.20410","url":null,"abstract":"<p>\u0000</p><ul>\u0000<li>Glycosylation is a key modification that affects secondary metabolites under stress and is influenced by glycinebetaine (GB) to regulate plant stress tolerance. However, the complexity and detection challenges of glycosides hinder our understanding of the regulatory mechanisms of their metabolic interaction with GB during stress.</li>\u0000<li>A glycoside-specific metabolomic approach utilizing cone voltage-induced in-source dissociation was developed, achieving precise and high-throughput detection of glycosides in tea plants by narrowing the target ion range by 94.3%. Combined with enzyme activity assays, exogenous spraying, and gene silencing, this approach helps investigate the role of GB-glycosides cascade effect in enhancing cold tolerance of tea plants.</li>\u0000<li>Our method demonstrated that silencing betaine aldehyde dehydrogenase (<i>CsBADH1</i>) in tea plants altered 60 glycoside ions while reducing GB content and cold tolerance, indicating that glycosylation affects GB-mediated cold tolerance. By combining glycoside-specific with conventional metabolomics, isorhoifolin, a GB-regulated cold response metabolite was discovered, and its precursor apigenin was found to be a new cold tolerance metabolite that enhanced cold tolerance by scavenging reactive oxygen species.</li>\u0000<li>This study reveals a new mechanism by which GB mediated cold tolerance in tea plants through regulating apigenin glycosylation, broadening our understanding of the role of glycosylation in plant cold tolerance.</li>\u0000</ul><p></p>","PeriodicalId":214,"journal":{"name":"New Phytologist","volume":"19 1","pages":""},"PeriodicalIF":9.4,"publicationDate":"2025-01-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"143030735","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
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