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Root system architecture (RSA) is a key factor in the efficiency of nutrient capture and water uptake in plants. Understanding the genetic control of RSA will be useful in minimizing fertilizer and water usage in agricultural cropping systems. Using a hydroponic screen and a gel-based imaging system, we identified a rice (Oryza sativa) gene, VAP-RELATED SUPPRESSOR OF TOO MANY MOUTHS1 (OsVST1), which plays a key role in controlling RSA. This gene encodes a homolog of the VAP-RELATED SUPPRESSORS OF TOO MANY MOUTHS (VST) proteins in Arabidopsis (Arabidopsis thaliana), which promote signaling in stomata by mediating plasma membrane-endoplasmic reticulum contacts. OsVST1 mutants have shorter primary roots, decreased root meristem size, and a more compact RSA. We show that the Arabidopsis VST triple mutants have similar phenotypes, with reduced primary root growth and smaller root meristems. Expression of OsVST1 largely complements the short root length and reduced plant height in the Arabidopsis triple mutant, supporting conservation of function between rice and Arabidopsis VST proteins. In a field trial, mutations in OsVST1 did not adversely affect grain yield, suggesting that modulation of this gene could be used as a way to optimize RSA without an inherent yield penalty.Jasmonates (JAs) are plant hormones that regulate the biosynthesis of many secondary metabolites, such as hydroxycinnamic acid amides (HCAAs), through jasmonic acid (JA)-responsive transcription factors (TFs). HCAAs are renowned for their role in plant defense against pathogens. The multidrug and toxic compound extrusion transporter DETOXIFICATION18 (DTX18) has been shown to mediate the extracellular accumulation of HCAAs p-coumaroylagmatine (CouAgm) at the plant surface for defense response. However, little is known about the regulatory mechanism of DTX18 gene expression by TFs. Yeast one-hybrid screening using the DTX18 promoter as bait isolated the key positive regulator redox-responsive TF 1 (RRTF1), which is a member of the AP2/ethylene-response factor family of proteins. RRTF1 is a JA-responsive factor that is required for the transcription of the DTX18 gene, and it thus promotes CouAgm secretion at the plant surface. As a result, overexpression of RRTF1 caused increased resistance against the fungus Botrytis cinerea, whereas rrtf1 mutant plants were more susceptible. Using yeast two-hybrid screening, we identified the BTB/POZ-MATH (BPM) protein BPM1 as an interacting partner of RRTF1. The BPM family of proteins acts as substrate adaptors of CUL3-based E3 ubiquitin ligases, and we found that only BPM1 and BPM3 were able to interact with RRTF1. In addition, we demonstrated that RRTF1 was subjected to degradation through the 26S proteasome pathway and that JA stabilized RRTF1. Knockout of BPM1 and BPM3 in bpm1/3 double mutants enhanced RRTF1 accumulation and DTX18 gene expression, thus increasing resistance to the fungus B. cinerea. Our results provide a better understanding of the fine-tuned regulation of JA-induced TFs in HCAA accumulation.Carotenoid levels in plant tissues depend on the relative rates of synthesis and degradation of the molecules in the pathway. selleck products While plant carotenoid biosynthesis has been extensively characterized, research on carotenoid degradation and catabolism into apocarotenoids is a relatively novel field. To identify apocarotenoid metabolic processes, we characterized the transcriptome of transgenic Arabidopsis (Arabidopsis thaliana) roots accumulating high levels of β-carotene and, consequently, β-apocarotenoids. Transcriptome analysis revealed feedback regulation on carotenogenic gene transcripts suitable for reducing β-carotene levels, suggesting involvement of specific apocarotenoid signaling molecules originating directly from β-carotene degradation or after secondary enzymatic derivatizations. Enzymes implicated in apocarotenoid modification reactions overlapped with detoxification enzymes of xenobiotics and reactive carbonyl species (RCS), while metabolite analysis excluded lipid stress response, a potential secondary effect of carotenoid accumulation. In agreement with structural similarities between RCS and β-apocarotenoids, RCS detoxification enzymes also converted apocarotenoids derived from β-carotene and from xanthophylls into apocarotenols and apocarotenoic acids in vitro. Moreover, glycosylation and glutathionylation-related processes and translocators were induced. In view of similarities to mechanisms found in crocin biosynthesis and cellular deposition in saffron (Crocus sativus), our data suggest apocarotenoid metabolization, derivatization and compartmentalization as key processes in (apo)carotenoid metabolism in plants.KLU, encoded by a cytochrome P450 CYP78A family gene, generates an important-albeit unknown-mobile signal that is distinct from the classical phytohormones. Multiple lines of evidence suggest that KLU/KLU-dependent signaling functions in several vital developmental programs, including leaf initiation, leaf/floral organ growth, and megasporocyte cell fate. However, the interactions between KLU/KLU-dependent signaling and the other classical phytohormones, as well as how KLU influences plant physiological responses, remain poorly understood. Here, we applied in-depth, multi-omics analysis to monitor transcriptome and metabolome dynamics in klu-mutant and KLU-overexpressing Arabidopsis plants. By integrating transcriptome sequencing data and primary metabolite profiling alongside phytohormone measurements, our results showed that cytokinin signaling, with its well-established function in delaying leaf senescence, was activated in KLU-overexpressing plants. Consistently, KLU-overexpressing plants exhibited significantly delayed leaf senescence and increased leaf longevity, whereas the klu-mutant plants showed early leaf senescence. In addition, proline biosynthesis and catabolism were enhanced following KLU overexpression owing to increased expression of genes associated with proline metabolism. Furthermore, KLU-overexpressing plants showed enhanced drought-stress tolerance and reduced water loss. Collectively, our work illustrates a role for KLU in positively regulating leaf longevity and drought tolerance by synergistically activating cytokinin signaling and promoting proline metabolism. These data promote KLU as a potential ideal genetic target to improve plant fitness.

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