Natural variations of growth thermo‐responsiveness determined by <scp>SAUR</scp>26/27/28 proteins in <i>Arabidopsis thaliana</i>

Wang, Zhixue; Yang, Leiyun; Liu, Zhenhua; Lu, Ming‐Hui; Wang, Minghui; Sun, Qi; Lan, Yiheng; Shi, Tieliu; Wu, Dianxing; Hua, Jian

doi:10.1111/nph.15956

Cited by 23 publications

(38 citation statements)

References 53 publications

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“…Relevant to the non-discrete distribution of the plastic responses in the accessions that we studied, variation in transcript abundance of SAUR26 explained 17% of the observed plastic response in leaf area to drought in our study (Figure 2F, G). The importance of SAUR26 is supported by previous work that revealed natural genetic variation in SAUR26 associated with growth thermo□responsiveness of the rosette compactness index (Wang et al, 2019) and cis□elements in the 5’ upstream region or the 3’UTR region of SAUR26 that were responsible for this response (Wang et al 2021). This conclusion is also supported by our meta-analysis of the larger Iberian population with transcriptome data, which also identified SAUR26 transcript abundance as positively correlated with higher water use efficiency (Fig.…”

Section: Discussionmentioning

confidence: 67%

“…2g, h). The importance of SAUR26 is supported by previous work that revealed natural genetic variation in SAUR26 associated with growth thermoresponsiveness of the rosette compactness index (Wang et al, 2019), and cis-elements in the 5' upstream region or the 3'UTR region of SAUR26 that were responsible for this response (Wang et al 2021). This conclusion is also supported by our meta-analysis of the larger Iberian population with transcriptome data, which also identified SAUR26 transcript abundance as positively correlated with higher WUEi (Fig.…”

Section: Identifying Candidate Regulators Of Plasticity and Homeostasismentioning

confidence: 60%

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Genetic variation associated with plastic and homeostatic growth responses to drought in Arabidopsis

Ferrero‐Serrano

Assmann

2021

Preprint

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Plants respond to environmental fluctuations through plastic phenotypic shifts. Whether a plastic response upon environmental variability is adaptive or not has been subject to debate. Using a set of Iberian Arabidopsis accessions, we quantified an interplay between passive plastic reductions in leaf areas that we found typical of accessions from productive environments and homeostatic leaf areas responses to drought typified by accessions originating from unproductive environments. Results from Genome-Wide Association Studies (GWAS) and Transcriptome Wide Association Studies (TWAS) highlight the role of auxin-related processes and, in particular, the possible role of the SMALL AUXIN UP RNA 26 (SAUR26) gene in the regulation of the observed plastic responses. Homeostatic responses in leaf area potential following drought were typical of accessions with lower leaf area potential under well-watered conditions. Transcripts that were negatively associated with leaf area potential and positively associated with homeostatic and positive leaf area plasticity following drought showed functional enrichment in ion transport processes. We hypothesized that the contrasting plastic and homeostatic responses in leaf area potential were associated with differential intrinsic water use efficiency (WUEi). We confirmed this relationship in a metanalysis conducted using previously published δ13C measurements. Our results highlight the adaptive role of homeostatic leaf area response to water depletion arising from increased WUEi. The concerted utilization of Genome-Wide Association Studies (GWAS), Transcriptome Wide Association Studies (TWAS), and expression Genome-Wide Association Studies (eGWAS) allows integration of phenotype, genotype, and transcript abundance to identify both "plasticity genes" and "homeostasis genes" associated with drought stress responses.

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Section: Discussionmentioning

confidence: 67%

Section: Identifying Candidate Regulators Of Plasticity and Homeostasismentioning

confidence: 60%

Genetic variation associated with plastic and homeostatic growth responses to drought in Arabidopsis

Ferrero‐Serrano

Assmann

2021

Preprint

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“…1e). Consistent with a previous study (Wang et al ., 2019), the Col‐0 accession that carries the Group A haplotype has a lower expression of SAUR26 compared to the Ang‐0 accession that carries the Group B haplotype. Taken together, variation in SAUR26 gene expression is determined by polymorphisms within its own gene, and the variations in the promoter and 5′UTR as well as the 3′UTR all have strong association with SAUR26 expression.…”

Section: Resultsmentioning

confidence: 98%

“…ICARUS 1 and ICARUS 2 , members of the tRNA His guanylyl transferase (Thg1) superfamily, are found to influence thermo‐responsive rosette growth (Zhu et al ., 2015; Méndez‐Vigo et al ., 2019). In addition, a SMALL AUXIN UP RNA ( SAUR ) gene cluster, SAUR26–SAUR28 , is shown to modulate thermo‐responsive rosette architecture in Arabidopsis natural accessions (Wang et al ., 2019). Natural polymorphisms in SAUR26–SAUR28 cause variations of thermo‐responsive rosette architecture via affecting mRNA abundance and protein activity, and expression variations in SAUR26–SAUR28 likely play a large role in conferring growth variations (Wang et al ., 2019).…”

Section: Introductionmentioning

confidence: 99%

Polymorphisms in cis‐elements confer SAUR26 gene expression difference for thermo‐response natural variation in Arabidopsis

Wang

Yang

et al. 2020

New Phytologist

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Summary The SAUR26 subfamily genes play an important role in conferring variations of thermo‐responsiveness of growth architecture among natural accessions of Arabidopsis thaliana. The expression variations are critical for their activity variations, but how expression variations are generated is unknown. We identified genetic loci for gene expression variations through expression genome‐wide association study (eGWAS) and investigated their mechanisms through molecular analyses. We found that cis elements are the major determinants for expression variations of SAUR26, SAUR27, and SAUR28. Polymorphisms in the promoter region likely impact PIF4 regulation while those at the 3′UTR affect mRNA stability to generate variations in SAUR26 expression levels. These polymorphisms also differentially affect the mRNA stability of SAUR26 at two temperatures. This study reveals two mechanisms involving cis elements in generating gene expression diversity, which is likely important for local adaptations in Arabidopsis natural accessions.

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“…8,9 Briefly, a variety of functional studies in Arabidopsis (Arabidopsis thaliana) SAUR genes have reported the following findings: SAUR10 is expressed in the stems and inflorescence branches to control shoot architecture; SAUR16/50 are light responsive in order to modulate cotyledon opening during de-etiolation; SAUR19s regulate hypocotyl growth in response to auxin and brassinosteroid (BR) signals; SAUR26/27/28 have extensive natural genetic polymorphisms that are associated with the thermo-responsiveness of the plant architecture; SAUR36 is involved in the promotion of leaf senescence; SAUR62/75 are required for pollen tube growth; and SAUR76/77/78 may affect ethylene receptor signaling during seedling growth. [8][9][10] The SAUR41 subfamily of Arabidopsis SAURs consists of four members, including SAUR41 (At1g16510), SAUR40 (At1g79130), SAUR71 (At1g56150), and SAUR72 (At3g12830). We have reported that artificial expression of SAUR41 by promoters of auxin transporter genes and root meristem patterning genes differentially modulate root cell expansion and root development.…”

mentioning

confidence: 99%

The SAUR41 subfamily of cell expansion-promoting genes modulates abscisic acid sensitivity and root touch response: a possible connection to ion homeostasis regulation

Ding

Zheng

Qiu

et al. 2019

Plant Signaling & Behavior

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Most primary auxin response genes are classified into three families, namely AUX/IAAs, GH3s, and SAURs. As a rapidly developing field of plant biology, recent studies have begun to address the function and mechanism of plant SAURs. We found that, in Arabidopsis, the SAUR41 subfamily genes were ABA-inducible, and overexpression of SAUR41 induced the biosynthesis of ABA. The saur41/40/71/72 quadruple mutants and the SAUR41 overexpression lines had an altered expression of ABA and calcium homeostasis/signaling genes, but not the AUX/IAAs and GH3s. Here, we reported that the quadruple mutants showed an increased sensitivity to ABA treatment, in terms of cotyledon greening/expansion rate, while for the overexpression lines, this was decreased. With respect to the root touch response, the overexpression of SAUR41 led to an extensive root looping phenotype, while the quadruple mutations of saur41s led to a relaxed root looping. As reported, the ion content (Na + , K + and Fe 2+), apoplast acidification ability, and salt tolerance were also abnormal in the quadruple mutants and/or the SAUR41 overexpression lines. Our work supports an emerging concept that ABA and calcium are integrated together to modulate ion homeostasis. In addition, our work demonstrates that SAUR41s might be new components for the regulation of ion homeostasis by ABA and calcium.

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Natural variations of growth thermo‐responsiveness determined by SAUR26/27/28 proteins in Arabidopsis thaliana

Cited by 23 publications

References 53 publications

Genetic variation associated with plastic and homeostatic growth responses to drought in Arabidopsis

Genetic variation associated with plastic and homeostatic growth responses to drought in Arabidopsis

Polymorphisms in cis‐elements confer SAUR26 gene expression difference for thermo‐response natural variation in Arabidopsis

The SAUR41 subfamily of cell expansion-promoting genes modulates abscisic acid sensitivity and root touch response: a possible connection to ion homeostasis regulation

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