Sepal shape variability is robust to cell size heterogeneity in
            <i>Arabidopsis</i>

Trinh, Duy-Chi; Lionnet, Claire; Trehin, Christophe; Hamant, Olivier

doi:10.1098/rsbl.2024.0099

Cited by 2 publications

References 25 publications

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Mechanical regulation of tissue flatness inMarchantia

Ferria,

Fournié,

Jankowska

et al. 2024

Preprint

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The production of flat organs involves a tight regulation of tissue expansion. During growth, the cell wall is under mechanical tension and continuous remodelling, requiring mechanisms to sense and maintain cell wall integrity (CWI). Here we studied the link between CWI sensing and flatness of Marchantia polymorpha thalli. We considered FERONIA (FER), a CWI sensor, and assessed its role in the maintenance of thallus shape. We developed a pipeline to quantify flatness at multiple scales. We found that both abolishing and increasing FER expression leads to loss of flatness. Based on experiments that reduce cell wall tension and partially restore wild-type cell size and thallus morphology, we ascribe loss of flatness to under- or to over-reaction of plants to mechanical stress. Altogether, our results support the concept that responses to mechanical stress contribute to the robustness of morphogenesis.

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Mechanical regulation of tissue flatness inMarchantia

Ferria,

Fournié,

Jankowska

et al. 2024

Preprint

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Unveiling the molecular mechanism of sepal curvature in Dendrobium Section Spatulata through full-length transcriptome and RNA-seq analysis

Qu,

Li,

et al. 2024

Front. Plant Sci.

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IntroductionOrchids are renowned for their intricate floral structures, where sepals and petals contribute significantly to ornamental value and pollinator attraction. In Dendrobium Section Spatulata, the distinctive curvature of these floral organs enhances both aesthetic appeal and pollination efficiency. However, the molecular and cellular mechanisms underlying this trait remain poorly understood.MethodsMorphological characteristics of five hybrids were analyzed, with a particular focus on hybrid H5, which exhibits pronounced sepal curling. Full-length transcriptomic sequencing was employed to assemble a reference transcriptome, while RNA-seq identified differentially expressed genes (DEGs) between sepals and petals. Gene ontology and pathway enrichment analyses were conducted to uncover biological processes associated with sepal curvature. Cytological microscopy was used to examine cell size and number, and quantitative real-time PCR (qRT-PCR) was performed to validate transcriptomic findings.ResultsThe reference transcriptome contained 94,258 non-redundant transcripts, and RNA-seq identified 821 DEGs between sepals and petals, with 72.8% of these upregulated in sepals. Enrichment analysis revealed the significant involvement of DEGs in cytokinesis, cytoskeletal organization, and energy metabolism. Notably, myosin II filament organization was implicated in generating the mechanical forces responsible for curling, while metabolic pathways provided the energy necessary for these developmental processes. Cytological observations showed that the upper cell layers of the sepal were smaller and more numerous than the lower layers, indicating that differential cell growth contributes to sepal curvature. qRT-PCR analysis validated the differential expression of selected genes, supporting the transcriptomic findings.DiscussionThe interplay of cellular mechanics, cytoskeletal dynamics, and metabolic regulation is crucial in shaping sepal morphology. Future studies involving gene knockdown or overexpression experiments are recommended to validate the roles of specific genes in processes such as actin organization and myosin activity. Such work would provide deeper insights into the contributions of cytoskeletal dynamics and mechanical force generation to sepal morphogenesis.

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Sepal shape variability is robust to cell size heterogeneity in Arabidopsis

Cited by 2 publications

References 25 publications

Mechanical regulation of tissue flatness inMarchantia

Mechanical regulation of tissue flatness inMarchantia

Unveiling the molecular mechanism of sepal curvature in Dendrobium Section Spatulata through full-length transcriptome and RNA-seq analysis

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