Getting leaves into shape: a molecular, cellular, environmental and evolutionary view

Maugarny-Calès, Aude; Laufs, Patrick

doi:10.1242/dev.161646

Cited by 68 publications

(48 citation statements)

References 182 publications

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“…On the other hand, and in support of the adaptation argument, it has also been demonstrated that leaf-blade dissection may be under oligogenic control (Sicard & al. 2014;Maugarny-Calès & Laufs 2018). This may explain our present observation that variation in ecologically adaptive and taxonomically decisive morphological features is not paralleled by genetic patterns based on molecular markers scattered throughout the whole genome like AFLP fingerprint loci.…”

Section: Genetic Differentiation Of Leucanthemum Corsicum -mentioning

confidence: 77%

Karyological and molecular analysis of Leucanthemum (Compositae, Anthemideae) in Corsica

et al. 2019

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Karyological, flow-cytometric and molecular analyses indicate that the genus Leucanthemum Mill. (Compositae, Anthemideae) is represented in Corsica (Corse) by two species: the tetraploid L. ircutianum DC. and the hexaploid L. corsicum (Less.) DC. The indication of the occurrence of the diploid L. vulgare Lam. on the island and of a tetraploid chromosome number for L. corsicum, given in former treatments of the genus for Corsica, could not be corroborated. AFLP fingerprinting further suggests that the infraspecific taxonomy of L. corsicum with two subspecies (L. corsicum subsp. corsicum and subsp. fenzlii) and three forms (L. corsicum f. corsicum, f. pinnatifidum and f. eschenlohrianum), which is mainly based on differences in the degree of leaf dissection, is not backed by genetic discontinuities. Owing to the observed little variation in leaf dissection within populations in the wild and the constancy of these features under cultivation, we propose the rank of varieties to taxonomically acknowledge these different stages in the broad spectrum of leaf-dissection grades exhibited by L. corsicum. As a consequence, the two new combinations L. corsicum var. eschenlohrianum (Gamisans) Vogt, Hugot & Oberpr. and L. corsicum var. fenzlii (Gamisans) Vogt, Hugot & Oberpr. are proposed.

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Section: Genetic Differentiation Of Leucanthemum Corsicum -mentioning

confidence: 77%

Karyological and molecular analysis of Leucanthemum (Compositae, Anthemideae) in Corsica

et al. 2019

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“…Plant leaves provide a powerful model in which to explore such questions on the mechanistic basis of evolutionary change because they show substantial, heritable morphological variation at different evolutionary scales and are ecophysiologically important because they fix CO 2 in terrestrial ecosystems [16,17]. Considerable insights into the genetic basis for diversification of leaf shape have come from comparative studies of simple leaves of the reference plant A. thaliana versus complex leaves of its relative Cardamine hirsuta, where leaves are divided into distinct units called leaflets.…”

Section: Resultsmentioning

confidence: 99%

Autoregulation of RCO by Low-Affinity Binding Modulates Cytokinin Action and Shapes Leaf Diversity

et al. 2019

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Graphical Abstract Highlights d Identification of genome-wide target genes for the RCO transcription factor d RCO delimits its own expression through autorepression by low-affinity binding d RCO represses local leaf growth via regulating multiple cytokinin (CK)-related genes d RCO negative autorepression fine-tunes CK activity and regulates leaf shape In Brief Hajheidari et al. identify target genes for the RCO homeodomain protein that drove leaf shape diversity. They show that RCO regulates growth via orchestrating homeostasis for the hormone cytokinin and that it also represses its own transcription via low-affinity binding sites. This autorepression helps delimit RCO expression and shape leaf form.

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“…This shift correlates with the role of sugar in promoting the Target of Rapamycin (TOR) pathway and repressing the Sucrose-non-fermenting1-related kinase 1 (SnRK1): TOR and T6P induce cell expansion by promoting macromolecular synthesis, whereas SnRK1 promotes catabolism ( Tsai and Gazzarrini, 2014 ; Sablowski, 2016 ). Two microRNAs play opposite roles in this cellular shift: miR319 represses the expression of class II TCP factors, which are inhibitors of cell proliferation, whereas miR396 restricts the expression of GROWTH REGULATING FACTORS (GRFs), which delay differentiation ( Das Gupta and Nath, 2015 ; Maugarny-Calés and Laufs, 2018 ). The transition from an indeterminate shoot apical meristem to a determinate floral meristem also involves temporal regulation of the cellular identity.…”

Section: Mechanisms Driving Changes In Developmental Timing In Plantsmentioning

confidence: 99%

The Times They Are A-Changin’: Heterochrony in Plant Development and Evolution

Buendía-Monreal

Gillmor

2018

Front. Plant Sci.

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Alterations in the timing of developmental programs during evolution, that lead to changes in the shape, or size of organs, are known as heterochrony. Heterochrony has been widely studied in animals, but has often been neglected in plants. During plant evolution, heterochronic shifts have played a key role in the origin and diversification of leaves, roots, flowers, and fruits. Heterochrony that results in a juvenile or simpler outcome is known as paedomorphosis, while an adult or more complex outcome is called peramorphosis. Mechanisms that alter developmental timing at the cellular level affect cell proliferation or differentiation, while those acting at the tissue or organismal level change endogenous aging pathways, morphogen signaling, and metabolism. We believe that wider consideration of heterochrony in the context of evolution will contribute to a better understanding of plant development.

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Getting leaves into shape: a molecular, cellular, environmental and evolutionary view

Cited by 68 publications

References 182 publications

Karyological and molecular analysis of Leucanthemum (Compositae, Anthemideae) in Corsica

Karyological and molecular analysis of Leucanthemum (Compositae, Anthemideae) in Corsica

Autoregulation of RCO by Low-Affinity Binding Modulates Cytokinin Action and Shapes Leaf Diversity

The Times They Are A-Changin’: Heterochrony in Plant Development and Evolution

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