MADS-domain transcription factors and the floral quartet model of flower development: linking plant development and evolution

Theißen, Günter; Melzer, Rainer; Rümpler, Florian

doi:10.1242/dev.134080

Cited by 339 publications

(341 citation statements)

References 117 publications

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“…Two SEP1 ‐linked SNPs were heterozygous in 27 of 28 males, whereas 21 of 22 females were homozygous, consistent with the existence of strongly X‐ and Y‐linked copies. If SEP homologs in Nepenthes are involved in the determination of floral organ identity (as in A. thaliana , Theißen et al ), the sex‐linked Nepenthes SEP1 homolog could be involved in unisexual flower development. In particular, sequence differences between the Nepenthes SEP1 X‐ and Y‐linked copies might modify their functions such that they suppress the development of either carpels or stamens.…”

Section: Discussionmentioning

confidence: 99%

Sex is determined by XY chromosomes across the radiation of dioeciousNepenthespitcher plants

et al. 2019

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Species with separate sexes (dioecy) are a minority among flowering plants, but dioecy has evolved multiple times independently in their history. The sex‐determination system and sex‐linked genomic regions are currently identified in a limited number of dioecious plants only. Here, we study the sex‐determination system in a genus of dioecious plants that lack heteromorphic sex chromosomes and are not amenable to controlled breeding: Nepenthes pitcher plants. We genotyped wild populations of flowering males and females of three Nepenthes taxa using ddRAD‐seq and sequenced a male inflorescence transcriptome. We developed a statistical tool (privacy rarefaction) to distinguish true sex specificity from stochastic noise in read coverage of sequencing data from wild populations and identified male‐specific loci and XY‐patterned single nucleotide polymorphsims (SNPs) in all three Nepenthes taxa, suggesting the presence of homomorphic XY sex chromosomes. The male‐specific region of the Y chromosome showed little conservation among the three taxa, except for the essential pollen development gene DYT1 that was confirmed as male specific by PCR in additional Nepenthes taxa. Hence, dioecy and part of the male‐specific region of the Nepenthes Y‐chromosomes likely have a single evolutionary origin.

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Section: Discussionmentioning

confidence: 99%

Sex is determined by XY chromosomes across the radiation of dioeciousNepenthespitcher plants

et al. 2019

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“…Some of these were characterised more than 20 years ago for their ability to interact with each other in different combinations to specify the floral organs of Antirrhinum (snapdragon) and Arabidopsis . In these seminal studies, homeotic floral mutants were used to deduce an elegant ‘ABC model’, later elaborated into an ‘ABCDE model’ that explains how the four concentric whorls of sepals, petals, male stamens and female carpels develop in these flowers 17– 19 . A-function genes specify sepals; A, B and E are needed to make petals; B, C and E male stamens; C female carpels; and D for ovules.…”

Section: Contributions Of Whole-genome Duplications To the Origin Andmentioning

confidence: 99%

“…In homeotic mutants lacking B-function, for example, sepals replace petals and carpels replace stamens 18 . Most of the A, B, C, D and E functions are performed by combinations of MADS-box transcription factors that operate as homodimers and heterodimers and tetramers with different selectivities for binding to variants of a common motif in the promoters of target genes 19, 20 . Hence, they target overlapping but distinct sets of floral identity genes many of which are themselves ohnologues 21 .…”

Section: Contributions Of Whole-genome Duplications To the Origin Andmentioning

confidence: 99%

“…An A/E gymnosperm pro-orthologue gave rise to angiosperm A and E genes, and further duplicated A genes were also retained after the ε WGD 19, 21– 24 . These duplicated and diversified gene sets organised to generate the first now-extinct flowers, and recent reconstructions suggest that these were bisexual with petal-like tepals and pollen-bearing stamens arranged in multiple concentric whorls, and female carpels in a central spiral 25 .…”

Section: Contributions Of Whole-genome Duplications To the Origin Andmentioning

confidence: 99%

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Recent advances in understanding the roles of whole genome duplications in evolution

MacKintosh

Ferrier

2017

F1000Res

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Ancient whole-genome duplications (WGDs)— paleopolyploidy events—are key to solving Darwin’s ‘abominable mystery’ of how flowering plants evolved and radiated into a rich variety of species. The vertebrates also emerged from their invertebrate ancestors via two WGDs, and genomes of diverse gymnosperm trees, unicellular eukaryotes, invertebrates, fishes, amphibians and even a rodent carry evidence of lineage-specific WGDs. Modern polyploidy is common in eukaryotes, and it can be induced, enabling mechanisms and short-term cost-benefit assessments of polyploidy to be studied experimentally. However, the ancient WGDs can be reconstructed only by comparative genomics: these studies are difficult because the DNA duplicates have been through tens or hundreds of millions of years of gene losses, mutations, and chromosomal rearrangements that culminate in resolution of the polyploid genomes back into diploid ones (rediploidisation). Intriguing asymmetries in patterns of post-WGD gene loss and retention between duplicated sets of chromosomes have been discovered recently, and elaborations of signal transduction systems are lasting legacies from several WGDs. The data imply that simpler signalling pathways in the pre-WGD ancestors were converted via WGDs into multi-stranded parallelised networks. Genetic and biochemical studies in plants, yeasts and vertebrates suggest a paradigm in which different combinations of sister paralogues in the post-WGD regulatory networks are co-regulated under different conditions. In principle, such networks can respond to a wide array of environmental, sensory and hormonal stimuli and integrate them to generate phenotypic variety in cell types and behaviours. Patterns are also being discerned in how the post-WGD signalling networks are reconfigured in human cancers and neurological conditions. It is fascinating to unpick how ancient genomic events impact on complexity, variety and disease in modern life.

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“…One application is to extract and visualize syntenic relationships for certain genes or gene families across and within species (depending on the question at hand). For example, APETALA3 (AP3) and PISTILLATA (PI) genes are important MADS-box transcription factors that specify petal and stamen identity (known as B-class floral regulatory genes) (Dodsworth, 2016;Theissen et al, 2016). A previous comparative study of floral MADS-box genes between the sister families Cleomaceae (Tarenaya hassleriana) and Brassicaceae (e.g.…”

Section: 'Network Effect': Deciphering Phylogenomic Evolutionary Pattmentioning

confidence: 99%

Synteny-based phylogenomic networks for comparative genomics

Zhao

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MADS-domain transcription factors and the floral quartet model of flower development: linking plant development and evolution

Cited by 339 publications

References 117 publications

Sex is determined by XY chromosomes across the radiation of dioeciousNepenthespitcher plants

Sex is determined by XY chromosomes across the radiation of dioeciousNepenthespitcher plants

Recent advances in understanding the roles of whole genome duplications in evolution

Synteny-based phylogenomic networks for comparative genomics

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