How to build a fruit: Transcriptomics of a novel fruit type in the Brassiceae

Comparative gene expression studies are invaluable for predicting how existing genetic pathways may be modified or redeployed to produce novel and variable phenotypes. Fruits are ecologically important organs because of their impact on plant fitness and seed dispersal, modifications in which results...

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Veröffentlicht in:	PloS one 2019-07, Vol.14 (7), p.e0209535-e0209535
Hauptverfasser:	Carey, Shane, Mendler, Kerrin, Hall, Jocelyn C
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Sprache:	eng
Schlagworte:	Arabidopsis Arabidopsis thaliana Biochemistry Biology and Life Sciences Brassica Brassicaceae Brassicaceae - genetics Brassicaceae - metabolism Dehiscence Dispersal Dispersion Evolution Fitness Fruit - genetics Fruit - metabolism Fruits Fruits (Food) Future predictions Gene expression Gene Expression Profiling Gene Expression Regulation, Plant Genes Genetic aspects Genomes Medicine and Health Sciences Morphology Mutation Novels Organs Phenotypes Plant Dispersal Regulators Reproductive fitness Research and Analysis Methods Seed dispersal Seeds Segmentation Species Transcription (Genetics) Transcriptome Valves
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description	Comparative gene expression studies are invaluable for predicting how existing genetic pathways may be modified or redeployed to produce novel and variable phenotypes. Fruits are ecologically important organs because of their impact on plant fitness and seed dispersal, modifications in which results in morphological variation across species. A novel fruit type in the Brassicaceae known as heteroarthrocarpy enables distinct dispersal methods in a single fruit through segmentation via a lateral joint and variable dehiscence at maturity. Given the close relationship to Arabidopsis, species that exhibit heteroarthrocarpy are powerful models to elucidate how differences in gene expression of a fruit patterning pathway may result in novel fruit types. Transcriptomes of distal, joint, and proximal regions from Erucaria erucarioides and Cakile lanceolata were analyzed to elucidate within fruit and between species differences in whole transcriptome, gene ontology, and fruit patterning expression profiles. Whole transcriptome expression profiles vary between fruit regions in patterns that are consistent with fruit anatomy. These transcriptomic variances do not correlate with changes in gene ontology, as they remain generally stable within and between both species. Upstream regulators in the fruit patterning pathway, FILAMENTOUS FLOWER and YABBY3, are expressed in the distal and proximal regions of E. erucarioides, but not in the joint, implicating alterations in the pathway in heteroarthrocarpic fruits. Downstream gene, INDEHISCENT, is significantly upregulated in the abscissing joint region of C. lanceolata, which suggests repurposing of valve margin genes for novel joint disarticulation in an otherwise indehiscent fruit. In summary, these data are consistent with modifications in fruit patterning genes producing heteroarthrocarpic fruits through different components of the pathway relative to other indehiscent, non-heteroarthrocarpic, species within the family. Our understanding of fruit development in Arabidopsis is now extended to atypical siliques within the Brassicaceae, facilitating future studies on seed shattering in important Brassicaceous crops and pernicious weeds.
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Fruits are ecologically important organs because of their impact on plant fitness and seed dispersal, modifications in which results in morphological variation across species. A novel fruit type in the Brassicaceae known as heteroarthrocarpy enables distinct dispersal methods in a single fruit through segmentation via a lateral joint and variable dehiscence at maturity. Given the close relationship to Arabidopsis, species that exhibit heteroarthrocarpy are powerful models to elucidate how differences in gene expression of a fruit patterning pathway may result in novel fruit types. Transcriptomes of distal, joint, and proximal regions from Erucaria erucarioides and Cakile lanceolata were analyzed to elucidate within fruit and between species differences in whole transcriptome, gene ontology, and fruit patterning expression profiles. Whole transcriptome expression profiles vary between fruit regions in patterns that are consistent with fruit anatomy. 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C</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>How to build a fruit: Transcriptomics of a novel fruit type in the Brassiceae</atitle><jtitle>PloS one</jtitle><addtitle>PLoS One</addtitle><date>2019-07-18</date><risdate>2019</risdate><volume>14</volume><issue>7</issue><spage>e0209535</spage><epage>e0209535</epage><pages>e0209535-e0209535</pages><issn>1932-6203</issn><eissn>1932-6203</eissn><abstract>Comparative gene expression studies are invaluable for predicting how existing genetic pathways may be modified or redeployed to produce novel and variable phenotypes. Fruits are ecologically important organs because of their impact on plant fitness and seed dispersal, modifications in which results in morphological variation across species. A novel fruit type in the Brassicaceae known as heteroarthrocarpy enables distinct dispersal methods in a single fruit through segmentation via a lateral joint and variable dehiscence at maturity. Given the close relationship to Arabidopsis, species that exhibit heteroarthrocarpy are powerful models to elucidate how differences in gene expression of a fruit patterning pathway may result in novel fruit types. Transcriptomes of distal, joint, and proximal regions from Erucaria erucarioides and Cakile lanceolata were analyzed to elucidate within fruit and between species differences in whole transcriptome, gene ontology, and fruit patterning expression profiles. Whole transcriptome expression profiles vary between fruit regions in patterns that are consistent with fruit anatomy. These transcriptomic variances do not correlate with changes in gene ontology, as they remain generally stable within and between both species. Upstream regulators in the fruit patterning pathway, FILAMENTOUS FLOWER and YABBY3, are expressed in the distal and proximal regions of E. erucarioides, but not in the joint, implicating alterations in the pathway in heteroarthrocarpic fruits. Downstream gene, INDEHISCENT, is significantly upregulated in the abscissing joint region of C. lanceolata, which suggests repurposing of valve margin genes for novel joint disarticulation in an otherwise indehiscent fruit. In summary, these data are consistent with modifications in fruit patterning genes producing heteroarthrocarpic fruits through different components of the pathway relative to other indehiscent, non-heteroarthrocarpic, species within the family. Our understanding of fruit development in Arabidopsis is now extended to atypical siliques within the Brassicaceae, facilitating future studies on seed shattering in important Brassicaceous crops and pernicious weeds.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>31318861</pmid><doi>10.1371/journal.pone.0209535</doi><orcidid>https://orcid.org/0000-0001-9905-4532</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Arabidopsis Arabidopsis thaliana Biochemistry Biology and Life Sciences Brassica Brassicaceae Brassicaceae - genetics Brassicaceae - metabolism Dehiscence Dispersal Dispersion Evolution Fitness Fruit - genetics Fruit - metabolism Fruits Fruits (Food) Future predictions Gene expression Gene Expression Profiling Gene Expression Regulation, Plant Genes Genetic aspects Genomes Medicine and Health Sciences Morphology Mutation Novels Organs Phenotypes Plant Dispersal Regulators Reproductive fitness Research and Analysis Methods Seed dispersal Seeds Segmentation Species Transcription (Genetics) Transcriptome Valves
title	How to build a fruit: Transcriptomics of a novel fruit type in the Brassiceae
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