Differential regulation of gene products in newly synthesized Brassica napus allotetraploids is not related to protein function nor subcellular localization

Allopolyploidy is a preeminent process in plant evolution that results from the merger of distinct genomes in a common nucleus via inter-specific hybridization. Allopolyploid formation is usually related to genome-wide structural and functional changes though the underlying mechanisms operating duri...

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Published in:BMC genomics 2007-02, Vol.8 (1), p.56-56, Article 56
Main Authors: Albertin, Warren, Alix, Karine, Balliau, Thierry, Brabant, Philippe, Davanture, Marlène, Malosse, Christian, Valot, Benoît, Thiellement, Hervé
Format: Article
Language:English
Subjects:
Brassica napus
Brassica napus - genetics
Brassica napus - metabolism
Diploidy
Electrophoresis, Gel, Two-Dimensional
Gene Expression Regulation, Plant
Genomics - methods
Mass Spectrometry - methods
Plant Proteins - genetics
Plant Proteins - metabolism
Plant Roots - genetics
Plant Roots - metabolism
Plant Stems - genetics
Plant Stems - metabolism
Polyploidy
Protein Isoforms - genetics
Protein Isoforms - metabolism
Proteomics - methods
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Summary:Allopolyploidy is a preeminent process in plant evolution that results from the merger of distinct genomes in a common nucleus via inter-specific hybridization. Allopolyploid formation is usually related to genome-wide structural and functional changes though the underlying mechanisms operating during this "genomic shock" still remain poorly known. The aim of the present study was to investigate the modifications occurring at the proteomic level following an allopolyploidization event and to determine whether these changes are related to functional properties of the proteins. In a previous report, we applied comparative proteomics to synthetic amphiploids of Brassica napus and to its diploid progenitors B. rapa and B. oleracea. Although several hundred polypeptides displayed additivity (i.e. mid-parent values) in the amphiploids, many of them showed non-additivity. Here, we report the in silico functional characterization of the "non-additive" proteins (the ones with a non-additive pattern of regulation) in synthetic B. napus. The complete set of non-additive proteins (335 in the stem and 205 in the root), as well as a subset of additive polypeptides (200 per organ), was identified by mass spectrometry. Several protein isoforms were found, and most of them (approximately 55%) displayed "different" or "opposite" patterns of regulation in the amphiploids, i.e. isoforms of the same protein showing both up-regulation and down-regulation in the synthetic B. napus compared to the mid-parent value. Components of protein complexes were identified of which approximately 50% also displayed "different" or "opposite" patterns of regulation in the allotetraploids. In silico functional categorization of the identified proteins was carried out, and showed that neither functional category nor metabolic pathway were systematically affected by non-additivity in the synthetic amphiploids. In addition, no subcellular compartment was found to be over- or under-represented among the proteins displaying non-additive values in the allopolyploids. Protein identification showed that functionally related polypeptides (isoforms and complex subunits) could be differentially regulated in synthetic B. napus in comparison to its diploid progenitors while such proteins are usually expected to display co-regulation. The genetic redundancy within an allopolyploid could explain why functionally related proteins could display imbalanced levels of expression. No functional category, no metabol
ISSN:1471-2164
1471-2164
DOI:10.1186/1471-2164-8-56