TY - JOUR

T1 - Mitochondrial proteome heterogeneity between tissues from the vegetative and reproductive stages of Arabidopsis thaliana Development

AU - Lee, Chun Pong

AU - Eubel, Holger

AU - Solheim, Cory

AU - Millar, A. Harvey

N1 - Copyright: Copyright 2013 Elsevier B.V., All rights reserved.

PY - 2012/6/1

Y1 - 2012/6/1

N2 - Specialization of the mitochondrial proteome in Arabidopsis has the potential to underlie the roles of these organelles at different developmental time points and in specific organs; however, most research to date has been limited to studies of mitochondrial composition from a few vegetative tissue types. To provide further insight into the extent of mitochondrial heterogeneity in Arabidopsis, mitochondria isolated from six organ/cell types, leaf, root, cell culture, flower, bolt stem, and silique, were analyzed. Of the 286 protein spots on a 2-D gel of the mitochondrial proteome, the abundance of 237 spots was significantly varied between different samples. Identification of these spots revealed a nonredundant set of 83 proteins which were differentially expressed between organ/cell types, and the protein identification information can be analyzed in an integrated manner in an interactive fashion online. A number of mitochondrial protein spots were identified as being derived from the same genes in Arabidopsis but differed in their pI, indicating organ-specific variation in the post-translational modifications, or in their MW, suggesting differences in truncated mitochondrial products accumulating in different tissues. Comparisons of the proteomic data for the major isoforms with microarray analysis showed a positive correlation between mRNA and mitochondrial protein abundance and 60-90% concordance between changes in protein and transcript abundance. These analyses demonstrate that, while mitochondrial proteins are controlled transcriptionally by the nucleus, post-transcriptional regulation and/or post-translational modifications play a vital role in modulating the state or regulation of proteins in key biochemical pathways in plant mitochondria for specific functions. The integration of protein abundance and protein modification data with respiratory measurements, enzyme assays, and transcript data sets has allowed the identification of organ-enhanced differences in central carbon and amino acid metabolism pathways and provides ranked lists of mitochondrial proteins that are strongly transcriptionally regulated vs those whose abundance or activity is strongly influenced by a variety of post-transcriptional processes.

AB - Specialization of the mitochondrial proteome in Arabidopsis has the potential to underlie the roles of these organelles at different developmental time points and in specific organs; however, most research to date has been limited to studies of mitochondrial composition from a few vegetative tissue types. To provide further insight into the extent of mitochondrial heterogeneity in Arabidopsis, mitochondria isolated from six organ/cell types, leaf, root, cell culture, flower, bolt stem, and silique, were analyzed. Of the 286 protein spots on a 2-D gel of the mitochondrial proteome, the abundance of 237 spots was significantly varied between different samples. Identification of these spots revealed a nonredundant set of 83 proteins which were differentially expressed between organ/cell types, and the protein identification information can be analyzed in an integrated manner in an interactive fashion online. A number of mitochondrial protein spots were identified as being derived from the same genes in Arabidopsis but differed in their pI, indicating organ-specific variation in the post-translational modifications, or in their MW, suggesting differences in truncated mitochondrial products accumulating in different tissues. Comparisons of the proteomic data for the major isoforms with microarray analysis showed a positive correlation between mRNA and mitochondrial protein abundance and 60-90% concordance between changes in protein and transcript abundance. These analyses demonstrate that, while mitochondrial proteins are controlled transcriptionally by the nucleus, post-transcriptional regulation and/or post-translational modifications play a vital role in modulating the state or regulation of proteins in key biochemical pathways in plant mitochondria for specific functions. The integration of protein abundance and protein modification data with respiratory measurements, enzyme assays, and transcript data sets has allowed the identification of organ-enhanced differences in central carbon and amino acid metabolism pathways and provides ranked lists of mitochondrial proteins that are strongly transcriptionally regulated vs those whose abundance or activity is strongly influenced by a variety of post-transcriptional processes.

KW - amino acid metabolism

KW - Arabidopsis

KW - development

KW - mitochondria

KW - organs

KW - post-translational modification

KW - protein-transcript correlation

KW - proteome

KW - tricarboxylic acid cycle

UR - http://www.scopus.com/inward/record.url?scp=84861822384&partnerID=8YFLogxK

U2 - 10.1021/pr3001157

DO - 10.1021/pr3001157

M3 - Article

C2 - 22540835

AN - SCOPUS:84861822384

VL - 11

SP - 3326

EP - 3343

JO - Journal of proteome research

JF - Journal of proteome research

SN - 1535-3893

IS - 6

ER -