Abstract
BackgroundHomeostasis of the proteome is critical to the development of chloroplasts and also affects the expression of certain nuclear genes. CLPC1 facilitates the translocation of chloroplast pre-proteins and mediates protein degradation.ResultsWe found that proteins involved in photosynthesis are dramatically decreased in their abundance in the clpc1 mutant, whereas many proteins involved in chloroplast transcription and translation were increased in the mutant. Expression of the full-length CLPC1 protein, but not of the N-terminus-deleted CLPC1 (ΔN), in the clpc1 mutant background restored the normal levels of most of these proteins. Interestingly, the ΔN complementation line could also restore some proteins affected by the mutation to normal levels. We also found that that the clpc1 mutation profoundly affects transcript levels of chloroplast genes. Sense transcripts of many chloroplast genes are up-regulated in the clpc1 mutant. The level of SVR7, a PPR protein, was affected by the clpc1 mutation. We showed that SVR7 might be a target of CLPC1 as CLPC1-SVR7 interaction was detected through co-immunoprecipitation.ConclusionOur study indicates that in addition to its role in maintaining proteome homeostasis, CLPC1 and likely the CLP proteasome complex also play a role in transcriptome homeostasis through its functions in maintaining proteome homeostasis.
Highlights
Homeostasis of the proteome is critical to the development of chloroplasts and affects the expression of certain nuclear genes
Results Isobaric tag for relative and absolute quantitation (iTRAQ) based proteomics analysis identified new misregulated proteins in clpc1 chloroplasts In Arabidopsis plastids, currently 2374 proteins have been identified according to the PPDB database [30]
A proteomics analysis indicated that some proteins in the clpc1 mutant were mis-regulated
Summary
Homeostasis of the proteome is critical to the development of chloroplasts and affects the expression of certain nuclear genes. The development and functions of chloroplasts depend heavily on host gene expression [4]. The CLPC1 (Clp protease ATP-binding subunit) protein ( known as HSP93v) was suggested to promote ATP hydrolysis to facilitate the functioning of the TIC complex [8]. Arabidopsis knockout mutants of CLPC1 were shown to have decreased efficiency of import and degradation of chloroplast proteins [12, 13]. These changes in protein homeostasis in chloroplasts may affect gene expression in chloroplasts, there has been limited study of this possibility
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