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Insights into the regulation of protein abundance from proteomic and transcriptomic analyses - PubMed

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Review

Insights into the regulation of protein abundance from proteomic and transcriptomic analyses

Christine Vogel et al. Nat Rev Genet. 2012.

Abstract

Recent advances in next-generation DNA sequencing and proteomics provide an unprecedented ability to survey mRNA and protein abundances. Such proteome-wide surveys are illuminating the extent to which different aspects of gene expression help to regulate cellular protein abundances. Current data demonstrate a substantial role for regulatory processes occurring after mRNA is made - that is, post-transcriptional, translational and protein degradation regulation - in controlling steady-state protein abundances. Intriguing observations are also emerging in relation to cells following perturbation, single-cell studies and the apparent evolutionary conservation of protein and mRNA abundances. Here, we summarize current understanding of the major factors regulating protein expression.

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Figures

Figure 1
Figure 1. Modes of translation and protein-degradation regulation

Protein abundances are determined by a balance of regulation of both RNA and protein production and turnover, and some of the major determinants of protein abundance are illustrated here. The figure focuses on major mechanisms of the regulation of translation and transcript stability (upper panel) and protein degradation (lower panel). Mechanisms of transcription regulation are not discussed in this article. miRNA, microRNA; uORF, upstream open reading frame. Figure adapted, with permission, from REF. 1© (2009) Royal Society of Chemistry.

Figure 2
Figure 2. Relationships between mRNA and protein abundances, as observed in large-scale proteome- and transcriptome-profiling experiments

a | mRNA transcript abundances only partially correlate with protein abundances, typically explaining approximately one- to two-thirds of the variance in steady-state protein levels, depending on the organism. This trend is evident in data from NIH3T3 mouse fibroblast cells. b | In mammalian cells, as shown here for a human DAOY medulloblastoma cell line, ∼30–40% of the variance in protein abundance is explained by mRNA abundance. A similarly large fraction of variance can be explained by other factors, which is indicative of post-transcriptional and translational regulation and protein degradation,. c | Nonetheless, mRNA levels are an excellent proxy (in general) for the presence of a protein — or, more precisely, for its detectability using current proteomics technologies. The resulting ‘lazy step function’ has been observed in bacteria, yeast and human cell culture: beyond a certain mRNA concentration, the probability of detecting a protein in the sample does not increase any further. d | Preliminary evidence also suggests that, when considering orthologues across highly divergent species, abundances of proteins are more conserved than abundances of the corresponding mRNAs,, suggesting that protein abundances may be evolutionarily favoured. (Numbers indicate Spearman rank correlation coefficients between molecular abundances.) Data such as these support an important role for regulatory mechanisms occurring downstream from the setting of mRNA levels. Panel a of this figure is adapted, with permission, from REF. 5 © (2011) Macmillan Publishers Ltd. All rights reserved. Panel b of this figure is adapted from REF. 24. Panel c of this figure is adapted, with permission, from REF. 42 © (2009) Oxford University Press. Panel d of this figure is adapted, with permission, from REF. 40 © (2010) Wiley.

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