System Wide Analyses have Underestimated Protein Abundances and the Importance of Transcription in Mammals

TL;DR

This study revises previous estimates of protein abundance in mammalian cells, showing transcription's greater importance and correcting underestimations from earlier large-scale surveys, with implications for understanding gene expression regulation.

Contribution

The paper introduces corrected protein abundance estimates and demonstrates that transcription explains a larger portion of protein level variance than previously thought.

Findings

Median protein abundance is around 170,000 molecules per cell after correction.

Transcription explains at least 56-81% of the variance in protein levels.

Translation contributes less to protein variance than earlier estimates suggested.

Abstract

Large scale surveys in mammalian tissue culture cells suggest that the protein expressed at the median abundance is present at 8,000 - 16,000 molecules per cell and that differences in mRNA expression between genes explain only 10-40% of the differences in protein levels. We find, however, that these surveys have significantly underestimated protein abundances and the relative importance of transcription. Using individual measurements for 61 housekeeping proteins to rescale whole proteome data from Schwanhausser et al., we find that the median protein detected is expressed at 170,000 molecules per cell and that our corrected protein abundance estimates show a higher correlation with mRNA abundances than do the uncorrected protein data. In addition, we estimated the impact of further errors in mRNA and protein abundances, showing that mRNA levels explain at least 56% of the differences in protein abundance for the genes detected by Schwanhausser et al., though because one major source of error could not be estimated the true percent contribution could be higher. We also employed a second, independent strategy to determine the contribution of mRNA levels to protein expression. We show that the variance in translation rates directly measured by ribosome profiling is only 12% of that inferred by Schwanhausser et al. and that the measured and inferred translation rates correlate only poorly (R2=0.13). Based on this, our second strategy suggests that mRNA levels explain ~81% of the variance in protein levels. We also determined the percent contributions of transcription, RNA degradation, translation and protein degradation to the variance in protein abundances using both of our strategies. While the magnitudes of the two estimates vary, they both suggest that transcription plays a more important role than the earlier studies implied and translation a much smaller role.