Deciphering thecis-regulatory landscape of natural yeast Transcript Leaders

Abstract

ABSTRACTProtein synthesis is a vital process that is highly regulated at the initiation step of translation. Eukaryotic 5’ transcript leaders (TLs) contain a variety ofcis-regulatory features that influence translation and mRNA stability. However, the relative influences of these features in natural TLs are poorly characterized. To address this, we used massively parallel reporter assays (MPRAs) to quantify RNA levels, ribosome loading, and protein levels from 11,027 natural yeast TLsin vivoand systematically compared the relative impacts of their sequence features on gene expression. We found that yeast TLs influence gene expression over two orders of magnitude. While a leaky scanning model using Kozak contexts and uAUGs explained half of the variance in expression across transcript leaders, the addition of other features explained ∼70% of gene expression variation. Our analyses detected keycis-acting sequence features, quantified their effects in vivo, and compared their roles to motifs reported from anin vitrostudy of ribosome recruitment. In addition, our work quantitated the effects of alternative transcription start site usage on gene expression in yeast. Thus, our study provides new quantitative insights into the roles of TL cis-acting sequences in regulating gene expression.