Identification of a secretion-enhancing cis regulatory targeting element (SECReTE) involved in mRNA localization and protein synthesis

Abstract

AbstractEarlier dogma states that mRNAs encoding secreted and membrane protein (mSMPs) reach the ER in a translation-dependent manner through the signal recognition particle (SRP) pathway. In this pathway, the signal sequence of the translation product is recognized by SRP and the mRNA-ribosome-nascent-chain-SRP complex is recruited to the ER via the interaction with an endoplasmic reticulum (ER)-localized SRP receptor. This model suggests that the translation product dictates the delivery of mRNAs to the ER and that the mRNA is a passive passenger. However, new evidence challenges this model and implies the existence of both translation - and SRP-independent mRNA localization to the ER, raising the possibility that mRNAs have an active role in determining their localization to the ER.Besides serving as a template for protein translation, mRNAs carry information required for other regulatory processes such as mRNA processing, translation and transcription efficiency, degradation and localization. In yeast, mRNA localization governed by cis-acting sequence elements has been characterized for asymmetrically (e.g. bud) localized mRNAs that localize to, and are transported with, cortical ER. Now, we identify a cis motif in mSMPs that targets mRNAs mainly to the nuclear ER in yeast and increases both protein synthesis and secretion. Termed SECReTE, for secretion-enhancing cis regulatory targeting element, this motif was identified by computational analysis of genes encoding secretome proteins. SECReTE consists of ≥10 repetitive triplets enriched with pyrimidines (i.e. C’s and U’s) every third base (i.e. NNY, N - any nucleotide, Y - pyrimidine), and is found particularly in mRNAs coding for cell wall proteins. To study the physiological relevance of SECReTE, we introduced synonymous mutations that either elevate or decrease its overall score in genes coding for secreted proteins, without changing the protein sequence, and examined the physiological effects in yeast. An increase in the SECReTE score elevated the synthesis and secretion of endogenous proteins while, in contrast, a reduction led to less secretion and physiological defects. Importantly, the addition of SECReTE to the 3’UTR of an exogenous protein (e.g. SS-GFP) led to its increased secretion from yeast. SECReTE is present all through evolution and, thus, constitutes a novel RNA targeting motif found in both prokaryotes and eukaryotes.