RNA-binding proteins (RBPs) are essential for the post-transcriptional regulation of gene expression. Recent high-throughput screens have dramatically increased the number of experimentally identified RBPs; however, comprehensive identification of RBPs within living organisms is elusive. Here we describe the repertoire of 765 and 594 proteins that reproducibly interact with polyadenylated mRNAs in Saccharomyces cerevisiae and Caenorhabditis elegans, respectively. Furthermore, we report the differential association of mRBPs upon apoptosis induction in C. elegans L4 stage larvae. Strikingly, most proteins comprising mRNA-binding proteomes (mRBPomes) are evolutionarily conserved between yeast and C. elegans, including components of early metabolic pathways and the proteasome. Based on our evidence that glycolytic enzymes bind to distinct glycolytic mRNAs, we speculate that enzyme-mRNA interactions relate to an ancient mechanism for post-transcriptional coordination of metabolic pathways, perhaps established during the transition from the early RNA to the protein ‘world’.
We describe a tandem RNA isolation procedure (TRIP) that enables purification of in vivo formed messenger ribonucleoprotein (mRNP) complexes. The procedure relies on the purification of polyadenylated mRNAs with oligo(dT) beads from cellular extracts, followed by the capture of specific mRNAs with 3'-biotinylated 2'-O-methylated antisense RNA oligonucleotides, which are recovered with streptavidin beads. TRIP was applied to isolate in vivo crosslinked mRNP complexes from yeast, nematodes and human cells for subsequent analysis of RNAs and bound proteins. The method provides a basis for adaptation to other types of polyadenylated RNAs, enabling the comprehensive identification of bound proteins/RNAs, and the investigation of dynamic rearrangement of mRNPs imposed by cellular or environmental cues.
Arsenate is a common toxic metalloid found in drinking water worldwide that causes several human diseases. The biochemical action underlying cellular response to arsenate, however, is not yet completely understood. Here we used Saccharomyces cerevisiae as an eukaryotic model system to identify proteins essential for adaptation to arsenate treatment. Previous studies have demonstrated a function for Hog1 MAPK in modulating the cellular response to arsenite. Our results, however, showed that cells deficient in Hog1 did not show increased sensitivity to arsenate, suggesting that perhaps other MAPKs may be involved in the response to this particular arsenic species. Here, we found that Slt2 MAPK and several of its upstream regulators are essential in modulating the response to arsenate, and that Slt2 is phosphorylated after arsenate treatment. Furthermore, whole-genome transcriptional analysis showed that Slt2 is required for the induction of several genes in response to arsenate exposure. Many of these genes are involved in the cellular response to heat, suggesting an overlap between these two stress response pathways, and pointing toward a common response to both arsenate and heat exposure in Saccharomyces cerevisiae. Furthermore, our results support the idea that cellular exposure to arsenate results in induction of cellular signalling pathways different from those induced under arsenite treatment.
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