Regulation of protein multi-functionality by 3 UTRs
Sloan-Kettering Inst Can Research, New York NY
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Abstract
Regulation of protein multi-functionality by 3â²UTRs SUMMARY Many protein functions are mediated by protein complexes whose formation is often regulated by abundance as higher levels increase the chance to encounter an interaction partner. mRNAs contain a coding region that is translated into protein, but they also contain a 3â² untranslated region (3â²UTR). In addition to regulation by abundance, my lab discovered that protein function can be regulated by 3â²UTRs as during protein synthesis 3â²UTRs mediate protein-protein interactions. 3â²UTR-dependent protein complex assembly is mediated by the local translation environment. Each mRNA generates its own translation environment that consists of the proteins bound by the mRNA together with the recruited proteins. As a result, mRNA isoforms with alternative 3â²UTRs â that often differ substantially in length â provide drastically different translation environments, and thus encode different protein functions. Currently, thousands of 3â²UTR-dependent functions are unknown because they cannot be inferred from canonical protein functions. We have developed a method to systematically identify protein functions mediated by long 3â²UTR isoforms of multi-UTR genes using a CRISPR-based approach. We will identify 3â²UTRs that mediate so far unknown protein functions involved in the evasion of cell death, in the regulation of migration, and differentiation. We currently know of two ways to achieve 3â²UTR-dependent functions. As described above, an mRNA that contains a long 3â²UTR can generate its own translation environment. Moreover, mRNAs can use elements in their 3â²UTRs to localize to pre-existing translation environments that are formed by phase-separated cytosolic compartments. Within these large cytosolic membraneless organelles the environment is generated by many mRNAs together with their recruited proteins. We discovered such a compartment called TIS granule network. We determined hundreds of enriched mRNAs and observed that usually only half of transcripts with the same 3â²UTR localize to TIS granules. This implies that proteins can have alternative functions depending on whether they are translated in the cytosol or in TIS granules. Our goal is to investigate how proteins change their function when translated within TIS granules. To study TIS granule-dependent protein functions, we have engineered cells that are unable to assemble TIS granules. For candidates whose mRNAs are strongly enriched in TIS granules, we are investigating if translation in TIS granules controls the addition of post- translational modifications, the establishment of specific protein complexes, or if it suppresses protein aggregation. If successful, our research will reveal a widespread role of mRNA in the compartmentalization and physical scaffolding during translation. It will show how elements in 3â²UTRs contribute to the diversification of protein function. In the long-term, it will facilitate the development of mRNA therapeutics where inclusion of specific 3â²UTR elements allows mRNAs to encode proteins with more robust or alternative functions.
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