Translation Velocity Determines the Efficacy of Engineered Suppressor TRNAs on Pathogenic Nonsense Mutations

Overview

Journal Nat Commun

Specialty Biology

Date 2024 Apr 5

PMID 38580646

Authors

Nikhil Bharti

Leonardo Santos

Marcos Davyt

Stine Behrmann

Marie Eichholtz

Alejandro Jimenez-Sanchez

Jeong S Hong

Andras Rab

Eric J Sorscher

Suki Albers

Zoya Ignatova

Affiliations

Soon will be listed here.

Abstract

Nonsense mutations - the underlying cause of approximately 11% of all genetic diseases - prematurely terminate protein synthesis by mutating a sense codon to a premature stop or termination codon (PTC). An emerging therapeutic strategy to suppress nonsense defects is to engineer sense-codon decoding tRNAs to readthrough and restore translation at PTCs. However, the readthrough efficiency of the engineered suppressor tRNAs (sup-tRNAs) largely varies in a tissue- and sequence context-dependent manner and has not yet yielded optimal clinical efficacy for many nonsense mutations. Here, we systematically analyze the suppression efficacy at various pathogenic nonsense mutations. We discover that the translation velocity of the sequence upstream of PTCs modulates the sup-tRNA readthrough efficacy. The PTCs most refractory to suppression are embedded in a sequence context translated with an abrupt reversal of the translation speed leading to ribosomal collisions. Moreover, modeling translation velocity using Ribo-seq data can accurately predict the suppression efficacy at PTCs. These results reveal previously unknown molecular signatures contributing to genotype-phenotype relationships and treatment-response heterogeneity, and provide the framework for the development of personalized tRNA-based gene therapies.

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