Abstract
mRNA degradation is a fundamentally important process that is regulated in response to stress in the globally important pathogen Mycobacterium tuberculosis. Several mycobacterial ribonucleases (RNases) are hypothesized to function together to coordinate mRNA degradation, but the interactions among them are mostly undefined. One of the rate-limiting enzymes, RNase E, contains intrinsically disordered regions (IDRs). Here, we aimed to define the interactions between major mycobacterial mRNA degradation enzymes and identify the function(s) of the two IDRs of RNase E in the nonpathogenic model Mycolicibacterium smegmatis. We found that the two IDRs differentially impact mRNA degradation rates in vivo but are largely functionally redundant in their impacts on steady-steady transcript abundance. In vitro, the IDRs are uninvolved in catalysis but play major roles in RNA binding and interactions with other mRNA degradation enzymes, namely PNPase, RNase J, and RhlE1. In vivo, these enzymes localize with RNase E, but its IDRs play only a minor role, suggesting substantial redundancy in subcellular localization mechanisms. Collectively, we propose a degradosome-like network model in mycobacteria, held together by dynamic, transient interactions among RNA degradation enzymes and RNA that can be disrupted during physiologically relevant stress to allow for adaptability.