<span class="paragraphSection"><div class="boxTitle">Abstract</div>Bacterial adaptation to stress involves changes in transcription and messenger RNA (mRNA) degradation. In <span style="font-style: italic;">Escherichia coli</span>, the Nudix hydrolase RppH initiates mRNA degradation by removing pyrophosphate from mRNA 5′-ends, converting 5′-triphosphates to 5′-monophosphates. We aimed to identify the RppH homolog in the globally important pathogen <span style="font-style: italic;">Mycobacterium tuberculosis</span> (Mtb). We identified the protein encoded by Rv3908, previously annotated as a nucleotide pool cleanser <span style="font-style: italic;">mutT4</span>, as the predominant mycobacterial RppH. Deletion of <span style="font-style: italic;">rppHMtb</span> increased the relative abundance of 5′-triphosphates on myriad mRNAs across the transcriptome. Purified RppH_Mtb converted mRNA 5′-triphosphates into monophosphates, and stimulated degradation by RNase E and RNase J <span style="font-style: italic;">in vitro</span> to varying extents. Surprisingly, deletion of <span style="font-style: italic;">rppHMtb</span> had mixed impacts on mRNA degradation <span style="font-style: italic;">in vivo</span>, suggesting that it may not sensitize most transcripts to degradation. RppH_Mtb has intrinsically disordered regions (IDRs), which often participate in biomolecular condensate formation. Microscopy showed that RppH_Mtb forms condensate-like bodies that localize with RNases and dissociate upon addition of rifampicin. The N-terminal IDR is sufficient for condensate-like body formation. Deletion of <span style="font-style: italic;">rppHMtb</span> leads to higher outer membrane permeability and resistance to oxidative stress. We conclude that MutT4