Mycobacteria that cause tuberculosis infections employ proteolytic pathways that modulate cellular behavior by destroying specific proteins in a highly regulated manner. Some proteolytic enzymes have emerged as novel antibacterial targets against drug-resistant tuberculosis infections.
Drug-resistant tuberculosis infections are a major challenge to global public health. Much effort has been invested in identifying new drug targets in the causative pathogen,
Mycobacterium tuberculosis
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The prevalence of drug resistant Mycobacterium tuberculosis infections has prompted extensive efforts to exploit new mycobacterial drug targets. ClpC1, the unfoldase component of the essential ClpC1P1P2 protease, has emerged as one particularly promising antibacterial target. However, efforts to identify and characterize ClpC1-targeting compounds are constrained by our limited knowledge of Clp protease function and regulation. To expand our understanding of ClpC1 physiology, we employed a co-immunoprecipitation and mass spectrometry workflow to identify proteins that interact with ClpC1 in Mycolicibacterium smegmatis, a relative of M. tuberculosis. We identify a diverse panel of interaction partners, many of which make co-immunoprecipitate with both the regulatory N-terminal domain and the ATPase core of ClpC1. Notably, our interactome analysis identifies MSMEI_3879, a truncated gene product unique to M. smegmatis, as a novel proteolytic substrate. Degradation of MSMEI_3879 by ClpC1P1P2 in vitro requires an exposed N-terminal sequence, reinforcing the idea that ClpC1 selectively recognizes disordered motifs. Fluorescent substrates incorporating MSMEI_3879 may be useful in screening for novel ClpC1-targeting antibiotics, to help address the challenge of M. tuberculosis drug resistance.
Global interest to explore alternative sources of energy that are sustainable has prompted the increase in biogas production from anaerobic digestion. In this paper, the modelling and simulation of mesophilic anaerobic digestion heating system is presented. It uses models designed with Simulink/matlab to describe the different subsystems that constitute the heating system, such as tankless electric water heater, heat exchanger and anaerobic digestion process. The paper also shows the Simulink model for the heating system, as well as presented tables that indicate the temperature values when the current supplied to the tankless electric water heater and the flow rate were altered.
Tuberculosis is a leading cause of worldwide infectious mortality. The prevalence of multidrug-resistant Mycobacterium tuberculosis (Mtb) infections drives an urgent need to exploit new drug targets. One such target is the ATP-dependent protease ClpC1P1P2, which is strictly essential for viability. However, few proteolytic substrates of mycobacterial ClpC1P1P2 have been identified to date. Recent studies in Bacillus subtilis have shown that the orthologous ClpCP protease recognizes proteolytic substrates bearing post-translational arginine phosphorylation. Several lines of evidence suggest that ClpC1P1P2 similarly recognizes phosphoarginine-bearing proteins, but the existence of phosphoarginine modifications in mycobacteria has remained in question. Here, we confirm the presence of post-translational phosphoarginine modifications in Mycolicibacterium smegmatis (Msm), a nonpathogenic surrogate of Mtb. Using a phosphopeptide enrichment workflow coupled with shotgun phosphoproteomics, we identify arginine phosphosites on a diverse collection of targets within the Msm proteome. Physicochemical and functional characterization of targets suggest that arginine phosphorylation is applied in a sequence-independent manner as part of a proteome-wide quality control pathway. Our findings provide new evidence supporting the existence of phosphoarginine-mediated proteolysis by ClpC1P1P2 in mycobacteria and other actinobacterial species.
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