Proteomic Analysis of Drug-Resistant Mycobacterium tuberculosis Clinical Isolates Under Aminoglycoside Drug Pressure.

Pharmacoproteomics enables the actual status of the drug-induced conditions at the protein level. Aminoglycosides have been a major component of second-line anti-TB therapy and with a well-known mechanism to inhibit protein synthesis in bacteria by interacting with several steps of the translational process. Researchers suggested the benefit of treating antibiotic-resistant M. tuberculosis strains with the same antibiotics at an effective and safe level. In this study, we analyzed the pharmaco-proteomic effects of aminoglycosides on eight drug-resistant clinical isolates by 2DE coupled with MALDI-TOF MS. Further, bioinformatics tools have been employed to characterize the protein-antibiotic interactions. This study revealed that nine proteins showed consistently increased intensities under drug pressure. 60 kDa chaperonin1 (Rv3417c) is a heat shock protein (Hsp) that plays a key role in the survival of bacilli under stress conditions. Elongation factor Tu (Rv0685) promotes GTP-dependent binding of aminoacyl-tRNA to the A-site of the ribosome during protein biosynthesis. Dihydrolipoyl dehydrogenase (Rv0462) is involved in energy metabolism. Ribosome recycling factor Rv2882c is responsible for increasing the efficiency of translation by recycling ribosomes from one round of translation to another. Proteasome subunit beta (Rv2110c) is involved in protein degradation. Antigen 85-A precursor (Rv3804c) is involved in cell-wall mycoloylation. Three proteins (Rv2623, Rv3389c, and Rv2744c) were identified with unknown functions. Overexpressed proteins and pathways could be directly/indirectly involved in aminoglycoside resistance. Bioinformatics revealed that three proteins of unknown functions showed good binding with aminoglycosides, suggesting their direct/indirect role in resistance, and need further exploration.