The physiology of Mycobacterium tuberculosis, the causative agent of tuberculosis, is being studied with intensity. However, despite the genomic and transcriptomic data available today, the pathogenic potential of these bacteria remains poorly understood. Therefore, proteomic approaches seem relevant in studying mycobacteria. This review covers the main stages in the proteomic analysis methods used to study mycobacteria. The main achievements in the area of M. tuberculosis proteomics are described in general. Special attention is paid to the proteomic features of the Beijing family, which is widespread in Russia. Considering that the proteome is a set of all the proteins in the cell, post-translational modifications of mycobacterium proteins are also described.
A minisequencing method based on matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI TOF MS) was developed for rapid identification of single nucleotide polymorphisms at bla(TEM) gene codons 104, 164 and 238 associated with extended-spectrum activity on TEM-type beta-lactamases. The method was validated by testing the Escherichia coli and Klebsiella pneumoniae strains possessing the known bla(TEM) gene sequences.
Escherichia coli and its bacteriophages are among the most studied model microorganisms. Bacteriophages for various E. coli strains can typically be easily isolated from environmental sources, and many of these viruses can be harnessed to combat E. coli infections in humans and animals. However, some relatively rare E. coli strains pose significant challenges in finding suitable phages. The uropathogenic strain E. coli UPEC124, isolated from a patient suffering from neurogenic bladder dysfunction, was found to be resistant to all coliphages in our collections, and initial attempts to isolate new phages failed. Using an improved procedure for phage enrichment, we isolated the N4-related phage Mimir124, belonging to the Gamaleyavirus genus, which was able to lyse this "difficult" E. coli strain. Although Mimir124 is a narrow-spectrum phage, it was effective in the individualized treatment of the patient, leading to pathogen eradication. The primary receptor of Mimir124 was the O antigen of the O101 type; consequently, Mimir124-resistant clones were rough (having lost the O antigen). These clones, however, gained sensitivity to some phages that recognize outer membrane proteins as receptors. Despite the presence of nine potential antiviral systems in the genome of the UPEC124 strain, the difficulty in finding effective phages was largely due to the efficient, non-specific cell surface protection provided by the O antigen. These results highlight the importance of an individualized approach to phage therapy, where narrow host-range phages-typically avoided in pre-fabricated phage cocktails-may be instrumental. Furthermore, this study illustrates how integrating genomic, structural, and functional insights can guide the development of innovative therapeutic strategies, paving the way for broader applications of phage therapy in combating multidrug-resistant bacterial pathogens.