Identification of seven types of pili in Mycobacterium tuberculosis: Using atomic force microscopy.

Background: Pili are polymeric, hydrophobic, proteinaceous structures generally composed of a major repeating subunit called pilin and, in some cases, a minor tip-associated adhesin subunit. Pili are involved in many virulence-associated functions, such as biofilm formation, adherence, and colonization of mucosal surfaces. Methods: Mycobacterium tuberculosis (MTB) strains were isolated from clinically and laboratory-confirmed cases of tuberculosis (TB). The TB isolates were subjected to the Xpert MTB/rifampicin test and then, further susceptibility testing was performed on them against first- and second-line drugs using proportional methods. Thereafter, the selected isolates were subculture in Dubos Tween-albumin liquid culture medium, and at their exponential growth phase (OD600 = 0.05 (5 × 106 colony-forming unit/mL), cells were observed under atomic force microscopy (AFM). For each isolate, 15-20 steel sample packs were prepared and observed under AFM. Here, the data presented are the result of average observation. Results: Under AFM, seven different types of pili were detected, out of which four types, i.e., Type III, Type IV secretion pili, and Type IV-like pili, curli-like pili (MTP) were similar to reported pili in Gram-negative and Gram-positive bacteria. Whereas the other three forms, i.e., Type V (relief funnel pili), Type VI (adhesion tapering), and Type VII (adhesion flap pili), were newly identified and named according to their appearance. Both Types of IV pili were detected in all clinical isolates irrespective of their susceptibility patterns, although significant differences were observed from the side of their protruding. Type Curli pili is similar in appearance in all clinical isolates. Types VI and VII were detected only in extensively drug-resistant and totally drug-resistant-TB isolates (100%). The Type III pili (secretion needle pili) was present in both susceptible- and drug-resistant bacilli, although in drug-resistant strains, we found a considerable difference in their length (50 µ ±10 nm in length) and sometimes, they also had tapering at end. The Type V pili was seen in susceptible isolates but it was at the resting stage (100%; lying aside of cell wall) whereas in drug-resistant isolates, they were getting apart from the cell wall of bacilli with a clear tapering or funnel shape structure. Conclusion: The results of this study highlight the importance of new types of pili expressions in respect of susceptibility patterns in TB. The identified new types of pili would be promising approaches for the treatment and prevention of drug-resistant TB, which needs further investigation.

Sequential adaptation in latent tuberculosis bacilli: observation by atomic force microscopy (AFM).

Mycobacterium tuberculosis (MTB) can persist within the human host for years without causing disease, in a syndrome known as latent tuberculosis. The mechanisms by which M. tuberculosis establishes a latent metabolic state is unknown, but it is hypothesized that reduced oxygen tension may trigger the bacillus to enter a state of latency. Therefore, we are studying anaerobic culture of M. tuberculosis (H37RV) as a model of latency. For the first time, the sequential adaptation of latent bacilli (every 90 days for 48 months) viewed under Atomic Force Microscopy (AFM). Two types of adaptation were observed and are described here. First, cells are undergoing temporary adaptation (from 1 to 18 months of latency) that includes; thickening of cell wall (20.5±1.8 nm versus 15.2±1.8 nm, P<0.05), formation of ovoid cells by "folding phenomena"(65-70%), size reduction (0.8±0.1 µm versus 2.5±0.5 µm), and budding type of cell division (20-25%).A second feature include changes that accompany development of specialized cells i.e., production of spore like cells (0.5±0.2 µm) and their progeny (filterable non -acid fast forms; 150 to 300 µm in size). Although, these cells were not real spore because they fail to form a heat resistant colony forming units, after incubation for 35-40 min at 65°C. The filterable non-acid fast forms of bacilli are metabolically active and increased their number by symmetrical type of cell-division. Therefore, survival strategies that developed by M. tuberculosis under oxygen limited condition are linked to its shape, size and conspicuous loss of acid fastness.

Growth and cell-division in extensive (XDR) and extremely drug resistant (XXDR) tuberculosis strains: transmission and atomic force observation.

The ultra-structure of Mycobacterium tuberculosis (MTB) was examined by transmission electronic (TEM)) and atomic force microscopy (AFM). The study was performed to describe the morphology of susceptible, multidrug-resistant (MDR), extensively drug-resistant (XDR) and extremely drug-resistant tuberculosis isolates (XXDR-TB) during their exponential growth phase. Four types of cell division were observed and described. While three of them (symmetrical, asymmetrical and branching type) occurred in all isolates studied, the fourth one (adapted type) was seen only in XDR and XXDR-TB bacilli. In the fourth type of cell division, a rod shaped mother cell produced a small round shape bacillus (0.3-0.5 µm). These round cells were different from buds or polar division, but similar to terminal endospores without showing the typing heat resistance. Based on the present observation, we suggest that XDR-and XXDR-TB bacilli accommodate changes helping them to overcome the hostile environment. Viewed under AFM, the other frequently detected shapes in MTB isolates were oval, V, Y and multi-branching filaments. These shape variation confirmed pleomorphic phenomena in MTB populations and the specific features of pan-resistant strains.