SUMMARY Environmental mycobacteria are emerging pathogens causing opportunistic infections in humans and animals. The health impacts of human-mycobacterial interactions are complex and likely much broader than currently recognized. Environmental mycobacteria preferentially survive chlorination in municipal water, using it as a vector to infect humans. Widespread chlorination of water has likely selected more resistant environmental mycobacteria species and potentially explains the shift from M. scrofulaceum to M. avium as a cause of cervical lymphadenitis in children. Thus, human activities have affected mycobacterial ecology. While the slow growth and hydrophobicity of environmental mycobacteria appear to be disadvantages, the unique cell wall architecture also grants high biocide and antibiotic resistance, while hydrophobicity facilitates nutrient acquisition, biofilm formation, and spread by aerosolization. The remarkable stress tolerance of environmental mycobacteria is the major reason they are human pathogens. Environmental mycobacteria invade protozoans, exhibiting parasitic and symbiotic relationships. The molecular mechanisms of mycobacterial intracellular pathogenesis in animals likely evolved from similar mechanisms facilitating survival in protozoans. In addition to outright infection, environmental mycobacteria may also play a role in chronic bowl diseases, allergies, immunity to other pulmonary infections, and the efficacy of bacillus Calmette-Guerin vaccination.
The stringent response utilizes hyperphosphorylated guanine [(p)ppGpp] as a signaling molecule to control bacterial gene expression involved in long-term survival under starvation conditions. In gram-negative bacteria, (p)ppGpp is produced by the activity of the related RelA and SpoT proteins. Mycobacterium tuberculosis contains a single homolog of these proteins (Rel Mtb ) and responds to nutrient starvation by producing (p)ppGpp. A rel Mtb knockout strain was constructed in a virulent strain of M. tuberculosis, H37Rv, by allelic replacement. The rel Mtb mutant displayed a significantly slower aerobic growth rate than the wild type in synthetic liquid media, whether rich or minimal. The growth rate of the wild type was equivalent to that of the mutant when citrate or phospholipid was employed as the sole carbon source. These two organisms also showed identical growth rates within a human macrophage-like cell line. These results suggest that the in vivo carbon source does not represent a stressful condition for the bacilli, since it appears to be utilized in a similar Rel Mtb -independent manner. In vitro growth in liquid media represents a condition that benefits from Rel Mtb -mediated adaptation. Long-term survival of the rel Mtb mutant during in vitro starvation or nutrient run out in normal media was significantly impaired compared to that in the wild type. In addition, the mutant was significantly less able to survive extended anerobic incubation than the wild-type virulent organism. Thus, the Rel Mtb protein is required for long-term survival of pathogenic mycobacteria under starvation conditions.
Tuberculosis continues to be a major disease threatening millions of lives worldwide. Several antigens of Mycobacterium tuberculosis, identified by monoclonal antibodies, have been cloned and are being exploited in the development of improved vaccines and diagnostic reagents. We have expressed and purified the 16-kDa antigen, an immunodominant antigen with serodiagnostic value, which has been previously cloned and shown to share low sequence homology with the ␣-crystallinrelated small heat shock protein family. Sedimentation equilibrium analytical ultracentrifugation and dynamic light scattering demonstrate the formation of a specific oligomer, 149 ؎ 8 kDa, consisting of approximately nine monomers. In 4 M urea, a smaller oligomer of 47 ؎ 6 kDa (or trimer) is produced. Analysis by electron cryomicroscopy reveals a triangular shaped oligomeric structure arising from the presence of three subparticles or globules. Taken together, the data suggest an antigen complex structure of a trimer of trimers. This antigen, independent of ATP addition, effectively suppresses the thermal aggregation of citrate synthase at 40°C, indicating that it can function as a molecular chaperone in vitro. A complex between the antigen and heat-denatured citrate synthase can be detected and isolated using high performance liquid chromatography. We propose to rename the 16-kDa antigen Hsp16.3 to be consistent with other members of the small heat shock protein family.
Protein disulfide isomerase (PDI) is a folding assistant of the eukaryotic endoplasmic reticulum, but it also binds the hormones, estradiol, and 3,3,5-triiodo-L-thyronine (T 3 ). Hormone binding could be at discrete hormone binding sites, or it could be a nonphysiological consequence of binding site(s) that are involved in the interaction PDI with its peptide and protein substrates. Equilibrium dialysis, fluorescent hydrophobic probe binding (4,4-dianilino-1,1-binaphthyl-5,5-disulfonic acid (bis-ANS)), competition binding, and enzyme activity assays reveal that the hormone binding sites are distinct from the peptide/protein binding sites. PDI has one estradiol binding site with modest affinity (2.1 ؎ 0.5 M). There are two binding sites with comparable affinity for T 3 (4.3 ؎ 1.4 M). One of these overlaps the estradiol site, whereas the other binds the hydrophobic probe, bis-ANS. Neither estradiol nor T 3 inhibit the catalytic or chaperone activity of PDI. Although the affinity of PDI for the hormones estradiol and T 3 is modest, the high local concentration of PDI in the endoplasmic reticulum (>200 M) would drive hormone binding and result in the association of a substantial fraction (>90%) of the hormones in the cell with PDI. High capacity, low affinity hormone sites may function to buffer hormone concentration in the cell and allow tight, specific binding to the true receptor while preserving a reasonable number of hormone molecules in the very small volume of the cellular environment.
Antibiotics are a relatively common disturbance to the normal microbiota of humans and agricultural animals, sometimes resulting in severe side effects such as antibiotic-associated enterocolitis. Gambusia affinis was used as a vertebrate model for effects of a broad-spectrum antibiotic, rifampicin, on the skin and gut mucosal microbiomes. The fish were exposed to the antibiotic in the water column for 1 week, and then monitored during recovery. As observed via culture, viable counts from the skin microbiome dropped strongly yet returned to pretreatment levels by 1.6 days and became >70% resistant. The gut microbiome counts dropped and took longer to recover (2.6 days), and became >90% drug resistant. The resistance persisted at ~20% of skin counts in the absence of antibiotic selection for 2 weeks. A community biochemical analysis measuring the presence/absence of 31 activities observed a 39% change in results after 3 days of antibiotic treatment. The antibiotic lowered the skin and gut microbiome community diversity and altered taxonomic composition, observed by 16S rRNA profiling. A 1-week recovery period did not return diversity or composition to pretreatment levels. The genus Myroides dominated both the microbiomes during the treatment, but was not stable and declined in abundance over time during recovery. Rifampicin selected for members of the family Comamonadaceae in the skin but not the gut microbiome. Consistent with other studies, this tractable animal model shows lasting effects on mucosal microbiomes following antibiotic exposure, including persistence of drug-resistant organisms in the community.
Protein disulfide-isomerase (PDI) catalyzes the formation and isomerization of disulfides during oxidative protein folding in the eukaryotic endoplasmic reticulum. At high concentrations, it also serves as a chaperone and inhibits aggregation. However, at lower concentrations, PDI can display the unusual ability to facilitate aggregation, termed anti-chaperone activity (Puig, A., and Gilbert, H. F. (1994) J. Biol. Chem. 269, 7764 -7771). Under reducing conditions (10 mM dithiothreitol) and at a low concentration (0.1-0.3 M) relative to the unfolded protein substrate, PDI facilitates aggregation of alcohol dehydrogenase (11 M) that has been denatured thermally or chemically. But at higher concentrations (>0.8 M), PDI inhibits aggregation under the same conditions. With denatured citrate synthase, PDI does not facilitate aggregation, but higher concentrations do inhibit aggregation. Anti-chaperone behavior is associated with the appearance of both PDI and substrate proteins in insoluble complexes, while chaperone behavior results in the formation of large (>500 kDa) but soluble complexes that contain both proteins. Physiological concentrations of calcium and magnesium specifically increase the apparent rate of PDI-dependent aggregation and shift the chaperone activity to higher PDI concentrations. However, calcium has no effect on the K m or V max for PDI-catalyzed oxidative folding, suggesting that the interactions that lead to chaperone/ anti-chaperone behavior are distinct from those required for catalytic activity. To account for this unusual behavior of a folding catalyst, a model with analogy to classic immunoprecipitation is proposed; multivalent interactions between PDI and a partially aggregated protein stimulate further aggregate formation by noncovalently cross-linking smaller aggregates. However, at high ratios of PDI to substrate, cross-linking may be inhibited by saturation of the sites with PDI. The effects of PDI concentration on substrate aggregation and the modulation of the behavior by physiological levels of calcium may have implications for the involvement of PDI in protein folding, aggregation, and retention in the endoplasmic reticulum.In the cell, the coupling of protein folding with the formation and isomerization of protein disulfide bonds (oxidative folding) occurs in the lumen of the endoplasmic reticulum (ER). 1 This specialized compartment provides high concentrations of a number of folding catalysts and chaperones along with a glutathione redox buffer (GSH and GSSG) that is significantly more oxidizing than that in the cytosol (1). Compared with uncatalyzed, spontaneous oxidative folding, protein folding in the ER is rapid and efficient. Folding catalysts accelerate disulfide formation and rearrangement, while chaperones inhibit aggregation by binding exposed hydrophobic surfaces and preventing their interaction. In addition, an ER quality control system retains proteins in the ER until they are correctly folded (2).Protein disulfide-isomerase (PDI) is the most active catalyst of oxi...
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