Introduction: The distinction between Mycobacterium tuberculosis complex (MTBC) and Non tuberculous Mycobacteria (NTM) infection is essential for an appropriate treatment. Unfortunately this distinction is not done at regular basis in resource limited settings, as the decision to start is based on smear microscopy which cannot distinguish between bacterial species. SD Bioline rapid test for the detection of Ag MPT64 which is specific to Mycobacterium can be an interesting alternative for differential diagnosis. Objective: To identify MTBC strains isolated at the National Reference Laboratory (NRL) of tuberculosis, Bamako using Ag MPT64 immunochromatographic SD Bioline rapid test relative to traditional biochemical and molecular tests. Methods: We detected MPT64 proteins from both human and animal mycobacterial strains. Human strains were isolated from patients who were referred to NRL for culture and drug susceptibility testing (DST). SD Bioline rapid test results were confirmed using traditional biochemical tests, morphological and molecular techniques. Results: We found that SD Bioline rapid test has a specificity and sensitivity of respectively 100% and 99%. There was only one false negative (FN) case which was identified by traditional biochemical and morphological techniques. Conclusion: This is a simple technique, and may provide a fast, cheap and easy-to-perform alternative method to distinguish between mycobacterial strains in resource limited settings. However, negative results should be confirmed by another identification method such as morphological identification.
The use of X-ray crystallography for the structure determination of biological macromolecules has experienced a steady expansion over the last 20 years with the Protein Data Bank growing from <1000 deposited structures in 1992 to >100 000 in 2014. The large number of structures determined each year not only reflects the impact of X-ray crystallography on many disciplines in the biological and medical fields but also its accessibility to non-expert laboratories. Thus protein crystallography is now largely a mainstream research technique and is routinely integrated in high-throughput pipelines such as structural genomics projects and structure-based drug design. Yet, significant frontiers remain that continuously require methodological developments. In particular, membrane proteins, large assemblies, and proteins from scarce natural sources still represent challenging targets for which obtaining the large diffracting crystals required for classical crystallography is often difficult. These limitations have fostered the emergence of microcrystallography, novel approaches in structural biology that collectively aim at determining structures from the smallest crystals. Here, we review the state of the art of macromolecular microcrystallography and recent progress achieved in this field.
Abstract The epidemic emergence of relatively rare and geographically isolated flaviviruses adds to the ongoing disease burden of viruses such as dengue. Structural analysis is key to understand and combat these pathogens. Here, we present a chimeric platform based on an insect-specific flavivirus for the safe and rapid structural analysis of pathogenic viruses. We use this approach to resolve the architecture of two neurotropic viruses and a structure of dengue virus at 2.5 Å, the highest resolution for an enveloped virion. These reconstructions allow improved modelling of the stem region of the envelope protein, revealing two lipid-like ligands within highly conserved pockets. We show that these sites are essential for viral growth and important for viral maturation. These findings define a hallmark of flavivirus virions and a potential target for broad-spectrum antivirals and vaccine design. We anticipate the chimeric platform to be widely applicable for investigating flavivirus biology.
ABSTRACT Borgs are huge extrachromosomal elements of anaerobic methane-oxidizing archaea. They exist in exceedingly complex microbiomes, lack cultivated hosts and have few protein functional annotations, precluding their classification as plasmids, viruses or other. Here, we used in silico structure prediction methods to investigate potential roles for ∼10,000 Borg proteins. Prioritizing analysis of multicopy genes that could signal importance for Borg lifestyles, we uncovered highly represented de-ubiquitination-like Zn-metalloproteases that may counter host targeting of Borg proteins for proteolysis. Also prevalent are clusters of multicopy genes for production of diverse glycoconjugates that could contribute to decoration of the host cell surface, or of putative capsid proteins that we predict multimerize into hexagonal arrays. Features including megabase-scale linear genomes with inverted terminal repeats, genomic repertoires for energy metabolism, central carbon compound transformations and translation, and pervasive direct repeat regions are shared with giant viruses of eukaryotes, although analyses suggest that these parallels arose via convergent evolution. If Borgs are giant archaeal viruses they would fill the gap in the tri(um)virate of giant viruses of all three domains of life. One Sentence Summary Protein analyses, informed by in silico protein structure prediction, revealed that Borgs share numerous features with giant eukaryotic viruses, suggesting that Borgs have a viral-like lifestyle and evolutionary convergence of large extrachromosomal elements across the Domains of Life.
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