Alberto Gómez Gómez scite author profile

When cultivated in the presence of trypsin, the Ruminococcus gnavus E1 strain, isolated from a human fecal sample, was able to produce an antibacterial substance that accumulated in the supernatant. This substance, called ruminococcin A, was purified to homogeneity by reverse-phase chromatography. It was shown to be a 2,675-Da bacteriocin harboring a lanthionine structure. The utilization of Edman degradation and tandem mass spectrometry techniques, followed by DNA sequencing of part of the structural gene, allowed the identification of 21 amino acid residues. Similarity to other bacteriocins present in sequence libraries strongly suggested that ruminococcin A belonged to class IIA of the lantibiotics. The purified ruminococcin A was active against various pathogenic clostridia and bacteria phylogenetically related to R. gnavus. This is the first report on the characterization of a bacteriocin produced by a strictly anaerobic bacterium from human fecal microbiota.

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Reactogenicity to major tuberculosis antigens absent in BCG is linked to improved protection against Mycobacterium tuberculosis

Aguilo

et al. 2017

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MTBVAC is a live-attenuated Mycobacterium tuberculosis vaccine, currently under clinical development, that contains the major antigens ESAT6 and CFP10. These antigens are absent from the current tuberculosis vaccine, BCG. Here we compare the protection induced by BCG and MTBVAC in several mouse strains that naturally express different MHC haplotypes differentially recognizing ESAT6 and CFP10. MTBVAC induces improved protection in C3H mice, the only of the three tested strains reactive to both ESAT6 and CFP10. Deletion of both antigens in MTBVAC reduces its efficacy to BCG levels, supporting a link between greater efficacy and CFP10- and ESAT6-specific reactogenicity. In addition, MTBVAC (but not BCG) triggers a specific response in human vaccinees against ESAT6 and CFP10. Our results warrant further exploration of this response as potential biomarker of protection in MTBVAC clinical trials.

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IS 6110 Mediates Increased Transcription of the phoP Virulence Gene in a Multidrug-Resistant Clinical Isolate Responsible for Tuberculosis Outbreaks

et al. 2004

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Drug resistance in Mycobacterium tuberculosis complex strains is solely due to chromosomal mutations that could affect bacterial virulence. Molecular epidemiology studies have shown that resistant strains are less likely to be clustered than susceptible strains. However, a few multidrug-resistant (MDR) M. tuberculosis complex strains have been described as causing outbreaks, suggesting that they have restored virulence or increased transmission. One of the biggest MDR tuberculosis outbreaks documented to date was caused by the B strain of M. bovis. Restriction fragment length polymorphism fingerprinting revealed that the B strain contains two copies of IS6110. Here, we mapped and sequenced the regions flanking the two copies of IS6110 in the B strain. Ligation-mediated PCR showed that one of these IS6110 copies is located within the promoter region of phoP, a transcriptional regulator that is essential for M. tuberculosis virulence. We used PCR to screen 219 MDR M. tuberculosis complex strains (90.4% of all MDR isolates) isolated in Spain between 1998 and 2002 and found that the B strain was the only strain that contained a copy of IS6110 in the phoP promoter. To determine whether IS6110 affects phoP promoter activity in the B strain, we individually cloned the phoP gene and its promoter region (including IS6110 from the B strain and the equivalent region from M. tuberculosis without IS6110 as a control) into a mycobacterial replicative plasmid and transformed M. smegmatis with the resulting plasmid. Primer extension analysis showed that phoP transcription was strongly upregulated when the promoter region contained IS6110, as in the case of the B strain.Tuberculosis (TB) is currently one of the leading causes of mortality throughout the world (8,25,27). The human immunodeficiency virus-AIDS pandemic, the deterioration of public health systems in developing countries, and the emergence of multidrug-resistant (MDR) Mycobacterium tuberculosis complex strains have further contributed to the spread of TB. Knowledge of the molecular mechanisms involved in the bacillus-host cell interaction is essential for developing adequate strategies for TB control. Recent advances in the genetic manipulation of mycobacteria (2, 29) combined with the publication of the complete M. tuberculosis genome sequence (6) have made it possible to study the contribution of individual genes to M. tuberculosis virulence (5, 7). However, little is known about the regulatory and expression mechanisms that determine the virulence of clinical isolates of M. tuberculosis.Insertion sequence (IS) 6110 has been extensively used for molecular typing of M. tuberculosis strains. Restriction fragment length polymorphism (RFLP) analysis using IS6110 as a probe is currently the most common molecular method used to type M. tuberculosis complex strains. However, the physiological role and impact of specific IS6110 insertions on the biology of bacilli are not well known. IS6110 fingerprinting studies have demonstrated heterogeneity between virulence and transm...

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