Helicobacter pylori VacA toxin promotes bacterial intracellular survival in gastric epithelial cells.

Helicobacter pylori colonizes the gastric epithelium of at least 50% of the world's human population, playing a causative role in the development of chronic gastritis, peptic ulcers, and gastric adenocarcinoma. Current evidence indicates that H. pylori can invade epithelial cells in the gastric mucosa. However, relatively little is known about the biology of H. pylori invasion and survival in host cells. Here, we analyze both the nature of and the mechanisms responsible for the formation of H. pylori's intracellular niche. We show that in AGS cells infected with H. pylori, bacterium-containing vacuoles originate through the fusion of late endocytic organelles. This process is mediated by the VacA-dependent retention of the small GTPase Rab7. In addition, functional interactions between Rab7 and its downstream effector, Rab-interacting lysosomal protein (RILP), are necessary for the formation of the bacterial compartment since expression of mutant forms of RILP or Rab7 that fail to bind each other impaired the formation of this unique bacterial niche. Moreover, the VacA-mediated sequestration of active Rab7 disrupts the full maturation of vacuoles as assessed by the lack of both colocalization with cathepsin D and degradation of internalized cargo in the H. pylori-containing vacuole. Based on these findings, we propose that the VacA-dependent isolation of the H. pylori-containing vacuole from bactericidal components of the lysosomal pathway promotes bacterial survival and contributes to the persistence of infection.

Combined effect of water activity and pH on the inhibition of Escherichia coli by nisin.

The Doehlert design and surface response methodology were used to study the influence of pH and water activity (aw) on Escherichia coli inhibition by nisin. Combining stress factors at levels where they are not inhibitory by themselves, a reduction of E. coli survival fraction can be achieved with lower nisin doses than in a single nisin treatment. For all the pH values assayed, a synergistic effect of aw and nisin concentration was detected, and the isoresponse lines showed the existence of an area of maximum inhibition. Factors that reduced viable cell counts by 4 to 5 log cycles were 1,000 to 1,400 IU of nisin per ml at pH 5.5 to 6.5 and a water activity of 0.97 and 0.98. The addition of different ionic and nonionic solutes to control aw suggested that the effect of aw in the inhibitory action of nisin on E. coli cells was not solute-specific. The use of the Doehlert experimental design was effective to determine the optimal combination of stress factors, as well as to point out the most important variables that affected E. coli inhibition.

Combined effect of nisin and pulsed electric fields on the inactivation of Escherichia coli.

The Doehlert design was applied in order to investigate the combined effect of nisin and high voltage pulsed electric fields (PEF) on the inactivation of Escherichia coli in simulated milk ultrafiltrate media. Nisin alone was totally inactivated by PEF, but in the presence of bacterial cells a protective effect was observed. However, the effectiveness of nisin was still decreased when bacterial cells were subjected to the combined treatment. In spite of this phenomenon, an almost additive response emerged as a consequence of the combined treatment. A 4-log cycle reduction may be accomplished with around 1,000 IU/ml (7.15 microM) of nisin and three pulses of 11.25 kV/cm or 500 IU/ml for five pulses of the same intensity. The observed efficacy arising from the combination of both treatments suggests the possibility of using PEF for improving the action spectrum of natural antimicrobials.

Characterization of the protein conferring immunity to the antimicrobial peptide carnobacteriocin B2 and expression of carnobacteriocins B2 and BM1.

Cloning of a 16-kb DNA fragment from the 61-kb plasmid of Carnobacterium piscicola LV17B into plasmidless C. piscicola LV17C restores the production of the plasmid-encoded carnobacteriocin B2 and the chromosomally-encoded carnobacteriocin BM1 and restores the immune phenotype. This fragment also has sufficient genetic information to allow the expression of carnobacteriocin B2 and its immunity in a heterologous host. The gene locus (cbiB2) responsible for immunity to carnobacteriocin B2 is located downstream of the structural gene for carnobacteriocin B2 and encodes a protein of 111 amino acids (CbiB2). CbiB2 was expressed in Escherichia coli as a fusion of the maltose-binding protein and CbiB2. The fusion protein was purified on an amylose column and cleaved with factor Xa, and pure CbiB2 was isolated by high-performance liquid chromatography. The N-terminal amino acid sequence and mass spectrometry (molecular weight [mean +/- standard error], 12,662.2 +/- 3.4) of the purified protein agree with the information deduced from the nucleotide sequence of cbiB2. Western blot (immunoblot) analysis indicates that the majority of the intracellular pool of this immunity protein is in the cytoplasm and that a smaller proportion is associated with the membrane. CbiB2 confers immunity to carnobacteriocin B2, but not to carnobacteriocin BM1, when it is expressed in homologous or heterologous hosts. No protective effect is observed for sensitive cells growing in the presence of the bacteriocin when the immunity protein is added to the medium. The purified immunity protein does not show significant binding to microtiter plates coated with carnobacteriocin B2 and is not able to inactivate the bacteriocin in solution.