pylori infection, independently of VacA and CagA. Loss of Cav1 has been associated with a more severe gastritis, accompanied by a strong macrophage infiltration into the infected gastric mucosa and by an increased sensitivity to selleck chemicals CagA-related cell stress (i.e., hummingbird phenotype) [38]. These results support a protective
role for Cav1 against H. pylori-induced inflammation and tissue damage. Although there is currently conflicting evidence concerning the relationship between H. pylori and host antimicrobial peptides, which could also be influenced by cholesterol availability or other variable growth conditions, without any doubt, H. pylori is able to modulate the expression of antimicrobial peptides, and this may contribute to its persistence in the gastric mucosa. A study demonstrated that H. pylori
induces the expression of the defensin HBD2 and of elafin, an antiprotease endowed with microbicidal find protocol activity [39]. However, both of these antimicrobials were minimally active against H. pylori. On the contrary, the defensin HBD3 and the cathelicidin LL-37 which efficiently kill H. pylori were negligibly expressed during the infection. In contrast with the latter evidence, a previous report demonstrated that gastric mucosa from H. pylori-infected patients expresses and secretes a large amount of LL-37 [40]. Moreover, a more recent study performed in mice and aimed to address the role of CRAMP, the mouse homologue of the human LL-37, also revealed that the cathelicidin CYTH4 exerts an important antimicrobial action in vivo, as the ablation
of the gene significantly increased the susceptibility toward H. pylori colonization and the associated gastritis [41]. Conflicting evidence also exists concerning the role of the defensin HBD1. While the study of Nuding et al. [39] revealed that HBD1 transcripts did not differ significantly between H. pylori-negative and -positive subjects, another study reported just the opposite [42]. Not only did H. pylori-infected patients express less HBD1 in the gastric mucosa than the healthy counterparts, but notably, this correlates with an increased burden of infection and a higher inflammatory score. Moreover, the same authors demonstrated that the downregulation of HBD1, resulting from an interference in the NF-κB signaling pathway, requires the engagement by the Type IV secretion system of a5b1 integrin as well as NOD activation in gastric epithelial cells. The above-mentioned mechanisms of host interaction may ultimately lead to cell modulation and cancerogenesis. Innate immune activation of different cell types by H. pylori is crucial for host defense and might, on the other hand, provide factors promoting DNA damage and cancer. One bacterial factor activating innate responses is the cagPAI, and in addition to gastric epithelial cells, new studies describe its particular effects on neutrophils [43] and dendritic cells [44].