Divergent mechanisms of interaction of Helicobacter pylori and Campylobacter jejuni with mucus and mucins.

Helicobacter pylori and Campylobacter jejuni colonize the stomach and intestinal mucus, respectively. Using a combination of mucus-secreting cells, purified mucins, and a novel mucin microarray platform, we examined the interactions of these two organisms with mucus and mucins. H. pylori and C. jejuni bound to distinctly different mucins. C. jejuni displayed a striking tropism for chicken gastrointestinal mucins compared to mucins from other animals and preferentially bound mucins from specific avian intestinal sites (in order of descending preference: the large intestine, proximal small intestine, and cecum). H. pylori bound to a number of animal mucins, including porcine stomach mucin, but with less avidity than that of C. jejuni for chicken mucin. The strengths of interaction of various wild-type strains of H. pylori with different animal mucins were comparable, even though they did not all express the same adhesins. The production of mucus by HT29-MTX-E12 cells promoted higher levels of infection by C. jejuni and H. pylori than those for the non-mucus-producing parental cell lines. Both C. jejuni and H. pylori bound to HT29-MTX-E12 mucus, and while both organisms bound to glycosylated epitopes in the glycolipid fraction of the mucus, only C. jejuni bound to purified mucin. This study highlights the role of mucus in promoting bacterial infection and emphasizes the potential for even closely related bacteria to interact with mucus in different ways to establish successful infections.

Cellular and molecular actions of dinitroaniline and phosphorothioamidate herbicides on Plasmodium falciparum: tubulin as a specific antimalarial target.

Microtubules play important roles in cell division, motility and structural integrity of malarial parasites. Some microtubule inhibitors disrupt parasite development at very low concentrations, but most of them also kill mammalian cells. However, the dinitroaniline family of herbicides, which bind specifically to plant tubulin, have inhibitory activity on plant cells but are relatively non-toxic to human cells. Certain dinitroanilines are also inhibitory to various protozoal parasites including Plasmodium. Here we demonstrate that the dinitroanilines trifluralin and oryzalin inhibited progression of erythrocytic Plasmodium falciparum through schizogony, blocked mitotic division, and caused accumulation of abnormal microtubular structures. Moreover, radiolabelled trifluralin interacted with purified, recombinant parasite tubulins but to a much lesser extent with bovine tubulins. The phosphorothioamidate herbicide amiprophos-methyl, which has the same herbicidal mechanism as dinitroanilines, also had antimalarial activity and a similar action on schizogony. These data suggest that P. falciparum tubulin contains a dinitroaniline/phosphorothioamidate-binding site that is not conserved in humans and might be a target for new antimalarial drugs.

Accumulation of the antimalarial microtubule inhibitors trifluralin and vinblastine by Plasmodium falciparum.

Malaria is a disease in desperate need of new chemotherapeutic approaches. Certain microtubule inhibitors, including vinblastine and taxol, have highly potent activity against malarial parasites and disrupt the normal microtubular structures of intra-erythrocytic parasites at relevant concentrations. While these inhibitors are useful tools, their potential as anti-malarial drugs is limited by their high toxicity to mammalian cells. In contrast, two classes of antimitotic herbicide, namely dinitroanilines (e.g. trifluralin and oryzalin) and phosphorothioamidates (e.g. amiprophosmethyl), exhibit moderate activity against the major human malarial parasite Plasmodium falciparum in culture but very low mammalian cytotoxicity. We examined the dynamics and kinetics of uptake and subcellular compartmentation of [14C]trifluralin in comparison with [3H]vinblastine. We wished to determine whether the relatively modest activity of trifluralin was the consequence of poor uptake into parasite cells. Trifluralin accumulated in parasite-infected erythrocytes to approximately 300 times the external concentration and vinblastine at up to approximately 110 times. Accumulation into uninfected erythrocytes was much lower. Uptake of trifluralin was rapid, non-saturable and readily reversed. It appears that the hydrophobic nature of trifluralin leads to accumulation largely in the membranes of the parasite, reducing the levels in the soluble fraction and limiting access to its microtubular target. By contrast, vinblastine accumulated predominantly in the soluble fraction and uptake was saturable and mostly irreversible, consistent with binding predominantly to tubulin. The results indicate that synthesis of more polar trifluralin derivatives may be a promising approach to designing microtubule inhibitors with more potent antimalarial activity.