Many bacterial pathogens of the intestinal tract have as an early and necessary step in initiation of disease the ability to penetrate gut epithelial cells. My lab's work in the early 1980's established that Shigella's genetic machinery to trigger invasion is encoded on a large virulence-associated plasmid. More recent studies have shown that the invasion ability of other enteric bacteria is chromosomally encoded. This project is aimed at understanding the prokaryotic and eukaryotic requirements for bacterial internalization, with the ultimate aim being a thorough molecular definition of the events involved in bacterial invasion of eukaryotic tissues. Current experimental approaches involve the use of assays measuring bacterial entry into cultured lines of human epithelial cells of various tissue origins. Biochemical inhibitors of prokaryotic structure/function or of eukaryotic cell processes are employed in these tissue culture invasion assays to examine the requirements for bacterial uptake. Direct visualization of bacterial entry is measured via transmission electron microscopy,video microscopy,fluorescent microscopy, and confocal microscopy. In addition to the approaches described above, genetic techniques are employed to clone the responsible bacterial genes. Eukaryotic receptors for bacterial ligands and specific eukaryotic cell responses to bacterial invasion are measured via inhibitor competition assays, ligand binding assays, and mRNA analyses of infected eukaryotic cells. The information gained from each of these approaches is integrated to provide a mechanistic understanding of bacterial entry for each pathway studied. Recent progress has revealed that Campylobacter jejuni invasion is dependent upon host microtubules but not microfilaments. Apparent signalling by the approaching bacterium triggers the host cell to extend a microtubule-based, fingerlike projection. C. jejuni interacts with a host receptor located in membrane caveolae at the tip of this membrane extension. This bacterial-host """"""""ligand -receptor"""""""" interaction activates a signal transduction cascade that releases Ca++ from intracellular stores and activates PI-3 kinase, calmodulin, and protein kinase C, which are required for C. jejuni internalization. The entering bacterium within an endosome moves via dynein and microtubules to the perinuclear region over 4 hrs.

Agency
National Institute of Health (NIH)
Institute
Center for Biologics Evaluation and Research - Bactrial Products (CBERBP)
Type
Intramural Research (Z01)
Project #
1Z01BJ005007-08
Application #
6543541
Study Section
(LEST)
Project Start
Project End
Budget Start
Budget End
Support Year
8
Fiscal Year
2001
Total Cost
Indirect Cost