Chapter 114. Molecular Mechanisms of Microbial Pathogenesis (Part 3)

Viral Adhesins(See also Chap. 161) All viral pathogens must bind to host cells, enter them, and replicate within them. Viral coat proteins serve as the ligands for cellular entry, and more than one ligand-receptor interaction may be needed; for example, HIV uses its envelope glycoprotein (gp) 120 to enter host cells by binding to both CD4 and one of two receptors for chemokines (designated CCR5 and CXCR4). Similarly, the measles virus H glycoprotein binds to both CD46 and the membrane-organizing protein moesin on host cells. The gB and gC proteins on herpes simplex virus bind to heparan sulfate; this...
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Chapter 114. Molecular Mechanisms of Microbial Pathogenesis (Part 3) Chapter 114. Molecular Mechanisms of Microbial Pathogenesis (Part 3) Viral Adhesins (See also Chap. 161) All viral pathogens must bind to host cells, enterthem, and replicate within them. Viral coat proteins serve as the ligands forcellular entry, and more than one ligand-receptor interaction may be needed; forexample, HIV uses its envelope glycoprotein (gp) 120 to enter host cells bybinding to both CD4 and one of two receptors for chemokines (designated CCR5and CXCR4). Similarly, the measles virus H glycoprotein binds to both CD46 andthe membrane-organizing protein moesin on host cells. The gB and gC proteins onherpes simplex virus bind to heparan sulfate; this adherence is not essential forentry but rather serves to concentrate virions close to the cell surface. This step isfollowed by attachment to mammalian cells mediated by the viral gD protein.Herpes simplex virus can use a number of eukaryotic cell surface receptors forentry, including the herpesvirus entry mediator (related to the tumor necrosisfactor receptor); members of the immunoglobulin superfamily; two proteins callednectin-1 and nectin-2; and modified heparan sulfate. Bacterial Adhesins Among the microbial adhesins studied in greatest detail are bacterial piliand flagella (Fig. 114-1). Pili or fimbriae are commonly used by gram-negativeand gram-positive bacteria for attachment to host cells and tissues. In electronmicrographs, these hairlike projections (up to several hundred per cell) may beconfined to one end of the organism (polar pili) or distributed more evenly overthe surface. An individual cell may have pili with a variety of functions. Most piliare made up of a major pilin protein subunit (molecular weight, 17,000–30,000)that polymerizes to form the pilus. Many strains of Escherichia coli isolated fromurinary tract infections express mannose-binding type 1 pili, whose binding to theintegral membrane glycoproteins called uroplakins that coat the cells in thebladder epithelium is inhibited by D-mannose. Other strains produce the Pap(pyelonephritis-associated) or P pilus adhesin that mediates binding to digalactose(gal-gal) residues on globosides of the human P blood groups. Both of these typesof pili have proteins located at the tips of the main pilus unit that are critical to thebinding specificity of the whole pilus unit. It is interesting that, althoughimmunization with the mannose-binding tip protein (FimH) of type 1 pili preventsexperimental E. coli bladder infections in mice and monkeys, a trial of this vaccinein humans was not successful. E. coli cells causing diarrheal disease express pilus-like receptors for enterocytes on the small bowel, along with other receptorstermed colonization factors. Figure 114-1 Bacterial surface structures. A and B. Traditional electron micrographicimages of fixed cells of Pseudomonas aeruginosa. Flagella (A) and pili (B)projecting out from the bacterial poles can be seen. C and D. Atomic forcemicroscopic image of live P. aeruginosa freshly planted onto a smooth micasurface. This technology reveals the fine, three-dimensional detail of the bacterialsurface structures. (Images courtesy of Dr. Martin Lee and Dr. Milan Bajmoczi,Harvard Medical School.) The type IV pilus, a common type of pilus found in Neisseria spp.,Moraxella spp., Vibrio cholerae, Legionella pneumophila, Salmonella entericaserovar typhi, enteropathogenic E. coli, and Pseudomonas aeruginosa, mediatesadherence of these organisms to target surfaces. These pili tend to have a relativelyconserved amino-terminal region and a more variable carboxyl-terminal region.For some species (e.g., N. gonorrhoeae, Neisseria meningitidis, andenteropathogenic E. coli), the pili are critical for attachment to mucosal epithelialcells. For others, such as P. aeruginosa, the pili only partially mediate the cellsadherence to host tissues. Whereas interference with this stage of colonizationwould appear to be an effective antibacterial strategy, attempts to develop pilus-based vaccines for human diseases have not been highly successful to date.