Structural properties of fibrillar proteins isolated from the cell surface and cytoplasm of Streptococcus salivarius (K+) cells and nonadhesive mutants.

J Bacteriol. 1986 March; 165(3): 756–762.

PMCID: PMC214493

A H Weerkamp, H C van der Mei, and R S Liem

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Abstract

Most Streptococcus salivarius (K+) cells contain two protein antigens with different adhesive functions. The subcellular distribution and some structural properties of purified proteins were studied. Antigen B (AgB), a protein involved in interbacterial coaggregation with gram-negative bacteria, was present in the cell wall fraction only of the wild-type strain and was absent from the cells of a nonadhesive mutant. Antigen C (AgC), a glycoprotein involved in host-associated adhesive functions, was predominantly associated with the cell wall of the wild-type strain (AgCw), but accumulated in high amounts in the cytoplasmic fraction (AgCin) of mutants lacking the wall-associated form. AgB, AgCw, and AgCin had molecular weights of 380,000, 250,000 to 320,000, and 488,000, respectively, upon gel electrophoresis under nondenaturing conditions. In the presence of sodium dodecyl sulfate and beta-mercaptoethanol the molecular weights were only slightly lower, suggesting that the free, isolated molecules exist as monomers under native conditions. AgCin readily stained with periodate-Schiff reagent, indicating a significant content of carbohydrate, similar to AgCw. Circular dichroism spectra showed that about 45% of the amino acids of AgCw were involved in alpha-helical coiled structures. AgB had a significantly lower proportion of ordered coiled structure. Electron microscopic observations of low-angle-shadowed preparations of purified antigens showed that they were flexible, thin rods with thickened or globular ends. Measurements corrected for shadow thickness showed lengths of 184 nm (AgB), 112 nm (AgCin), and 87 nm (AgCw). Treatment of AgCw with protease destroyed the fibrillar core, but seemed not to affect the globular ends. Comparison of the results with the localization of the antigens in wild-type and specific mutant strains suggested that each antigen molecule may represent a single, characteristic surface fibril with a specific adhesive capacity.

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Selected References

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