The VC1777-VC1779 proteins are members of a sialic acid-specific subfamily of TRAP transporters (SiaPQM) and constitute the sole route of sialic acid uptake in the human pathogen Vibrio cholerae.

Sialic acids are nine-carbon amino sugars that are present on all mucous membranes and are often used by bacteria as nutrients. In pathogenic Vibrio the genes for sialic acid catabolism (SAC) are known to be important for host colonization, yet the route for sialic acid uptake is not proven. Vibrio cholerae contains a tripartite ATP-independent periplasmic (TRAP) transporter, SiaPQM (VC1777-VC1779), encoded by genes within the Vibrio pathogenicity island-2 (VPI-2), which are adjacent to the SAC genes nanA, nanE and nanK. We demonstrate a correlation of the occurrence of VPI-2 and the ability of Vibrio to grow on the common sialic acid N-acetylneuraminic acid (Neu5Ac), and that a V. cholerae N16961 mutant defective in vc1777, encoding the large membrane protein component of the TRAP transporter, SiaM, is unable to grow on Neu5Ac as the sole carbon source. Using the genome context and known structures of the SiaP protein component of the TRAP transporter, we define a subfamily of Neu5Ac-specific TRAP transporters, of which the vc1777-vc1779 genes are the only representatives in V. cholerae. A recent report has suggested that an entirely different TRAP transporter (VC1927-VC1929) is the Neu5Ac transporter in V. cholerae. Bioinformatics and genomic analysis suggest strongly that this is a C(4)-dicarboxylate-specific TRAP transporter, and indeed disruption of vc1929 results in a defect in growth on C(4)-dicarboxylates but not Neu5Ac. Together these data demonstrate unequivocally that the siaPQM-encoded TRAP transporter within VPI-2 is the sole sialic acid transporter in V. cholerae.

Glycoprotein M is important for the efficient incorporation of glycoprotein H-L into herpes simplex virus type 1 particles.

Herpes simplex virus type 1 glycoprotein M (gM) is a type III membrane protein conserved throughout the family Herpesviridae. However, despite this conservation, gM is classed as a non-essential protein in most alphaherpesviruses. Previous data have suggested that gM is involved in secondary envelopment, although how gM functions in this process is unknown. Using transfection-based assays, we have previously shown that gM is able to mediate the internalization and subcellular targeting of other viral envelope proteins, suggesting a possible role for gM in localizing herpesvirus envelope proteins to sites of secondary envelopment. To investigate the role of gM in infected cells, we have now analysed viral envelope protein localization and virion incorporation in cells infected with a gM-deletion virus or its revertant. In the absence of gM expression, we observed a substantial inhibition of glycoprotein H-L (gH-L) internalization from the surface of infected cells. Although deletion of gM does not affect expression of gH and gL, virions assembled in the absence of gM demonstrated significantly reduced levels of gH-L, correlating with defects of the gM-negative virus in entry and cell-to-cell spread. These data suggest an important role of gM in mediating the specific internalization and efficient targeting of gH-L to sites of secondary envelopment in infected cells.