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. 1997 Jun;65(6):2353–2361. doi: 10.1128/iai.65.6.2353-2361.1997

Differential recognition of members of the carcinoembryonic antigen family by Opa variants of Neisseria gonorrhoeae.

M P Bos 1, F Grunert 1, R J Belland 1
PMCID: PMC175326  PMID: 9169774

Abstract

Opacity (Opa) protein variation in Neisseria gonorrhoeae is implicated in the pathogenesis of gonorrhea, possibly by mediating adherence and entry of the bacteria into human tissues. One particular Opa protein mediates adherence to epithelial cells through cell surface proteoglycans. Recently, two other eukaryotic cell receptors for Opa proteins have been reported. These receptors are members of a subgroup of the carcinoembryonic (CEA) gene family that express CD66 antigens. CEA family members vary in their distribution in human tissues. In order to understand whether interactions between Opa and CEA-like molecules play any role in pathogenesis, we must investigate which CEA family members are able to serve as Opa receptors and which Opa proteins recognize CEA-like molecules. We therefore studied HeLa cells that were stably transfected with five different members of the CEA family, i.e., CEA, CEA gene family member 1a (CGM1a), CGM6, nonspecific cross-reacting antigen (NCA), and biliary glycoprotein a (BGPa). We infected these transfectants with all possible 11 Opa variants of gonococcal strain MS11 and determined the numbers of bacteria that were bound and internalized. To account for proteoglycan-mediated adherence, infection assays were also performed in the presence of heparin. Our results show that of the 11 Opa variants of MS11, the same 4 recognized CGM1a and NCA. CGM6, however, was not recognized by any Opa variant of MS11. CEA was recognized by at least 9 of 11 Opa variants, and the BGP transfectants specifically bound and internalized 10 of 11 Opa variants and also bound Opa-negative gonococci. Immunofluorescence experiments showed that clustering of CEA-like molecules occurred upon infection of HeLa transfectants with those Opa variants that interacted specifically with the CEA family member. Together these data show that CEA family members are differentially recognized by gonococcal Opa variants, suggesting that this phenomenon may contribute to cell tropism displayed by gonococci.

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Selected References

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