α-Enolase Resides on the Cell Surface of Mycoplasma fermentans and Binds Plasminogen▿

Plasminogen (Plg) binding to the cell surface of Mycoplasma fermentans results in a marked increase in the maximal adherence of the organism to HeLa cells, enhanced Plg activation by the urokinase-type Plg activator, and the induction of the internalization of M. fermentans by eukaryotic host cells (A. Yavlovich, A. Katzenell, M. Tarshis, A. A. Higazi, and S. Rottem, Infect. Immun. 72:5004-5011, 2004). In this study, the M. fermentans Plg binding protein was isolated by affinity chromatography of Triton X-100-solubilized M. fermentans membranes by utilizing a column of a Plg-biotin complex attached to avidin that was eluted with ɛ-aminocaproic acid. The eluted ∼50-kDa protein was identified by mass spectrometric techniques as α-enolase. The possibility that α-enolase, a key cytoplasmatic glycolytic enzyme, resides also on the cell surface of M. fermentans was supported by an immunoblot analysis using polyclonal anti-α-enolase antiserum, which showed that α-enolase was present in a purified M. fermentans membrane preparation, as well as by immunochemical criteria and by immunoelectron microscopy analysis. Our observation that Plg blocked the binding of anti-α-enolase antibodies to a 50-kDa polypeptide band resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of M. fermentans membrane or soluble preparations further supports our notion that mycoplasmal surface α-enolase is a major Plg binding protein of M. fermentans

Mycoplasma fermentans Binds to and Invades HeLa Cells: Involvement of Plasminogen and Urokinase

Adherence of Mycoplasma fermentans to HeLa cells followed saturation kinetics, required a divalent cation, and was enhanced by preincubation of the organism at 37°C for 1 h in a low-osmolarity solution. Proteolytic digestion, choline phosphate, or anti-choline phosphate antibodies partially inhibited the adherence, supporting the notion that M. fermentans utilizes at least two surface components for adhesion, a protease-sensitive surface protein and a phosphocholine-containing glycolipid. Plasminogen binding to M. fermentans greatly increased the maximal adherence of the organism to HeLa cells. Anti-plasminogen antibodies and free plasminogen inhibited this increase. These observations suggest that in the presence of plasminogen the organism adheres to novel sites on the HeLa cell surface, which are apparently plasminogen receptors. Plasminogen-bound M. fermentans was detected exclusively on the cell surface of the infected HeLa cells. Nevertheless, plasminogen binding in the presence of the urokinase-type plasminogen activator (uPA) promoted the invasion of HeLa cells by M. fermentans. The latter finding indicates that the invasiveness of M. fermentans does not result from binding plasminogen but from activation of the bound plasminogen to plasmin. Cholesterol depletion and sequestration with β-cyclodextrin and filipin, respectively, did not affect the capacity of M. fermentans to adhere, but invasion of HeLa cells by uPA-activated plasminogen-bound M. fermentans was impaired, suggesting that lipid rafts are implicated in M. fermentans entry