The proteolytic activity of human plasmin (hPm) is utilized by various cells to provide a surface protease that increases the potential of cells to migrate and disseminate. Skin-trophic Pattern D strains of Streptococcus pyogenes (GAS), e.g., GAS isolate AP53, contain a surface M-protein (PAM) that directly and strongly interacts (Kd ~ 1 nM) with human host plasminogen (hPg), after which it is activated to hPm by a specific coinherited bacterial activator, streptokinase (SK2b), or by host activators. Another ubiquitous class of hPg binding proteins on GAS cells includes “moonlighting” proteins, such as the glycolytic enzyme, enolase (Sen). However, the importance of Sen in hPg acquisition, especially when PAM is present, has not been fully developed. Sen forms a complex with hPg on different surfaces, but not in solution. Isogenic AP53 cells with a targeted deletion of PAM do not bind hPg, but the surface expression of Sen is also greatly diminished upon deletion of the PAM gene, thus confounding this approach for defining the role of Sen. However, cells with point deletions in PAM that negate hPg binding, but fully express PAM and Sen, show that hPg binds weakly to Sen on GAS cells. Despite this, Sen does not stimulate hPg activation by SK2b, but does stimulate tissue-type plasminogen activator-catalyzed activation of hPg. These data demonstrate that PAM plays the dominant role as a functional hPg receptor in GAS cells that also contain surface enolase.
Cellular plasminogen (Pg) receptors (PgRs) are utilized to recruit Pg; stimulate its activation to the serine protease, plasmin (Pm); and sterically protect the surface Pm from inactivation by host inhibitors. One such PgR is the moonlighting enzyme, enolase, some of which leaves the cytoplasm and resides at the cell surface to potentially function as a PgR. Since microbes employ conscription of host Pg by PgRs as one virulence mechanism, we explored the structural basis of the ability of Streptococcus pyogenes enolase (Sen) to function in this manner. Employing single-particle cryo-electron microscopy (cryo-EM), recombinant Sen from S. pyogenes was modeled at 2.6 Å as a stable symmetrical doughnut-shaped homooctamer with point group 422 (D4) symmetry, with a monomeric subunit molecular weight of ∼49 kDa. Binding sites for hPg were reported in other studies to include an internal K 252,255 and the COOH-terminal K 434,435 residues of Sen. However, in native Sen, the latter are buried within the minor interfaces of the octamer and do not function as a Pg-binding epitope. Whereas Sen and hPg do not interact in solution, when Sen is bound to a surface, hPg interacts with Sen independently of K 252,255,434,435 . PgRs devoid of COOH-terminal lysine utilize lysine isosteres comprising a basic residue, "i", and an anionic residue at "i + 3" around one turn of an α-helix. We highlight a number of surface-exposed potential hPg-binding lysine isosteres and further conclude that while the octameric structure of Sen is critical for hPg binding, disruption of this octamer without dissociation exposes hPg-binding epitopes.
Cellular plasminogen (Pg) receptors (PgR) are utilized to recruit Pg, stimulate its activation to the serine protease, plasmin (Pm), and sterically protect the generated Pm from inactivation by natural host inhibitors. The net result is that cells contain a stable proteolytic surface used for biological mechanisms involved in cell migration. One such PgR is the moonlighting enzyme, enolase, some of which leaves the cytoplasm and resides at the cell surface to potentially function as a PgR. Since microbes employ conscription of host Pg by PgRs as one virulence mechanism, we explored the structural basis of the ability of Streptococcus pyogenes enolase (Sen) to function in this regard. Employing single-particle cryo-electron microscopy (cryo-EM), recombinant Sen from S. pyogenes was modeled at 2.6 Angstrom as a stable symmetrical homooctamer displaying point group 422 (D4) symmetry, with a monomeric subunit molecular weight of ~49 kDa. Subunit-subunit interactions showed four major and four minor interfaces in the octamer. Binding sites for hPg were previously proposed to include the COOH-terminal K434,435 residues of Sen, but in native Sen these residues are buried within the minor interfaces of the octamer and do not function as a Pg binding epitope. Whereas Sen and hPg do not interact in solution, when Sen is bound to a surface, hPg interacts with Sen independently of K434,435. We propose that the octameric structure of Sen is important to its ability to interact with hPg, but disruption of its overall octameric conformation without dissociation of the octamer exposes neoepitopes for hPg binding.
Human plasminogen (hPg)-binding M-protein (PAM), a major virulence factor of Pattern D Streptococcus pyogenes (GAS), is the primary receptor responsible for binding and activating hPg. PAM is covalently bound to the cell wall (CW) through cell membrane (CM)-resident sortase A (SrtA)-catalyzed cleavage of the PAM-proximal C-terminal LPST¯-GEAA motif present immediately upstream of its transmembrane domain (TMD), and subsequent transpeptidation to the CW. These steps expose the N-terminus of PAM to the extracellular milieu (EM) to interact with PAM ligands, e.g., hPg. Previously, we found that inactivation of SrtA showed little reduction in functional binding of PAM to hPg, indicating that PAM retained in the cell membrane (CM) by the TMD nonetheless exposed its N-terminus to the EM. In the current study, we assessed the effects of mutating the Thr4 (P1) residue of the SrtA-cleavage site in PAM (Thr355 in PAM) to delay PAM in the CM in the presence of SrtA. Using rSrtA in vitro, LPSYGEAA and LPSWGEAA peptides were shown to have low activities, while LPSTGEAA had the highest activity. Isolated CM fractions of AP53/DSrtA cells showed that LPSYGEAA and LPSWGEAA peptides were cleaved at substantially faster rates than LPSTGEAA, even in CMs with an AP53/DSrtA/PAM[T355Y] double mutation, but the transpeptidation step did not occur. These results implicate another CM-resident enzyme that cleaves LPSYGEAA and LPSWGEAA motifs, most likely LPXTGase, but cannot catalyze the transpeptidation step. We conclude that the natural P1 (Thr) of the SrtA cleavage site has evolved to dampen PAM from nonfunctional cleavage by LPXTGase.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.