The 5'-nucleotidase S5nA is dispensable for evasion of phagocytosis and biofilm formation in Streptococcus pyogenes

Immunomodulating Enzymes from Streptococcus pyogenes-In Pathogenesis, as Biotechnological Tools, and as Biological Drugs

Streptococcus pyogenes, or Group A Streptococcus, is an exclusively human pathogen that causes a wide variety of diseases ranging from mild throat and skin infections to severe invasive disease. The pathogenesis of S. pyogenes infection has been extensively studied, but the pathophysiology, especially of the more severe infections, is still somewhat elusive. One key feature of S. pyogenes is the expression of secreted, surface-associated, and intracellular enzymes that directly or indirectly affect both the innate and adaptive host immune systems. Undoubtedly, S. pyogenes is one of the major bacterial sources for immunomodulating enzymes. Major targets for these enzymes are immunoglobulins that are destroyed or modified through proteolysis or glycan hydrolysis. Furthermore, several enzymes degrade components of the complement system and a group of DNAses degrade host DNA in neutrophil extracellular traps. Additional types of enzymes interfere with cellular inflammatory and innate immunity responses. In this review, we attempt to give a broad overview of the functions of these enzymes and their roles in pathogenesis. For those enzymes where experimentally determined structures exist, the structural aspects of the enzymatic activity are further discussed. Lastly, we also discuss the emerging use of some of the enzymes as biotechnological tools as well as biological drugs and vaccines.

Studies of Streptococcus anginosus Virulence in Dictyostelium discoideum and Galleria mellonella Models

For many years, Streptococcus anginosus has been considered a commensal colonizing the oral cavity, as well as the gastrointestinal and genitourinary tracts. However, recent epidemiological and clinical data designate this bacterium as an emerging opportunistic pathogen. Despite the reported pathogenicity of S. anginosus, the molecular mechanism underpinning its virulence is poorly described. Therefore, our goal was to develop and optimize efficient and simple infection models that can be applied to examine the virulence of S. anginosus and to study host-pathogen interactions. Using 23 S. anginosus isolates collected from different infections, including severe and superficial infections, as well as an attenuated strain devoid of CppA, we demonstrate for the first time that Dictyostelium discoideum is a suitable model for initial, fast, and large-scale screening of virulence. Furthermore, we found that another nonvertebrate animal model, Galleria mellonella, can be used to study the pathogenesis of S. anginosus infection, with an emphasis on the interactions between the pathogen and host innate immunity. Examining the profile of immune defense genes, including antimicrobial peptides, opsonins, regulators of nodulation, and inhibitors of proteases, by quantitative PCR (qPCR) we identified different immune response profiles depending on the S. anginosus strain. Using these models, we show that S. anginosus is resistant to the bactericidal activity of phagocytes, a phenomenon confirmed using human neutrophils. Notably, since we found that the data from these models corresponded to the clinical severity of infection, we propose their further application to studies of the virulence of S. anginosus.

The Use of Galleria mellonella (Wax Moth) as an Infection Model for Group A Streptococcus

Recently, the use of Galleria mellonella larvae as a nonmammalian model to simulate bacterial infectious diseases has shown to be a rapid, simple, and cost-effective alternative. The insect's innate immune response is remarkably similar to that of the vertebrates, and consists of both the cellular and the humoral immune response. Here, we provide a protocol for using G. mellonella larvae to study virulence of GAS, including the use of a health score system for quantitative analysis and the methods for assessing post-infection bacterial burden in vivo.

Cell wall-anchored 5'-nucleotidases in Gram-positive cocci

5'-nucleotidases (5'-NTs) are enzymes that catalyze the hydrolysis of nucleoside monophosphates to produce nucleosides and phosphate. Since the identification of adenosine synthase A (AdsA) in Staphylococcus aureus in 2009, several other 5'-NTs have been discovered in Gram-positive cocci, mainly in streptococci. Despite some differences in substrate specificity, pH range and metal ion requirements, all characterized 5'-NTs use AMP and ADP, and in some cases ATP, to produce the immunosuppressive adenosine, which dampens pro-inflammatory immune responses. Several 5'-NTs are also able to use dAMP as substrate to generate deoxy-adenosine which is cytotoxic for macrophages. A synergy between 5'-NTs and exonucleases which are commonly expressed in Gram-positive cocci has been described, where the nucleases provide dAMP as a cleavage product from DNA. Some of these nucleases produce dAMP by degrading the DNA backbone of neutrophil extracellular traps (NETs) resulting in a "double hit" strategy of immune evasion. This Micro Review provides an overview of the biochemical properties of Gram-positive cell wall-anchored 5'-NTs and their role as virulence factors. A potential use of 5'-NTs for vaccine development is also briefly discussed.