Inhibition of antimicrobial peptides by group A streptococci: SIC and DRS.

SIC (streptococcal inhibitor of complement) is a 31 kDa protein secreted by a few highly virulent strains of GAS (group A streptococci), predominantly by the M1 strain. Initially described as an inhibitor of the membrane attack complex of complement, it has turned out to be a polyfunctional inhibitor of the innate mucosal immune response. The SIC protein sequence contains three domains: an N-terminal SRR (short repeat region), followed by three longer tandem repeats [LRR (long repeat region)] and a C-terminal PRR (proline-rich region). SIC inhibits the antibacterial activity of a wide range of antimicrobial peptides and proteins: i.e. lysozyme, SLPI (secretory leucocyte proteinase inhibitor), LL-37, hNP-1 (human neutrophil peptide-1) and the human beta-defensins 1, 2 and 3. Analysis of the functional properties of recombinant domains of SIC shows that binding and inhibition of lysozyme and human beta-defensin-3 require the SRR+LRR, as does binding to SLPI. Complement inhibition is confined to the SRR. M12 GAS secrete a protein 'distantly related to SIC' (DRS). DRS contains a C-terminal PRR which is significantly similar to that of SIC, but it has no central LRR and the N-terminal SRR is very different. DRS inhibits human beta-defensin-3, but has no effect on lysozyme, SLPI or complement.

Antimicrobial peptides: mediators of innate immunity as templates for the development of novel anti-infective and immune therapeutics.

Antimicrobial molecules are ancient and essential small cationic molecules of the host defence system which are found in a wide variety of species. They display antimicrobial activity against a wide range of bacteria, fungi and viruses, an activity that has been mostly attributed to the disruption of microbial membranes. In this article, we will review the "classical" functions of 3 classes of antimicrobial molecules, namely defensins, cathelicidins, and the four-disulfide core proteins secretory leukocyte proteinase inhibitor (SLPI) and elafin. In addition to the study of their expression in a variety of cell types and the regulation of their production, we will also describe novel properties of these molecules that have been highlighted by recent studies. These include their ability to chemoattract a variety of inflammatory, immune and other cell types (neutrophils, macrophages, monocytes, lymphocytes, mast cells, epithelial cells) in vitro and in vivo. In addition, we will discuss the potential use of these newly discovered properties for therapeutic or vaccination purposes, using protein- or gene-transfer based methodologies. Finally, we will examine in an extensive fashion the strategies used by microorganisms to circumvent and subvert host defence mechanisms, such as the modifications of cell membranes and walls, the secretion of inactivating proteins and proteases and the down-regulation of expression of antimicrobial molecules. Increased understanding of the mechanisms used by both the host and the microbes to 'win the battle' may ultimately lead to new therapeutic strategies aimed to treat infectious diseases.

Streptococcal inhibitor of complement (SIC) inhibits the membrane attack complex by preventing uptake of C567 onto cell membranes.

Streptococcal inhibitor of complement (SIC) was first described in 1996 as a putative inhibitor of the membrane attack complex of complement (MAC). SIC is a 31 000 MW protein secreted in large quantities by the virulent Streptococcus pyogenes strains M1 and M57, and is encoded by a gene which is extremely variable. In order to study further the interactions of SIC with the MAC, we have made a recombinant form of SIC (rSIC) in Escherichia coli and purified native M1 SIC which was used to raise a polyclonal antibody. SIC prevented reactive lysis of guinea pig erythrocytes by the MAC at a stage prior to C5b67 complexes binding to cell membranes, presumably by blocking the transiently expressed membrane insertion site on C7. The ability of SIC and clusterin (another putative fluid phase complement inhibitor) to inhibit complement lysis was compared, and found to be equally efficient. In parallel, by enzyme-linked immunosorbent assay both SIC and rSIC bound strongly to C5b67 and C5b678 complexes and to a lesser extent C5b-9, but only weakly to individual complement components. The implications of these data for virulence of SIC-positive streptococci are discussed, in light of the fact that Gram-positive organisms are already protected against complement lysis by the presence of their peptidoglycan cell walls. We speculate that MAC inhibition may not be the sole function of SIC.