Antimicrobial activity of community-associated methicillin-resistant Staphylococcus aureus is caused by phenol-soluble modulin derivatives

Community-associated methicillin-resistant Staphylococcus aureus (CA-MRSA) are causing an ongoing pandemic of mostly skin and soft tissue infections. The success of CA-MRSA as pathogens is due to a combination of antibiotic resistance with high virulence. In addition, it has been speculated that CA-MRSA strains such as the epidemic U.S. clone USA300 have increased capacity to colonize human epithelia, owing to bacteriocin-based bacterial interference. We here analyzed the molecular basis of antimicrobial activity detected in S. aureus strains, including those of the USA300 lineage. In contrast to a previous hypothesis, we found that this activity is not due to expression of a lantibiotic-type bacteriocin, but proteolytically processed derivatives of the phenol-soluble modulin (PSM) peptides PSMα1 and PSMα2. Notably, processed PSMα1 and PSMα2 exhibited considerable activity against Streptococcus pyogenes, indicating a role of PSMs in the interference of S. aureus strains with the competing colonizing pathogen. Furthermore, by offering a competitive advantage during colonization of the human body, the characteristically high production of PSMs in USA300 and other CA-MRSA strains may thus contribute not only to virulence but also the exceptional capacity of those strains to sustainably spread in the population, which so far has remained poorly understood.     

Direct and synergistic hemolysis caused by Staphylococcus phenol-soluble modulins: implications for diagnosis and pathogenesis

Phenol-soluble modulins are secreted staphylococcal peptides with an amphipathic α-helical structure. Some PSMs are strongly cytolytic toward human neutrophils and represent major virulence determinants during Staphylococcus aureus skin and blood infection. However, capacities of PSMs to lyse human erythrocytes have not been investigated. Here, we demonstrate that many S. aureus and Staphylococcus epidermidis PSMs lyse human erythrocytes. Furthermore, synergism with S. aureus β-toxin considerably increased the hemolytic capacities of several PSMs. This synergism may be of key importance in PSM and β-toxin-producing S. aureus or in mixed-strain or -species infections with PSM and β-toxin producers. Of specific interest, several PSMs, in particular PSMα peptides, contributed to a considerable extent to synergistic hemolysis with β-toxin or when using the β-toxin-producing strain RN4220 in CAMP assays. Thus, CAMP-type assays should not be used to detect or quantify S. aureus δ-toxin production, but may be used for an overall assessment of Agr functionality. Our study suggests an additional role of PSMs in staphylococcal pathogenesis and demonstrates that the repertoire of staphylococcal hemolysins is not limited to S. aureus and is much larger and diverse than previously thought.     

Identification of novel cytolytic peptides as key virulence determinants for community-associated MRSA

Methicillin-resistant Staphylococcus aureus (MRSA) remains a major human pathogen. Traditionally, MRSA infections occurred exclusively in hospitals and were limited to immunocompromised patients or individuals with predisposing risk factors. However, recently there has been an alarming epidemic caused by community-associated (CA)-MRSA strains, which can cause severe infections that can result in necrotizing fasciitis or even death in otherwise healthy adults outside of healthcare settings. In the US, CA-MRSA is now the cause of the majority of infections that result in trips to the emergency room. It is unclear what makes CA-MRSA strains more successful in causing human disease compared with their hospital-associated counterparts. Here we describe a class of secreted staphylococcal peptides that have a remarkable ability to recruit, activate and subsequently lyse human neutrophils, thus eliminating the main cellular defense against S. aureus infection. These peptides are produced at high concentrations by standard CA-MRSA strains and contribute significantly to the strains' ability to cause disease in animal models of infection. Our study reveals a previously uncharacterized set of S. aureus virulence factors that account at least in part for the enhanced virulence of CA-MRSA.     

Staphylococcus epidermidis strategies to avoid killing by human neutrophils

Staphylococcus epidermidis is a leading nosocomial pathogen. In contrast to its more aggressive relative S. aureus, it causes chronic rather than acute infections. In highly virulent S. aureus, phenol-soluble modulins (PSMs) contribute significantly to immune evasion and aggressive virulence by their strong ability to lyse human neutrophils. Members of the PSM family are also produced by S. epidermidis, but their role in immune evasion is not known. Notably, strong cytolytic capacity of S. epidermidis PSMs would be at odds with the notion that S. epidermidis is a less aggressive pathogen than S. aureus, prompting us to examine the biological activities of S. epidermidis PSMs. Surprisingly, we found that S. epidermidis has the capacity to produce PSMδ, a potent leukocyte toxin, representing the first potent cytolysin to be identified in that pathogen. However, production of strongly cytolytic PSMs was low in S. epidermidis, explaining its low cytolytic potency. Interestingly, the different approaches of S. epidermidis and S. aureus to causing human disease are thus reflected by the adaptation of biological activities within one family of virulence determinants, the PSMs. Nevertheless, S. epidermidis has the capacity to evade neutrophil killing, a phenomenon we found is partly mediated by resistance mechanisms to antimicrobial peptides (AMPs), including the protease SepA, which degrades AMPs, and the AMP sensor/resistance regulator, Aps (GraRS). These findings establish a significant function of SepA and Aps in S. epidermidis immune evasion and explain in part why S. epidermidis may evade elimination by innate host defense despite the lack of cytolytic toxin expression. Our study shows that the strategy of S. epidermidis to evade elimination by human neutrophils is characterized by a passive defense approach and provides molecular evidence to support the notion that S. epidermidis is a less aggressive pathogen than S. aureus.     

Functional Amyloids Composed of Phenol Soluble Modulins Stabilize Staphylococcus aureus Biofilms

Staphylococcus aureus is an opportunistic pathogen that colonizes the skin and mucosal surfaces of mammals. Persistent staphylococcal infections often involve surface-associated communities called biofilms. Here we report the discovery of a novel extracellular fibril structure that promotes S. aureus biofilm integrity. Biochemical and genetic analysis has revealed that these fibers have amyloid-like properties and consist of small peptides called phenol soluble modulins (PSMs). Mutants unable to produce PSMs were susceptible to biofilm disassembly by matrix degrading enzymes and mechanical stress. Previous work has associated PSMs with biofilm disassembly, and we present data showing that soluble PSM peptides disperse biofilms while polymerized peptides do not. This work suggests the PSMs'' aggregation into amyloid fibers modulates their biological activity and role in biofilms.     

葡萄球菌致病毒力因子酚溶性调节蛋白的研究进展

葡萄球菌是临床常见的革兰氏阳性致病菌,包括表皮葡萄球菌和金黄色葡萄球菌等.随着耐药葡萄球菌的出现,尤其是多药耐药葡萄球菌的传播和蔓延,其感染性疾病的发病率和死亡率逐年升高.葡萄球菌的高致病性与其表达大量毒力因子密切相关.酚溶性调节蛋白(phenol-soluble modulin,PSM)是一组具有广泛溶细胞活性的两亲...     

RNAIII-independent target gene control by the agr quorum-sensing system: insight into the evolution of virulence regulation in Staphylococcus aureus

Cell-density-dependent gene regulation by quorum-sensing systems has a crucial function in bacterial physiology and pathogenesis. We demonstrate here that the Staphylococcus aureus agr quorum-sensing regulon is divided into (1) control of metabolism and PSM cytolysin genes, which occurs independently of the small regulatory RNA RNAIII, and (2) RNAIII-dependent control of additional virulence genes. Remarkably, PSM expression was regulated by direct binding of the AgrA response regulator. Our findings suggest that quorum-sensing regulation of PSMs was established before wide-ranging control of virulence was added to the agr regulon, which likely occurred by development of the RNAIII-encoding region around the gene encoding the PSM delta-toxin. Moreover, the agr regulon in the community-associated methicillin-resistant S. aureus MW2 considerably differed from that previously determined using laboratory strains. By establishing a two-level model of quorum-sensing target gene regulation in S. aureus, our study gives important insight into the evolution of virulence control in this leading human pathogen.     

A novel core genome-encoded superantigen contributes to lethality of community-associated MRSA necrotizing pneumonia

Bacterial superantigens (SAg) stimulate T-cell hyper-activation resulting in immune modulation and severe systemic illnesses such as Staphylococcus aureus toxic shock syndrome. However, all known S. aureus SAgs are encoded by mobile genetic elements and are made by only a proportion of strains. Here, we report the discovery of a novel SAg staphylococcal enterotoxin-like toxin X (SElX) encoded in the core genome of 95% of phylogenetically diverse S. aureus strains from human and animal infections, including the epidemic community-associated methicillin-resistant S. aureus (CA-MRSA) USA300 clone. SElX has a unique predicted structure characterized by a truncated SAg B-domain, but exhibits the characteristic biological activities of a SAg including Vβ-specific T-cell mitogenicity, pyrogenicity and endotoxin enhancement. In addition, SElX is expressed by clinical isolates in vitro, and during human, bovine, and ovine infections, consistent with a broad role in S. aureus infections of multiple host species. Phylogenetic analysis suggests that the selx gene was acquired horizontally by a progenitor of the S. aureus species, followed by allelic diversification by point mutation and assortative recombination resulting in at least 17 different alleles among the major pathogenic clones. Of note, SElX variants made by human- or ruminant-specific S. aureus clones demonstrated overlapping but distinct Vβ activation profiles for human and bovine lymphocytes, indicating functional diversification of SElX in different host species. Importantly, SElX made by CA-MRSA USA300 contributed to lethality in a rabbit model of necrotizing pneumonia revealing a novel virulence determinant of CA-MRSA disease pathogenesis. Taken together, we report the discovery and characterization of a unique core genome-encoded superantigen, providing new insights into the evolution of pathogenic S. aureus and the molecular basis for severe infections caused by the CA-MRSA USA300 epidemic clone.     

Host chemokines bind to Staphylococcus aureus and stimulate protein A release

There are few examples of host signals that are beneficial to bacteria during infection. Here we found that 31 out of 42 host immunoregulatory chemokines were able to induce release of the virulence factor protein A (SPA) from a strain of community-associated methicillin-resistant Staphylococcus aureus (CA-MRSA). Detailed study of chemokine CXCL9 revealed that SPA release occurred through a post-translational mechanism and was inversely proportional to bacterial density. CXCL9 bound specifically to the cell membrane of CA-MRSA, and the related SPA-releasing chemokine CXCL10 bound to both cell wall and cell membrane. Clinical samples from patients infected with S. aureus and samples from a mouse model of CA-MRSA skin abscess all contained extracellular SPA. Further, SPA-releasing chemokines were present in mouse skin lesions infected with CA-MRSA. Our data identify a potential new mode of immune evasion, in which the pathogen exploits a host defense factor to release a virulence factor; moreover, chemokine binding may serve a scavenging function in immune evasion by S. aureus.     

The Staphylococcus aureus surface protein IsdA mediates resistance to innate defenses of human skin

Resistance to human skin innate defenses is crucial for survival and carriage of Staphylococcus aureus, a common cutaneous pathogen and nasal colonizer. Free fatty acids extracted from human skin sebum possess potent antimicrobial activity against S. aureus. The mechanisms by which S. aureus overcomes this host defense during colonization remain unknown. Here, we show that S. aureus IsdA, a surface protein produced in response to the host, decreases bacterial cellular hydrophobicity rendering them resistant to bactericidal human skin fatty acids and peptides. IsdA is required for survival of S. aureus on live human skin. Reciprocally, skin fatty acids prevent the production of virulence determinants and the induction of antibiotic resistance in S. aureus and other Gram-positive pathogens. A purified human skin fatty acid was effective in treating systemic and topical infections of S. aureus suggesting that our natural defense mechanisms can be exploited to combat drug-resistant pathogens.     

Cross-talk between Staphylococcus aureus leukocidins-intoxicated macrophages and lung epithelial cells triggers chemokine secretion in an inflammasome-dependent manner

Staphylococcus aureus is a major pathogen responsible for both nosocomial and community-acquired infections. Central to its virulence is its ability to secrete haemolysins, pore-forming toxins and cytolytic peptides. The large number of membrane-damaging toxins and peptides produced during S. aureus infections has hindered a precise understanding of their specific roles in diseases. Here, we used comprehensive libraries of recombinant toxins and synthetic cytolytic peptides, of S. aureus mutants and clinical strains to investigate the role of these virulence factors in targeting human macrophages and triggering IL-1β release. We found that the Panton Valentine leukocidin (PVL) is the major trigger of IL-1β release and inflammasome activation in primary human macrophages. The cytolytic peptides, δ-haemolysin and PSMα3; the pore-forming toxins, γ-haemolysin and LukDE; and β-haemolysin synergize with PVL to amplify IL-1β release, indicating that these factors cooperate with PVL to trigger inflammation. PVL(+) S. aureus causes necrotizing pneumonia in children and young adults. The severity of this disease is due to the massive recruitment of neutrophils that cause lung damage. Importantly, we demonstrate that PVL triggers IL-1β release in human alveolar macrophages. Furthermore, IL-1β released by PVL-intoxicated macrophages stimulates the secretion of the neutrophil attracting chemokines, IL-8 and monocyte chemotactic protein-1, by lung epithelial cells. Finally, we show that PVL-induced IL-8/monocyte chemotactic protein-1 release is abolished by the inclusion of IL-1 receptor antagonist (IL-1Ra) in a mixed culture of lung epithelial cells and macrophages. Together, our results identify PVL as the predominant S. aureus secreted factor for triggering inflammasome activation in human macrophages and demonstrate how PVL-intoxicated macrophages orchestrate inflammation in the lung. Finally, our work suggests that anakinra, a synthetic IL-1Ra, may be an effective therapeutic agent to reduce the massive neutrophils infiltration observed during necrotizing pneumonia and decrease the resulting host-mediated lung injury.     

The dominant Australian community-acquired methicillin-resistant Staphylococcus aureus clone ST93-IV [2B] is highly virulent and genetically distinct

Community-associated methicillin-resistant Staphylococcus aureus (CA-MRSA) USA300 has spread rapidly across North America, and CA-MRSA is also increasing in Australia. However, the dominant Australian CA-MRSA strain, ST93-IV [2B] appears distantly related to USA300 despite strikingly similar clinical and epidemiological profiles. Here, we compared the virulence of a recent Australian ST93 isolate (JKD6159) to other MRSA, including USA300, and found that JKD6159 was the most virulent in a mouse skin infection model. We fully sequenced the genome of JKD6159 and confirmed that JKD6159 is a distinct clone with 7616 single nucleotide polymorphisms (SNPs) distinguishing this strain from all other S. aureus genomes. Despite its high virulence there were surprisingly few virulence determinants. However, genes encoding α-hemolysin, Panton-Valentine leukocidin (PVL) and α-type phenol soluble modulins were present. Genome comparisons revealed 32 additional CDS in JKD6159 but none appeared to encode new virulence factors, suggesting that this clone's enhanced pathogenicity could lie within subtler genome changes, such as SNPs within regulatory genes. To investigate the role of accessory genome elements in CA-MRSA epidemiology, we next sequenced three additional Australian non-ST93 CA-MRSA strains and compared them with JKD6159, 19 completed S. aureus genomes and 59 additional S. aureus genomes for which unassembled genome sequence data was publicly available (82 genomes in total). These comparisons showed that despite its distinctive genotype, JKD6159 and other CA-MRSA clones (including USA300) share a conserved repertoire of three notable accessory elements (SSCmecIV, PVL prophage, and pMW2). This study demonstrates that the genetically distinct ST93 CA-MRSA from Australia is highly virulent. Our comparisons of geographically and genetically diverse CA-MRSA genomes suggest that apparent convergent evolution in CA-MRSA may be better explained by the rapid dissemination of a highly conserved accessory genome from a common source.     

Investigating the lytic activity and structural properties of Staphylococcus aureus phenol soluble modulin (PSM) peptide toxins

The ubiquitous bacterial pathogen, Staphylococcus aureus, expresses a large arsenal of virulence factors essential for pathogenesis. The phenol-soluble modulins (PSMs) are a family of cytolytic peptide toxins which have multiple roles in staphylococcal virulence. To gain an insight into which specific factors are important in PSM-mediated cell membrane disruption, the lytic activity of individual PSM peptides against phospholipid vesicles and T cells was investigated. Vesicles were most susceptible to lysis by the PSMα subclass of peptides (α1–3 in particular), when containing between 10 and 30 mol% cholesterol, which for these vesicles is the mixed solid ordered (s_o)–liquid ordered (l_o) phase. Our results show that the PSMβ class of peptides has little effect on vesicles at concentrations comparable to that of the PSMα class and exhibited no cytotoxicity. Furthermore, within the PSMα class, differences emerged with PSMα4 showing decreased vesicle and cytotoxic activity in comparison to its counterparts, in contrast to previous studies. In order to understand this, peptides were studied using helical wheel projections and circular dichroism measurements. The degree of amphipathicity, alpha-helicity and properties such as charge and hydrophobicity were calculated, allowing a structure–function relationship to be inferred. The degree of alpha-helicity of the peptides was the single most important property of the seven peptides studied in predicting their lytic activity. These results help to redefine this class of peptide toxins and also highlight certain membrane parameters required for efficient lysis.     

Staphylococcal alpha‐phenol soluble modulins contribute to neutrophil lysis after phagocytosis

Staphylococcus aureus community‐acquired (CA) MRSA strains are highly virulent and can cause infections in otherwise healthy individuals. The most important mechanism of the host for clearing S. aureus is phagocytosis by neutrophils and subsequent killing of the pathogen. Especially CA‐MRSA strains are very efficient in circumventing this neutrophil killing. Interestingly, only a relative small number of virulence factors have been associated with CA‐MRSA, one of which are the phenol soluble modulins (PSMs). We have recently shown that the PSMs are functionally inhibited by serum lipoproteins, indicating that PSMs may exert their cytolytic function primarily in the intracellular environment. To further investigate the intracellular role of the PSMs we measured the effect of the α‐type and β‐type PSMs on neutrophil killing after phagocytosis. Using fluorescently labelled S. aureus, we measured bacterial survival after phagocytosis in a plate reader, which was employed next to flow cytometry and time‐lapse microscopy. Phagocytosis of the CA‐MRSA strain MW2 by human neutrophils resulted in rapid host cell death. Using mutant strains of MW2, we demonstrated that in the presence of serum, the intracellular expression of only the psmα operon is both necessary and sufficient for both increasedneutrophil cell death and increased survival of S. aureus. Our results identify PSMα peptides as prominent contributors to killing of neutrophils after phagocytosis, a finding with major implications for our understanding of S. aureus pathogenesis and strategies for S. aureus vaccine development.     

Genome sequence of Staphylococcus lugdunensis N920143 allows identification of putative colonization and virulence factors

Staphylococcus lugdunensis is an opportunistic pathogen related to Staphylococcus aureus and Staphylococcus epidermidis. The genome sequence of S. lugdunensis strain N920143 has been compared with other staphylococci, and genes were identified that could promote survival of S. lugdunensis on human skin and pathogenesis of infections. Staphylococcus lugdunensis lacks virulence factors that characterize S. aureus and harbours a smaller number of genes encoding surface proteins. It is the only staphylococcal species other than S. aureus that possesses a locus encoding iron-regulated surface determinant (Isd) proteins involved in iron acquisition from haemoglobin.     

Isoalantolactone protects against Staphylococcus aureus pneumonia

Staphylococcus aureus is a versatile pathogen that can cause life-threatening infections. The growing emergence of methicillin-resistant S.?aureus strains and a decrease in the discovery of new antibiotics warrant the search for new therapeutic targets to combat infections. Staphylococcus aureus produces many extracellular virulence factors that contribute to its pathogenicity. Therefore, targeting bacterial virulence as an alternative strategy to the development of new antimicrobials has gained great interest. α-Toxin is a 33.2-kDa, water-soluble, pore-forming toxin that is secreted by most S.?aureus strains. α-Toxin is essential for the pathogenesis of pneumonia, as strains lacking α-toxin display a profound defect in virulence. In this report, we demonstrate that isoalantolactone (IAL), a naturally occurring compound found in Inula helenium (Compositae), has no anti-S.?aureus activity as per MIC evaluation in vitro. However, IAL can markedly inhibit the expression of α-toxin in S.?aureus at very low concentrations. Furthermore, the in vivo data indicate that treatment with IAL protects mice from S.?aureus pneumonia.     

Identification of a Novel Staphylococcus aureus Two-Component Leukotoxin Using Cell Surface Proteomics

Staphylococcus aureus is a prominent human pathogen and leading cause of bacterial infection in hospitals and the community. Community-associated methicillin-resistant S. aureus (CA-MRSA) strains such as USA300 are highly virulent and, unlike hospital strains, often cause disease in otherwise healthy individuals. The enhanced virulence of CA-MRSA is based in part on increased ability to produce high levels of secreted molecules that facilitate evasion of the innate immune response. Although progress has been made, the factors that contribute to CA-MRSA virulence are incompletely defined. We analyzed the cell surface proteome (surfome) of USA300 strain LAC to better understand extracellular factors that contribute to the enhanced virulence phenotype. A total of 113 identified proteins were associated with the surface of USA300 during the late-exponential phase of growth in vitro. Protein A was the most abundant surface molecule of USA300, as indicated by combined Mascot score following analysis of peptides by tandem mass spectrometry. Unexpectedly, we identified a previously uncharacterized two-component leukotoxin–herein named LukS-H and LukF-G (LukGH)-as two of the most abundant surface-associated proteins of USA300. Rabbit antibody specific for LukG indicated it was also freely secreted by USA300 into culture media. We used wild-type and isogenic lukGH deletion strains of USA300 in combination with human PMN pore formation and lysis assays to identify this molecule as a leukotoxin. Moreover, LukGH synergized with PVL to enhance lysis of human PMNs in vitro, and contributed to lysis of PMNs after phagocytosis. We conclude LukGH is a novel two-component leukotoxin with cytolytic activity toward neutrophils, and thus potentially contributes to S. aureus virulence.     

Host-pathogen interactions between the skin and Staphylococcus aureus

Staphylococcus aureus is responsible for the vast majority of bacterial skin infections in humans. The propensity for S. aureus to infect skin involves a balance between cutaneous immune defense mechanisms and virulence factors of the pathogen. The tissue architecture of the skin is different from other epithelia especially since it possesses a corneal layer, which is an important barrier that protects against the pathogenic microorganisms in the environment. The skin surface, epidermis, and dermis all contribute to host defense against S. aureus. Conversely, S. aureus utilizes various mechanisms to evade these host defenses to promote colonization and infection of the skin. This review will focus on host-pathogen interactions at the skin interface during the pathogenesis of S. aureus colonization and infection.     

Phenol Soluble Modulin (PSM) Variants of Community-Associated Methicillin-Resistant Staphylococcus aureus (MRSA) Captured Using Mass Spectrometry-Based Molecular Networking

Molecular genetic analysis indicates that the problematic human bacterial pathogen methicillin-resistant Staphylococcus aureus possesses more than 2000 open reading frames in its genome. This number of potential gene products, coupled with intrinsic mechanisms of posttranslational modification, endows methicillin-resistant Staphylococcus aureus with a highly complex biochemical repertoire. Recent proteomic and metabolomic advances have provided methodologies to better understand and characterize the biosynthetic factors released by microbial organisms. Here, the emerging tool of mass spectrometry-based molecular networking was used to visualize and map the repertoire of biosynthetic factors produced by a community-associated methicillin-resistant Staphylococcus aureus strain representative of the epidemic USA300 clone. In particular, the study focused on elucidating the complexity of the recently discovered phenol soluble modulin family of peptides when placed under various antibiotic treatment stresses. Novel PSM truncated variant peptides were captured, and the type of variants that were clustered by the molecular networks platform changed in response to the different antibiotic treatment conditions. After discovery, a group of the peptides were selected for functional analysis in vitro. The peptides displayed bioactive properties including the ability to induce proinflammatory responses in human THP-1 monocytes. Additionally, the tested peptides did not display antimicrobial activity as previously reported for other phenol soluble modulin truncated variants. Our findings reveal that the PSM family of peptides are quite structurally diverse, and suggest a single phenol soluble modulin parent peptide can functionally spawn differential bioactivities in response to various external stimuli.A significant percentage of the human population harbors Staphylococcus aureus as a natural resident of their microbial flora (1). In non-infected individuals, S. aureus maintains a homeostatic coexistence with neighboring microbes and with the host (2). However, when equilibrium is disrupted, S. aureus is capable of establishing diseases ranging from minor superficial infections to potentially life-threatening invasive conditions (3, 4). Through the discovery and administration of antibiotics, clinicians have significantly reduced the morbidity and mortality associated with S. aureus (5, 6). In recent years, the consequences of persistent antibiotic exposure have become increasingly manifest through the emergence of resistant strains, including those left unperturbed by methicillin and related β-lactam antibiotics (MRSA)¹ or those with intermediate or full resistance to vancomycin (VISA/VRSA) (7). Certain drug-resistant S. aureus strains, such as the USA300 clone, have spread beyond the hospital setting and into the community, producing serious infections even in previously healthy individuals (8, 9). Both community-associated (CA) and hospital-associated (HA) multi-drug resistant S. aureus are highly evolved, multifaceted pathogens that pose an increasing threat to the health of not only our own, but future generations as well.The pathogenic mechanisms of S. aureus have been examined extensively through different stages of infection (10, 11), with an improved understanding of specific functions that various staphylococcal components contribute to virulence (12). The ability to outcompete other microflora for colonization, or to circumvent the host immune response during infectious spread, largely reflects a complex network of proteins and non-protein molecules that S. aureus secretes into its surroundings-which may collectively be termed biosynthetic release factors. One component of this network is the newly studied and multifunctional phenol soluble modulin (PSM) family of peptides. Associated with biofilm formation and possessing bioactivity toward host cells, PSMs are produced more abundantly by CA-MRSA compared with HA-MRSA strains (13, 14). PSMs are biosynthesized and released with formylated initiator methionine, allowing binding and activation of host neutrophils via the formyl peptide receptor 2 (FPR2) (15). A number of PSMs show cytolytic properties toward host cell lines, and supporting this, isogenic PSM-knockout mutants have decreased virulence in murine models of invasive infection (13). Recently, it was found that many in vitro PSMs phenotypes (e.g. neutrophil lysis, FPR2 binding) were strongly inhibited by serum lipoproteins (16). The same study showed up-regulation of PSM biosynthesis following phagocytosis, suggesting an important role in intracellular survival. Additionally, N-terminal truncated derivative forms of PSMs (dPSMs) with antibacterial properties were identified (17, 18). The finding that dPSMs possess antibacterial activities that are absent in the corresponding full-length parent PSMs, inspired a hypothesis that dPSMs endow CA-MRSA strains with a competitive advantage against resident microbiota upon colonizing host epithelia (i.e. once truncated PSMs gain antimicrobial properties).The invaluable tool of MS has played a major role in characterizing biosynthetic release factors for a diverse number of organisms (19). Over the past decade, the field has spawned several innovative methods to optimize data collection, processing, and organization. The advancement of MS processing methods has improved the capabilities for extracting significant information regarding an organism''s biochemical repertoire. One emerging tool to study biosynthetic release factor potential is the tandem MS data processing program, Spectral Networks. In conjunction with Cytoscape graphical mapping, Spectral Networks allows for the construction of a molecular network map that gives a visualization of tandem mass spectra grouping, based on similar scoring of overlapping ion fragmentation patterns (20, 21). The matching of spectra, termed spectral pairing, is unlike the conventional mode of processing MS data by matching against a reference library or specifying specific posttranslational modifications for identification (22). Instead, within a molecular network map, ion fragmentation patterns can be represented by correlation points, displayed as circular nodes, connected with a straight line to other nodes containing high similarity scores. The power of molecular networking is the information provided on tandem MS subpopulation clusters, which represent structurally matching but variant protein or non-protein biosynthetic release factors.In this work, the MS-based molecular networking platform was applied to a representative strain of the epidemic CA-MRSA USA300 clone. The study sought to provide insight into the biosynthetic release factor map of this pre-eminent human bacterial pathogen under normal growth and antibiotic challenged conditions. Biologically relevant pharmacological stimuli studied included sub-inhibitory concentrations of commonly prescribed commercial antibiotics as well as the innate human defense peptide LL-37 (23–25). In particular, our study goal was to monitor any variations in the type of dPSMs clustered within the molecular network map in response to these stimuli. We show an enriched extract derived from CA-MRSA alone or under these specific challenge conditions provides a highly complex biosynthetic release factor map. Analysis of subpopulation node clusters associated with PSMs prompted the discovery of several previously unreported α, β, and γ type dPSMs. The antibiotic stimuli modulated the type of dPSMs clustered, allowing for differential subclusters to be visualized that were absent in the untreated sample; including nodes that did not sequence to proteogenic PSMs. A group of the newly discovered PSM variants were assessed for functional properties and showed the induction of proinflammatory responses in THP-1 cells. In addition, in contrast to previous reports (17, 18), the tested dPSMs did not display antimicrobial activity. We conclude MS-based molecular networking can be used as a targeted discovery tool with the ability to identify previously unreported bioactive peptides.