Abstract
Secretion of extracellular vesicles (EVs), a process common to eukaryotes, archae, and bacteria, represents a secretory pathway that allows cell-free intercellular communication. Microbial EVs package diverse proteins and influence the host-pathogen interaction, but the mechanisms underlying EV production in Gram-positive bacteria are poorly understood. Here we show that EVs purified from community-associated methicillin-resistant Staphylococcus aureus package cytosolic, surface, and secreted proteins, including cytolysins. Staphylococcal alpha-type phenol-soluble modulins promote EV biogenesis by disrupting the cytoplasmic membrane; whereas, peptidoglycan cross-linking and autolysin activity modulate EV production by altering the permeability of the cell wall. We demonstrate that EVs purified from a S. aureus mutant that is genetically engineered to express detoxified cytolysins are immunogenic in mice, elicit cytolysin-neutralizing antibodies, and protect the animals in a lethal sepsis model. Our study reveals mechanisms underlying S. aureus EV production and highlights the usefulness of EVs as a S. aureus vaccine platform.
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Introduction
Staphylococcus aureus is a pathogenic bacterium that causes a wide spectrum of human infections, ranging from mild skin lesions to invasive, life-threatening infections. The pathogenesis of S. aureus infections is attributed to a wide array of virulence determinants, including surface proteins1 and glycopolymers2, as well as multiple secreted proteins, such as superantigens, leukotoxins, hemolysins, and proteases3. Although several specific export pathways have been described in S. aureus, the secretome often includes proteins that lack export signals and have typical cytoplasmic functions. The mechanisms by which cytoplasmic proteins are excreted by S. aureus have attracted recent interest4,5, and there is increasing evidence that these proteins may be secreted within extracellular membrane vesicles (EVs)6,7,8,9.
EVs are nano-sized, spherical, bilayered membrane vesicles with a cargo that includes diverse proteins, polysaccharides, nucleic acids, and lipids. EV formation by Gram-negative bacteria was first observed by electron microscopy in the 1960s10, and these bacteria secrete what are now referred to as outer membrane vesicles (OMVs). The generation of OMVs occurs by phospholipid accumulation in the outer leaflet of the outer membrane, followed by the formation of outer membrane protrusions that pinch off to form vesicles11. OMVs likely play important roles in bacterial pathogenesis due to packaging of multiple virulence factors12, and the ability of OMVs to serve as immune modulators by inducing innate and adaptive immune responses13.
Recent work has described the production and release of EVs from Gram-positive bacteria and fungi6,7,8,9,14. Because of the thick peptidoglycan (PGN) structure typical of Gram-positive microbes, EV biogenesis is a complex and poorly understood process. Toyofuku et al.14 recently reported that membrane vesicle formation in Bacillus subtilis was a result of prophage-encoded endolysins that generated holes in the PGN, facilitating EV release. EVs from Gram-positive organisms play important roles in host-pathogen interactions, as supported by reports that EVs contain biologically active toxins, exhibit cytotoxicity, and elicit proinflammatory mediators9. Moreover, toxin-positive S. aureus EVs elicit skin barrier disruption in mice with characteristic atopic dermatitis-like skin inflammation15,16. The toxicity of staphylococcal EVs has hampered a relevant study of their immunogenicity and potential use as a vaccine platform.
Despite repeated efforts to develop experimental vaccines and immunotherapeutics against S. aureus, neither have proven effective in preventing staphylococcal infections in humans17. Mice immunized with native S. aureus EVs produced a robust T-cell response and were protected against lung infection, but EV toxicity was not addressed in this study18. The development of EVs as a S. aureus vaccine platforms will require characterization of the mechanisms of EV biogenesis to enable consistent production with adequate quality assurance.
In this study, we generate EVs from a predominant community-acquired, methicillin-resistant S. aureus (CA-MRSA) clone in the United States. Our study reveals distinct mechanisms that facilitate EV production at multiple stages. Phenol-soluble modulins (PSMs) act at the membrane level to facilitate vesicle budding at the cytoplasmic membrane; whereas, cell wall porosity is modulated by PGN cross-linking and production of autolysins. Our results demonstrate the cytotoxicity of native S. aureus EVs for multiple cell types. By genetically engineering a non-toxic S. aureus mutant to over-produce detoxified cytolysins, we show that engineered EVs (eng-EVs) are immunogenic, non-toxic, and protect mice against S. aureus lethal sepsis. Our investigation describes a vaccine platform and provides the basis for further studies on the impact of EVs on the pathogenicity of S. aureus and other Gram-positive pathogens.
Results
Isolation of S. aureus EVs
Ultrathin sections of JE219 cells examined by transmission electron microscopy (TEM) revealed vesicle-like structures released from the S. aureus cell surface (Fig. 1a). We isolated the EVs by concentrating the culture supernatants to remove molecules <100 kDa before ultracentrifugation to pellet the EVs, shown in Fig. 1b. To remove non-membranous proteins, protein aggregates, and denatured EVs, Optiprep-based density gradient centrifugation was performed on the crude EV preparations. Consecutive Optiprep fractions (10 µl) were subjected to SDS-PAGE. Little silver-stained material was recovered from fractions 1 and 2 (Fig. 1c). Samples with similar protein banding patterns (fractions 3–8 and 9–11) were pooled, diafiltered, and examined by TEM. EVs were observed in fractions 3–8 (Fig. 1d), but not from fractions 9–11, indicating that EVs were distributed in fractions containing 20−35% Optiprep.
Protein composition of S. aureus EVs
A proteomic analysis of purified JE2 EVs by liquid chromatography–tandem mass spectrometry (LC–MS/MS) identified 165 proteins (Supplementary Data 1), including alpha toxin (Hla), leukocidin subunits (LukS-PV, LukF-PV, LukE, LukD, HlgB, and HlgC), adhesins (ClfA, ClfB, SdrD, SdrE, Efb, and Ebh), MntC, proteases, and immune evasion factors (Sbi, phenol-soluble modulins, catalase, CHIPS, and SodA). Other proteins of interest included penicillin-binding proteins, autolysins (Atl, Sle1, and other putative autolysins with predicted N-acetylmuramoyl-l-alanine amidase activity), proteins involved in iron acquisition, and multiple other lipoproteins. Bioinformatic analyses revealed that 46% of EV proteins were cytoplasmic (n = 76), 16% were extracellular proteins (n = 27), 16% had an unknown localization (n = 27), 12% were membrane proteins (n = 19), and 10% were cell wall associated proteins (n = 16).
Phenol-soluble modulins promote EV release
S. aureus secretes PSMs, which are a family of amphipathic, alpha-helical, surfactant-like peptides that are proinflammatory and show cytolytic activity against neutrophils, erythrocytes, epithelial cells, and endothelial cells20,21. Alpha-type PSMs are required for mobilizing lipoproteins from the staphylococcal cytoplasmic membrane, a process essential for activating TLR222, as well as the export of cytoplasmic proteins, consistent with the membrane-damaging activity of PSMs5. Because the cargo of S. aureus EVs is enriched for both lipoproteins and cytoplasmic proteins, we evaluated whether PSM peptides were critical for EV generation.
We measured EV production by the WT USA300 LAC strain (the parent strain of JE2), as well as LAC ∆psmα, ∆psmβ, and ∆psmα∆psmβ mutants21. Dot immunoblot analysis revealed that deletion of psmα genes reduced EV production (Fig. 2a). Likewise, protein assays and nanoparticle tracking analysis (NTA) indicated that the psmα mutant showed significantly reduced S. aureus EV yield (Fig. 2b) and particle number (Fig. 2c), respectively. The ∆psmα and ∆psmα∆psmβ double mutant produced comparable levels of EVs (Fig. 2b), indicating that PSMα peptides play the dominant role in this phenotype. Complemention with pTX∆ expressing PSMα1-4 genes, but not the pTX∆ vector alone, restored EV production to the ∆psmα mutant (Fig. 2b, c). Mutation of the psmα genes significantly reduced S. aureus EV size (Fig. 2c, d); whereas, the ∆psmβ mutant produced EVs of intermediate size compared to that of wild-type (WT) LAC. We transduced pTX∆PSMα1-421 into strain JE2, and its EV yield (protein content) increased from 184 ± 12 to 650 ± 17 ng ml−1 (n = 3). Nonetheless, electron micrographs of JE2 (pTX∆PSMα1-4) showed intact bacterial cells producing abundant EVs (Fig. 2f). Significant differences in bacterial numbers recovered from JE2 cultures with or without pTX∆PSMα1-4 were not observed (Supplementary Fig. 1a), indicating minimal impact of EV formation on bacterial viability.
PGN cross-linking modulates EVs production
Unlike OMVs produced by Gram-negative microbes, S. aureus cytoplasmic membrane-derived EVs must traverse a PGN cell wall structure before cellular release. To determine whether the degree of PGN cross-linking affected S. aureus EV biogenesis, we cultured S. aureus JE2 in medium with a sublethal concentration (0.2 µg ml−1) of penicillin G (PenG) that has been shown to decrease PGN cross-linking23. Treatment with a sublethal concentration (0.1 µg ml−1) of erythromycin (Em) served as an antibiotic control that has no effect on PGN cross-linking. Compared to EVs recovered from untreated cultures or cultures incubated with Em, the EV yield from PenG-treated cultures was distinctly higher (Fig. 3a). When the EV protein content was quantified from a fixed volume of culture left untreated or treated with sublethal antibiotic concentrations, we observed a 10-fold increase in EV yield from PenG-treated cultures (Fig. 3b). EV production had little effect on bacterial viability since differences were not observed in bacterial numbers recovered from JE2 cultured with or without PenG (Supplementary Fig. 1b).
S. aureus penicillin-binding protein 4 (PBP4) is a carboxypeptidase that is essential for secondary cross-linking of PGN, and a pbp4 mutant shows a significant reduction in PGN cross-linking24. As predicted, both dot blot (Fig. 3c) and EV protein yield assays (Fig. 3d) showed increased EV production by JE2Δpbp4, and the protein yield was threefold higher than the wild-type JE2 strain. We also measured EV production in MRSA isolates MW2, COL, and their ∆pbp4 mutants; the relative increase in EV yield in the mutant strains (Fig. 3c, d) was consistent with that of JE2∆pbp4.
WTA is a PGN-anchored glycopolymer that is major component of the S. aureus cell wall and plays a critical role in cell wall homeostasis2. The tagO gene encodes an N-acetyl glucosamine-phosphate transferase enzyme that catalyzes the first step in WTA biosynthesis25,26, and deletion of tagO gene abrogates S. aureus WTA production27. Compared to the WT strains JE2, COL, and Newman, tagO mutants showed an enhanced signal in the dot immunoblot assay for EV production (Fig. 3e). Likewise, quantitative analysis of EV protein yield showed that all three tagO mutants produced significantly more EVs than the parental isolates (Fig. 3f). Thus, WTAs negatively modulate S. aureus EV production, consistent with reports showing that tagO mutants are characterized by diminished PGN cross-linking28. The WTA backbone is decorated with ester-linked D-ala residues, which confer a zwitterionic charge to the polymer29. As shown in panels e and f of Fig. 3, production and yield of EVs by the ΔdltA mutant were similar to that of the parental strain Newman.
To determine whether EV size was affected by reduced PGN cross-linking, the size distribution of purified EVs was measured by dynamic light scattering (DSL). Treatment of JE2 cultures with PenG or mutation of pbp4 or tagO resulted in a significant increase in the size distribution of EVs (Fig. 3g), as well as an increased EV average size (Fig. 3h) compared to untreated WT EVs. Because enhanced EV production and yield associated with reduced PGN cross-linking might be a result of larger EVs that would carry an increased cargo load, we quantified EVs by nanoparticle tracking analysis. As shown in Fig. 3i, treatment of JE2 cultures with PenG or mutation of pbp4 or tagO resulted in suspensions containing significantly greater numbers of EV particles per ml compared to untreated WT EVs. Electron micrographs of bacterial cells treated with PenG (Fig. 3j) or carrying a pbp4 mutation (Fig. 3k) showed EVs being released or budding, respectively, from the cell membrane. Taken together, our data indicate that S. aureus EV production is inversely proportional to the degree of PGN cross-linking.
Autolysin Sle1 promotes the release of EVs
Atl and Sle1 belong to a family of PGN hydrolases that plays a critical role in separation of daughter cells30,31, and Atl modulates the excretion of a subset of staphylococcal cytoplasmic proteins4. To determine whether PGN-hydrolases facilitate the release of EVs by altering the thick Gram-positive cell wall, we compared EV production from isogenic atl and sle1 mutants with that of strains JE2 and Newman. Although both mutants showed reduced EV production (Fig. 4a), the reduction in yield was only significant in the sle1 mutants (Fig. 4b). Likewise, NTA revealed that only the sle1 mutant yielded a significantly lower EV concentration compared to WT JE2 (Fig. 4c). Complemention with pSle1 expressing the sle1 gene, but not the pOS1-hprK vector alone, fully restored EV production to the JE2 ∆sle1 mutant (Fig. 4b, c). Both atl and sle1 mutants exhibited significantly reduced EV size compared to WT JE2 EVs (Fig. 4d, e).
Bacteriophages also produce PGN hydrolases called endolysins, which degrade the bacterial cell wall from within, resulting in cell lysis and release of progeny phages. Recently, Toyofuku et al.14 reported that prophage-encoded endolysins mediate the formation and release of EVs from Bacillus subtilis by generating a hole in the cell wall, leading to cell death. To investigate whether prophages or prophage-encoded endolysins are involved in S. aureus EV production, we analyzed S. aureus strains NCTC 8325 carrying ϕ11, ϕ12, and ϕ13 and 8325-4, which is cured of all three prophages32. Plating culture filtrates of NCTC 8325 on lawns of recipient strain RN4220 resulted in the formation of plaques, whereas culture filtrates of 8325-4 yielded no plaques (Supplementary Fig. 2a). EV yields and NTA revealed that NCTC 8325 and prophage-free strain 8325-4 produced comparable level of EVs (Supplementary Fig. 2b and 2c), indicating that prophage mobilization is not essential for the generation of S. aureus EVs.
Effects of the S. aureus capsule on EV release
To determine whether the presence of capsular polysaccharide (CP) production impacted S. aureus EV biogenesis, we evaluated a number of isogenic CP+ and CP− strains. As shown in Fig. 5a, the CP phenotype had no obvious impact on the EV dot blot signal derived from WT or CP− mutants of strains Newman (CP5+) or 6850 (CP8+). Similarly, USA300 strain 923 (complemented to restore CP5 production) produced CP533, but there was no effect on the EV signal levels achieved by dot blotting (Fig. 5a). Likewise, CP+ and isogenic CP− strains of Newman, 6850, and 923 produced comparable protein yields of EVs (Fig. 5b), indicating that CP did not modulate S. aureus EV production.
To investigate whether CP antigens were associated with S. aureus EVs, we performed CP immunoblots on EVs prepared from strains Newman (CP5+), MN8 (CP8+), and USA300 FPR3757 (CP−). CP antibodies react with surface-associated CP on intact EVs, whereas intravesicular CP would only be detected in sonicated EV preparations. Figure 5c shows that CP5 was only detected in sonicated, but not intact Newman EVs; whereas, CP8 was detected in both intact and sonicated MN8 EVs. EVs from CP− FPR3757 were non-reactive. Thus, both CP5 and CP8 were associated with EVs produced by CP+ S. aureus, although only CP8 was surface exposed.
Detoxified EVs as a multicomponent vaccine platform
Multiple antigens were packaged within JE2 EVs, including lipoproteins, cytolytic toxins, surface proteins, and enzymes (Supplementary Data 1). If the toxicity of the EVs were eliminated, JE2 EVs could serve as a multicomponent S. aureus vaccine candidate. To repress the expression of cytolytic toxins, we mutated the S. aureus global regulator agr in strain JE2. We subsequently deleted spa (the gene encoding protein A) since an agr mutant overexpresses Spa, which binds to the Fcγ domain of immunoglobulin and dampens antibody development by cross-linking the Fab domain of VH3-type B-cell receptors34. The JE2 agr mutation significantly inhibited mRNA expression of hla (encoding alpha toxin) and the genes encoding all nine leukocidin subunits (Supplementary Fig. 3a). The JE2∆agr∆spa double mutant served as our S. aureus EV vaccine producing host strain. EVs from JE2, but not the JE2∆agr∆spa mutant, contained native Hla and LukE (Supplementary Fig. 3b) as assessed by western blotting. When we analyzed the protein content of JE2∆agr∆spa EVs by LC–MS/MS, many of the extracellular proteins present in JE2 WT EVs were not detected in JE2∆agr∆spa EVs. However, some antigens such as MntC and FhuD2 that protect mice against experimental S. aureus infections35,36 were present in EVs from the mutant strain. Neither protein A nor the toxins Hla, Panton-Valentine leukocidin (Luk-PVL), LukED, HlgCB, SelX, or PSMs were detectable in EVs purified from the JE2∆agr∆spa mutant (Supplementary Data 2). Although LukAB was still present in EVs from JE2∆agr∆spa, there was ≥86% reduction in the number of peptides detected in the mutant strain (Supplementary Data 1 and 2). Moreover, as indicated below, EVs recovered from the mutant strain showed no residual toxicity toward human leukocytes.
We immunized mice with 5 µg EVs from JE2∆agr or JE2∆agr∆spa mutants; control mice were given phosphate buffered saline (PBS). EVs from both mutants elicited a serum antibody response against sonicated WT EVs, although the antibody level elicited by ∆agr EVs was higher than that elicited by ∆agr∆spa EVs (Supplementary Fig. 4a). To examine the antigen profiles from EVs that elicited antibody responses after immunization, a bacterial lysate from USA300 strain FPR3757 was subjected to SDS-PAGE and immunoblotted with sera pooled from mice immunized with either ∆agr EVs or ∆agr∆spa EVs. Sera from ∆agr∆spa EVs-immunized mice reacted with more bacterial antigens than sera from ∆agr EVs-immunized mice (Supplementary Fig. 4b), suggesting that ∆agr∆spa EVs elicited a greater diversity of antibodies than ∆agr EVs. The immunized mice were then challenged with strain FPR3757, a heterologous USA300 isolate. Immunization of mice with EVs from JE2∆agr∆spa, but not EVs from JE2∆agr, provided significant protection against lethal sepsis (Supplementary Fig. 4c). Immunization with higher doses of JE2∆agr∆spa EVs mixed with alum did not significantly enhance immunogenicity (Supplementary Fig. 4d).
Engineered EVs protect mice against lethal sepsis
To enhance the protective efficacy of detoxified EVs from JE2∆agr∆spa, we engineered JE2 to package non-toxic HlaH35L37 and the LukE monomer within eng-EVs. LukED, detected in 82% of blood isolates and 61% of nasal isolates38, targets human and murine neutrophils, macrophages, T cells, dendritic cells, NK cells, and erythrocytes39.
We expressed non-toxic HlaH35L and LukE in strain JE2∆agr∆spa under control of the spa promoter, which is enhanced in an ∆agr genetic background40. Thus, mRNA levels of HlaH35L and LukE expressed in JE2∆agr∆spa were dramatically increased compared to expression in JE2∆agr∆spa or JE2∆agr∆spa with the empty vector (Supplementary Fig. 3c). Both HlaH35L and LukE were detected by western blot in eng-EVs isolated from recombinant strain JE2∆agr∆spa (pHlaH35L-LukE) (Supplementary Fig. 3b).
The relative toxicity of EVs prepared from WT strain JE2 and JE2∆agr∆spa vs. eng-EVs from JE2∆agr∆spa (pHlaH35L-LukE) was assessed by incubating EVs in vitro with three different cell types. A549 cells are susceptible to Hla-mediated cytolysis, and WT strain JE2 EVs were toxic for A549 cells at concentrations as low as 1 µg ml−1. In contrast, JE2∆agr∆spa mutant EVs and the eng-EVs from JE2∆agr∆spa (pHlaH35L-LukE) exhibited negligible toxicity (Supplementary Fig. 5a). HL60 cells are susceptible to the cytolysis induced by S. aureus leukocidins, and JE2 EVs, but not ∆agr∆spa or eng-EVs, were cytolytic for HL60 cells (Supplementary Fig. 5b). Rabbit erythrocytes are susceptible to Hla, PSMs, and the leukocidins HlgAB and LukED39. JE2 EVs exhibited significant hemolytic activity, whereas no hemolysis resulted from ∆agr∆spa mutant EVs or eng-EVs (Supplementary Fig. 5c). These data demonstrate that the eng-EVs were non-toxic in vitro for mammalian cells.
We immunized mice on days 0, 14, and 28 with 5 µg eng-EVs from JE2∆agr∆spa (pHlaH35L-LukE) or with 5 µg EVs from the JE2∆agr∆spa mutant; control mice received 5 µg bovine serum albumin (BSA). Whereas sera from mice immunized with both eng-EVs and ∆agr∆spa EVs, but not BSA, reacted by ELISA with sonicated WT JE2 EVs (Fig. 6a), only mice given the eng-EVs responded with antibodies to purified Hla (Fig. 6b) or LukE (Fig. 6c). These data indicate that recombinant proteins packaged within S. aureus EV are immunogenic.
To examine whether the antibodies elicited by the eng-EV vaccine were functional, toxin neutralizing assays were performed. Sera from mice immunized with eng-EVs effectively neutralized Hla at dilutions ranging from 1:20 to 1:80 (Fig. 6d), whereas serum neutralizing antibodies were low or undetectable in the BSA or ∆agr∆spa EV groups. Similarly, sera from mice immunized with eng-EVs, but not BSA or ∆agr∆spa EVs, were able to effectively neutralize LukED at dilutions ranging from 1:10 to 1:20 (Fig. 6e). Sera from mice immunized with eng-EVs also neutralized leukocidin HlgAB (Fig. 6f), but not PVL-SF or HlgCB leukotoxins.
The immunized mice were challenged with USA300 strain LAC or USA500 strain NRS685, a PVL-negative MRSA bacteremia isolate. We chose the latter strain because the PVL-S and PVL-F subunits can interact with LukE and LukD to form inactive hybrid complexes, which have been shown to influence LukED-mediated S. aureus virulence in mice41. As shown in Fig. 6g, h, immunization with eng-EVs provided significant protection against both S. aureus isolates in the lethal murine sepsis model. JE2∆agr∆spa EVs were not protective against the USA500 strain (Fig. 6h).
Discussion
The production of membrane vesicles represents a secretory pathway common to mammalian cells, fungi, and bacteria that allows cell-free intercellular communication42,43,44. Microbial EVs encapsulate cargo that include lipids, proteins, glycans, and nucleic acids, which have been shown to play roles in microbial physiology, pathogenesis, and the transmission of biological signals into host cells to modulate biological processes and host innate immune responses42,43,45,46. In Gram-negative bacteria, EVs are generated by pinching off the outer membrane, but the mechanism(s) by which EVs escape the thick cell walls of Gram-positive bacteria, mycobacteria, and fungi are unknown. Once shed, S. aureus EVs can undergo cholesterol-dependent fusion with host cell membranes to deliver their toxic cargo47. S. aureus EVs are produced in vivo during experimental pneumonia in mice47. In this report, we demonstrate unique properties associated with EV production by JE2, a S. aureus USA300 strain representative of the prevalent CA-MRSA clone in the US. Similar to EVs characterized from other S. aureus isolates47,48,49, JE2 EVs encapsulate an array of bacterial antigens, including lipoproteins, exotoxins, and cytoplasmic proteins.
In this report, we evaluated putative factors that modulate the membrane and PGN related steps of EV release. PSMs are a group of small alpha helical peptides that have surfactant-like properties and potent cytolytic activity for leukocytes, epithelial cells, and endothelial cells20. PSMα peptides are 20–22 amino acids in length; whereas, PSMβ peptides are 43–45 amino acids in length. In our studies, PSMα peptides, but not PSMβ peptides, supported the generation of EVs from S. aureus. EVs from the PSMα mutant were less abundant and smaller in size compared with WT EVs. Chatterjee et al.50 reported that an S. aureus mutant that lacks the PSM transporter protein accumulates PSMs intracellularly, causing cytoplasmic membrane perturbations. Surfactants or surfactant-like proteins with amphipathic helical structures have been shown to insert into lipid monolayers and generate local deformation51,52. PSMs, due to their surfactant-like activity, as well as amphipathic helical structure, may enhance membrane curvature under cytoplasmic turgor pressure, resulting in membrane disruption and the formation of EVs. Although EVs from Gram-negative bacteria arise from the outer membrane rather than the plasma membrane, the biogenesis of OMV production is also thought to be due to perturbations in the outer leaflet of the membrane due to specific phospholipid accumulation therein11. Recently, Ebner et al.5 reported that S. aureus PSMα peptides-induced the cellular release of cytoplasmic proteins, lipids, nucleic acids, and ATP into culture supernatants, and that this effect was mediated by the membrane-damaging activity of the PSMα peptides. Because PSMα peptides promote EV production, and EVs encapsulate cytoplasmic proteins, lipids, and nucleic acids18 within a bilayered membrane, we postulate that these released cellular components are associated with and are likely contained within EVs.
The S. aureus cell envelope is comprised of a thick, highly cross-linked PGN layer, proteins, and glycopolymers like lipoteichoic acid, WTA, and CP. Highly cross-linked PGN serves as a barrier for EV biogenesis since treatment of S. aureus with a sublethal concentration of PenG or genetic inactivation of pbp4 or tagO resulted in a significant increase in EV production and size. This inverse correlation between PGN cross-linking and EV yield was also observed with S. aureus strains MW2, COL, and Newman. WTA has been shown to be critical for PGN-cross-linking by regulating PBP4 localization to the septation site28. A secondary mechanism by which WTA regulates EV production is via its ability to control the activity of Atl and Sle1—not only by preventing their binding to S. aureus cell wall PGN53,54, but also by creating an acidic milieu that limits Atl PGN hydrolase activity55. Consequently, autolytic activity is not localized to the septum area in a tagO mutant but is spread throughout the cell surface, likely facilitating EV release. Schlag et al.53 reported that a tagO mutant showed an altered cell surface with bobble- and hairy-like protrusions, which may represent EVs. Although we do not yet fully understand the mechanism(s) of EV generation in Gram-positive bacteria, it seems logical that a poorly cross-linked cell wall or a cell wall lacking WTA would lessen the barrier to EV release and generate larger EVs as a result of larger pores within the PGN structure.
Autolysins that cleave the PGN barrier also impact the biogenesis of S. aureus EVs. Atl and Sle1 localize to the septum during cell division where they exhibit peptidoglycan hydrolase activity, resulting in separation of the daughter cells53,54. Sle1 is a 32 kDa protein comprised of an N terminal cell wall binding domain and a C terminal catalytic domain with N-acetyl muramyl-l-alanine amidase activity. In contrast, Atl is a 138 kDa bifunctional PGN hydrolase that is processed to yield a 62 kDa protein with amidase activity (similar to that of Sle1) and a 51 kDa protein with endo-β-N-acetyl glucosaminidase activity. Atl is also involved in cell wall turnover and penicillin- or detergent-induced bacterial autolysis. Deletion of sle1, but not atl, significantly reduced S. aureus EV production. Pasztor et al.4 reported that an SA113 atl mutant overexpressed eight putative secondary PGN hydrolases both at the transcriptional and at the protein levels, highlighting the supplementary role of these alternative autolysins in the absence of Atl. This observation may at least partially explain why JE2Δatl and NewmanΔatl showed only a modest reduction in EV yield. Mutation of atl only slightly reduced EV yield, but the average size of EVs from the mutant was smaller than that of WT JE2, suggesting that Atl is involved in EV biogenesis. Atl modulates the excretion of staphylococcal cytoplasmic proteins4, and it is likely that EV production at least partially explains the Atl-mediated shedding of cytoplasmic proteins in S. aureus.
Although both autolysin activities are localized to the S. aureus septum region, JE2 EVs are not confined to the septal region (Fig. 2f), and EVs have been visualized by others surrounding the bacterial surface7,48,56. A recent report demonstrated differential roles for Atl and Sle1 during cell division and separation57. Whereas Sle1 could be visualized over the entire septal surface, Atl localized only at the external (surface exposed) edge of the septum58. How autolysins modulate EV release from the cell wall or whether this process is spatially or temporally regulated remains to be determined.
We reported that S. aureus CP was shed from broth-grown S. aureus cells59, and it is feasible that EVs could serve as a vehicle to liberate CP from the cell envelope. The Streptococcus pneumoniae capsule was reported to hinder EV release in this pathogen7, whereas no effect was observed on EV yield in strains with or without the hyaluronic capsule of Streptococcus pyogenes8. Whether these streptococcal CPs are present as EV cargo in these pathogens was not addressed. Although EV yield varied among different isolates, we recovered similar quantities of EVs from isogenic S. aureus strains that varied only in CP production. The glucuronoxylomannan capsule of Cryptococcus neoformans has been identified as a component of EVs from this fungal pathogen60, and polysaccharide A from Bacteroides fragilis was shown to be packaged into OMVs that were capable of inducing immunomodulatory signaling in dendritic cells46. Ongoing studies in our laboratory will address whether S. aureus EV-host cell interactions impact the pathogenesis of staphylococcal disease.
We considered that S. aureus EVs could serve as a vaccine platform if their cytotoxicity was abrogated, and this was accomplished by purifying EVs from an ∆agr∆spa mutant of strain JE2. To enhance the protective efficacy of the ∆agr∆spa EV vaccine, non-toxic HlaH35L and LukE were expressed in JE2∆agr∆spa under the control of the agr-derepressed spa promoter. Immunization with purified non-toxic HlaH35L has been shown to prevent lethal pneumonia and lethal peritonitis and reduce the incidence of necrotic skin abscesses61,62,63. S. aureus leukocidins comprise a family of pore-forming cytolysins produced by S. aureus that target monocytes, lymphocytes, neutrophils, and macrophages—the very cells responsible for resolution of bacterial infection. These “eng-EVs” elicited antibodies in the sera of immunized mice that reacted with Hla and LukE by ELISA and neutralized the cytolytic activity of Hla, LukED, and HlgAB in vitro.
Immunization with eng-EVs provided significant protection against lethal sepsis provoked by USA300 strain LAC, a virulent PVL+ isolate. Because of a report that the presence of PVL modulates LukED-mediated S. aureus virulence in mice41, we challenged another group of immunized mice with USA500 strain NRS685, a PVL-negative MRSA bacteremia isolate. Immunization with eng-EVs, but not ∆agr∆spa EVs, protected 50% of the mice against NRS685 lethal sepsis. Protective efficacy against additional S. aureus strains and in additional infection models remains to be evaluated. Overexpression of additional antigens that have been shown to protect mice against experimental S. aureus infections, such as MntC and FhuD235,36, in second-generation eng-EVs may yield a more broadly protective vaccine. LC–MS/MS analysis of EVs from both WT JE2 and the ∆agr∆spa mutant strain contained multiple lipoproteins. As a predominant TLR2 ligand, lipoproteins have been increasingly used as adjuvant components64,65 because they are potent activators of host innate immunity and can mediate humoral and cell mediated immune responses. The self-adjuvanting composition of eng-EVs may provide it with a unique advantage over purified component vaccines.
In summary, we have generated, purified, and characterized EVs isolated from S. aureus USA300, the predominant CA-MRSA clone in the United States. Our study revealed that S. aureus PSMs are central for EVs generation by targeting the cytoplasmic membrane. Likewise, the Sle1 autolysin was shown to be critical for the release of EVs from the S. aureus cell wall. Whereas mutations in Atl or CP production did not affect EV yield, PBP4 and WTA promoted PGN cross-linking and consequently diminished EV production. Our study elucidates certain mechanisms whereby S. aureus produces and sheds EVs (Fig. 7) and will ultimately further our understanding of bacterial physiology and pathogenesis. We designed and created eng-EVs as a vaccine platform against S. aureus infection. Detoxified EVs that over-produced HlaH35L and LukE were immunogenic, elicited toxin neutralizing antibodies, and protected mice in a S. aureus lethal sepsis model, indicating that these naturally produced vesicles have potential as a noval vaccine platform.
Methods
Bacterial strains and plasmids
S. aureus isolates (listed in Supplementary Table 1) were cultivated overnight with aeration in tryptic soy broth (TSB; Difco) at 37 °C. Escherichia coli strain XL-10 (Agilent), used in DNA cloning experiments, was grown at 37 °C in Luria Broth (LB; Difco). S. aureus—E. coli shuttle vector pCU166 was used for cloning and expression of appropriate genes in S. aureus, and pOS1-hprK was used for pSle1 complementation studies. Antibiotics were added in the following concentrations: PenG 0.2 μg ml−1, ampicillin (Amp; 100 μg ml−1), Em 5 μg ml−1, chloramphenicol (Cm; 10 μg ml−1), kanamycin (Kan; 50 μg ml−1), and tetracycline (Tet; 5 μg ml−1).
DNA manipulation
Fey et al.19 derived S. aureus JE2 from the USA300 strain LAC by curing it of plasmids, rendering it sensitive to Em. The agr mutation (∆agr::tetM) was transduced from S. aureus RN691140 to WT JE2 using bacteriophage ϕ80α with selection for Tet resistance. To construct the JE2 ∆agr∆spa double mutant, the spa mutation was transduced from JE2 (spa::ermB) to JE2∆agr by ϕ80α transduction. The pbp4 mutation was transduced from JE2 (∆pbp4::ermB) to WT MW2 and COL by ϕ80α transduction with selection for Em resistance. All mutants were confirmed by PCR using the primers listed in Supplementary Table 2. ELISA results confirmed the phenotype of the ∆spa mutant, and the agr mutant lost its hemolytic phenotype. To construct the WTA mutants, the tagO mutation was transduced from SA113∆tagO (pRBtagO) to WT JE2 and COL with ϕ80α with selection for Em resistance. Mutants were confirmed by PCR and acquisition of resistance to lysis by ϕ80α. To complement the JE2∆sle1 mutant, a DNA fragment of 1005 bp containing the sle1 gene was amplified from JE2 genomic DNA using the primer pair listed in Supplementary Table 2. The Sle1 expression plasmid was constructed by cloning the sle1 gene under the control of the hprK promoter into the E.coli—S. aureus shuttle vector pOS167. pSle1 was transformed into RN4220 by electroporation and then transduced to JE2∆sle1 by ϕ80α transduction.
To construct a shuttle vector for expression of HlaH35L and LukE, the spa promoter, hla H35L , and lukE genes were amplified from S. aureus strains JE2, DU1090 (pHlaH35L), and FPR3757, respectively, using the primers listed in Supplementary Table 2. To drive the expression of hla H35L , its sequence was fused to the 3′ terminus of the spa promoter containing the ribosome binding site by overlapping PCR. The P spa -hla H35L fusion sequence was cloned into the shuttle plasmid pCU1 with restriction enzymes HindIII and SalI. The amplified lukE sequence containing a ribosome binding site was inserted into pCU1 with restriction enzymes SalI and EcoRI. The resulting plasmid pCU1-P spa -hla H35L -lukE was verified by enzyme digestion and DNA sequencing. To construct JE2∆spa∆agr expressing non-toxic HlaH35L and LukE, pCU1-P spa -hla H35L -lukE was transformed into RN4220 by electroporation and then transduced with ϕ80α to JE2∆spa∆agr, selecting for Cm resistance.
Isolation and purification of EVs
S. aureus was cultivated in TSB with shaking to an OD650 nm of 1.2. The culture supernatant was filtered and concentrated 25-fold with a 100-kDa tangential flow filtration system (Pall Corp.). The retentate was filtered again before centrifugation at 150,000×g for 3 h at 4 °C to pellet the vesicles and leave soluble proteins in the supernatant. The EV pellet was suspended in 40% Optiprep density gradient medium (Sigma) and overlaid with gradient layers of Optiprep ranging from 35 to 10%. After centrifugation at 139,000×g for 16 h at 4 °C, 1 ml fractions were removed sequentially from the top of the gradient. Each fraction was subjected to SDS-PAGE and stained with a Thermo Fisher silver staining kit. Fractions with a similar protein profile on SDS-PAGE were pooled, and the Optiprep medium was removed by diafiltration with PBS using an Amicon Ultra-50 Centrifugal Filter Unit. The diafiltered retentate was filtered (0.45 µm) and stored at 4 °C. EV protein concentrations were determined by using a Protein Assay Dye Reagent (Bio-Rad). EV samples were evaluated with a Nanobrook ZetaPALS potential analyzer (Brookhaven Instruments Corp.), and the data for size distribution and particle diameter were generated with ZetaPALS particle sizing software. Nanoparticle tracking analysis was performed by purifying EVs from 100 ml bacterial cultures, as described above. The number of EV particles recovered from individual cultures (and suspended in 1 ml PBS) was determined using a Nanosight NS300 Sub Micron Particle Imaging System (Malvern). A camera level of 12 and a gain of 1 was utilized to optimize data collection, and analyses were performed with Nanoparticle Tracking and Analysis software (NTA 3.1). Each sample was analyzed three times for 30 s at 20 °C using different fields of view. Frame sequences were analyzed under manual particle detection and tracking parameters (screen gain of 4 and detection threshold of 17).
Transmission electron microscopy
For imaging S. aureus ultrathin sections, the cultures were fixed with 2.5% paraformaldehyde, 5% glutaraldehyde, and 0.06% picric acid in cacodylate buffer and postfixed with 1% osmium tetroxide/1.5% potassium ferrocyanide. After incubation in 1% uranyl acetate, samples were sequentially dehydrated in ethanol before they were soaked in propylene oxide and infiltrated overnight with propylene oxide and TAAB Epon. Ultrathin sections were stained with lead citrate. To image EVs, 5 µl S. aureus EVs were adsorbed for 1 min to a carbon coated grid that was made hydrophilic by a 30-s exposure to a glow discharge. The samples were stained with 0.75% uranyl formate. All samples were examined in a TecnaiG2 Spirit BioTWIN transmission electron microscope, and images were recorded with an AMT 2k CCD camera.
Proteomic analysis of EVs by LC–MS/MS
S. aureus EVs (8–10 µg) were subjected to SDS-PAGE and stained with Coomassie Blue R-250. Gel sections were analyzed at the Taplin mass spectrometry facility at Harvard Medical School using an LTQ Orbitrap Velos Pro ion-trap mass spectrometer (Thermo Fisher). Peptide sequences (and hence protein identity) were determined by matching protein databases with the acquired fragmentation pattern using the software program Sequest (Thermo Fisher Scientific). Proteins were identified by a minimum of two peptides and at least one unique peptide. Sequence analysis was performed with a database containing protein sequences of the S. aureus USA300 FPR3757 genome downloaded from NCBIprot. The subcellular localization of each identified protein was predicted by PsortB v.3.0 (www.psort.org/psorb/).
Real-time RT-PCR assay
S. aureus strains were cultivated in 5 ml TSB at 37 °C to an OD650 nm of 0.9. After centrifugation at 4 °C, the bacterial cells were mixed with glass beads in 300 µl lysis buffer (RNeasy mini kit; Qiagen) and lysed by using a high speed Ultramat 2 Amalgamator (SDI, Inc.). Total RNA from the lysate supernatant was purified with the RNeasy mini kit (Qiagen), treated with DNase I (Invitrogen), and stored at −70 °C. cDNA was synthesized from 1 µg of bacterial RNA using a Protoscript II First Strand cDNA synthesis kit (New England Biolabs). A total of 50 ng of synthesized cDNA was subjected to Real-time RT-PCR using a Power Green PCR Master Mix (Applied Biosystems) with primers listed in Supplementary Table 2 and detected in a StepOnePlus Real-Time PCR System (Applied Biosystems). The relative transcriptional levels of hla H35L and lukE were calculated using the ∆∆Ct method by normalizing to the 16S rRNA transcriptional level.
Immunoblotting assays
For western blots, 10 µg S. aureus EVs were subjected to SDS-PAGE, transferred to nitrocellulose membranes, and blocked with PBS + 0.05% Tween-20 (PBST) and 1% skim milk for 1 h at room temperature (RT). After washing with PBST, the membranes were incubated with rabbit anti-LukS-PV (2 μg ml−1; IBT Bioservices; Cat. No. 04-0009) or mouse anti-Hla monoclonal antibody (mAb) 6C12 (1 μg ml−1; IBT Bioservices; Cat. No. 0210-005) overnight at 4 °C. The membranes were washed and incubated with HRP-conjugated goat anti-rabbit IgG (1:5000; ImmunoReagent, Inc.; Cat. No. GtxRb-004-DHRPX) or anti-mouse IgG (1:5000; ImmunoReagent, Inc.; Cat. No. GtxMu-004-DHRPX) for 2 h at RT before developing the blots using TMB membrane peroxidase substrate (Kirkegaard & Perry Laboratories, Inc). Purified Hla (List Biological Labs) and LukE (IBT Bioservices) were used as positive controls. Uncropped scans of the western blots are shown in Supplementary Fig. 6.
For EV dot blotting assays, intact or sonicated EVs were applied to nitrocellulose membranes using a 96-well dot blotter system (Bio-Rad). The membranes were immersed in PBST + 5% skim milk for 2 h before blocking the staphylococcal IgG binding proteins (Spa and Sbi) by overnight incubation at 4 °C with an irrelevant human IgG1 monoclonal antibody (10 µg ml−1) in PBST + 1% skim milk. The membrane was washed with PBST and incubated overnight at 4 °C with sera (diluted 1:1000 in PBST + 1% skim milk) pooled from mice immunized with EVs (see below) or murine mAbs59 to CP5 (4C2; 1.2 µg ml−1) or CP8 (5A6; 1.2 µg ml−1). After washes with PBST, the membrane was incubated with alkaline phosphatase (AP)-conjugated goat anti-mouse antibody (1:15,000; Sigma; Cat. No. A2429) at RT for 2 h. The membrane was washed with PBST and developed with AP membrane substrate (KPL).
EV cytotoxicity
The relative toxicity of S. aureus EVs (1–20 µg ml−1) toward human A549 lung epithelial cells (ATCC), neutrophil-like HL60 cells (ATCC), and rabbit erythrocytes (Hardy Diagnostics) was assessed. A549 lung epithelial cells grown in a 96-well plate were incubated overnight at 37 °C with EVs or 1 µg ml−1 of purified Hla. Toxicity was assessed using an LDH cytotoxicity assay kit (Thermo Fisher Scientific). Differentiated HL60 cells (2 × 105 cells) were seeded in a 96-well plate and treated with EVs or 1 µg ml−1 of PVL for 4 h at 37 °C. Cell viability was measured with a CellTiter kit (Promega). A 2% rabbit erythrocyte suspension was mixed with EVs or 1 µg ml−1 Hla in a 96-well plate for 1 h at 37 °C. The erythrocytes were pelleted by centrifugation, and hemolysis was recorded by measuring the OD545 nm of the supernatant using an ELISA reader.
Animal studies
Mouse experiments were carried out in accordance with the recommendations in the PHS Policy on Humane Care and Use of Laboratory Animals, and animal use protocols were approved by the Partners Healthcare Institutional Animal Care and Use Committee. Female Swiss Webster mice (4 weeks old; Charles River) were immunized by the subcutaneous route on days 0, 14, and 28 with 5 µg of ∆agr EVs, ∆agr∆spa EVs, or eng-EVs. Control animals were immunized similarly with BSA (Sigma). Blood was collected from the mice by tail vein puncture before each vaccination and again before challenge. Sera were diluted 1:100 and tested by ELISA on 96-well plates coated with 5 µg ml−1 sonicated WT EVs, 5 µg ml−1 LukE, or 1 µg ml−1 Hla. Immunized mice were inoculated with 0.8–2 × 108 CFU S. aureus by intravenous (IV) tail vein injection 2 weeks after the third vaccination. Survival was monitored up to 15 days post challenge, and the data were analyzed using the log-rank test.
Toxin neutralization assays
For the Hla neutralization assays, mouse serum samples were pre-incubated with native Hla for 1 h before the addition of 2% rabbit erythrocytes. After 1 h, the cytotoxicity of the serum-neutralized samples was measured by recording the OD545 nm of the sample supernatants68. For leukocidin neutralization assays, blood was collected from healthy volunteers giving written informed consent, as approved by the Institutional Review Board of The Brigham and Women’s Hospital (Human Subject Assurance Number 00000484). Neutrophils were isolated from 10 ml blood using Polymorphprep (Accurate Chemical), washed, and suspended in RPMI (Invitrogen) containing 5% fetal bovine serum (Invitrogen). Sera from immunized mice were serially diluted and mixed with toxin concentrations yielding ~75% cell lysis (12.5 µg ml−1 LukED, 2.5 µg ml−1 PVL, 1 µg ml−1 HlgAB, or 2 µg ml−1 HlgCB (1∶1 S and F subunits). Samples were pre-incubated with leukocidins for 30 min at RT before the addition of neutrophils (1.2 × 105 cells). After 2 h at 37 °C in 5% CO2, the cells were collected by centrifugation and suspended in fresh medium. Cell cytotoxicity was evaluated using a CellTiter kit (Promega). Percent neutralization was calculated using the formula: [% cytotoxicity of (toxin + cells)—% cytotoxicity of (serum + toxin + cells)].
Data availability
Data supporting the findings of this manuscript are available from the corresponding author upon reasonable request. Mass spectrometry proteomics data were deposited in the ProteomeXchange Consortium (http://proteomecentral.proteomexchange.org) via the PRIDE partner repository with the data set identifier PXD007953.
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Acknowledgements
We are grateful to Drs. Michael Otto for providing the S. aureus psm mutants, Jianxun Ding for providing assistance with DLS and nanotracking particle analysis experiments, and Matthew Waldor for use of the StepOnePlus Real-Time PCR System.
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X.W. initiated the project, and X.W., C.W., and J.C.L designed experiments. X.W. performed the experiments with the assistance of C.D.T. All authors analyzed the data, and X.W., C.W., and J.C.L. wrote the manuscript. All authors reviewed the manuscript.
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Wang, X., Thompson, C.D., Weidenmaier, C. et al. Release of Staphylococcus aureus extracellular vesicles and their application as a vaccine platform. Nat Commun 9, 1379 (2018). https://doi.org/10.1038/s41467-018-03847-z
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DOI: https://doi.org/10.1038/s41467-018-03847-z
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