Jeremy Yethon

A mucosal vaccine against Chlamydia trachomatis generates two waves of protective memory T cells

The right combination for protection Despite its prevalence, no vaccine exists to protect against infection with the sexually transmitted bacterium Chlamydia trachomatis. Stary et al. now report on one potential vaccine candidate (see the Perspective by Brunham). Vaccinating with an ultraviolet light-inactivated C. trachomatis linked to adjuvant-containing charged nanoparticles protected female conventional and humanized mice against C. trachomatis infection. The vaccine conferred protection only when delivered through mucosal routes. Protection relied on targeting the bacteria to a particular population of immunogenic dendritic cells and inducing memory T cells that resided in the female genital tract. Science, this issue 10.1126/science.aaa8205; see also p. 1322 A nanoparticle-based vaccine protects mice against infection with Chlamydia trachomatis. [Also see Perspective by Brunham] INTRODUCTION Administering vaccines through nonmucosal routes often leads to poor protection against mucosal pathogens, presumably because such vaccines do not generate memory lymphocytes that migrate to mucosal surfaces. Although mucosal vaccination induces mucosa-tropic memory lymphocytes, few mucosal vaccines are used clinically; live vaccine vectors pose safety risks, whereas killed pathogens or molecular antigens are usually weak immunogens when applied to intact mucosa. Adjuvants can boost immunogenicity; however, most conventional mucosal adjuvants have unfavorable safety profiles. Moreover, the immune mechanisms of protection against many mucosal infections are poorly understood. RATIONALE One case in point is Chlamydia trachomatis (Ct), a sexually transmitted intracellular bacterium that infects >100 million people annually. Mucosal Ct infections can cause female infertility and ectopic pregnancies. Ct is also the leading cause of preventable blindness in developing countries and induces pneumonia in infants. No approved vaccines exist to date. Here, we describe a Ct vaccine composed of ultraviolet light–inactivated Ct (UV-Ct) conjugated to charge-switching synthetic adjuvant nanoparticles (cSAPs). After immunizing mice with live Ct, UV-Ct, or UV-Ct–cSAP conjugates, we characterized mucosal immune responses to uterine Ct rechallenge and dissected the underlying cellular mechanisms. RESULTS In previously uninfected mice, Ct infection induced protective immunity that depended on CD4 T cells producing the cytokine interferon-γ, whereas uterine exposure to UV-Ct generated tolerogenic Ct-specific regulatory T cells, resulting in exacerbated bacterial burden upon Ct rechallenge. In contrast, mucosal immunization with UV-Ct–cSAP elicited long-lived protection. This differential effect of UV-Ct–cSAP versus UV-Ct was because the former was presented by immunogenic CD11b+CD103– dendritic cells (DCs), whereas the latter was presented by tolerogenic CD11b–CD103+ DCs. Intrauterine or intranasal vaccination, but not subcutaneous vaccination, induced genital protection in both conventional and humanized mice. Regardless of vaccination route, UV-Ct–cSAP always evoked a robust systemic memory T cell response. However, only mucosal vaccination induced a wave of effector T cells that seeded the uterine mucosa during the first week after vaccination and established resident memory T cells (TRM cells). Without TRM cells, mice were suboptimally protected, even when circulating memory cells were abundant. Optimal Ct clearance required both early uterine seeding by TRM cells and infection-induced recruitment of a second wave of circulating memory cells. CONCLUSIONS Mucosal exposure to both live Ct and inactivated UV-Ct induces antigen-specific CD4 T cell responses. While immunogenic DCs present the former to promote immunity, the latter is instead targeted to tolerogenic DCs that exacerbate host susceptibility to Ct infection. By combining UV-Ct with cSAP nanocarriers, we have redirected noninfectious UV-Ct to immunogenic DCs and achieved long-lived protection. This protective vaccine effect depended on the synergistic action of two memory T cell subsets with distinct differentiation kinetics and migratory properties. The cSAP technology offers a platform for efficient mucosal immunization that may also be applicable to other mucosal pathogens. Protection against C. trachomatis infection after mucosal UV-Ct–cSAP vaccination. Upon mucosal vaccination, dendritic cells carry UV-Ct–cSAP to lymph nodes and stimulate CD4 T cells. Effector T cells are imprinted to traffic to uterine mucosa (first wave) and establish tissue-resident memory cells (TRM cells). Vaccination also generates circulating memory T cells. Upon genital Ct infection, local reactivation of uterine TRM cells triggers the recruitment of the circulating memory subset (second wave). Optimal pathogen clearance requires both waves of memory cells. Genital Chlamydia trachomatis (Ct) infection induces protective immunity that depends on interferon-γ–producing CD4 T cells. By contrast, we report that mucosal exposure to ultraviolet light (UV)–inactivated Ct (UV-Ct) generated regulatory T cells that exacerbated subsequent Ct infection. We show that mucosal immunization with UV-Ct complexed with charge-switching synthetic adjuvant particles (cSAPs) elicited long-lived protection in conventional and humanized mice. UV-Ct–cSAP targeted immunogenic uterine CD11b+CD103– dendritic cells (DCs), whereas UV-Ct accumulated in tolerogenic CD11b–CD103+ DCs. Regardless of vaccination route, UV-Ct–cSAP induced systemic memory T cells, but only mucosal vaccination induced effector T cells that rapidly seeded uterine mucosa with resident memory T cells (TRM cells). Optimal Ct clearance required both TRM seeding and subsequent infection-induced recruitment of circulating memory T cells. Thus, UV-Ct–cSAP vaccination generated two synergistic memory T cell subsets with distinct migratory properties.

Salmonella enterica Serovar Typhimurium waaP Mutants Show Increased Susceptibility to Polymyxin and Loss of Virulence In Vivo

ABSTRACT In Escherichia coli, the waaP(rfaP) gene product was recently shown to be responsible for phosphorylation of the first heptose residue of the lipopolysaccharide (LPS) inner core region. WaaP was also shown to be necessary for the formation of a stable outer membrane. These earlier studies were performed with an avirulent rough strain of E. coli (to facilitate the structural chemistry required to properly define waaP function); therefore, we undertook the creation of a waaP mutant of Salmonella enterica serovar Typhimurium to assess the contribution of WaaP and LPS core phosphorylation to the biology of an intracellular pathogen. TheS. enterica waaP mutant described here is the first to be both genetically and structurally characterized, and its creation refutes an earlier claim that waaP mutations in S. enterica must be leaky to maintain viability. The mutant was shown to exhibit characteristics of the deep-rough phenotype, despite its ability to produce a full-length core capped with O antigen. Further, phosphoryl modifications in the LPS core region were shown to be required for resistance to polycationic antimicrobials. ThewaaP mutant was significantly more sensitive to polymyxin in both wild-type and polymyxin-resistant backgrounds, despite the decreased negative charge of the mutant LPSs. In addition, thewaaP mutation was shown to cause a complete loss of virulence in mouse infection models. Taken together, these data indicate that WaaP is a potential target for the development of novel therapeutic agents.

Mutation of the Lipopolysaccharide Core Glycosyltransferase Encoded by waaG Destabilizes the Outer Membrane of Escherichia coli by Interfering with Core Phosphorylation

In Escherichia coli, phosphoryl substituents in the lipopolysaccharide core region are essential for outer membrane stability. Mutation of the core glucosyltransferase encoded by waaG (formerly rfaG) resulted in lipopolysaccharide truncated immediately after the inner core heptose residues, which serve as the sites for phosphorylation. Surprisingly, mutation of waaG also destabilized the outer membrane. Structural analyses of waaG mutant lipopolysaccharide showed that the cause for this phenotype was a decrease in core phosphorylation, an unexpected side effect of the waaG mutation.

Structure-guided Antigen Engineering Yields Pneumolysin Mutants Suitable for Vaccination against Pneumococcal Disease

Pneumolysin (PLY) is a cholesterol-binding, pore-forming protein toxin. It is an important virulence factor of Streptococcus pneumoniae and a key vaccine target against pneumococcal disease. We report a systematic structure-driven approach that solves a long-standing problem for vaccine development in this field: detoxification of PLY with retention of its antigenic integrity. Using three conformational restraint techniques, we rationally designed variants of PLY that lack hemolytic activity and yet induce neutralizing antibodies against the wild-type toxin. These results represent a key milestone toward a broad-spectrum protein-based pneumococcal vaccine and illustrate the value of structural knowledge in formulating effective strategies for antigen optimization.

Antibodies to PhnD Inhibit Staphylococcal Biofilms

ABSTRACT Biofilm formation on central lines or peripheral catheters is a serious threat to patient well-being. Contaminated vascular devices can act as a nidus for bloodstream infection and systemic pathogen dissemination. Staphylococcal biofilms are the most common cause of central-line-associated bloodstream infections, and antibiotic resistance makes them difficult to treat. As an alternative to antibiotic intervention, we sought to identify anti-staphylococcal biofilm targets for the development of a vaccine or antibody prophylactic. A screening strategy was devised using a microfluidic system to test antibody-mediated biofilm inhibition under biologically relevant conditions of shear flow. Affinity-purified polyclonal antibodies to target antigen PhnD inhibited both Staphylococcus epidermidis and S. aureus biofilms. PhnD-specific antibodies blocked biofilm development at the initial attachment and aggregation stages, and deletion of phnD inhibited normal biofilm formation. We further adapted our microfluidic biofilm system to monitor the interaction of human neutrophils with staphylococcal biofilms and demonstrated that PhnD-specific antibodies also serve as opsonins to enhance neutrophil binding, motility, and biofilm engulfment. These data support the identification of PhnD as a lead target for biofilm intervention strategies performed either by vaccination or through passive administration of antibodies.

Limitations of Murine Models for Assessment of Antibody-Mediated Therapies or Vaccine Candidates against Staphylococcus epidermidis Bloodstream Infection

ABSTRACT Staphylococcus epidermidis is normally a commensal colonizer of human skin and mucus membranes, but, due to its ability to form biofilms on indwelling medical devices, it has emerged as a leading cause of nosocomial infections. Bacteremia or bloodstream infection is a frequent and costly complication resulting from biofilm fouling of medical devices. Our goal was to develop a murine model of S. epidermidis infection to identify potential vaccine targets for the prevention of S. epidermidis bacteremia. However, assessing the contribution of adaptive immunity to protection against S. epidermidis challenge was complicated by a highly efficacious innate immune response in mice. Naive mice rapidly cleared S. epidermidis infections from blood and solid organs, even when the animals were immunocompromised. Cyclophosphamide-mediated leukopenia reduced the size of the bacterial challenge dose required to cause lethality but did not impair clearance after a nonlethal challenge. Nonspecific innate immune stimulation, such as treatment with a Toll-like receptor 4 (TLR4) agonist, enhanced bacterial clearance. TLR2 signaling was confirmed to accelerate the clearance of S. epidermidis bacteremia, but TLR2−/− mice could still resolve a bloodstream infection. Furthermore, TLR2 signaling played no role in the clearance of bacteria from the spleen. In conclusion, these data suggest that S. epidermidis bloodstream infection is cleared in a highly efficient manner that is mediated by both TLR2-dependent and -independent innate immune mechanisms. The inability to establish a persistent infection in mice, even in immunocompromised animals, rendered these murine models unsuitable for meaningful assessment of antibody-mediated therapies or vaccine candidates.

Correction for Lam et al., antibodies to PhnD inhibit staphylococcal biofilms.

Volume 82, no. 9, p. [3764–3774][1], 2014. Page 3764: The byline and affiliation lines should read as given above. Page 3773, column 1, Acknowledgments. Lines 39–41 should read as follows. “We thank P. D. Fey for strains and plasmids, J. Switzer and P. Mott for cloning and expression