Metabolic labelling of the carbohydrate core in bacterial peptidoglycan and its applications.

Bacterial cells are surrounded by a polymer known as peptidoglycan (PG), which protects the cell from changes in osmotic pressure and small molecule insults. A component of this material, N-acetyl-muramic acid (NAM), serves as a core structural element for innate immune recognition of PG fragments. We report the synthesis of modifiable NAM carbohydrate derivatives and the installation of these building blocks into the backbone of Gram-positive and Gram-negative bacterial PG utilizing metabolic cell wall recycling and biosynthetic machineries. Whole cells are labelled via click chemistry and visualized using super-resolution microscopy, revealing higher resolution PG structural details and allowing the cell wall biosynthesis, as well as its destruction in immune cells, to be tracked. This study will assist in the future identification of mechanisms that the immune system uses to recognize bacteria, glean information about fundamental cell wall architecture and aid in the design of novel antibiotics.

Murine macrophage inflammatory cytokine production and immune activation in response to Vibrio parahaemolyticus infection.

Vibrio parahaemolyticus is the most common cause of bacterial, seafood-related illness in the USA. Currently, there is a dearth of published reports regarding immunity to infection with this pathogen. Here, production of both pro- and anti-inflammatory cytokines by V. parahaemolyticus-infected RAW 264.7 murine macrophages was studied. It was determined that this infection results in increased concentrations of IL-1α, IL-6, TNF-α and IL-10. Additionally, decreases in cell surface TLR2 and TLR4 and increases in T-cell co-stimulatory molecules CD40 and CD86 were discovered. The data presented here begin to identify the immune variables required to eliminate V. parahaemolyticus from infected host tissues.

D27-pLpxL, an avirulent strain of Yersinia pestis, primes T cells that protect against pneumonic plague.

Vaccinating with live, conditionally attenuated, pigmentation (Pgm)-deficient Yersinia pestis primes T cells that protect mice against pneumonic plague. However, Pgm-deficient strains are not considered safe for human use because they retain substantial virulence in animal models. Y. pestis strains engineered to express Escherichia coli LpxL are avirulent owing to constitutive production of lipopolysaccharide with increased Toll-like receptor 4-activating ability. We generated an LpxL-expressing Pgm-deficient strain (D27-pLpxL) and demonstrate here that this avirulent strain retains the capacity to prime protective T cells. Compared with unvaccinated controls, mice immunized intranasally with live D27-pLpxL exhibit a decreased bacterial burden and increased survival when challenged intranasally with virulent Y. pestis. T cells provide a substantial degree of this protection, as vaccine efficacy is maintained in B-cell-deficient muMT mice unless those animals are depleted of CD4 and CD8 T cells at the time of challenge. Upon challenge with Y. pestis, pulmonary T-cell numbers decline in naive mice, whereas immunized mice show increased numbers of CD44(high) CD43(high) effector T cells and T cells primed to produce tumor necrosis factor alpha and gamma interferon; neutralizing these cytokines at the time of challenge abrogates protection. Immunization does not prevent dissemination of Y. pestis from the lung but limits bacterial growth and pathology in visceral tissue, apparently by facilitating formation of granuloma-like structures. This study describes a new model for studying T-cell-mediated protection against pneumonic plague and demonstrates the capacity for live, highly attenuated, Y. pestis vaccine strains to prime protective memory T-cell responses safely.

Antibodies and cytokines independently protect against pneumonic plague.

Yersinia pestis causes pneumonic plague, an exceptionally virulent disease for which we lack a safe and effective vaccine. Antibodies specific for the Y. pestis F1 and LcrV proteins can protect mice against pulmonary Y. pestis infection. We demonstrate that neutralizing tumor necrosis factor-alpha (TNFalpha) and gamma-interferon (IFNgamma) abrogates this protection at sub-optimal levels of F1- or LcrV-specific antibody, but not at optimal levels. Moreover, we demonstrate that endogenous TNFalpha and IFNgamma confer measurable protection in the complete absence of protective antibodies. These findings indicate that antibodies and cytokines independently protect against pneumonic plague and suggest that surrogate assays for plague vaccine efficacy should consider both the level of vaccine-induced antibody and the capacity of vaccine recipients to produce TNFalpha and IFNgamma upon exposure to Y. pestis.

Gamma interferon suppresses erythropoiesis via interleukin-15.

Impaired erythropoiesis causes anemia during genetic disorders, chronic disease, and infection. In studies of the underlying mechanisms researchers have increasingly focused on gamma interferon (IFN-gamma). Here, we identified a previously unrecognized role for interleukin-15 (IL-15) in red blood cell homeostasis and demonstrated that IFN-gamma and signal transducer and activator of transcription protein 1-dependent pathways up-regulate expression of IL-15 in vivo. These findings identified new therapeutic targets for anemia.

Brucella abortus bacA mutant induces greater pro-inflammatory cytokines than the wild-type parent strain.

The inner-membrane protein BacA affects Brucella LPS structure. A bacA deletion mutant of Brucella abortus, known as KL7 (bacA(mut)-KL7), is attenuated in BALB/c mice and protects against challenge. Thus, bacA mutation was a candidate for incorporation into live attenuated vaccines. We assessed bacA(mut)-KL7 in 2 additional mouse strains: the more resistant C57BL/6 that produces interferon-gamma throughout the infection and the highly susceptible interferon-gamma-deficient C57BL/6 in which brucellae exhibit continual exponential growth. While it was hypothesized that bacA(mut)-KL7 would exhibit even greater attenuation relative to its parent strain B. abortus 2308 in C57BL/6 mice than it did in BALB/c mice, this was not the case. Moreover, it was more pathogenic in C57BL/6 interferon-gamma-deficient mice than 2308 causing abscesses and wasting even though the splenic loads of bacA(mut)-KL7 were significantly lower. These 2 observations were correlated, respectively, with an ability of IFNgamma-activated macrophages to equivalently control strains 2308 and bacA(mut)-KL7 and the ability of bacA(mut)-KL7 organism and its LPS to induce greater amounts of pro-inflammatory cytokines than 2308. We conclude that attenuation properties of bacA mutation are dependent upon the nature of the host but more importantly that bacterial gene deletion can result in increased host pathology without an increase in bacterial load, crucial considerations for vaccine design.

Gamma interferon, tumor necrosis factor alpha, and nitric oxide synthase 2, key elements of cellular immunity, perform critical protective functions during humoral defense against lethal pulmonary Yersinia pestis infection.

Pulmonary infection by Yersinia pestis causes pneumonic plague, a rapidly progressing and often fatal disease. To aid the development of safe and effective pneumonic plague vaccines, we are deciphering mechanisms used by the immune system to protect against lethal pulmonary Y. pestis infection. In murine pneumonic plague models, passive transfer of convalescent-phase sera confers protection, as does active vaccination with live Y. pestis. Here, we demonstrate that protection by either protocol relies upon both gamma interferon (IFN-gamma) and tumor necrosis factor alpha (TNF-alpha) cytokines classically associated with type 1 cellular immunity. In both protocols, abrogating IFN-gamma or TNF-alpha activity significantly decreases survival and increases the bacterial burden in pulmonary, splenic, and hepatic tissues. Neutralization of either cytokine also counteracts challenge-induced, vaccination-dependent upregulation of nitric oxide synthase 2 (NOS2). Moreover, genetic depletion of NOS2 suppresses protection conferred by serotherapy. We conclude that IFN-gamma, TNF-alpha, and NOS2, key elements of cellular immunity, perform critical protective functions during humoral defense against lethal pulmonary Y. pestis challenge. These observations strongly suggest that plague vaccines should strive to maximally prime both cellular and humoral immunity.

Tumor necrosis factor alpha and gamma interferon, but not hemorrhage or pathogen burden, dictate levels of protective fibrin deposition during infection.

While coagulation often causes pathology during infectious disease, we recently demonstrated that fibrin, a product of the coagulation pathway, performs a critical protective function during acute toxoplasmosis (L. L. Johnson, K. N. Berggren, F. M. Szaba, W. Chen, and S. T. Smiley, J. Exp. Med. 197:801-806, 2003). Here, we investigate the mechanisms regulating the formation of this protective fibrin. Through comparisons of Toxoplasma-infected wild-type and cytokine-deficient mice we dissociate, for the first time, the relative fibrin-regulating capacities of pathogen products, host cytokines, and infection-stimulated hemorrhage. Remarkably, neither the pathogen burden nor hemorrhage is a primary regulator of fibrin levels. Rather, two type 1 cytokines exert dominant and counterregulatory roles: tumor necrosis factor alpha (TNF-alpha), acting via the type 1 TNF-alpha receptor, promotes fibrin deposition, while gamma interferon (IFN-gamma), acting via STAT1 and IFN-gamma receptors expressed on radioresistant cells, suppresses fibrin deposition. These findings have important clinical implications, as they establish that cytokines known to regulate pathological coagulation also dictate levels of protective fibrin deposition. We present a novel model depicting mechanisms by which the immune system can destroy infected tissue while independently restraining hemorrhage and promoting tissue repair through the deliberate deposition of protective fibrin.

Infection-stimulated fibrin deposition controls hemorrhage and limits hepatic bacterial growth during listeriosis.

Bacterial infections are major causes of human mortality. The activation of coagulation pathways leading to the deposition of insoluble fibrin frequently accompanies bacterial infection, and much attention has focused upon the pathological attributes of infection-stimulated fibrin deposition. Nevertheless, here we present conclusive evidence that infection-stimulated fibrin deposition can perform critical protective functions during bacterial infection. Specifically, we demonstrate that coagulation-impaired fibrin(ogen)-deficient mice, in comparison with genetically matched control mice, display increased mortality upon peritoneal infection with the gram-positive facultative intracellular bacterium Listeria monocytogenes. To distinguish effects of fibrinogen from those of fibrin, we treat wild-type mice with warfarin, an anticoagulant that suppresses fibrin formation without impacting fibrinogen levels. Warfarin treatment exacerbates listeriosis, suggesting that fibrin is the key mediator of protection. With regard to the underlying protective mechanisms, we demonstrate that fibrin(ogen) suppresses anemia, reduces hemorrhagic pathology, and limits bacterial growth during listeriosis. Despite confirming a prior report that fibrin(ogen) promotes the peritoneal clearance of the extracellular bacterium Staphylococcal aureus, we demonstrate that fibrin(ogen) plays little role in controlling peritoneal numbers of L. monocytogenes bacteria or the dissemination of L. monocytogenes bacteria from the peritoneal cavity. Rather, fibrin(ogen) primarily limits the growth of these intracellular bacteria within hepatic tissue. While the pathological potential of excessive infection-stimulated fibrin deposition is well appreciated, our findings reveal that fibrin can function protectively, via multiple mechanisms, during bacterial infection.

Brucella abortus siderophore 2,3-dihydroxybenzoic acid (DHBA) facilitates intracellular survival of the bacteria.

Siderophores are low molecular weight molecules that allow bacteria to acquire iron from host cell proteins. 2,3-dihydroxybenzoic acid (DHBA) is the only known siderophore produced by the intracellular pathogen Brucella abortus. Here its role in virulence was assessed by evaluating the ability of a mutant with a disruption of the entC gene to survive and replicate in vitro in murine and bovine cells and in vivo in resistant and susceptible murine hosts. It was hypothesized that DHBA is vital for bacterial virulence by its ability to chelate intracellular iron thereby preventing generation of anti-bacterial hydroxyl radicals via the Haber-Weiss reaction, to scavenge reactive oxygen intermediates and for acquisition of iron needed for nutritional purposes. The data showed DHBA played a significant role for bacterial survival in host cells after infection including in murine macrophages cultured in the presence and absence of exogenous interferon-gamma (IFN-gamma) and in bovine trophoblasts supplemented with erythritol. In severely iron-depleted conditions, DHBA was also found to be essential for growth in murine macrophages. Despite these deficiencies, the absence of DHBA had no long-term significant effect on the number of CFU recovered in vivo from either the Brucella-resistant C57BL/6 mice or Brucella-susceptible IFN-gamma knock-out C57BL/6 mice.