Neutralization of B. anthracis toxins during ex vivo phagocytosis.

Glycoconjugates (GCs) are recognized as stimulation and signaling agents, affecting cell adhesion, activation, and growth of living organisms. Among GC targets, macrophages are considered ideal since they play a central role in inflammation and immune responses against foreign agents. In this context, we studied the effects of highly selective GCs in neutralizing toxin factors produced by B. anthracis during phagocytosis using murine macrophages. The effects of GCs were studied under three conditions: A) prior to, B) during, and C) following exposure of macrophages to B. anthracis individual toxin (protective antigen [PA], edema factor [EF], lethal factor [LF] or toxin complexes (PA-EF-LF, PA-EF, and PA-LF). We employed ex vivo phagocytosis and post-phagocytosis analysis including direct microscopic observation of macrophage viability, and macrophage activation. Our results demonstrated that macrophages are more prone to adhere to GC-altered PA-EF-LF, PA-EF, and PA-LF toxin complexes. This adhesion results in a higher phagocytosis rate and toxin complex neutralization during phagocytosis. In addition, GCs enhance macrophage viability, activate macrophages, and stimulate nitric oxide (NO) production. The present study may be helpful in identifying GC ligands with toxin-neutralizing and/or immunomodulating properties. In addition, our study could suggest GCs as new targets for existing vaccines and the prospective development of vaccines and immunomodulators used to combat the effects of B. anthracis.

Glycoconjugates prevent B. anthracis toxin-induced cell death through binding while activating macrophages.

Bacillus anthracis toxins may be attenuated if macrophages could neutralize toxins upon contact or exposure. Glycoconjugate-bearing polymers, which have been shown to bind to Bacillus spores, were tested for recognition and binding of protective antigen (PA), lethal factor (LF), and edema factor (EF) toxins. We have demonstrated modulation of macrophage activity following exposure to these toxins. Without glycoconjugate (GC) activation, murine macrophages were killed by Bacillus toxins. GCs were shown to have a protective influence, sparing macrophages from toxin-induced cell death, as shown by increased macrophage cell viability based on trypan blue assay. Increased levels of inducible nitric oxide (NO) production by macrophages in presence of GCs suggest that GCs provide an activation signal for macrophages and stimulate their function. Results hint to GCs that promote neutralization of Bacillus toxins, block toxin-induced macrophage death, while increasing macrophage activation. Polymeric GCs may suggest novel approaches to improve existing or develop new vaccines as well as immunotherapeutics.

Killing of Bacillus spores is mediated by nitric oxide and nitric oxide synthase during glycoconjugate-enhanced phagocytosis.

Nitric oxide (NO) is a signaling and defense molecule of major importance. NO endows macrophages with bactericidal, cytostatic as well as cytotoxic activity against various pathogens. Bacillus spores can produce serious diseases, which might be attenuated if macrophages were able to kill the spores on contact. Present research was carried out to study whether glycoconjugates stimulated NO and nitric oxide synthase (NOS2) production during phagocytosis killing of Bacillus spores. Murine macrophages exposed to glycoconjugate-treated spores induced NOS2 and NO production that was correlated with high viability of macrophages and killing rate of bacterial spores. Increased levels of inducible NOS2 and NO production by macrophages in presence of glycoconjugates suggested that the latter provide an activation signal directed to macrophages. Glycoconjugates were shown to exert a protective influence, sparing macrophages from spore-induced cell death. In presence of glycoconjugates, macrophages efficiently kill the organisms. Without glycoconjugate activation, murine macrophages were ineffective at killing Bacillus spores. These results suggest that glycoconjugates promote killing of Bacillus spores by blocking spore-induced macrophage cell death, while increasing their activation level and NO and NOS2 production. Glycoconjugates suggest novel antimicrobial approaches to prevention and treatment of infection caused by bacterial spores.

Selective deficiency of HIF-1alpha in myeloid cells influences secondary intention wound healing in mouse skin.

BACKGROUND: Hypoxia-inducible factor-1 (HIF-1) influences myeloid cell function. In this study we examined the role of myeloid cell HIF-1alpha on wound healing in vivo using a cell-specific knockout (KO) mouse model. MATERIALS AND METHODS: HIF-1alpha KO mice and wild-type (WT) controls received 8 mm full thickness dorsal dermal wounds. Wound dimensions were measured until full closure. Tissue was obtained from 3-day-old wounds for (immuno-)histochemical analysis. Production of interleukin-1beta (IL-1beta) and nitric oxide (NO) in response to lipopolysaccharide (LPS) and/or desferrioxamine (DFX) was examined in vitro. RESULTS: Early wound closure occurred significantly faster in HIF-1alpha KO mice than in WT mice. Wounds of KO mice contained similar numbers of neutrophils and macrophages, but more activated keratinocytes, consistent with accelerated re-epithelialization. Interestingly, while LPS and LPS+DFX elicited a similar IL-1beta response in macrophages from the 2 mouse types, NO production was blunted in HIF-1alpha KO macrophages. CONCLUSION: Absence of HIF-1alpha in myeloid cells accelerates the early phase of secondary intention wound healing in vivo. This may be associated with a deficient ability of myeloid cells to initiate an appropriate NO production response. Pharmacologic modulators of HIF-1alpha should be explored in situations with abnormal wound healing.

Glycoconjugates enhanced the intracellular killing of Bacillus spores, increasing macrophage viability and activation.

Infections caused by Bacillus spores can be attenuated if the intracellular killing of the organism by macrophages can be enhanced. Glycoconjugate-bearing polymers, which selectively bind to Bacillus spores, were tested for modulation of intracellular killing when added prior to, during, and following macrophage exposure to B. cereus spores. In the absence of glycoconjugates, murine macrophages were ineffective at killing Bacillus spores. In presence of glycoconjugates, however, macrophages efficiently killed spores, whether the glycoconjugates were added to the cells prior to, during, and following spore addition. Glycoconjugates were shown to exert a protective influence on macrophages and increase their activation, as evidenced by viability and lactate dehydrogenase release assays. Increased levels of nitric oxide production by macrophages pretreated with glycoconjugates suggest that, under these conditions, glycoconjugates provide an activation signal to macrophages. These results indicate that glycoconjugates promote killing of Bacillus spores, while increasing macrophage activation level and viability. The selection of glycoconjugate ligands bearing immunomodulating properties could be exploited for vaccine and/or immunomodulator development and/or for the improvement of existing vaccines against B. cereus and B. anthracis.

Polymeric glycoconjugates protect and activate macrophages to promote killing of Bacillus cereus spores during phagocytosis.

Diseases caused by Bacillus spores might be attenuated if macrophages were able to kill the spores on exposure. Glycoconjugate-bearing polymers, which have been shown to bind to Bacillus spores, were tested for modulation of phagocytosis of B. cereus spores. Without glycoconjugate activation, murine macrophages were ineffective at killing Bacillus spores during phagocytosis. In the presence of glycoconjugates, however, the macrophages efficiently killed the organisms. The glycoconjugates were shown to have a protective influence, sparing macrophages from spore-induced cell death. Very low concentrations of the glycoconjugates prevented macrophage cell death, as shown by lactate dehydrogenase (LDH) release and trypan blue assays. Increased levels of inducible nitric oxide (NO) production by the macrophages in the presence of glycoconjugates suggested that the glycoconjugates provide an activation signal to the macrophages. These results suggest that glycoconjugates promote the killing of Bacillus spores by blocking spore-induced macrophage cell death, while increasing their activation level. Polymeric glycoconjugates may suggest novel approaches to improve existing vaccines as well as prevent and treat infections incurred through either B. cereus or B. anthracis spores.

Macrophage production of inflammatory mediators is potently inhibited by a butyric acid derivative demonstrated to inactivate antigen-stimulated T cells.

The butyric acid derivative, 2-(4-morpholynl) ethyl butyrate hydrochloride (MEB), has been reported to induce antigen-specific T cell unresponsiveness and to block T cell-mediated graft-versus-host disease. As a potential therapeutic agent, it was important to determine the effects of MEB on other cells that contribute to immunopathology. Accordingly, we tested the effects of MEB on macrophage functions. MEB did not affect macrophage viability, phagocytic activity, or the activation-induced up-regulation of molecules associated with antigen presentation: MHC-II, CD86, CD40, or ICAM-1. However, MEB potently inhibited activation-induced production of inflammatory mediators, including tumor necrosis factor-alpha (TNF-alpha), IL-6, chemokine CCL2 and nitric oxide (NO). MEB inhibited the induction of NO synthase (NOS2), which is necessary for inducible NO, and inhibited nuclear translocation of NFkappaB, suggesting that MEB interferes with the signaling pathway involved in NOS2 induction. Thus, while inducing specific T cell unresponsiveness, MEB also exerts anti-inflammatory activity by acting on macrophages to suppress production of cytokines and NO.

Inhaled isobutyl nitrite inhibited macrophage inducible nitric oxide by blocking NFkappaB signaling and promoting degradation of inducible nitric oxide synthase-2.

We previously reported that inhaled isobutyl nitrite inhibited macrophage tumoricidal activity by inhibiting inducible nitric oxide (NO) production. In the present study, a much shorter inhalant exposure regimen (five daily exposures) inhibited inducible NO and the NO synthase (NOS2). One of the ways in which NO and NOS2 are regulated is by ubiquitin-dependent NOS2 degradation. Immunoprecipitated NOS2 showed increased poly-ubiquitination, following exposure to the inhalant. In addition, Western blots of macrophage nuclear extracts for the NFkappaB subunit, p65, showed that exposure to the inhalant inhibited NFkappaB signaling, necessary for induction of NOS2. The inhalant blocked phosphorylation of the NFkappaB inhibitor, IkappaBalpha. The inhibition of NFkappaB signaling following inhalant exposure was confirmed using mice transgenic for the kappaB-dependent promoter of the HIV 5' LTR linked to luciferase. The data suggested that inhalant exposure likely inhibited macrophage NO production by blocking NFkappaB-mediated activation signaling and promoting poly ubiquitination of NOS2.

Cytotoxicity by nitrite inhalants is not related to peroxynitrite formation.

Nitrite inhalant abuse has been correlated with HIV and Kaposi's sarcoma. Mouse models of inhalant exposure show immunosuppression and loss of immune cells. In the present study, isobutyl nitrite caused a dose-dependent loss of viability of a macrophage cell line. In the absence of cells, isobutyl nitrite reacted with hydrogen peroxide to form peroxynitrite. However, assays of mitochondrial respiration and nitration that detect peroxynitrite indicated that very little was present in cell cultures following exposure to the inhalants. Isobutyl, isoamyl, and butyl nitrites inhibited mitochondrial respiration, but only at high concentrations. Similarly, the nitrating activity of isobutyl nitrite occurred only at high concentrations and was not affected by the presence of hydrogen peroxide. Western blots showed that the inhalant did not increase nitrotyrosine formation in RAW cells or in peritoneal exudate macrophages (PEM) from exposed mice. Thus, the toxicity induced by isobutyl nitrite was probably not due to peroxynitrite formation.