Vaccination with recombinant chlamydial protease-like activity factor (rCPAF) has been shown to provide robust protection against genital Chlamydia infection. Adoptive transfer of IFN-γ competent CPAF-specific CD4+ T cells was sufficient to induce early resolution of chlamydial infection and reduction of subsequent pathology in recipient IFN-γ-deficient mice indicating the importance of IFN-γ secreting CD4+ T cells in host defense against Chlamydia. In this study, we identify CD4+ T cell reactive CPAF epitopes and characterize the activation of epitope-specific CD4+ T cells following antigen immunization or Chlamydia challenge. Using the HLA-DR4 (HLA-DRB1*0401) transgenic mouse for screening overlapping peptides that induced T cell IFN-γ production, we identified at least 5 CPAF T cell epitopes presented by the HLA-DR4 complex. Immunization of HLA-DR4 transgenic mice with a rCPAFep fusion protein containing these 5 epitopes induced a robust cell-mediated immune response and significantly accelerated the resolution of genital and pulmonary Chlamydia infection. rCPAFep vaccination induced CPAF-specific CD4+ T cells in the spleen were detected using HLA-DR4/CPAF-epitope tetramers. Additionally, CPAF-specific CD4+ clones could be detected in the mouse spleen following C. muridarum and a human C. trachomatis strain challenge using these novel tetramers. These results provide the first direct evidence that a novel CPAF epitope vaccine can provide protection and that HLA-DR4/CPAF-epitope tetramers can detect CPAF epitope-specific CD4+ T cells in HLA-DR4 mice following C. muridarum or C. trachomatis infection. Such tetramers could be a useful tool for monitoring CD4+ T cells in immunity to Chlamydia infection and in developing epitope-based human vaccines using the murine model.
Background:Pulmonary Francisella infection resulted in reduction of plasma alkaline phosphatase activity. Results: Francisella heat shock protein DnaK binds to alkaline phosphatase thus reducing enzymatic activity. Conclusion: A Francisella protein component responsible for alkaline phosphatase inhibition was identified. Significance: We present a novel mechanism used by a bacterial pathogen to evade the host's defense.
BACKGROUND: There is an unmet need to identify novel targeted therapies for Diffuse Midline glioma (DMG) which is currently a refractory disease. Recently, we identified high expression of a cell surface antigen, CD99 in H3K27M-mutant expressing DMGs compared to other normal brain counterparts. We developed a novel chimeric CD99 antibody and tested the anti-tumor efficacy of this antibody in vitro and in vivo. METHOD: Bio-legend cell-surface screening was performed in H3K27M-mutant and WT DMG cells. Functional role of CD99 was studied using CD99 proficient and depleted tumors. Designed and synthesized CD99 antibody with a new binding sequence on a human IgG scaffold and performed cell toxicity and growth-inhibitory studies using DMG tumor and normal cells. We also performed these studies in combination with radiation. Multiple patient-derived orthotopic DMG xenograft models was used to test the antibody efficacy. Different antibody delivery routes, that are clinically relevant were investigated. RESULTS: CD99 expression is transcriptionally regulated by H3K27M and is enriched on the cell surface of K27M tumors compared to WT DMG tumors. Our new CD99 antibody (10D1 clone) significantly reduced DIPG tumor cell proliferation in vitro. Intravenous infusion of this antibody in DIPG tumor bearing mice showed complete clearance of tumor that prolonged animal survival suggesting the enhanced anti-tumor efficacy of 10D1-CD99 and importantly, its ability in crossing the blood-brain-barrier and reaching the pons target site. Loco-regional administration of 10D1 showed similar anti-tumor effects even at much reduced antibody concentrations while toxicity to CD99-expressing T cells was minimum. Radiation increased CD99 expression and enhanced the cytotoxic effect of 10D1-CD99. CONCLUSION: We have developed a novel CNS penetrant CD99 antibody that is an attractive therapeutic strategy in treating DMG. 10D1 is currently in development as a therapeutic.
Background and Rationale Diffuse intrinsic pontine glioma (DIPG) is one of the most aggressive pediatric brain tumors. Currently, the main treatment for DIPG is radiation and it’s only a palliative care, as the tumor eventually becomes resistant to radiation. In this study we found that radiation leads to an increase in anti-apoptotic BH3 proteins mainly BCL2 in DIPG. Previous studies in other tumor types have shown that increase in these pro-survival BCL2 family members are associated with treatment resistance and poor prognosis. Therefore, we hypothesize that inhibition of BCL2 using a small-molecule inhibitor, venetoclax that crosses the blood-brain barrier, will represent a possible therapeutic strategy to overcome radiation resistance in DIPG. Approach: For in vitro studies, DIPG cells were exposed to different radiation doses (0–10 Gy) and the magnitude of the sensitizing effect of venetoclax (with IC15) was calculated by clonogenic assay. Evaluated BCL2 family proteins by western and cytotoxicity by cleaved caspase incucyte assays. For in vivo studies, NSG mice orthotopically engrafted with a human H3K27M-DIPG luciferase-expressing cells in the pons were exposed to a focal fractionated radiation of 2Gy/day for 3 days. Mice were randomized into 2 groups based on bioluminescence IVIS signal intensity; each group receiving either venetoclax (15 mg/kg, by i.p) 3 days/week for 10 weeks or vehicle. Decrease in tumor burden was measured by IVIS and survival was evaluated compared to vehicle treated mice. Results Single agent venetoclax showed no significant activity against DIPG tumors in in vitro and in vivo DIPG xenografts. Single-agent radiation cleared the tumor burden but only transiently. Combination of radiation with venetoclax showed considerable synergistic anti-tumor effect in vitro and in vivo leading to a significant increase in animal survival beyond either single agent treatments. The metabolic reprogramming that results in this enhanced cell-killing effect will be discussed.
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