Protective effect of ß-glucan on Poly(I:C)-induced acute lung injury/inflammation: Therapeutic implications of viral infections in the respiratory system.

AIMS: Acute lung inflammation, particularly acute respiratory distress syndrome (ARDS), is caused by a variety of pathogens including bacteria and viruses. ß-Glucans have been reported to possess both anti-inflammatory and immunomodulatory properties. The current study evaluated the therapeutic effect of ß-glucans on polyinosinic:polycytidylic acid (Poly(I:C)) induced lung inflammation in both hamster and mice models. MAIN METHODS: Poly(I:C)-induced ALI/inflammation models were developed in hamsters (2.5 mg/kg) and mice (2 mg/kg) by delivering the Poly(I:C) intratracheally, and followed with and without ß-glucan administration. After treatment, lung mechanics were assessed and lung tissues were isolated and analyzed for mRNA/protein expression, and histopathological examinations. KEY FINDINGS: Poly(I:C) administration, caused a significant elevation of inflammatory marker's expression in lung tissues and showed abnormal lung mechanics in mice and hamsters. Interestingly, treatment with ß-glucan significantly (p < 0.001) reversed the Poly(I:C)-induced inflammatory events and inflammatory markers expression in both mRNA (IL-6, IL-1ß, TNF-α, CCL2 and CCL7) and protein levels (TNF-α, CD68, myeloperoxidase, neutrophil elastase, MUC-5Ac and iNOS). Lung functional assays revealed that ß-glucan treatment significantly improved lung mechanics. Histopathological analysis showed that ß-glucan treatment significantly attenuated the Poly(I:C) induced inflammatory cell infiltration, injury and goblet cell population in lung tissues. Consistent with these findings, ß-glucan treatment markedly reduced the number of neutrophils and macrophages in lung tissues. Our findings further demonstrated that ß-glucan could reduce inflammation by suppressing the MAPK pathway. SIGNIFICANCE: These results suggested that ß-glucan may attenuate the pathogenic effects of Poly(I:C)-induced ALI/ARDS via modulating the MAPK pathway, indicating ß-glucan as a possible therapeutic agent for the treatment of viral-pulmonary inflammation/injury.

Immunoprophylaxis of multi-antigen peptide (MAP) vaccine for human lymphatic filariasis.

Human lymphatic filariasis, the parasitic disease caused by the filarial nematodes Wuchereria bancrofti, Brugia malayi, and Brugia timori, is ranked as the second most complex clinical condition leading to permanent and long-term disability. The multiple antigen peptide (MAP) approach is an effective method to chemically synthesize and deliver multiple T and B cell epitopes as the constituents of a single immunogen. Here, we report on the design, chemical synthesis, and immunoprophylaxis of three epitopes that have been identified from promising vaccine candidates reported in our previous studies, constructed as MAP on an inert lysine core for human lymphatic filariasis in Jird model. Two epitopes from Thioredoxin and one epitope from Transglutaminase were constructed as MAP in an inert lysine core. The immunoprophylaxis of the synthetic vaccine construct studied in Jird models showed protective antibody (1 in 64,000 titer) and cellular immune response. Thioredoxin-Transglutaminase MAP (TT MAP) conferred a significantly high protection of 63.04% compared to control (8.5%). Multi-antigen peptide vaccine is one best approach to provide immunity against multiple antigens delivered by the complex filarial parasite.

Dissecting the Immune Response Elicited by WbALT-2, ALT MAP in Clinical Populations and Mouse Model: A Prophylactic Measure Against Lymphatic Filariasis.

BACKGROUND: Abundant Larval Transcript (ALT) is one of the major groups of immune-dominant proteins produced by filarial worms during their larval stage. The major B-cell and T-cell epitopic domains of the ALT-2 antigen were mapped to develop a multiple antigenic peptide (MAP) prophylactic antigen against lymphatic filariasis. METHODS AND RESULTS: ALT MAP was constructed by solid phase peptide synthesis. The reactivity of whole ALT protein and ALT MAP against clinical sera described a high reactivity of endemic normal sera against ALT MAP compared to WbALT-2 protein. The antibody isotype pattern revealed elevated levels of IgG1 and IgG2 against ALT MAP, followed by IgG3 and IgG4. In this study we also analyzed the immune response pattern elicited by ALT MAP, ALT in mice models, which revealed similar pattern of humoral response, while low T cell proliferation in ALT MAP groups. The low proliferation could be attributed to T/B epitope arrangement on the construct, MHC restriction, and incomplete signal delivery by T cell receptor. CONCLUSION: The immunodominant epitopes in ALT MAP were found to play a crucial role in inducing high antigen specific proliferation. This revealed the significance of ALT MAP in stimulating innate immunity in offering protective immune response probably through the activation of complement cascade along with stimulation of cellular response. An improved understanding, including the construction of ALT MAP and parasite challenge study in jirds to determine the worm clearance would give a better insight in the characterization ALT MAP construct as a prophylactic vaccine candidate.