Functional analysis of genetic polymorphism in Wuchereria bancrofti glutathione S-transferase antioxidant gene: impact on protein structure and enzyme catalysis.

Wuchereria bancrofti glutathione S-transferase (Wb-GST) is referred as a promising chemotherapeutic target for lymphatic filariasis. GST represents the major class of detoxifying enzymes of the tissue dwelling parasitic helminths. Though many inhibition studies were carried out for Wb-GST, understanding its genetic distribution in parasite population is necessary to develop ideal inhibitor. Our genetic polymorphic studies exposed the existence of three variant Wb-GST alleles in the four endemic regions of India. Moreover, it also revealed the variability in the distribution of Wb-GST alleles in the studied population. Therefore we cloned, expressed and purified the recombinant variant Wb-GST proteins to study the mutation impact on its structure and hence on its catalysis. Among the studied mutations, the I60F/G78S substitutions in the N-terminal domain and loop region connecting the two domains of Wb-GST lowered the affinity for glutathione and its analog, S-hexyl glutathione. Moreover, molecular modeling and docking studies revealed that the I60F/G78S mutations affected the proximity of Trp38 and Arg95 in glutathione binding site resulting in weaker interaction with S-hexyl glutathione. Besides, the variants also had lower affinity (Ki) and higher IC50 values for well-known GST inhibitors. Interestingly, the Wb-GST variant proteins showed enhanced catalytic efficiency for lipid peroxidation products which are produced due to oxidative stress. Thus, our study provides evidence for the functional impact of mutations on Wb-GST protein and also spotlights the mechanisms of parasite survival against the host oxidative stress environment.

Comparison of immunogenicity, protective efficacy of single and cocktail DNA vaccine of Brugia malayi abundant larval transcript (ALT-2) and thioredoxin peroxidase (TPX) in mice.

Although DNA vaccines have several advantages over conventional vaccines, antibody production and protection are often not adequate, particularly in single plasmid vaccine formulation. In the present study we evaluated the efficacy of a cocktail vaccine based on plasmids encoding larval (L3) stage-specific Brugia malayi abundant larval transcript (BmALT-2) and antioxidant detoxification enzyme B. malayi thioredoxin peroxidase (BmTPX) to induce antibodies, protective efficacy and cell-mediated immune response in mice. Mice immunized with cocktail DNA vaccines containing the pVAX ALT-2+TPX developed higher titers of anti-BmALT-2+TPX (1:5000) antibodies, compared to the mice immunized with single DNA vaccine of pVAX ALT-2 or pVAX TPX (1:2000). Correlating with this, the mice administered with cocktail vaccine induced up to 78% of cytotoxicity against B. malayi mf. This cytotoxicity was high compared to 34% induced by the pVAX-ALT2 or 37% by pVAX-TPX. Moreover, cocktail vaccination of mice resulted in significantly higher level of cellular proliferative response associated with raised levels of IFN-gamma that skewed towards Th1 type of response compared to vaccination using either of the components. Taken together, these data suggest that the combination of two or more antigens maybe an effective vaccine development strategy to improve protection and immunogenicity against human lymphatic filariasis.