Association of ebola virus matrix protein VP40 with microtubules

Viruses exploit a variety of cellular components to complete their life cycles, and it has become increasingly clear that use of host cell microtubules is a vital part of the infection process for many viruses. A variety of viral proteins have been identified that interact with microtubules, either directly or via a microtubule-associated motor protein. Here, we report that Ebola virus associates with microtubules via the matrix protein VP40. When transfected into mammalian cells, a fraction of VP40 colocalized with microtubule bundles and VP40 coimmunoprecipitated with tubulin. The degree of colocalization and microtubule bundling in cells was markedly intensified by truncation of the C terminus to a length of 317 amino acids. Further truncation to 308 or fewer amino acids abolished the association with microtubules. Both the full-length and the 317-amino-acid truncation mutant stabilized microtubules against depolymerization with nocodazole. Direct physical interaction between purified VP40 and tubulin proteins was demonstrated in vitro. A region of moderate homology to the tubulin binding motif of the microtubule-associated protein MAP2 was identified in VP40. Deleting this region resulted in loss of microtubule stabilization against drug-induced depolymerization. The presence of VP40-associated microtubules in cells continuously treated with nocodazole suggested that VP40 promotes tubulin polymerization. Using an in vitro polymerization assay, we demonstrated that VP40 directly enhances tubulin polymerization without any cellular mediators. These results suggest that microtubules may play an important role in the Ebola virus life cycle and potentially provide a novel target for therapeutic intervention against this highly pathogenic virus.     

A new Bacillus pasteurii urease inhibitor from Euphorbia decipiens

Inhibition of Bacillus pasteurii urease enzyme by 3,7,15-tri-O-acetyl-5-O-nicotinoyl-13,14-dihydroxymyrsinol (1), a diterpene ester with a myrsinol-type skeleton, isolated from Euphorbia decipiens Boiss. and Buhse, was un-competitive consistent with the molecular docking results. The Ki value was 117.40 +/- 0.7 microM.     

Biophysical analyses of human resistin: oligomer formation suggests novel biological function

Resistin, a small secreted peptide initially identified as a link between obesity and diabetes in mice, was shown to be involved in mediating inflammation in humans. We had shown earlier that recombinant human resistin has a tendency to form aggregates by formation of inter/intramolecular disulfide linkages and that it undergoes a concentration-dependent conformational change in secondary structure from alpha-helical to beta-sheet form. Here we report that this change in secondary structural conformation is due to the increase in the oligomeric form of human resistin as a function of protein concentration. Gel filtration analysis under different conditions further demonstrated that recombinant human resistin exists as a mixture of oligomer and trimer but is converted to a mixture of monomer and oligomer in the presence of 100 mM NaCl. We show that while the trimeric form of human resistin is stable to urea-induced denaturation, it is highly susceptible to NaCl and NaF, indicating the importance of ionic interactions in stabilization of trimer. In addition, urea was able to destabilize the oligomers indicating the involvement of hydrophobic interactions in oligomerization. Ionic as well as hydrophobic interactions stabilize the monomeric human resistin. Our data suggest that human resistin exists predominantly as oligomer and trimer in vitro. The oligomeric form of human resistin shows more potent effect on stimulation of proinflammatory cytokines. Therefore, it is very tempting to propose that the structural conformation of resistin may be involved in maintaining the very fine balance in regulation of macrophage function for successful response to a variety of pathological conditions.