Unlike processive cellular motors such as myosin V, whose structure has recently been determined in a "rigor-like" conformation, myosin II from contracting muscle filaments necessarily spends most of its time detached from actin. By using squid and sea scallop sources, however, we have now obtained similar rigor-like atomic structures for muscle myosin heads (S1). The significance of the hallmark closed actin-binding cleft in these crystal structures is supported here by actin/S1-binding studies. These structures reveal how different duty ratios, and hence cellular functions, of the myosin isoforms may be accounted for, in part, on the basis of detailed differences in interdomain contacts. Moreover, the rigor-like position of switch II turns out to be unique for myosin V. The overall arrangements of subdomains in the motor are relatively conserved in each of the known contractile states, and we explore qualitatively the energetics of these states.
Protease inhibitor resistance still poses one of the greatest challenges in treating HIV. To better design inhibitors able to target resistant proteases, a deeper understanding is needed of the effects of accumulating mutations and the contributions of active-and nonactive-site mutations to the resistance. We have engineered a series of variants containing the nonactive-site mutations M46I and I54V and the active-site mutation I84V. These mutations were added to a protease clone (V6) isolated from a pediatric patient on ritonavir therapy. This variant possessed the ritonavir-resistance-associated mutations in the active-site (V32I and V82A) and nonactive-site mutations (K20R, L33F, M36I, L63P, A71V, and L90M). The I84V mutation had the greatest effect on decreasing catalytic efficiency, 10-fold when compared to the pretherapy clone LAI. The decrease in catalytic efficiency was partially recovered by the addition of mutations M46I and I54V. The M46I and I54V were just as effective at decreasing inhibitor binding as the I84V mutation when compared to V6 and LAI. The V6 54/84 variant showed over 1000-fold decrease in inhibitor-binding strength to ritonavir, indinavir, and nelfinavir when compared to LAI and V6. Crystalstructure analysis of the V6 54/84 variant bound to ritonavir and indinavir shows structural changes in the 80's loops and active site, which lead to an enlarged binding cavity when compared to pretherapy structures in the Protein Data Bank. Structural changes are also seen in the 10's and 30's loops, which suggest possible changes in the dynamics of flap opening and closing.The development of resistance to protease inhibitors (PI) 1 during treatment of infection by the Human Immunodeficiency Virus (HIV) still poses one of the greatest challenges in the struggle to limit the virus replicative capacity. After initiation of therapy with single or multiple protease inhibitors, resistance mutations in the protease can appear within weeks. Under a constant drug selection pressure, resistant mutations continue to accumulate. It is clear that there is a correlation between the number of resistance mutations and the level of resistance and cross resistance to multiple protease inhibitors. It is of great interest to understand the level of contributions made by active-and nonactive-site mutations to the development of a high level of resistance (1-6). The HIV protease is a symmetric dimer composed of two 99-residue polypeptides (Figure 1). The dimerization region comprises the floor of the active site, which includes two catalytic aspartic acids (Asp25), one provided by each polypeptide. Unlike the human aspartic proteases that have one flap, two flaps completely cap the active site of the HIV protease. A more detailed description of HIV-1 protease structure, inhibitor binding, and resistance can be found in reviews by Wlodawer and Gustchina, Tomasselli and Heinrikson,.In this study, we analyze the effect of adding the nonactive-site mutations M46I and I54V and the active-site mutation I84V to a post...
Previous studies have shown a statistically significant correlation between human carcinomas and monoclonal antibody detection of a Mycoplasma hyorhinis -encoded protein known as p37. A potential mechanism of p37 is that it might promote invasion and metastasis. Recombinant p37 enhanced the invasiveness of two prostate carcinoma and two melanoma cell lines in a dosedependent manner in vitro, but did not have a significant effect on tumor cell growth. Furthermore, the increased binding to cell surfaces and the enhanced invasive potential of cancer cells from exposure to p37 could be completely reversed by preincubation of the cancer cells with an anti-p37 monoclonal antibody. Sequence comparisons, followed by three-dimensional molecular modeling, revealed a region of similarity between p37 and influenza hemagglutinin A, a sialic acid -binding protein that plays a critical role in viral entry. Binding of p37 to prostate carcinoma cells was found to be at least partially sialic acid dependent because neuraminidase treatment decreased this binding. Taken together, these observations suggest that M. hyorhinis can infect humans and may facilitate tumor invasiveness via p37. These results further suggest that p37 may be a molecular target for cancer therapy. [Mol Cancer Ther 2005;4(7):1031 -8]
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