Targeting KSHV processivity to prevent oral KS in AIDS
Ricciardi, Robert Paul   
University of Pennsylvania, Philadelphia, PA, United States

Oral Kaposi's sarcoma is the classic malignancy associated with AIDS and is caused by the opportunistic virus, Kaposi's sarcoma herpesvirus. The recently discovered processivity factor (PF-8) of KSHV is an exciting new therapeutic target for eliminating oral KS. PF-8 binds and tethers KSHV DNA polymerase (Pol-8) on the DNA. In so doing, PF-8 enables Pol-8 to be processive, i.e., to incorporate thousands of nucleotides continuously without dissociating from the template. By contrast, Pol-8 alone incorporates only three nucleotides. The inability of a KSHV PF-8 deletion mutant virus to replicate confirms that PF-8 is essential for viral propagation. Important features of PF-8 that define precise targets for therapeutic intervention include two domains that are required to form PF-8 homo-dimers and a discrete Pol-8 binding domain. In addition to stabilizing Pol-8 on the DNA, PF-8 has been shown to be necessary for transporting Pol-8 into the nucleus via a nuclear localization signal. Significantly, the attractiveness of targeting PF-8 is its specificity for Pol-8 and no other viral or cellular proteins. The goal of this study is to focus on discovering PF-8 therapeutic compounds by using several complementary approaches. The first approach will be to validate compounds we have already identified from a small primary screen of the NCI combinatorial library that inhibited PF-8/Pol-8 processive DNA synthesis using our newly invented Rapid Plate Assay. We will identify additional compounds by high throughput screening of the NCI library. The second approach will be to employ a refined assay to screen for inhibitors that prevent formation of PF-8 homo-dimers, which are essential for processivity function. Our third approach will be to employ peptides to target PF-8 protein-interaction domains. These peptides, one of which has already been shown to block processivity by probably inhibiting PF-8 homo-dimerization, will be used to design therapeutic peptidomimetics. All of the inhibitors will be examined in cell-based assays for their abilities to block KSHV lytic infection as well as to eliminate latent KS-like spindle cells. Since KSHV lytic infection is apparently crucial in sustaining KS tumors, therapeutics that specifically block PF-8-dependent processive DNA synthesis are predicted to eliminate oral KS tumors directly with minimal secondary effects.