A novel approach to develop anti-HIV drugs: adapting non-nucleoside anticancer chemotherapeutics

Some anticancer drugs, but not all, inhibit replication of human immunodeficiency virus (HIV) and thus, exhibit a therapeutic potential. Such drugs, unlike the traditional HIV enzyme inhibitors, could suppress HIV strains that are resistant to inhibitors of viral enzymes, decrease proviral burden in vivo, or reduce reservoirs of infection via killing infected cells. Thus, they may be an effective adjunct therapy or perhaps result in a cure. The incidence of HIV infection and AIDS mortalities continue to increase worldwide, including the United States and parts of Africa, with a parallel increase in a number of other manifestations, including AIDS defining malignancies. The basis for continual spread of HIV presumably in large part stems from the viral resistance to previously successful drugs and the lack of curative antiretroviral drugs. To reverse these trends, other approaches for AIDS therapy must be developed. One possibility is the development of potent anticancer drugs, that exhibit anti-HIV activities. At least four chemically and pharmacologically distinct classes of anticancer drugs, i.e. certain cyclin-dependent kinase inhibitors (CDKIs), topoisomerase 1 enzyme (top 1) inhibitors, non-nucleoside antimetabolites, and estrogen receptor ligands are promising candidates. These drugs, at high doses are used for cancer therapy; at lower concentrations they exhibit anti-HIV activities in cultured cells. While the antiretroviral and the anticancer activities of the cdk inhibitor flavopiridol appear to be mutually exclusive and unrelated in cells and animal model(s) of HIV disease, the top 1 inhibitor 9-nitrocamptothecin, as well as the cdk-inhibitor roscovitine inhibit replication of HIV via selective sensitization of HIV-infected cells to apoptosis. In contrast, the inhibitory effects of these compounds are different from other cancer therapeutics that, at toxic concentrations, activate HIV either in cultured cells (such as certain ingenol and butyrate derivatives) and/or in patients (such as the widely used cyclophosmamide and cisplatin). This quality may lead to the eradication of proviral reservoirs, which is not accomplished by the currently available antiretroviral drugs. In this review, relevant available clinical and in vitro data that either support or discourage using certain anticancer drugs for treatment of HIV disease, and the rationales for developing novel antiretroviral drugs that may target infected cells rather than viral proteins are discussed.     

5-(1-Substituted) alkyl pyrimidine nucleosides as antiviral (herpes) agents

The treatment of viral diseases remains one of the major challenges to modern medicine. During the past two decades there has been increased recognition of the consequences of serious viral illnesses that are not controlled by vaccination. These illnesses include human immunodeficiency virus, human herpes viruses, and viruses that cause hepatitis. There are now eight pathogens recognized in the herpes virus family that cause infections in humans. Infections by the herpes viruses are opportunistic and often life-threatening, leading to significant morbidity and mortality in the increasing number of chronically immune compromised individuals such as AIDS patients, cancer patients and transplant recipients on immunosuppressive therapy. Nearly all individuals with AIDS are infected with one or more of the herpes viruses. Antiviral therapy with guanosine nucleoside analogs acyclovir and ganciclovir has had a major impact on diseases caused by herpes simplex virus type-1 and type-2 (HSV-1, HSV-2), Varicella zoster virus (VZV), and human cytomegalovirus (HCMV) but development of resistant virus strains and the absence of any effective treatment for other members of the herpes family provide a stimulus for increased search of new agents effective against various herpes viruses. Pyrimidine nucleosides have taken up an important role in the therapy of virus infection. Significant progress in the study of anti-herpes nucleosides has been made by the advent of 5-substituted pyrimidine nucleosides such as 5-iodo-, 5-ethyl-, 5-(2-chloroethyl)-, and (E)-5-(2-bromovinyl)- derivatives of 2'-deoxyuridine. These are highly specific inhibitors of HSV-1, HSV-2, and/or VZV infections. However, Epstein Barr virus (EBV) and HCMV are much less sensitive to these agents. In 5-substituted pyrimidine nucleosides the nature of substituents, particularly at the C-5 position, has been found to be an important determinant of anti-herpes activity. Structural requirements at the C-2 carbon of the 5-substituent of pyrimidine nucleosides have been well established for anti-herpes activity. However, there is little qualitative or mechanistic knowledge of the derivatives with substitution at the C-1 carbon of the 5-substituent of pyrimidine nucleosides. During the last few years of our research, we have investigated a variety of C-1 functionalized substituents at the 5-position of the pyrimidine nucleosides to determine their usefulness as antiviral (herpes) agents. In the 5-(1-substituted) group of pyrimidine nucleosides, we demonstrated that novel substituents present at the C-1 carbon of the 5-side chain of the pyrimidine nucleosides are important determinants of potent and broad spectrum antiviral (herpes) activity including EBV and HCMV. In this article the work on design, synthesis and structure activity relationships of several 5-[(1-substituted) alkyl (or vinyl)] pyrimidine nucleoside derivatives as potential inhibitors of herpes viruses is reviewed.