HEPT类HIV-1逆转录酶抑制剂的研究进展

逆转录酶是设计抗艾滋病药物研究的选择性靶酶,从作用机制、构效关系等方面综述HEPT及其类似物作为HIV-1逆转录酶抑制剂的研究进展.     

Small-molecule HIV-1 gp120 inhibitors to prevent HIV-1 entry: an emerging opportunity for drug development

The HIV-1 gp120 envelope protein is an essential component in the multi-tiered viral entry process. Despite the overall genetic heterogeneity of the gp120 glycoprotein, the conserved CD4 binding site provides an attractive antiviral target. Recently, increased efforts aimed at the development of inhibitors of gp120 have been reported. This review focuses primarily on small-molecule gp120 inhibitors and discusses key characteristics of compounds that appear to fall within this class. The preclinical profiles of compounds that prevent gp120 from assuming a conformation favorable for CD4 binding are described in this review. In addition, inhibitors possessing some common structural features, including at least one compound that exhibits sub-nanomolar potency in a cell fusion assay are discussed. A series of compounds that were designed to enhance immune responses to virus via alteration of the gp120 conformation after targeting the CD4 binding pocket are also described. The efficacy of gp120 inhibitors as a microbicide to prevent sexual HIV transmission in the rhesus macaque model is discussed. Results suggest that this class of compounds may have value if included in a microbicide cocktail with inhibitors of alternate mechanisms. Importantly, preliminary results from clinical studies of orally administered BMS-488043 demonstrate that antiviral efficacy can be achieved in humans with a CD4-attachment inhibitor that targets gp120.     

A novel HIV-1 antiviral high throughput screening approach for the discovery of HIV-1 inhibitors

Antiviral high throughput screens remain a viable option for identifying novel target inhibitors. However, few antiviral screens have been reduced to practice on an industrial scale. In this study, we describe an HIV-1 dual reporter assay that allows for the simultaneous evaluation of the potential antiviral activities and cytotoxicities of compounds in a high throughput screen (HTS) format. We validate the assay with known HIV-1 inhibitors and show that the antiviral and cytotoxic activities of compounds are reproducibly measured under screening conditions. In addition, we show that the assay exhibits parameters (e.g., signal-to-background ratios and Z' coefficients) suitable for high throughout screening. In a pilot screen, we demonstrate that non-specific or cytotoxic compounds represent a significant fraction of the hits identified in an antiviral screen and that these false positives are identified and deprioritized by the HIV-1 dual reporter assay at the primary screening step. We propose that the HIV-1 dual reporter assay represents a novel approach to HIV-1 antiviral screening that allows for the effective execution of industrial scale HTS campaigns with significantly greater returns on resource investment when compared to previous methods.     

Computational strategies in discovering novel non-nucleoside inhibitors of HIV-1 RT

A three-dimensional common feature pharmacophore model was developed using the X-ray structure of RT/non-nucleoside inhibitor (NNRTI) complexes. Starting from the pharmacophore hypothesis and the structure of the lead compound TBZ, new NNRTIs were designed and synthesized, having the benzimidazol-2-one system as a scaffold. Docking experiments showed that these molecules docked in a position and orientation similar to that of known inhibitors. Biological testing confirmed that our strategy was successful in searching for new leads as NNRTIs.     

HIV-1 protease inhibitors in development

Several pharmaceutical companies have developed an increasing number of second generation protease inhibitors (PI) during the last few years. Many of these compounds have been in preclinical trials and some are now in clinical use. All drugs in this category have been designed to be well absorbed and overcome the crucial problem of cross-resistance within this class of compounds. Taking into account the rapid occurrence of PI cross-resistance, clinicians who are treating patients with the HIV-1 infection will need new active PIs in the near future. The clinical and antiviral efficacy of the new molecules versus the older PIs will be investigated through comparative trials that are likely to be completed over the next 12 months. These third-generation PIs currently in development will be the subject of our review.     

HIV-1 protease inhibitors in development

Several pharmaceutical companies have developed an increasing number of second generation protease inhibitors (PI) during the last few years. Many of these compounds have been in preclinical trials and some are now in clinical use. All drugs in this category have been designed to be well absorbed and overcome the crucial problem of cross-resistance within this class of compounds. Taking into account the rapid occurrence of PI cross-resistance, clinicians who are treating patients with the HIV-1 infection will need new active PIs in the near future. The clinical and antiviral efficacy of the new molecules versus the older PIs will be investigated through comparative trials that are likely to be completed over the next 12 months. These third-generation PIs currently in development will be the subject of our review.     

Relationships between structure and interaction kinetics for HIV-1 protease inhibitors

The interaction between HIV-1 protease and 58 structurally diverse transition-state analogue inhibitors has been analyzed by a surface plasmon resonance based biosensor. Association and dissociation rate constants and affinities were determined and displayed as k(on)-k(off)-K(D) maps. It was shown that different classes of inhibitors fall into distinct clusters in these maps. Significant changes in association and dissociation rates were found as a result of modifying the P1/P1' or P2/P2' side chains of a linear lead compound. Similarly, cyclic urea and cyclic sulfamide inhibitors displayed different kinetic features and the affinities of both classes of cyclic compounds were limited by fast dissociation rates. These results confirm that association and dissociation rates are important features of drug-target interactions and indicate that optimization of inhibitor efficacy may be guided by aiming for high association and low dissociation rates rather than high affinity alone. The present approach thus provides a new tool for structure-interaction kinetic analysis and drug discovery.     

HIV-1 regulatory proteins: targets for novel drug development

Due to the development of HIV-1 resistance to current antiviral drugs and the known toxicity of many of these drugs, there is a clear need to identify and develop novel compounds for use in the treatment of HIV-1 infected patients. The HIV-1 regulatory proteins, Tat and Rev, are required for HIV-1 replication and therefore represent two important viral targets for drug development. Novel drugs that target these proteins would increase the number of available treatment strategies for HIV-1 infection. This could result in better combination therapies in which many different viral targets could be inhibited simultaneously, thereby decreasing the likelihood of selecting for drug-resistant viruses. This review outlines many of the ways that Tat and Rev can be targeted for drug development, describes recently reported lead compounds as inhibitors of these proteins and discusses strategies for implementing drug screens for identifying novel inhibitors.     

HIV-1 regulatory proteins: targets for novel drug development

Due to the development of HIV-1 resistance to current antiviral drugs and the known toxicity of many of these drugs, there is a clear need to identify and develop novel compounds for use in the treatment of HIV-1 infected patients. The HIV-1 regulatory proteins, Tat and Rev, are required for HIV-1 replication and therefore represent two important viral targets for drug development. Novel drugs that target these proteins would increase the number of available treatment strategies for HIV-1 infection. This could result in better combination therapies in which many different viral targets could be inhibited simultaneously, thereby decreasing the likelihood of selecting for drug-resistant viruses. This review outlines many of the ways that Tat and Rev can be targeted for drug development, describes recently reported lead compounds as inhibitors of these proteins and discusses strategies for implementing drug screens for identifying novel inhibitors.     

Surrogacy in antiviral drug development

The coming of age of molecular biology has resulted in an explosion in our understanding of the pathogenesis of virus related diseases. New pathogens have been identified and characterized as being responsible for old diseases. Empirical clinical evaluation of morbidity and mortality as outcome measures after a therapeutic intervention have started to give way to the use of an increasing number of surrogate markers. Using a combination of these markers, it is now possible to measure and monitor the pathogen as well as the host's response. Nowhere is this better exemplified in virology than in the field of AIDS. We have utilized the advances in pathogenesis and new antiretroviral drug development to: * develop a new class of drugs which block the entry of HIV-1 into cells. * develop a new approach for effectively delivering these drugs to those tissues in which most viral replication takes place. Over the last 10 years, our work has progressed from concept to clinical trial. Our laboratory based evaluation of the new molecules developed as well as our clinical evaluation of their safety and efficacy have had to respond and adapt to the rapid changes taking place in AIDS research. This paper discusses the problems encountered and the lessons learnt.