Discovery of HIV-1 integrase inhibitors through a novel combination of ligand and structure-based drug design

Over the past 10 years, classical computer-aided molecular design methods have not been frequently applied for the discovery of novel HIV-1 integrase (IN) inhibitors, due to the intrinsic challenges that this enzyme presents. Therefore, a novel approach that combines the chemical information of known integrase inhibitors with the enzyme's detailed 3D structure in a stepwise fashion is proposed: (I) use of a pharmacophore model (PM), which takes into account in a weighted fashion the chemical features of known ligands, in analogous manner to the to search the Maybridge and the NCI 3D databases; (II) drug-likeness optimization; (III) virtual high-throughput screening of the hits matching the PM query against 1QS4 wild-type IN structure using different Docking/Scoring combinations; (IV) visual inspection and selection of the hits in function of: binding free energies; binding mode type within the active site; retrieval among the best 20% hits in more than 6 Docking/Scoring protocols at the same time. This approach aims at a rational selection of new potential HIV-1 integrase inhibitors.     

五种药用石斛内生真菌抑制HIV-1整合酶活性研究

目的 评价5种药用石斛内生真菌发酵产物抑制HIV-1整合酶的活性.方法 将分离自石斛的202株内生真菌提取物共404个采用高通量ELISA法评价其抑制HIV-l整合酶活性;对抑制活性大于100％的样品进行量效关系考察并进行体外抑制肿瘤细胞活性筛选.结果 筛选得到19个对HIV-l整合酶抑制活性大于80％的样品,其中样品5119F、5297F、5097F、5140J和5211F的抑制率分别达到117.96％、113.53％、108.62％、103.74％和109.02％,其对应的IC50值分别为0.02024、0.003125、0.00862、0.01007 和 0.01192 mg/ml.结论石斛属药用植物内生真菌是一个潜在的、丰富的用于筛选HIV-1整合酶抑制剂的资源库,值得进一步研究和开发.     

Computer-aided design, synthesis, and biological activity evaluation of potent fusion inhibitors targeting HIV-1 gp41

This discovered and optimized several novel HIV-1 fusion inhibitors and further evaluated the inhibitory activities of these compounds in vitro. Here, we have reported the computer-aided design, synthesis, and biological evaluation of a series of small molecule fusion inhibitors targeting HIV-1 gp41. Based on the structure of inhibitor (NB2), we carried out de novo design and screened out a series of novel structure molecules by using Leapfrog and Autodock programs. Our structure-based modification obtained a potent fusion inhibitor (IC?? = 41.1 μg/mL). Several novel compounds were discovered as fusion inhibitors, which suggested that our design methodology is reliable, paving the way for de novo design of novel small-molecule HIV inhibitors targeting gp41.     

Examining structural analogs of elvitegravir as potential inhibitors of HIV-1 integrase

Acquired immunodeficiency syndrome (AIDS) is a major health problem in many parts of the world. The human immunodeficiency virus-1 integrase (HIV-1 IN) enzyme has been targeted in HIV patients for therapy. Several integrase inhibitors have been reported, but only elvitegravir (EVG), a new-generation drug, is clinically approved for HIV treatment. In the present work, we investigated two structural analogs of EVG as potential inhibitors of the target molecule, HIV-1 IN. The ligand binding site on HIV-1 IN was identified using Q-SiteFinder, and the HIV-1 IN protein was docked with ligand (EVG and/or analogs) using AutoDock 4. The results suggest that Lys173, Thr125, and His171 are involved in enzyme-substrate binding through hydrogen bonds. Single mutations carried out at Lys173, viz. Lys173Leu (polar > nonpolar) and Lys173Gln (polar > polar), in chain B using PyMOL showed the mutants to have lower binding energy when docked with analog 2, suggesting it to be more stable than analog 1. In conclusion, the mutant HIV-1 IN can bind EVG and its analogs. The physicochemical and pharmacokinetic parameters also show analog 2 to be a promising molecule that can be developed as an alternative to EVG to help overcome the problem of drug resistance by HIV to this inhibitor. Analog 2 may be used as an HIV-1 IN inhibitor with similar potential to that of EVG. Further validation through wet-lab studies, however, is required for future applications.     

A high-throughput assay for HIV-1 integrase 3'-processing activity using time-resolved fluorescence

HIV-1 integrase (HIV-1 IN), a well-validated antiviral drug target, catalyzes multistep reactions to incorporate viral DNA into the genome of the host cell; these include both a 3'-processing (3'P) reaction and a strand transfer reaction. These enzymatic activities can be measured in vitro with short DNA oligonucleotides that mimic a single viral LTR DNA end and purified IN. A highly sensitive and reproducible time-resolved fluorescence (TRF)-based assay for HIV-1 IN 3'P activity is now reported. This assay was optimized with respect to time and concentrations of metal ions, substrate and enzyme. The assay has now been used successfully to measure HIV-1 IN 3'P activity and has been shown to detect the anti-IN activity of several known 3'P inhibition compounds accurately. This assay, which is amenable to high-throughput screening, will be useful for identification of additional HIV-1 IN 3'P inhibitors.     

Resilience to resistance of HIV-1 protease inhibitors: profile of darunavir

The current effectiveness of HAART in the management of HIV infection is compromised by the emergence of extensively cross-resistant strains of HIV-1, requiring a significant need for new therapeutic agents. Due to its crucial role in viral maturation and therefore HIV-1 replication and infectivity, the HIV-1 protease continues to be a major development target for antiretroviral therapy. However, new protease inhibitors must have higher thresholds to the development of resistance and cross-resistance. Research has demonstrated that the binding characteristics between a protease inhibitor and the active site of the HIV-1 protease are key factors in the development of resistance. More specifically, the way in which a protease inhibitor fits within the substrate consensus volume, or "substrate envelope", appears to be critical. The currently available inhibitors are not only smaller than the native substrates, but also have a different shape. This difference in shape underlies observed patterns of resistance because primary drug-resistant mutations often arise at positions in the protease where the inhibitors protrude beyond the substrate envelope but are still in contact with the enzyme. Since all currently available protease inhibitors occupy a similar space (in spite of their structural differences) in the active site of the enzyme, the specific positions where the inhibitors protrude and contact the enzyme correspond to the locations where most mutations occur that give rise to multidrug-resistant HIV-1 strains. Detailed investigation of the structure, thermodynamics, and dynamics of the active site of the protease enzyme is enabling the identification of new protease inhibitors that more closely fit within the substrate envelope and therefore decrease the risk of drug resistance developing. The features of darunavir, the latest FDA-approved protease inhibitor, include its high binding affinity (Kd = 4.5 x 10-12 M) for the protease active site, the presence of hydrogen bonds with the backbone, and its ability to fit closely within the substrate envelope (or consensus volume). Darunavir is potent against both wild-type and protease inhibitor-resistant viruses in vitro, including a broad range of over 4,000 clinical isolates. Additionally, in vitro selection studies with wild-type HIV-1 strains have shown that resistance to darunavir develops much more slowly and is more difficult to generate than for existing protease inhibitors. Clinical studies have shown that darunavir administered with low-dose ritonavir (darunavir/ritonavir) provides highly potent viral suppression (including significant decreases in HIV viral load in patients with documented protease inhibitor resistance) together with favorable tolerability. In conclusion, as a result of its high binding affinity for and overall fit within the active site of HIV-1 protease, darunavir has a higher genetic barrier to the development of resistance and better clinical efficacy against multidrug-resistant HIV relative to current protease inhibitors. The observed efficacy, safety and tolerability of darunavir in highly treatment-experienced patients makes darunavir an important new therapeutic option for HIV-infected patients.     

Mutagenesis of the dimer interface residues of tethered and untethered HIV-1 protease result in differential activity and suggest multiple mechanisms of compensation

As is the case for all retroviruses, the protease of HIV-1 is only functional as a homodimer; dimerization of two protease monomers results in the formation of the enzyme active site. This dimer structure is supported primarily by interactions between the first four amino-terminal and the last four carboxy-terminal amino acids. These eight amino acids form a beta-sheet in which hydrophobic residues are oriented towards the core of the molecule and polar residues are directed towards the solvent. Although the structure of the dimer interface has been determined, the forces that support dimerization have not been fully characterized. Here, we describe a tethered construct in which two protease monomers are joined by a 5 amino acid linker. We evaluate the relative role of each dimer interface residue in functional homo- and heterodimers. Our studies indicate that the hydrophobic residues of the dimer interface are particularly important in maintaining enzyme activity and that enzyme activity is more sensitive to substitutions of the C-terminal amino acids. Further, we demonstrate that the presence of the tether is able to compensate for mutations within the dimer interface that inactivate the enzyme.     

HIV-1整合酶酶联免疫吸附试验及其抑制剂的研究

目的　建立一种检测人类免疫缺陷病毒 1型 (HIV - 1 )整合酶的酶联免疫吸附试验(ELISA)方法 ,用于筛选和研究HIV - 1整合酶抑制剂。方法　将质粒F1 85K C2 80SIN1 2 88转化到大肠埃希菌中 ,经IPTG诱导表达 ,柱亲和层析纯化 ,获得HIV 1整合酶融合蛋白。建立酶联免疫吸附试验方法测定其生物学活性 ,与3 2 P同位素标记方法比较 ,并用ELISA方法筛选HIV 1整合酶的抑制剂。结果　SDS PAGE电泳分析显示 ,相对分子质量 30 0 0 0上方有HIV 1整合酶融合蛋白条带出现。ELISA及3 2 P同位素标记法证实 ,此融合蛋白对于特异底物具有 3′切割和链转移活性。ELISA反应的平均P N值为 2 836± 0 1 61 ,批内及批间变异系数 (CV)分别为 4 63 %和 5 89%。检测到中药丹参提取物CEH等有抑制整合酶的活性 ,CEH的大孔树脂洗脱物CEHL活性提高。结论　ELISA法检测HIV 1整合酶活性技术简单 ,快速 ,重复性好 ,无同位素污染 ,可用于HIV 1整合酶为靶点的抑制剂的筛选及抗 HIV药物作用机理的研究。     

Structural biology of retroviral DNA integration

Three-dimensional macromolecular structures shed critical light on biological mechanism and facilitate development of small molecule inhibitors. Clinical success of raltegravir, a potent inhibitor of HIV-1 integrase, demonstrated the utility of this viral DNA recombinase as an antiviral target. A variety of partial integrase structures reported in the past 16 years have been instrumental and very informative to the field. Nonetheless, because integrase protein fragments are unable to functionally engage the viral DNA substrate critical for strand transfer inhibitor binding, the early structures did little to materially impact drug development efforts. However, recent results based on prototype foamy virus integrase have fully reversed this trend, as a number of X-ray crystal structures of active integrase-DNA complexes revealed key mechanistic details and moreover established the foundation of HIV-1 integrase strand transfer inhibitor action. In this review we discuss the landmarks in the progress of integrase structural biology during the past 17 years.     

Four-tiered pi interaction at the dimeric interface of HIV-1 integrase critical for DNA integration and viral infectivity

HIV-1 integrase (IN) is an essential enzyme for viral infection. Here, we report an extensive pi electron orbital interaction between four amino acids, W132, M178, F181 and F185, located at the dimeric interface of IN that is critical for the strand transfer activity alone. Catalysis of nine different mutant IN proteins at these positions were evaluated. Whereas the 3'-processing activity is predominantly strong, the strand transfer activity of each enzyme was completely dependent on an intact pi electron orbital interaction at the dimeric interface. Four representative IN mutants were constructed in the context of the infectious NL4.3 HIV-1 viral clone. Whereas viruses with an intact pi electron orbital interaction at the IN dimeric interface replicated comparable to wild type, viruses containing an abolished pi interaction were non-infectious. Q-PCR analysis of viral DNA forms during viral replication revealed pleiotropic effects of most mutations. We hypothesize that the pi interaction is a critical contact point for the assembly of functional IN multimeric complexes, and that IN multimerization is required for a functional pre-integration complex. The rational design of small molecule inhibitors targeting the disruption of this pi-pi interaction should lead to powerful anti-retroviral drugs.     

Expression of functional HIV-1 integrase in the yeastSaccharomyces cerevisiae leads to the emergence of a lethal phenotype: potential use for inhibitor screening

The integrase of the human immunodeficiency virus type 1 (HIV-1) has been expressed in yeast in order to investigate its potential lethal effect mediated by DNA damage. To this end, we have constructed an expression plasmid containing the retroviral integrase gene under the control of the inducible promotor ADH2/GAPDH which is regulated by the glucose concentration of the medium. Haploid yeast strain W303-1A did not appear to be clearly sensitive to HIV-1 integrase expression. However, disruption of theRAD 52 gene, which is involved in the repair of double-strand DNA breaks, strongly increased the deleterious effects of the retroviral enzyme in this yeast strain. The diploid strain constructed with W303-1A and an isogenic strain of the opposite mating type also showed a strong sensitivity to the HIV-1 integrase. Under yeast culture conditions allowing moderate integrase synthesis, the deleterious effect was totally abolished by missense integrase mutations, which are known to abolish HIV-1 integrase activities in vitro. We conclude that the lethal phenotype due to HIV-1 integrase expression in yeast may be closely related to the HIV-1 integration reaction in infected human cells, and that yeast may be a useful tool to study the HIV-1 integration process and to screen drugs capable of inhibiting HIV-1 integration in vivo.