HIV-1整合酶链转移反应抑制剂的荧光筛选方法

整合酶被认为是抗HIV-1药物研究的理想靶点之一。为了建立便捷高效的整合酶链转移反应抑制剂筛选方法,首先将HIV-1整合酶原核表达载体pNL-IN转化入大肠杆菌感受态细胞BL21(DE3)进行原核表达,并用镍琼脂糖凝胶进行亲和纯化,获得了纯度和活性均较高的整合酶重组蛋白;然后设计了生物素标记的供体DNA和FITC标记的靶DNA,用链霉亲和素磁珠捕获反应体系中的DNA产物;最后用荧光分析仪检测DNA产物的荧光信号,并计算待测样品的抑制率。用已知整合酶抑制剂S-1360和MK-0518对筛选方法进行了验证,测定结果与已有实验数据相当,表明本筛选方法能够有效应用于HIV-1整合酶链转移反应抑制剂的筛选。与现有的整合酶链转移反应抑制剂筛选方法相比,本筛选方法步骤更为简化、耗时更短、成本更低。     

Retroviral Integrase Proteins and HIV-1 DNA Integration

Retroviral integrases catalyze two reactions, 3′-processing of viral DNA ends, followed by integration of the processed ends into chromosomal DNA. X-ray crystal structures of integrase-DNA complexes from prototype foamy virus, a member of the Spumavirus genus of Retroviridae, have revealed the structural basis of integration and how clinically relevant integrase strand transfer inhibitors work. Underscoring the translational potential of targeting virus-host interactions, small molecules that bind at the host factor lens epithelium-derived growth factor/p75-binding site on HIV-1 integrase promote dimerization and inhibit integrase-viral DNA assembly and catalysis. Here, we review recent advances in our knowledge of HIV-1 DNA integration, as well as future research directions.     

Substrate features important for recognition and catalysis by human immunodeficiency virus type 1 integrase identified by using novel DNA substrates.

The integrase encoded by human immunodeficiency virus type 1 (HIV-1) is required for integration of viral DNA into the host cell chromosome. In vitro, integrase mediates a concerted cleavage-ligation reaction (strand transfer) that results in covalent attachment of viral DNA to target DNA. With a substrate that mimics the strand transfer product, integrase carries out disintegration, the reverse of the strand transfer reaction, resolving this integration intermediate into its viral and target DNA parts. We used a set of disintegration substrates to study the catalytic mechanism of HIV-1 integrase and the interaction between the protein and the viral and target DNA sequence. One substrate termed dumbbell consists of a single oligonucleotide that can fold to form a structure that mimics the integration intermediate. Kinetic analysis using the dumbbell substrate showed that integrase turned over, establishing that HIV-1 integrase is an enzyme. Analysis of the disintegration activity on the dumbbell substrate and its derivatives showed that both the viral and target DNA parts of the molecule were required for integrase recognition. Integrase recognized target DNA asymmetrically: the target DNA upstream of the viral DNA joining site played a much more important role than the downstream target DNA in protein-DNA interaction. The site of transesterification was determined by both the DNA sequence of the viral DNA end and the structure of the branched substrate. Using a series of disintegration substrates with various base modifications, we found that integrase had relaxed structural specificity for the hydroxyl group used in transesterification and could tolerate distortion of the double-helical structure of these DNA substrates.     

Inhibition of human immunodeficiency virus type 1 concerted integration by strand transfer inhibitors which recognize a transient structural intermediate

Human immunodeficiency virus type 1 (HIV-1) integrase (IN) inserts the viral DNA genome into host chromosomes. Here, by native agarose gel electrophoresis, using recombinant IN with a blunt-ended viral DNA substrate, we identified the synaptic complex (SC), a transient early intermediate in the integration pathway. The SC consists of two donor ends juxtaposed by IN noncovalently. The DNA ends within the SC were minimally processed (~15%). In a time-dependent manner, the SC associated with target DNA and progressed to the strand transfer complex (STC), the nucleoprotein product of concerted integration. In the STC, the two viral DNA ends are covalently attached to target and remain associated with IN. The diketo acid inhibitors and their analogs effectively inhibit HIV-1 replication by preventing integration in vivo. Strand transfer inhibitors L-870,810, L-870,812, and L-841,411, at low nM concentrations, effectively inhibited the concerted integration of viral DNA donor in vitro. The inhibitors, in a concentration-dependent manner, bound to IN within the SC and thereby blocked the docking onto target DNA, which thus prevented the formation of the STC. Although 3'-OH recessed donor efficiently formed the STC, reactions proceeding with this substrate exhibited marked resistance to the presence of inhibitor, requiring significantly higher concentrations for effective inhibition of all strand transfer products. These results suggest that binding of inhibitor to the SC occurs prior to, during, or immediately after 3'-OH processing. It follows that the IN-viral DNA complex is "trapped" by the strand transfer inhibitors via a transient intermediate within the cytoplasmic preintegration complex.     

New class of HIV-1 integrase (IN) inhibitors with a dual mode of action

tert-Butoxy-(4-phenyl-quinolin-3-yl)-acetic acids (tBPQA) are a new class of HIV-1 integrase (IN) inhibitors that are structurally distinct from IN strand transfer inhibitors but analogous to LEDGINs. LEDGINs are a class of potent antiviral compounds that interacts with the lens epithelium-derived growth factor (LEDGF) binding pocket on IN and were identified through competition binding against LEDGF. LEDGF tethers IN to the host chromatin and enables targeted integration of viral DNA. The prevailing understanding of the antiviral mechanism of LEDGINs is that they inhibit LEDGF binding to IN, which prevents targeted integration of HIV-1. We showed that in addition to the properties already known for LEDGINs, the binding of tBPQAs to the IN dimer interface inhibits IN enzymatic activity in a LEDGF-independent manner. Using the analysis of two long terminal repeat junctions in HIV-infected cells, we showed that the inhibition by tBPQAs occurs at or prior to the viral DNA 3'-processing step. Biochemical studies revealed that this inhibition operates by compound-induced conformational changes in the IN dimer that prevent proper assembly of IN onto viral DNA. For the first time, tBPQAs were demonstrated to be allosteric inhibitors of HIV-1 IN displaying a dual mode of action: inhibition of IN-viral DNA assembly and inhibition of IN-LEDGF interaction.     

The role of manganese in promoting multimerization and assembly of human immunodeficiency virus type 1 integrase as a catalytically active complex on immobilized long terminal repeat substrates.

The integration of a DNA copy of the viral genome into the genome of the host cell is an essential step in the replication of all retroviruses. Integration requires two discrete biochemical reactions; specific processing of each viral long terminal repeat terminus or donor substrate, and a DNA strand transfer step wherein the processed donor substrate is joined to a nonspecific target DNA. Both reactions are catalyzed by a virally encoded enzyme, integrase. A microtiter assay for the strand transfer activity of human immunodeficiency virus type 1 integrase which uses an immobilized oligonucleotide as the donor substrate was previously published (D. J. Hazuda, J. C. Hastings, A. L. Wolfe, and E. A. Emini, Nucleic Acids Res. 22;1121-1122, 1994). We now describe a series of modifications to the method which facilitate study of both the nature and the dynamics of the interaction between integrase and the donor DNA. The enzyme which binds to the immobilized donor is shown to be sufficient to catalyze strand transfer with target DNA substrates added subsequent to assembly; in the absence of the target substrate, the complex was retained on the donor in an enzymatically competent state. Assembly required high concentrations of divalent cation, with optimal activity achieved at 25 mM MnCl2. In contrast, preassembled complexes catalyzed strand transfer equally efficiently in either 1 or 25 mM MnCl2, indicating mechanistically distinct functions for the divalent cation in assembly and catalysis, respectively. Prior incubation of the enzyme in 25 mM MnCl2 was shown to promote the multimerization of integrase in the absence of a DNA substrate and alleviate the requirement for high concentrations of divalent cation during assembly. The superphysiological requirement for MnCl2 may, therefore, reflect an insufficiency for functional self-assembly in vitro. Subunits were observed to exchange during the assembly reaction, suggesting that multimerization can occur either before or coincident with but not after donor binding. These studies both validate and illustrate the utility of this novel methodology and suggest that the approach may be generally useful in characterizing other details of this biochemical reaction.     

Biochemical and biophysical analyses of concerted (U5/U3) integration

Retrovirus integrase (IN) integrates the viral linear DNA genome (10 kb) into a host chromosome, a step which is essential for viral replication. Integration occurs via a nucleoprotein complex, termed the preintegration complex (PIC). This article focuses on the reconstitution of synaptic complexes from purified components whose molecular properties mirror those of the PIC, including the efficient concerted integration of two ends of linear viral DNA into target DNA. The methods described herein permit the biochemical and biophysical analyses of concerted integration. The methods enable (1) the study of interactions between purified recombinant IN and its viral DNA substrates at the molecular level; (2) the identification and characterization of nucleoprotein complexes involved in the human immunodeficiency virus type-1 (HIV-1) concerted integration pathway; (3) the determination of the multimeric state of IN within these complexes; (4) dissection of the interaction between HIV-1 IN and cellular proteins such as lens epithelium-derived growth factor (LEDGF/p75); (5) the examination of HIV-1 Class II and strand transfer inhibitor resistant IN mutants; (6) the mechanisms associated with strand transfer inhibitors directed against HIV-1 IN that have clinical relevance in the treatment of HIV-1/AIDS.     

Differential divalent cation requirements uncouple the assembly and catalytic reactions of human immunodeficiency virus type 1 integrase.

Previous in vitro analyses have shown that the human immunodeficiency virus type 1 (HIV-1) integrase uses either manganese or magnesium to assemble as a stable complex on the donor substrate and to catalyze strand transfer. We now demonstrate that subsequent to assembly, catalysis of both 3' end processing and strand transfer requires a divalent cation cofactor and that the divalent cation requirements for assembly and catalysis can be functionally distinguished based on the ability to utilize calcium and cobalt, respectively. The different divalent cation requirements manifest by these processes are exploited to uncouple assembly and catalysis, thus staging the reaction. Staged 3' end processing and strand transfer assays are then used in conjunction with exonuclease III protection analysis to investigate the effects of integrase inhibitors on each step in the reaction. Analysis of a series of related inhibitors demonstrates that these types of compounds affect assembly and not either catalytic process, therefore reconciling the apparent disparate results obtained for such inhibitors in assays using isolated preintegration complexes. These studies provide evidence for a distinct role of the divalent cation cofactor in assembly and catalysis and have implications for both the identification and characterization of integrase inhibitors.     

Structural insights into the retroviral DNA integration apparatus

Retroviral replication depends on successful integration of the viral genetic material into a host cell chromosome. Virally encoded integrase, an enzyme from the DDE(D) nucleotidyltransferase superfamily, is responsible for the key DNA cutting and joining steps associated with this process. Insights into the structural and mechanistic aspects of integration are directly relevant for the development of antiretroviral drugs. Recent breakthroughs have led to biochemical and structural characterization of the principal integration intermediates revealing the tetramer of integrase that catalyzes insertion of both 3' viral DNA ends into a sharply bent target DNA. This review discusses the mechanism of retroviral DNA integration and the mode of action of HIV-1 integrase strand transfer inhibitors in light of the recent visualization of the prototype foamy virus intasome, target DNA capture and strand transfer complexes.     

Homogeneous high-throughput screening assays for HIV-1 integrase 3beta-processing and strand transfer activities

HIV-1 integrase (HIV-IN) is a well-validated antiviral drug target catalyzing a multistep reaction to incorporate the HIV-1 provirus into the genome of the host cell. Small molecule inhibitors of HIV-1 integrase that specifically target the strand transfer step have demonstrated efficacy in the suppression of virus propagation. However, only few specific strand transfer inhibitors have been identified to date, and the need to screen for novel compound scaffolds persists. Here, the authors describe 2 homogeneous time-resolved fluorescent resonance energy transfer-based assays for the measurement of HIV-1 integrase 3'-processing and strand transfer activities. Both assays were optimized for high-throughput screening formats, and a diverse library containing more than 1 million compounds was screened in 1536-well plates for HIV-IN strand transfer inhibitors. As a result, compounds were found that selectively affect the enzymatic strand transfer reaction over 3beta processing. Moreover, several bioactive molecules were identified that inhibited HIV-1 reporter virus infection in cellular model systems. In conclusion, the assays presented herein have proven their utility for the identification of mechanistically interesting and biologically active inhibitors of HIV-1 integrase that hold potential for further development into potent antiviral drugs.     

HIV-1整合酶四聚体结构模拟及其活性位点分析

HIV-1复制需要HIV-1整合酶将其环状DNA整合进宿主DNA中,这其中包括2个重要反应,即“3′-加工”和“链转移”,两者均由HIV-1整合酶催化完成.阻断其中的任一反应,都能达到抑制HIV-1复制的目的.因此,了解HIV-1整合酶的完整结构和聚合状态,对深入探讨其作用机理及设计新型抑制剂具有重要的指导作用.然而,迄今为止仅有HIV-1整合酶单独结构域的晶体结构可供参考,而其全酶晶体结构尚未获得解析.本研究利用分子模拟技术,通过蛋白质 蛋白质/DNA分子对接、动力学模拟等方法,构建了全长整合酶四聚体的结构模型、HIV-1 DNA与整合酶复合物的结构模型,进一步从理论上证实HIV-1整合酶是以四聚体形态发挥催化作用,明确“3′-加工”和“链转移”在HIV-1整合酶上的催化位点.同时,通过与作用机理相似的细菌转座子Tn5转座酶等的结构比对,推测HIV-1整合酶的核心结构域中应有第2个Mg^２＋存在,其位置螯合于Asp64与Glu152之间.在HIV-1整合酶结构研究的基础上,有望进一步设计出新的抗艾滋病药物.     

Chemical and enzymatic modifications of integric acid and HIV-1 integrase inhibitory activity

Integric acid (1), an acyl eremophilane sesquiterpenoid, was identified as an inhibitor of HIV-1 integrase, the enzyme responsible for provirus entry into the host cell nucleus and integration in to the host genome. Chemical and enzymatic modification of integric acid led to the preparation of several selective chemical derivatives of integric acid. Preparation, HIV-1 inhibitory activity, and the structure-activity relationship against coupled and strand transfer assays are described. It appears that most of the groups present in the natural product are required for inhibition of HIV-1 integrase strand transfer activity. In contrast, inhibition of 3' processing activity is less stringent suggesting distinct SAR for the two integrase reactions.     

HIV-1 integrase preassembled on donor DNA is refractory to activity stimulation by LEDGF/p75

LEDGF/p75 is known to enhance the integrase strand transfer activity in vitro, but the underlying mechanism is unclear. Using an integrase assay with a chemiluminescent readout adapted to a 96-well plate format, the effect of LEDGF/p75 on both the 3'-processing and strand transfer steps was analyzed. Integrase inhibitors of the strand transfer reaction remained active in the presence of LEDGF/p75, but displayed 3- to 7-fold higher IC50 values. Our analyses indicate that, in the presence of 150 nM LEDGF/p75, active integrase/donor DNA complexes were increased by 5.3-fold during the 3'-processing step. In addition, these integrase/donor DNA complexes showed a 4.5-fold greater affinity for the target DNA during the subsequent strand transfer step. We also observed a 3.7-fold increase in the rate constant of catalysis of the strand transfer step when 150 nM LEDGF/p75 was present during the 3'-processing step. In contrast, when LEDGF/p75 was added at the beginning of the strand transfer step, no increase in either the concentration of active integrase/donor DNA complex or its rate constant of strand transfer catalysis was observed. This observation suggested that the integrase/donor DNA formed in the absence of LEDGF/p75 became refractory to the stimulatory effect of LEDGF/p75. Instead, this LEDGF/p75 added at the start of the strand transfer step was able to promote the formation of a new cohort of active integrase/donor DNA complexes which became functional with a delay of 45 min after LEDGF/p75 addition. We propose a model whereby LEDGF/p75 can only bind integrase before the latter binds donor DNA whereas donor DNA can engage either free or LEDGF/p75-bound integrase.     

Structural determinants for HIV-1 integrase inhibition by beta-diketo acids.

Among all the HIV-1 integrase inhibitors, the beta-diketo acids (DKAs) represent a major lead in anti-HIV-1 integrase drug design. These derivatives inhibit the integration reaction in vitro with a strong specificity for the 3'-end joining step. They are also antiviral and inhibit integration in vivo. The aim of the present study has been to investigate the molecular interactions between DKAs and HIV-1 integrase. We have compared 5CITEP with one of the most potent DKAs reported by the Merck group (L-708,906) and found that 5CITEP inhibits 3'-processing at concentrations where L-708,906 is only active on strand transfer. We also report a novel bifunctional DKA derivative that inhibits 3'-processing even more effectively than 5CITEP. The interactions of these inhibitors with the viral DNA donor ends have been studied by performing experiments with oligonucleotides containing defined modifications. We propose that the bifunctional DKA derivative binds to both the acceptor and donor sites of HIV-1 integrase, whereas the monofunctional L-708,906 derivative binds selectively to the acceptor site.     

Integration requires a specific interaction of the donor DNA terminal 5'-cytosine with glutamine 148 of the HIV-1 integrase flexible loop

Integration is essential for retroviral replication and gene therapy using retroviral vectors. Human immunodeficiency virus, type 1 (HIV-1), integrase specifically recognizes the terminal sequences of each long terminal repeat (LTR) and cleaves the 3'-end terminal dinucleotide 5'-GT. The exposed 3'-hydroxyl is then positioned for nucleophilic attack and subsequent strand transfer into another DNA duplex (target or chromosomal DNA). We report that both the terminal cytosine at the protruding 5'-end of the long terminal repeats (5'-C) and the integrase residue Gln-148 are critical for strand transfer. Proximity of the 5'-C and Gln-148 was demonstrated by disulfide cross-linking. Cross-linking is inhibited by the inhibitor 5CITEP 1-(5-chloroindol-3-yl)-3-hydroxy-3-(2H-tetrazol-5-yl)-propenone. We propose that strand transfer requires a conformational change of the integrase-viral (donor) DNA complex with formation of an H-bond between the N-3 of the 5'-C and the amine group of Gln-148. These findings have implications for the molecular mechanisms coupling 3'-processing and strand transfer as well as for the molecular pharmacology of integrase inhibitors.