Development of the Gag/Lysyl tRNA synthetase interaction as a target for anti-HIV

开发 Gag/赖氨酰 tRNA 合成酶相互作用作为抗 HIV 靶点

• 批准号: 7547575
• 负责人: LAWRENCE KLEIMAN
• 金额: $ 66.28万
• 依托单位: SIR MORTIMER B. DAVIS JEWISH GEN HOSP
• 依托单位国家: 美国
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-07-01 至 2013-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7547575
• 关键词: Alanine; Anisotropy; Anti-HIV Therapy; Antiviral Agents; Binding; Binding Proteins; Binding Sites; Biological Assay; C-terminal; Capsid; Cells; Co-Immunoprecipitations; Collaborations; Complex; Computer Simulation; Cultured Cells; DNA; Data; Development; Dimerization; Enzymes; Fluorescence Anisotropy; Gagging; Genome; HIV-1; Helix (Snails); Human; In Vitro; Label; Libraries; Life Cycle Stages; Lysine-Specific tRNA; Lysine-tRNA Ligase; Mammalian Cell; Maps; Measures; Minnesota; Monitor; Mutagenesis; Mutate; Mutation; N Domain; NMR Spectroscopy; Ohio; Peptides; Protein Footprinting; Proteins; RNA; RNA-Directed DNA Polymerase; Reaction; Reporting; Resolution; Reverse Transcription; Scanning; Screening procedure; Site; Small Interfering RNA; Study models; Techniques; Testing; Tracer; Transfer RNA; Universities; Viral; Viral Proteins; Viral Reverse Transcription; Virion; Virus; Work; X-Ray Crystallography; Yang; analog; aptamer; design; drug development; ear helix; gag Gene Products; high throughput screening; improved; in vivo; inhibitor/antagonist; mutant; novel; particle; prevent; small molecule; viral DNA; viral RNA

DESCRIPTION (provided by applicant): The genome of HIV-1 is composed of RNA, and after this RNA enters a cell, it must be converted to viral DNA, which can then insert into the cell's DNA, and be used to produce new viral protein and viruses. The RNA is converted into DNA by the viral enzyme reverse transcriptase. This enzyme requires a primer to start reverse transcription. The primer for reverse transcription in HIV-1 is human tRNALys3, which is selectively packaged into the virion during viral assembly in the cell, and binds (anneals) to a region in the viral RNA genome termed the primer binding site (PBS). It is from this bound tRNALys3 that reverse transcription begins. The selective packaging of tRNALys3 occurs because the viral protein Gag specifically interacts with a major tRNALys3-binding protein in the cell, lysyl-tRNA synthetase (LysRS), so that both tRNALys3 and LysRS are packaged into the assembling virus. Disrupting this reaction through mutations in either Gag or LysRS prevent tRNALys3 from being packaged into the virus, and greatly reduces reverse transcription and viral infectivity. The Gag/LysRS interaction, therefore, represents a novel target for anti-HIV-1 therapy. In this project, we are seeking to identify small molecule inhibitors of this interaction. This will be done using high throughput screening (HTS) of libraries of compounds to find molecules that inhibit the Gag/LysRS interaction. The interaction of LysRS with either Gag or the smaller capsid (CA) molecule will be measured using fluorescent anisotropy (FA), using fluorescently-labeled CA as the tracer in the HTS of the LysRS/CA interaction. The ability of small peptides or RNA molecules to inhibit this interaction will also be investigated, using peptides from Gag or LysRS that are known to be involved in the Gag/LysRS interaction, or SELEX to isolate RNA molecules that specifically bind to CA. Project Narrative Many reports have now demonstrated that the selective packaging into HIV-1 of the primer for reverse transcription, tRNALys3, is essential for the viral life cycle. This selective incorporation of tRNALys3 requires a specific interaction between Gag and LysRS, making the Gag/LysRS interaction an attractive target for antiviral drug development. The feasibility of using a fluorescence anisotropy assay to detect the binding interaction has already been demonstrated, and will be used in this project facilitate the development of rapid screening techniques to search for inhibitors of this novel target, which will then be tested for their ability to specifically inhibit HIV-1 replication.

描述（由申请人提供）：HIV-1的基因组由RNA组成，在该RNA进入细胞后，必须将其转换为病毒DNA，然后可以将其插入细胞的DNA中，并用于产生新的病毒蛋白和病毒。通过病毒酶逆转录酶将RNA转化为DNA。该酶需要底漆开始逆转录。 HIV-1中逆转录的引物是人类TRNALYS3，在细胞中的病毒组装过程中选择性地包装到病毒粒子中，并与病毒RNA基因组中的区域结合（退火）称为引物结合位点（PBS）。逆转录开始是从这个结合的trnalys3开始。 TRNALYS3的选择性包装之所以发生，是因为病毒蛋白GAG与细胞中主要的TRNalys3结合蛋白（Lysyl-tRNA合成酶（LYSR））特异性相互作用，因此将Trnalys3和Lysr均包装到组装病毒中。通过GAG或LYSR中的突变破坏这种反应，以防止Trnalys3被包装到病毒中，并大大降低了逆转录和病毒感染性。因此，GAG/LYSR相互作用代表了抗HIV-1治疗的新靶标。在这个项目中，我们试图鉴定这种相互作用的小分子抑制剂。这将使用化合物文库的高吞吐量筛选（HTS）进行，以找到抑制GAG/LYSR相互作用的分子。 LYSR与GAG或较小的衣壳（Ca）分子的相互作用将使用荧光各向异性（FA）测量，使用荧光标记的CA作为LYSRS/CA相互作用的HTS中的示踪剂。小肽或RNA分子抑制这种相互作用的能力也将被研究，使用来自GAG或LYSR的肽，这些肽已知与GAG/LYSR相互作用相互作用，或SELEX与特异性结合的RNA分子分离。项目叙述现在许多报道都证明了底漆的hiv-1的选择性包装trnalys3对于病毒生命周期至关重要。 Trnalys3的这种选择性融合需要GAG和LYSR之间的特定相互作用，使GAG/LYSRS相互作用成为抗病毒药药发育的有吸引力的靶标。已经证明了使用荧光各向异性测定检测结合相互作用的可行性，并将用于该项目，将有助于开发快速筛选技术来寻找这种新型靶标的抑制剂，然后将测试其特定抑制HIV HIV-1的能力。