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  1. Gill MSA, Hassan SS, Ahemad N
    Eur J Med Chem, 2019 Oct 01;179:423-448.
    PMID: 31265935 DOI: 10.1016/j.ejmech.2019.06.058
    HIV infection is a major challenge to mankind and a definitive cure or a viable vaccine for HIV is still elusive. HIV-1 is constantly evolving and developing resistant against clinically used anti-HIV drugs thus posing serious hurdles in the treatment of HIV infection. This prompts the need to developed new anti-HIV drugs; preferentially adopting intelligent ways to counteract an evolving virus. Highly Active Anti-Retroviral Therapy (HAART): a strategy involving multiple targeting through various drugs has proven beneficial in the management of AIDS. However, it is a complex regimen with high drug load, increased risk of drug interactions and adverse effects, which lead to poor patient compliance. Reverse transcriptase (RT) and Integrase (IN) are two pivotal enzymes in HIV-1 lifecycle with high structural and functional analogy to be perceived as drug-able targets for novel dual-purpose inhibitors. Designed multi-functional ligand (DML) is a modern strategy by which multiple targets can be exploited using a single chemical entity. A single chemical entity acting on multiple targets can be much more effective than a complex multi-drug regimen. The development of such multifunctional ligands is highly valued in anti-HIV drug discovery with the proposed advantage of being able to stop two or more stages of viral replication cycle. This review will encompass the evolution of the RT-IN dual inhibitory scaffolds reported so far and the contribution made by the leading research groups over the years in this field.
    Matched MeSH terms: HIV Reverse Transcriptase/metabolism
  2. Chander S, Tang CR, Al-Maqtari HM, Jamalis J, Penta A, Hadda TB, et al.
    Bioorg Chem, 2017 06;72:74-79.
    PMID: 28371664 DOI: 10.1016/j.bioorg.2017.03.013
    In the present study, a series of fourteen 5-benzoyl-4-methyl-1,3,4,5-tetrahydro-2H-1,5-benzodiazepin-2-one derivatives were designed, synthesized and characterized by appropriate spectral analysis. Further, titled compounds were in-vitro screened against wild HIV-1 RT enzyme using ELISA based colorimetric assay, in which four compounds significantly inhibited the RT activity with IC50≤25µM. Moreover, two significantly active compounds of the series, A10 and A11 exhibited IC50 values 8.62 and 6.87µM respectively, during the in-vitro assay. Structure Activity Relationship (SAR) studies were performed for the synthesized compounds in order to estimate the effect of substitution pattern on the RT inhibitory potency. The cytotoxicity of the synthesized compounds was evaluated against T lymphocytes. Further, putative binding modes of the significantly active (A11) and the least active (A4) compounds with wild HIV-1 RT were also investigated using docking studies.
    Matched MeSH terms: HIV Reverse Transcriptase/metabolism
  3. Kharkwal H, Kumar BK, Murugesan S, Singhvi G, Avasthi P, Goyal A, et al.
    Future Med Chem, 2021 02;13(3):269-286.
    PMID: 33399497 DOI: 10.4155/fmc-2020-0257
    Reverse transcriptase and integrase are key enzymes that play a pivotal role in HIV-1 viral maturation and replication. Reverse transcriptase consists of two active sites: RNA-dependent DNA polymerase and RNase H. The catalytic domains of integrase and RNase H share striking similarity, comprising two aspartates and one glutamate residue, also known as the catalytic DDE triad, and a Mg2+ pair. The simultaneous inhibition of reverse transcriptase and integrase can be a rational drug discovery approach for combating the emerging drug resistance problem. In the present review, the dual inhibition of RNase H and integrase is systematically discussed, including rationality of design, journey of development, advancement and future perspective.
    Matched MeSH terms: HIV Reverse Transcriptase/metabolism
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