Structural Basis of Activity of and Resistance to HIV Integrase Inhibitors
Dmitry Lyumkis

TL;DR
This paper explores how HIV becomes resistant to a key class of drugs and suggests ways to improve future treatments.
Contribution
The study combines structural biology and other methods to uncover resistance mechanisms and guide drug improvement.
Findings
Drug-resistant mutations in HIV integrase are linked to specific structural changes observed via cryo-EM.
Novel resistance pathways are identified that could inform the design of more effective INSTIs.
Collaboration with chemists is leading to the development of therapeutics targeting resistant HIV strains.
Abstract
The Human Immunodeficiency Virus Type 1 (HIV) currently infects ∼40 million people worldwide. In the absence of a cure, antiretroviral therapy represents the primary treatment option, because it slows disease progression and reduces new infections. Integrase (IN) Strand Transfer Inhibitors (INSTIs) are a class of antiretroviral therapeutics that block integration of viral DNA into host chromosomes. This process is mediated by the viral IN enzyme, which assembles into oligomeric nucleoprotein complexes on the ends of viral DNA, termed “intasomes”. INSTIs selectively target intasomes and represent first-line therapies in the clinic. However, the emergence of IN variants resistant to INSTIs is becoming a greater clinical problem. We are using interdisciplinary approaches that include structural biology via cryogenic electron microscopy, biochemistry, cellular virology, and computation to…
Genes, proteins, chemicals, diseases, species, mutations and cell lines named across the full text — each resolved to its canonical identifier and authoritative record.
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Taxonomy
TopicsHIV/AIDS drug development and treatment · Biochemical and Molecular Research · Enzyme Structure and Function
