Researchers uncover molecular mechanisms of HIV drug resistance

“With HIV, one must think two steps ahead of the virus,” says Salk Associate Professor Dmitry Lyumkis, co-senior author and the Hearst Foundation Developmental Chair.

Update: 2023-07-24 14:30 GMT

Representative image (File)

LA JOLLA: Researchers from the Salk Institute and the National Institutes of Health have identified the molecular pathways by which the human immunodeficiency virus (HIV) develops resistance to dolutegravir, one of the most potent antiviral medications now being used in clinical use to treat HIV.

The latest research, which was published in Science Advances, describes how modifications to the 3D structures of the HIV protein integrase can cause resistance to dolutegravir and how alternative drugs might be able to break this resistance.

“With HIV, one must think two steps ahead of the virus,” says Salk Associate Professor Dmitry Lyumkis, co-senior author and the Hearst Foundation Developmental Chair.

“We’ve now determined how the virus could continue evolving against drugs like Dolutegravir, which is important to consider for the development of future therapeutics.”

HIV infection is based on the virus's capacity to insert its own genetic material into the genomes of human cells, thus stealing control of the cells and turning them into factories for the production of the virus. In order for a virus to successfully integrate its own DNA into the host genome, integrase, a protein, must be active. Integrase is blocked by dolutegravir and comparable medications.

HIV is unable to successfully infect human cells in the absence of an active integrase. A growing number of HIV strains are becoming resistant to dolutegravir since HIV is a virus that mutates quickly.

In the past, Lyumkis’ lab discovered the 3D structure of the integrase protein while attached to DNA as well as exactly how drugs like Dolutegravir bind to and block integrase.

But researchers weren’t sure how the integrase structure changed when the virus stopped responding to Dolutegravir.

In the new study, Lyumkis and collaborators from the National Institutes of Health created versions of the integrase protein with mutations known to make HIV resistant to Dolutegravir. Then they determined the structure of each mutant integrase, revealing why Dolutegravir could no longer bind to and block each version of the protein.

The scientists also evaluated the “fitness” of the virus (its capacity to produce infectious descendants) and the activity of the enzyme to better understand what leads to drug resistance in patients.

“We were quite surprised by the magnitude of resistance that these integrase variants had,” says Lyumkis. “The ability of Dolutegravir to function was completely compromised.”

The researchers also tested the efficacy of an experimental HIV drug, 4d, to block the function of Dolutegravir-resistant integrase proteins.

4d was developed by Lyumkis’ collaborators at the NIH as a next-generation integrase-targeting drug and is currently in pre-clinical animal trials. In all the variants, they discovered that 4d still potently blocked the ability of HIV to integrate its genes into human cells.

This suggests that 4d or variants of this compound may be effectively used to treat the virus in patients who have developed resistance to Dolutegravir. The structural data on how 4d binds to the Dolutegravir-resistant integrase proteins also hinted at how new drugs could overcome drug resistance.

“4d is really just an example of how to combat drug resistance, but it provides us with some basic principles that we can learn from to design other therapeutics,” says co-senior author Robert Craigie of the National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK), part of the National Institutes of Health.


“The way a section of the 4d molecule stacks like a flat sheet on top of a section of the integrase protein-DNA assembly could be replicated in other compounds.”

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