Montelukast can bind to and block a crucial protein produced by SARS-CoV-2, reducing viral replication in human immune cells, according to a new study by researchers at the Indian Institute of Science (IISc).
Montelukast has been around for more than 20 years and is usually prescribed to reduce inflammation caused by conditions like asthma, hay fever and hives.
In the study, published in eLife, the researchers showed that the drug binds strongly to the C-terminal, which is one end of a SARS-CoV-2 protein called Nsp1, which is one of the first viral proteins unleashed inside human cells. NSp1 can bind to ribosomes inside immune cells, shutting down production of vital proteins that the immune system needs, thereby weakening it. Nsp1 could therefore be a target to reduce the virus’s damage.
“The mutation rate in this protein, especially the C-terminal region, is very low compared to the rest of the viral proteins,” explained IISc’s Assistant Professor Tanweer Hussain, senior author of the study. Since Nsp1 is unlikely to change in future variants, targeting it with drugs is a viable strategy, he added.
The researchers screened more than 1600 FDA-approved drugs with computational modelling to find the ones that bound strongly to Nsp1, coming up with a shortlist of drugs including montelukast and saquinavir, an anti-HIV drug. “The molecular dynamic simulations generate a lot of data, in the range of terabytes, and help to figure out the stability of the drug-bound protein molecule. To analyse these and identify which drugs may work inside the cell was a challenge,” said Mohammad Afsar, first author of the study.
The researchers then cultured human cells which produced Nsp1, treated them with montelukast and saquinavir separately, and found that only montelukast was able to rescue the inhibition of protein synthesis by Nsp1.
“There are two aspects [to consider]: one is affinity and the other is stability,” explained Afsar. This means that the drug needs to not only bind to the viral protein strongly, but also stay bound for a sufficiently long time to prevent the protein from affecting the host cell, he adds. “The anti-HIV drug (saquinavir) showed good affinity, but not good stability.” Montelukast, on the other hand, was found to bind strongly and stably to Nsp1, allowing the host cells to resume normal protein synthesis.
The researchers then tested the effect of the drug on live viruses and found that the drug was able to reduce viral numbers in infected cells in the culture.
“Clinicians have tried using the drug … and there are reports that said that montelukast reduced hospitalisation in COVID patients,” said A/Prof Hussain, adding that the exact mechanisms behind it still need to be fully understood. His team plans to work with chemists to see if they can modify the structure of the drug to increase its potency, and also plan to continue the hunt for more drugs.
Source: Indian Institute of Science