antivirals
Early Data Suggest Pfizer Pill May Prevent Severe COVID-19
Posted on by Dr. Francis Collins
Over the course of this pandemic, significant progress has been made in treating COVID-19 and helping to save lives. That progress includes the development of life-preserving monoclonal antibody infusions and repurposing existing drugs, to which NIH’s Accelerating COVID-19 Therapeutic Interventions and Vaccines (ACTIV) public-private partnership has made a major contribution.
But for many months we’ve had hopes that a safe and effective oral medicine could be developed that would reduce the risk of severe illness for individuals just diagnosed with COVID-19. The first indication that those hopes might be realized came from the announcement just a month ago of a 50 percent reduction in hospitalizations from the Merck and Ridgeback drug molnupiravir (originally developed with an NIH grant to Emory University, Atlanta). Now comes word of a second drug with potentially even higher efficacy: an antiviral pill from Pfizer Inc. that targets a different step in the life cycle of SARS-CoV-2, the novel coronavirus that causes COVID-19.
The most recent exciting news started to roll out earlier this month when a Pfizer research team published in the journal Science some promising initial data involving the antiviral pill and its active compound [1]. Then came even bigger news a few days later when Pfizer announced interim results from a large phase 2/3 clinical trial. It found that, when taken within three days of developing symptoms of COVID-19, the pill reduced by 89 percent the risk of hospitalization or death in adults at high risk of progressing to severe illness [2].
At the recommendation of the clinical trial’s independent data monitoring committee and in consultation with the U.S. Food and Drug Administration (FDA), Pfizer has now halted the study based on the strength of the interim findings. Pfizer plans to submit the data to the FDA for Emergency Use Authorization (EUA) very soon.
Pfizer’s antiviral pill is a protease inhibitor, originally called PF-07321332, or just 332 for short. A protease is an enzyme that cleaves a protein at a specific series of amino acids. The SARS-CoV-2 virus encodes its own protease to help process a large virally-encoded polyprotein into smaller segments that it needs for its life cycle; a protease inhibitor drug can stop that from happening. If the term protease inhibitor rings a bell, that’s because drugs that work in this way already are in use to treat other viruses, including human immunodeficiency virus (HIV) and hepatitis C virus.
In the case of 332, it targets a protease called Mpro, also called the 3CL protease, coded for by SARS-CoV-2. The virus uses this enzyme to snip some longer viral proteins into shorter segments for use in replication. With Mpro out of action, the coronavirus can’t make more of itself to infect other cells.
What’s nice about this therapeutic approach is that mutations to SARS-CoV-2’s surface structures, such as the spike protein, should not affect a protease inhibitor’s effectiveness. The drug targets a highly conserved, but essential, viral enzyme. In fact, Pfizer originally synthesized and pre-clinically evaluated protease inhibitors years ago as a potential treatment for severe acute respiratory syndrome (SARS), which is caused by a coronavirus closely related to SARS-CoV-2. This drug might even have efficacy against other coronaviruses that cause the common cold.
In the study published earlier this month in Science [1], the Pfizer team led by Dafydd Owen, Pfizer Worldwide Research, Cambridge, MA, reported that the latest version of their Mpro inhibitor showed potent antiviral activity in laboratory tests against not just SARS-CoV-2, but all of the coronaviruses they tested that are known to infect people. Further study in human cells and mouse models of SARS-CoV-2 infection suggested that the treatment might work to limit infection and reduce damage to lung tissue.
In the paper in Science, Owen and colleagues also reported the results of a phase 1 clinical trial with six healthy people. They found that their protease inhibitor, when taken orally, was safe and could reach concentrations in the bloodstream that should be sufficient to help combat the virus.
But would it work to treat COVID-19 in an infected person? So far, the preliminary results from the larger clinical trial of the drug candidate, now known as PAXLOVID™, certainly look encouraging. PAXLOVID™ is a formulation that combines the new protease inhibitor with a low dose of an existing drug called ritonavir, which slows the metabolism of some protease inhibitors and thereby keeps them active in the body for longer periods of time.
The phase 2/3 clinical trial included about 1,200 adults from the United States and around the world who had enrolled in the clinical trial. To be eligible, study participants had to have a confirmed diagnosis of COVID-19 within a five-day period along with mild-to-moderate symptoms of illness. They also required at least one characteristic or condition associated with an increased risk for developing severe illness from COVID-19. Each individual in the study was randomly selected to receive either the experimental antiviral or a placebo every 12 hours for five days.
In people treated within three days of developing COVID-19 symptoms, the Pfizer announcement reports that 0.8 percent (3 of 389) of those who received PAXLOVID™ were hospitalized within 28 days compared to 7 percent (27 of 385) of those who got the placebo. Similarly encouraging results were observed in those who got the treatment within five days of developing symptoms. One percent (6 of 607) on the antiviral were hospitalized versus 6.7 percent (41 of 612) in the placebo group. Overall, there were no deaths among people taking PAXLOVID™; 10 people in the placebo group (1.6 percent) subsequently died.
If all goes well with the FDA review, the hope is that PAXLOVID™ could be prescribed as an at-home treatment to prevent severe illness, hospitalization, and deaths. Pfizer also has launched two additional trials of the same drug candidate: one in people with COVID-19 who are at standard risk for developing severe illness and another evaluating its ability to prevent infection in adults exposed to the coronavirus by a household member.
Meanwhile, Britain recently approved the other recently developed antiviral molnupiravir, which slows viral replication in a different way by blocking its ability to copy its RNA genome accurately. The FDA will meet on November 30 to discuss Merck and Ridgeback’s request for an EUA for molnupiravir to treat mild-to-moderate COVID-19 in infected adults at high risk for severe illness [3]. With Thanksgiving and the winter holidays fast approaching, these two promising antiviral drugs are certainly more reasons to be grateful this year.
References:
[1] An oral SARS-CoV-2 M(pro) inhibitor clinical candidate for the treatment of COVID-19.
Owen DR, Allerton CMN, Anderson AS, Wei L, Yang Q, Zhu Y, et al. Science. 2021 Nov 2: eabl4784.
[2] Pfizer’s novel COVID-19 oral antiviral treatment candidate reduced risk of hospitalization or death by 89% in interim analysis of phase 2/3 EPIC-HR Study. Pfizer. November 5, 2021.
[3] FDA to hold advisory committee meeting to Discuss Merck and Ridgeback’s EUA Application for COVID-19 oral treatment. Food and Drug Administration. October 14, 2021.
Links:
COVID-19 Research (NIH)
Accelerating COVID-19 Therapeutic Interventions and Vaccines (ACTIV) (NIH)
A Study of PF-07321332/Ritonavir in Nonhospitalized Low-Risk Adult Participants With COVID-19 (ClinicalTrials.gov)
A Post-Exposure Prophylaxis Study of PF-07321332/Ritonavir in Adult Household Contacts of an Individual With Symptomatic COVID-19 (ClinicalTrials.gov)
Finding New Ways to Fight Coronavirus … From Studying Bats
Posted on by Dr. Francis Collins
David Veesler has spent nearly 20 years imaging in near-atomic detail the parts of various viruses, including coronaviruses, that enable them to infect Homo sapiens. In fact, his lab at the University of Washington, Seattle, was the first to elucidate the 3D architecture of the now infamous spike protein, which coronaviruses use to gain entry into human cells [1]. He uses these fundamental insights to guide the design of vaccines and therapeutics, including promising monoclonal antibodies.
Now, Veesler and his lab are turning to another mammal in their search for new leads for the next generation of antiviral treatments, including ones aimed at the coronavirus that causes COVID-19, SARS-CoV-2. With support from a 2020 NIH Director’s Pioneer Award, Veesler will study members of the order Chiroptera. Or, more colloquially, bats.
Why bats? Veesler says bats are remarkable creatures. They are the only mammals capable of sustained flight. They rarely get cancer and live unusually long lives for such small creatures. More importantly for Veesler’s research, bats host a wide range of viruses—more than any other mammal species. Despite carrying all of these viruses, bats rarely show symptoms of being sick. Yet they are the source for many of the viruses that have spilled over into humans with devastating effect, including rabies, Ebola virus, Nipah and Hendra viruses, severe acute respiratory syndrome coronavirus (SARS-CoV), and, likely, SARS-CoV-2.
Beyond what is already known about bats’ intriguing qualities, Veesler says humans still have much to discover about these flying mammals, including how their immune systems cope with such an onslaught of viral invaders. For example, it turns out that a bat’s learned, or adaptive, immune system is, for the most part, uncharted territory. As such, it offers an untapped source of potentially promising viral inhibitors just waiting to be unearthed, fully characterized, and then used to guide the development of new kinds of anti-viral therapeutics.
In his studies, Veesler will work with collaborators studying bats around the world to characterize their antibody production. He wants to learn how these antibodies contribute to bats’ impressive ability to tolerate viruses and other pathogens. What is it about the structure of bat antibodies that make them different from human antibodies? And, how can those structural differences serve as blueprints for promising new treatments to combat many potentially deadly viruses?
Interestingly, Veesler’s original grant proposal makes no mention of SARS-CoV-2 or COVID-19. That’s because he submitted it just months before the first reports of the novel coronavirus in Wuhan, China. But Veesler doesn’t consider himself a visionary by expanding his research to bats. He and others had been working on closely related coronaviruses for years, inspired by earlier outbreaks, including SARS in 2002 and Middle East respiratory syndrome (MERS) in 2012 (although MERS apparently came from camels). The researcher didn’t see SARS-CoV-2 coming, but he recognized the potential for some kind of novel coronavirus outbreak in the future.
These days, the Veesler lab has been hard at work to understand SARS-CoV-2 and the human immune response to the virus. His team showed that SARS-CoV-2 uses the human receptor ACE2 to gain entry into our cells [2]. He’s also a member of the international research team that identified a human antibody, called S309, from a person who’d been infected with SARS in 2003. This antibody is showing promise for treating COVID-19 [3], now in a phase 3 clinical trial in the United States.
In another recent study, reported as a pre-print in bioRxiv, Veesler’s team mapped dozens of distinct human antibodies capable of neutralizing SARS-CoV-2 by their ability to hit viral targets outside of the well-known spike protein [4]. Such discoveries may form the basis for new and promising combinations of antibodies to treat COVID-19 that won’t be disabled by concerning new variations in the SARS-CoV-2 spike protein. Perhaps, in the future, such therapeutic cocktails may include modified bat-inspired antibodies too.
References:
[1] Cryo-electron microscopy structure of a coronavirus spike glycoprotein trimer. Walls AC, Tortorici MA, Bosch BJ, Frenz B, Rottier PJM, DiMaio F, Rey FA, Veesler D. Nature. 2016 Mar 3;531(7592):114-117.
[2] Structure, function, and antigenicity of the SARS-CoV-2 spike glycoprotein. Walls AC, Park YJ, Tortorici MA, Wall A, McGuire AT, Veesler D. Cell. 2020 Apr 16;181(2):281-292.e6.
[3] Cross-neutralization of SARS-CoV-2 by a human monoclonal SARS-CoV antibody. Pinto D, Park YJ, Beltramello M, Veesler D, Cortil D, et al. Nature.18 May 2020 [Epub ahead of print]
[4] N-terminal domain antigenic mapping reveals a site of vulnerability for SARS-CoV-2. McCallum M, Marco A, Lempp F, Tortorici MA, Pinto D, Walls AC, Whelan SPJ, Virgin HW, Corti D, Pizzuto MS, Veesler D, et al. bioRxiv. 2021 Jan 14.
Links:
COVID-19 Research (NIH)
Veesler Lab (University of Washington, Seattle)
Veesler Project Information (NIH RePORTER)
NIH Director’s Pioneer Award Program (Common Fund)
NIH Support: Common Fund; National Institute of Allergy and Infectious Diseases
