Designing Antiviral Proteins Via Computer Could Help Halt the Next Pandemic

This antivirus software protects health, not computers. Researchers are beginning to combat deadly infections using computer-generated antiviral proteins – a valuable tool to fight a future pandemic.

Computers may play an important role in preparing us for the next viral outbreak – whether flu or Ebola. UW Institute for Protein Design

As Bill Gates sees it, there are three main threats to our species: nuclear war, climate change and the next global pandemic.

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Speaking on pandemic preparedness at the Munich Security Conference earlier this year, Gates reminded us that “the fact that a deadly global pandemic has not occurred in recent history shouldn’t be mistaken for evidence that a deadly pandemic will not occur in the future.”

If we want to be prepared for the worst, Gates says, “first and most importantly, we have to build an arsenal of new weapons – vaccines, drugs and diagnostics.”

Some scientists are now using computers to do just that.

Going beyond the immune system

Despite the availability of the flu shot, the World Health Organization reports that seasonal influenza is still responsible for millions of serious illnesses and as many as half a million deaths per year globally. The partial efficacy of each year’s flu shot, coupled with long manufacturing times and limited global availability, suggests new flu-fighting methods are still needed.

And that’s just for the seasonal flu. Pandemic influenza, like the devastating 1918 Spanish flu, could again kill tens of millions of people in a single year.

Antibodies, a natural part of the immune system, are front-line soldiers in the war against viruses. The job of an antibody is to recognize and physically adhere to a foreign invader like influenza. Human antibodies are bivalent, meaning they have two hands with which they can grab onto their target.

A glass model of an influenza virus hanging in the Smithsonian National Museum of Natural History. Tim Evanson

Under a microscope, influenza looks like a tiny ball with spikes. It uses some of its surface spikes to break into human cells. By grabbing tightly to those spikes using one or both hands, antibodies can prevent flu particles from infecting human cells. But every year the rapidly evolving influenza picks up mutations in its spike proteins, causing the sticky hands of our antibodies to no longer recognize the virus.

Researchers have long sought a universal flu vaccine – one that doesn’t need to be re-administered every year. Efforts to produce one tend to involve injecting noninfectious flu lookalikes in hopes that it will prime the immune system to mount a proper attack on whatever real strain of flu it sees next. Despite some progress, researchers have not yet been able to coax the immune system to defend against all strains of influenza, and the threat of a global pandemic still looms.

1981
Dr. Erskine. L. Palmer; Dr. M. L. Martin
This negative-stained transmission electron micrograph (TEM) depicts the ultrastructural details of an influenza virus particle, or “virion”. A member of the taxonomic family Orthomyxoviridae, the influenza virus is a single-stranded RNA organismThe flu is a contagious respiratory illness caused by influenza viruses. It can cause mild to severe illness, and at times can lead to death. The best way to prevent this illness is by getting a flu vaccination each fall.
Every year in the United States, on average:
– 5% to 20% of the population gets the flu
– more than 200,000 people are hospitalized from flu complications, and
– about 36,000 people die from flu. Some people, such as older people, young children, and people with certain health conditions, are at high risk for serious flu complications. See PHIL 8430 for a black and white version of this image.
Influenza A and B are the two types of influenza viruses that cause epidemic human disease. Influenza A viruses are further categorized into subtypes on the basis of two surface antigens: hemagglutinin and neuraminidase. Influenza B viruses are not categorized into subtypes. Since 1977, influenza A (H1N1) viruses, influenza A (H3N2) viruses, and influenza B viruses have been in global circulation. In 2001, influenza A (H1N2) viruses that probably emerged after genetic reassortment between human A (H3N2) and A (H1N1) viruses began circulating widely. Both influenza A and B viruses are further separated into groups on the basis of antigenic characteristics. New influenza virus variants result from frequent antigenic change (i.e., antigenic drift) resulting from point mutations that occur during viral replication. Influenza B viruses undergo antigenic drift less rapidly than influenza A viruses. CDC/Erskine. L. Palmer, Ph.D.; M. L. Martin

Software to beat the flu

Computational protein design offers another way. Rather than relying on the immune system to generate an antibody protein capable of shutting down a virus like the flu, computer modeling can now help quickly create custom antiviral proteins programmed to shut down a deadly virus.

Unlike a vaccine, this class of drug could be administered to treat an existing infection or given days prior to exposure to prevent one. And because these designer proteins work independently of the immune system, their potency does not depend on having an intact immune system – a useful trait, as those with weaker immune systems are at high risk for viral infection.

Computer-generated antiviral proteins work the same way some natural proteins in our immune system do. By having surfaces that are chemically complementary to their targets, antiviral proteins can stick tightly to a specific virus. If a protein sticks to a virus in just the right way, it can physically block how that virus moves, ultimately preventing infection.

By designing an antiviral protein on a computer, building it in the laboratory and then administering it into the body, you effectively digitize part of the immune system.

In 2016, computer-generated proteins were shown to be more effective than oseltamivir (Tamiflu) in warding off death in influenza-infected mice. One dose of designer protein given intranasally was more effective than 10 doses of Tamiflu, a drug considered an “essential medicine” by the WHO due to its antiflu activity. What’s more, these new computer-generated antiflu proteins protected mice against diverse strains of the flu. Efforts to turn these promising results into FDA-approved drugs are underway.

In a just published paper in Nature Biotechnology, scientists here at the Institute for Protein Design at the University of Washington went a step further and demonstrated a new way to shut down the flu: They used computer modeling to build a completely new kind of antiviral protein with three sticky hands.

Why three? It turns out many deadly envelope viruses – like influenza, Ebola and HIV – build their spike proteins out of three symmetric parts.

A single antiviral drug with three properly spaced hands should be able to symmetrically grab each part of a spike protein, leading to tighter binding and overall better antiviral activity. This geometric feat is beyond what the human immune system can naturally do.

Left: The tips of many viral spike proteins are built out of three symmetric parts, with one part highlighted in pink. Right: A new three-handed antiflu protein (blue) bound to influenza’s HA spike. UW Institute for Protein Design

The design strategy worked. The best three-handed protein, called Tri-HSB.1C, was able to bind tightly to diverse strains of influenza. When given to mice, it also afforded complete protection against a lethal flu infection with only minimal associated weight loss – a trait commonly used to diagnose flu severity in mice. Researchers are now applying the same tools to the Ebola spike protein.

It will be many years before this new technology is approved for use in humans, for any virus. But we may not have to wait long to see some lifesaving benefits.

Viral diagnostics

By coating a strip of paper with a three-handed flu binder and applying influenza samples on top, the same team was able to detect the presence of viral surface protein even at very low concentrations. This proof-of-concept detection system could be transformed into a reliable and affordable on-site diagnostic tool for a variety of viruses by detecting them in saliva or blood. Like a pregnancy test, a band on a test strip could indicate flu. Or Ebola. Or the next rapidly spreading global pandemic.

In a 2015 letter to the New England Journal of Medicine on lessons learned from the Ebola epidemic in West Africa, Bill Gates describes the lack of preparation by the global community as “a global failure.”

“Perhaps the only good news from the tragic Ebola epidemic,” Gates says, “is that it may serve as a wake-up call.” (The Bill and Melinda Gates Foundation funds work on protein design at the University of Washington.)

The ConversationWhen a global viral pandemic like the 1918 Spanish flu strikes again, antivirus software of the biological kind may play an important role in saving millions of lives.

Ian Haydon is a Doctoral Student in Biochemistry at the University of Washington. This article was originally published on The Conversation. Read the original article.

Designing Antiviral Proteins Via Computer Could Help Halt the Next Pandemic