Discovery of a druggable pocket in the SARS-CoV-2 Spike protein could stop virus in its tracks
Press release issued: 21 September 2020
A druggable pocket in the SARS-CoV-2 Spike protein that could be used to stop the virus from infecting human cells has been discovered by an international team of scientists led by the University of Bristol. The researchers say their findings, published today [21 September] in the journal Science, are a potential 'game changer' in defeating the current pandemic and add that small molecule anti-viral drugs developed to target the pocket they discovered could help eliminate COVID-19.
SARS-CoV-2 is decorated by multiple copies of a glycoprotein, known as the 'Spike protein', which plays an essential role in viral infectivity. Spike binds to the human cell surface, allowing the virus to penetrate the cells and start replicating, causing widespread damage.
In this ground-breaking study, the team headed by Professor Christiane Schaffitzel from Bristol’s School of Biochemistry and Professor Imre Berger from the Max Planck-Bristol Centre for Minimal Biology, used a powerful imaging technique, electron cryo-microscopy (cryo-EM), to analyse SARS-CoV-2 Spike at near atomic resolution. Enabled by Oracle high-performance cloud computing, a 3D structure of SARS CoV-2 Spike protein was generated allowing the researchers to peer deep inside the Spike identifying its molecular composition.
Unexpectedly, the research team’s analysis revealed the presence of a small molecule, linoleic acid (LA), buried in a tailor-made pocket within the Spike protein. LA is a free fatty acid, which is indispensable for many cellular functions. The human body cannot produce LA. Instead, the body absorbs this essential molecule through diet. Intriguingly, LA plays a vital role in inflammation and immune modulation, which are both key elements of COVID-19 disease progression. LA is also needed to maintain cell membranes in the lungs so that we can breathe properly.
Professor Berger said: "We were truly puzzled by our discovery, and its implications. So here we have LA, a molecule which is at the centre of those functions that go haywire in COVID-19 patients, with terrible consequences. And the virus that is causing all this chaos, according to our data, grabs and holds on to exactly this molecule – basically disarming much of the body's defences."
Professor Schaffitzel explained: "From other diseases we know that tinkering with LA metabolic pathways can trigger systemic inflammation, acute respiratory distress syndrome and pneumonia. These pathologies are all observed in patients suffering from severe COVID-19. A recent study of COVID-19 patients showed markedly reduced LA levels in their sera."
Professor Berger adds: "Our discovery provides the first direct link between LA, COVID-19 pathological manifestations and the virus itself. The question now is how to turn this new knowledge against the virus itself and defeat the pandemic."
There is reason for hope. In rhinovirus, a virus causing the common cold, a similar pocket was exploited to develop potent small molecules that bound tightly to the pocket distorting the structure of the rhinovirus, stopping its infectivity. These small molecules were successfully used as anti-viral drugs in human trials and show promise for treating rhinovirus clinically. The Bristol team, based on their data, is optimistic that a similar strategy can now be pursued to develop small molecule anti-viral drugs against SARS-CoV-2.
Professor Schaffitzel said: "COVID-19 continues to cause widespread devastation and in the absence of a proven vaccine, it is vital that we also look at other ways to combat the disease. If we look at HIV, after 30 years of research what worked in the end is a cocktail of small molecule anti-viral drugs that keeps the virus at bay. Our discovery of a druggable pocket within the SARS-CoV-2 Spike protein could lead to new anti-viral drugs to shut down and eliminate the virus before it entered human cells, stopping it firmly in its tracks."
Alison Derbenwick Miller, Vice President, Oracle for Research, added: "Oracle for Research unites researchers and cloud computing to help bring about beneficial change for our planet and its people. SARS-CoV-2 and COVID-19 are causing global devastation, and research efforts to find vaccines and treatments cannot move quickly enough. We are so pleased that Oracle's high-performance cloud infrastructure enabled Professors Berger and Schaffitzel to examine the molecular structures of the coronavirus spike protein and make this powerful and unexpected new discovery that could help curb the pandemic and save lives."
The team included experts from Bristol UNCOVER Group, Bristol biotech Imophoron Ltd, the Max Planck Institute for Biomedical Research in Heidelberg, Germany and Geneva Biotech Sàrl, Switzerland. The study was supported by funds from the Elizabeth Blackwell Institute with additional support from Oracle high-performance cloud computing and Genscript. We are very grateful to the University of Bristol's alumni and friends for their generous philanthropic support of this research.
'Free fatty acid binding pocket in the locked structure of SARS CoV-2 spike protein' by C Toelzer et al in Science
A webinar explaining the team's discovery of a druggable pocket in the SARS-CoV-2 Spike, is available on SelectScience.
About Professor Christiane Schaffitzel
Christiane Schaffitzel is also a Wellcome Trust Investigator and Academic Lead of the Wellcome Trust/BBSRC-funded GW4 Cryo-EM Facility at the University of Bristol.
About Professor Imre Berger
Imre Berger is also Director of BrisSynBio, a BBSRC/EPSRC Research Centre for Synthetic Biology in Bristol and a partner in the Wellcome Trust COVID-19 Protein Portal Consortium CPPC.
BrisSynBio is part of the Bristol BioDesign Institute.
University of Bristol collaborators on the project include: Professor Adrian Mulholland in the School of Chemistry, who worked on the molecular dynamics simulations and Dr Andrew Davidson, Reader in Systems Virology at Bristol, who in partnership with the team showed that LA works in synergy with the drug remdesivir to reduce virus replication, suggesting that supplementation of LA might be beneficial during treatment of SARS-CoV-2 infection.
In addition to Oracle cloud resources, this work used ARCHER (Advanced Research Computing High End Resource) High Performance Computing (HPC) through EPSRC, and the University of Bristol’s HPC resources.
About coronavirus (SARS-CoV-2)
The surface of the coronavirus particle has proteins sticking out of it known as Spike proteins which are embedded in a membrane. They have the appearance of tiny little crowns, giving the virus its name (corona). Inside the membrane is the viral genome wrapped up in other proteins. The genome contains all the genetic instruction to mass produce the virus. Once the virus attaches to the outside of a human cell, its membrane fuses with the human cell membrane and its genetic information into the human cell. Next, the virus instructs the cell to start replicating its genome and produce its proteins. These are then assembled into many new copies of the virus which, upon release, can infect many more cells. The viral proteins play diverse further roles in coronavirus pathology.
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In response to the COVID-19 crisis, researchers at the University of Bristol formed the Bristol COVID Emergency Research Group (UNCOVER) to pool resources, capacities and research efforts to combat this infection.
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For more information about the University of Bristol’s coronavirus (COVID-19) research priorities visit: www.bristol.ac.uk/research/impact/coronavirus/research-priorities/
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