缅北强奸 researcher receives the Mitacs Award for outstanding innovation
As a protein engineer, Wei Zhang gives old molecules new tricks. And now, he鈥檚 transformed a single human protein into a virus-crushing arsenal that could lead to long-sought treatments for deadly infections.
On Tuesday, Zhang received the Mitacs Award for Outstanding Innovation for his work on creating molecular antidotes against viruses that cause Middle East Respiratory Syndrome (MERS) and Crimean-Congo Hemorrhagic Fever (Congo Fever). His patent-pending research was crucial to the launch of a new Toronto-based company called Ubiquitech, which will further commercialize his work so it can be used in a clinical setting.
As a postdoctoral researcher in Associate Professor Jason Moffat鈥檚 group at 缅北强奸's Donnelly Centre, Zhang already holds the competitive Elevate Fellowship from Mitacs, a nonprofit that supports innovation across the public and private sectors. The Mitacs fellowship enabled Zhang to start thinking about commercializing his research through a collaboration with the Centre for Commercialization of Antibodies and Biologics (CCAB), which is located at 缅北强奸.
鈥淲ei has done a phenomenal job of applying a cutting-edge new technology to the pressing issue of emerging pathogenic viruses. It鈥檚 a great example of how an investment by Canada in basic research and talented young scientists can lead to real impacts on human health,鈥 says Sachdev Sidhu, CEO of CCAB.
After completing a doctorate with Professor Daniel Durocher, Zhang joined Moffat and Sidhu鈥檚 labs to learn the ropes of protein engineering. The two teams had previously developed a powerful technology to quickly create synthetic proteins that could be used as research reagents, or developed further into drugs.
Although Zhang鈥檚 work revolves around a single protein, called ubiquitin, its applications are far-reaching. Named for its pervasive presence in every cell on earth, ubiquitin works by attaching to other proteins to help relay signals telling the cell to grow or fight infections, for example.
Encoded by genes, proteins do most of the work in the cell. They are built from amino acids, which are stitched together based on the DNA blueprint. Using molecular tricks, scientists can change how a protein behaves by changing its DNA sequence.
And so, through subtle tweaks, Zhang has turned a lone, naturally occurring ubiquitin into a set of tools鈥攕ynthetic ubiquitin variants (UbV)鈥攚hich allow him to manipulate the proteins that ubiquitin normally binds to. For example, a ubiquitin variant may spur the activity of the other protein, or it may take it out of action completely. But each variant has a unique target, allowing Zhang to control protein activity with unrivalled precision.
Being able to thwart a protein is particularly useful when dealing with harmful molecules, like those made by bacteria and viruses, for example.
鈥淯biquitin-dependent signalling is important in the immune response, and a lot of viruses encode proteins that bind human ubiquitin, which allows them to topple the body鈥檚 defence mechanism," says Zhang. One of them is MERS, a respiratory virus similar to SARS that caused a global epidemic in 2002. Fourteen years later, nothing has come out of clinical trials. While vaccines are being developed for many viruses, there is no treatment in sight for people who are infected.鈥
MERS emerged in Saudi Arabia in 2012, and it kills almost 40 per cent of those who become infected, making it even more dangerous than SARS. Zhang has engineered a ubiquitin variant which blocks MERS鈥 ability to evade the immune response.
鈥淲hen we treat the cells infected with MERS with the ubiquitin variant, we can kill the virus in two days,鈥 says Zhang.
The list of anti-viral ubiquitins could become long. Zhang has already created a variant that鈥檚 effective against Congo Fever virus, which causes internal bleeding and kills almost half of those infected. But what鈥檚 most exciting about Zhang鈥檚 approach is that it can be applied to any viral protein that binds ubiquitin.
鈥淲e are able to quickly 鈥 in less than one month 鈥 generate inhibitors for any ubiquitin-binding proteins in the virus,鈥 says Zhang. This means that Zhang鈥檚 work could also be applied to viruses such as SARS, Zika, and Ebola, as well as to preventing viral damage to food crops and animals.
鈥淲ei has fully captured the potential of protein engineering technology with his research," says Moffat. "He is poised to turn basic science into applications that could help people.鈥