Drug meant for Ebola may also work against coronaviruses
3D virus illustration (stock image). Credit: © dottedyeti / Adobe Stock
Drug meant for Ebola may also work against coronaviruses
Understanding how drugs work is an important step in developing new treatments for COVID-19
February 27, 2020
Science Daily/University of Alberta Faculty of Medicine & Dentistry
Researchers who have discovered why the drug remdesivir is effective in treating the coronaviruses that cause Middle East respiratory syndrome (MERS) and severe acute respiratory syndrome (SARS) expect it might also be effective for treating patients infected with the new COVID-19 strain.
A group of University of Alberta researchers who have discovered why the drug remdesivir is effective in treating the coronaviruses that cause Middle East respiratory syndrome (MERS) and severe acute respiratory syndrome (SARS) expect it might also be effective for treating patients infected with the new COVID-19 strain.
"Even if you know a drug works, it can be a red flag if you don't know how it works," said virologist Matthias Götte. "It is reassuring if you know exactly how it works against the target.
"We know the drug works against different coronaviruses, like MERS and SARS, and we know the novel coronavirus is very similar to SARS. So I would say I'm cautiously optimistic that the results our team found with remdesivir and MERS will be similar with COVID-19."
The study, published in the Journal of Biological Chemistry this week, is among the first in Canada to discuss the COVID-19 strain.
Until now, there has not been a published explanation of why remdesivir may work against coronaviruses, said Götte, who added his study is an important step in answering that question.
Developed by Gilead Sciences as a response to the 2014 West African Ebola virus epidemic, remdesivir was first used on a patient with the novel coronavirus earlier this year in the United States.
As reported in the New England Journal of Medicine, the patient was given the drug on the seventh day of illness, and showed marked improvement the following day, with symptoms eventually disappearing altogether. And at a recent press conference in Beijing, the assistant director-general of the World Health Organization, Bruce Alyward, said remdesivir is the only drug available that may have real efficacy against COVID-19.
"What our study showed was that remdesivir essentially mimics one of the natural building blocks for RNA synthesis necessary for genome replication of the virus. Enzymes within the virus are synthesizing the viral RNA genome with these building blocks, but they mix up the bits they need with the drug. Once the drug is incorporated into the growing RNA chain, the virus can no longer replicate,"explained Götte.
He said the next step is to wait for results from ongoing clinical trials with remdesivir, which are expected by the end of April. Even then, that won't be the end of the story, he cautioned.
"It's likely we'll need more than one drug to properly fight emerging diseases like COVID-19, as we have with HIV and hepatitis C virus infections," Götte said.
"Ideally, we will have a couple of drugs because certain strains could be resistant to certain treatments."
Götte's study was supported by grants from the Canadian Institutes of Health Research and the Alberta Ministry of Economic Development, Trade and Tourism through the Major Innovation Fund Program and Antimicrobial Resistance -- One Health Consortium.
https://www.sciencedaily.com/releases/2020/02/200227122123.htm
COVID-19 vaccine development
February 26, 2020
Science Daily/Hong Kong University of Science and Technology
Scientists have recently identified a set of potential vaccine targets for SARS-CoV-2 coronavirus, to guide experimental efforts towards vaccine development against novel pneumonia (COVID-19).
A team of scientists at the Hong Kong University of Science and Technology (HKUST) has recently made an important discovery in identifying a set of potential vaccine targets for the SARS-CoV-2 coronavirus, providing crucial leads for guiding experimental efforts towards the vaccine development against the novel pneumonia (COVID-19) caused by the virus.
Like SARS-CoV, which caused the SARS (Severe Acute Respiratory Syndrome) outbreak in 2003, SARS-CoV-2 belongs to the same Betacoronavirus genus. By considering the genetic similarity between SARS-CoV-2 and SARS-CoV, the team leveraged experimentally-determined immunological data to identify a set of SARS-CoV- derived B cell and T cell epitopes that exactly match to SARS-CoV-2. Epitopes are biomarkers recognized by the immune system to trigger actions against the virus. As no mutation has been observed in the identified epitopes among the available SARS-CoV-2 genetic sequences, immune targeting of these epitopes may potentially offer protection against the novel pneumonia COVID-19.
The team, led by data scientists Prof. Matthew McKay and Dr. Ahmed Abdul Quadeer, expected that their work can assist in guiding experimental research towards the development of effective vaccines against SARS- CoV-2.
Prof. McKay highlighted that "Despite similarities between SARS-CoV and SARS-CoV-2, there is genetic variation between the two, and it is not obvious if epitopes that elicit an immune response against SARS-CoV will likely be effective against SARS-CoV-2. We found that only roughly 20% of the SARS-CoV epitopes map identically to SARS-CoV-2, and believe these are promising candidates."
"For the identified T cell epitopes, we also performed a population coverage analysis and determined a set of epitopes that is estimated to provide broad coverage globally as well as in China" said Dr. Quadeer. The estimated population coverage represents the percentage of individuals within the selected population that are likely to elicit an immune response to at least one epitope from the identified set.
Prof. McKay is a Professor in the Departments of Electronic & Computer Engineering and Chemical & Biological Engineering; Dr. Quadeer is a post-doctoral fellow in the Department of Electronic & Computer Engineering. Their findings were recently published in the scientific journal Viruses this month.
"Our objective was to try to assist with the initial phase of vaccine development, by providing recommendations of specific epitopes that may potentially be considered for incorporation in vaccine designs" Prof. McKay added. "More generally, our work is part of a global effort seeking to capitalize on data for COVID-19, made available and rapidly shared by the scientific community, to understand this new virus and come up with effective interventions."
The beginning of 2020 has seen the emergence of SARS-CoV-2 outbreak in mainland China, which has quickly spread to over 30 countries around the world, infecting over 80,000 people and causing over 2,600 deaths as of late February 2020.
https://www.sciencedaily.com/releases/2020/02/200226091227.htm
Effectiveness of travel bans -- readily used during infectious disease outbreaks -- mostly unknown
February 13, 2020
Science Daily/University of Washington
While travel bans are frequently used to stop the spread of an emerging infectious disease, a new study of published research found that the effectiveness of travel bans is mostly unknown.
Because of the quick and deadly outbreak in late December of a novel coronavirus in Wuhan, China, now known as COVID-19 -- infecting tens of thousands and killing hundreds within weeks, while spreading to at least 24 other countries -- many governments, including the United States, have banned or significantly restricted travel to and from China.
And while travel bans are frequently used to stop the spread of an emerging infectious disease, a new University of Washington and Johns Hopkins University study of published research found that the effectiveness of travel bans is mostly unknown.
However, said lead author Nicole Errett, a lecturer in the UW Department of Environmental & Occupational Health Sciences in the School of Public Health, that's largely due to the fact that very little research into the effectiveness of travel bans exists.
"Some of the evidence suggests that a travel ban may delay the arrival of an infectious disease in a country by days or weeks. However, there is very little evidence to suggest that a travel ban eliminates the risk of the disease crossing borders in the long term," said Errett, co-director of the ColLABorative on Extreme Event Resilience, a research lab focused on addressing real-world issues relevant to community resilience.
The researchers combed through thousands of published articles in an effort to identify those that directly addressed travel bans used to reduce the geographic impact of the Ebola virus, SARS (Severe Acute Respiratory Syndrome), MERS (Middle East Respiratory Syndrome) and the Zika virus. They did not include studies of influenza viruses, for which travel bans have already been shown to be ineffective in the long term.
In the end, the researchers were able to identify just six studies that fit their criteria. Those six were based on models or simulations, not data from actual bans after they were implemented, to assess the effectiveness of travel bans in controlling outbreaks. Consequently, to improve research in this area, the study authors recommend that research questions, partnerships and study protocols be established ahead of the next outbreak so empirical data can be collected and assessed quickly.
"Travel bans are one of several legal options that governments have drawn on to mitigate a pandemic," said co-author Lainie Rutkow, a professor of health policy and management at Johns Hopkins Bloomberg School of Public Health. "As coronavirus spreads, our study raises the importance of understanding the effectiveness of legal and policy responses intended to protect and promote the public's health."
"When assessing the need for, and validity of, a travel ban, given the limited evidence, it's important to ask if it is the least restrictive measure that still protects the public's health, and even if it is, we should be asking that question repeatedly, and often," said co-author Lauren Sauer, an assistant professor of emergency medicine at Johns Hopkins University's School of Medicine and director of operations with the university's Office of Critical Event Preparedness and Response.
Consequently, the authors write, additional research is "urgently needed" to inform policy decisions, especially in light of the tremendous social, economic and political impacts of their implementation.
https://www.sciencedaily.com/releases/2020/02/200213175923.htm