Washington, DC – March 1, 2016 – A new study suggests that the Middle East Respiratory Syndrome coronavirus (MERS-CoV) develops mutations that make the virus less virulent during an outbreak rather than more virulent. The study, published this week in mBio, an online open-access journal of the American Society for Microbiology, has implications for vaccine development.
MERS-CoV causes severe respiratory infection and has a worldwide mortality rate of approximately 35%. Similar to other coronaviruses, MERS-CoV utilizes a large surface spike glycoprotein to enter human CD26 cells and cause infection.
From May to July 2015, a large outbreak of MERS initiated by an infected traveler from the Arabian Peninsula swept South Korea and resulted in 186 confirmed cases and 38 deaths. "The unexpected outbreak raised strong concerns about the possible generation of mutant viruses and prompted us to investigate the MERS viruses infecting Korean patients," said Nam Hyuk Cho, PhD, principal investigator of the new study and a faculty member at the Seoul National University College of Medicine in Korea.
In the new study, investigators isolated 13 new viral genomes from 14 infected patients with MERS treated during the outbreak. They found that 12 of the genomes had two specific point mutations (I529T and D510G mutations) in the receptor-binding domain (RBD) of the viral spike protein. Further analysis showed that the acquired mutations impaired viral fitness and virulence, rather than making the virus more virulent.
"Strikingly, both mutations resulted in reduced affinity of RBD to human CD26 compared to wild-type RBD," explained Dr. Cho. "This is an interesting strategy of coronavirus evolution to survive in nature and live together with the new host. The virus may tune down its power to attack for the sake of longer survival in the new host. The unexpected findings suggest that MERS-CoV adaptation during human-to-human spread may be driven by host immunological pressure such as neutralizing antibodies, resulting in reduced affinity to the host receptor."
Currently, most vaccine trials for MERS prevention are using the spike antigen to generate effective neutralizing antibodies against it. "Strategies for vaccine development also need to consider the chance of emergence of neutralizing antibody-escape mutants," said Dr. Cho. "Vaccines for MERS need to target the more stable and conserved region of the spike."
The American Society for Microbiology is the largest single life science society, composed of over 47,000 scientists and health professionals. ASM's mission is to promote and advance the microbial sciences.
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