The SARS virus is capable of changing rapidly and unpredictably, which could present serious challenges for managing the disease and developing drugs and vaccines to combat it, research at the University of Michigan suggests. Ever since the SARS virus suddenly appeared in humans, scientists have been speculating about its origins and relationships to other, similar viruses. Using evolutionary analysis of protein sequences, the U-M researchers concluded that the SARS virus represents a different and previously little known lineage that has undergone some recombination, a process that can shuffle genes or gene regions among different viral lineages. This shuffling process provides genetic variation, which can help viruses survive and adapt in new hosts. The results appear in the September issue of the journal Infection, Genetics and Evolution. From University of Michigan:
SARS virus can change quickly and unpredictably, analysis indicates
ANN ARBOR, Mich.—The SARS virus is capable of changing rapidly and unpredictably, which could present serious challenges for managing the disease and developing drugs and vaccines to combat it, research at the University of Michigan suggests.
Ever since the SARS virus suddenly appeared in humans, scientists have been speculating about its origins and relationships to other, similar viruses. Using evolutionary analysis of protein sequences, the U-M researchers concluded that the SARS virus represents a different and previously little known lineage that has undergone some recombination, a process that can shuffle genes or gene regions among different viral lineages. This shuffling process provides genetic variation, which can help viruses survive and adapt in new hosts. The results appear in the September issue of the journal Infection, Genetics and Evolution.
The virus associated with SARS (known as SARS-CoV) is a type of coronavirus, so named because of the crown of spikes on its surface. Coronaviruses are divided into three categories: group one has been found in primates, carnivores and the group of animals that includes cattle, pigs and deer; group two occurs in that same group of animals as well as in rodents, birds and animals in the group that includes horses, tapirs and rhinos; group three has been found only in birds. Previous evolutionary analyses have suggested that the SARS virus is equally, but distantly, related to the three coronavirus groups.
Graduate student Joshua Rest and associate professor David Mindell, both of the U-M Department of Ecology and Evolutionary Biology, used a technique that detects recombination by analyzing the gene for a protein known as RNA dependent RNA polymerase (RDRP). In their analysis, one end of the RDRP gene appeared most closely related to group 3 coronaviruses, but the other end appeared distantly related to all three groups, suggesting that the RDRP gene in SARS-CoV had been cobbled together from parts of RDRP genes taken from different coronavirus lineages sometime in the past.
“Our results do not mean that human infection by SARS-CoV is linked to the particular recombination event for which we found evidence,” said Mindell. “But demonstration of recombination in the SARS-CoV lineages does indicate its potential for rapid, unpredictable evolutionary change, and this is a potentially important challenge for public health management and for drug and vaccine development.”