The researchers previously found that NS5 plays a similar interferon-blocking role for other members of the flavivirus family, most notably dengue virus and West Nile virus. The current study extends those findings to four other little-known viruses. Each virus appears to have evolved differently, they say, and uses a different NS5 mechanism to alter the host immune response. The researchers, including a group from NIH's National Institute of Allergy and Infectious Diseases, noted that one of the viruses they examined - Spondweni virus - has the potential to emerge as a human pathogen. Spondweni, a close relative of Zika virus, is spread by mosquitoes in sub-Saharan Africa and Southeast Asia.
With Zika virus, their study details how NS5 specifically inhibits human interferon responses by blocking the STAT2 protein, which is essential for signaling an interferon response. The researchers liken the interferon response to pulling a fire alarm to alert the immune response that a virus is nearby, but using NS5, Zika virus can silence the alarm and establish infection.
The scientists believe it may be possible to design a vaccine against Zika virus by using a live, weakened form of the virus made by altering the NS5 protein, though this concept is still far from being applied to a product. They also have shown with West Nile, yellow fever, and tick-borne encephalitis viruses that NS5 mutations weaken those viruses, which suggests that NS5 could be a vaccine target for those diseases as well.
A Grant et al. Zika virus targets human STAT2 to inhibit type I interferon signaling. Cell Host & Microbe DOI: 10.1016/j.chom.2016.05.009 (2016).
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