posted on 2018-12-28, 00:00authored byChamnongsak
Ken Chanthamontri, David S. Jordan, Wenjie Wang, Chao Wu, Yanchun Lin, Tom J. Brett, Michael L. Gross, Daisy W. Leung
Members
of Mononegavirales, the order that includes nonsegmented
negative sense RNA viruses (NNSVs), encode a small number of multifunctional
proteins. In members of the Filoviridae family, virus protein 35 (VP35)
facilitates immune evasion and functions as an obligatory cofactor
for viral RNA synthesis. VP35 functions in a manner orthologous to
that of phosphoproteins from other NNSVs. Although the critical roles
of Ebola viral VP35 (eVP35) in immune evasion and RNA synthesis are
well-appreciated, a complete understanding of its organization and
its role in carrying out its many functions has yet to be fully realized.
In particular, we currently lack information about the role of the
oligomerization domain within eVP35. To address this limitation, we
report here an investigation of the oligomer structure of eVP35 using
hybrid methods that include multiangle light scattering, small-angle
X-ray scattering, and cross-linking coupled with mass spectrometry
to determine the shape and orientation of the eVP35 oligomer. Our
integrative results are consistent with a parallel tetramer in which
the N-terminal regions that are required for RNA synthesis are all
oriented in the same direction. Furthermore, these results define
a framework for targeting the symmetric tetramer for structure-based
antiviral discovery.