posted on 2018-11-29, 12:34authored bySergio
A. Poveda-Cuevas, Catherine Etchebest, Fernando L. Barroso da Silva
The flavivirus genus has several organisms responsible
for generating various diseases in humans. Recently, especially in
tropical regions, Zika virus (ZIKV) has raised great health concerns
due to the high number of cases affecting the area during the last
years that has been accompanied by a rise in the cases of the Guillain–Barré
syndrome and fetal and neonatal microcephaly. Diagnosis is still difficult
since the clinical symptoms between ZIKV and other flaviviruses (e.g.,
dengue and yellow fever) are highly similar. The understanding of
their common physicochemical properties that are pH-dependent and
biomolecular interaction features and their differences sheds light
on the relation strain-virulence and might suggest alternative strategies
toward differential serological diagnostics and therapeutic intervention.
Due to their immunogenicity, the primary focus of this study was on
the ZIKV nonstructural proteins 1 (NS1). By means of computational
studies and semiquantitative theoretical analyses, we calculated the
main physicochemical properties of this protein from different strains
that are directly responsible for the biomolecular interactions and,
therefore, can be related to the differential infectivity of the strains.
We also mapped the electrostatic differences at both the sequence
and structural levels for the strains from Uganda to Brazil, which
could suggest possible molecular mechanisms for the increase of the
virulence of ZIKV in Brazil. Exploring the interfaces used by NS1
to self-associate in some different oligomeric states and interact
with membranes and the antibody, we could map the strategy used by
the ZIKV during its evolutionary process. This indicates possible
molecular mechanisms that can be correlated with the different immunological
responses. By comparing with the known antibody structure available
for the West Nile virus, we demonstrated that this antibody would
have difficulties to neutralize the NS1 from the Brazilian strain.
The present study also opens up perspectives to computationally design
high-specificity antibodies.