Características de la estructura molecular de las proteínas E del virus del Zika y E1 del virus de la rubéola y posibles implicaciones en el neurotropismo y en las alteraciones del sistema nervioso / E-ZIKV and E1-RV proteins molecular structure and their potential implications in neurotropism and nervous system disorders

Resumen Introducción. El virus del Zika (ZIKV) es un flavivirus con envoltura, transmitido a los seres humanos principalmente por el vector Aedes aegypti. La infección por ZIKV se ha asociado con un gran neurotropismo y con efectos neuropáticos, como el síndrome de Guillain-Barré en el adulto y la microcefalia fetal y posnatal, así como con un síndrome de infección congénita similar al producido por el virus de la rubéola (RV). Objetivo. Comparar las estructuras moleculares de la proteína de envoltura E del virus del Zika (E-ZIKV) y de la E1 del virus de la rubéola (E1-RV), y plantear posibles implicaciones en el neurotropismo y en las alteraciones del sistema nervioso asociadas con el ZIKV. Materiales y métodos. La secuencia de aminoácidos de la proteína E-ZIKV (PDB: 5iZ7) se alineó con la de la glucopreteína E1 del virus de la rubéola (PDB: 4ADG). Los elementos de la estructura secundaria se determinaron usando los programas Vector NTI Advance®, DSSP y POSA, así como herramientas de gestión de datos (AlignX®). Uno de los criterios principales de comparación y alineación fue la asignación de residuos estructuralmente equivalentes, con más de 70 % de identidad. Resultados. La organización estructural de la proteína E-ZIKV (PDB: 5iZ7) fue similar a la de E1-RV (PDB: 4ADG) (70 a 80 % de identidad), y se observó una correspondencia con la estructura definida para las glucoproteínas de fusión de membrana de clase II de los virus con envoltura. E-ZIKV y E1-RV exhibieron elementos estructurales de fusión muy conservados en la región distal del dominio II, asociados con la unión a los receptores celulares de entrada del virus de la rubéola (glucoproteína de mielina del oligodendrocito, Myelin Oligodendrocyte Glycoprotein, MOG), y con los receptores celulares Axl del ZIKV y de otros flavivirus. Conclusión. La comparación de las proteínas E-ZIKV y E1-RV es un paso necesario hacia la definición de otros factores moleculares determinantes del neurotropismo y la patogenia del ZIKV, el cual puede contribuir a generar estrategias de diagnóstico, prevención y tratamiento de las complicaciones neurológicas inducidas por el ZIKV.

Abstract Introduction: Zika virus (ZIKV) is an enveloped flavivirus transmitted to humans mainly by Aedes aegypti. ZIKV infection has been associated with high neurotropism and neuropathic effects such as the Guillain-Barré syndrome in adults, and fetal and postnatal microcephaly and the congenital Zika virus syndrome similar to that produced by rubella virus (VR). Objective: To compare Zika virus membrane protein E (E-ZIKV) and rubella virus membrane protein E1 (E1-RV), and to propose possible implications for neurotropism and nervous system disorders associated with ZIKV infections. Materials and methods: The amino acid sequence of E-ZIKV protein (PDB: 5iZ7) was aligned to that of rubella virus glycoprotein E1 (PDB: 4ADG). The secondary structure elements were determined using the programs Vector NTI Advance®, DSSP, and POSA, and integrated data management tools (AlignX®). One of the main comparison and alignment criteria was the allocation of structurally equivalent residues with more than 70% identity. Results: E-ZIKV structural organization (PDB: 5iZ7) was similar to that of E1-RV (PDB: 4ADG) (70%-80% identity), and it was consistent with relevant structural features of viral membrane class II fusion glycoproteins. E-ZIKV and E1-RV exhibited highly conserved fusion structural elements at the distal region of domain II, which has been associated with the RV myelin oligodendrocyte glycoprotein and Axl cell receptors in ZIKV and other flaviviruses. Conclusion: The comparison of E-ZIKV and E1-RV proteins constitutes an essential step towards the definition of ZIKV neurotropism and pathogenesis molecular determinants, and for the adoption of diagnosis, prevention and treatment strategies against neurological complications induced by ZIKV infection.

From DCPD to NTCP: The long journey towards identifying a functional hepatitis B virus receptor

Hepatitis B virus (HBV) is the prototype of hepatotropic DNA viruses (hepadnaviruses) infecting a wide range of human and non-human hosts. Previous studies with duck hepatitis B virus (DHBV) identified duck carboxypeptidase D (dCPD) as a host specific binding partner for full-length large envelope protein, and p120 as a binding partner for several truncated versions of the large envelope protein. p120 is the P protein of duck glycine decarboxylase (dGLDC) with restricted expression in DHBV infectible tissues. Several lines of evidence suggest the importance of dCPD, and especially p120, in productive DHBV infection, although neither dCPD nor p120 cDNA could confer susceptibility to DHBV infection in any cell line. Recently, sodium taurocholate cotransporting polypeptide (NTCP) has been identified as a binding partner for the N-terminus of HBV large envelope protein. Importantly, knock down and reconstitution experiments unequivocally demonstrated that NTCP is both necessary and sufficient for in vitro infection by HBV and hepatitis delta virus (HDV), an RNA virus using HBV envelope proteins for its transmission. What remains unclear is whether NTCP is the major HBV receptor in vivo. The fact that some HBV patients are homozygous with an NTCP mutation known to abolish its receptor function suggests the existence of NTCP-independent pathways of HBV entry. Also, NTCP very likely mediates just one step of the HBV entry process, with additional co-factors for productive HBV infection still to be discovered. NTCP offers a novel therapeutic target for the control of chronic HBV infection.

Inflammatory response of endothelial cells to hepatitis C virus recombinant envelope glycoprotein 2 protein exposure

The hepatitis C virus (HCV) encodes approximately 10 different structural and non-structural proteins, including the envelope glycoprotein 2 (E2). HCV proteins, especially the envelope proteins, bind to cell receptors and can damage tissues. Endothelial inflammation is the most important determinant of fibrosis progression and, consequently, cirrhosis. The aim of this study was to evaluate and compare the inflammatory response of endothelial cells to two recombinant forms of the HCV E2 protein produced in different expression systems (Escherichia coli and Pichia pastoris). We observed the induction of cell death and the production of nitric oxide, hydrogen peroxide, interleukin-8 and vascular endothelial growth factor A in human umbilical vein endothelial cells (HUVECs) stimulated by the two recombinant E2 proteins. The E2-induced apoptosis of HUVECs was confirmed using the molecular marker PARP. The apoptosis rescue observed when the antioxidant N-acetylcysteine was used suggests that reactive oxygen species are involved in E2-induced apoptosis. We propose that these proteins are involved in the chronic inflammation caused by HCV.

Interaction between human cytomegalovirus UL136 protein and ATP1B1 protein

Interplay between the host and human cytomegalovirus (HCMV) has a pivotal role in the outcome of infection. A region (referred to as UL/b’) present in the Toledo strain of HCMV and low passage clinical isolates contains 19 additional genes, which are absent in the highly passaged laboratory strain AD169. Products of the UL/b’ genes may determine the manifestations of HCMV infection in vivo. However, little is known about the host factors, which interact with UL/b’ proteins. This study was conducted to investigate the function of the HCMV UL136 protein. By yeast two-hybrid screening, the β1 subunit of the host Na+/K+-ATPase (ATP1B1) was identified to be a candidate protein, which interacts with the HCMV UL136 protein. The interaction was further evaluated both in vitro by pull-down assay and in vivo by immunofluorescent co-localization. The results showed that the UL136 protein can interact with ATP1B1 in vitro. Co-localization of UL136-EGFP and ATP1B1-DsRed in cell membranes suggests that ATP1B1 was a partner of the UL136 protein. It can be proposed that the HCMV UL136 protein may have important roles in processes such as cell-to-cell spread, and in maintaining cell osmotic pressure and intracellular ion homeostasis during HCMV infection.

Kinetics of fusion with cells of reconstituted Sendai virus envelopes lacking hemagglutinin-neuraminidase.

The fusion potential of reconstituted Sendai virus envelopes containing only the F protein (F-virosomes) has been assessed. F-virosomes and F,HN-virosomes were prepared by solubilization of the intact virus in Triton X-100 followed by its removal using SM-2 biobeads. Viral envelopes containing HN whose disulphide bonds were irreversibly reduced (HNred) were also prepared by treating the envelopes with dithiothreitol followed by dialysis. Both F-virosomes and F,HNred-virosomes hemolysed red blood cells in the presence of wheat germ agglutinin. The rates and extent of hemolysis induced by these virosomes were, however, significantly lower than that induced by F,HN-virosomes. Using a fluorescence probe based membrane mixing fusion assay, F- and F,HNred-virosomes were found to fuse with cultured HeLa cells in the presence of wheat-germ agglutinin. A direct comparison of the fusion activity of F,HN-virosomes and F-virosomes was made by using desialylated HepG2 cells as target containing the asialoglycoprotein receptor (ASGP-R) that binds to a terminal beta-galactose moiety of F protein. A 2- to 3-fold enhancement in the fusion rate when HN was included in the viral envelope was observed. Based on the kinetic data, a model for fusion of paramyxo-virosomes with HepG2 cells is proposed.