Analysis of the structural proteins of rubella virus

Berkowitz, Cheryl Anne

January 1988

Complications of rubella virus infection, including congenital rubella syndrome and the association of rubella virus with joint inflammation, emphasize the need for continued research on rubella virus. The finding that the association of rubella virus infection with joint manifestations is more pronounced with wild strains than with vaccine strains suggested the possibility of strain variation. Several different techniques have been employed in order to compare six rubella virus strains and identify variations in their structural proteins. Differences in biological activities were detected, including the extent of virus production and the ability of various cell types to support replication of rubella virus (tissue tropism). However, the strains were shown to have remarkably similar electrophoretic patterns. Variation appeared to result from alterations in glycosylation. Efforts to isolate the protein components of the two envelope glycoproteins were unsuccessful, and it was therefore not possible to localize variation to either the protein or the carbohydrate components. Future work employing more sensitive methods for examination of fine molecular structure and the correlation of these structures with biological activity will further our understanding of the pathogenesis of rubella virus infection. / Medicine, Faculty of / Pathology and Laboratory Medicine, Department of / Graduate

Rubella virus

Proteins -- Analysis

Studies on the processing of rubella virus structural proteins by analysis of the endoproteolytic cleavage sites

McDonald, Helen L

January 1990

Rubella virus is a small enveloped positive strand RNA virus. Two species of viral RNA are found in infected cells: a full-length genomic RNA and a subgenomic species corresponding to the 3' one third of the genomic RNA molecule. The 24S subgenomic RNA specifies a polyprotein which is cotranslationally processed by endoproteolytic cleavage by host signal peptidase to yield three structural proteins, El, E2 and capsid. El and E2 are membrane glycoproteins forming the virion spikes, and C protein binds to 40S genomic RNA to form a nucleocapsid. El and E2 proteins contain N-linked oligosaccharide as a consequence of their passage through the endoplasmic reticulum (ER) and Golgi apparatus. According to the signal hypothesis, translocation of secretory and membrane proteins into the ER is mediated by a hydrophobic signal peptide. The signal peptides for E2 and El have been localized by in vivo expression of El and E2 cDNAs. Oligonucleotide-directed mutagenesis was used to define the cleavage sites between C, E2, and El, as well as the effect of the cleavages on the transport and processing of E2 and El. The expression of the cleavage site mutants was studied in vitro and in vivo. It was found that uncleaved precursor polypeptides were retained in the ER and very little E2 or El polypeptide was observed at either the Golgi apparatus or the plasma membrane. The E2 and El polypeptides can cross the ER membrane without the cleavage of the signal peptide while the transport of E2 and El beyond the ER requires the cleavage of E2 from C and El from E2. The C-termini of the C and E2 proteins, which were not previously defined, have been partially characterized. Capsid protein does not appear to undergo further proteolytic processing after it is cleaved from E2 by signal peptidase, but E2 may be processed at a second cleavage site at its C-terminus by a trypsin-like enzyme. / Medicine, Faculty of / Medical Genetics, Department of / Graduate

Rubella virus

Proteins -- Metabolism

Molecular cell biology of Rubella virus structural proteins

Hobman, Tom Cunningham

January 1989

Rubella virus (RV) is a small, enveloped, positive-stranded RNA virus in the family Togaviridae, and bears striking similarities to the prototype alphaviruses Semliki Forest virus (SFV) and Sindbis virus (SV) in terms of genome organization and structural protein expression strategy. However unlike alphaviruses, RV infection of cultured cells is characterized by relatively long latency periods, slow replication kinetics, limited cytopathology, and the ability to establish a persistent infection in virtually every cell line capable of supporting its growth. RV virions contain three structural proteins C, E2, and El which are derived by post-translational processing of a precursor polyprotein pllO (NF₂-C-E2-El-COOH). Processing and intracellular transport of RV structural proteins has been studied by jn vitro and jn vivo expression of RV cDNAs. It was found that targeting of El and E2 into the endoplasmic reticulum was mediated by two independently functioning signal peptides. Coincident with translocation into the ER, both proteins underwent addition of N-linked glycans and proteolytic processing. C protein did not appear to play a role in the processing of pllO. Expression of the RV structural proteins in COS cells revealed that E2 exited the ER, and was transported through the Golgi to the cell surface in an El-independent manner, although coexpression of El seemed to increase the rate of transport. Conversely, El was retained in a Golgi-like region and was not found on the plasma membrane in the absence of E2. Oligonucleotide-directed mutagenesis of El and E2 cDNAs showed that El andE2 both contain three N-linked glycans respectively. Lack of glycosylation did not appear to affect the intracellular localization of the RV glycoproteins in COS cells. A number of significant differences between RV and SFV/SV structural protein expression strategies were discovered, and their possible relationship to RV virion assembly are discussed. / Medicine, Faculty of / Medical Genetics, Department of / Graduate

Rubella virus

Proteins

Viral Proteins

Studies on rubella virus hemagglutinins the use of a cell line chronically infected with rubella.

Ortiz, Jesse Santana.

January 1970

Thesis (DR. P.H.)--University of Michigan.

Studies on rubella virus hemagglutinins the use of a cell line chronically infected with rubella.

Ortiz, Jesse Santana.

January 1970

Thesis (DR. P.H.)--University of Michigan.

Investigation of Interactions of the Rubella Virus P150 Replicase Protein with Host Cell Proteins in Infected Cells

Suppiah, Suganthi

15 April 2009

Due to their simplicity, viruses require the assistance of host factors for various aspects of their replication cycle. This study investigated the interaction of one of the two non-structural replicase proteins of rubella virus (RUBV), P150, with cell proteins. RUBV forms replication complexes for replicating its RNA in association with membranes of endosomes and lysosomes; the thusly modified endosomes/lysosomes are termed cytopathic vacuoles or CPVs. In the first study, a RUBV expressing a FLAG epitope-tagged P150 was used to co-immunoprecipitate putative interacting cell proteins from an infected cell lysate fraction enriched for CPVs using differential centrifugation. However, the only interacting protein identified was the companion RUBV replicase protein P90. Thus, cell proteins do not bind with either sufficient affinity or in stoichiometric amounts to be detected by this method and may not be a component of the virus holoenzyme. In the second study, a proline-rich region within P150 with three PxxPxR consensus SH3 domain-binding motifs was investigated for its ability to bind cell proteins. Substitution mutations (to alanine) of the two prolines were made in each of these motifs with the finding that mutations in the first two motifs led to lower viral titers and a small plaque phenotype with reversion to the wt sequence within one passage. Mutations in the third motif had a wt phenotype and did not revert. However, these mutations did not affect viral RNA synthesis, suggesting that the importance of these motifs is in a later stage of viral life cycle, e.g. virion assembly and release. To extend these findings, the proline hinge region with either the wt or mutant sequence was expressed as a GST-fusion in human cells. Pulldown experiments revealed specific binding with human p32 protein (gC1qR), which was previously shown to interact with the RUBV capsid protein. Binding of p32 with P150 was confirmed. The function of p32 in the RUBV replication cycle is unclear, but could involve virion assembly and release or induction of apoptosis.

Rubella virus

p32

Cytopathic vacuole

SH3 domain

Proteomics

Biology, general

The molecular evolution and epidemiology of Rubella virus

Cloete, Leendert J.

January 2014

>Magister Scientiae - MSc / Despite widespread rubella virus (RV) vaccination programs, annually RV still causes severe congenital defects in an estimated 100,000 children globally. A concerted attempt to eradicate RV is currently underway and analytical tools to monitor the global decline of the last remaining RV lineages will be useful for assessing the effectiveness of this endeavour. Importantly, RV evolves rapidly enough that much of its epidemiological information might be inferable from RV genomic sequence data. Using BEASTv1.8.0, I analysed publically available RV sequence data to estimate genome-wide and gene-specific nucleotide substitution rates, to test whether the current estimates of RV substitution rates are representative of the entire RV genome. During these investigations, I specifically accounted for possible confounders of nucleotide substitution rate estimates, such as temporally biased sampling, sporadic recombination, and natural selection favouring either increased or decreased genetic diversity (estimated by the PARRIS and FUBAR methods) at nucleotide sites within RV nucleic acid secondary structures (predicted by the NASP method). I determined that RV nucleotide substitution rates range from 1.19×10-3 substitutions/site/year (in the E1 region) to 7.52×10-4 substitutions/site/year (in the P150 region). I found that these differences between nucleotide substitution rate estimates in various RV gene regions are largely attributable to temporal sampling biases, such that datasets containing a higher proportion of recently sampled sequences will tend to have inflated estimates of mean substitution rates. Although there exists little evidence of positive selection or natural genetic recombination in RV, I revealed that RV genomes possess extensive biologically functional nucleic acid secondary structures and that purifying selection acting to maintain these structures contributes substantially to variations in estimated nucleotide substitution rates across RV genomes. Although both temporal sampling biases and purifying selection favouring the conservation of RV nucleic acid secondary structures have an appreciable impact on substitution rate estimates, I find that these biases do not preclude the use of RV sequence data to date ancestral sequences and evaluate the associated RV phylodynamics. The combination of uniformly high substitution rates across the RV genome and strong temporal signal within the available sequence data enabled me to analyse the epidemiological and demographical dynamics of this virus during these attempts to eradicate it. By implementing a generalized linear model (GLM) and symmetrical model of discretized phylogeographic spread, I was able to identify several predictive variables of geographical RV spread and detect transmission linkages between distinct geographical regions. These results suggest that, in addition to strengthened vaccination strategies, there also needs to be an increased effort to educate people about the effects of vaccination and risks of RV infection.

Congenital Rubella Syndrome

Rubella virus

Nucleic acid secondary structures

Exploring the Role of Calcium Ions in Biological Systems by Computational Prediction and Protein Engineering

Zhou, Yubin

28 November 2007

Ca2+, a signal for death and life, is closely involved in the regulation of numerous important cellular events. Ca2+ carries out its function through its binding to Ca2+-receptors or Ca2+-binding proteins. The EF-hand protein, with a helix-loop-helix Ca2+-binding motif, constitutes one of the largest protein families. To facilitate our understanding of the role of Ca2+ in biological systems (denoted as calciomics) using genomic information, an improved pattern search method (http://www.chemistry.gsu.edu/faculty/Yang/Calciomics.htm) for the identification of EF-hand and EF-like Ca2+-binding proteins was developed. This fast and robust method allows us to analyze putative EF-hand proteins at the genome-wide level and further visualize the evolutionary scenario of the EF-hand protein family. This prediction method further enables us to locate a putative viral EF-hand Ca2+-binding motif within the rubella virus nonstructural protease that cleaves the nonstructural protein precursor into two active replicase components. A novel grafting approach has been used to probe the metal-binding properties of this motif by engineering the predicted 12-residue Ca2+-coordinating loop into a non-Ca2+-binding scaffold protein, CD2 domain 1. Structural and conformational studies were further performed on a purified, bacterially-expressed NS protease minimal metal-binding domain spanning the Zn2+- and EF-hand Ca2+-binding motif. It was revealed that Ca2+ binding induced local conformational changes and increased thermal stability. Furthermore, functional studies were carried out using RUB infectious cDNA clone and replicon constructs. Our studies have shown that the Ca2+ binding loop played a structural role in the NS protease and was specifically required for optimal stability under physiological conditions. In addition, we have predicted and characterized a calmodulin-binding domain in the gap junction proteins connexin43 and connexin44. Peptides encompassing the CaM binding motifs were synthesized and their ability to bind CaM was determined using various biophysical approaches. Transient expression in HeLa cells of two mutant Cx43-EYFP constructs without the putative CaM-binding site eliminated the Ca2+-dependent inhibition of gap junction permeability. These results provide the first direct evidence that CaM binds to a specific region of the ubiquitous gap junction protein Cx43 and Cx44 in a Ca2+-dependent manner, providing a molecular basis for the well-characterized Ca2+-dependent inhibition of Cx43-containing gap junctions.

gap junction

connexin

CD2

prediction

calmodulin

EF-hand

pattern search

protein engineering

rubella virus

calcium

Chemistry

Cellular responses to Rubella virus infection of neural progenitors derived from human embryonic stem cells

Xu, Jie

18 December 2013

Rubella virus (RUBV) is a significant human pathogen. RUBV infection takes an enormous toll due to congenital rubella syndrome (CRS), a constellation of birth defects including blindness, hearing defects and mental retardation. Little is known about RUBV-induced teratogenesis due to the absence of useful models. This research is now enabled by the availability of human embryonic stem cells (hESCs) and hESC-derived precursor cell lines. Human neural progenitor cells (hNPCs) serve as a particularly relevant model due to the symptoms and complications of CRS related to neural system development. The overarching question addressed in this dissertation is: what is the mechanism underlying the development of neurological abnormalities seen in CRS? In this context, we investigated the cellular responses of hNPCs to RUBV infection comprehensively by: 1) assessing susceptibility of the cells to RUBV infection; 2) analyzing the effect of infection on cell proliferation; and 3) examining the impact of RUBV infection on differentiation of hNPCs into neuronal and astroglial lineages . We found that hNPCs are susceptible to RUBV infection and that the percentage of infected cells closely mimics CRS in which few cells harbor virus. The virus was able to persist in culture for up to one month without significant alteration of cell morphology and stemness marker expression. In addition, RUBV infection moderately attenuated the proliferation of undifferentiated hNPCs by triggering cell cycle arrest, but not apoptosis or other cell death events commonly seen upon virus infection. This lack of apoptosis appeared to be due in part to virus-induced anti-apoptotic suppression. Interestingly, the virus only had a marginal effect on the induction of cell differentiation into both neuronal and astroglial phenotypes. In fact, RUBV infection promoted terminal differentiation of the culture due to depletion of precursor cells. With differentiation, viral replication was suppressed. We thus propose a model for RUBV-induced neurological defects in which the virus acts by depleting precursor cell pools. The results of this study provide clues for elucidating the mechanisms of RUBV teratogenicity at the cellular level and serves as a potential reference study for elucidating mechanisms of teratogenesis induced by other infectious agents.

Rubella virus

Congenital rubella syndrome

Central nervous system

Brain

Stem cells

Neural progenitors

Cellular responses to Rubella virus infection of neural progenitors derived from human embryonic stem cells

Xu, Jie

18 December 2013

Rubella virus (RUBV) is a significant human pathogen. RUBV infection takes an enormous toll due to congenital rubella syndrome (CRS), a constellation of birth defects including blindness, hearing defects and mental retardation. Little is known about RUBV-induced teratogenesis due to the absence of useful models. This research is now enabled by the availability of human embryonic stem cells (hESCs) and hESC-derived precursor cell lines. Human neural progenitor cells (hNPCs) serve as a particularly relevant model due to the symptoms and complications of CRS related to neural system development. The overarching question addressed in this dissertation is: what is the mechanism underlying the development of neurological abnormalities seen in CRS? In this context, we investigated the cellular responses of hNPCs to RUBV infection comprehensively by: 1) assessing susceptibility of the cells to RUBV infection; 2) analyzing the effect of infection on cell proliferation; and 3) examining the impact of RUBV infection on differentiation of hNPCs into neuronal and astroglial lineages . We found that hNPCs are susceptible to RUBV infection and that the percentage of infected cells closely mimics CRS in which few cells harbor virus. The virus was able to persist in culture for up to one month without significant alteration of cell morphology and stemness marker expression. In addition, RUBV infection moderately attenuated the proliferation of undifferentiated hNPCs by triggering cell cycle arrest, but not apoptosis or other cell death events commonly seen upon virus infection. This lack of apoptosis appeared to be due in part to virus-induced anti-apoptotic suppression. Interestingly, the virus only had a marginal effect on the induction of cell differentiation into both neuronal and astroglial phenotypes. In fact, RUBV infection promoted terminal differentiation of the culture due to depletion of precursor cells. With differentiation, viral replication was suppressed. We thus propose a model for RUBV-induced neurological defects in which the virus acts by depleting precursor cell pools. The results of this study provide clues for elucidating the mechanisms of RUBV teratogenicity at the cellular level and serves as a potential reference study for elucidating mechanisms of teratogenesis induced by other infectious agents.

Rubella virus

Congenital rubella syndrome

Central nervous system

Brain

Stem cells

Neural progenitors