Your search keyword '"Claes Örvell"' showing total 5 results

1. Functional Properties and Genetic Relatedness of the Fusion and Hemagglutinin-Neuraminidase Proteins of a Mumps Virus-Like Bat Virus

Author

Georg Herrler, Christian Sauder, Jan Felix Drexler, Markus Hoffmann, Steven A. Rubin, Biao He, Victor M. Corman, Christian Drosten, Nadine Krüger, Marcel A. Müller, and Claes Örvell

Subjects

Gene Expression Regulation, Viral, Signal peptide, Molecular Sequence Data, Immunology, Sequence Homology, Mumps virus, Antibodies, Viral, medicine.disease_cause, Giant Cells, Microbiology, Virus, Chiroptera, Virology, Chlorocebus aethiops, medicine, Animals, Humans, HN Protein, Vero Cells, DNA Primers, chemistry.chemical_classification, Base Sequence, biology, Sequence Analysis, DNA, Flow Cytometry, Molecular biology, Fusion protein, Virus-Cell Interactions, chemistry, Insect Science, biology.protein, Glycoprotein, Viral Fusion Proteins, Neuraminidase, Hemagglutinin-neuraminidase, HeLa Cells, Plasmids

Abstract

A bat virus with high phylogenetic relatedness to human mumps virus (MuV) was identified recently at the nucleic acid level. We analyzed the functional activities of the hemagglutinin-neuraminidase (HN) and the fusion (F) proteins of the bat virus (batMuV) and compared them to the respective proteins of a human isolate. Transfected cells expressing the F and HN proteins of batMuV were recognized by antibodies directed against these proteins of human MuV, indicating that both viruses are serologically related. Fusion, hemadsorption, and neuraminidase activities were demonstrated for batMuV, and either bat-derived protein could substitute for its human MuV counterpart in inducing syncytium formation when coexpressed in different mammalian cell lines, including chiropteran cells. Cells expressing batMuV glycoproteins were shown to have lower neuraminidase activity. The syncytia were smaller, and they were present in lower numbers than those observed after coexpression of the corresponding glycoproteins of a clinical isolate of MuV (hMuV). The phenotypic differences in the neuraminidase and fusion activity between the glycoproteins of batMuV and hMuV are explained by differences in the expression level of the HN and F proteins of the two viruses. In the case of the F protein, analysis of chimeric proteins revealed that the signal peptide of the bat MuV fusion protein is responsible for the lower surface expression. These results indicate that the surface glycoproteins of batMuV are serologically and functionally related to those of hMuV, raising the possibility of bats as a reservoir for interspecies transmission. IMPORTANCE The recently described MuV-like bat virus is unique among other recently identified human-like bat-associated viruses because of its high sequence homology (approximately 90% in most genes) to its human counterpart. Although it is not known if humans can be infected by batMuV, the antigenic relatedness between the bat and human forms of the virus suggests that humans carrying neutralizing antibodies against MuV are protected from infection by batMuV. The close functional relationship between MuV and batMuV is demonstrated by cooperation of the respective HN and F proteins to induce syncytium formation in heterologous expression studies. An interesting feature of the glycoproteins of batMuV is the downregulation of the fusion activity by the signal peptide of F, which has not been reported for other paramyxoviruses. These results are important contributions for risk assessment and for a better understanding of the replication strategy of batMuV.

Published

2015

2. Identification of Key Residues in Virulent Canine Distemper Virus Hemagglutinin That Control CD150/SLAM-Binding Activity

Author

Claes Örvell, Marc Vandevelde, Philippe Plattet, Andreas Zurbriggen, Ljerka Zipperle, and Johannes P. M. Langedijk

Subjects

Models, Molecular, Paramyxoviridae, Immunology, Hemagglutinins, Viral, Virus Attachment, Hemagglutinin (influenza), Receptors, Cell Surface, Plasma protein binding, Microbiology, Virus, Dogs, Signaling Lymphocytic Activation Molecule Family Member 1, Morbillivirus, Antigens, CD, Virology, Chlorocebus aethiops, medicine, Animals, Mononegavirales, Distemper Virus, Canine, Vero Cells, Host cell surface, biology, Canine distemper, biology.organism_classification, medicine.disease, Protein Structure, Tertiary, Virus-Cell Interactions, Insect Science, biology.protein, Receptors, Virus, Protein Binding

Abstract

Morbillivirus cell entry is controlled by hemagglutinin (H), an envelope-anchored viral glycoprotein determining interaction with multiple host cell surface receptors. Subsequent to virus-receptor attachment, H is thought to transduce a signal triggering the viral fusion glycoprotein, which in turn drives virus-cell fusion activity. Cell entry through the universal morbillivirus receptor CD150/SLAM was reported to depend on two nearby microdomains located within the hemagglutinin. Here, we provide evidence that three key residues in the virulent canine distemper virus A75/17 H protein (Y525, D526, and R529), clustering at the rim of a large recessed groove created by β-propeller blades 4 and 5, control SLAM-binding activity without drastically modulating protein surface expression or SLAM-independent F triggering.

Published

2010

3. The Nature of the N-Terminal Amino Acid Residue of HIV-1 RNase H Is Critical for the Stability of Reverse Transcriptase in Viral Particles

Author

Claes Örvell, Nikunj V. Somia, and Guney Boso

Subjects

Protein subunit, medicine.medical_treatment, viruses, Immunology, DNA Mutational Analysis, Ribonuclease H, Biology, Microbiology, RNase PH, Virology, Enzyme Stability, medicine, Humans, Amino Acids, RNase H, chemistry.chemical_classification, Protease, Virion, Molecular biology, Reverse transcriptase, HIV Reverse Transcriptase, Amino acid, Virus-Cell Interactions, NS2-3 protease, RNase MRP, Biochemistry, chemistry, Insect Science, Proteolysis, biology.protein, HIV-1

Abstract

Reverse transcriptase (RT) of human immunodeficiency virus type 1 (HIV-1) is synthesized and packaged into the virion as a part of the GagPol polyprotein. Mature RT is released by the action of viral protease. However, unlike other viral proteins, RT is subject to an internal cleavage event leading to the formation of two subunits in the virion: a p66 subunit and a p51 subunit that lacks the RNase H domain. We have previously identified RNase H to be an HIV-1 protein that has the potential to be a substrate for the N-end rule pathway, which is an ubiquitin-dependent proteolytic system in which the identity of the N-terminal amino acid determines the half-life of a protein. Here we examined the importance of the N-terminal amino acid residue of RNase H in the early life cycle of HIV-1. We show that changing this residue to an amino acid structurally different from the conserved residue leads to the degradation of RT and, in some cases, integrase in the virus particle and this abolishes infectivity. Using intravirion complementation and in vitro protease cleavage assays, we show that degradation of RT in RNase H N-terminal mutants occurs in the absence of active viral protease in the virion. Our results also indicate the importance of the RNase H N-terminal residue in the dimerization of RT subunits. IMPORTANCE HIV-1 proteins are initially made as part of a polyprotein that is cleaved by the viral protease into the proteins that form the virus particle. We were interested in one particular protein, RNase H, that is cleaved from reverse transcriptase. In particular, we found that the first amino acid of RNase H never varied in over 1,850 isolates of HIV-1 that we compared. When we changed the first amino acid, we found that the reverse transcriptase in the virus was degraded. While other studies have implied that the viral protease can degrade mutant RT proteins, we show here that this may not be the case for our mutants. Our results suggest that the presence of active viral protease is not required for the degradation of RT in RNase H N-terminal mutants, suggesting a role for a cellular protease in this process.

Published

2014

4. A subgroup-specific antigenic site in the G protein of respiratory syncytial virus forms a disulfide-bonded loop

Author

B. Åkerlind-Stopner, M. A. Mufson, Claes Örvell, G Utter, Richard A. Lerner, and Erling Norrby

Subjects

Antigenicity, Paramyxoviridae, Protein Conformation, medicine.drug_class, Molecular Sequence Data, Immunology, Enzyme-Linked Immunosorbent Assay, Peptide, Monoclonal antibody, Respirovirus Infections, Microbiology, Epitope, Epitopes, Mice, Viral Proteins, Protein structure, Viral Envelope Proteins, Virology, medicine, Animals, Humans, Amino Acid Sequence, Disulfides, Antigens, Viral, Peptide sequence, chemistry.chemical_classification, HN Protein, biology, Antibodies, Monoclonal, biology.organism_classification, Molecular biology, Respiratory Syncytial Viruses, Amino acid, chemistry, Insect Science, Chromosome Deletion, Peptides, Research Article

Abstract

An antigenic site (represented by 15 amino acids, residues 174 to 188, designated peptide 12) of the large glycoprotein G of respiratory syncytial virus was demonstrated to be subgroup specific in peptide enzyme-linked immunosorbent assay tests with murine monoclonal antibodies and human postinfection sera. The role of individual amino acids in this subgroup-specific site was determined by use of single-amino-acid-deletion sets of peptides. When monoclonal antibodies were reacted with the deletion sets, a broad amino acid dependence of 11 or 12 residues, Cys-176 (Ile-175 in subgroup B) to Cys-186, was found. Human postinfection sera exhibited a narrower reaction profile (for subgroup A, Cys-182 to Trp-183; for subgroup B, Cys-176 to Lys-183). Reduction of peptides on microtiter plates by treatment with dithiothreitol completely destroyed their antigenic activity in tests with monoclonal antibodies and human postinfection sera of subgroup B. A variant of peptide 12 containing all four cysteines of the G protein (represented by 16 amino acids, residues 172 to 187, designated peptide 12var) also was subgroup specific. We concluded that the activity of the antigenic site in tests with monoclonal antibodies for subgroups A and B appears to depend on intrapeptide disulfide bonds. Reactions with postinfection sera of subgroup B also may depend on a disulfide bond. In contrast, postinfection sera of subgroup A appeared to have the capacity to identify a subgroup-specific site in a linear form of the selected 15-amino-acid-long peptide. Treatment of peptides with dithiothreitol had no effect on their antigenic activity in tests with human postinfection sera of subgroup A. These findings have relevance for molecular engineering of peptide antigens for use in respiratory syncytial virus subgroup-specific site-directed serology.

Published

1990

5. Antigenic Structure of Human Respiratory Syncytial Virus Fusion Glycoprotein

Author

Claes Örvell, Blanca García-Barreno, Juan Antonio López, José A. Melero, Mabel Berois, Juan Arbiza, and Regla Bustos

Subjects

medicine.drug_class, Immunology, Biology, Monoclonal antibody, Antibodies, Viral, Microbiology, Virus, Epitope, Antigenic drift, Structure-Activity Relationship, Viral Proteins, Antigen, Viral Envelope Proteins, Neutralization Tests, Virology, Animal Viruses, medicine, Humans, HN Protein, Amino Acid Sequence, Peptide sequence, Antigens, Viral, Glycoproteins, chemistry.chemical_classification, Antibodies, Monoclonal, Molecular biology, chemistry, Mutagenesis, Insect Science, Respiratory Syncytial Virus, Human, Epitopes, B-Lymphocyte, Glycoprotein

Abstract

New series of escape mutants of human respiratory syncytial virus were prepared with monoclonal antibodies specific for the fusion (F) protein. Sequence changes selected in the escape mutants identified two new antigenic sites (V and VI) recognized by neutralizing antibodies and a group-specific site (I) in the F1 chain of the F molecule. The new epitopes, and previously identified antigenic sites, were incorporated into a refined prediction of secondary-structure motifs to generate a detailed antigenic map of the F glycoprotein.

Published

1998