Your search keyword '"Sandra G. P. van de Water"' showing total 14 results

1. A single vaccination with four-segmented rift valley fever virus prevents vertical transmission of the wild-type virus in pregnant ewes

Author

Paul J. Wichgers Schreur, Lucien van Keulen, Judith Oymans, Yves Dehon, Zoltan Penzes, Jet Kant, Anna Kollar, Sandra G. P. van de Water, Jeroen Kortekaas, and Pál Soós

Subjects

0301 basic medicine, 030231 tropical medicine, Immunology, Virulence, Diseases, Biology, Abortion, Microbiology, Article, 03 medical and health sciences, Medical research, 0302 clinical medicine, medicine, Life Science, Pharmacology (medical), Rift Valley fever, reproductive and urinary physiology, RC254-282, Host Pathogen Interaction & Diagnostics, Pharmacology, Pregnancy, Transmission (medicine), Bacteriologie, Outbreak, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Bacteriology, Bacteriology, Host Pathogen Interaction & Diagnostics, RC581-607, PE&RC, medicine.disease, Virology, Host Pathogen Interactie & Diagnostiek, Virology & Molecular Biology, Virologie & Moleculaire Biologie, Vaccination, 030104 developmental biology, Infectious Diseases, Bacteriologie, Host Pathogen Interactie & Diagnostiek, Flock, Immunologic diseases. Allergy, Biotechnology

Abstract

Rift Valley fever virus (RVFV) is a mosquito-transmitted bunyavirus that causes severe outbreaks among wild and domesticated ruminants, of which sheep are the most susceptible. Outbreaks are characterised by high mortality rates among new-born lambs and abortion storms, in which all pregnant ewes in a flock may abort their foetuses. In endemic areas, Rift Valley fever (RVF) can be controlled by vaccination with either inactivated or live-attenuated vaccines. Inactivated vaccines are safe for animals during all physiological stages, including pregnancy. However, optimal efficacy of these vaccines depends on multiple vaccinations and yearly re-vaccination. Live-attenuated vaccines are generally highly efficacious after a single vaccination, but currently available live-attenuated vaccines may transmit to the ovine foetus, resulting in stillbirths, congenital malformations or abortion. We have previously reported the development of a novel live-attenuated RVFV vaccine, named RVFV-4s. This vaccine virus was created by splitting the M genome segment and deleting the major virulence determinant NSs, and was shown to be safe even for the most susceptible species, including pregnant ewes. The demonstrated efficacy and safety profile suggests that RVFV-4s holds promise for veterinary and human application. The RVFV-4s vaccine for veterinary application, here referred to as vRVFV-4s, was shown to provide complete protection after a single vaccination of lambs, goats and cattle. In this work, we evaluated the efficacy of the vRVFV-4s vaccine in pregnant ewes. Anticipating on the extremely high susceptibility of pregnant ewes for RVFV, both a single vaccination and double vaccination were evaluated in two independent experiments. The combined results suggest that a single vaccination with vRVFV-4s is sufficient to protect pregnant ewes and to prevent transmission to the ovine foetus.

Published

2021

2. RNA elements in open reading frames of the bluetongue virus genome are essential for virus replication.

Author

Femke Feenstra, René G P van Gennip, Sandra G P van de Water, and Piet A van Rijn

Subjects

Medicine, Science

Abstract

Members of the Reoviridae family are non-enveloped multi-layered viruses with a double stranded RNA genome consisting of 9 to 12 genome segments. Bluetongue virus is the prototype orbivirus (family Reoviridae, genus Orbivirus), causing disease in ruminants, and is spread by Culicoides biting midges. Obviously, several steps in the Reoviridae family replication cycle require virus specific as well as segment specific recognition by viral proteins, but detailed processes in these interactions are still barely understood. Recently, we have shown that expression of NS3 and NS3a proteins encoded by genome segment 10 of bluetongue virus is not essential for virus replication. This gave us the unique opportunity to investigate the role of RNA sequences in the segment 10 open reading frame in virus replication, independent of its protein products. Reverse genetics was used to generate virus mutants with deletions in the open reading frame of segment 10. Although virus with a deletion between both start codons was not viable, deletions throughout the rest of the open reading frame led to the rescue of replicating virus. However, all bluetongue virus deletion mutants without functional protein expression of segment 10 contained inserts of RNA sequences originating from several viral genome segments. Subsequent studies showed that these RNA inserts act as RNA elements, needed for rescue and replication of virus. Functionality of the inserts is orientation-dependent but is independent from the position in segment 10. This study clearly shows that RNA in the open reading frame of Reoviridae members does not only encode proteins, but is also essential for virus replication.

Published

2014

3. Bluetongue virus nonstructural protein NS3/NS3a is not essential for virus replication.

Author

René G P van Gennip, Sandra G P van de Water, and Piet A van Rijn

Subjects

Medicine, Science

Abstract

Orbiviruses form the largest genus of the family Reoviridae consisting of at least 23 different virus species. One of these is the bluetongue virus (BTV) and causes severe hemorrhagic disease in ruminants, and is transmitted by bites of Culicoides midges. BTV is a non-enveloped virus which is released from infected cells by cell lysis and/or a unique budding process induced by nonstructural protein NS3/NS3a encoded by genome segment 10 (Seg-10). Presence of both NS3 and NS3a is highly conserved in Culicoides borne orbiviruses which is suggesting an essential role in virus replication. We used reverse genetics to generate BTV mutants to study the function of NS3/NS3a in virus replication. Initially, BTV with small insertions in Seg-10 showed no CPE but after several passages these BTV mutants reverted to CPE phenotype comparable to wtBTV, and NS3/NS3a expression returned by repair of the ORF. These results show that there is a strong selection for functional NS3/NS3a. To abolish NS3 and/or NS3a expression, Seg-10 with one or two mutated start codons (mutAUG1, mutAUG2 and mutAUG1+2) were used to generate BTV mutants. Surprisingly, all three BTV mutants were generated and the respective AUG(Met)→GCC(Ala) mutations were maintained. The lack of expression of NS3, NS3a, or both proteins was confirmed by westernblot analysis and immunostaining of infected cells with NS3/NS3a Mabs. Growth of mutAUG1 and mutAUG1+2 virus in BSR cells was retarded in both insect and mammalian cells, and particularly virus release from insect cells was strongly reduced. Our findings now enable research on the role of RNA sequences of Seg-10 independent of known gene products, and on the function of NS3/NS3a proteins in both types of cells as well as in the host and insect vector.

Published

2014

4. Vaccine efficacy of self-assembled multimeric protein scaffold particles displaying the glycoprotein Gn head domain of rift valley fever virus

Author

Jet Kant, Mirriam G.J. Tacken, Benjamin Gutjahr, Rebecca König, Markus Keller, Yanyin Lin, Paul J. Wichgers Schreur, Martin Eiden, Melanie Rissmann, Lucien van Keulen, Felicitas von Arnim, Alexander Brix, Catherine Charreyre, Jean Christophe Audonnet, Martin H. Groschup, Sandra G. P. van de Water, and Jeroen Kortekaas

Subjects

0301 basic medicine, sheep, Bacterial superglue, Protein subunit, Immunology, multimeric protein scaffold particles, lcsh:Medicine, Viremia, Lumazine synthase, Article, 03 medical and health sciences, 0302 clinical medicine, Antigen, In vivo, Drug Discovery, medicine, bacterial superglue, Pharmacology (medical), BIOS Plant Development Systems, Multimeric protein scaffold particles, Host Pathogen Interaction & Diagnostics, Pharmacology, chemistry.chemical_classification, Sheep, biology, Gn head domain, Immunogenicity, Bacteriologie, lcsh:R, Bacteriology, Bacteriology, Host Pathogen Interaction & Diagnostics, PE&RC, medicine.disease, Rift Valley fever virus, Virology, Host Pathogen Interactie & Diagnostiek, Virology & Molecular Biology, Virologie & Moleculaire Biologie, 030104 developmental biology, Infectious Diseases, chemistry, 030220 oncology & carcinogenesis, Bacteriologie, Host Pathogen Interactie & Diagnostiek, biology.protein, Antibody, Glycoprotein

Abstract

Compared to free antigens, antigens immobilized on scaffolds, such as nanoparticles, generally show improved immunogenicity. Conventionally, antigens are conjugated to scaffolds through genetic fusion or chemical conjugation, which may result in impaired assembly or heterogeneous binding and orientation of the antigens. By combining two emerging technologies—i.e., self-assembling multimeric protein scaffold particles (MPSPs) and bacterial superglue—these shortcomings can be overcome and antigens can be bound on particles in their native conformation. In the present work, we assessed whether this technology could improve the immunogenicity of a candidate subunit vaccine against the zoonotic Rift Valley fever virus (RVFV). For this, the head domain of glycoprotein Gn, a known target of neutralizing antibodies, was coupled on various MPSPs to further assess immunogenicity and efficacy in vivo. The results showed that the Gn head domain, when bound to the lumazine synthase-based MPSP, reduced mortality in a lethal mouse model and protected lambs, the most susceptible RVFV target animals, from viremia and clinical signs after immunization. Furthermore, the same subunit coupled to two other MPSPs (Geobacillus stearothermophilus E2 or a modified KDPG Aldolase) provided full protection in lambs as well.

Published

2021

5. Safety and efficacy of four-segmented Rift Valley fever virus in young sheep, goats and cattle

Author

Nadia Oreshkova, Paul J. Wichgers Schreur, Zoltan Penzes, Jet Kant, Lucien van Keulen, Anna Kollar, Sandra G. P. van de Water, Jeroen Kortekaas, Yves Dehon, and Pál Soós

Subjects

0301 basic medicine, lcsh:Immunologic diseases. Allergy, Rift Valley fever virus, 030231 tropical medicine, Immunology, Virulence, Biology, Genome, lcsh:RC254-282, Article, 03 medical and health sciences, 0302 clinical medicine, Virology, Homologous chromosome, Life Science, Pharmacology (medical), Host Pathogen Interaction & Diagnostics, Pharmacology, chemistry.chemical_classification, Vaccines, Bacteriologie, Outbreak, RNA, Bacteriology, Bacteriology, Host Pathogen Interaction & Diagnostics, PE&RC, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Host Pathogen Interactie & Diagnostiek, Virology & Molecular Biology, Virologie & Moleculaire Biologie, Vaccination, 030104 developmental biology, chemistry, Bacteriologie, Host Pathogen Interactie & Diagnostiek, Infectious diseases, Glycoprotein, lcsh:RC581-607

Abstract

Rift Valley fever virus (RVFV) is a mosquito-borne bunyavirus that causes severe and recurrent outbreaks on the African continent and the Arabian Peninsula and continues to expand its habitat. RVFV induces severe disease in newborns and abortion in pregnant ruminants. The viral genome consists of a small (S), medium (M) and large (L) RNA segment of negative polarity. The M segment encodes a glycoprotein precursor protein that is co-translationally cleaved into the two structural glycoproteins Gn and Gc, which are involved in receptor attachment and cell entry. We previously constructed a four-segmented RVFV (RVFV-4s) by splitting the M genome segment into two M-type segments encoding either Gn or Gc. RVFV-4s replicates efficiently in cell culture but was shown to be completely avirulent in mice, lambs and pregnant ewes. Here, we show that a RVFV-4s candidate vaccine for veterinary use (vRVFV-4s) does not disseminate in vaccinated animals, is not shed or spread to the environment and does not revert to virulence. Furthermore, a single vaccination of lambs, goat kids and calves was shown to induce protective immunity against a homologous challenge. Finally, the vaccine was shown to provide full protection against a genetically distinct RVFV strain. Altogether, we demonstrate that vRVFV-4s optimally combines efficacy with safety, holding great promise as a next-generation RVF vaccine.

Published

2020

6. Multimeric single-domain antibody complexes protect against bunyavirus infections

Author

Frank Grosveld, Sara Rodriguez Conde, Paul J. Wichgers Schreur, Dorota Kozub, Jan Hellert, Kieran K Mistry, Erick Bermúdez-Méndez, Martin Beer, Pablo Guardado-Calvo, Félix A. Rey, Karen Brennan, Ziyan Deng, Michiel M. Harmsen, Olalekan Daramola, Sandra G. P. van de Water, Jeroen Kortekaas, Dubravka Drabek, Maiken Søndergaard Kristiansen, Andrea Aebischer, Lucien van Keulen, Kerstin Wernike, Wageningen BioVeterinary Research, Wageningen University and Research [Wageningen] (WUR), Erasmus University Medical Center [Rotterdam] (Erasmus MC), Harbour Antibodies B.V, Institute of Diagnostic Virology (IVD), Friedrich-Loeffler-Institut (FLI), AstraZeneca [Cambridge, UK], Virologie Structurale - Structural Virology, Institut Pasteur [Paris]-Centre National de la Recherche Scientifique (CNRS), Innovative Medicines Initiative (ZAPI (grant agreement no. 115760))Ministerio de Ciencia Tecnología y Telecomunicaciones (Student Fellowship (PEM-066-2015-II))Universidad de Costa Rica (Student Fellowship (OAICE-CAB-05-56-2016)), European Project: 115760,EC:FP7:SP1-JTI,IMI-JU-11-2013,ZAPI(2015), Cell biology, and Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Male, 0301 basic medicine, Rift Valley fever virus, Laboratory of Virology, bunyavirus, MESH: Antibodies, Neutralizing, Mice, schmallenberg virus, MESH: Animals, Biology (General), Microbiology and Infectious Disease, biology, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], General Neuroscience, Bacteriologie, Schmallenberg virus, Bacteriology, Host Pathogen Interaction & Diagnostics, General Medicine, PE&RC, Virology & Molecular Biology, 3. Good health, MESH: Camelids, New World, Medicine, Female, Antibody, Camelids, New World, Research Article, MESH: Antiviral Agents, QH301-705.5, Science, infectious disease, 030106 microbiology, virus, Bunyaviridae Infections, Antiviral Agents, MESH: Single-Domain Antibodies, General Biochemistry, Genetics and Molecular Biology, Virus, World health, Laboratorium voor Virologie, MESH: Bunyaviridae Infections, 03 medical and health sciences, Emerging pathogen, SDG 3 - Good Health and Well-being, Animals, Humans, Life Science, MESH: Mice, single-domain antibody, Host Pathogen Interaction & Diagnostics, therapy, MESH: Humans, General Immunology and Microbiology, microbiology, vhh, Bacteriology, Single-Domain Antibodies, biology.organism_classification, Antibodies, Neutralizing, Virology, Host Pathogen Interactie & Diagnostiek, MESH: Male, Virologie & Moleculaire Biologie, 030104 developmental biology, Single-domain antibody, Infectious disease (medical specialty), Bacteriologie, Host Pathogen Interactie & Diagnostiek, biology.protein, MESH: Female, rift valley fever virus

Abstract

International audience; The World Health Organization has included three bunyaviruses posing an increasing threat to human health on the Blueprint list of viruses likely to cause major epidemics and for which no, or insufficient countermeasures exist. Here, we describe a broadly applicable strategy, based on llama-derived single-domain antibodies (VHHs), for the development of bunyavirus biotherapeutics. The method was validated using the zoonotic Rift Valley fever virus (RVFV) and Schmallenberg virus (SBV), an emerging pathogen of ruminants, as model pathogens. VHH building blocks were assembled into highly potent neutralizing complexes using bacterial superglue technology. The multimeric complexes were shown to reduce and prevent virus-induced morbidity and mortality in mice upon prophylactic administration. Bispecific molecules engineered to present two different VHHs fused to an Fc domain were further shown to be effective upon therapeutic administration. The presented VHH-based technology holds great promise for the development of bunyavirus antiviral therapies.

Published

2020

7. Author response: Multimeric single-domain antibody complexes protect against bunyavirus infections

Author

Ziyan Deng, Kerstin Wernike, Dorota Kozub, Sandra G. P. van de Water, Frank Grosveld, Pablo Guardado-Calvo, Jeroen Kortekaas, Sara Rodriguez Conde, Andrea Aebischer, Paul J. Wichgers Schreur, Jan Hellert, Kieran K Mistry, Olalekan Daramola, Martin Beer, Félix A. Rey, Karen Brennan, Erick Bermúdez-Méndez, Dubravka Drabek, Lucien van Keulen, M.M. Harmsen, and Maiken Søndergaard Kristiansen

Subjects

Single-domain antibody, Chemistry, Virology

Published

2020

8. Bluetongue viruses based on modified-live vaccine serotype 6 with exchanged outer shell proteins confer full protection in sheep against virulent BTV8.

Author

René G P van Gennip, Sandra G P van de Water, Mieke Maris-Veldhuis, and Piet A van Rijn

Subjects

Medicine, Science

Abstract

Since 1998, Bluetongue virus (BTV)-serotypes 1, 2, 4, 9, and 16 have invaded European countries around the Mediterranean Basin. In 2006, a huge BT outbreak started after incursion of BTV serotype 8 (BTV8) in North-Western Europe. IN 2008, BTV6 and BTV11 were reported in the Netherlands and Germany, and in Belgium, respectively. In addition, Toggenburg orbivirus (TOV) was detected in 2008 in Swiss goats, which was recognized as a new serotype of BTV (BTV25). The (re-)emergency of BTV serotypes needs a rapid response to supply effective vaccines. Reverse genetics has been developed for BTV1 and more recently also for BTV6. This latter strain, BTV6/net08, is closely related to live-attenuated vaccine for serotype 6 as determined by full genome sequencing. Here, we used this strain as backbone and exchanged segment 2 and 6, respectively Seg-2 (VP2) and Seg-6 (VP5), for those of BTV serotype 1 and 8 using reverse genetics. These so-called 'serotyped' vaccine viruses, as mono-serotype and multi-serotype vaccine, were compared for their protective capacity in sheep. In general, all vaccinated animals developed a neutralizing antibody response against their respective serotype. After challenge at three weeks post vaccination with cell-passaged, virulent BTV8/net07 (BTV8/net07/e1/bhkp3) the vaccinated animals showed nearly no clinical reaction. Even more, challenge virus could not be detected, and seroconversion or boostering after challenge was negligible. These data demonstrate that all sheep were protected from a challenge with BTV8/net07, since sheep of the control group showed viremia, seroconversion and clinical signs that are specific for Bluetongue. The high level of cross-protection is discussed.

Published

2012

9. Rescue of recent virulent and avirulent field strains of bluetongue virus by reverse genetics.

Author

René G P van Gennip, Sandra G P van de Water, Christiaan A Potgieter, Isabel M Wright, Daniel Veldman, and Piet A van Rijn

Subjects

Medicine, Science

Abstract

Since 1998, Bluetongue virus (BTV)-serotypes 1, 2, 4, 9, and 16 have invaded European countries around the Mediterranean Basin. In 2006, a huge BT-outbreak started after incursion of BTV-serotype 8 (BTV8) in North-Western Europe. More recently, BTV6 and BTV11 were reported in North-Western Europe in 2008. These latter strains are closely related to live-attenuated vaccine, whereas BTV8 is virulent and can induce severe disease in ruminants, including cattle. In addition, Toggenburg orbivirus (TOV) was detected in 2008 in Swiss goats, which was recognized as a new serotype of BTV (BTV25). The (re-)emergency of known and unknown BTV-serotypes needs a rapid response to supply effective vaccines, and research to study this phenomenon. Recently, orbivirus research achieved an important breakthrough by the establishment of reverse genetics for BTV1. Here, reverse genetics for two recent BTV strains representing virulent BTV8 and avirulent BTV6 was developed. For this purpose, extensive sequencing of full-genomes was performed, resulting in the consensus sequences of BTV8/net07 and BTV6/net08. The recovery of 'synthetic BTV', respectively rgBTV8 and rgBTV6, completely from T7-derived RNA transcripts was confirmed by silent mutations by which these 'synthetic BTVs' could be genetically distinguished from wild type BTV, respectively wtBTV6 and wtBTV8. The in vitro and in vivo properties of rgBTV6 or rgBTV8 were comparable to the properties of their parent strains. The asymptomatic or avirulent properties of rgBTV6 and the virulence of rgBTV8 were confirmed by experimental infection of sheep. Reverse genetics of the vaccine-related BTV6 provides a perfect start to develop new generations of BT-vaccines. Reverse genetics of the virulent BTV8 will accelerate research on the special features of BTV8, like transmission by species of Culicoides in a moderate climate, transplacental transmission, and pathogenesis in cattle.

Published

2012

10. Structural protein VP2 of African horse sickness virus is not essential for virus replication in vitro

Author

René G. P. van Gennip, Piet A. van Rijn, Sandra G. P. van de Water, and Christiaan A. Potgieter

Subjects

Gene Expression Regulation, Viral, 0301 basic medicine, Virus replication, Transcription, Genetic, Viral protein, viruses, Immunology, Gene Expression, Reoviridae, Genome, Viral, Reovirus, Serogroup, medicine.disease_cause, Microbiology, Virus, Structural protein VP2, Mice, 03 medical and health sciences, African Horse Sickness, Cricetinae, Virology, African Horse Sickness Virus, medicine, Animals, Horses, Orbivirus, Virus Release, RNA, Double-Stranded, Sequence Deletion, biology, AHSV, Epizootic hemorrhagic disease virus, biology.organism_classification, Virus-Cell Interactions, Virology & Molecular Biology, Virologie & Moleculaire Biologie, Phenotype, 030104 developmental biology, Viral replication, Reverse genetics, Insect Science, Mutation, RNA, Viral, African horse sickness, Capsid Proteins

Abstract

The Reoviridae family consists of nonenveloped multilayered viruses with a double-stranded RNA genome consisting of 9 to 12 genome segments. The Orbivirus genus of the Reoviridae family contains African horse sickness virus (AHSV), bluetongue virus, and epizootic hemorrhagic disease virus, which cause notifiable diseases and are spread by biting Culicoides species. Here, we used reverse genetics for AHSV to study the role of outer capsid protein VP2, encoded by genome segment 2 (Seg-2). Expansion of a previously found deletion in Seg-2 indicates that structural protein VP2 of AHSV is not essential for virus replication in vitro . In addition, in-frame replacement of RNA sequences in Seg-2 by that of green fluorescence protein (GFP) resulted in AHSV expressing GFP, which further confirmed that VP2 is not essential for virus replication. In contrast to virus replication without VP2 expression in mammalian cells, virus replication in insect cells was strongly reduced, and virus release from insect cells was completely abolished. Further, the other outer capsid protein, VP5, was not copurified with virions for virus mutants without VP2 expression. AHSV without VP5 expression, however, could not be recovered, indicating that outer capsid protein VP5 is essential for virus replication in vitro . Our results demonstrate for the first time that a structural viral protein is not essential for orbivirus replication in vitro , which opens new possibilities for research on other members of the Reoviridae family. IMPORTANCE Members of the Reoviridae family cause major health problems worldwide, ranging from lethal diarrhea caused by rotavirus in humans to economic losses in livestock production caused by different orbiviruses. The Orbivirus genus contains many virus species, of which bluetongue virus, epizootic hemorrhagic disease virus, and African horse sickness virus (AHSV) cause notifiable diseases according to the World Organization of Animal Health. Recently, it has been shown that nonstructural proteins NS3/NS3a and NS4 are not essential for virus replication in vitro , whereas it is generally assumed that structural proteins VP1 to -7 of these nonenveloped, architecturally complex virus particles are essential. Here we demonstrate for the first time that structural protein VP2 of AHSV is not essential for virus replication in vitro . Our findings are very important for virologists working in the field of nonenveloped viruses, in particular reoviruses.

Published

2017

11. Requirements and comparative analysis of reverse genetics for bluetongue virus (BTV) and African horse sickness virus (AHSV)

Author

René G. P. van Gennip, Piet A. van Rijn, Sandra G. P. van de Water, and Femke Feenstra

Subjects

0301 basic medicine, viruses, 030106 microbiology, dsRNA, Genome, Viral, Biology, Reoviridae, Bluetongue, Virus, 03 medical and health sciences, Plasmid, Reassortment, African Horse Sickness, Virology, African Horse Sickness Virus, Animals, Horses, Orbivirus, 2. Zero hunger, Genetics, Expression vector, Methodology, RNA, Ruminants, biology.organism_classification, Reverse Genetics, Reverse genetics, Virology & Molecular Biology, Virologie & Moleculaire Biologie, RNA silencing, 030104 developmental biology, Infectious Diseases, Genetic modification, RNA, Viral, African horse sickness, African horse sickness virus, Bluetongue virus, Plasmids

Abstract

Background: Bluetongue virus (BTV) and African horse sickness virus (AHSV) are distinct arthropod borne virus species in the genus Orbivirus (Reoviridae family), causing the notifiable diseases Bluetongue and African horse sickness of ruminants and equids, respectively. Reverse genetics systems for these orbiviruses with their ten-segmented genome of double stranded RNA have been developed. Initially, two subsequent transfections of in vitro synthesized capped run-off RNA transcripts resulted in the recovery of BTV. Reverse genetics has been improved by transfection of expression plasmids followed by transfection of ten RNA transcripts. Recovery of AHSV was further improved by use of expression plasmids containing optimized open reading frames. Results: Plasmids containing full length cDNA of the 10 genome segments for T7 promoter-driven production of full length run-off RNA transcripts and expression plasmids with optimized open reading frames (ORFs) were used. BTV and AHSV were rescued using reverse genetics. The requirement of each expression plasmid and capping of RNA transcripts for reverse genetics were studied and compared for BTV and AHSV. BTV was recovered by transfection of VP1 and NS2 expression plasmids followed by transfection of a set of ten capped RNAs. VP3 expression plasmid was also required if uncapped RNAs were transfected. Recovery of AHSV required transfection of VP1, VP3 and NS2 expression plasmids followed by transfection of capped RNA transcripts. Plasmid-driven expression of VP4, 6 and 7 was also needed when uncapped RNA transcripts were used. Irrespective of capping of RNA transcripts, NS1 expression plasmid was not needed for recovery, although NS1 protein is essential for virus propagation. Improvement of reverse genetics for AHSV was clearly demonstrated by rescue of several mutants and reassortants that were not rescued with previous methods. Conclusions: A limited number of expression plasmids is required for rescue of BTV or AHSV using reverse genetics, making the system much more versatile and generally applicable. Optimization of reverse genetics enlarge the possibilities to rescue virus mutants and reassortants, and will greatly benefit the control of these important diseases of livestock and companion animals.

Published

2016

12. Experimental infection of small ruminants with bluetongue virus expressing Toggenburg Orbivirus proteins

Author

René G. P. van Gennip, Mieke A. Maris-Veldhuis, Piet A. van Rijn, and Sandra G. P. van de Water

Subjects

0301 basic medicine, Serotype, Gene Expression Regulation, Viral, 040301 veterinary sciences, viruses, Reoviridae, Viremia, Serogroup, Microbiology, Bluetongue, Neutralization, Virus, Cell Line, 0403 veterinary science, 03 medical and health sciences, Viral Proteins, Cricetinae, medicine, Animals, Seroconversion, Experimental infection, Orbivirus, Goat Diseases, Sheep, General Veterinary, biology, Goats, 04 agricultural and veterinary sciences, General Medicine, biology.organism_classification, Culicoides, medicine.disease, veterinary(all), Virology, Virology & Molecular Biology, Virologie & Moleculaire Biologie, 030104 developmental biology, Reverse genetics, Goat, Toggenburg Orbivirus, Protein expression, Bluetongue virus

Abstract

Bluetongue virus (BTV) is the prototype orbivirus (Reoviridae family, genus Orbivirus) consisting of more than 24 recognized serotypes or neutralization groups. Recently, new BTV serotypes in goats have been found; serotype 25 (Toggenburg Orbivirusor TOV), serotype 26 (KUW2010/02), and serotype 27 from Corsica, France. KUW2010/02 has been isolated in mammalian cells but is not replicating in Culicoides cells. TOVhas been detected in goats but could not been cultured, although TOV has been successfully passed to naïve animals by experimental infection using viremic blood. Genome segments Seg-2[VP2], Seg-6[VP5], Seg-7[VP7], and Seg-10[NS3/NS3a] expressing the respective TOV proteins were incorporated in BTV using reverse genetics, demonstrating that these TOV proteins are functional in BTV replication. Depending on the incorporated TOV proteins, in vitro replication is, however, decreased compared to the ancestor BTV, in particular by TOV-VP5. Sheep and goats were experimentally infected with BTV expressing both outer capsid proteins VP2 and VP5 of TOV, so-named ‘TOV-serotyped BTV’. Viremia was not detected in sheep, and hardly detected in goats after infection with TOV-serotyped BTV. Seroconversion by cELISA, however, was detected, suggesting that TOV-serotyped BTV replicates in small ruminants. One goat was coincidentally pregnant, and the fetus was strong PCR-positive in blood samples and several organs, which conclusively demonstrates that TOV-serotyped BTV replicates in vivo.

Published

2016

13. Rescue of recent virulent and avirulent field strains of bluetongue virus by reverse genetics

Author

Christiaan A. Potgieter, Isabel M. Wright, René G. P. van Gennip, Daniel Veldman, Sandra G. P. van de Water, and Piet A. van Rijn

Subjects

Serotype, lcsh:Medicine, netherlands, release, epidemic, lcsh:Science, Genetics, Multidisciplinary, Orbivirus, biology, Virulence, Genomics, Culicoides, Virology & Molecular Biology, Veterinary Diseases, europe, Genetic Engineering, Research Article, Biotechnology, Genetic Markers, Veterinary Medicine, replication, Transplacental transmission, Sequence analysis, Molecular Sequence Data, Genome, Viral, Bluetongue, Virus, Cell Line, Veterinary Epidemiology, trafficking, Animals, Biology, serotype-8, Sheep, Base Sequence, lcsh:R, belgium, biology.organism_classification, Virology, Reverse genetics, infection, Reverse Genetics, Virologie & Moleculaire Biologie, Mutation, lcsh:Q, Cattle, Veterinary Science, protein, Bluetongue virus

Abstract

Since 1998, Bluetongue virus (BTV)-serotypes 1, 2, 4, 9, and 16 have invaded European countries around the Mediterranean Basin. In 2006, a huge BT-outbreak started after incursion of BTV-serotype 8 (BTV8) in North-Western Europe. More recently, BTV6 and BTV11 were reported in North-Western Europe in 2008. These latter strains are closely related to live-attenuated vaccine, whereas BTV8 is virulent and can induce severe disease in ruminants, including cattle. In addition, Toggenburg orbivirus (TOV) was detected in 2008 in Swiss goats, which was recognized as a new serotype of BTV (BTV25). The (re) emergency of known and unknown BTV-serotypes needs a rapid response to supply effective vaccines, and research to study this phenomenon. Recently, orbivirus research achieved an important breakthrough by the establishment of reverse genetics for BTV1. Here, reverse genetics for two recent BTV strains representing virulent BTV8 and avirulent BTV6 was developed. For this purpose, extensive sequencing of full-genomes was performed, resulting in the consensus sequences of BTV8/net07 and BTV6/net08. The recovery of 'synthetic BTV', respectively rgBTV8 and rgBTV6, completely from T7-derived RNA transcripts was confirmed by silent mutations by which these 'synthetic BTVs' could be genetically distinguished from wild type BTV, respectively wtBTV6 and wtBTV8. The in vitro and in vivo properties of rgBTV6 or rgBTV8 were comparable to the properties of their parent strains. The asymptomatic or avirulent properties of rgBTV6 and the virulence of rgBTV8 were confirmed by experimental infection of sheep. Reverse genetics of the vaccine-related BTV6 provides a perfect start to develop new generations of BT-vaccines. Reverse genetics of the virulent BTV8 will accelerate research on the special features of BTV8, like transmission by species of Culicoides in a moderate climate, transplacental transmission, and pathogenesis in cattle.

Published

2011

14. Genetic modification of Bluetongue virus by uptake of 'synthetic' genome segments

Author

Piet A. van Rijn, René G. P. van Gennip, Sandra G. P. van de Water, and Daniel Veldman

Subjects

Serotype, Genes, Viral, Reassortment, Short Report, Genome, Viral, Biology, release, Genome, Virus, lcsh:Infectious and parasitic diseases, recovery, Virology, Animals, lcsh:RC109-216, rna, Gene, Recombination, Genetic, particles, Genetics, RNA, proteins, Reverse genetics, Virology & Molecular Biology, Virologie & Moleculaire Biologie, Restriction enzyme, Infectious Diseases, cells, Directed Molecular Evolution, Genetic Engineering, Bluetongue virus, Reassortant Viruses

Abstract

Since 1998, several serotypes of Bluetongue virus (BTV) have invaded several southern European countries. In 2006, the unknown BTV serotype 8 (BTV8/net06) unexpectedly invaded North-West Europe and has resulted in the largest BT-outbreak ever recorded. More recently, in 2008 BTV serotype 6 was reported in the Netherlands and Germany. This virus, BTV6/net08, is closely related to modified-live vaccine virus serotype 6, except for genome segment S10. This genome segment is closer related to that of vaccine virus serotype 2, and therefore BTV6/net08 is considered as a result of reassortment. Research on orbiviruses has been hampered by the lack of a genetic modification method. Recently, reverse genetics has been developed for BTV based on ten in vitro synthesized genomic RNAs. Here, we describe a targeted single-gene modification system for BTV based on the uptake of a single in vitro synthesized viral positive-stranded RNA. cDNAs corresponding to BTV8/net06 genome segments S7 and S10 were obtained by gene synthesis and cloned downstream of the T7 RNA-polymerase promoter and upstream of a unique site for a restriction enzyme at the 3'-terminus for run-off transcription. Monolayers of BSR cells were infected by BTV6/net08, and subsequently transfected with purified in vitro synthesized, capped positive-stranded S7 or S10 RNA from BTV8/net06 origin. "Synthetic" reassortants were rescued by endpoint dilutions, and identified by serotype-specific PCR-assays for segment 2, and serogroup-specific PCRs followed by restriction enzyme analysis or sequencing for S7 and S10 segments. The targeted single-gene modification system can also be used to study functions of viral proteins by uptake of mutated genome segments. This method is also useful to generate mutant orbiviruses for other serogroups of the genus Orbivirus for which reverse genetics has not been developed yet.

Published

2010