249 results on '"Encephalitis Virus, Murray Valley"'
Search Results
2. Co-circulation of Murray Valley encephalitis virus and Japanese encephalitis virus in south-eastern Australia.
- Author
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McGuinness SL, Lau CL, and Leder K
- Subjects
- Humans, Australia, Encephalitis Virus, Japanese, Encephalitis Virus, Murray Valley
- Published
- 2023
- Full Text
- View/download PDF
3. An integrated public health response to an outbreak of Murray Valley encephalitis virus infection during the 2022-2023 mosquito season in Victoria.
- Author
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Braddick M, O'Brien HM, Lim CK, Feldman R, Bunter C, Neville P, Bailie CR, Butel-Simoes G, Jung MH, Yuen A, Hughes N, and Friedman ND
- Subjects
- Humans, Animals, Horses, Victoria epidemiology, Public Health, Seasons, Mosquito Vectors, Disease Outbreaks, Encephalitis Virus, Murray Valley, Encephalitis, Arbovirus epidemiology, Encephalitis, Arbovirus diagnosis, Culicidae
- Abstract
Introduction: Murray Valley encephalitis virus (MVEV) is a mosquito-borne flavivirus known to cause infrequent yet substantial human outbreaks around the Murray Valley region of south-eastern Australia, resulting in significant mortality., Methods: The public health response to MVEV in Victoria in 2022-2023 included a climate informed pre-season risk assessment, and vector surveillance with mosquito trapping and laboratory testing for MVEV. Human cases were investigated to collect enhanced surveillance data, and human clinical samples were subject to serological and molecular testing algorithms to assess for co-circulating flaviviruses. Equine surveillance was carried out via enhanced investigation of cases of encephalitic illness. Integrated mosquito management and active health promotion were implemented throughout the season and in response to surveillance signals., Findings: Mosquito surveillance included a total of 3,186 individual trapping events between 1 July 2022 and 20 June 2023. MVEV was detected in mosquitoes on 48 occasions. From 2 January 2023 to 23 April 2023, 580 samples (sera and CSF) were tested for flaviviruses. Human surveillance detected 6 confirmed cases of MVEV infection and 2 cases of "flavivirus-unspecified." From 1 September 2022 to 30 May 2023, 88 horses with clinical signs consistent with flavivirus infection were tested, finding one probable and no confirmed cases of MVE., Discussion: The expanded, climate-informed vector surveillance system in Victoria detected MVEV in mosquitoes in advance of human cases, acting as an effective early warning system. This informed a one-health oriented public health response including enhanced human, vector and animal surveillance, integrated mosquito management, and health promotion., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Braddick, O’Brien, Lim, Feldman, Bunter, Neville, Bailie, Butel-Simoes, Jung, Yuen, Hughes and Friedman.)
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- 2023
- Full Text
- View/download PDF
4. Nucleic Acid Preservation Card Surveillance Is Effective for Monitoring Arbovirus Transmission on Crocodile Farms and Provides a One Health Benefit to Northern Australia
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Nina Kurucz, Jamie Lee McMahon, Allan Warchot, Glen Hewitson, Jean Barcelon, Frederick Moore, Jasmin Moran, Jessica J. Harrison, Agathe M. G. Colmant, Kyran M. Staunton, Scott A. Ritchie, Michael Townsend, Dagmar Meyer Steiger, Roy A. Hall, Sally R. Isberg, Sonja Hall-Mendelin, Unité des Virus Emergents (UVE), and Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Institut National de la Santé et de la Recherche Médicale (INSERM)
- Subjects
saltwater crocodile ,Farms ,Encephalitis Virus, Murray Valley ,Mosquito Vectors ,Kunjin virus ,FTATM cards ,Virology ,Nucleic Acids ,Northern Territory ,Animals ,One Health ,mosquitoes ,virus isolation ,Alligators and Crocodiles ,[SDV.BA]Life Sciences [q-bio]/Animal biology ,Flavivirus ,sentinel chickens ,Infectious Diseases ,Culicidae ,[SDV.MP.VIR]Life Sciences [q-bio]/Microbiology and Parasitology/Virology ,surveillance ,RNA, Viral ,[SDV.SPEE]Life Sciences [q-bio]/Santé publique et épidémiologie ,West Nile virus ,flaviviruses ,Arboviruses - Abstract
The Kunjin strain of West Nile virus (WNVKUN) is a mosquito-transmitted flavivirus that can infect farmed saltwater crocodiles in Australia and cause skin lesions that devalue the hides of harvested animals. We implemented a surveillance system using honey-baited nucleic acid preservation cards to monitor WNVKUN and another endemic flavivirus pathogen, Murray Valley encephalitis virus (MVEV), on crocodile farms in northern Australia. The traps were set between February 2018 and July 2020 on three crocodile farms in Darwin (Northern Territory) and one in Cairns (North Queensland) at fortnightly intervals with reduced trapping during the winter months. WNVKUN RNA was detected on all three crocodile farms near Darwin, predominantly between March and May of each year. Two of the NT crocodile farms also yielded the detection of MVE viral RNA sporadically spread between April and November in 2018 and 2020. In contrast, no viral RNA was detected on crocodile farms in Cairns during the entire trapping period. The detection of WNVKUN and MVEV transmission by FTATM cards on farms in the Northern Territory generally correlated with the detection of their transmission to sentinel chicken flocks in nearby localities around Darwin as part of a separate public health surveillance program. While no isolates of WNVKUN or MVEV were obtained from mosquitoes collected on Darwin crocodile farms immediately following the FTATM card detections, we did isolate another flavivirus, Kokobera virus (KOKV), from Culex annulirostris mosquitoes. Our studies support the use of the FTATM card system as a sensitive and accurate method to monitor the transmission of WNVKUN and other arboviruses on crocodile farms to enable the timely implementation of mosquito control measures. Our detection of MVEV transmission and isolation of KOKV from mosquitoes also warrants further investigation of their potential role in causing diseases in crocodiles and highlights a “One Health” issue concerning arbovirus transmission to crocodile farm workers. In this context, the introduction of FTATM cards onto crocodile farms appears to provide an additional surveillance tool to detect arbovirus transmission in the Darwin region, allowing for a more timely intervention of vector control by relevant authorities.
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- 2022
- Full Text
- View/download PDF
5. Early detection of Murray Valley encephalitis virus activity in Victoria using mosquito surveillance.
- Author
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Braddick M, Yuen A, Feldman R, and Friedman ND
- Subjects
- Humans, Animals, Early Diagnosis, Encephalitis Virus, Murray Valley, Culicidae, Encephalitis, Arbovirus diagnosis
- Published
- 2023
- Full Text
- View/download PDF
6. Different tertiary interactions create the same important 3D features in a distinct flavivirus xrRNA
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Quentin Vicens, Rachel A. Jones, Anna-Lena Steckelberg, Jeffrey S. Kieft, Benjamin M. Akiyama, and Matthew J. Szucs
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Untranslated region ,RNA Folding ,RNA, Untranslated ,Cations, Divalent ,Computational biology ,Encephalitis Virus, Murray Valley ,Biology ,Crystallography, X-Ray ,Article ,03 medical and health sciences ,Animals ,Viral rna ,Nucleotide ,Magnesium ,Nucleic acid structure ,Molecular Biology ,3' Untranslated Regions ,Base Pairing ,030304 developmental biology ,Subgenomic mRNA ,chemistry.chemical_classification ,0303 health sciences ,Base Sequence ,030302 biochemistry & molecular biology ,Flaviviridae ,RNA ,Zika Virus ,biology.organism_classification ,Exoribonucleases ,Flavivirus ,chemistry ,Host-Pathogen Interactions ,RNA, Viral ,Viruses, Unclassified - Abstract
During infection by a flavivirus (FV), cells accumulate noncoding subgenomic flavivirus RNAs (sfRNAs) that interfere with several antiviral pathways. These sfRNAs are formed by structured RNA elements in the 3′ untranslated region (UTR) of the viral genomic RNA, which block the progression of host cell exoribonucleases that have targeted the viral RNA. Previous work on these exoribonuclease-resistant RNAs (xrRNAs) from mosquito-borne FVs revealed a specific three-dimensional fold with a unique topology in which a ring-like structure protectively encircles the 5′ end of the xrRNA. Conserved nucleotides make specific tertiary interactions that support this fold. Examination of more divergent FVs reveals differences in their 3′ UTR sequences, raising the question of whether they contain xrRNAs and if so, how they fold. To answer this, we demonstrated the presence of an authentic xrRNA in the 3′ UTR of the Tamana bat virus (TABV) and solved its structure by X-ray crystallography. The structure reveals conserved features from previously characterized xrRNAs, but in the TABV version these features are created through a novel set of tertiary interactions not previously seen in xrRNAs. This includes two important A–C interactions, four distinct backbone kinks, several ordered Mg2+ ions, and a C+–G–C base triple. The discovery that the same overall architecture can be achieved by very different sequences and interactions in distantly related flaviviruses provides insight into the diversity of this type of RNA and will inform searches for undiscovered xrRNAs in viruses and beyond.
- Published
- 2020
7. Nanoscale Structure Determination of Murray Valley Encephalitis and Powassan Virus Non-coding RNAs
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Borries Demeler, Tyler Mrozowich, Amy Henrickson, and Trushar R. Patel
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Models, Molecular ,0301 basic medicine ,RNA, Untranslated ,viruses ,lcsh:QR1-502 ,Encephalitis Virus, Murray Valley ,Computational biology ,Powassan Virus ,medicine.disease_cause ,Murray Valley encephalitis virus ,Article ,lcsh:Microbiology ,Encephalitis Viruses, Tick-Borne ,03 medical and health sciences ,Murray Valley Encephalitis Virus ,Modelling methods ,Virology ,Scattering, Small Angle ,medicine ,Powassan virus ,Analytical Ultracentrifugation ,030304 developmental biology ,0303 health sciences ,030102 biochemistry & molecular biology ,biology ,Flavivirus ,Small-angle X-ray Scattering ,030302 biochemistry & molecular biology ,RNA ,Non-coding RNA ,biology.organism_classification ,Non-Coding RNA ,3. Good health ,030104 developmental biology ,Infectious Diseases ,Terminal (electronics) ,Computational RNA Structure Modeling ,Murray valley encephalitis ,Nucleic Acid Conformation ,RNA, Viral ,Ultracentrifuge - Abstract
Viral infections are responsible for numerous deaths worldwide. Flaviviruses, which contain RNA as their genetic material, are one of the most pathogenic families of viruses. There is an increasing amount of evidence suggesting that their 5&rsquo, and 3&rsquo, non-coding terminal regions are critical for their survival. Information on their structural features is essential to gain detailed insights into their functions and interactions with host proteins. In this study, the 5&rsquo, terminal regions of Murray Valley encephalitis virus and Powassan virus were examined using biophysical and computational modeling methods. First, we used size exclusion chromatography and analytical ultracentrifuge methods to investigate the purity of in-vitro transcribed RNAs. Next, we employed small-angle X-ray scattering techniques to study solution conformation and low-resolution structures of these RNAs, which suggest that the 3&rsquo, terminal regions are highly extended as compared to the 5&rsquo, terminal regions for both viruses. Using computational modeling tools, we reconstructed 3-dimensional structures of each RNA fragment and compared them with derived small-angle X-ray scattering low-resolution structures. This approach allowed us to reinforce that the 5&rsquo, terminal regions adopt more dynamic structures compared to the mainly double-stranded structures of the 3&rsquo, terminal regions.
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- 2020
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8. Murray Valley encephalitis in an adult traveller complicated by long-term flaccid paralysis: case report and review of the literature
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Douglas, Mark W., Stephens, Dianne P., Burrow, James N.C., Anstey, Nicholas M., Talbot, Kevin, and Currie, Bart J.
- Subjects
BRAIN diseases ,FLAVIVIRUSES ,PREVENTION of communicable diseases - Abstract
Summary: Murray Valley encephalitis (MVE) virus, a mosquito-borne flavivirus, is the most common cause of viral encephalitis in the tropical ‘Top End’ of northern Australia. Clinical encephalitis due to MVE virus has a mortality rate of approximately 30%, with a similar proportion of patients being left with significant neurological deficits. We report the case of a 25-year-old man from the UK who acquired MVE while travelling through northern Australia. He required prolonged admission to the Intensive Care Unit and several years later remains partly ventilator-dependent, with flaccid quadriparesis. To our knowledge, this is the first reported case of MVE virus-induced flaccid paralysis in an adult in northern Australia, although it is well described in children. Paralysis was thought to be due to anterior horn cell involvement in the spinal cord and extensive bilateral thalamic destruction, both of which are well recognised complications of infection with MVE virus. Cases of flaccid paralysis with similar pathology have been described following infection with the related flavivirus Japanese encephalitis virus as well as more recently with West Nile virus. Our case highlights the potential severity of flavivirus-induced encephalitis and the importance of avoiding mosquito bites while travelling through endemic areas. [Copyright &y& Elsevier]
- Published
- 2007
- Full Text
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9. The ecology and epidemiology of Ross River and Murray Valley encephalitis viruses in Western Australia: examples of One Health in Action
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Allison Imrie, John S. Mackenzie, David W. Smith, and Michael D. A. Lindsay
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Climate ,Ecology (disciplines) ,030231 tropical medicine ,Encephalitis Virus, Murray Valley ,Review ,Disease ,Environment ,medicine.disease_cause ,Murray Valley encephalitis virus ,03 medical and health sciences ,Ross River virus ,0302 clinical medicine ,Multidisciplinary approach ,Urbanization ,Encephalitis Viruses ,medicine ,Animals ,Humans ,One Health ,030212 general & internal medicine ,Weather ,Ecosystem ,Mosquito vectors ,Ecology ,biology ,Encephalitis, Arbovirus ,Public Health, Environmental and Occupational Health ,Western Australia ,General Medicine ,biology.organism_classification ,Culicidae ,Infectious Diseases ,Geography ,Vertebrate hosts ,Parasitology - Abstract
Arboviruses are maintained and transmitted through an alternating biological cycle in arthropods and vertebrates, with largely incidental disease in humans and animals. As such, they provide excellent examples of One Health, as their health impact is inextricably linked to their vertebrate hosts, their arthropod vectors and the environment. Prevention and control requires a comprehensive understanding of these interactions, and how they may be effectively and safely modified. This review concentrates on human disease due to Ross River and Murray Valley encephalitis viruses, the two major arboviral pathogens in Australia. It describes how their pattern of infection and disease is influenced by natural climatic and weather patterns, and by anthropogenic activities. The latter includes human-mediated environmental manipulations, such as water impoundment infrastructures, human movements and migration, and community and social changes, such as urban spread into mosquito larval habitats. Effective interventions need to be directed at the environmental precursors of risk. This can best be achieved using One Health approaches to improve collaboration and coordination between different disciplines and cross-sectoral jurisdictions in order to develop more holistic mitigation and control procedures, and to address poorly understood ecological issues through multidisciplinary research.
- Published
- 2017
- Full Text
- View/download PDF
10. Fatal Infection with Murray Valley Encephalitis Virus Imported from Australia to Canada, 2011
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Andreas Kramer, David Safronetz, Raymond Tellier, Michael A. Drebot, Kimberly Holloway, Daniel J Niven, Andrew S Johnson, Kevin Fonseca, Kevin Afra, and Mircea Iftinca
- Subjects
0301 basic medicine ,fatal infection ,Epidemiology ,lcsh:Medicine ,Encephalitis Virus, Murray Valley ,medicine.disease_cause ,Murray Valley encephalitis virus ,Disease Outbreaks ,Murray Valley encephalitis ,imported case ,Fatal Outcome ,0302 clinical medicine ,flavivirus ,Communicable Diseases, Imported ,Meningitis/encephalitis ,Fatal Infection with Murray Valley Encephalitis Virus Imported from Australia to Canada, 2011 ,Travel ,biology ,traveler ,Dispatch ,Encephalitis, Arbovirus ,Brain ,Magnetic Resonance Imaging ,Flavivirus ,Infectious Diseases ,Geography ,Female ,Autopsy ,meningitis/encephalitis ,Encephalitis ,Microbiology (medical) ,Canada ,030231 tropical medicine ,flaviviridae ,Arbovirus ,lcsh:Infectious and parasitic diseases ,Young Adult ,03 medical and health sciences ,Flaviviridae ,Northern Territory ,medicine ,Humans ,viruses ,lcsh:RC109-216 ,lcsh:R ,Australia ,Outbreak ,Japanese encephalitis ,biology.organism_classification ,medicine.disease ,Virology ,arbovirus ,030104 developmental biology ,encephalomyelitis ,Biomarkers - Abstract
Murray Valley encephalitis virus (MVEV), a flavivirus belonging to the Japanese encephalitis serogroup, can cause severe clinical manifestations in humans. We report a fatal case of MVEV infection in a young woman who returned from Australia to Canada. The differential diagnosis for travel-associated encephalitis should include MVEV, particularly during outbreak years.
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- 2017
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11. Mosquito-Borne Viruses and Non-Human Vertebrates in Australia: A Review
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Brian J. Johnson, Julie M. Old, Eloise B. Skinner, and Oselyne T. W. Ong
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0301 basic medicine ,Disease reservoir ,Livestock ,Insular biogeography ,030231 tropical medicine ,lcsh:QR1-502 ,Animals, Wild ,Alphavirus ,Encephalitis Virus, Murray Valley ,Review ,medicine.disease_cause ,mosquito vectors ,Murray Valley encephalitis virus ,lcsh:Microbiology ,Disease Outbreaks ,03 medical and health sciences ,Ross River virus ,0302 clinical medicine ,Virology ,biology.animal ,parasitic diseases ,medicine ,Animals ,Humans ,Endemism ,animal diseases ,biology ,Alphavirus Infections ,Ecology ,fungi ,Australia ,Encephalitis, Arbovirus ,Vertebrate ,Outbreak ,disease reservoirs ,Pets ,biology.organism_classification ,Culicidae ,030104 developmental biology ,Infectious Diseases ,arboviruses ,Public Health ,animal distribution ,Barmah Forest virus - Abstract
Mosquito-borne viruses are well recognized as a global public health burden amongst humans, but the effects on non-human vertebrates is rarely reported. Australia, houses a number of endemic mosquito-borne viruses, such as Ross River virus, Barmah Forest virus, and Murray Valley encephalitis virus. In this review, we synthesize the current state of mosquito-borne viruses impacting non-human vertebrates in Australia, including diseases that could be introduced due to local mosquito distribution. Given the unique island biogeography of Australia and the endemism of vertebrate species (including macropods and monotremes), Australia is highly susceptible to foreign mosquito species becoming established, and mosquito-borne viruses becoming endemic alongside novel reservoirs. For each virus, we summarize the known geographic distribution, mosquito vectors, vertebrate hosts, clinical signs and treatments, and highlight the importance of including non-human vertebrates in the assessment of future disease outbreaks. The mosquito-borne viruses discussed can impact wildlife, livestock, and companion animals, causing significant changes to Australian ecology and economy. The complex nature of mosquito-borne disease, and challenges in assessing the impacts to non-human vertebrate species, makes this an important topic to periodically review.
- Published
- 2021
- Full Text
- View/download PDF
12. Novel Flavivirus Attenuation Markers Identified in the Envelope Protein of Alfuy Virus
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Daniel J. Westlake, Natalie A. Prow, Helle Bielefeldt-Ohmann, Roy A. Hall, Westlake, Daniel, Bielefeldt-Ohmann, Helle, Prow, Natalie A, and Hall, Roy A
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0301 basic medicine ,Glycosylation ,viruses ,Amino Acid Motifs ,lcsh:QR1-502 ,Encephalitis Virus, Murray Valley ,Viral Plaque Assay ,medicine.disease_cause ,Murray Valley encephalitis virus ,lcsh:Microbiology ,Mice ,chemistry.chemical_compound ,Viral Envelope Proteins ,flavivirus ,glycosaminoglycan (GAG) ,Serial Passage ,attenuation ,Glycosaminoglycans ,Virulence ,biology ,Strain (chemistry) ,Encephalitis, Arbovirus ,Brain ,alfuy virus (ALFV) ,Flavivirus ,Infectious Diseases ,Murray Valley encephalitis virus (MVEV) ,030106 microbiology ,Murray Valley encephali-tis virus (MVEV) ,Article ,Cell Line ,Flavivirus Infections ,Alfuy virus (ALFV) ,03 medical and health sciences ,Residue (chemistry) ,Protein Domains ,Virology ,medicine ,Animals ,Gene ,Heparin ,Wild type ,biology.organism_classification ,030104 developmental biology ,chemistry ,Encephalitis Viruses, Japanese ,Mutation - Abstract
Alfuy (ALFV) is an attenuated flavivirus related to the Murray Valley encephalitis virus (MVEV). We previously identified markers of attenuation in the envelope (E) protein of the prototype strain (ALFV3929), including the hinge region (E273–277) and lack of glycosylation at E154-156. To further determine the mechanisms of attenuation we assessed ALFV3929 binding to glycosaminoglycans (GAG), a known mechanism of flaviviruses attenuation. Indeed, ALFV3929 exhibited reduced binding to GAG-rich cells in the presence of heparin, however, low-passage ALFV isolates were relatively unaffected. Sequence comparisons between ALFV strains and structural modelling incriminated a positively-charged residue (K327) in ALFV3929 as a GAG-binding motif. Substitution of this residue to the corresponding uncharged residue in MVEV (L), using a previously described chimeric virus containing the prM &, E genes of ALFV3929 in the backbone of MVEV (MVEV/ALFV-prME), confirmed a role for K327 in enhanced GAG binding. When the wild type residues at E327, E273–277 and E154–156 of ALFV3929 were replaced with the corresponding residues from virulent MVEV, it revealed each motif contributed to attenuation of ALFV3929, with the E327/E273–277 combination most dominant. These data demonstrate that attenuation of ALFV3929 is multifactorial and provide new insights for the rational design of attenuated flavivirus vaccines.
- Published
- 2021
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13. Alfred Walter Campbell's return to Australia
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Malcolm Macmillan
- Subjects
Male ,History ,Psychoanalysis ,Gorilla ,Encephalitis Virus, Murray Valley ,050105 experimental psychology ,03 medical and health sciences ,0302 clinical medicine ,History and Philosophy of Science ,Cortex (anatomy) ,biology.animal ,medicine ,Pathology ,Humans ,0501 psychology and cognitive sciences ,Cerebral Cortex ,Australian X disease ,biology ,General Neuroscience ,Research ,05 social sciences ,Australia ,Brain ,History, 19th Century ,History, 20th Century ,United Kingdom ,medicine.anatomical_structure ,Neurology ,Psychotic Disorders ,Cerebellar cortex ,Murray valley encephalitis ,Lunatic ,Neurology (clinical) ,030217 neurology & neurosurgery - Abstract
Alfred Walter Campbell (1868-1937) established the basic cytoarchitectonic structure of the human brain while he was working as a pathologist at the Rainhill Lunatic Asylum near Liverpool in the United Kingdom. He returned to Australia in 1905 and continued doing research while establishing a neurological practice. His research over the next 17 years focused on four topics: (a) localisation in the cerebellum, (b) the neuroses and psychoses in war, (c) localisation in the cerebral cortex of the gorilla, and (d) the causes and pathology of the mysterious Australian "X" Disease (later known as Murray Valley encephalitis). In this article, I elaborate on his research in these areas, which provided evidence (a) against Louis Bolk's thesis that variation in the size of the cerebellar cortex reflected variation in the amount of cortex controlling various groups of muscle, (b) against the view that the neuroses and psychoses in war were different from those in civilian life, (c) for a parcelation of the cortex of the gorilla brain that supported his earlier findings in the higher apes, and (d) on the cause and pathophysiology of Australian "X" disease. Much of this research was overlooked, but it remains of considerable value and historical significance.
- Published
- 2017
14. Differential Diagnosis of Flavivirus Infections in Horses Using Viral Envelope Protein Domain III Antigens in Enzyme-Linked Immunosorbent Assay
- Author
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Alexander A. Khromykh, Peter D. Kirkland, Yin Xiang Setoh, David Perera, Thisun B. H. Piyasena, Natalie A. Prow, Helle Bielefeldt-Ohmann, Mary Jane Cardosa, Roy A. Hall, Jody Hobson-Peters, Piyasena, Thisun BH, Setoh, Yin X, Hobson-Peters, Jody, Prow, Natalie A, Bielefeldt-Ohmann, Helle, Khromykh, Alexander A, Perera, David, Cardosa, Mary J, Kirkland, Peter D, and Hall, Roy A
- Subjects
0301 basic medicine ,040301 veterinary sciences ,viruses ,viral envelope protein ,serology ,Enzyme-Linked Immunosorbent Assay ,Encephalitis Virus, Murray Valley ,Biology ,medicine.disease_cause ,Antibodies, Viral ,Microbiology ,Murray Valley encephalitis virus ,Serology ,Disease Outbreaks ,0403 veterinary science ,03 medical and health sciences ,Viral Proteins ,Antigen ,flavivirus ,Neutralization Tests ,Virology ,medicine ,Animals ,Flavivirus Infections ,Horses ,medicine.diagnostic_test ,equine disease ,Encephalitis, Arbovirus ,virus diseases ,domain III ,04 agricultural and veterinary sciences ,biology.organism_classification ,medicine.disease ,Flavivirus ,030104 developmental biology ,Infectious Diseases ,Immunoassay ,biology.protein ,Horse Diseases ,Antibody ,New South Wales ,West Nile virus ,Encephalitis ,West Nile Fever - Abstract
In Australia, infection of horses with the West Nile virus (WNV) or Murray Valley encephalitis virus (MVEV) occasionally results in severe neurological disease that cannot be clinically differentiated. Confirmatory serological tests to detect antibody specific for MVEV or WNV in horses are often hampered by cross-reactive antibodies induced to conserved epitopes on the envelope (E) protein. This study utilized bacterially expressed recombinant antigens derived from domain III of the E protein (rE-DIII) of MVEV and WNV, respectively, to determine whether these subunit antigens provided specific diagnostic markers of infection with these two viruses. When a panel of 130 serum samples, from horses with known flavivirus infection status, was tested in enzyme-linked immunosorbent assay (ELISA) using rE-DIII antigens, a differential diagnosis of MVEV or WNV was achieved for most samples. Time-point samples from horses exposed to flavivirus infection during the 2011 outbreak of equine encephalitis in south-eastern Australia also indicated that the rE-DIII antigens were capable of detecting and differentiating MVEV and WNV infection in convalescent sera with similar sensitivity and specificity to virus neutralization tests and blocking ELISAs. Overall, these results indicate that the rE-DIII is a suitable antigen for use in rapid immunoassays for confirming MVEV and WNV infections in horses in the Australian context and warrant further assessment on sensitive, high-throughput serological platforms such as multiplex immune assays. Refereed/Peer-reviewed
- Published
- 2017
15. Extended detection and isolation of Murray Valley encephalitis virus in whole blood and urine
- Author
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Ram Ghimire, Brinthan Rajaratnam, Ella M. Meumann, Julian Druce, Leon Caly, Jonathan Marrow, Robert W. Baird, and Natalie Davidson
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Native Hawaiian or Other Pacific Islander ,Isolation (health care) ,Arbovirus Infections ,Encephalitis, Arbovirus ,Electroencephalography ,Encephalitis Virus, Murray Valley ,General Medicine ,Urine ,Biology ,medicine.disease_cause ,Polymerase Chain Reaction ,Virology ,Murray Valley encephalitis virus ,Plasma ,Young Adult ,Blood ,Northern Territory ,medicine ,Humans ,RNA, Viral ,Female ,Whole blood - Published
- 2019
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16. Mosquito-Borne Viruses and Non-Human Vertebrates in Australia: A Review.
- Author
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Ong OTW, Skinner EB, Johnson BJ, and Old JM
- Subjects
- Alphavirus, Alphavirus Infections veterinary, Animals, Animals, Wild virology, Australia epidemiology, Disease Outbreaks veterinary, Disease Reservoirs virology, Encephalitis Virus, Murray Valley, Encephalitis, Arbovirus veterinary, Humans, Livestock virology, Pets virology, Public Health, Ross River virus, Alphavirus Infections epidemiology, Culicidae virology, Disease Reservoirs veterinary, Encephalitis, Arbovirus epidemiology, Mosquito Vectors virology
- Abstract
Mosquito-borne viruses are well recognized as a global public health burden amongst humans, but the effects on non-human vertebrates is rarely reported. Australia, houses a number of endemic mosquito-borne viruses, such as Ross River virus, Barmah Forest virus, and Murray Valley encephalitis virus. In this review, we synthesize the current state of mosquito-borne viruses impacting non-human vertebrates in Australia, including diseases that could be introduced due to local mosquito distribution. Given the unique island biogeography of Australia and the endemism of vertebrate species (including macropods and monotremes), Australia is highly susceptible to foreign mosquito species becoming established, and mosquito-borne viruses becoming endemic alongside novel reservoirs. For each virus, we summarize the known geographic distribution, mosquito vectors, vertebrate hosts, clinical signs and treatments, and highlight the importance of including non-human vertebrates in the assessment of future disease outbreaks. The mosquito-borne viruses discussed can impact wildlife, livestock, and companion animals, causing significant changes to Australian ecology and economy. The complex nature of mosquito-borne disease, and challenges in assessing the impacts to non-human vertebrate species, makes this an important topic to periodically review.
- Published
- 2021
- Full Text
- View/download PDF
17. Molecular characterization and phylogenetic analysis of Murray Valley encephalitis virus and West Nile virus (Kunjin subtype) from an arbovirus disease outbreak in horses in Victoria, Australia, in 2011
- Author
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Julian Motha, Mark Fegan, Rachel A. Mann, Simone Warner, and Kim O’Riley
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Victoria ,viruses ,Molecular Sequence Data ,Encephalitis Virus, Murray Valley ,Disease ,Viral Nonstructural Proteins ,medicine.disease_cause ,Arbovirus ,Murray Valley encephalitis virus ,Virus ,Disease Outbreaks ,medicine ,Animals ,Amino Acid Sequence ,Horses ,Phylogeny ,Base Sequence ,General Veterinary ,biology ,Phylogenetic tree ,Reverse Transcriptase Polymerase Chain Reaction ,Encephalitis, Arbovirus ,virus diseases ,Outbreak ,Sequence Analysis, DNA ,medicine.disease ,biology.organism_classification ,Virology ,nervous system diseases ,Flavivirus ,RNA, Viral ,Horse Diseases ,Sequence Alignment ,West Nile virus ,West Nile Fever ,Encephalitis - Abstract
Virus was detected in the central nervous system (CNS) tissue of 11 horses from Victoria that died displaying neurological symptoms during an outbreak of disease in Australia in 2011. Five horses were identified as being infected with Murray Valley encephalitis virus (MVEV) and 6 as being infected with West Nile virus subtype Kunjin (WNVKUN). Analysis of partial sequence information from the NS5 and E genes indicated that the MVEVs within the samples were highly homogenous and all belonged to lineage I, which is enzootic to the tropical regions of northern Australia. Likewise, analysis of partial NS5 and E gene and full genome sequences indicated that the WNVKUN within the samples were also highly homogenous and clustered with WNV lineage 1, clade b, which is consistent with other WNVKUN isolates. Full genomes of 1 MVEV isolate and 2 WNVKUN isolates were sequenced and characterized. The genome sequences of Victorian WNVKUN are almost identical (3 amino acid differences) to that of the recently sequenced WNV isolate WNVNSW2011. Metagenome sequencing directly from CNS tissue identified the presence of WNVKUN and MVEV within infected CNS tissue.
- Published
- 2013
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18. Deployable Molecular Detection of Arboviruses in the Australian Outback
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Peter J. Neville, Stephen P. Frances, Timothy J. J. Inglis, David Smith, Adam J. Merritt, Avram Levy, Russell L. McInnes, Michael D. A. Lindsay, Jay Nicholson, and Richard S. Bradbury
- Subjects
0301 basic medicine ,Veterinary medicine ,viruses ,030231 tropical medicine ,Population ,Alphavirus ,Subtropics ,Encephalitis Virus, Murray Valley ,Mosquito Vectors ,medicine.disease_cause ,Real-Time Polymerase Chain Reaction ,Arbovirus ,Murray Valley encephalitis virus ,Population density ,03 medical and health sciences ,Ross River virus ,0302 clinical medicine ,Virology ,medicine ,Animals ,education ,education.field_of_study ,biology ,virus diseases ,Articles ,Western Australia ,biochemical phenomena, metabolism, and nutrition ,biology.organism_classification ,medicine.disease ,030104 developmental biology ,Infectious Diseases ,Geography ,Culicidae ,Population Surveillance ,Parasitology ,Queensland ,Barmah Forest virus ,West Nile virus ,Arboviruses - Abstract
The most common causes of human infection from the arboviruses that are endemic in Australia are the arthritogenic alphaviruses: Ross River virus (RRV) and Barmah Forest virus (BFV). The most serious infections are caused by the neurotropic flaviviruses, Murray Valley encephalitis virus (MVEV) and the Kunjin subtype of West Nile virus. The greatest individual risk of arbovirus infection occurs in tropical/subtropical northern Australia because of the warm, wet summer conditions from December to June, where conventional arbovirus surveillance is difficult due to a combination of low population density, large distances between population centers, poor roads, and seasonal flooding. Furthermore, virus detection requires samples to be sent to Perth up to 2,000 km away for definitive analysis, causing delays of days to weeks before test results are available and public health interventions can be started. We deployed a portable molecular biology laboratory for remote field detection of endemic arboviruses in northern Queensland, then in tropical Western Australia and detected BFV, MVEV, and RRV RNA by polymerase chain reaction (PCR) assays of extracts from mosquitoes trapped in Queensland. We then used a field-portable compact real-time thermocycler for the samples collected in the Kimberley region of Western Australia. Real-time field PCR assays enabled concurrent endemic arbovirus distribution mapping in outback Queensland and Western Australia. Our deployable laboratory method provides a concept of operations for future remote area arbovirus surveillance.
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- 2016
19. Historical Perspective: What Constitutes Discovery (of a New Virus)?
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F A, Murphy
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Sin Nombre virus ,Ultrafiltration ,History, 19th Century ,Vaccinia virus ,Encephalitis Virus, Murray Valley ,Variola virus ,History, 20th Century ,Ebolavirus ,Orthomyxoviridae ,Databases as Topic ,Inventions ,Virology ,Hemorrhagic Fever Virus, Crimean-Congo ,HIV-1 ,Workforce ,Animals ,Humans ,Yellow fever virus - Abstract
A historic review of the discovery of new viruses leads to reminders of traditions that have evolved over 118 years. One such tradition gives credit for the discovery of a virus to the investigator(s) who not only carried out the seminal experiments but also correctly interpreted the findings (within the technological context of the day). Early on, ultrafiltration played a unique role in "proving" that an infectious agent was a virus, as did a failure to find any microscopically visible agent, failure to show replication of the agent in the absence of viable cells, thermolability of the agent, and demonstration of a specific immune response to the agent so as to rule out duplicates and close variants. More difficult was "proving" that the new virus was the etiologic agent of the disease ("proof of causation")-for good reasons this matter has been revisited several times over the years as technologies and perspectives have changed. One tradition is that the discoverers get to name their discovery, their new virus (unless some grievous convention has been broken)-the stability of these virus names has been a way to honor the discoverer(s) over the long term. Several vignettes have been chosen to illustrate several difficulties in holding to the traditions (vignettes chosen include vaccinia and variola viruses, yellow fever virus, and influenza viruses. Crimean-Congo hemorrhagic fever virus, Murray Valley encephalitis virus, human immunodeficiency virus 1, Sin Nombre virus, and Ebola virus). Each suggests lessons for the future. One way to assure that discoveries are forever linked with discoverers would be a permanent archive in one of the universal virus databases that have been constructed for other purposes. However, no current database seems ideal-perhaps members of the global community of virologists will have an ideal solution.
- Published
- 2016
20. Confirmed case of encephalitis caused by Murray Valley encephalitis virus infection in a horse
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Anita N. Gordon, John Bingham, David T. Williams, Glen Edmunds, Cameron R. Marbach, Jane Oakey, Sinead M. Diviney, and Kelly Condon
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Pathology ,medicine.medical_specialty ,Encephalomyelitis ,Molecular Sequence Data ,Encephalitis Virus, Murray Valley ,Biology ,medicine.disease_cause ,Murray Valley encephalitis virus ,Virus ,Fatal Outcome ,Viral Envelope Proteins ,Veterinary virology ,medicine ,Animals ,Horses ,Phylogeny ,Base Sequence ,General Veterinary ,Reverse Transcriptase Polymerase Chain Reaction ,Encephalitis, Arbovirus ,Sequence Analysis, DNA ,medicine.disease ,Spinal cord ,biology.organism_classification ,Immunohistochemistry ,Virology ,Reverse transcription polymerase chain reaction ,Flavivirus ,medicine.anatomical_structure ,RNA, Viral ,Horse Diseases ,Queensland ,Sequence Alignment ,Encephalitis - Abstract
A 5-year-old Australian stock horse in Monto, Queensland, Australia, developed neurological signs and was euthanized after a 6-day course of illness. Histological examination of the brain and spinal cord revealed moderate to severe subacute, nonsuppurative encephalomyelitis. Sections of spinal cord stained positively in immunohistochemistry with a flavivirus-specific monoclonal antibody. Reverse transcription polymerase chain reaction assay targeting the envelope gene of flavivirus yielded positive results from brain, spinal cord, cerebrospinal fluid, and facial nerve. A flavivirus was isolated from the cerebrum and spinal cord. Nucleotide sequences obtained from amplicons from both tissues and virus isolated in cell culture were compared with those in GenBank and had 96–98% identity with Murray Valley encephalitis virus. The partial envelope gene sequence of the viral isolate clustered into genotype 1 and was most closely related to a previous Queensland isolate.
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- 2012
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21. Habitat modification for mosquito control in the Ilparpa Swamp, Northern Territory, Australia
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Raelene T Whitters, Peter I Whelan, Susan P. Jacups, and Nina Kurucz
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Wet season ,Mosquito Control ,Urban Population ,Culex annulirostris ,Culex ,Wetland ,Encephalitis Virus, Murray Valley ,Swamp ,Arbovirus ,Northern Territory ,medicine ,Animals ,Humans ,Ecosystem ,Poultry Diseases ,Ecology, Evolution, Behavior and Systematics ,geography ,geography.geographical_feature_category ,Ecology ,biology ,fungi ,Encephalitis, Arbovirus ,biology.organism_classification ,medicine.disease ,Insect Vectors ,Mosquito control ,Habitat ,Larva ,Wetlands ,Chickens ,West Nile virus ,West Nile Fever - Abstract
Habitat modification is an established method of effective long-term mosquito management, particularly in salt-marsh environments. It is especially pertinent when mosquitoes are known vectors of life-threatening disease and their larval breeding habitat is in close proximity to residential areas. The Ilparpa Swamp is located less than 10 km from Alice Springs, Northern Territory. Wet season rainfall, often followed by effluent discharges to the swamp from the adjacent sewage treatment plant, create ideal sites for the immature stages of the common banded mosquito Culex annulirostris (Skuse), a major vector of Murray Valley encephalitis (MVEV) and Kunjin (KUNV) viruses. Subsequent to increases in notifications of MVEV disease cases in 2000 and 2001, a drainage system was established in the Ilparpa Swamp in early 2002. This paper evaluates the drainage intervention effects. Results indicate a significant reduction in mosquito numbers following habitat modification, which remain low. There have been no seroconversions in sentinel chickens to MVEV or KUNV and no human infections from these viruses in the Alice Springs urban region since the drains were completed. Habitat modification has successfully reduced mosquito numbers and minimized the risk for mosquito-borne disease to residents in Alice Springs urban and surrounding areas, which has never before been documented in Australia.
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- 2011
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22. Toponymous diseases of Australia
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Jan Tent, John S. Mackenzie, and Ranil D Appuhamy
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Henipavirus Infections ,Geography ,Alphavirus Infections ,business.industry ,Association (object-oriented programming) ,Australia ,Encephalitis, Arbovirus ,History, 19th Century ,Alphavirus ,Encephalitis Virus, Murray Valley ,General Medicine ,Disease ,History, 20th Century ,Genealogy ,Hendra Virus ,Virus Diseases ,Ross River virus ,Humans ,Names ,Medicine ,business ,Buruli Ulcer - Abstract
Names are more than just labels used to identify diseases. They can be windows into the discovery, characteristics and attributes of the disease. Toponymous diseases are diseases that are named after places. Hendra, Ross River, Bairnsdale, Murray Valley and Barmah Forest are all examples of Australian places that have had diseases named after them. They all have unique and interesting stories that provide a glimpse into their discovery, history and culture. Because of perceived negative connotations, the association of diseases with placenames has sometimes generated controversy.
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- 2010
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23. Biochemical characterisation of Murray Valley encephalitis virus proteinase
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Wee Liang Kuan, Joma Joy, Ng Fui Mee, Jeffrey Hill, Then Siew Wen, and Kwek Zekui Perlyn
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Inhibitor ,viruses ,medicine.medical_treatment ,Biophysics ,Encephalitis Virus, Murray Valley ,medicine.disease_cause ,Biochemistry ,Murray Valley encephalitis virus ,Genome ,Murray Valley encephalitis ,Dengue ,Serine ,Viral Proteins ,Structural Biology ,Endopeptidases ,Genetics ,medicine ,Molecular Biology ,Polyproteins ,Cloning ,NS3 ,Protease ,biology ,Flavivirus ,virus diseases ,Cell Biology ,biochemical phenomena, metabolism, and nutrition ,biology.organism_classification ,Fusion protein ,Virology ,Serine Proteases ,West Nile virus ,Protein Processing, Post-Translational - Abstract
Murray Valley encephalitis virus (MVEV) is a member of the flavivirus group, a large family of single stranded RNA viruses, which cause serious disease in all regions of the world. Its genome encodes a large polyprotein which is processed by both host proteinases and a virally encoded serine proteinase, non-structural protein 3 (NS3). NS3, an essential viral enzyme, requires another virally encoded protein cofactor, NS2B, for proteolytic activity. The cloning, expression and biochemical characterisation of a stable MVEV NS2B–NS3 fusion protein is described.
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- 2010
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24. Influence of Hosts on the Ecology of Arboviral Transmission: Potential Mechanisms Influencing Dengue, Murray Valley Encephalitis, and Ross River Virus in Australia
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Andrew Jardine, Scott Carver, Abbey Bestall, and Richard S. Ostfeld
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Cross Protection ,Cross immunity ,Encephalitis Virus, Murray Valley ,Dengue virus ,medicine.disease_cause ,Models, Biological ,Microbiology ,Murray Valley encephalitis virus ,Dengue fever ,Dengue ,Ross River virus ,Virology ,medicine ,Animals ,Humans ,biology ,Alphavirus Infections ,Ecology ,Research ,Zoonosis ,Australia ,Encephalitis, Arbovirus ,Biodiversity ,Dengue Virus ,medicine.disease ,biology.organism_classification ,Insect Vectors ,Culicidae ,Infectious Diseases ,Infectious disease (medical specialty) ,Host-Pathogen Interactions ,Biological dispersal - Abstract
Ecological interactions are fundamental to the transmission of infectious disease. Arboviruses are particularly elegant examples, where rich arrays of mechanisms influence transmission between vectors and hosts. Research on host contributions to the ecology of arboviral diseases has been undertaken within multiple subdisciplines, but significant gaps in knowledge remain and multidisciplinary approaches are needed. Through our multidisciplinary review of the literature we have identified five broad areas where hosts may influence the ecology of arboviral transmission: host immunity; cross-protective immunity and antibody-dependent enhancement; host abundance; host diversity; and pathogen spillover and dispersal. Herein we discuss the known and theoretical roles of hosts within these topics and then apply this knowledge to three epidemiologically important mosquito-borne arboviruses that occur in Australia: dengue virus (DENV), Murray Valley encephalitis virus (MVEV), and Ross River virus (RRV). We argue that the underlying mechanisms by which hosts influence arboviral activity are numerous and attempts to delineate these mechanisms further are needed. Investigations that focus on hosts of vector-borne diseases are likely to be rewarding, particularly where the ecology of vectors is relatively well understood. From an applied perspective, enhanced knowledge of host influences upon vector-borne disease transmission is likely to enable better management of disease burden. Finally, we suggest a framework that may be useful to identify and determine host contributions to the ecology of arboviruses.
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- 2009
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25. A glycosylated peptide in the West Nile virus envelope protein is immunogenic during equine infection
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Katharine N. Bossart, Melissa D. Sánchez, Lin-Fa Wang, David C. Clark, Jody Hobson-Peters, Wai Yuen Cheah, Philip Toye, and Roy A. Hall
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Glycosylation ,medicine.drug_class ,viruses ,Molecular Sequence Data ,Encephalitis Virus, Murray Valley ,Antibodies, Viral ,Monoclonal antibody ,Epitope ,Cell Line ,Viral Envelope Proteins ,Kunjin virus ,Virology ,Chlorocebus aethiops ,medicine ,Animals ,Amino Acid Sequence ,Horses ,Vero Cells ,Peptide sequence ,biology ,Antibodies, Monoclonal ,virus diseases ,biology.organism_classification ,Fusion protein ,nervous system diseases ,Flavivirus ,Epitope mapping ,COS Cells ,biology.protein ,Horse Diseases ,Antibody ,Peptides ,West Nile virus ,Epitope Mapping ,West Nile Fever - Abstract
Using a monoclonal antibody directed to domain I of the West Nile virus (WNV) envelope (E) protein, we identified a continuous (linear) epitope that was immunogenic during WNV infection of horses. Using synthetic peptides, this epitope was mapped to a 19 aa sequence (WN19: E147–165) encompassing the WNV NY99 E protein glycosylation site at position 154. The inability of WNV-positive horse and mouse sera to bind the synthetic peptides indicated that glycosylation was required for recognition of peptide WN19 by WNV-specific antibodies in sera. N-linked glycosylation of WN19 was achieved through expression of the peptide as a C-terminal fusion protein in mammalian cells and specific reactivity of WNV-positive horse sera to the glycosylated WN19 fusion protein was shown by Western blot. Additional sera collected from horses infected with Murray Valley encephalitis virus (MVEV), which is similarly glycosylated at position E154 and exhibits high sequence identity to WNV NY99 in this region, also recognized the recombinant peptide. Failure of most WNV- and MVEV-positive horse sera to recognize the epitope as a deglycosylated fusion protein confirmed that the N-linked glycan was important for antibody recognition of the peptide. Together, these results suggest that the induction of antibodies to the WN19 epitope during WNV infection of horses is generally associated with E protein glycosylation of the infecting viral strain.
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- 2008
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26. Genetic and phenotypic differences between isolates of Murray Valley encephalitis virus in Western Australia, 1972–2003
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David Smith, Stéphane Hemmerter, Fiona J. May, Annette K. Broom, David C. Clark, Roy A. Hall, John S. Mackenzie, Veronica Susai, and Cheryl A. Johansen
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Molecular Sequence Data ,Envelope Gene ,Encephalitis Virus, Murray Valley ,medicine.disease_cause ,Murray Valley encephalitis virus ,Virology ,parasitic diseases ,Genetics ,medicine ,Animals ,Molecular Biology ,Phylogeny ,biology ,Geographic area ,Genetic Variation ,New guinea ,Western Australia ,General Medicine ,Japanese encephalitis ,medicine.disease ,biology.organism_classification ,Phenotype ,Flavivirus ,Culicidae ,Homogeneous - Abstract
Murray Valley encephalitis virus (MVEV) is a medically important mosquito-borne flavivirus found in Australia and Papua New Guinea (PNG). Partial envelope gene nucleotide sequences of 28 isolates of MVEV from Western Australia (WA) between 1972 and 2003 were aligned and compared phylogenetically with the prototype MVE-1-51 from Victoria in 1951 and isolates from northern Queensland and PNG. Monoclonal antibody-binding patterns were also investigated. Results showed that the majority of isolates of MVEV from widely disparate locations in WA were genetically and phenotypically homogeneous. Furthermore, isolates of MVEV from WA and northern Queensland were almost identical, confirming results from earlier studies. Recent isolates of MVEV from Western Province in PNG were more similar to Australian isolates of MVEV than to isolates from PNG in 1956 and 1966, providing further evidence for the movement of flaviviruses between PNG and Australia. Additional representatives of a unique variant of MVEV (OR156) from Kununurra in the northeast Kimberley region of WA were also detected. This suggests that the OR156 lineage is still intermittently active but may be restricted to a small geographic area in northern WA, possibly due to altered biological characteristics.
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- 2007
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27. Structure of the Murray Valley encephalitis virus RNA helicase at 1.9 Å resolution
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David I. Stuart, Erika J. Mancini, Jonathan M. Grimes, Anil Verma, Raymond J. Owens, Roman Tuma, Thomas S. Walter, and Rene Assenberg
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Models, Molecular ,viruses ,Amino Acid Motifs ,Molecular Sequence Data ,Encephalitis Virus, Murray Valley ,Viral Nonstructural Proteins ,Crystallography, X-Ray ,medicine.disease_cause ,Biochemistry ,Murray Valley encephalitis virus ,Virus ,03 medical and health sciences ,Flaviviridae ,medicine ,Amino Acid Sequence ,Molecular Biology ,Peptide sequence ,030304 developmental biology ,Adenosine Triphosphatases ,0303 health sciences ,NS3 ,biology ,Nucleotides ,Serine Endopeptidases ,030302 biochemistry & molecular biology ,virus diseases ,Helicase ,Japanese encephalitis ,biology.organism_classification ,medicine.disease ,Virology ,3. Good health ,Flavivirus ,Protein Structure Report ,biology.protein ,Sequence Alignment ,RNA Helicases - Abstract
Murray Valley encephalitis virus (MVEV), a mosquito-borne flavivirus endemic to Australia, is closely related to Japanese encephalitis virus and West Nile virus. Nonstructural protein 3 (NS3) is a multifunctional enzyme with serine protease and DEXH/D-box helicase domains, whose activity is central to flavivirus replication and is therefore a possible target for anti-flaviviral compounds. Cloning, purification, and crystal structure determination to 1.9 Angstrom resolution of the NS3 helicase of MVEV and characterization of its enzymatic activity is reported. Comparison with the structures of helicases from related viruses supports a possible mechanism of ATP hydrolysis-driven strand separation.
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- 2007
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28. Murray Valley encephalitis in an adult traveller complicated by long-term flaccid paralysis: case report and review of the literature
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Nicholas M. Anstey, Bart J. Currie, Mark W. Douglas, Kevin Talbot, Dianne P Stephens, and James Burrow
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Adult ,Male ,Pediatrics ,medicine.medical_specialty ,Flaccid paralysis ,viruses ,Encephalitis Virus, Murray Valley ,medicine ,Paralysis ,Humans ,Tetraplegia ,Travel ,biology ,business.industry ,Viral encephalitis ,Encephalitis, Arbovirus ,Public Health, Environmental and Occupational Health ,General Medicine ,Japanese encephalitis ,medicine.disease ,biology.organism_classification ,Magnetic Resonance Imaging ,Virology ,Poliomyelitis ,Flavivirus ,Infectious Diseases ,Parasitology ,medicine.symptom ,Tomography, X-Ray Computed ,business ,Encephalitis - Abstract
Murray Valley encephalitis (MVE) virus, a mosquito-borne flavivirus, is the most common cause of viral encephalitis in the tropical 'Top End' of northern Australia. Clinical encephalitis due to MVE virus has a mortality rate of approximately 30%, with a similar proportion of patients being left with significant neurological deficits. We report the case of a 25-year-old man from the UK who acquired MVE while travelling through northern Australia. He required prolonged admission to the Intensive Care Unit and several years later remains partly ventilator-dependent, with flaccid quadriparesis. To our knowledge, this is the first reported case of MVE virus-induced flaccid paralysis in an adult in northern Australia, although it is well described in children. Paralysis was thought to be due to anterior horn cell involvement in the spinal cord and extensive bilateral thalamic destruction, both of which are well recognised complications of infection with MVE virus. Cases of flaccid paralysis with similar pathology have been described following infection with the related flavivirus Japanese encephalitis virus as well as more recently with West Nile virus. Our case highlights the potential severity of flavivirus-induced encephalitis and the importance of avoiding mosquito bites while travelling through endemic areas.
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- 2007
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29. End-point disease investigation for virus strains of intermediate virulence as illustrated by flavivirus infections
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Willy W. Suen, Yin Xiang Setoh, Natalie A. Prow, Helle Bielefeldt-Ohmann, Roy A. Hall, Suen, Willy W, Prow, Natalie A, Setoh, Yin X, Hall, Roy A, and Bielefeldt-Ohmann, Helle
- Subjects
0301 basic medicine ,viruses ,030106 microbiology ,Virulence ,Disease ,Encephalitis Virus, Murray Valley ,Biology ,medicine.disease_cause ,Asymptomatic ,Murray Valley encephalitis virus ,Nervous System ,Virus ,Flavivirus Infections ,Pathogenesis ,03 medical and health sciences ,Mice ,Virology ,medicine ,Animals ,Histocytochemistry ,Reproducibility of Results ,Viral Load ,Survival Analysis ,Disease Models, Animal ,030104 developmental biology ,medicine.symptom ,Viral load ,West Nile virus ,Injections, Intraperitoneal - Abstract
Viruses of intermediate virulence are defined as isolates causing an intermediate morbidity/mortality rate in a specific animal model system, involving specific host and inoculation parameters (e.g. dose and route). Therefore, variable disease phenotype may exist between animals that develop severe disease or die and those that are asymptomatic or survive after infection with these isolates. There may also be variability amongst animals within each of these subsets. Such potential variability may confound the use of time-point sacrifice experiments to investigate pathogenesis of this subset of virus strains, as uniformity in disease outcome is a fundamental assumption for time-course sacrifice experiments. In the current study, we examined the disease phenotype, neuropathology, neural infection and glial cell activity in moribund/dead and surviving Swiss white (CD-1) mice after intraperitoneal infection with various Australian flaviviruses, including West Nile virus (WNV) strains of intermediate virulence (WNV NSW2011 and WNV NSW2012 ), and highly virulent Murray Valley encephalitis virus (MVEV) isolates. We identified notable intragroup variation in the end-point disease in mice infected with either WNV NSW strain, but to a lesser extent in mice infected with MVEV strains. The variable outcomes associated with WNV NSW infection suggest that pathogenesis investigations using time-point sacrifice of WNV NSW -infected mice may not be the best approach, as the assumption of uniformity in outcomes is violated. Our study has therefore highlighted a previously unacknowledged challenge to investigating pathogenesis of virus isolates of intermediate virulence. We have also set a precedent for routine examination of the disease phenotype in moribund/dead and surviving mice during survival challenge experiments. Refereed/Peer-reviewed
- Published
- 2015
30. The Molecular Epidemiology and Evolution of Murray Valley Encephalitis Virus: Recent Emergence of Distinct Sub-lineages of the Dominant Genotype 1
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Aziz-ur-Rahman Niazi, John S. Mackenzie, B. Chua, Alyssa T. Pyke, Stephen L. Doggett, Cheryl A. Johansen, Belinda L. Herring, David T. Williams, Sinead M. Diviney, and Peter A. Durr
- Subjects
lcsh:Arctic medicine. Tropical medicine ,Genotype ,lcsh:RC955-962 ,Molecular Sequence Data ,Encephalitis Virus, Murray Valley ,Biology ,medicine.disease_cause ,Murray Valley encephalitis virus ,Evolution, Molecular ,Mice ,Phylogenetics ,Genetic variation ,medicine ,Animals ,Cluster Analysis ,Humans ,Phylogeny ,Genetics ,Viral Structural Proteins ,Genetic diversity ,Molecular Epidemiology ,Molecular epidemiology ,Phylogenetic tree ,Australasia ,lcsh:Public aspects of medicine ,Public Health, Environmental and Occupational Health ,Encephalitis, Arbovirus ,Genetic Variation ,lcsh:RA1-1270 ,Sequence Analysis, DNA ,Infectious Diseases ,Evolutionary biology ,Viral evolution ,Enzootic ,RNA, Viral ,Female ,Research Article - Abstract
Background Recent increased activity of the mosquito-borne Murray Valley encephalitis virus (MVEV) in Australia has renewed concerns regarding its potential to spread and cause disease. Methodology/Principal Findings To better understand the genetic relationships between earlier and more recent circulating strains, patterns of virus movement, as well as the molecular basis of MVEV evolution, complete pre-membrane (prM) and Envelope (Env) genes were sequenced from sixty-six MVEV strains from different regions of the Australasian region, isolated over a sixty year period (1951–2011). Phylogenetic analyses indicated that, of the four recognized genotypes, only G1 and G2 are contemporary. G1 viruses were dominant over the sampling period and found across the known geographic range of MVEV. Two distinct sub-lineages of G1 were observed (1A and 1B). Although G1B strains have been isolated from across mainland Australia, Australian G1A strains have not been detected outside northwest Australia. Similarly, G2 is comprised of only Western Australian isolates from mosquitoes, suggesting G1B and G2 viruses have geographic or ecological restrictions. No evidence of recombination was found and a single amino acid substitution in the Env protein (S332G) was found to be under positive selection, while several others were found to be under directional evolution. Evolutionary analyses indicated that extant genotypes of MVEV began to diverge from a common ancestor approximately 200 years ago. G2 was the first genotype to diverge, followed by G3 and G4, and finally G1, from which subtypes G1A and G1B diverged between 1964 and 1994. Conclusions/Significance The results of this study provides new insights into the genetic diversity and evolution of MVEV. The demonstration of co-circulation of all contemporary genetic lineages of MVEV in northwestern Australia, supports the contention that this region is the enzootic focus for this virus., Author Summary Murray Valley encephalitis virus is the most significant cause of mosquito-borne encephalitis in humans in Australia, and can also cause neurological disease in horses. This study reports an expanded phylogenetic study of this virus and the first molecular evolutionary analysis. Of the four recognized genotypes of Murray Valley encephalitis virus, only two were found to be actively circulating (genotypes 1 and 2), and genotype 1 was dominant. Distinct genetic sub-lineages within genotype 1 were found to have recently emerged. Molecular clock analysis indicated that genotype 2 viruses are the oldest genetic lineage while genotype 1 viruses are the most recent to diverge. The co-circulation of distinct genetic lineages of this virus in northwestern Australia, comprising the oldest and youngest lineages, supports previous findings that MVEV circulates endemically in this region.
- Published
- 2015
31. Long-term outcomes of Murray Valley encephalitis cases in Western Australia: what have we learnt?
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L A, Selvey, D J, Speers, and D W, Smith
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Adult ,Male ,Time Factors ,Adolescent ,Encephalitis, Arbovirus ,Infant ,Encephalitis Virus, Murray Valley ,Western Australia ,Middle Aged ,Young Adult ,Treatment Outcome ,Child, Preschool ,Humans ,Female ,Child ,Aged ,Follow-Up Studies - Abstract
Murray Valley encephalitis virus (MVEV) is a mosquito-borne flavivirus that causes encephalitis in some cases of infection. It is endemic in Northern Australia and cases occasionally occur in South Eastern Australia. The long-term sequelae of MVEV infection have not previously been well described.To investigate the long-term sequelae of MVEV infection.This was a descriptive case series of all clinical MVEV infections using data linkage and standard surveys. Hospital admissions, emergency department, psychiatric outpatients and mortality data were obtained. We attempted to follow-up all 53 cases of MVEV clinical infection that occurred in Western Australia from 1978 to 2011 inclusive. Two cases opted out of the study.We followed-up 39 surviving cases. Seven of the nine with paralysis or paresis were under 5 years and they fared worse than other patients, requiring lengthy hospitalisation (median duration 133 days). Two died due to complications of quadriplegia following a total of 691 days in hospital. Nine surviving patients, including two with non-encephalitic illness, required care for depression and other psychiatric conditions following MVEV infection. Two patients who were discharged with neurological sequelae had no further documented hospital occasions of service but reported ongoing challenges with cognitive dysfunction and inability to work.This is the first study of long-term outcomes of Murray Valley encephalitis that included cases with no obvious sequelae at discharge. In spite of the small numbers involved, the study demonstrated the significant medical and social burden due to MVEV in Australia.
- Published
- 2015
32. A case of Murray Valley encephalitis in a 2-year-old Australian stock horse in south-east Queensland
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Lisa Kidd, Helle Bielefeldt-Ohmann, Natalie A. Prow, Roy A. Hall, Anita Jane Barton, Barton, Aj, Prow, Na, Hall, Ra, Kidd, L, and Bielefeldt-Ohmann, H
- Subjects
Pediatrics ,medicine.medical_specialty ,Cerebellar Ataxia ,Facial Paralysis ,Enzyme-Linked Immunosorbent Assay ,Encephalitis Virus, Murray Valley ,medicine.disease_cause ,Murray Valley encephalitis virus ,Serology ,Fatal Outcome ,Kunjin virus ,medicine ,Animals ,Horses ,Index case ,horses ,Paresis ,General Veterinary ,biology ,business.industry ,Encephalitis, Arbovirus ,Meningoencephalitis ,Horse ,Brain ,meningoencephalitis ,General Medicine ,medicine.disease ,biology.organism_classification ,Virology ,Titer ,arbovirus ,Female ,Horse Diseases ,Queensland ,medicine.symptom ,business - Abstract
Case report: This report summarises the findings from a case of naturally-occurring Murray Valley encephalitis in a 2-year-old filly presenting with acute onset of depression and weakness. Serum samples tested at the onset of clinical signs were negative for Hendra and Kunjin virus antibodies, but positive for Murray Valley encephalitis virus (MVEV) using IgM-capture ELISA (1:300 dilution). A virus neutralisation assay performed 4 weeks later confirmed a titre of 1:160. Sera collected in the weeks preceding neurological signs returned a negative titre for MVEV 2 weeks prior followed by a titre of 1:80 in the week prior to illness. Serological surveillance conducted on 67 co-located horses returned a positive titre of 1:20 in one in-contact horse. There was no history of clinical disease in that horse. At 3 months after the onset of clinical signs in the index case, the filly continued to show mild facial paresis and hypermetria; the owners elected euthanasia and gave permission for necropsy. Histopathological analysis of the brain showed a mild meningoencephalitis. Conclusion: The progression of a naturally-occurring MVEV infection in a horse has been documented in this case. Refereed/Peer-reviewed
- Published
- 2015
33. Inefficient Signalase Cleavage Promotes Efficient Nucleocapsid Incorporation into Budding Flavivirus Membranes
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Eva Lee and Mario Lobigs
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Gene Expression Regulation, Viral ,Signal peptide ,viruses ,Molecular Sequence Data ,Immunology ,Encephalitis Virus, Murray Valley ,Biology ,medicine.disease_cause ,Cleavage (embryo) ,Microbiology ,Murray Valley encephalitis virus ,Cell Line ,Viral Envelope Proteins ,Aedes ,Cricetinae ,Virology ,Chlorocebus aethiops ,medicine ,Animals ,Amino Acid Sequence ,Nucleocapsid ,Vero Cells ,Peptide sequence ,Membranes ,Virus Assembly ,Structure and Assembly ,Endoplasmic reticulum ,Serine Endopeptidases ,Virion ,Membrane Proteins ,virus diseases ,biochemical phenomena, metabolism, and nutrition ,biology.organism_classification ,Transmembrane protein ,Cell biology ,Flavivirus ,Biochemistry ,Capsid ,Insect Science ,COS Cells ,Mutation - Abstract
The mechanism for efficient nucleocapsid (NC) uptake into flavivirus particles which form by budding through the membranes of the endoplasmic reticulum (ER) was investigated by using Murray Valley encephalitis virus as a model. Budding of flavivirus membranes is driven by the viral transmembrane proteins prM and E independently of NC interaction. We show that control of signalase cleavage of the multimembrane-spanning flavivirus polyprotein by the catalytic function of the viral protease is critical for efficient virus morphogenesis. In wild-type virus, signalase cleavage of prM remains inefficient until cleavage of capsid at the cytosolic side of the signal sequence separating the two proteins has occurred. This obligatory sequence of cleavages was uncoupled in a mutant virus with the consequence of greatly reduced incorporation of NC into budding membranes and augmented release of NC-free virus-like particles. Efficient signalase cleavage of prM in the mutant virus resulted in partial inhibition of cleavage of capsid by the viral NS2B-3 protease. Our results support a model for flavivirus morphogenesis involving temporal and spatial coordination of NC assembly and envelopment by regulated cleavages of an ER membrane-spanning capsid-prM intermediate.
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- 2003
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34. Antibody-dependent enhancement of Murray Valley encephalitis virus virulence in mice
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David Smith, Geoffrey Shellam, P.C. Mcminn, John S. Mackenzie, Margie Wallace, Annette K. Broom, and Roy A. Hall
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Population ,Encephalitis Virus, Murray Valley ,Antibodies, Viral ,Virus Replication ,medicine.disease_cause ,Murray Valley encephalitis virus ,Virus ,Microbiology ,Mice ,Virology ,medicine ,Animals ,Antibody-dependent enhancement ,Viremia ,Encephalitis, Japanese ,education ,Encephalitis Virus, Japanese ,Antiserum ,Mice, Inbred BALB C ,education.field_of_study ,Virulence ,biology ,Japanese Encephalitis Vaccines ,Vaccination ,Encephalitis, Arbovirus ,Immunization, Passive ,Brain ,Japanese encephalitis ,medicine.disease ,biology.organism_classification ,Antibody-Dependent Enhancement ,Flavivirus ,Encephalitis - Abstract
Enhancement of flavivirus infection in vitro in the presence of subneutralizing concentrations of homologous or heterologous antiserum has been well described. However, the importance of this phenomenon in the enhancement of flavivirus infection in vivo has not been established. In order to study antibody-mediated enhancement of flavivirus infection in vivo, we investigated the effect of passive immunization of mice with Japanese encephalitis virus (JE) antiserum on the outcome of infection with Murray Valley encephalitis virus (MVE). We show that prior treatment of mice with subneutralizing concentrations of heterologous JE antiserum resulted in an increase in viraemia titres and in mortality following challenge with wild-type MVE. Our findings support the hypothesis that subneutralizing concentrations of antibody may enhance flavivirus infection and virulence in vivo. These findings are of potential importance for the design of JE vaccination programs in geographic areas in which MVE co-circulates. Should subneutralizing concentrations of antibody remain in the population following JE vaccination, it is possible that enhanced disease may be observed during MVE epidemics.
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- 2003
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35. Polymerase chain reaction tests for the identification of Ross River, Kunjin and Murray Valley encephalitis virus infections in horses
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N. Ficorilli, Roy A. Hall, J. K. Azuolas, J. R. Vasey, Michael J. Studdert, and Jin-an Huang
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animal diseases ,viruses ,Molecular Sequence Data ,Context (language use) ,Encephalitis Virus, Murray Valley ,medicine.disease_cause ,Sensitivity and Specificity ,Murray Valley encephalitis virus ,Virus ,law.invention ,Serology ,Ross River virus ,Kunjin virus ,law ,medicine ,Animals ,Amino Acid Sequence ,Horses ,Polymerase chain reaction ,DNA Primers ,General Veterinary ,biology ,Alphavirus Infections ,Reverse Transcriptase Polymerase Chain Reaction ,Encephalitis, Arbovirus ,Reproducibility of Results ,virus diseases ,General Medicine ,biology.organism_classification ,medicine.disease ,Virology ,RNA, Viral ,Horse Diseases ,Sequence Alignment ,West Nile virus ,West Nile Fever ,Encephalitis - Abstract
Objective To develop and validate specific, sensitive and rapid diagnostic tests using RT-PCR for the detection of Ross River virus (RRV), Kunjin virus (KV) and Murray Valley encephalitis virus (MVEV) infections in horses. Methods Primer sets based on nucleotide sequence encoding the envelope glycoprotein E2 of RRV and on the nonstructural protein 5 (NS5) of KV and MVEV were designed and used in single round PCRs to test for the respective viruses in infected cell cultures and, in the case of RRV, in samples of horse blood and synovial fluid. Results The primer pairs designed for each of the three viruses amplified a product of expected size from prototype viruses that were grown in cell culture. The identity of each of the products was confirmed by nucleotide sequencing indicating that in the context used the RT-PCRs were specific. RRV was detected in serums from 8 horses for which there were clinical signs consistent with RRV infection such that an acute-phase serum sample was taken and submitted for RRV serology testing. The RRV RT-PCR was analytically sensitive in that it was estimated to detect as little as 50 TCID50 of RRV per mL of serum and was specific in that the primer pairs did not amplify other products from the 8 serum samples. The RRV primers also detected virus in three independent mosquito pools known to contain RRV by virus isolation in cell culture. Samples from horses suspected to be infected with KV and MVEV were not available. Conclusion Despite much anecdotal and serological evidence for infection of horses with RRV actual infection and associated clinical disease are infrequently confirmed. The availability of a specific and analytically sensitive RT-PCR for the detection of RRV provides additional opportunities to confirm the presence of this virus in clinical samples. The RTPCR primers for the diagnosis of KV and MVEV infections were shown to be specific for cell culture grown viruses but the further validation of these tests requires the availability of appropriate clinical samples from infected horses.
- Published
- 2003
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36. Murray Valley encephalomyelitis in a horse
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James R. Gilkerson, CM El Hage, MA Muurlink, Ron Slocombe, and JM Holmes
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Pathology ,medicine.medical_specialty ,Exploratory laparotomy ,medicine.medical_treatment ,Encephalomyelitis ,Encephalitis Virus, Murray Valley ,medicine.disease_cause ,Murray Valley encephalitis virus ,Lesion ,Fatal Outcome ,Animals ,Medicine ,Severe pain ,Horses ,General Veterinary ,Reverse Transcriptase Polymerase Chain Reaction ,business.industry ,Encephalitis, Arbovirus ,Horse ,General Medicine ,medicine.disease ,Female ,Horse Diseases ,Intractable pain ,medicine.symptom ,business ,Encephalitis - Abstract
A 5-year-old Thoroughbred mare presented with signs of severe pain and was taken to exploratory laparotomy based on suspicion of an acute abdominal lesion. A mild gastrointestinal lesion was discovered, but was considered disproportional to the severity of signs displayed. The mare was later euthanased because of intractable pain. Comprehensive postmortem examination, including polymerase chain reaction testing of central nervous system tissue samples, allowed a definitive diagnosis of Murray Valley encephalomyelitis to be made. This case demonstrates the variability of clinical presentations in horses infected with Murray Valley encephalitis virus.
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- 2012
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37. Isolation of Arboviruses from Mosquitoes (Diptera: Culicidae) Collected from the Gulf Plains Region of Northwest Queensland, Australia
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Scott A. Ritchie, P. N. Foley, Nigel W. Beebe, John S. Mackenzie, D. J. Nisbet, and A. F. Van Den Hurk
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Culex annulirostris ,viruses ,Zoology ,Encephalitis Virus, Murray Valley ,Alphavirus ,Ross River virus ,Aedes ,Anopheles ,parasitic diseases ,medicine ,Animals ,Genetics & Heredity ,General Veterinary ,biology ,Aedes lineatopennis ,Ecology ,fungi ,Japanese encephalitis ,biology.organism_classification ,medicine.disease ,Insect Vectors ,Culex ,Flavivirus ,Culicidae ,Infectious Diseases ,Insect Science ,Culex sitiens ,Female ,Parasitology ,Queensland ,Sindbis Virus ,Ochlerotatus ,West Nile virus ,Arboviruses - Abstract
As part of investigations into Japanese encephalitis (JE) virus and related flaviviruses in northern Australia, 153,529 mosquitoes were collected and processed for virus isolation from the Gulf Plains region of northwest Queensland. Collections from within 30 km of each of the townships of Croydon, Normanton and Karumba yielded 3,087 (2.0%), 66,009 (43.0%), and 84,433 (55.0%) mosquitoes, respectively, from which 16 viruses were isolated. Four isolates of Murray Valley encephalitis (MVE), two of Kunjin (KUN), three of Ross River (RR), and one of Sindbis (SIN) viruses were obtained from Culex sitiens subgroup mosquitoes. Molecular identification of the mosquito species composition of these virus positive pools revealed that most isolates were from pools containing mainly Culex annulirostris Skuse and low numbers of Culex palpalis (Taylor). Only three pools, one each of MVE, KUN, and RR, were from mosquitoes identified exclusively as Cx. annulirostris. Other viruses isolated include one Edge Hill virus from Ochlerotatus normanensis (Taylor), an isolate of SIN from Anopheles meraukensis Venhuis, two isolates of RR from Anopheles amictus Edwards, and single isolates of RR from Anopheles bancroftii Giles and Aedes lineatopennis (Ludlow). The isolate of RR from Ae. lineatopennis was the first reported from this species. The public health implications of these isolations in the Gulf Plains region are discussed briefly.
- Published
- 2002
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38. Epizootic activity of Murray Valley encephalitis virus in an aboriginal community in the southeast Kimberley region of Western Australia: results of cross-sectional and longitudinal serologic studies
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A.E. Wright, Alexander F. Broom, John S. Mackenzie, Michael D. A. Lindsay, Robert J. Condon, and Aileen J. Plant
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Adult ,Longitudinal study ,Native Hawaiian or Other Pacific Islander ,Adolescent ,Population ,Encephalitis Virus, Murray Valley ,medicine.disease_cause ,Murray Valley encephalitis virus ,Disease Outbreaks ,Virology ,Humans ,Medicine ,Longitudinal Studies ,Seroconversion ,Child ,education ,Epizootic ,Subclinical infection ,education.field_of_study ,biology ,business.industry ,Encephalitis, Arbovirus ,Infant, Newborn ,Infant ,Western Australia ,Middle Aged ,medicine.disease ,biology.organism_classification ,Flavivirus ,Cross-Sectional Studies ,Infectious Diseases ,Child, Preschool ,Parasitology ,business ,Encephalitis ,Demography - Abstract
Murray Valley encephalitis (MVE) virus is a mosquito-borne flavivirus causing severe encephalitis with a resultant high morbidity and mortality. In the period 1989-1993, we undertook a cross-sectional and longitudinal study by annually screening members of a small remote Aboriginal community in northwestern Australia for MVE virus antibodies. Of the estimated 250-300 people in the community, 249 were tested, and 52.6% had positive serology to MVE. The proportion testing positive increased with increasing age group, and males were slightly more likely to be positive than females. During the study period, a high proportion of the population seroconverted to MVE; the clinical/subclinical ratio seems to be lower than previously reported. Although MVE is mostly asymptomatic, the devastating consequences of clinical illness indicate that advice should be provided regarding the avoidance of mosquito bites. Our longitudinal study showed that the risk of seroconversion was similar for each age group, not just the young.
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- 2002
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39. Investigation of the Southern Limits of Murray Valley Encephalitis Activity in Western Australia During the 2000 Wet Season
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Susan A. Harrington, David Smith, Annette K. Broom, and Michael D. A. Lindsay
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Wet season ,Veterinary medicine ,Time Factors ,Rain ,Encephalitis Virus, Murray Valley ,Antibodies, Viral ,medicine.disease_cause ,Microbiology ,Murray Valley encephalitis virus ,Disease Outbreaks ,Virology ,medicine ,Animals ,Humans ,Data Collection ,Encephalitis, Arbovirus ,Outbreak ,Western Australia ,Culicidae ,Infectious Diseases ,Geography ,Murray valley encephalitis ,Seasons ,Chickens ,Sentinel Surveillance - Abstract
Western Australia experienced its worst-ever outbreak of the mosquito-borne Murray Valley encephalitis (MVE) virus during the 2000 wet season. Highest-on-record rainfall throughout much of the state during the 2000 wet season gave rise to extensive mosquito breeding and increased MVE virus transmission, resulting in nine cases of encephalitis. Activity of MVE virus in Western Australia is monitored by detecting MVE virus-specific antibodies in serum from sentinel chickens, located at towns and communities throughout the north of the state. However, during 2000, all 28 flocks of chickens seroconverted to MVE virus, including a flock located600 km further south than MVE virus activity had ever previously been recorded. Furthermore, the majority of the nine cases of encephalitis occurred outside the enzootic Kimberley region. We therefore undertook a major serosurvey of domestic chicken flocks both south and east of the previously defined regions of virus activity. The results suggest that MVE virus activity extended as far south as the Midwest and northern Goldfields during 2000. A new southern limit of activity of MVE virus is therefore proposed. The results have implications for managing outbreaks of MVE virus in Western Australia and have enabled us to locate additional sentinel flocks as part of the MVE surveillance program for future years.
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- 2002
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40. Visual detection of murray valley encephalitis virus by reverse transcription loop-mediated isothermal amplification
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Rui, Gong, Han Hua, Wang, Hong, Qin, Xiao Ping, Guo, and Xue Jun, Ma
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Base Sequence ,Transcription, Genetic ,Limit of Detection ,Encephalitis Virus, Murray Valley ,DNA Primers - Abstract
A sensitive reverse transcription loop-mediated isothermal amplification (RT-LAMP) assay was developed for rapid visual detection of Murray valley encephalitis virus (MVEV) infection. The reaction was performed in one step in a single tube at 63 °C for 60 min with the addition of the hydroxynaphthol blue (HNB) dye prior to amplification. The detection limit of the RT-LAMP assay was 100 copies per reaction based on 10-fold dilutions of in vitro transcribed RNA derived from a synthetic MVEV DNA template. No cross-reaction was observed with other encephalitis-associated viruses. The assay was further evaluated using spiked cerebrospinal fluid sample with pseudotype virus containing the NS5 gene of MVEV.
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- 2014
41. Rainfall and sentinel chicken seroconversions predict human cases of Murray Valley encephalitis in the north of Western Australia
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Annette K. Broom, Catarina Antao, John S. Mackenzie, David W. Smith, Cheryl A. Johansen, Linda A. Selvey, and Michael D. A. Lindsay
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Veterinary medicine ,medicine.medical_specialty ,Epidemiology ,Rain ,Encephalitis Virus, Murray Valley ,Arbovirus Infections ,medicine.disease_cause ,Antibodies, Viral ,Population density ,Murray Valley encephalitis virus ,Disease Outbreaks ,medicine ,Environmental factors ,Animals ,Humans ,Seroconversion ,biology ,Murray valley encephalitis ,Sentinel chicken surveillance ,Flavivirus ,Australia ,Encephalitis, Arbovirus ,Outbreak ,Western Australia ,biology.organism_classification ,medicine.disease ,Infectious Diseases ,Geography ,Chickens ,Sentinel Surveillance ,Encephalitis ,Research Article ,Human risk - Abstract
Background Murray Valley encephalitis virus (MVEV) is a flavivirus that occurs in Australia and New Guinea. While clinical cases are uncommon, MVEV can cause severe encephalitis with high mortality. Sentinel chicken surveillance is used at many sites around Australia to provide an early warning system for risk of human infection in areas that have low population density and geographical remoteness. MVEV in Western Australia occurs in areas of low population density and geographical remoteness, resulting in logistical challenges with surveillance systems and few human cases. While epidemiological data has suggested an association between rainfall and MVEV activity in outbreak years, it has not been quantified, and the association between rainfall and sporadic cases is less clear. In this study we analysed 22 years of sentinel chicken and human case data from Western Australia in order to evaluate the effectiveness of sentinel chicken surveillance for MVEV and assess the association between rainfall and MVEV activity. Methods Sentinel chicken seroconversion, human case and rainfall data from the Kimberley and Pilbara regions of Western Australia from 1990 to 2011 were analysed using negative binomial regression. Sentinel chicken seroconversion and human cases were used as dependent variables in the model. The model was then tested against sentinel chicken and rainfall data from 2012 and 2013. Results Sentinel chicken seroconversion preceded all human cases except two in March 1993. Rainfall in the prior three months was significantly associated with both sentinel chicken seroconversion and human cases across the regions of interest. Sentinel chicken seroconversion was also predictive of human cases in the models. The model predicted sentinel chicken seroconversion in the Kimberley but not in the Pilbara, where seroconversions early in 2012 were not predicted. The latter may be due to localised MVEV activity in isolated foci at dams, which do not reflect broader virus activity in the region. Conclusions We showed that rainfall and sentinel chickens provide a useful early warning of MVEV risk to humans across endemic and epidemic areas, and that a combination of the two indicators improves the ability to assess MVEV risk and inform risk management measures. Electronic supplementary material The online version of this article (doi:10.1186/s12879-014-0672-3) contains supplementary material, which is available to authorized users.
- Published
- 2014
42. The structural basis of pathogenic subgenomic flavivirus RNA (sfRNA) production
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Jeffrey S. Kieft, Erich G. Chapman, David A. Costantino, Jeffrey Wilusz, Stephanie L. Moon, Jay C. Nix, and Jennifer L. Rabe
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Exonuclease ,Models, Molecular ,Base pair ,viruses ,Molecular Sequence Data ,Encephalitis Virus, Murray Valley ,Biology ,medicine.disease_cause ,Crystallography, X-Ray ,Article ,medicine ,Nucleotide ,Nucleic acid structure ,Base Pairing ,Subgenomic mRNA ,chemistry.chemical_classification ,Mutation ,Multidisciplinary ,Base Sequence ,RNA ,Virology ,Enzyme ,chemistry ,Exoribonucleases ,biology.protein ,Nucleic Acid Conformation ,RNA, Viral - Abstract
Resisting the Chop Dengue, West Nile, and Yellow Fever viruses are all flaviviruses that have single-stranded RNA genomes and form specific, short flaviviral RNAs (sfRNAs) during infection that cause viral pathogenicity. These sfRNAs are produced by the incomplete degradation of viral RNA by the host-cell exonuclease Xrn1. What stops the host enzyme from completely chopping up the viral RNA? Chapman et al. (p. 307 ) reveal a pseudoknot in the structure of the Xrn1-resistant segment of a sfRNA from Murray Valley Encephalitis Virus, which, perhaps, the host Xrn1 exonuclease cannot untangle.
- Published
- 2014
43. Recent Weather Extremes and Impacts on Agricultural Production and Vector-Borne Disease Outbreak Patterns
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Jennifer Small, James Crutchfield, Kenneth J. Linthicum, Assaf Anyamba, Curt Reynolds, Compton J. Tucker, Seth C. Britch, and Edwin W. Pak
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Environmental Impacts ,Atmospheric Science ,Rift Valley Fever ,Epidemiology ,Climate ,lcsh:Medicine ,Encephalitis Virus, Murray Valley ,Disease Vectors ,Global Health ,Mosquitoes ,Disease Outbreaks ,Russia ,Dengue ,Medicine and Health Sciences ,Public and Occupational Health ,Rift Valley fever ,Spacecraft ,lcsh:Science ,Multidisciplinary ,Ecology ,Geography ,Flooding (psychology) ,Encephalitis, Arbovirus ,Agriculture ,Vegetation ,Africa, Eastern ,Droughts ,Insects ,Infectious Diseases ,Biogeography ,Climatology ,Moderate-resolution imaging spectroradiometer ,Public Health ,Research Article ,Arthropoda ,Crops ,Disease Surveillance ,Ecosystems ,Environmental Epidemiology ,Africa, Southern ,Extreme weather ,Agricultural Production ,Meteorology ,medicine ,Animals ,Agricultural productivity ,Terrestrial Ecology ,Weather ,business.industry ,lcsh:R ,Ecology and Environmental Sciences ,Organisms ,Australia ,Outbreak ,Biology and Life Sciences ,medicine.disease ,Invertebrates ,Floods ,United States ,Earth Sciences ,Bioindicators ,lcsh:Q ,business ,West Nile Fever - Abstract
We document significant worldwide weather anomalies that affected agriculture and vector-borne disease outbreaks during the 2010-2012 period. We utilized 2000-2012 vegetation index and land surface temperature data from NASA's satellite-based Moderate Resolution Imaging Spectroradiometer (MODIS) to map the magnitude and extent of these anomalies for diverse regions including the continental United States, Russia, East Africa, Southern Africa, and Australia. We demonstrate that shifts in temperature and/or precipitation have significant impacts on vegetation patterns with attendant consequences for agriculture and public health. Weather extremes resulted in excessive rainfall and flooding as well as severe drought, which caused ∼10 to 80% variation in major agricultural commodity production (including wheat, corn, cotton, sorghum) and created exceptional conditions for extensive mosquito-borne disease outbreaks of dengue, Rift Valley fever, Murray Valley encephalitis, and West Nile virus disease. Analysis of MODIS data provided a standardized method for quantifying the extreme weather anomalies observed during this period. Assessments of land surface conditions from satellite-based systems such as MODIS can be a valuable tool in national, regional, and global weather impact determinations.
- Published
- 2014
44. Internal Ribosome Entry Site-Based Attenuation of a Flavivirus Candidate Vaccine and Evaluation of the Effect of Beta Interferon Coexpression on Vaccine Properties
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Michael Frese, Eva Lee, Ian A. Ramshaw, Mario Lobigs, Maximilian Larena, Klaus I. Matthaei, Pek Siew Lim, Alexander A. Khromykh, and Sudha Rao
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Myxovirus Resistance Proteins ,viruses ,Immunology ,Antiviral protein ,Encephalitis Virus, Murray Valley ,Kaplan-Meier Estimate ,Biology ,Dengue virus ,Recombinant virus ,medicine.disease_cause ,Microbiology ,Murray Valley encephalitis virus ,Virus ,Mice ,Virology ,Vaccines and Antiviral Agents ,Chlorocebus aethiops ,medicine ,Animals ,Cloning, Molecular ,Encephalomyocarditis virus ,Vero Cells ,DNA Primers ,Immunity, Cellular ,Vaccines, Synthetic ,Attenuated vaccine ,Reverse Transcriptase Polymerase Chain Reaction ,Viral Vaccine ,Viral Vaccines ,Interferon-beta ,biology.organism_classification ,Antibodies, Neutralizing ,Immunohistochemistry ,Mice, Inbred C57BL ,Flavivirus ,Insect Science ,Genetic Engineering ,Ribosomes - Abstract
Infectious clone technologies allow the rational design of live attenuated viral vaccines with the possibility of vaccine-driven coexpression of immunomodulatory molecules for additional vaccine safety and efficacy. The latter could lead to novel strategies for vaccine protection against infectious diseases where traditional approaches have failed. Here we show for the flavivirus Murray Valley encephalitis virus (MVEV) that incorporation of the internal ribosome entry site (IRES) of Encephalomyocarditis virus between the capsid and prM genes strongly attenuated virulence and that the resulting bicistronic virus was both genetically stable and potently immunogenic. Furthermore, the novel bicistronic genome organization facilitated the generation of a recombinant virus carrying an beta interferon (IFN-β) gene. Given the importance of IFNs in limiting virus dissemination and in efficient induction of memory B and T cell antiviral immunity, we hypothesized that coexpression of the cytokine with the live vaccine might further increase virulence attenuation without loss of immunogenicity. We found that bicistronic mouse IFN-β coexpressing MVEV yielded high virus and IFN titers in cultured cells that do not respond to the coexpressed IFN. However, in IFN response-sufficient cell cultures and mice, the virus produced a self-limiting infection. Nevertheless, the attenuated virus triggered robust innate and adaptive immune responses evidenced by the induced expression of Mx proteins (used as a sensitive biomarker for measuring the type I IFN response) and the generation of neutralizing antibodies, respectively. IMPORTANCE The family Flaviviridae includes a number of important human pathogens, such as Dengue virus , Yellow fever virus , Japanese encephalitis virus , West Nile virus , and Hepatitis C virus . Flaviviruses infect large numbers of individuals on all continents. For example, as many as 100 million people are infected annually with Dengue virus , and 150 million people suffer a chronic infection with Hepatitis C virus . However, protective vaccines against dengue and hepatitis C are still missing, and improved vaccines against other flaviviral diseases are needed. The present study investigated the effects of a redesigned flaviviral genome and the coexpression of an antiviral protein (interferon) on virus replication, pathogenicity, and immunogenicity. Our findings may aid in the rational design of a new class of well-tolerated and safe vaccines.
- Published
- 2014
45. Immunogenicity of Two Peptide Determinants in the Cytolytic T-Cell Response to Flavivirus Infection: Inverse Correlation Between Peptide Affinity for MHC Class I and T-Cell Precursor Frequency
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Mario Lobigs, Arno Müllbacher, Robert V. Blanden, and Matthias Regner
- Subjects
T cell ,Immunology ,Antigen presentation ,Dose-Response Relationship, Immunologic ,Encephalitis Virus, Murray Valley ,Immunodominance ,Major histocompatibility complex ,Interferon-gamma ,Mice ,Viral Proteins ,Virology ,MHC class I ,medicine ,Animals ,Cytotoxic T cell ,biology ,Histocompatibility Antigens Class I ,MHC restriction ,Hematopoietic Stem Cells ,Molecular biology ,medicine.anatomical_structure ,Mice, Inbred CBA ,biology.protein ,Molecular Medicine ,Female ,Immunologic Memory ,CD8 ,T-Lymphocytes, Cytotoxic - Abstract
We used the CD8+ cytotoxic T (Tc) cell immune response against the flavivirus, Murray Valley encephalitis virus (MVE), restricted by the H-2Kk major histocompatibility complex (MHC) class I molecule, to investigate immunodominance. Split-clone limiting dilution analysis revealed almost exclusive recognition of two peptides, MVE1785 and MVE1971, derived from the viral NS3 protein. The precursor frequency of MVE-reactive Tc cells was determined by limiting dilution analysis for cytotoxic function and intracellular staining for interferon-gamma; the latter gave a 100-fold higher estimate of MVE-reactive Tc cell precursors. MHC class I cell surface stabilization assays revealed that affinity for H-2Kk as well as halflives of the peptide-H-2Kk-complexes were markedly different for the two peptides. However, a kinetic study of antigen presentation showed that both peptides are presented for recognition by Tc cells with a comparable kinetics during the latent period of virus infection. Nevertheless, the lower affinity peptide MVE1785 elicited roughly twofold more Tc cell clones than the high-affinity peptide MVE1971. While the cytolytic activity against both determinants was similar after in vitro restimulation at the peak of the primary response, the smaller pool of memory anti-MVE1971 Tc cells correlated with an impaired memory response against that determinant, suggesting that the available T-cell repertoire is a major factor influencing the establishment of T-cell memory.
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- 2001
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46. Substitutions at the Putative Receptor-Binding Site of an Encephalitic Flavivirus Alter Virulence and Host Cell Tropism and Reveal a Role for Glycosaminoglycans in Entry
- Author
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Eva Lee and Mario Lobigs
- Subjects
viruses ,Immunology ,Virulence ,Encephalitis Virus, Murray Valley ,Virus Replication ,medicine.disease_cause ,Microbiology ,Murray Valley encephalitis virus ,Virus ,Mice ,Viral Envelope Proteins ,Viral entry ,Mutant protein ,Virology ,medicine ,Animals ,Tropism ,Glycosaminoglycans ,RGD motif ,biology ,biology.organism_classification ,Virus-Cell Interactions ,Flavivirus ,Insect Science ,Receptors, Virus - Abstract
The flavivirus receptor-binding domain has been putatively assigned to a hydrophilic region (FG loop) in the envelope (E) protein. In some flaviviruses this domain harbors the integrin-binding motif Arg-Gly-Asp (RGD). One of us has shown earlier that host cell adaptation of Murray Valley encephalitis virus (MVE) can result in the selection of attenuated variants altered at E protein residue Asp 390 , which is part of an RGD motif. Here, a full-length, infectious cDNA clone of MVE was constructed and employed to systematically investigate the impact of single amino acid changes at Asp 390 on cell tropism, virus entry, and virulence. Each of 10 different E protein 390 mutants was viable. Three mutants (Gly 390 , Ala 390 , and His 390 ) showed pronounced differences from an infectious clone-derived control virus in growth in mammalian and mosquito cells. The altered cell tropism correlated with (i) a difference in entry kinetics, (ii) an increased dependence on glycosaminoglycans (determined by inhibition of virus infectivity by heparin) for attachment of the three mutants to different mammalian cells, and (iii) the loss of virulence in mice. These results confirm a functional role of the FG loop in the flavivirus E protein in virus entry and suggest that encephalitic flaviviruses can enter cells via attachment to glycosaminoglycans. However, it appears that additional cell surface molecules are also used as receptors by natural isolates of MVE and that the increased dependence on glycosaminoglycans for entry results in the loss of neuroinvasiveness.
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- 2000
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47. Characterization of infectious Murray Valley encephalitis virus derived from a stably cloned genome-length cDNA
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Ann Nestorowicz, Robert J. Hurrelbrink, and Peter C. McMinn
- Subjects
DNA, Complementary ,viruses ,Molecular Sequence Data ,Clone (cell biology) ,Fluorescent Antibody Technique ,Encephalitis Virus, Murray Valley ,Viral Plaque Assay ,Virus Replication ,medicine.disease_cause ,Murray Valley encephalitis virus ,Virus ,Cell Line ,Mice ,Rapid amplification of cDNA ends ,Virology ,Complementary DNA ,Chlorocebus aethiops ,medicine ,Animals ,Cloning, Molecular ,3' Untranslated Regions ,Vero Cells ,Virus quantification ,Base Sequence ,Virulence ,biology ,Reverse Transcriptase Polymerase Chain Reaction ,cDNA library ,Encephalitis, Arbovirus ,biology.organism_classification ,Precipitin Tests ,Molecular biology ,Flavivirus ,Mutagenesis, Site-Directed ,RNA, Viral - Abstract
An infectious cDNA clone of Murray Valley encephalitis virus prototype strain 1-51 (MVE-1-51) was constructed by stably inserting genome-length cDNA into the low-copy-number plasmid vector pMC18. Designated pMVE-1-51, the clone consisted of genome-length cDNA of MVE-1-51 under the control of a T7 RNA polymerase promoter. The clone was constructed by using existing components of a cDNA library, in addition to cDNA of the 3′ terminus derived by RT–PCR of poly(A)-tailed viral RNA. Upon comparison with other flavivirus sequences, the previously undetermined sequence of the 3′ UTR was found to contain elements conserved throughout the genus Flavivirus. RNA transcribed from pMVE-1-51 and subsequently transfected into BHK-21 cells generated infectious virus. The plaque morphology, replication kinetics and antigenic profile of clone-derived virus (CDV-1-51) was similar to the parental virus in vitro. Furthermore, the virulence properties of CDV-1-51 and MVE-1-51 (LD50 values and mortality profiles) were found to be identical in vivo in the mouse model. Through site-directed mutagenesis, the infectious clone should serve as a valuable tool for investigating the molecular determinants of virulence in MVE virus.
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- 1999
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48. The Severity of Murray Valley Encephalitis in Mice Is Linked to Neutrophil Infiltration and Inducible Nitric Oxide Synthase Activity in the Central Nervous System
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Leanne Sammels, Vance B. Matthews, Daniel M. Andrews, A.C. Carrello, and P.C. Mcminn
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Central Nervous System ,Chemokine ,Immunology ,Central nervous system ,Nitric Oxide Synthase Type II ,Encephalitis Virus, Murray Valley ,medicine.disease_cause ,Microbiology ,Murray Valley encephalitis virus ,Neutrophil Activation ,Mice ,Virology ,medicine ,Animals ,biology ,Encephalitis, Arbovirus ,medicine.disease ,Nitric oxide synthase ,medicine.anatomical_structure ,Cerebral cortex ,Insect Science ,biology.protein ,Pathogenesis and Immunity ,Tumor necrosis factor alpha ,Nitric Oxide Synthase ,Infiltration (medical) ,Encephalitis - Abstract
A study of immunopathology in the central nervous system (CNS) during infection with a virulent strain of Murray Valley encephalitis virus (MVE) in weanling Swiss mice following peripheral inoculation is presented. It has previously been shown that virus enters the murine CNS 4 days after peripheral inoculation, spreads to the anterior olfactory nucleus, the pyriform cortex, and the hippocampal formation at 5 days postinfection (p.i.), and then spreads throughout the cerebral cortex, caudate putamen, thalamus, and brain stem between 6 and 9 days p.i. (P. C. McMinn, L. Dalgarno, and R. C. Weir, Virology 220:414–423, 1996). Here we show that the encephalitis which develops in MVE-infected mice from 5 days p.i. is associated with the development of a neutrophil inflammatory response in perivascular regions and in the CNS parenchyma. Infiltration of neutrophils into the CNS was preceded by increased expression of tumor necrosis factor alpha and the neutrophil-attracting chemokine N51/KC within the CNS. Depletion of neutrophils with a cytotoxic monoclonal antibody (RB6-8C5) resulted in prolonged survival and decreased mortality in MVE-infected mice. In addition, neutrophil infiltration and disease onset correlated with expression of the enzyme-inducible nitric oxide synthase (iNOS) within the CNS. Inhibition of iNOS by aminoguanidine resulted in prolonged survival and decreased mortality in MVE-infected mice. This study provides strong support for the hypothesis that Murray Valley encephalitis is primarily an immunopathological disease.
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- 1999
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49. Australian encephalitis in the Northern Territory: clinical and epidemiological features, 1987-1996
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P. I. Whelan, Dale Fisher, D. W. Smith, C. J. Kilburn, Bart J. Currie, and J. Burrow
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Adult ,Male ,Pediatrics ,medicine.medical_specialty ,Encephalitis Virus, Murray Valley ,medicine.disease_cause ,Murray Valley encephalitis virus ,Flaviviridae ,Epidemiology ,Northern Territory ,Internal Medicine ,Humans ,Medicine ,Seroconversion ,biology ,business.industry ,Encephalitis, Arbovirus ,Infant ,Outbreak ,Middle Aged ,medicine.disease ,biology.organism_classification ,Virology ,Flavivirus ,Child, Preschool ,Female ,Viral disease ,business ,Encephalitis - Abstract
Background: The last epidemic of Australian encephalitis occurred in 1974. Since then, cases have been reported from the Kimberley of Western Australia (WA). Aims: To describe the epidemiology and clinical features of Australian encephalitis in the Northern Territory (NT) of Australia. Methods: Review of cases of Australian encephalitis presenting to Royal Darwin Hospital from 1987-1996 and review of sentinel chicken surveillance for Australian encephalitis viruses. Results: Sixteen patients were identified; ten from the NT and six from WA. Cases occurred in the years 1987, 1988, 1991 and 1993. Infection was acquired throughout northern NT below latitude 20°S in the months March to July. All infections were due to Murray Valley encephalitis (MVE) virus. Eleven of the patients were children. Distinguishing features were spinal cord and brainstem involvement and the absence of seizures in adults. CT scanning was normal and EEG showed no focal activity. Five died (31%) and four (25%) have residual neurological disability. Sentinel chicken surveillance since 1992 shows yearly seroconversion to MVE virus throughout northern NT; human cases occurred simultaneously with chicken seroconversion in 1993. Conclusions: Australian encephalitis is endemic in the NT; the areas at risk are north of Tennant Creek. Outbreaks are seasonal and occur every few years. Young children are most at risk. Mortality and morbidity are high. Prevention of disease is by avoidance of mosquito exposure and vector control measures.
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- 1998
- Full Text
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50. DNA-Based and Alphavirus-Vectored Immunisation with PrM and E Proteins Elicits Long-Lived and Protective Immunity against the Flavivirus, Murray Valley Encephalitis Virus
- Author
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G. Colombage, Roy A. Hall, Mario Lobigs, and Megan Pavy
- Subjects
Recombinant Fusion Proteins ,viruses ,Genetic Vectors ,Mice, Inbred Strains ,Alphavirus ,Encephalitis Virus, Murray Valley ,Recombinant virus ,Semliki Forest virus ,medicine.disease_cause ,Antibodies, Viral ,Murray Valley encephalitis virus ,Virus ,DNA vaccination ,Mice ,Viral Envelope Proteins ,Neutralization Tests ,Virology ,medicine ,Vaccines, DNA ,Animals ,Replicon ,biology ,Vaccination ,Encephalitis, Arbovirus ,Viral Vaccines ,Biolistics ,biology.organism_classification ,Semliki forest virus ,Flavivirus ,Immunoglobulin G ,COS Cells ,Plasmids - Abstract
The immunogenicity and protective efficacy of DNA-based vaccination with plasmids encoding the membrane proteins prM and E of the flavivirus Murray Valley encephalitis virus (MVE) were investigated. Gene gun-mediated intradermal delivery of DNA encoding the prM and E proteins elicited long-lived, virus-neutralising antibody responses in three inbred strains of mice and provided protection from challenge with a high titer inoculum of MVE. Intramuscular DNA vaccination by needle injection also induced MVE-specific antibodies that conferred resistance to challenge with live virus but failed to reduce virus infectivity in vitro . The two routes of DNA-based vaccination with prM and E encoding plasmids resulted in humoral immunty with distinct IgG subtypes. MVE-specific IgG 1 antibodies were always prevalent after intradermal DNA vaccination via a gene gun but not detected when mice were immunised with DNA by the intramuscular route or infected with live virus. We also tested a Semliki Forest virus replicon as vector for a flavivirus prM and E protein-based subunit vaccine. Single-cycle infections in mice vaccinated with packaged recombinant replicon particles elicited durable, MVE-specific, and virus-neutralising antibody responses.
- Published
- 1998
- Full Text
- View/download PDF
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