Your search keyword '"Horses virology"' showing total 21 results

1. Equine Herpesvirus 1 Variant and New Marker for Epidemiologic Surveillance, Europe, 2021.

Author

Sutton G, Normand C, Carnet F, Couroucé A, Garvey M, Castagnet S, Fortier CI, Hue ES, Marcillaud-Pitel C, Legrand L, Paillot R, Pitel PH, Cullinane A, and Pronost S

Subjects

Animals, Epidemiological Monitoring, Europe epidemiology, Herpesviridae Infections epidemiology, Horses virology, Open Reading Frames, Herpesviridae Infections veterinary, Herpesvirus 1, Equid genetics, Horse Diseases epidemiology

Abstract

Equine herpesvirus 1 isolates from a 2021 outbreak of neurologic disease in Europe have a mutation, A713G, in open reading frame 11 not detected in 249 other sequences from equine herpesvirus 1 isolates. This single-nucleotide polymorphism could help identify horses infected with the virus strain linked to this outbreak.

Published

2021

2. West Nile Virus Lineage 2 in Horses and Other Animals with Neurologic Disease, South Africa, 2008-2015.

Author

Venter M, Pretorius M, Fuller JA, Botha E, Rakgotho M, Stivaktas V, Weyer C, Romito M, and Williams J

Subjects

Animals, Culex virology, Epidemiological Monitoring, Horse Diseases, Horses virology, Humans, Mosquito Vectors virology, Nervous System Diseases epidemiology, Nervous System Diseases mortality, Nervous System Diseases virology, Prevalence, Prospective Studies, Seasons, South Africa epidemiology, Survival Analysis, West Nile Fever epidemiology, West Nile Fever mortality, West Nile Fever virology, West Nile virus classification, West Nile virus isolation & purification, West Nile virus pathogenicity, Antibodies, Viral blood, Nervous System Diseases veterinary, RNA, Viral genetics, Veterinarians, West Nile Fever veterinary, West Nile virus genetics

Abstract

During 2008-2015 in South Africa, we conducted West Nile virus surveillance in 1,407 animals with neurologic disease and identified mostly lineage 2 cases in horses (7.4%, 79/1,069), livestock (1.5%, 2/132), and wildlife (0.5%, 1/206); 35% were fatal. Geographic correlation of horse cases with seropositive veterinarians suggests disease in horses can predict risk in humans.

Published

2017

3. Hendra Virus Infection in Dog, Australia, 2013.

Author

Kirkland PD, Gabor M, Poe I, Neale K, Chaffey K, Finlaison DS, Gu X, Hick PM, Read AJ, Wright T, and Middleton D

Subjects

Animals, Chiroptera virology, Dogs blood, Henipavirus Infections virology, Horse Diseases virology, Horses virology, Queensland, Viral Load veterinary, Zoonoses virology, Dogs virology, Hendra Virus pathogenicity, Henipavirus Infections transmission, Zoonoses transmission

Abstract

Hendra virus occasionally causes severe disease in horses and humans. In Australia in 2013, infection was detected in a dog that had been in contact with an infected horse. Abnormalities and viral RNA were found in the dog's kidney, brain, lymph nodes, spleen, and liver. Dogs should be kept away from infected horses.

Published

2015

4. Sindbis and Middelburg Old World Alphaviruses Associated with Neurologic Disease in Horses, South Africa.

Author

van Niekerk S, Human S, Williams J, van Wilpe E, Pretorius M, Swanepoel R, and Venter M

Subjects

Alphavirus genetics, Animals, Horses genetics, Humans, Phylogeny, Sindbis Virus genetics, South Africa epidemiology, Horses virology, Sindbis Virus pathogenicity, Zoonoses epidemiology

Abstract

Old World alphaviruses were identified in 52 of 623 horses with febrile or neurologic disease in South Africa. Five of 8 Sindbis virus infections were mild; 2 of 3 fatal cases involved co-infections. Of 44 Middelburg virus infections, 28 caused neurologic disease; 12 were fatal. Middelburg virus likely has zoonotic potential.

Published

2015

5. Serologic assessment of possibility for MERS-CoV infection in equids.

Author

Meyer B, García-Bocanegra I, Wernery U, Wernery R, Sieberg A, Müller MA, Drexler JF, Drosten C, and Eckerle I

Subjects

Animals, Antibodies, Viral blood, Chlorocebus aethiops, Coronavirus Infections blood, Coronavirus Infections immunology, Disease Reservoirs virology, Horse Diseases blood, Horse Diseases immunology, Vero Cells, Coronavirus Infections veterinary, Horse Diseases virology, Horses virology, Middle East Respiratory Syndrome Coronavirus physiology, Virus Replication

Published

2015

6. Influenza virus transmission from horses to dogs, Australia.

Author

Kirkland PD, Finlaison DS, Crispe E, and Hurt AC

Subjects

Amino Acid Sequence, Animals, Australia epidemiology, Dogs virology, Horse Diseases transmission, Horses virology, Molecular Sequence Data, Orthomyxoviridae Infections epidemiology, Orthomyxoviridae Infections transmission, Orthomyxoviridae Infections virology, Phylogeny, Dog Diseases virology, Horse Diseases virology, Influenza A Virus, H3N8 Subtype genetics, Influenza A Virus, H3N8 Subtype pathogenicity, Orthomyxoviridae Infections veterinary

Abstract

During the 2007 equine influenza outbreak in Australia, respiratory disease in dogs in close contact with infected horses was noted; influenza (H3N8) virus infection was confirmed. Nucleotide sequence of the virus from dogs was identical to that from horses. No evidence of dog-to-dog transmission or virus persistence in dogs was found.

Published

2010

7. New hosts for equine herpesvirus 9.

Author

Schrenzel MD, Tucker TA, Donovan TA, Busch MD, Wise AG, Maes RK, and Kiupel M

Subjects

Animals, Animals, Zoo virology, Base Sequence, California, DNA, Viral genetics, Disease Reservoirs virology, Herpesviridae Infections transmission, Herpesviridae Infections veterinary, Herpesviridae Infections virology, Horse Diseases transmission, Horse Diseases virology, Horses virology, Species Specificity, Varicellovirus genetics, Varicellovirus pathogenicity, Equidae virology, Ursidae virology, Varicellovirus isolation & purification

Abstract

Equine herpesvirus 9 was detected in a polar bear with progressive encephalitis; the source was traced to 2 members of a potential equid reservoir species, Grevy's zebras. The virus was also found in an aborted Persian onager. Thus, the natural host range is extended to 6 species in 3 mammalian orders.

Published

2008

8. Magpies as hosts for West Nile virus, southern France.

Author

Jourdain E, Gauthier-Clerc M, Sabatier P, Grège O, Greenland T, Leblond A, Lafaye M, and Zeller HG

Subjects

Animals, Feces virology, France epidemiology, Horse Diseases virology, Horses virology, Sentinel Surveillance veterinary, Seroepidemiologic Studies, Topography, Medical, Disease Reservoirs veterinary, Disease Reservoirs virology, Passeriformes virology, West Nile Fever epidemiology, West Nile virus

Abstract

European magpies (Pica pica) from southern France were tested for antibodies to West Nile virus (WNV) and viral shedding in feces during spring-autumn 2005. Results suggest that this peridomestic species may be a suitable sentinel species and a relevant target for additional investigations on WNV ecology in Europe.

Published

2008

9. West Nile virus, Venezuela.

Author

Bosch I, Herrera F, Navarro JC, Lentino M, Dupuis A, Maffei J, Jones M, Fernández E, Pérez N, Pérez-Emán J, Guimarães AE, Barrera R, Valero N, Ruiz J, Velásquez G, Martinez J, Comach G, Komar N, Spielman A, and Kramer L

Subjects

Animals, Bird Diseases virology, Birds virology, Chickens virology, Horse Diseases virology, Horses virology, Poultry Diseases virology, Venezuela epidemiology, West Nile Fever epidemiology, Antibodies, Viral blood, Bird Diseases epidemiology, Horse Diseases epidemiology, Poultry Diseases epidemiology, West Nile Fever veterinary, West Nile virus immunology

Published

2007

10. Introductions of West Nile virus strains to Mexico.

Author

Deardorff E, Estrada-Franco J, Brault AC, Navarro-Lopez R, Campomanes-Cortes A, Paz-Ramirez P, Solis-Hernandez M, Ramey WN, Davis CT, Beasley DW, Tesh RB, Barrett AD, and Weaver SC

Subjects

Animals, Bird Diseases epidemiology, Bird Diseases virology, Birds classification, Birds virology, Crows virology, Culex virology, Horse Diseases epidemiology, Horse Diseases virology, Horses virology, Humans, Mexico epidemiology, Mice, Molecular Sequence Data, Sequence Analysis, DNA, United States, Virulence, West Nile Fever virology, West Nile virus classification, West Nile virus genetics, West Nile virus pathogenicity, West Nile Fever epidemiology, West Nile virus isolation & purification

Abstract

Complete genome sequencing of 22 West Nile virus isolates suggested 2 independent introductions into Mexico. A previously identified mouse-attenuated glycosylation variant was introduced into southern Mexico through the southeastern United States, while a common US genotype appears to have been introduced incrementally into northern Mexico through the southwestern United States.

Published

2006

11. Postepizootic persistence of Venezuelan equine encephalitis virus, Venezuela.

Author

Navarro JC, Medina G, Vasquez C, Coffey LL, Wang E, Suárez A, Biord H, Salas M, and Weaver SC

Subjects

Animals, Cattle, Culicidae virology, Didelphis virology, Disease Reservoirs virology, Encephalitis Virus, Venezuelan Equine genetics, Encephalomyelitis, Venezuelan Equine blood, Horses blood, Humans, Murinae virology, Phylogeny, Seasons, Sentinel Surveillance, Venezuela epidemiology, Disease Outbreaks, Encephalitis Virus, Venezuelan Equine isolation & purification, Encephalomyelitis, Venezuelan Equine epidemiology, Encephalomyelitis, Venezuelan Equine virology, Horses virology

Abstract

Five years after the apparent end of the major 1995 Venezuelan equine encephalitis (VEE) epizootic/epidemic, focal outbreaks of equine encephalitis occurred in Carabobo and Barinas States of western Venezuela. Virus isolates from horses in each location were nearly identical in sequence to 1995 isolates, which suggests natural persistence of subtype IC VEE virus (VEEV) strains in a genetically stable mode. Serologic evidence indicated that additional outbreaks occurred in Barinas State in 2003. Field studies identified known Culex (Melanoconion) spp. vectors and reservoir hosts of enzootic VEEV but a dearth of typical epidemic vectors. Cattle serosurveys indicated the recent circulation of enzootic VEEV strains, and possibly of epizootic strains. Persistence of VEEV subtype IC strains and infection of horses at the end of the rainy season suggest the possibility of an alternative, cryptic transmission cycle involving survival through the dry season of infected vectors or persistently infected vertebrates.

Published

2005

12. Phylogenetic analysis of West Nile virus, Nuevo Leon State, Mexico.

Author

Blitvich BJ, Fernández-Salas I, Contreras-Cordero JF, Loroño-Pino MA, Marlenee NL, Díaz FJ, González-Rojas JI, Obregón-Martínez N, Chiu-García JA, Black WC 4th, and Beaty BJ

Subjects

Animals, Horse Diseases epidemiology, Horses virology, Male, Mexico epidemiology, Molecular Sequence Data, Sequence Analysis, DNA, Viral Envelope Proteins genetics, West Nile Fever epidemiology, West Nile Fever virology, West Nile virus classification, West Nile virus isolation & purification, Horse Diseases virology, Phylogeny, West Nile Fever veterinary, West Nile virus genetics

Abstract

West Nile virus RNA was detected in brain tissue from a horse that died in June 2003 in Nuevo Leon State, Mexico. Nucleotide sequencing and phylogenetic analysis of the premembrane and envelope genes showed that the virus was most closely related to West Nile virus isolates collected in Texas in 2002.

Published

2004

13. West Nile virus, Guadeloupe.

Author

Quirin R, Salas M, Zientara S, Zeller H, Labie J, Murri S, Lefrançois T, Petitclerc M, and Martinez D

Subjects

Animals, Antibodies, Viral blood, Chickens virology, Cross-Sectional Studies, Enzyme-Linked Immunosorbent Assay, Guadeloupe, Neutralization Tests, West Nile virus immunology, Birds virology, Horses virology, West Nile virus isolation & purification

Abstract

To determine whether West Nile virus (WNV) had reached the archipelago of Guadeloupe, a serologic study in horses and birds was conducted in 2002. Immunoglobulin (Ig) G, IgM, enzyme-linked immunosorbent assay, and seroneutralization tests identified WNV infection in horses and chickens. Six months later, a high rate of seroconversion was observed in horses.

Published

2004

14. West Nile virus in farmed alligators.

Author

Miller DL, Mauel MJ, Baldwin C, Burtle G, Ingram D, Hines ME 2nd, and Frazier KS

Subjects

Animals, Antibodies, Viral isolation & purification, Bacterial Infections complications, Bacterial Infections veterinary, Female, Horses virology, Male, RNA, Viral isolation & purification, Reverse Transcriptase Polymerase Chain Reaction, West Nile Fever complications, West Nile Fever diagnosis, West Nile Fever immunology, West Nile virus genetics, West Nile virus immunology, Alligators and Crocodiles virology, West Nile Fever veterinary, West Nile virus isolation & purification

Abstract

Seven alligators were submitted to the Tifton Veterinary Diagnostic and Investigational Laboratory for necropsy during two epizootics in the fall of 2001 and 2002. The alligators were raised in temperature-controlled buildings and fed a diet of horsemeat supplemented with vitamins and minerals. Histologic findings in the juvenile alligators were multiorgan necrosis, heterophilic granulomas, and heterophilic perivasculitis and were most indicative of septicemia or bacteremia. Histologic findings in a hatchling alligator were random foci of necrosis in multiple organs and mononuclear perivascular encephalitis, indicative of a viral cause. West Nile virus was isolated from submissions in 2002. Reverse transcription-polymerase chain reaction (RT-PCR) results on all submitted case samples were positive for West Nile virus for one of four cases associated with the 2001 epizootic and three of three cases associated with the 2002 epizootic. RT-PCR analysis was positive for West Nile virus in the horsemeat collected during the 2002 outbreak but negative in the horsemeat collected after the outbreak.

Published

2003

15. Serologic evidence of West Nile virus infection in horses, Coahuila State, Mexico.

Author

Blitvich BJ, Fernandez-Salas I, Contreras-Cordero JF, Marlenee NL, Gonzalez-Rojas JI, Komar N, Gubler DJ, Calisher CH, and Beaty BJ

Subjects

Animals, Antibodies, Viral blood, Horses virology, Mexico epidemiology, West Nile Fever immunology, West Nile virus immunology, West Nile virus isolation & purification, Horse Diseases epidemiology, Horse Diseases virology, West Nile Fever epidemiology, West Nile Fever veterinary

Abstract

Serum samples were obtained from 24 horses in the State of Coahuila, Mexico, in December 2002. Antibodies to West Nile virus were detected by epitope-blocking enzyme-linked immunosorbent assay and confirmed by plaque reduction neutralization test in 15 (62.5%) horses. We report the first West Nile virus activity in northern Mexico.

Published

2003

16. Phylogenetic relationships of southern African West Nile virus isolates.

Author

Burt FJ, Grobbelaar AA, Leman PA, Anthony FS, Gibson GV, and Swanepoel R

Subjects

Aedes virology, Africa, Southern, Animals, Birds virology, Culex virology, Dogs, Horses virology, Humans, Reverse Transcriptase Polymerase Chain Reaction, Evolution, Molecular, Phylogeny, West Nile Fever virology, West Nile virus genetics, West Nile virus isolation & purification

Abstract

Phylogenetic relationships were examined for 29 southern African West Nile virus (formal name West Nile virus [WNV]) isolates from various sources in four countries from 1958 to 2001. In addition, sequence data were retrieved from GenBank for another 23 WNV isolates and Kunjin and Japanese encephalitis viruses. All isolates belonged to two lineages. Lineage 1 isolates were from central and North Africa, Europe, Israel, and North America; lineage 2 isolates were from central and southern Africa and Madagascar. No strict correlation existed between grouping and source of virus isolate, pathogenicity, geographic distribution, or year of isolation. Some southern African isolates have been associated with encephalitis in a human, a horse, and a dog and with fatal hepatitis in a human and death of an ostrich chick.

Published

2002

17. Experimental infection of horses with West Nile virus.

Author

Bunning ML, Bowen RA, Cropp CB, Sullivan KG, Davis BS, Komar N, Godsey MS, Baker D, Hettler DL, Holmes DA, Biggerstaff BJ, and Mitchell CJ

Subjects

Aedes physiology, Aedes virology, Animals, Antibodies, Viral blood, Antibodies, Viral immunology, Bird Diseases virology, Brain virology, Chlorocebus aethiops, Female, Horse Diseases blood, Horse Diseases immunology, Horse Diseases transmission, Horse Diseases virology, Horses blood, Horses immunology, Insect Vectors physiology, Insect Vectors virology, Male, Saliva immunology, Saliva virology, Songbirds virology, Vero Cells, Viremia blood, Viremia immunology, Viremia transmission, Viremia virology, West Nile Fever blood, West Nile Fever immunology, West Nile Fever virology, West Nile virus immunology, Horses virology, West Nile Fever transmission, West Nile virus physiology

Abstract

A total of 12 horses of different breeds and ages were infected with West Nile virus (WNV) via the bites of infected Aedes albopictus mosquitoes. Half the horses were infected with a viral isolate from the brain of a horse (BC787), and half were infected with an isolate from crow brain (NY99-6625); both were NY99 isolates. Postinfection, uninfected female Ae. albopictus fed on eight of the infected horses. In the first trial, Nt antibody titers reached >1:320, 1:20, 1:160, and 1:80 for horses 1 to 4, respectively. In the second trial, the seven horses with subclinical infections developed Nt antibody titers >1:10 between days 7 and 11 post infection. The highest viremia level in horses fed upon by the recipient mosquitoes was approximately 460 Vero cell PFU/mL. All mosquitoes that fed upon viremic horses were negative for the virus. Horses infected with the NY99 strain of WNV develop low viremia levels of short duration; therefore, infected horses are unlikely to serve as important amplifying hosts for WNV in nature.

Published

2002

18. Detection of North American West Nile virus in animal tissue by a reverse transcription-nested polymerase chain reaction assay.

Author

Johnson DJ, Ostlund EN, Pedersen DD, and Schmitt BJ

Subjects

Animals, Bird Diseases epidemiology, Bird Diseases pathology, Birds virology, Brain pathology, Brain virology, Horse Diseases epidemiology, Horse Diseases pathology, Horses virology, New York epidemiology, North America, RNA, Viral analysis, Reverse Transcriptase Polymerase Chain Reaction, Sensitivity and Specificity, West Nile Fever epidemiology, West Nile Fever pathology, West Nile Fever virology, West Nile virus genetics, Bird Diseases virology, Disease Reservoirs veterinary, Horse Diseases virology, West Nile Fever veterinary, West Nile virus isolation & purification

Abstract

A traditional single-stage reverse transcription-polymerase chain reaction (RT-PCR) procedure is effective in determining West Nile (WN) virus in avian tissue and infected cell cultures. However, the procedure lacks the sensitivity to detect WN virus in equine tissue. We describe an RT-nested PCR (RT-nPCR) procedure that identifies the North American strain of WN virus directly in equine and avian tissues.

Published

2001

19. West Nile virus surveillance in Connecticut in 2000: an intense epizootic without high risk for severe human disease.

Author

Hadler J, Nelson R, McCarthy T, Andreadis T, Lis MJ, French R, Beckwith W, Mayo D, Archambault G, and Cartter M

Subjects

Animals, Bird Diseases epidemiology, Bird Diseases mortality, Birds virology, Connecticut epidemiology, Culex virology, Culicidae virology, Horse Diseases epidemiology, Horse Diseases mortality, Horses virology, Humans, Insect Vectors virology, Prospective Studies, Risk Factors, Seroepidemiologic Studies, Songbirds, West Nile Fever mortality, West Nile Fever veterinary, West Nile Fever virology, Bird Diseases virology, Disease Reservoirs veterinary, Horse Diseases virology, Population Surveillance methods, Sentinel Surveillance veterinary, West Nile Fever epidemiology, West Nile virus isolation & purification

Abstract

In 1999, Connecticut was one of three states in which West Nile (WN) virus actively circulated prior to its recognition. In 2000, prospective surveillance was established, including monitoring bird deaths, testing dead crows, trapping and testing mosquitoes, testing horses and hospitalized humans with neurologic illness, and conducting a human seroprevalence survey. WN virus was first detected in a dead crow found on July 5 in Fairfield County. Ultimately, 1,095 dead crows, 14 mosquito pools, 7 horses, and one mildly symptomatic person were documented with WN virus infection. None of 86 hospitalized persons with neurologic illness (meningitis, encephalitis, Guillain-Barré-like syndrome) and no person in the seroprevalence survey were infected. Spraying in response to positive surveillance findings was minimal. An intense epizootic of WN virus can occur without having an outbreak of severe human disease in the absence of emergency adult mosquito management.

Published

2001

20. West Nile virus infection in mosquitoes, birds, horses, and humans, Staten Island, New York, 2000.

Author

Kulasekera VL, Kramer L, Nasci RS, Mostashari F, Cherry B, Trock SC, Glaser C, and Miller JR

Subjects

Animals, Bird Diseases mortality, Birds virology, Horses virology, Humans, New York City epidemiology, West Nile Fever epidemiology, West Nile Fever veterinary, Bird Diseases virology, Culicidae virology, Disease Reservoirs veterinary, Horse Diseases virology, Insect Vectors virology, West Nile Fever virology, West Nile virus isolation & purification

Abstract

West Nile (WN) virus transmission in the United States during 2000 was most intense on Staten Island, New York, where 10 neurologic illnesses among humans and 2 among horses occurred. WN virus was isolated from Aedes vexans, Culex pipiens, Cx. salinarius, Ochlerotatus triseriatus, and Psorophora ferox, and WN viral RNA was detected in Anopheles punctipennis. An elevated weekly minimum infection rate (MIR) for Cx. pipiens and increased dead bird density were present for 2 weeks before the first human illness occurred. Increasing mosquito MIRs and dead bird densities in an area may be indicators of an increasing risk for human infections. A transmission model is proposed involving Cx. pipiens and Cx. restuans as the primary enzootic and epizootic vectors among birds, Cx. salinarius as the primary bridge vector for humans, and Aedes/Ochlerotatus spp. as bridge vectors for equine infection.

Published

2001

21. A novel morbillivirus pneumonia of horses and its transmission to humans.

Author

Murray K, Rogers R, Selvey L, Selleck P, Hyatt A, Gould A, Gleeson L, Hooper P, and Westbury H

Subjects

Adult, Animals, Antibodies, Viral analysis, Australia epidemiology, DNA, Viral analysis, Disease Outbreaks, Fluorescent Antibody Technique, Direct, Humans, Lung pathology, Lung virology, Male, Microscopy, Immunoelectron, Middle Aged, Morbillivirus genetics, Morbillivirus growth & development, Morbillivirus ultrastructure, Morbillivirus Infections epidemiology, Morbillivirus Infections mortality, Pneumonia, Viral epidemiology, Pneumonia, Viral mortality, Quarantine veterinary, Seroepidemiologic Studies, Horses virology, Morbillivirus Infections transmission, Morbillivirus Infections veterinary, Pneumonia, Viral transmission, Pneumonia, Viral veterinary

Published

1995