Your search keyword '"African Horse Sickness transmission"' showing total 75 results

1. Modelling bluetongue and African horse sickness vector (Culicoides spp.) distribution in the Western Cape in South Africa using random forest machine learning.

Author

de Klerk J, Tildesley M, Labuschagne K, and Gorsich E

Subjects

Animals, Cattle, Bluetongue virus, Climate, Disease Outbreaks, Ecosystem, Horses, Random Forest, South Africa epidemiology, Sheep, African Horse Sickness epidemiology, African Horse Sickness transmission, African Horse Sickness virology, Bluetongue epidemiology, Bluetongue transmission, Bluetongue virology, Ceratopogonidae virology, Insect Vectors virology, Machine Learning

Abstract

Background: Culicoides biting midges exhibit a global spatial distribution and are the main vectors of several viruses of veterinary importance, including bluetongue (BT) and African horse sickness (AHS). Many environmental and anthropological factors contribute to their ability to live in a variety of habitats, which have the potential to change over the years as the climate changes. Therefore, as new habitats emerge, the risk for new introductions of these diseases of interest to occur increases. The aim of this study was to model distributions for two primary vectors for BT and AHS (Culicoides imicola and Culicoides bolitinos) using random forest (RF) machine learning and explore the relative importance of environmental and anthropological factors in a region of South Africa with frequent AHS and BT outbreaks., Methods: Culicoides capture data were collected between 1996 and 2022 across 171 different capture locations in the Western Cape. Predictor variables included climate-related variables (temperature, precipitation, humidity), environment-related variables (normalised difference vegetation index-NDVI, soil moisture) and farm-related variables (livestock densities). Random forest (RF) models were developed to explore the spatial distributions of C. imicola, C. bolitinos and a merged species map, where both competent vectors were combined. The maps were then compared to interpolation maps using the same capture data as well as historical locations of BT and AHS outbreaks., Results: Overall, the RF models performed well with 75.02%, 61.6% and 74.01% variance explained for C. imicola, C. bolitinos and merged species models respectively. Cattle density was the most important predictor for C. imicola and water vapour pressure the most important for C. bolitinos. Compared to interpolation maps, the RF models had higher predictive power throughout most of the year when species were modelled individually; however, when merged, the interpolation maps performed better in all seasons except winter. Finally, midge densities did not show any conclusive correlation with BT or AHS outbreaks., Conclusion: This study yielded novel insight into the spatial abundance and drivers of abundance of competent vectors of BT and AHS. It also provided valuable data to inform mathematical models exploring disease outbreaks so that Culicoides-transmitted diseases in South Africa can be further analysed., (© 2024. The Author(s).)

Published

2024

2. Ecological niche modeling predicting the potential distribution of African horse sickness virus from 2020 to 2060.

Author

Assefa A, Tibebu A, Bihon A, Dagnachew A, and Muktar Y

Subjects

Africa epidemiology, Animals, Ceratopogonidae virology, Disease Outbreaks veterinary, Horses, India epidemiology, Insect Vectors virology, Software, South Africa epidemiology, South America epidemiology, Temperature, Vector Borne Diseases epidemiology, Vector Borne Diseases transmission, Vector Borne Diseases veterinary, African Horse Sickness epidemiology, African Horse Sickness transmission, African Horse Sickness Virus, Ecosystem, Models, Statistical

Abstract

African horse sickness is a vector-borne, non-contagious and highly infectious disease of equines caused by African horse sickness viruses (AHSv) that mainly affect horses. The occurrence of the disease causes huge economic impacts because of its high fatality rate, trade ban and disease control costs. In the planning of vectors and vector-borne diseases like AHS, the application of Ecological niche models (ENM) used an enormous contribution in precisely delineating the suitable habitats of the vector. We developed an ENM to delineate the global suitability of AHSv based on retrospective outbreak data records from 2005 to 2019. The model was developed in an R software program using the Biomod2 package with an Ensemble modeling technique. Predictive environmental variables like mean diurnal range, mean precipitation of driest month(mm), precipitation seasonality (cv), mean annual maximum temperature ( o c), mean annual minimum temperature ( o c), mean precipitation of warmest quarter(mm), mean precipitation of coldest quarter (mm), mean annual precipitation (mm), solar radiation (kj /day), elevation/altitude (m), wind speed (m/s) were used to develop the model. From these variables, solar radiation, mean maximum temperature, average annual precipitation, altitude and precipitation seasonality contributed 36.83%, 17.1%, 14.34%, 7.61%, and 6.4%, respectively. The model depicted the sub-Sahara African continent as the most suitable area for the virus. Mainly Senegal, Burkina Faso, Niger, Nigeria, Ethiopia, Sudan, Somalia, South Africa, Zimbabwe, Madagascar and Malawi are African countries identified as highly suitable countries for the virus. Besides, OIE-listed disease-free countries like India, Australia, Brazil, Paraguay and Bolivia have been found suitable for the virus. This model can be used as an epidemiological tool in planning control and surveillance of diseases nationally or internationally., (© 2022. The Author(s).)

Published

2022

3. Species composition and relative abundance of the genus Culicoides (Diptera: Ceratopogonidae) in Romania.

Author

Hristescu D, Bărbuceanu F, Dascălu L, Nițescu C, Goffredo M, Santilli A, Quaglia M, Balenghien T, and Predoi G

Subjects

African Horse Sickness transmission, Animals, Bluetongue transmission, Insect Vectors classification, Romania, Ceratopogonidae classification

Abstract

Background: Culicoides biting midges are vectors involved in the biological transmission cycle of important animal diseases such as bluetongue and African horse sickness. In Romania, the first outbreaks of bluetongue were reported in 2014, leading to increased activities within the existing entomological surveillance network. The main goals of the surveillance activities were the establishment of the vector free period in relation to animal trade and the identification of Culicoides species involved in the transmission of the pathogen. This study was conducted on the composition and relative abundance of the species belonging to the genus Culicoides (Diptera: Ceratopogonidae) in certain regions of Romania and provided the opportunity to update the existing checklist of Culicoides species of this country., Methods: The study was conducted in 33 of the 42 administrative units (counties), including a total of 659 catches, in 102 locations. The collections were carried out with UV blacklight suction traps (OVI type). The collected insects were preserved in 70% ethanol. Morphological insect identification was carried out using a stereomicroscope, according to established identification keys. In ten localities the relative abundance of the cryptic species of the Obsoletus complex was determined by multiplex PCR assay based on the ITS2 segment. The identification of the Culicoides chiopterus (Meigen) species by morphological examination was confirmed by PCR assay based on the ITS1 segment., Results: Eleven species were identified using morphological and PCR tools. The rest of the individuals were separated into five taxa. The species of the Obsoletus complex (grouping Culicoides obsoletus (Meigen) and Culicoides scoticus Downes & Kettle) were the most abundant, accounting for 59% of the total number of captured Culicoides spp. Three of the identified species are mentioned, according to our knowledge, for the first time in Romania: Culicoides newsteadi Austen, Culicoides flavipulicaris Dzhafarov and Culicoides bysta Sarvašová, Kočisová, Candolfi & Mathieu., Conclusions: Our study demonstrates that the Culicoides species most commonly cited as being involved in the transmission of arboviruses in Europe (i.e. bluetongue and Schmallenberg viruses) make up a high proportion of adult Culicoides trapped in Romania.

Published

2020

4. Assessing the potential of plains zebra to maintain African horse sickness in the Western Cape Province, South Africa.

Author

Porphyre T and Grewar JD

Subjects

African Horse Sickness pathology, African Horse Sickness transmission, Animals, Disease Outbreaks, Horse Diseases epidemiology, Horse Diseases virology, Horses virology, Insect Vectors virology, South Africa, African Horse Sickness virology, African Horse Sickness Virus pathogenicity, Equidae virology

Abstract

African horse sickness (AHS) is a disease of equids that results in a non-tariff barrier to the trade of live equids from affected countries. AHS is endemic in South Africa except for a controlled area in the Western Cape Province (WCP) where sporadic outbreaks have occurred in the past 2 decades. There is potential that the presence of zebra populations, thought to be the natural reservoir hosts for AHS, in the WCP could maintain AHS virus circulation in the area and act as a year-round source of infection for horses. However, it remains unclear whether the epidemiology or the ecological conditions present in the WCP would enable persistent circulation of AHS in the local zebra populations. Here we developed a hybrid deterministic-stochastic vector-host compartmental model of AHS transmission in plains zebra (Equus quagga), where host populations are age- and sex-structured and for which population and AHS transmission dynamics are modulated by rainfall and temperature conditions. Using this model, we showed that populations of plains zebra present in the WCP are not sufficiently large for AHS introduction events to become endemic and that coastal populations of zebra need to be >2500 individuals for AHS to persist >2 years, even if zebras are infectious for more than 50 days. AHS cannot become endemic in the coastal population of the WCP unless the zebra population involves at least 50,000 individuals. Finally, inland populations of plains zebra in the WCP may represent a risk for AHS to persist but would require populations of at least 500 zebras or show unrealistic duration of infectiousness for AHS introduction events to become endemic. Our results provide evidence that the risk of AHS persistence from a single introduction event in a given plains zebra population in the WCP is extremely low and it is unlikely to represent a long-term source of infection for local horses., Competing Interests: The authors have declared that no competing interests exist.

Published

2019

5. Spatial distribution modelling of Culicoides (Diptera: Ceratopogonidae) biting midges, potential vectors of African horse sickness and bluetongue viruses in Senegal.

Author

Diarra M, Fall M, Fall AG, Diop A, Lancelot R, Seck MT, Rakotoarivony I, Allène X, Bouyer J, and Guis H

Subjects

African Horse Sickness epidemiology, African Horse Sickness virology, African Horse Sickness Virus genetics, African Horse Sickness Virus isolation & purification, African Horse Sickness Virus physiology, Animal Distribution, Animals, Bluetongue epidemiology, Bluetongue virology, Bluetongue virus genetics, Bluetongue virus isolation & purification, Bluetongue virus physiology, Ceratopogonidae virology, Ecosystem, Horses, Insect Vectors virology, Models, Statistical, Seasons, Senegal epidemiology, African Horse Sickness transmission, Bluetongue transmission, Ceratopogonidae physiology, Horse Diseases transmission, Insect Vectors physiology

Abstract

Background: In Senegal, the last epidemic of African horse sickness (AHS) occurred in 2007. The western part of the country (the Niayes area) concentrates modern farms with exotic horses of high value and was highly affected during the 2007 outbreak that has started in the area. Several studies were initiated in the Niayes area in order to better characterize Culicoides diversity, ecology and the impact of environmental and climatic data on dynamics of proven and suspected vectors. The aims of this study are to better understand the spatial distribution and diversity of Culicoides in Senegal and to map their abundance throughout the country., Methods: Culicoides data were obtained through a nationwide trapping campaign organized in 2012. Two successive collection nights were carried out in 96 sites in 12 (of 14) regions of Senegal at the end of the rainy season (between September and October) using OVI (Onderstepoort Veterinary Institute) light traps. Three different modeling approaches were compared: the first consists in a spatial interpolation by ordinary kriging of Culicoides abundance data. The two others consist in analyzing the relation between Culicoides abundance and environmental and climatic data to model abundance and investigate the environmental suitability; and were carried out by implementing generalized linear models and random forest models., Results: A total of 1,373,929 specimens of the genus Culicoides belonging to at least 32 different species were collected in 96 sites during the survey. According to the RF (random forest) models which provided better estimates of abundances than Generalized Linear Models (GLM) models, environmental and climatic variables that influence species abundance were identified. Culicoides imicola, C. enderleini and C. miombo were mostly driven by average rainfall and minimum and maximum normalized difference vegetation index. Abundance of C. oxystoma was mostly determined by average rainfall and day temperature. Culicoides bolitinos had a particular trend; the environmental and climatic variables above had a lesser impact on its abundance. RF model prediction maps for the first four species showed high abundance in southern Senegal and in the groundnut basin area, whereas C. bolitinos was present in southern Senegal, but in much lower abundance., Conclusions: Environmental and climatic variables of importance that influence the spatial distribution of species abundance were identified. It is now crucial to evaluate the vector competence of major species and then combine the vector densities with densities of horses to quantify the risk of transmission of AHS virus across the country.

Published

2018

6. Spatial and temporal variation in the abundance of Culicoides biting midges (Diptera: Ceratopogonidae) in nine European countries.

Author

Cuéllar AC, Kjær LJ, Kirkeby C, Skovgard H, Nielsen SA, Stockmarr A, Andersson G, Lindstrom A, Chirico J, Lühken R, Steinke S, Kiel E, Gethmann J, Conraths FJ, Larska M, Hamnes I, Sviland S, Hopp P, Brugger K, Rubel F, Balenghien T, Garros C, Rakotoarivony I, Allène X, Lhoir J, Chavernac D, Delécolle JC, Mathieu B, Delécolle D, Setier-Rio ML, Venail R, Scheid B, Chueca MÁM, Barceló C, Lucientes J, Estrada R, Mathis A, Tack W, and Bødker R

Subjects

African Horse Sickness transmission, Animals, Bluetongue transmission, Europe, Farms, Geography, Population Density, Population Dynamics, Ruminants, Seasons, Species Specificity, Ceratopogonidae classification, Insect Vectors classification

Abstract

Background: Biting midges of the genus Culicoides (Diptera: Ceratopogonidae) are vectors of bluetongue virus (BTV), African horse sickness virus and Schmallenberg virus (SBV). Outbreaks of both BTV and SBV have affected large parts of Europe. The spread of these diseases depends largely on vector distribution and abundance. The aim of this analysis was to identify and quantify major spatial patterns and temporal trends in the distribution and seasonal variation of observed Culicoides abundance in nine countries in Europe., Methods: We gathered existing Culicoides data from Spain, France, Germany, Switzerland, Austria, Denmark, Sweden, Norway and Poland. In total, 31,429 Culicoides trap collections were available from 904 ruminant farms across these countries between 2007 and 2013., Results: The Obsoletus ensemble was distributed widely in Europe and accounted for 83% of all 8,842,998 Culicoides specimens in the dataset, with the highest mean monthly abundance recorded in France, Germany and southern Norway. The Pulicaris ensemble accounted for only 12% of the specimens and had a relatively southerly and easterly spatial distribution compared to the Obsoletus ensemble. Culicoides imicola Kieffer was only found in Spain and the southernmost part of France. There was a clear spatial trend in the accumulated annual abundance from southern to northern Europe, with the Obsoletus ensemble steadily increasing from 4000 per year in southern Europe to 500,000 in Scandinavia. The Pulicaris ensemble showed a very different pattern, with an increase in the accumulated annual abundance from 1600 in Spain, peaking at 41,000 in northern Germany and then decreasing again toward northern latitudes. For the two species ensembles and C. imicola, the season began between January and April, with later start dates and increasingly shorter vector seasons at more northerly latitudes., Conclusion: We present the first maps of seasonal Culicoides abundance in large parts of Europe covering a gradient from southern Spain to northern Scandinavia. The identified temporal trends and spatial patterns are useful for planning the allocation of resources for international prevention and surveillance programmes in the European Union.

Published

2018

7. Comparative Risk Analysis of Two Culicoides-Borne Diseases in Horses: Equine Encephalosis More Likely to Enter France than African Horse Sickness.

Author

Faverjon C, Leblond A, Lecollinet S, Bødker R, de Koeijer AA, and Fischer EAJ

Subjects

African Horse Sickness transmission, African Horse Sickness virology, Animals, Communicable Diseases, Emerging epidemiology, Communicable Diseases, Emerging transmission, Communicable Diseases, Emerging virology, Communicable Diseases, Imported epidemiology, Communicable Diseases, Imported transmission, Communicable Diseases, Imported virology, France epidemiology, Horses, Probability, Quarantine, Reoviridae Infections epidemiology, Reoviridae Infections transmission, Reoviridae Infections virology, Risk, African Horse Sickness epidemiology, Ceratopogonidae virology, Communicable Diseases, Emerging veterinary, Communicable Diseases, Imported veterinary, Insect Vectors virology, Reoviridae Infections veterinary

Abstract

African horse sickness (AHS) and equine encephalosis (EE) are Culicoides-borne viral diseases that could have the potential to spread across Europe if introduced, thus being potential threats for the European equine industry. Both share similar epidemiology, transmission patterns and geographical distribution. Using stochastic spatiotemporal models of virus entry, we assessed and compared the probabilities of both viruses entering France via two pathways: importation of live-infected animals or importation of infected vectors. Analyses were performed for three consecutive years (2010-2012). Seasonal and regional differences in virus entry probabilities were the same for both diseases. However, the probability of EE entry was much higher than the probability of AHS entry. Interestingly, the most likely entry route differed between AHS and EE: AHS has a higher probability to enter through an infected vector and EE has a higher probability to enter through an infectious host. Consequently, different effective protective measures were identified by 'what-if' scenarios for the two diseases. The implementation of vector protection on all animals (equine and bovine) coming from low-risk regions before their importation was the most effective in reducing the probability of AHS entry. On the other hand, the most significant reduction in the probability of EE entry was obtained by the implementation of quarantine before import for horses coming from both EU and non-EU countries. The developed models can be useful to implement risk-based surveillance., (© 2016 Blackwell Verlag GmbH.)

Published

2017

8. First molecular identification of the vertebrate hosts of Culicoides imicola in Europe and a review of its blood-feeding patterns worldwide: implications for the transmission of bluetongue disease and African horse sickness.

Author

Martínez-DE LA Puente J, Navarro J, Ferraguti M, Soriguer R, and Figuerola J

Subjects

Animals, Ceratopogonidae genetics, Electron Transport Complex IV genetics, Feeding Behavior, Female, Insect Proteins genetics, Sequence Analysis, DNA, Spain, African Horse Sickness transmission, Bluetongue transmission, Ceratopogonidae physiology, DNA Barcoding, Taxonomic

Abstract

Culicoides (Diptera: Ceratopogonidae) are vectors of pathogens that affect wildlife, livestock and, occasionally, humans. Culicoides imicola (Kieffer, 1913) is considered to be the main vector of the pathogens that cause bluetongue disease (BT) and African horse sickness (AHS) in southern Europe. The study of blood-feeding patterns in Culicoides is an essential step towards understanding the epidemiology of these pathogens. Molecular tools that increase the accuracy and sensitivity of traditional methods have been developed to identify the hosts of potential insect vectors. However, to the present group's knowledge, molecular studies that identify the hosts of C. imicola in Europe are lacking. The present study genetically characterizes the barcoding region of C. imicola trapped on farms in southern Spain and identifies its vertebrate hosts in the area. The report also reviews available information on the blood-feeding patterns of C. imicola worldwide. Culicoides imicola from Spain feed on blood of six mammals that include species known to be hosts of the BT and AHS viruses. This study provides evidence of the importance of livestock as sources of bloodmeals for C. imicola and the relevance of this species in the transmission of BT and AHS viruses in Europe., (© 2017 The Royal Entomological Society.)

Published

2017

9. African Horse Sickness Virus: History, Transmission, and Current Status.

Author

Carpenter S, Mellor PS, Fall AG, Garros C, and Venter GJ

Subjects

Africa, African Horse Sickness virology, African Horse Sickness Virus, Animals, Asia, Europe, History, 15th Century, History, 16th Century, History, 17th Century, History, 18th Century, History, 19th Century, History, 20th Century, History, 21st Century, History, Medieval, Horse Diseases virology, Horses, Senegal, South Africa, African Horse Sickness history, African Horse Sickness transmission, Ceratopogonidae virology, Equidae, Horse Diseases history, Horse Diseases transmission

Abstract

African horse sickness virus (AHSV) is a lethal arbovirus of equids that is transmitted between hosts primarily by biting midges of the genus Culicoides (Diptera: Ceratopogonidae). AHSV affects draft, thoroughbred, and companion horses and donkeys in Africa, Asia, and Europe. In this review, we examine the impact of AHSV critically and discuss entomological studies that have been conducted to improve understanding of its epidemiology and control. The transmission of AHSV remains a major research focus and we critically review studies that have implicated both Culicoides and other blood-feeding arthropods in this process. We explore AHSV both as an epidemic pathogen and within its endemic range as a barrier to development, an area of interest that has been underrepresented in studies of the virus to date. By discussing AHSV transmission in the African republics of South Africa and Senegal, we provide a more balanced view of the virus as a threat to equids in a diverse range of settings, thus leading to a discussion of key areas in which our knowledge of transmission could be improved. The use of entomological data to detect, predict and control AHSV is also examined, including reference to existing studies carried out during unprecedented outbreaks of bluetongue virus in Europe, an arbovirus of wild and domestic ruminants also transmitted by Culicoides.

Published

2017

10. African horse sickness: The potential for an outbreak in disease-free regions and current disease control and elimination techniques.

Author

Robin M, Page P, Archer D, and Baylis M

Subjects

African Horse Sickness epidemiology, Animals, Disease Outbreaks prevention & control, Horses, African Horse Sickness transmission, Disease Outbreaks veterinary

Abstract

African horse sickness (AHS) is an arboviral disease of equids transmitted by Culicoides biting midges. The virus is endemic in parts of sub-Saharan Africa and official AHS disease-free status can be obtained from the World Organization for Animal Health on fulfilment of a number of criteria. AHS is associated with case fatality rates of up to 95%, making an outbreak among naïve horses both a welfare and economic disaster. The worldwide distributions of similar vector-borne diseases (particularly bluetongue disease of ruminants) are changing rapidly, probably due to a combination of globalisation and climate change. There is extensive evidence that the requisite conditions for an AHS epizootic currently exist in disease-free countries. In particular, although the stringent regulations enforced upon competition horses make them extremely unlikely to redistribute the virus, there are great concerns over the effects of illegal equid movement. An outbreak of AHS in a disease free region would have catastrophic effects on equine welfare and industry, particularly for international events such as the Olympic Games. While many regions have contingency plans in place to manage an outbreak of AHS, further research is urgently required if the equine industry is to avoid or effectively contain an AHS epizootic in disease-free regions. This review describes the key aspects of AHS as a global issue and discusses the evidence supporting concerns that an epizootic may occur in AHS free countries, the planned government responses, and the roles and responsibilities of equine veterinarians., (© 2016 EVJ Ltd.)

Published

2016

11. Insight on the larval habitat of Afrotropical Culicoides Latreille (Diptera: Ceratopogonidae) in the Niayes area of Senegal, West Africa.

Author

Bakhoum MT, Fall AG, Fall M, Bassene CK, Baldet T, Seck MT, Bouyer J, Garros C, and Gimonneau G

Subjects

African Horse Sickness transmission, African Horse Sickness virology, African Horse Sickness Virus, Animals, Horses, Insect Vectors virology, Larva physiology, Senegal, Ceratopogonidae physiology, Ecosystem

Abstract

Background: Certain biting midges species of the genus Culicoides (Diptera: Ceratopogonidae) are vectors of virus to livestock worldwide. Culicoides larval ecology has remained overlooked because of difficulties to identify breeding sites, methodological constraints to collect samples and lack of morphological tools to identify field-collected individuals to the species level. After the 2007 unforeseen outbreaks of African horse sickness virus (AHSV) in Senegal (West Africa), there is a need to identify suitable and productive larval habitats in horse farms for the main Culicoides species to evaluate the implementation of vector control measures or preventive actions., Methods: We investigate twelve putative larval habitats (habitat types) of Culicoides inside and outside of three horse farms in the Niayes area of Senegal using a combination of flotation and emergence methods during four collection sessions., Results: Among the three studied horse farms, three habitat types were found positive for Culicoides larvae: pond edge, lake edge and puddle edge. A total of 1420 Culicoides individuals (519♂/901♀) belonging to ten species emerged from the substrate samples. Culicoides oxystoma (40 %), C. similis (25 %) and C. nivosus (24 %) were the most abundant species and emerged from the three habitat types while C. kingi (5 %) was only retrieved from lake edges and one male emerged from puddle edge. Culicoides imicola (1.7 %) was found in low numbers and retrieved only from pond and puddle edges., Conclusions: Larval habitats identified were not species-specific. All positive larval habitats were found outside the horse farms. This study provides original baseline information on larval habitats of Culicoides species in Senegal in an area endemic for AHSV, in particular for species of interest in animal health. These data will serve as a point of reference for future investigations on larval ecology and larval control measures.

Published

2016

12. Foraging range of arthropods with veterinary interest: New insights for Afrotropical Culicoides biting midges (Diptera: Ceratopogonidae) using the ring method.

Author

Bakhoum MT, Fall M, Seck MT, Gardès L, Fall AG, Diop M, Mall I, Balenghien T, Baldet T, Gimonneau G, Garros C, and Bouyer J

Subjects

Africa, Western epidemiology, African Horse Sickness epidemiology, African Horse Sickness virology, African Horse Sickness Virus, Animals, Cattle parasitology, Cattle virology, Ceratopogonidae, Disease Outbreaks, Feeding Behavior, Female, Goats parasitology, Horses parasitology, Horses virology, Senegal epidemiology, Sheep parasitology, Sheep virology, Species Specificity, African Horse Sickness parasitology, African Horse Sickness transmission, Arthropod Vectors virology, Goats virology, Host Specificity, Insect Vectors virology

Abstract

The identification of blood meal source of arthropod vector species contributes to the understanding of host-vector-pathogen interactions. The aim of the current work was to identify blood meal source in Culicoides biting midge species, biological vectors of internationally important arboviruses of livestock and equids, using a new ecological approach. We examined the correlation between blood meal source identified in engorged Culicoides females collected in a suction light trap and the available vertebrate hosts along four rings (200, 500, 1000 and 2000 m) centered at the trap site and described the foraging range of the three main vector species of veterinary interest present in the study area, Culicoides imicola, Culicoides kingi and Culicoides oxystoma. The study was performed in four sites localized in the Niayes region of Senegal (West Africa) where recent outbreaks of African horse sickness occurred. Blood meal source identification was carried out by species-specific multiplex PCRs with genomic DNA extracted from the abdomen of engorged females collected during nine night collections for twenty-six collections. The four most abundant hosts present in the studied area (horse, cattle, goat and sheep) were surveyed in each ring zone. The blood meal source varied according to Culicoides species and host availability in each site. C. oxystoma and C. imicola females mainly fed on horses readily available at 200 m maximum from the trap location whereas females of C. kingi fed mainly on cattle, at variable distances from the traps (200 to 2000 m). C. oxystoma may also feed on other vertebrates. We discuss the results in relation with the transmission of Culicoides-borne arboviruses and the species dispersion capacities., (Copyright © 2016. Published by Elsevier B.V.)

Published

2016

13. Quantitative Risk Assessment for African Horse Sickness in Live Horses Exported from South Africa.

Author

Sergeant ES, Grewar JD, Weyer CT, and Guthrie AJ

Subjects

African Horse Sickness epidemiology, African Horse Sickness transmission, Animals, Horses, Quarantine, Risk Assessment, Seasons, South Africa epidemiology, African Horse Sickness diagnosis, African Horse Sickness Virus isolation & purification, Insect Vectors virology

Abstract

African horse sickness (AHS) is a severe, often fatal, arbovirus infection of horses, transmitted by Culicoides spp. midges. AHS occurs in most of sub-Saharan Africa and is a significant impediment to export of live horses from infected countries, such as South Africa. A stochastic risk model was developed to estimate the probability of exporting an undetected AHS-infected horse through a vector protected pre-export quarantine facility, in accordance with OIE recommendations for trade from an infected country. The model also allows for additional risk management measures, including multiple PCR tests prior to and during pre-export quarantine and optionally during post-arrival quarantine, as well as for comparison of risk associated with exports from a demonstrated low-risk area for AHS and an area where AHS is endemic. If 1 million horses were exported from the low-risk area with no post-arrival quarantine we estimate the median number of infected horses to be 5.4 (95% prediction interval 0.5 to 41). This equates to an annual probability of 0.0016 (95% PI: 0.00015 to 0.012) assuming 300 horses exported per year. An additional PCR test while in vector-protected post-arrival quarantine reduced these probabilities by approximately 12-fold. Probabilities for horses exported from an area where AHS is endemic were approximately 15 to 17 times higher than for horses exported from the low-risk area under comparable scenarios. The probability of undetected AHS infection in horses exported from an infected country can be minimised by appropriate risk management measures. The final choice of risk management measures depends on the level of risk acceptable to the importing country.

Published

2016

14. Protection of horses against Culicoides biting midges in different housing systems in Switzerland.

Author

Lincoln VJ, Page PC, Kopp C, Mathis A, von Niederhäusern R, Burger D, and Herholz C

Subjects

African Horse Sickness epidemiology, African Horse Sickness transmission, Animals, Bluetongue epidemiology, Bluetongue transmission, Disease Outbreaks prevention & control, Female, Horses, Housing, Insect Repellents, Mosquito Nets, Seasons, Switzerland epidemiology, African Horse Sickness prevention & control, African Horse Sickness Virus physiology, Bluetongue prevention & control, Bluetongue virus physiology, Ceratopogonidae virology, Disease Outbreaks veterinary, Insect Vectors virology, Mosquito Control methods

Abstract

Species belonging to the Culicoides complexes (Diptera, Ceratopogonidae), obsoletus and pulicaris, in Switzerland, are potential vectors of both bluetongue virus (BTV) and African horse sickness virus (AHSV). The epidemic of BTV in 2006 and 2007 in Europe has highlighted the risk of introduction and spread of vector-borne diseases in previously non-endemic areas. As a measure of prevention, as part of an integrated control programme in the event of an outbreak of African horse sickness (AHS), it is of utmost importance to prevent, or substantially reduce, contact between horses and Culicoides. The aim of the present study was to compare the effect of three protection systems, net, fan, repellent, or combinations thereof, with regard to their potential to reduce contact between horses and Culicoides. Three different equine housing systems, including individual boxes (BX), group housing systems (GR), and individual boxes with permanently accessible paddock (BP) were used. The efficacy of the protection systems were evaluated by comparing the total number counts of collected female Culicoides, of non-blood-fed and blood-fed Culicoides, respectively, with UV black light traps. The study was conducted over 3 summer months during 2012 and 2013 each and focused on the efficacy and practicality of the protection systems. The repellent was tested in 2012 only and not further investigated in 2013, as it showed no significant effect in reducing Culicoides collected in the light traps. Net protection system provided the best overall protection for the total number of female Culicoides, non-blood-fed and blood-fed Culicoides in all tested housing systems. The net, with a pore size of 0.1825 mm(2), reduced the total number of Culicoides collected in the housing systems BP, GR and BX by 98%, 85% and 67%, respectively. However, in the GR housing system, no significant difference between the effectiveness of the fan and the net were determined for any of the three Culicoides categories. The results of the present study demonstrated that horse owners can substantially reduce their horses' exposure to Culicoides, by using net protection in the housing systems BX, BP and GR. In GR housing systems, protection against Culicoides using a fan is also recommended., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2015

15. A spatiotemporal model to assess the introduction risk of African horse sickness by import of animals and vectors in France.

Author

Faverjon C, Leblond A, Hendrikx P, Balenghien T, de Vos CJ, Fischer EA, and de Koeijer AA

Subjects

African Horse Sickness economics, African Horse Sickness epidemiology, Animals, Cattle, Equidae, Risk Factors, African Horse Sickness transmission, Ceratopogonidae physiology, Commerce, Models, Biological

Abstract

Background: African horse sickness (AHS) is a major, Culicoides-borne viral disease in equines whose introduction into Europe could have dramatic consequences. The disease is considered to be endemic in sub-Saharan Africa. Recent introductions of other Culicoides-borne viruses (bluetongue and Schmallenberg) into northern Europe have highlighted the risk that AHS may arrive in Europe as well. The aim of our study was to provide a spatiotemporal quantitative risk model of AHS introduction into France. The study focused on two pathways of introduction: the arrival of an infectious host (PW-host) and the arrival of an infectious Culicoides midge via the livestock trade (PW-vector). The risk of introduction was calculated by determining the probability of an infectious animal or vector entering the country and the probability of the virus then becoming established: i.e., the virus's arrival in France resulting in at least one local equine host being infected by one local vector. This risk was assessed using data from three consecutive years (2010 to 2012) for 22 regions in France., Results: The results of the model indicate that the annual risk of AHS being introduced to France is very low but that major spatiotemporal differences exist. For both introduction pathways, risk is higher from July to October and peaks in July. In general, regions with warmer climates are more at risk, as are colder regions with larger equine populations; however, regional variation in animal importation patterns (number and species) also play a major role in determining risk. Despite the low probability that AHSV is present in the EU, intra-EU trade of equines contributes most to the risk of AHSV introduction to France because it involves a large number of horse movements., Conclusion: It is important to address spatiotemporal differences when assessing the risk of ASH introduction and thus also when implementing efficient surveillance efforts. The methods and results of this study may help develop surveillance techniques and other risk reduction measures that will prevent the introduction of AHS or minimize AHS' potential impact once introduced, both in France and the rest of Europe.

Published

2015

16. Culicoides (Diptera: Ceratopogonidae) midges, the vectors of African horse sickness virus--a host/vector contact study in the Niayes area of Senegal.

Author

Fall M, Diarra M, Fall AG, Balenghien T, Seck MT, Bouyer J, Garros C, Gimonneau G, Allène X, Mall I, Delécolle JC, Rakotoarivony I, Bakhoum MT, Dusom AM, Ndao M, Konaté L, Faye O, and Baldet T

Subjects

African Horse Sickness epidemiology, African Horse Sickness transmission, Animals, Female, Horses, Male, Seasons, Senegal epidemiology, African Horse Sickness virology, African Horse Sickness Virus physiology, Ceratopogonidae virology, Disease Outbreaks veterinary, Insect Vectors virology

Abstract

Background: African horse sickness (AHS) is an equine disease endemic to Senegal. The African horse sickness virus (AHSV) is transmitted to the mammalian hosts by midges of the Culicoides Latreille genus. During the last epizootic outbreak of AHS in Senegal in 2007, 1,169 horses died from this disease entailing an estimated cost of 1.4 million euros. In spite of the serious animal health and economic implications of AHS, very little is known about determinants involved in transmission such as contact between horses and the Culicoides species suspected of being its vectors., Methods: The monthly variation in host/vector contact was determined in the Niayes area, Senegal, an area which was severely affected by the 2007 outbreak of AHS. A horse-baited trap and two suction light traps (OVI type) were set up at each of five sites for three consecutive nights every month for one year., Results: Of 254,338 Culicoides midges collected 209,543 (82.4%) were female and 44,795 (17.6%) male. Nineteen of the 41 species collected were new distribution records for Senegal. This increased the number of described Culicoides species found in Senegal to 53. Only 19 species, of the 41 species found in light trap, were collected in the horse-baited trap (23,669 specimens) largely dominated by Culicoides oxystoma (22,300 specimens, i.e. 94.2%) followed by Culicoides imicola (482 specimens, i.e. 2.0%) and Culicoides kingi (446 specimens, i.e. 1.9%)., Conclusions: Culicoides oxystoma should be considered as a potential vector of AHSV in the Niayes area of Senegal due to its abundance on horses and its role in the transmission of other Culicoides-borne viruses.

Published

2015

17. Culicoides species abundance and potential over-wintering of African horse sickness virus in the Onderstepoort area, Gauteng, South Africa.

Author

Venter GJ, Labuschagne K, Majatladi D, Boikanyo SN, Lourens C, Ebersohn K, and Venter EH

Subjects

African Horse Sickness epidemiology, Animal Distribution, Animals, Horses, Population Density, South Africa epidemiology, Time Factors, African Horse Sickness transmission, African Horse Sickness Virus physiology, Ceratopogonidae, Insect Vectors virology, Seasons

Abstract

In South Africa, outbreaks of African horse sickness (AHS) occur in summer; no cases are reported in winter, from July to September. The AHS virus (AHSV) is transmitted almost exclusively by Culicoides midges (Diptera: Ceratopogonidae), of which Culicoides imicola is considered to be the most important vector. The over-wintering mechanism of AHSV is unknown. In this study, more than 500 000 Culicoides midges belonging to at least 26 species were collected in 88 light traps at weekly intervals between July 2010 and September 2011 near horses in the Onderstepoort area of South Africa. The dominant species was C. imicola. Despite relatively low temperatures and frost, at least 17 species, including C. imicola, were collected throughout winter (June-August). Although the mean number of midges per night fell from > 50 000 (March) to < 100 (July and August), no midge-free periods were found. This study, using virus isolation on cell cultures and a reverse transcriptase polymerase chain reaction (RT-PCR) assay, confirmed low infection prevalence in field midges and that the detection of virus correlated to high numbers. Although no virus was detected during this winter period, continuous adult activity indicated that transmission can potentially occur. The absence of AHSV in the midges during winter can be ascribed to the relatively low numbers collected coupled to low infection prevalence, low virus replication rates and low virus titres in the potentially infected midges. Cases of AHS in susceptible animals are likely to start as soon as Culicoides populations reach a critical level.

Published

2014

18. Seasonal dynamics of Culicoides (Diptera: Ceratopogonidae) biting midges, potential vectors of African horse sickness and bluetongue viruses in the Niayes area of Senegal.

Author

Diarra M, Fall M, Fall AG, Diop A, Seck MT, Garros C, Balenghien T, Allène X, Rakotoarivony I, Lancelot R, Mall I, Bakhoum MT, Dosum AM, Ndao M, Bouyer J, and Guis H

Subjects

African Horse Sickness epidemiology, African Horse Sickness transmission, African Horse Sickness virology, Animals, Disease Outbreaks, Horses, Population Dynamics, Senegal epidemiology, Species Specificity, Time Factors, African Horse Sickness Virus physiology, Bluetongue virus physiology, Ceratopogonidae physiology, Insect Vectors virology, Seasons

Abstract

Background: The African horse sickness epizootic in Senegal in 2007 caused considerable mortality in the equine population and hence major economic losses. The vectors involved in the transmission of this arbovirus have never been studied specifically in Senegal. This first study of the spatial and temporal dynamics of the Culicoides (Diptera: Ceratopogonidae) species, potential vectors of African horse sickness in Senegal, was conducted at five sites (Mbao, Parc Hann, Niague, Pout and Thies) in the Niayes area, which was affected by the outbreak., Methods: Two Onderstepoort light traps were used at each site for three nights of consecutive collection per month over one year to measure the apparent abundance of the Culicoides midges., Results: In total, 224,665 specimens belonging to at least 24 different species (distributed among 11 groups of species) of the Culicoides genus were captured in 354 individual collections. Culicoides oxystoma, Culicoides kingi, Culicoides imicola, Culicoides enderleini and Culicoides nivosus were the most abundant and most frequent species at the collection sites. Peaks of abundance coincide with the rainy season in September and October., Conclusions: In addition to C. imicola, considered a major vector for the African horse sickness virus, C. oxystoma may also be involved in the transmission of this virus in Senegal given its abundance in the vicinity of horses and its suspected competence for other arboviruses including bluetongue virus. This study depicted a site-dependent spatial variability in the dynamics of the populations of the five major species in relation to the eco-climatic conditions at each site.

Published

2014

19. The threat of midge-borne equine disease: investigation of Culicoides species on UK equine premises.

Author

Robin M, Archer D, Garros C, Gardès L, and Baylis M

Subjects

African Horse Sickness transmission, African Horse Sickness virology, African Horse Sickness Virus isolation & purification, Animals, Disease Outbreaks veterinary, Horses, Insect Control, Insect Vectors virology, United Kingdom epidemiology, African Horse Sickness epidemiology, Ceratopogonidae physiology, Ceratopogonidae virology

Abstract

There are concerns that outbreaks of exotic or novel vector-borne viral diseases will increasingly occur within northern Europe and the UK in the future. African horse sickness (AHS) is a viral disease of equids that is transmitted by Culicoides and is associated with up to 95 per cent mortality. AHS has never occurred in the UK; however, it has been suggested that appropriate Culicoides species and climatic conditions are present in northern Europe to support an outbreak. No data are currently available regarding the Culicoides species present on UK equine properties. This study demonstrates the presence of potential AHS virus vector Culicoides species on both urban and rural equine properties within the south-east UK. PCR analysis revealed that engorged members of these species contained equine DNA, proving a direct vector-host interaction. It is therefore possible that an AHS outbreak could occur in the UK if the virus were to be imported and, given the severe welfare and economic consequences of AHS, this would have devastating consequences to the naïve UK equine population.

Published

2014

20. Focus on: African horse sickness.

Author

Hopley R and Toth B

Subjects

African Horse Sickness economics, African Horse Sickness transmission, African Horse Sickness Virus immunology, African Horse Sickness Virus pathogenicity, Animal Husbandry economics, Animal Husbandry legislation & jurisprudence, Animal Husbandry methods, Animals, Disease Outbreaks economics, Disease Outbreaks prevention & control, Female, Horses, Male, Viral Vaccines administration & dosage, Viral Vaccines immunology, African Horse Sickness prevention & control, Disease Outbreaks veterinary, Legislation, Veterinary, Sentinel Surveillance veterinary

Published

2013

21. Where are the horses? With the sheep or cows? Uncertain host location, vector-feeding preferences and the risk of African horse sickness transmission in Great Britain.

Author

Lo Iacono G, Robin CA, Newton JR, Gubbins S, and Wood JL

Subjects

African Horse Sickness epidemiology, African Horse Sickness prevention & control, Animals, Cattle virology, Ceratopogonidae physiology, Communicable Disease Control, Feeding Behavior, Geography, Insect Vectors physiology, Risk Factors, Seasons, Sheep virology, United Kingdom epidemiology, Vaccination veterinary, Viral Vaccines therapeutic use, African Horse Sickness transmission, Ceratopogonidae virology, Horses virology, Insect Vectors virology

Abstract

Understanding the influence of non-susceptible hosts on vector-borne disease transmission is an important epidemiological problem. However, investigation of its impact can be complicated by uncertainty in the location of the hosts. Estimating the risk of transmission of African horse sickness (AHS) in Great Britain (GB), a virus transmitted by Culicoides biting midges, provides an insightful example because: (i) the patterns of risk are expected to be influenced by the presence of non-susceptible vertebrate hosts (cattle and sheep) and (ii) incomplete information on the spatial distribution of horses is available because the GB National Equine Database records owner, rather than horse, locations. Here, we combine land-use data with available horse owner distributions and, using a Bayesian approach, infer a realistic distribution for the location of horses. We estimate the risk of an outbreak of AHS in GB, using the basic reproduction number (R0), and demonstrate that mapping owner addresses as a proxy for horse location significantly underestimates the risk. We clarify the role of non-susceptible vertebrate hosts by showing that the risk of disease in the presence of many hosts (susceptible and non-susceptible) can be ultimately reduced to two fundamental factors: first, the abundance of vectors and how this depends on host density, and, second, the differential feeding preference of vectors among animal species.

Published

2013

22. Risk of introducing African horse sickness virus into the Netherlands by international equine movements.

Author

de Vos CJ, Hoek CA, and Nodelijk G

Subjects

African Horse Sickness epidemiology, African Horse Sickness virology, Animals, Ceratopogonidae physiology, Ceratopogonidae virology, Disease Outbreaks prevention & control, Equidae virology, Feeding Behavior, Horses, Incidence, Insect Vectors physiology, Insect Vectors virology, Models, Biological, Netherlands epidemiology, Prevalence, Risk, Seasons, Sensitivity and Specificity, Species Specificity, Transportation, African Horse Sickness prevention & control, African Horse Sickness transmission, African Horse Sickness Virus physiology, Disease Outbreaks veterinary

Abstract

African horse sickness (AHS) is a vector-borne viral disease of equines that is transmitted by Culicoides spp. and can have severe consequences for the horse industry in affected territories. A study was performed to assess the risk of introducing AHS virus (AHSV) into the Netherlands (P_AHS) by international equine movements. The goal of this study was to provide more insight into (a) the regions and equine species that contribute most to this risk, (b) the seasonal variation in this risk, and (c) the effectiveness of measures to prevent introduction of AHSV. Countries worldwide were grouped into three risk regions: (1) high risk, i.e., those countries in which the virus is presumed to circulate, (2) low risk, i.e., those countries that have experienced outbreaks of AHS in the past and/or where the main vector of AHS, Culicoides imicola, is present, and (3) very low risk, i.e., all other countries. A risk model was constructed estimating P_AHS taking into account the probability of release of AHSV in the Netherlands and the probability that local vectors will subsequently transmit the virus to local hosts. Model calculations indicated that P_AHS is very low with a median value of 5.1×10(-4)/year. The risk is highest in July and August, while equine movements in the period October till March pose a negligible risk. High and low risk regions contribute most to P_AHS with 31% and 53%, respectively. Importations of donkeys and zebras constitute the highest risk of AHSV release from high risk regions, while international movements of competition horses constitute the highest risk of AHSV release from low and very low risk regions. Preventive measures currently applied reduce P_AHS by 46% if compared to a situation in which no preventive measures are applied. A prolonged and more effective quarantine period in high risk regions and more stringent import regulations for low risk regions could further reduce P_AHS. Large uncertainty was involved in estimating model input parameters. Sensitivity analysis indicated that uncertainty about the probability of non-notified presence of AHS in low and very low risk regions, the protective effect of quarantine and the vector-host ratio had most impact on the estimated risk. Furthermore, temperature values at the time of release of AHSV largely influenced the probability of onward spread of the virus by local vectors to local hosts., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

23. Transmission and control of African horse sickness in The Netherlands: a model analysis.

Author

Backer JA and Nodelijk G

Subjects

African Horse Sickness epidemiology, Animals, Horse Diseases epidemiology, Horses, Models, Theoretical, Netherlands epidemiology, African Horse Sickness prevention & control, African Horse Sickness transmission, Horse Diseases prevention & control, Horse Diseases transmission

Abstract

African horse sickness (AHS) is an equine viral disease that is spread by Culicoides spp. Since the closely related disease bluetongue established itself in The Netherlands in 2006, AHS is considered a potential threat for the Dutch horse population. A vector-host model that incorporates the current knowledge of the infection biology is used to explore the effect of different parameters on whether and how the disease will spread, and to assess the effect of control measures. The time of introduction is an important determinant whether and how the disease will spread, depending on temperature and vector season. Given an introduction in the most favourable and constant circumstances, our results identify the vector-to-host ratio as the most important factor, because of its high variability over the country. Furthermore, a higher temperature accelerates the epidemic, while a higher horse density increases the extent of the epidemic. Due to the short infectious period in horses, the obvious clinical signs and the presence of non-susceptible hosts, AHS is expected to invade and spread less easily than bluetongue. Moreover, detection is presumed to be earlier, which allows control measures to be targeted towards elimination of infection sources. We argue that recommended control measures are euthanasia of infected horses with severe clinical signs and vector control in infected herds, protecting horses from midge bites in neighbouring herds, and (prioritized) vaccination of herds farther away, provided that transport regulations are strictly applied. The largest lack of knowledge is the competence and host preference of the different Culicoides species present in temperate regions.

Published

2011

24. A comparison of the susceptibility of the biting midge Culicoides imicola to infection with recent and historical isolates of African horse sickness virus.

Author

Venter GJ, Wright IM, and Paweska JT

Subjects

African Horse Sickness history, African Horse Sickness transmission, African Horse Sickness virology, Animals, Disease Susceptibility veterinary, Disease Susceptibility virology, Female, History, 20th Century, Horses virology, Insect Vectors virology, Male, South Africa, African Horse Sickness Virus pathogenicity, Ceratopogonidae virology

Abstract

The susceptibility of Culicoides (Avaritia) imicola Kiefer (Diptera: Ceratopogonidae) to 21 isolates representing all nine known serotypes of African horse sickness virus (AHSV), recovered from clinical cases of the disease in South Africa during 1998-2004, was compared with its susceptibility to approximately 40-year-old isolates stored at the Agricultural Research Council-Onderstepoort Veterinary Institute. Field-collected C. imicola were fed through a chicken skin membrane on sheep blood spiked with one of the virus isolates to a concentration in the range of 5.6-7.5 log (10)TCID(50)/mL. After 10 days incubation at 23.5 degrees C, five of the nine historical serotypes (AHSV-1, -2, -3, -7 and -9) could not be isolated from C. imicola. All nine serotypes were recovered for the 21 recent isolates, for 16 of which the virus recovery rates were higher than for the corresponding historical isolates. These results emphasize the need to assess the oral susceptibility of local Culicoides populations to viruses in circulation during outbreaks in order to estimate their vector potential.

Published

2010

25. [African horse sickness and equine encephalosis: must Switzerland get prepared].

Author

Zimmerli U, Herholz C, Schwermer H, Hofmann M, and Griot C

Subjects

Africa epidemiology, African Horse Sickness prevention & control, African Horse Sickness transmission, Animals, Asia epidemiology, Bluetongue epidemiology, Bluetongue prevention & control, Bluetongue transmission, Encephalomyelitis, Eastern Equine epidemiology, Encephalomyelitis, Eastern Equine prevention & control, Encephalomyelitis, Eastern Equine transmission, Europe epidemiology, Horse Diseases epidemiology, Horse Diseases prevention & control, Horse Diseases transmission, Horses, Risk Factors, Switzerland epidemiology, African Horse Sickness epidemiology

Abstract

African horse sickness (AHS) of equines is partly transmitted by the same culicoides species as Bluetongue (BT) disease in even-toed ungulates. Horses normally get seriously sick, with a high case fatality rate. Equine Encephalosis is another, but less-known viral disease of equines, caused by viruses of the same genus as BT and AHS. Like BT of serotype 8 in 2006, both diseases could theoretically be introduced to Europe anytime and spread rapidly then. After the lessons learnt from the most recent bluetongue outbreaks in Europe, the regulations and AHS-contingency plans in force must be updated. All stakeholders must be aware of the risks and take own measures to prevent a possible emergence of the diseases, and be prepared in case of an outbreak.

Published

2010

26. Strengthening cooperation on vectorborne diseases in Europe.

Subjects

African Horse Sickness transmission, Animals, Bluetongue transmission, Communicable Diseases, Emerging epidemiology, Communicable Diseases, Emerging prevention & control, Europe epidemiology, Molecular Epidemiology, Reoviridae Infections epidemiology, Reoviridae Infections transmission, Risk Assessment, Sentinel Surveillance veterinary, African Horse Sickness epidemiology, Bluetongue epidemiology, Ceratopogonidae virology, Communicable Diseases, Emerging veterinary, Disease Vectors, Reoviridae Infections veterinary

Published

2010

27. The oral susceptibility of South African field populations of Culicoides to African horse sickness virus.

Author

Venter GJ, Wright IM, Van Der Linde TC, and Paweska JT

Subjects

African Horse Sickness virology, Animals, Disease Susceptibility, Neutralization Tests, South Africa epidemiology, African Horse Sickness transmission, African Horse Sickness Virus isolation & purification, Ceratopogonidae virology, Insect Bites and Stings virology

Abstract

Twenty-two isolates of African horse sickness virus (AHSV), representing its distinct serotypes, geographical and historical origins, were fed to three populations of South African livestock-associated Culicoides spp. (Diptera, Ceratopogonidae). Infective blood meals included 12 recent isolates, nine historical reference strains and one live attenuated vaccine strain serotype 7 (AHSV-7) of the virus. Field-collected midges were fed through a chicken-skin membrane on sheep blood spiked with one of the viruses, which concentrations ranged from 5.4 to 8.8 log(10)TCID(50)/mL of blood. After 10 days incubation at 23.5 degrees C, AHSV was isolated from 11 Culicoides species. Standard in vitro passaging of AHSV-7, used for the preparation of live attenuated vaccine, did not reduce its ability to infect Culicoides species. Virus recovery rates in orally infected Culicoides midges differed significantly between species and populations, serotypes, isolates and seasons. Significant variations in oral susceptibility recorded in this study emphasize a complex inter-relationship between virus and vector, which is further influenced by multiple intrinsic and extrinsic factors. As it is not possible to standardize all these factors under laboratory conditions, conclusive assessment of the role of field-collected Culicoides midges in the transmission of orbiviruses remains problematic. Nevertheless, results of this study suggest the potential for multi-vector transmission of AHSV virus in South Africa.

Published

2009

28. ['Emerging vector-borne diseases' in the horse].

Author

Sloet van Oldruitenborgh-Oosterbaan MM, Goehring LS, Koopmans MP, van Rijn PA, and van Maanen C

Subjects

African Horse Sickness prevention & control, African Horse Sickness transmission, Animals, Communicable Diseases, Emerging epidemiology, Communicable Diseases, Emerging prevention & control, Communicable Diseases, Emerging transmission, Disease Vectors, Equine Infectious Anemia prevention & control, Equine Infectious Anemia transmission, Horse Diseases prevention & control, Horse Diseases transmission, Horses, Netherlands epidemiology, Seasons, West Nile Fever epidemiology, West Nile Fever prevention & control, West Nile Fever transmission, African Horse Sickness epidemiology, Communicable Diseases, Emerging veterinary, Equine Infectious Anemia epidemiology, Horse Diseases epidemiology, West Nile Fever veterinary

Published

2009

29. Adaptive strategies of African horse sickness virus to facilitate vector transmission.

Author

Wilson A, Mellor PS, Szmaragd C, and Mertens PP

Subjects

Adaptation, Physiological, Animals, African Horse Sickness transmission, African Horse Sickness virology, African Horse Sickness Virus physiology, Ceratopogonidae virology, Insect Vectors virology

Abstract

African horse sickness virus (AHSV) is an orbivirus that is usually transmitted between its equid hosts by adult Culicoides midges. In this article, we review the ways in which AHSV may have adapted to this mode of transmission. The AHSV particle can be modified by the pH or proteolytic enzymes of its immediate environment, altering its ability to infect different cell types. The degree of pathogenesis in the host and vector may also represent adaptations maximising the likelihood of successful vectorial transmission. However, speculation upon several adaptations for vectorial transmission is based upon research on related viruses such as bluetongue virus (BTV), and further direct studies of AHSV are required in order to improve our understanding of this important virus.

Published

2009

30. Development and evaluation of a real-time quantitative PCR assay for Culicoides imicola, one of the main vectors of bluetongue (BT) and African horse sickness (AHS) in Africa and Europe.

Author

Cêtre-Sossah C, Mathieu B, Setier-Rio ML, Grillet C, Baldet T, Delécolle JC, and Albina E

Subjects

Africa epidemiology, Animals, DNA, Intergenic genetics, Europe epidemiology, Sensitivity and Specificity, African Horse Sickness transmission, Bluetongue transmission, Ceratopogonidae genetics, Insect Vectors classification, Polymerase Chain Reaction methods

Abstract

The current microscopy method for identifying the Culicoides imicola Kieffer, 1913 species can be time and labour intensive. There is a need for the development of a rapid and quantitative tool to quantify the biting midges C. imicola ss in light trap catches. A reproducible and sensitive real-time polymerase chain reaction method that targets the internal transcribed spacer (ITS-1) of ribosomal DNA of C. imicola ss species was developed. This real-time PCR assay was first performed on 10-fold serial dilutions of purified plasmid DNA containing specific C. imicola ss ITS-1. It was then possible to construct standard curves with a high correlation coefficient (r2=0.99) in the range of 10(-2)-10(-8) ng of purified DNA. The performances of this PCR were evaluated in comparison with morphological determination on Culicoides trapped along the Mediterranean coastal mainland France. ROC statistical analysis was carried out using morphology as gold standard and the area under the ROC curve had a satisfactory value of 0.9752. The results indicated that this real-time PCR assay holds promise for monitoring C. imicola ss population in both surveillance and research programmes because of its good specificity (92%) and sensitivity (95%).

Published

2008

31. Virus recovery rates for wild-type and live-attenuated vaccine strains of African horse sickness virus serotype 7 in orally infected South African Culicoides species.

Author

Venter GJ and Paweska JT

Subjects

Administration, Oral, African Horse Sickness prevention & control, African Horse Sickness transmission, African Horse Sickness virology, African Horse Sickness Virus classification, Animals, Horses, Serotyping, South Africa, Vaccines, Attenuated, Virus Replication, African Horse Sickness Virus isolation & purification, Ceratopogonidae virology, Insect Vectors virology, Viral Vaccines administration & dosage

Abstract

Previously reported virus recovery rates from Culicoides (Avaritia) imicola Kieffer and Culicoides (Avaritia) bolitinos Meiswinkel (Diptera, Ceratopogonidae) orally infected with vaccine strain of African horse sickness virus serotype 7 (AHSV-7) were compared with results obtained from concurrently conducted oral infections with five recent AHSV-7 isolates from naturally infected horses from various localities in South Africa. Culicoides were fed sheep bloods spiked with 10(7.6) TCID(50)/mL of a live-attenuated vaccine strain AHSV-7, and with five field isolates in which virus titre in the bloodmeals ranged from 10(7.1) to 10(8.2) TCID(50)/mL). After an extrinsic incubation of 10 days at 23.5 degrees C, virus recovery rates were significantly higher in C. imicola (13.3%) and C. bolitinos (4.2%) infected with the live-attenuated virus than in midges infected with any of the field isolates. The virus recovery rates for the latter groups ranged from 0% to 9.5% for C. imicola and from 0% to 1.5% for C. bolitinos. The C. imicola population at Onderstepoort was significantly more susceptible to infection with AHSV-7 isolated at Onderstepoort than to the virus strains isolated from other localities. Results of this study suggest that tissue culture attenuation of AHSV-7 does not reduce its ability to orally infect competent Culicoides species and may even lead to enhanced replication in the vector. Furthermore, oral susceptibility in a midge population appears to vary for geographically distinct isolates of AHSV-7.

Published

2007

32. African horse sickness--a serious disease.

Subjects

African Horse Sickness Virus pathogenicity, Animals, Australia epidemiology, Disease Outbreaks prevention & control, Disease Outbreaks veterinary, Horses, Vaccination veterinary, African Horse Sickness epidemiology, African Horse Sickness pathology, African Horse Sickness prevention & control, African Horse Sickness transmission, Equidae

Published

2006

33. Differentiation of Culicoides obsoletus and Culicoides scoticus (Diptera: Ceratopogonidae) based on mitochondrial cytochrome oxidase subunit I.

Author

Pagès N and Sarto I Monteys V

Subjects

African Horse Sickness transmission, Animals, Bluetongue transmission, Ceratopogonidae anatomy & histology, Ceratopogonidae enzymology, Ceratopogonidae genetics, Electrophoresis, Agar Gel methods, Female, Insect Vectors anatomy & histology, Insect Vectors enzymology, Insect Vectors genetics, Male, Mitochondria enzymology, Molecular Sequence Data, Polymerase Chain Reaction methods, Sequence Alignment, Species Specificity, Ceratopogonidae classification, Electron Transport Complex IV genetics, Insect Vectors classification

Abstract

Culicoides obsoletus (Meigen) and Culicoides scoticus Downes & Kettle (Diptera: Ceratopogonidae) are sibling species of the Obsoletus group. This group comprises species of biting midges that are suspect vectors of bluetongue virus (family Reoviridae, genus Orbivirus, BTV) and African horse sickness virus (family Reoviridae, genus Orbivirus, AHSV). BTV and AHSV have been isolated several times from females of this group, although it has not been possible to determine the particular species harboring the virus, because of the inability to clearly identify the females of each species based on morphology. Both sexes of C. obsoletus and C. scoticus midges from Catalonia and the Balearics (Spain) were sequenced for the mitochondrial gene cytochrome oxidase subunit I (COI), and these sequences were analyzed to determine intra- and interspecific genetic variability. Species-specific primers for C. obsoletus and C. scoticus were designed and a polymerase chain reaction (PCR)-based diagnostic assay based on the COI gene and using a hemi-nested PCR technique was developed for reliably distinguishing the females of both species. The species-specific PCR diagnostic was compared with morphological discrimination of C. obsoletus and C. scoticus females. The morphologic characters were not fully reliable.

Published

2005

34. African horse sickness.

Author

Mellor PS and Hamblin C

Subjects

African Horse Sickness epidemiology, African Horse Sickness virology, African Horse Sickness Virus pathogenicity, Animals, Culicidae, Europe epidemiology, Horses, Insect Vectors, African Horse Sickness prevention & control, African Horse Sickness transmission

Abstract

African horse sickness virus (AHSV) causes a non-contagious, infectious insect-borne disease of equids and is endemic in many areas of sub-Saharan Africa and possibly Yemen in the Arabian Peninsula. However, periodically the virus makes excursions beyond its endemic areas and has at times extended as far as India and Pakistan in the east and Spain and Portugal in the west. The vectors are certain species of Culicoides biting midge the most important of which is the Afro-Asiatic species C. imicola. This paper describes the effects that AHSV has on its equid hosts, aspects of its epidemiology, and present and future prospects for control. The distribution of AHSV seems to be governed by a number of factors including the efficiency of control measures, the presence or absence of a long term vertebrate reservoir and, most importantly, the prevalence and seasonal incidence of the major vector which is controlled by climate. However, with the advent of climate-change the major vector, C. imicola, has now significantly extended its range northwards to include much of Portugal, Spain, Italy and Greece and has even been recorded from southern Switzerland. Furthermore, in many of these new locations the insect is present and active throughout the entire year. With the related bluetongue virus, which utilises the same vector species of Culicoides this has, since 1998, precipitated the worst outbreaks of bluetongue disease ever recorded with the virus extending further north in Europe than ever before and apparently becoming endemic in that continent. The prospects for similar changes in the epidemiology and distribution of AHSV are discussed.

Published

2004

35. Oral susceptibility of South African Culicoides species to live-attenuated serotype-specific vaccine strains of African horse sickness virus (AHSV).

Author

Paweska JT, Prinsloo S, and Venter GJ

Subjects

Administration, Oral, African Horse Sickness transmission, African Horse Sickness Virus classification, Animals, Female, Horses, Male, Serotyping veterinary, South Africa, Vaccines, Attenuated administration & dosage, Virus Replication, African Horse Sickness prevention & control, African Horse Sickness Virus immunology, Ceratopogonidae virology, Viral Vaccines administration & dosage

Abstract

The oral susceptibility of livestock-associated South African Culicoides midges (Diptera: Ceratopogonidae) to infection with the tissue culture-attenuated vaccine strains of African horse sickness virus (AHSV) currently in use is reported. Field-collected Culicoides were fed on horse blood-virus mixtures each containing one of the seven serotype-specific vaccine strains of AHSV, namely serotypes 1, 2, 3, 4, 6, 7 and 8. The mean titres of virus in the bloodmeals for the seven vaccine strains were between 6.8 and 7.6 log10TCID50/mL. All females (n = 3262) that survived 10 days extrinsic incubation (10 dEI) at 23.5 degrees C were individually assayed in microplate BHK-21 cell cultures. In midges tested immediately after feeding, AHSV was detected in 96.1% individuals; mean virus titre was 2.0 log10TCID50/midge. After 10 dEI virus recovery rates varied in Culicoides (Avaritia) imicola Kieffer from 1% (AHSV-2) to 11% (AHSV-7) and in Culicoides (A.) bolitinos Meiswinkel from 0% (AHSV-3) to 14.6% (AHSV-2). Although our results indicate that two major field vectors C. imicola and C. bolitinos are susceptible to oral infection with vaccine strains of AHSV, the level of viral replication for most of the vaccine strains tested was below the postulated threshold (=2.5 log10TCID50/midge) for fully disseminated orbivirus infection. In this study, for the first time AHSV has been recovered after 10 dEI from six non-Avaritia livestock-associated Old World species: C. engubandei de Meillon (AHSV-4), C. magnus Colaço (AHSV-3, -4), C. zuluensis de Meillon (AHSV-2, -4), C. pycnostictus Ingram & Macfie (AHSV-2), C. bedfordi Ingram & Macfie (AHSV-7), and C. dutoiti de Meillon (AHSV-7). As little is known about the virogenesis of AHSV in the southern African species of Culicoides, the epidemiological significance of our findings in relation to the potential for transmission of current AHSV vaccine strains by Culicoides requires further assessment.

Published

2003

36. Phylogenetic status and matrilineal structure of the biting midge, Culicoides imicola, in Portugal, Rhodes and Israel.

Author

Dallas JF, Cruickshank RH, Linton YM, Nolan DV, Patakakis M, Braverman Y, Capela R, Capela M, Pena I, Meiswinkel R, Ortega MD, Baylis M, Mellor PS, and Mordue Luntz AJ

Subjects

African Horse Sickness transmission, African Horse Sickness Virus isolation & purification, Animals, Bayes Theorem, Bluetongue transmission, Bluetongue virus isolation & purification, Ceratopogonidae enzymology, Ceratopogonidae genetics, Ceratopogonidae virology, DNA, Mitochondrial genetics, Disease Outbreaks veterinary, Female, Greece, Haplotypes, Horses, Insect Vectors enzymology, Insect Vectors genetics, Insect Vectors virology, Israel, Likelihood Functions, Male, Population Dynamics, Portugal, Sheep, South Africa, Ceratopogonidae classification, Electron Transport Complex IV genetics, Genes, Insect, Insect Vectors classification, Phylogeny

Abstract

The biting midge Culicoides imicola Kieffer (Diptera: Ceratopogonidae) is the most important Old World vector of African horse sickness (AHS) and bluetongue (BT). Recent increases of BT incidence in the Mediterranean basin are attributed to its increased abundance and distribution. The phylogenetic status and genetic structure of C. imicola in this region are unknown, despite the importance of these aspects for BT epidemiology in the North American BT vector. In this study, analyses of partial mitochondrial cytochrome oxidase subunit I gene (COI) sequences were used to infer phylogenetic relationships among 50 C. imicola from Portugal, Rhodes, Israel, and South Africa and four other species of the Imicola Complex from southern Africa, and to estimate levels of matrilineal subdivision in C. imicola between Portugal and Israel. Eleven haplotypes were detected in C. imicola, and these formed one well-supported clade in maximum likelihood and Bayesian trees implying that the C. imicola samples comprise one phylogenetic species. Molecular variance was distributed mainly between Portugal and Israel, with no haplotypes shared between these countries, suggesting that female-mediated gene flow at this scale has been either limited or non-existent. Our results provide phylogenetic evidence that C. imicola in the study areas are potentially competent AHS and BT vectors. The geographical structure of the C. imicola COI haplotypes was concordant with that of BT virus serotypes in recent BT outbreaks in the Mediterranean basin, suggesting that population subdivision in its vector can impose spatial constraints on BT virus transmission.

Published

2003

37. Evidence for a new field Culicoides vector of African horse sickness in South Africa.

Author

Meiswinkel R and Paweska JT

Subjects

African Horse Sickness etiology, African Horse Sickness Virus isolation & purification, Animals, Ceratopogonidae classification, Horses, Insect Vectors classification, Prevalence, Seasons, South Africa epidemiology, African Horse Sickness epidemiology, African Horse Sickness transmission, Ceratopogonidae virology, Disease Outbreaks veterinary, Insect Vectors virology

Abstract

Between February and May 1998, approximately 100 horses died of African horse sickness (AHS) in the cooler, mountainous, central region of South Africa. On 14 affected farms, 156,875 Culicoides of 27 species were captured. C. imicola Kieffer, hitherto considered the only field vector for AHS virus (AHSV), constituted <1% of the total Culicoides captured, and was not found on 29% of the farms. In contrast, 65% of the Culicoides were C. bolitinos Meiswinkel, and was found on all farms. Five isolations of AHSV were made from C. bolitinos, and none from 18 other species of Culicoides (including C. imicola).

Published

2003

38. Spatial distribution of Culicoides species in Portugal in relation to the transmission of African horse sickness and bluetongue viruses.

Author

Capela R, Purse BV, Pena I, Wittman EJ, Margarita Y, Capela M, Romão L, Mellor PS, and Baylis M

Subjects

African Horse Sickness Virus physiology, Animals, Bluetongue virus physiology, Disease Outbreaks veterinary, Horses, Population Dynamics, Portugal, Seasons, Sheep, African Horse Sickness transmission, Bluetongue transmission, Ceratopogonidae physiology, Ceratopogonidae virology, Insect Vectors physiology, Insect Vectors virology

Abstract

Surveillance of Culicoides (Diptera: Ceratopogonidae) biting midge vectors was carried out at 87 sites within a 50 x 50 km grid distributed across Portugal, using light trap collections at the time of peak midge abundance. Culicoides imicola (Kieffer) made up 66% of the 55 937 Culicoides in these summer collections. It was highly abundant in the central eastern portion of Portugal, between 37 degrees 5' N and 41 degrees 5' N, and in a band across to the Lisbon peninsula (at around 38 degrees 5' N). Of all the complexes, its distribution was most consistent with that of previous outbreaks of Culicoides-borne disease, suggesting that it may remain the major vector in Portugal. Its distribution was also broadly consistent with that predicted by a recent climate-driven model validating the use of remote sensing datasets for modelling of Culicoides distribution. Adult C. imicola were found to have overwintered at 12 of 20 sites re-surveyed in winter but it did so in very low numbers. Culicoides obsoletus (Meigen) and Culicoides pulicaris (Linnaeus) complex midges were widespread despite their low summer abundance. The observed coincidence of high abundances of C. imicola and high abundances of C. pulicaris in summer lead us to suggest that C. imicola could bring African horse sickness virus or bluetongue virus into contact with C. pulicaris and the latter complex, together with C. obsoletus, could then transmit these viruses across much wider areas of Europe. The fact that adult C. pulicaris are present in high abundances in winter may provide a mechanism by which these viruses can overwinter in these areas.

Published

2003

39. A comparison of the vector competence of the biting midges, Culicoides (Avaritia) bolitinos and C. (A.) imicola, for the Bryanston serotype of equine encephalosis virus.

Author

Venter GJ, Groenewald D, Venter E, Hermanides KG, and Howell PG

Subjects

African Horse Sickness virology, Animals, Ceratopogonidae classification, Female, Horses parasitology, Horses virology, South Africa, African Horse Sickness transmission, African Horse Sickness Virus physiology, Ceratopogonidae physiology, Ceratopogonidae virology, Insect Vectors physiology, Insect Vectors virology

Abstract

Equine encephalosis virus (EEV) is widespread and prevalent in southern Africa. In this study, the oral susceptibility of Culicoides (Avaritia) imicola Kieffer (Diptera: Ceratopogonidae) to EEV was confirmed. In addition, C. (A.) bolitinos Meiswinkel, collected in the high-lying eastern Free State, South Africa, was systemically infected with the Bryanston serotype of EEV after feeding through a membrane on artificially infected equine blood containing 4.7 log10 PFU/mL of EEV. The mean infectivity of Bryanston virus in C. bolitinos increased from 1.2 log10 PFU/midge, in midges assayed for virus immediately after feeding on the blood-virus mixture, to 3.1 log10 PFU/midge in midges assayed after 10 days' incubation at 23.5 degrees C. Elevated virus infectivity titres, found in individual infected C. bolitinos, suggested that this Culicoides species is a vector of EEV. This bovine dung-breeding Culicoides species may play an important role in transmitting EEV in the cooler parts of southern Africa, where it can be the most abundant Culicoides species collected near livestock. In the present study the prevalence of infection obtained for C. bolitinos (2.2%) with the Bryanston serotype of EEV was significantly lower than that of C. imicola (18.4%). After incubation, the Bryanston serotype of EEV was also isolated from one of 110 C. onderstepoortensis Fiedler assayed. However, the virus titre in this midge was 1.2 log10 PFU/midge, which is not different from the titre that would be expected immediately after feeding on the blood-virus mixture. Culicoides species that survived the incubation period and that were negative for the presence of Bryanston virus were C. magnus Colaço (96), C. bedfordi Ingram & Macfie (95) and C. pycnostictus Ingram & Macfie (45).

Published

2002

40. Transmission patterns of African horse sickness and equine encephalosis viruses in South African donkeys.

Author

Lord CC, Venter GJ, Mellor PS, Paweska JT, and Woolhouse ME

Subjects

Age Factors, Animals, Female, Geography, Male, Movement, Seroepidemiologic Studies, South Africa epidemiology, African Horse Sickness transmission, Encephalomyelitis, Equine transmission, Equidae virology, Orbivirus pathogenicity

Abstract

African horse sickness (AHS) and equine encephalosis (EE) viruses are endemic to southern Africa. AHS virus causes severe epidemics when introduced to naive equine populations, resulting in severe restrictions on the movement of equines between AHS-positive and negative countries. Recent zoning of South Africa has created an AHS-free zone to facilitate equine movement, but the transmission dynamics of these viruses are not fully understood. Here, we present further analyses of serosurveys of donkeys in South Africa conducted in 1983-5 and in 1993-5. Age-prevalence data are used to derive estimates of the force of infection, A. For both viruses, A was highest in the northeastern part of the country and declined towards the southwest. In most of the country, EE virus had a higher transmission rate than AHS. The force of infection increased for EE virus between 1985 and 1993, but decreased for AHS virus. Both viruses showed high levels of variation in transmission between districts within the same province, particularly in areas of intermediate transmission. These data emphasize the focal nature of these viruses, and indicate areas where further data will assist in understanding the geographical variation in transmission.

Published

2002

41. Using climate data to map the potential distribution of Culicoides imicola (Diptera: Ceratopogonidae) in Europe.

Author

Wittmann EJ, Mellor PS, and Baylis M

Subjects

African Horse Sickness transmission, Animals, Bluetongue transmission, Equidae, Europe, Logistic Models, Models, Biological, Rain, Ruminants, Temperature, Ceratopogonidae physiology, Climate, Insect Vectors physiology

Abstract

Culicoides imicola, a vector of bluetongue virus and African horse sickness virus, is principally Afro-Asian in distribution, but has recently been found in parts of Europe. A logistic regression model based on climate data (temperature, saturation deficit, rainfall and altitude) and the published distribution of C. imicola in Iberia was developed and then applied to other countries in Europe, to identify locations where C. imicola could become established. The model identified three temperature variables as significant determinants of the distribution of C. imicola in Iberia (minimum of the monthly minimum temperatures, maximum of the monthly maximum temperatures and number of months per year with a mean temperature > or = 12.5 degrees C). The model indicated that under current conditions, the distribution of C. imicola in Spain, Greece and Italy could be extended and the vector could potentially invade parts of Albania, Yugoslavia, Bosnia and Croatia. To simulate the effect of global warming, temperature values in the model were increased by 2 degrees C. Under these conditions, the potential spread of C. imicola in Europe would be even more extensive.

Published

2001

42. Prevalence of Culicoides imicola and other species (Diptera: Ceratopogonidae) at eight sites in Zimbabwe.

Author

Musuka GN, Meiswinkel R, Baylis M, Kelly PJ, and Mellor PS

Subjects

African Horse Sickness epidemiology, Animals, Bluetongue epidemiology, Horses, Prevalence, Sheep, Zimbabwe epidemiology, African Horse Sickness transmission, Bluetongue transmission, Ceratopogonidae growth & development, Insect Vectors growth & development

Published

2001

43. Stabling and the protection of horses from Culicoides bolitinos (Diptera: Ceratopogonidae), a recently identified vector of African horse sickness.

Author

Meiswinkel R, Baylis M, and Labuschagne K

Subjects

Animals, Horses, African Horse Sickness prevention & control, African Horse Sickness transmission, Diptera, Housing, Animal, Insect Vectors

Abstract

The stabling of horses at night reportedly offers protection from African horse sickness and the most significant vector of the disease, Culicoides imicola Kieffer, has been shown to be exophilic. In certain high-lying regions of South Africa, however, C. bolitinos Meiswinkel, may be the major vector of the disease but its entry behaviour into stables is unknown. Accordingly, in the eastern Free State province of South Africa, light trap catches of C. bolitinos inside stables and outside, were compared. Two horse-baited stables, one traditional, and one modern, were used and combinations of stable (old/new), ceiling fans (on/off) and accessibility to Culicoides (stable doors open/closed or windows gauzed/ungauzed) were investigated as treatments. A total of 111,452 Culicoides of 26 species was collected on 60 trap nights; C. bolitinos was dominant (89.1% overall) with C. imicola second in abundance (2.9%). Outside catches were greater on warmer, drier, evenings but were suppressed by high wind speeds. Catches of C. imicola inside stables with doors open, or with windows ungauzed, were less than the numbers captured outside. In contrast, more C. bolitinos were caught in open stables than outside, i.e. open structures may protect horses from the exophilic C. imicola, but may increase attack rates from the endophilic C. bolitinos. The closing of doors and the gauzing of windows, however, led to a 14-fold reduction in numbers of C. bolitinos and C. imicola entering stables. A well-gauzed 'traditional' stable was as effective as a closed 'modern' stable. Ceiling fans had no suppressant effect.

Published

2000

44. Climate change: effects on culicoides--transmitted viruses and implications for the UK.

Author

Wittmann EJ and Baylis M

Subjects

Animals, Climate, Horses, Humans, Insect Vectors, Population Dynamics, Sheep, United Kingdom epidemiology, African Horse Sickness transmission, Bluetongue transmission, Ceratopogonidae, Disease Outbreaks veterinary, Greenhouse Effect

Abstract

Changes in the distribution and abundance of insects are likely to be amongst the most important and immediate effects of climate change. We review here the risk that climate change poses to the UK's livestock industry via effects on Culicoides biting midges, the vectors of several arboviruses, including those that cause bluetongue (BT) and African horse sickness (AHS). The major old-world vector of BT and AHS viruses, C. imicola, occurs in southern Europe and will spread further north as global temperatures increase. It is unlikely, however, that in the foreseeable future it will reach and become established in the UK. As the distribution of C. imicola moves north, however, it may bring BT and AHS viruses into the range of other Culicoides species that are known to be competent vectors and which occur much further north. Once infected via this 'baton effect', these species may be able to spread the viruses over much of Europe, including the UK. Climate change may increase their vector competence further and will also increase the likelihood of viruses surviving from one year to the next. An additional risk is that the predicted increase in the frequency of short periods of hot temperatures may lead to the creation of novel vector species, by removing the barriers that in colder conditions make them refractory to viral infection., (Copyright 2000 Harcourt Publishers Ltd.)

Published

2000

45. Climatic and geographic influences on arboviral infections and vectors.

Author

Mellor PS and Leake CJ

Subjects

African Horse Sickness epidemiology, African Horse Sickness transmission, Animals, Arbovirus Infections transmission, Encephalitis, Arbovirus epidemiology, Encephalitis, Arbovirus transmission, Humans, Incidence, Insect Vectors physiology, Prevalence, Rift Valley Fever epidemiology, Rift Valley Fever transmission, Seasons, Arbovirus Infections epidemiology, Climate, Disease Vectors

Abstract

Those components of climate that are likely to have major effects upon the geographical distribution, seasonal incidence and prevalence of vector-borne diseases are described. On the basis of existing and predicted climatic variations, examples are given of the types of changes that are to be expected, using several internationally important human and animal arboviral diseases including Rift Valley fever and African horse sickness.

Published

2000

46. Culicoides in relation to transmission of African horse sickness virus in The Gambia.

Author

Rawlings P, Snow WF, Boorman J, Denison E, Hamblin C, and Mellor PS

Subjects

Animals, Antigens, Viral, Female, Gambia, Horses, Population Density, Serologic Tests, African Horse Sickness transmission, Ceratopogonidae, Insect Vectors, Orbivirus immunology

Abstract

Twelve light trap collections made near overnight shelters of horses and donkeys in four villages in the Central River Division of The Gambia captured fourteen species of biting midge of the genus Culicoides. Five species new to The Gambia were identified. This brought the number of recognized species of Culicoides (after a revision of C. schultzei) to twenty-nine in The Gambia. Species known or suspected as vectors of African horse sickness virus (AHSV) and bluetongue virus (BTV) comprised 83% of female captures, 65% of captures being C. imicola or its sibling species, C. miombo. Captures of female Culicoides in the late dry season were almost as large as in the early dry season, despite the extreme heat and dryness at this time of the year. Tests on batches of formalin-preserved female midges, using AHSV or BTV antigen capture ELISAs, did not show the presence of any virus amongst 2286 females in 240 aliquots. Nearly all Gambian equines are reportedly seropositive to AHSV and these results suggest that virus challenge from Culicoides vectors may be a factor in the health of Gambian horses and donkeys.

Published

1998

47. The seasonal and geographical distribution of Culicoides imicola, C. pulicaris group and C. obsoletus group biting midges in central and southern Spain.

Author

Ortega MD, Mellor PS, Rawlings P, and Pro MJ

Subjects

African Horse Sickness epidemiology, African Horse Sickness transmission, Animals, Bluetongue epidemiology, Bluetongue transmission, Disease Outbreaks veterinary, Equidae, Ruminants, Seasons, Spain epidemiology, Ceratopogonidae physiology, Insect Vectors physiology

Abstract

Pirbright-type light traps were used to collect Culicoides biting midges (Diptera: Ceratopogonidae) at fifteen sites in twelve provinces of central Spain and Andalusia. A total of 293,625 Culicoides were collected in 1,387 samples over a two year period. These comprised approximately 9.2% Culicoides imicola, 11.4% C. pulicaris group, 1.6% C. obsoletus group and 12.2% C. circumscriptus. Culicoides imicola was present at ten of the fifteen sites; the five sites from which it was absent were the most eastern of the fifteen. The greatest abundance of this species was at Navalmoral in Caceres Province. Culicoides pulicaris group were present at all sites; C. obsoletus group were present at twelve sites. The annual peaks in abundance were: C. imicola, August-October; C. pulicaris group, May-June; and C. obsoletus group, March-June. The geographical and seasonal distributions of C. imicola are consistent with those of the outbreaks of African horse sickness (AHS) and bluetongue (BT) during epizootics in Spain, and support the contention that C. imicola was the major vector of AHS and BT viruses.

Published

1998

48. The relationship between climate and the distribution of Culicoides imicola in Iberia.

Author

Rawlings P, Capela R, Pro MJ, Ortega MD, Pena I, Rubio C, Gasca A, and Mellor PS

Subjects

African Horse Sickness epidemiology, African Horse Sickness transmission, Animals, Disease Outbreaks veterinary, Equidae, Geography, Humidity, Portugal epidemiology, Spain epidemiology, Temperature, Ceratopogonidae physiology, Climate, Insect Vectors physiology

Abstract

The biting midge Culicoides imicola was captured at 17 of 27 farms in Spain and Portugal during a survey of its distribution following outbreaks of African horse sickness in Iberia that occurred between 1987 and 1990. Farms were sampled approximately twice weekly from October 1992 to February 1995. Farms were widely spaced apart (maximum 850 km) and had considerable variation in climate. Across sites, summer temperatures ranged from 18.3 degrees C-27.2 degrees C; in winter the range was 4.4 degrees C-11.6 degrees C. Relative humidities in summer ranged from 37.2% to 90.1%. Proximity to southern Spain (Seville) was the most significant predictor of the presence/absence of C. imicola, but high summer temperatures and possibly dry summer conditions, were also important. Vila Nova de Milfontes in Portugal, where C. imicola was abundant and the climate is relatively cool, was an exception to the climatic trends at the other 26 sites. This exception points to a lack of knowledge of climatic requirements for immature development of C. imicola. The absence of C. imicola from the three most easterly sites, which have apparently favourable climates, suggests a relatively recent invasion by this species into Iberia.

Published

1998

49. Transmission and distribution of African horse sickness virus serotypes in South African zebra.

Author

Lord CC, Woolhouse ME, and Barnard BJ

Subjects

African Horse Sickness epidemiology, African Horse Sickness virology, Animals, Prevalence, Serotyping veterinary, South Africa epidemiology, African Horse Sickness transmission, African Horse Sickness Virus classification, Equidae

Abstract

The prevalences of African horse sickness (AHS) virus serotypes in zebra foals from the Kruger National Park, South Africa were examined for possible associations between serotypes. Serotypes known to cross-react were combined for analysis. The distributions of serotypes between zebra were not always independent; in 7-8 month old zebra positive pairwise associations were observed between 3 serotypes. This could be generated by biological interactions between serotypes or heterogeneity in host-vector transmission. The data were also used to estimate the basic reproduction number, R0. For AHS virus overall, estimates of R0 ranged from 31-68. This underlines the need for a better understanding of serotype transmission and interactions in AHS.

Published

1998

50. The 1996 outbreak of African horse sickness in South Africa--the entomological perspective.

Author

Meiswinkel R

Subjects

African Horse Sickness epidemiology, African Horse Sickness prevention & control, Animals, Horses, Housing, Animal, Rain, Seasons, South Africa epidemiology, African Horse Sickness transmission, Ceratopogonidae physiology, Disease Outbreaks veterinary, Insect Vectors physiology

Abstract

During the 1996 summer season (January-April) in South Africa an estimated 500 horses died of African horse sickness (AHS); 80% of deaths were due to AHS virus serotypes 2 and 4. Nearly all cases occurred in the northern, north-eastern and central parts of South Africa. This study reports the first attempt to verify the involvement of the biting midge Culicoides imicola in a field outbreak of AHS in southern Africa. In light-trap collections made at 47 sites over 12 weeks, C. imicola comprised 94.2% of 4.78 million Culicoides. Culicoides imicola was the most prevalent of 34 species captured and was the only species whose distribution matched that of the disease. Record catches of C. imicola were made, and reveal that in years of above average rainfall its numbers can show a 200-fold increase over those in dry years. Soil type appeared to determine strongly the distribution of C. imicola. The largest populations of C. imicola were found in areas with clayey, moisture-retentive soils whereas the lowest numbers, or none, occurred in areas where the soils were sandy and quick-draining. The deaths of two horses (confirmed AHS) in a sandy area were perplexing as they occurred in a region known to be free of C. imicola. The probable origin of these infections was established.

Published

1998