Identifying equine premises at high risk of introduction of vector-borne diseases using geo-statistical and space-time analyses

The identification of premises that may play an important role in the introduction or spread of animal diseases is fundamental to the development of risk-based surveillance and control programs. A combination of geo-statistical and cluster analysis methods was used to identify geographical areas and periods of time at highest risk for introduction of the African horse sickness virus (AHSV) into the Castile and Leon (CyL) region of Spain. Risk was estimated based on the predicted premises-specific abundance of Culicoides spp., a vector for AHSV, and on the frequency of equine introductions from outside regions. The largest abundance of Culicoides spp. was observed between May and September in the northern region of CyL. Six significant (P-value <0.01) space-time clusters of equine premises were found, at which presence of Culicoides spp. was predicted and live equidae were introduced from outside CyL. The clusters included 37 equine premises and took place between April and December. These results will contribute to updating plans for prevention of AHSV introduction and spread in Spain. The methodological approach developed here may be adapted and applied to design and establish risk-based surveillance and control programs for Spain and other European countries.     

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

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).     

Rapid and sensitive detection of African horse sickness virus by real-time PCR

A highly sensitive and specific TaqMan-MGB real-time RT-PCR assay has been developed and standardised for the detection of African horse sickness virus (AHSV). Primers and MGB probe specific for AHSV were selected within a highly conserved region of genome segment 7. The robustness and general application of the diagnostic method were verified by the detection of 12 AHSV isolates from all of the nine serotypes. The analytical sensitivity ranged from 0.001 to 0.15 TCID₅₀ per reaction, depending on the viral serotype. Real-time PCR performance was preliminarily assessed by analysing a panel of field equine samples. The same primer pair was used to standardise a conventional RT-PCR as an affordable, useful and simple alternative method in laboratories without access to real-time PCR instruments. The two techniques present novel tools to improve the molecular diagnosis of African horse sickness (AHS).     

非洲马瘟病毒VP7蛋白研究进展

非洲马瘟(African horse sickness, AHS)是由非洲马瘟病毒(African horse sickness virus, AHSV)引起的一种通过库蜢等昆虫传播的、主要感染马科动物的传染病。我国是世界动物卫生组织认可的非洲马瘟无疫国,随着AHS疫情在东南亚的传播,增大了疫情传入我国的风险。AHSV编码了7种结构蛋白(VP1～VP7),其中VP7是病毒内衣壳蛋白的主要组成部分,在AHSV 9个血清型中高度保守,常作检测的靶标。此外,VP7蛋白的自组装特点对于AHSV亚单位疫苗和病毒样颗粒疫苗(VLP)的研究有基础性作用。对当前AHSV VP7蛋白相关研究进展进行了综述,以期为AHSV检测方法及疫苗等研究提供参考。     

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

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.     

African horse sickness in naturally infected,immunised horses

To determine whether subclinical cases, together with clinical cases, of African horse sickness (AHS) occur in immunised horses in field conditions, whole blood samples were collected and rectal temperatures recorded weekly from 50 Nooitgedacht ponies resident in open camps at the Faculty of Veterinary Science, University of Pretoria, Onderstepoort, during 2008–2010. The samples were tested for the presence of African horse sickness virus (AHSV) RNA by a recently developed real‐time RT‐PCR. It was shown that 16% of immunised horses in an AHS endemic area were infected with AHSV over a 2 year period, with half of these (8%) being subclinically infected. The potential impact of such cases on the epidemiology of AHS warrants further investigation.     

非洲马瘟病毒、西尼罗病毒和马冠状病毒的基因芯片检测技术研究

为探索建立马病病毒基因芯片检测方法,采用人工拼接的方式拼接了非洲马瘟病毒(ASHV)核酸序列,通过分子克隆技术获得西尼罗病毒(WNV)和马冠状病毒(ECV)的特异基因片段。用芯片点样仪逐点分配到处理过的玻片上,制备成检测芯片。以拼接、克隆的核酸序列为模板通过多重不对称RT-PCR进行特异性扩增和荧光标记后滴加到芯片上进行杂交,对杂交结果进行扫描检测和计算机软件分析。结果显示,制备的基因芯片可同时检测和鉴别上述3种病毒,ECV质粒样品、WNV质粒样品检测灵敏度为10²拷贝;AHSV质粒样品检测灵敏度为10⁴拷贝。其他病毒材料未出现荧光信号,验证了本方法的特异性。证明基因芯片技术可快速、准确和灵敏地同时进行多种病毒的检测。     

A serological survey of African horse sickness in Botswana

A retrospective serological survey of African horse sickness (AHS) in Botswana covering a 10-year period (1995-2004) is reported. The survey involved horses showing clinical symptoms of the disease; the horses had not been vaccinated against AHS. Over the period surveyed, serological evidence suggestive of infection with AHS virus (AHSV) was found in 99 clinical cases out of which 41.4% (41/99) cases were found during the 1st half (1995-1999) and 58.6 % (58/99) cases were found in the 2nd half of the survey period (2000-2004). These serological findings are discussed in relation to AHSV serotypes isolated from diseased horses in Botswana before and during the period of this serological survey.     

环状病毒的流行与传播

环状病毒是牲畜常见的重要病原体,主要包括有蓝舌病病毒、非洲马瘟病毒、马器质性脑病病毒和流行性出血热病毒等。这些病毒能够通过吸血性的库蠓传播。本文主要介绍了这几种病毒在世界各地的流行与传播情况。     

First Report of an Outbreak of African Horsesickness Virus Serotype 2 in the Northern Hemisphere

A case of a rapidly fatal disease in polo horses caused by African horsesickness (AHS) virus serotype 2 is described. The pattern of polo tournaments, environmental/management conditions (moist and warm), as well as probable importation strategies with no regard for import control and quarantine, favored introduction and spread of the virus. The outbreak, which involved a large number of horses, was characterized by severe respiratory distress, fever, supraorbital edema, and death. This is the first time a widespread epidemic of AHS has been reported in Nigeria and this is the first report of AHSV serotype 2 in the northern hemisphere. In addition, we amplified the complete genome of the virus using RNA extracted from clotted blood. This report indicates that AHS is expanding its geographical territory northwards and assuming a new microbial ecology.     

非洲马瘟间接ELISA方法的建立及初步应用

为建立检测非洲马瘟间接酶联免疫吸附试验方法,利用重组杆状病毒感染昆虫细胞表达出具有良好抗原性的VP7蛋白,将感染VP7重组杆状病毒的昆虫细胞裂解液作为包被抗原,通过优化包被抗原浓度、二抗稀释度等,建立了检测非洲马瘟的间接ELISA方法,并进行了初步运用。结果表明,直接利用真核细胞表达VP7蛋白的昆虫细胞裂解液作为包被液可成功建立检测非洲马瘟的间接ELISA方法。     

African horse sickness

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.     

Effects of chlorine, iodine, and quaternary ammonium compound disinfectants on several exotic disease viruses

The effects of three representative disinfectants, chlorine (sodium hypochlorite), iodine (potassium tetraglicine triiodide), and quaternary ammonium compound (didecyldimethylammonium chloride), on several exotic disease viruses were examined. The viruses used were four enveloped viruses (vesicular stomatitis virus, African swine fever virus, equine viral arteritis virus, and porcine reproductive and respiratory syndrome virus) and two non-enveloped viruses (swine vesicular disease virus (SVDV) and African horse sickness virus (AHSV)). Chlorine was effective against all viruses except SVDV at concentrations of 0.03% to 0.0075%, and a dose response was observed. Iodine was very effective against all viruses at concentrations of 0.015% to 0.0075%, but a dose response was not observed. Quaternary ammonium compound was very effective in low concentration of 0.003% against four enveloped viruses and AHSV, but it was only effective against SVDV with 0.05% NaOH. Electron microscopic observation revealed the probable mechanism of each disinfectant. Chlorine caused complete degeneration of the viral particles and also destroyed the nucleic acid of the viruses. Iodine destroyed mainly the inner components including nucleic acid of the viruses. Quaternary ammonium compound induced detachment of the envelope of the enveloped viruses and formation of micelle in non-enveloped viruses. According to these results, chlorine and iodine disinfectants were quite effective against most of the viruses used at adequately high concentration. The effective concentration of quaternary ammonium compound was the lowest among the disinfectants examined.     

Re-emergence of bluetongue, African horse sickness, and other Orbivirus diseases

Arthropod-transmitted viruses (Arboviruses) are important causes of disease in humans and animals, and it is proposed that climate change will increase the distribution and severity of arboviral diseases. Orbiviruses are the cause of important and apparently emerging arboviral diseases of livestock, including bluetongue virus (BTV), African horse sickness virus (AHSV), equine encephalosis virus (EEV), and epizootic hemorrhagic disease virus (EHDV) that are all transmitted by haematophagous Culicoides insects. Recent changes in the global distribution and nature of BTV infection have been especially dramatic, with spread of multiple serotypes of the virus throughout extensive portions of Europe and invasion of the south-eastern USA with previously exotic virus serotypes. Although climate change has been incriminated in the emergence of BTV infection of ungulates, the precise role of anthropogenic factors and the like is less certain. Similarly, although there have been somewhat less dramatic recent alterations in the distribution of EHDV, AHSV, and EEV, it is not yet clear what the future holds in terms of these diseases, nor of other potentially important but poorly characterized Orbiviruses such as Peruvian horse sickness virus.     

Probability of introduction of exotic strains of bluetongue virus into the US and into California through importation of infected cattle

Strategies designed to minimize the probability of bluetongue virus (BTV) introduction to new areas should be based on a quantitative assessment of the probability of actually establishing the virus once it is introduced. The risk of introducing a new strain of bluetongue virus into a region depends on the number of viremic animals that enter and the competency of local vectors to transmit the virus. We used Monte Carlo simulation to model the probability of introducing BTV into California, USA, and the US through importation of cattle. Records of cattle and calf imports into California and the US were obtained, as was seroprevalence information from the exporting countries. A simulation model was constructed to evaluate the probability of importing either a viremic PCR-negative animal after 14-day quarantine, a c-ELISA BTV-antibody-negative animal after 28-day quarantine, or an untested viremic animal after 100-day quarantine into California and into the US. We found that for animals imported to the US, the simulated (best to worst scenarios) median percentage that tested positive for BTV-antibody ranged from 5.4 to 7.2%, while for the subset imported to California, the simulated median percentage that tested positive for BTV-antibody ranged from 20.9 to 78.9%. Using PCR, for animals imported to the US these values were 71.8–85.3%, and for those imported to California, the simulated median that test positive ranged from 74.3 to 92.4%. The probability that an imported animal was BTV-viremic is very low regardless of the scenario selected (median probability = 0.0%). The probability of introducing an exotic strain of BTV into California or the US by importing infected cattle was remote, and the current Office International des Epizooties (OIE) recommendation of either a final PCR test performed 14 days after entry into quarantine, a c-ELISA performed 28 days after entry into quarantine or a 100-day quarantine with no testing requirement was adequate to protect cattle in the US and California from an exotic strain of BTV.     

应用多重PCR检测和区分3个型的马疱疹病毒

针对马疱疹病毒（EHV）的EHV-1、EHV-2和EHV-4糖蛋白B基因序列，设计、合成了3对特异性引物进行多重PCR，不仅可以在数小时内分别检测这3个型的EHV，而且在同一反应系统内可以清晰地区分EHV-1、EHV-2和EHV-4，其PCR产物大小分别为226、333、570bp，符合预期的片段大小，序列分析证实与已发表的序列一致；该检测方法的灵敏度达到10^3 TCID50；分别从血清学阳性但病毒分离为阴性的1匹进口马组织样品和一些出口前检疫马的鼻咽样品检测到EHV-1和EHV-4特异性核酸。