Role of horse flies in transmission of wquine infectious anemia from carrier ponies

Equine infectious anemia virus was transmitted from an acutely ill and an inapparently infected pony to uninfected ponies by the interrupted feeding of horse flies (tabanids). Transmission from acutely ill ponies was not accomplished following: (1) the interrupted feeding of a single horse fly, (2) bites of horse flies that had fed on an acutely affected pony 24 hours earlier, (3) bites of horse flies that had oviposited after feeding on an acutely affected pony, or (4) the inoculation of larval material derived from horse flies that had fed to repletion. It was concluded that horse fly transmission of equine infectious anemia virus is mechanical only and that infected horses that are free of clinical signs can be a source of virus for insect transmission.     

Detection of equine infectious anemia virus in a horse with an equivocal agar gel immunodiffusion test reaction

A horse whose serum reacted equivocally in the agar gel immunodiffusion (AGID) test for equine infectious anemia was studied over a 3-year period. The horse remained afebrile and virus was detected in only 1 of 6 horse inoculation tests. The intensity of AGID test reactions increased temporarily following this evidence for virus. Although the AGID test reaction was equivocal and 5 of the 6 transmission attempts failed, the 1 successful transmission proved the horse was infected.     

Equine infectious anemia virus: development of a simple reproducible method for titrating infectivity of the cell-adapted strain.

An equine dermal cell line between the 14th and 30th subpassages was used to develop a reproducible method of titrating the infectivity of the cell-adapted strain of equine infectious anemia virus (EIAV). Cells inoculated with EIAV were subcultured or fed once each week and were monitored for the production of P26 antigen of EIAV in supernatant fluids. Ultrathin sections were prepared once each week and were examined for the detection of budding virus-like particles (VLP). The VLP could not be detected in the infected cells subcultured once each week. When the medium was changed once week and when the cells not transferred, budding VLP were detected routinely after 3 to 4 weeks, Feeding of the infected cells once each week was used to establish the infectivity assay. The reproducibility of the assay on a frozen viral stock preparation was within an endpoint of one tenfold dilution.     

Failure to propagate equine infectious anemia virus in mosquitoes and Culicoides variipennis.

Laboratory-colonized mosquitoes, Culex tarsalis, aedes aegypti, Culiseta inornata, and Anopheles free-borni, and the biting gnat, Culicoides variipennis, were exposed to equine infectious anemia virus. Exposure to the virus was by intrathoracic inoculation for mosquitoes and by oral ingestion of an infective blood meal through a membrane for C variipennis. After various intervals, groups of 15 to 20 insects were homogenized and inoculated into susceptible ponies. Positive immunodiffusion test results were used as criterion for equine infectious anemia infection in ponies. Virus was not detected in the 4 species of mosquitoes at 3, 6, 12, and 18 days after inoculation, or in C variipennis at 6, 8, 12, 14, 21, and 26 days after oral exposure to the virus.     

Enzyme-linked immunosorbent assay for detection of equine infectious anemia antibody to purified P26 viral protein

An indirect enzyme-linked immunosorbent assay (ELISA) was developed for the detection of equine infectious anemia (EIA) antibody in horse sera. Purified P26 viral protein was the antigen; alkaline phosphatase linked to rabbit anti-horse immunoglobulin G was the conjugate. The ELISA detected EIA antibodies in horse sera as early as 11 to 14 days after experimental inoculations. There was full agreement between the results of ELISA and the agar-gel immunodiffusion tests on EIA proficiency test sera. The ELISA readily detected EIA antibody in horse sera that had weak positive reactions on agar-gel immunodiffusion.     

Indirect hemagglutination test in equine infectious anemia.

An indirect hemagglutination was developed for the diagnosis of equine infectious anemia using sheep red blood cells coated with group specific virus antigen which had been highly purified by affinity chromatography. The presence of indirect hemagglutination antibodies was demonstrated in horses with equine infectious anemia since the cells were specifically agglutinated by all the serum samples obtained from experimentally infected horses. Antibodies appeared within 35 days after inoculation, and development of which coincided well with that of precipitating and complement fixing antibodies. Titer of indirect hemagglutination antibodies were ten to 320 times greater than those of precipitating antibodies. Test results could be read more clearly by the indirect hemagglutination test especially in weakly positive cases. Ninety-six samples from suspected field cases collected from every region of Japan which were positive on the immunodiffusion test were also positive on indirect hemagglutination test. Serum samples from 420 horses in one race track were examined by both the indirect hemagglutination and immunodiffusion tests to determine the reliability of the indirect hemagglutination test for diagnosis of equine infectious anemia. The same result was obtained on both tests. Based on this evidence, the indirect hemagglutination test can be employed as a very sensitive serological test for the diagnosis of equine infectious anemia.     

马传染性贫血病毒envgp90基因在实验感染马体内的遗传变异

为确定马传染性贫血病毒（ＥＩＡＶ）ｅｎｇ ｇｐ９０基因的遗传变异特性,本研究应用ＥＬＡＶ日本分离强毒株Ｐ３３７－Ｖ７０实验感染了１匹健康马,经第２次感染后,实验马未呈现临床症状,ｇｐ９０基因的核苷酸序列被直接从这匹马的外周血和肝脏所获得的前病毒ＤＮＡ扩增。     

Proviral Genomic Variation of EIAV Envelop gp 90 Gene Observed in Experimentally Infected Horse

The present experiment was designed to observe the genetic variation of equine infectious anemia virus (EIAV) envelop gp 90 gene in infected horse. One horse was infected experimentally with P337-V70 strain and showed no clinical signs after being infected at twice with the same virus strain. Seventeen proviral sequences covering principal neutralizing domain (PND) of EIAV gp 90 gene were obtained from the buffy coat and liver of the horse through PCR amplification and cloning. Comparative analysis of the sequences revealed that some sequences contained the nucleotide insertions in the PND region. The insertions might be generated by direct repeat and strand displacement of sequence segment in their PND gene, showing different lenghts.     

Induction of a cell membrane antigen by equine infectious anemia virus.

Equine fibroblasts persistently infected with equine infectious anemia virus acquire a new cell membrane antigen demonstrable by indirect radioimmunoassay, using infected horse serum as an antibody source.     

Encephalitozoon cuniculi–Associated Equine Encephalitis: A Case Report

A case of encephalitis of unknown origin in the horse was investigated. Postmortem examination findings revealed a nonsuppurative granulomatous meningoencephalitis in the right hemisphere of the cerebral cortex. Testing for West Nile virus, equine herpes virus, equine infectious anemia, Toxoplasma gondii, Neospora caninum, and Sarcocystis neurona were negative. The horse had a titer for Encephalitozoon cuniculi, and sections from the affected area of the brain tested positive for the organism using both polymerase chain reaction (PCR) and immunohistochemistry. Amplicons generated using PCR were sequenced, and E. cuniculi genotype II was identified. This is the first case of E. cuniculi genotype II associated with encephalitis in the horse.     

利用Real-time PCR对外周血白细胞中EIAV前病毒及血浆中病毒RNA含量的测定

利用Real-time PCR和Real-time RT-PCR方法对马传染性贫血病(EIA)驴白细胞弱毒疫苗(DLA-EIAV)、DLA-EIAV感染性分子克隆衍生毒(vOK8226)、强弱毒嵌合病毒(vOKVltr)以及EIA强毒接种马后不同时期外周血白细胞中前病毒含量及血浆中病毒含量进行了监测,结果发现直接攻击强毒的2匹马及1匹接种vOK8226后再用强毒攻击的马血浆中病毒含量快速升高,伴随着明显的临床反应,最后均以死亡结束.其它免疫接种马在攻击强毒后均获得保护,没有发病,马血浆中有低水平病毒存在,攻毒后3个月血浆中检测不到病毒,说明感染马体内病毒的大量增殖与疾病的进程有着直接的关系.而外周血白细胞中前病毒的含量在各试验马各时期均能检测到,说明EIAV以前病毒的形式潜伏在感染马体内,疫苗的免疫只能控制发病,而不能清除感染的病毒.     

Persistent thrombocytopenia in a case of equine infectious anemia

Persistent thrombocytopenia was detected in a horse with equine infectious anemia (EIA). The thrombocytopenia was considered to be immune-mediated, developing secondary to infection with EIA virus. Epistaxis, petechial hemorrhages, subcutaneous hematomas, and edema resolved after treatment with corticosteroids; however, the owners requested that the mare by euthanatized because of infection with EIA virus. Although clinical signs attributable to immune-mediated thrombocytopenia may resolve with appropriate treatment, horses with immune-mediated thrombocytopenia secondary to EIA have a guarded to grave prognosis, because of the risk of recurrence and transmission of the EIA virus.     

Effect of viral inoculum size on appearance of clinical signs in equine Getah virus infection.

A study was performed to examine the effect of viral inoculum size on the appearance of clinical signs in equine Getah virus (GV) infection by intramuscular inoculation with 10(1.3) to 10(6.3) TCID50 of the MI-110 strain in 6 experimental horses. When inoculated with more than 10(3.3) TCID50 of the virus, every horse developed pyrexia, edema in the hind legs, serous nasal discharge, lymphopenia and viremia in the relatively early stage of disease. On the other hand, enlargement of the submandibular lymph node was observed only in horses inoculated with 10(5.3) and 10(6.3) TCID50 of the virus, while typical eruptions were developed in every horse inoculated with 10(4.3) TCID50 or less. These results demonstrated that the appearance of clinical signs in equine GV infection was dependent on viral inoculum size. Besides, it was assumed to be rare chance that eruptions and enlargement of the submandibular lymph node were developed simultaneously in a horse.     

Interstate Equine Semen and Embryo Shipment Regulations in the United States and Their Implications on Control of Disease Transmission

Outbreaks of both equine viral arteritis and contagious equine metritis (CEM) in the United States have occurred in recent years. Shipped semen has been implicated in disease transmission and rapid spread. A survey was performed of state regulations regarding testing for equine arteritis virus (EAV) and CEM before interstate semen or embryo shipment. Results demonstrated lack of any requirements in 31 states. Four states had regulations regarding EAV; 17 required a Certificate of Veterinary Inspection (CVI) to accompany a semen or embryo shipment. Ten states required a negative equine infectious anemia test, primarily as a requirement of a CVI versus because of risk of dissemination of disease. No states required CEM testing. A comparison of state department of agriculture or veterinary medical association Web sites and direct communication with state veterinarians or their offices demonstrated contradictory information in six states. The lack of uniform regulations concerning CEM and EAV testing for shipped semen and embryos, and the threat they pose to the equine breeding industry and horse health, should be alarming to veterinarians and horse owners. Routine testing of animals before shipment of semen or embryos and veterinary involvement in collection and breeding activities are appropriate and necessary to help prevent future outbreaks and protect equine health.     

马传贫驴白细胞弱毒疫苗株基质蛋白基因的克隆与表达

从感染驴白细胞的马传贫驴白细胞弱毒疫苗株前病毒DNA中克隆了编码基质蛋白（p15)的基因，并在大肠杆菌中进行了表达，所表达的蛋白是一种可溶性的融合蛋白，其氨基端带有6个组氨酸的标签，因此可以用固定化金属离子亲和层析法在非变性条件下进行纯化，在间接ELISA和免疫印迹试验中，重组的基质蛋白可与马传贫阳性血清样品发生反应，而与健康马血清无任何反应，这表明该重组蛋白具有良好的抗原性和特异性，可用于马传贫弱毒疫苗株在体内外复制及在接种马体人免疫应答的研究中。     

H3N8亚型马流感病毒单克隆抗体的制备及鉴定

以灭活马流感病毒(EIV)A/Equine/Jilin/1/1989(H3N8)为免疫原,免疫Balb/c小鼠,经常规细胞融合后,用血凝抑制试验(H1)和间接ELISA方法筛选获得3株(3C2、5G10和5A10)能稳定分泌H3N8亚型马流感病毒单克隆抗体(mAb)的杂交瘤细胞株.其中3C2和5G10为IgG2α,5A...     

Use of western blot and radioimmunoprecipitation for diagnosis of feline leukemia and feline immunodeficiency virus infections.

The uses and limitations of the western blot (WB) and radioimmunoprecipitation assay (RIPA) techniques for study of feline immunodeficiency virus (FIV) and FeLV were evaluated. Western blot analysis was used to detect antigenic relatedness between the 2 lentiviruses. Using a rabbit serum directed against p26 of the equine infectious anemia virus (EIAV) and anti-EIAV horse serum obtained from an infected horse, cross-reactivity with p24 of FIV was revealed. Cat sera obtained late after experimentally induced FIV infection recognized p26 of EIAV, which indicates reciprocal cross-reactivity. For RIPA, FIV was metabolically labeled, and virus-coded proteins were identified, using immunoprecipitation. Polypeptides with apparent molecular mass of about 15, 24, 43, 50, 120, and 160 kilodaltons were detected. An additional polypeptide of 10 kilodaltons was found only by use of WB analysis.     

Detection of equine infectious anemia virus in horse leukocyte cultures derived from horses in various stages of equine infectious anemia viral infection

The enzyme-linked immunosorbent assay (ELISA) antigen-positive and agar-gel immunodiffusion test (AGID)-negative horses do not have infective equine infectious anemia (EIA) virus. The ELISA testing of horse leukocyte culture (HLC) supernatants did detect EIA virus in a HLC that was infected with the Wyoming strain of EIA virus and in HLC derived from horses in febrile, acute, or subacute stages of EIA infection. In supernatants of HLC derived from chronic and inapparent carrier horses, EIA virus was not detected with ELISA. Direct fluorescent antibody tests detected EIA virus in HLC infected with 10(6)TCID50 of the Wyoming strain of EIA virus and in 50% of the HLC from febrile acute or subacute horses. The direct fluorescent antibody testing of HLC derived from chronic and inapparent carrier horses did not detect cell-associated EIA virus. The pony inoculation test proved to be the most reliable and accurate method for detecting infective EIA virus in horses in various stages of EIA infection and accurately correlated with the AGID test.     

Apparent propagation of the equine infectious anemia virus in a mosquito (Culex pipiens quinquefasciatus Say) ovarian cell line.

A tissue culture of Culex pipiens quinquefasciatus Say ovarian cells appeared to support the growth of equine infectious anemia (EIA) virus. Shetland ponies inoculated with 2nd, 7th, 9th, and 11th passages of mediums harvested from infected tissue culture had clinical signs of the disease and became EIA positive on 11, 19, 23, and 43 days after inoculation, respectively.     

2. Persistence of Equine Herpesviruses in Experimentally Infected Horses and the Experimental Induction of Abortion

An 8-month-old filly (No. 2) developed an acute vulvo-vaginitis and respiratory disease following inoculation of equine herpesvirus (EH virus) type 1 (EH 39 virus; equine rhinopneumonitis virus) into the vestibule of the vagina. The same virus produced acute respiratory disease but not balanoposthitis following intranasal, intravenous and intrapreputial inoculation of a 12-month-old colt (No. 3). A second 8-month-old filly (No. 1) developed a mild respiratory disease but not vulvo-vaginitis following intravestibular inoculation of EH 39 virus. EH viruses that were slowly cytopathic for equine foetal kidney cell cultures and serologically unrelated to the inoculated EH 39 virus were isolated from the buffy coat cells at 3 days and from the nasal cavity at 6 days after inoculation of horse No. 1. EH virus that was slowly cytopathic and serologically unrelated to EH 39 virus was isolated at 16 days from the vagina of the filly (No. 2) that developed acute vulvovaginitis and was frequently isolated from the nasal cavities of 2 of the 3 horses for 83 days and from the nasal cavity of the third horse for 57 days under conditions that precluded reinfection from other equidae except from each other. EH viruses were recovered from the 3 horses for a further 58 days under conditions where contact with other equidae may, although was not known to, have occurred between 83 and 141 days postinoculation. It was concluded that these viruses represented a single virus type that was present in the nasal cavity (designated EH 1–6 virus) perhaps also the blood stream of filly No. 1 at the time the 3 horses were purchased and that this virus was subsequently transmitted to the vagina of 1 and the nasal cavities of the other 2 horses. Accordingly a carrier state for EH 39 virus was not shown to occur. These findings are discussed in relation to the natural history of EH virus infections. Attempts to reactivate the EH viruses to cause clinical respiratory disease, by a series of injections of adrenalin and cortisone, were inconclusive. The 3 horses showed no clinical evidence of respiratory disease when they were reinfected intranasally with EH 39 virus 360 days (1 horse) and 412 days (2 horses) after the initial infection with this virus. Abortion was produced when EH 39 virus was inoculated directly into the allantoic or amniotic cavity of a pregnant mare although naturally occurring EH virus abortion remains unrecognised in Australia.