Possible introduction of epizootic hemorrhagic disease of deer virus (serotype 2) and bluetongue virus (serotype 11) into British Columbia in 1987 and 1988 by infected Culicoides carried on the wind.

Outbreaks of epizootic hemorrhagic disease of deer and of bluetongue began in British Columbia in August and October 1987 respectively and recrudescence of infection by both viruses was detected the following year in August. Weather records for up to 18 days before the initial outbreaks of disease, isolation of virus or seroconversion were examined to determine if the viruses could have been introduced by infected Culicoides carried on the wind. Data on temperature, rainfall, wind speed and direction and pressure together with backward trajectory analysis showed that there were suitable winds which could have introduced Culicoides infected with epizootic hemorrhagic disease of deer virus on 13 August 1987 (14 days before disease was observed), Culicoides infected with bluetongue virus on 1 October 1987 (7 days before virus was isolated and 13 days before disease in sheep) and Culicoides infected with bluetongue or epizootic hemorrhagic disease of deer viruses on 20 July 1988 (15 days before seroconversion was detected). The arrival on 13 August 1987 coincided with the passage of a cold front and rain and that on 1 October 1987 with a fall in temperature and calm winds. The source of the Culicoides before arrival could have been the Okanogan Valley as far south as the junction of the Okanogan and Columbia rivers in Washington, USA. Flight would have been at temperatures of 12.6 degrees C or higher and at heights up to 1.5 km.     

EPIZOOTIOLOGY OF BLUETONGUE: THE SITUATION IN THE UNITED STATES OF AMERICA

Bluetongue was first reported in the United States in 1948 in sheep in Texas. The virus has now been isolated from sheep in 19 States. When the disease first occurs in a flock, the morbidity may reach 50 to 75% and mortality 20 to 50%. In subsequent years, the morbidity may be only 1 to 2% with very few deaths. Difference in breed susceptibility has not been observed. Natural bluetongue infection has not been observed in Angora or dairy goats. Bluetongue virus was first isolated from cattle, in Oregon, in 1959. The virus has now been isolated from cattle in 13 States. In cattle, the disease is usually inapparent but can cause mild to severe clinical disease and neonatal losses. Natural clinical bluetongue has also been reported in bighorn sheep, exotic ruminants in a zoo, mule deer, and white-tailed deer. Serological evidence of exposure to the virus has also been found in other species of ruminants in the wild. Inoculation of virulent bluetongue virus, vaccine virus, or natural disease can cause congenital deformities and neonatal losses in calves, lambs, and white-tailed deer fawns. Culicoides is considered the important insect vector of bluetongue. The virus has also been isolated from sheep keds and cattle lice. U.S. field strains of the virus fit into four serologic groups. No cross reactions were found between bluetongue and epizootic haemorrhagic disease of deer viruses. Cattle are considered significant virus reservoirs. It is necessary to use washed erythrocytes, rather than whole blood, and to inoculate susceptible sheep, rather than embryonated chicken eggs, to detect longer-term viraemia in cattle.     

Mural folliculitis and alopecia caused by infection with goat-associated malignant catarrhal fever virus in two sika deer

Two sika deer from a zoo in Florida were examined because of chronic hair loss and skin lesions. No common causes of alopecia were identified in either deer. One deer was treated with prednisone, but the condition worsened when the dosage was decreased. Both deer were euthanatized after several months because of continued disease. The predominant histologic lesion in skin specimens was granulomatous mural folliculitis. Serologic testing and sequencing of fragments produced with a consensus polymerase chain reaction assay indicated that both deer were infected with caprine herpesvirus-2, a newly recognized member of the malignant catarrhal fever group of viruses. Disease in these deer was substantially different from that typically seen following infection with ovine herpesvirus-2, the sheep-associated malignant catarrhal fever virus. Findings in these deer establish the pathogenicity of caprine herpesvirus-2 in sika deer and illustrate the ability of this group of complex herpesviruses to cause a wide variety of clinical abnormalities in diverse species.     

Epidemiology, disease and control of infections in ruminants by herpesviruses--an overview

There are at least 16 recognised herpesviruses that naturally infect cattle, sheep, goats and various species of deer and antelopes. Six of the viruses are recognised as distinct alphaherpesviruses and 9 as gammaherpesviruses. Buffalo herpesvirus (BflHV) and ovine herpesvirus-1 (OvHV-1) remain officially unclassified. The prevalence of ruminant herpesviruses varies from worldwide to geographically restricted in distribution. Viruses in both subfamilies Alphaherpesvirinae and Gammaherpesvirinae cause mild to moderate and severe disease in respective natural or secondary ruminant hosts. Accordingly, the economic and ecological impact of the viruses is also variable. The molecular characteristics of some members have been investigated in detail. This has led to the identification of virulence-associated genes and construction of deletion mutants and recombinant viruses. Some of the latter have been developed as commercial vaccines. This paper aims to give an overview of the epidemiology and pathogenesis of infection by these viruses, immuno-prophylaxis and mechanisms of recovery from infection. Since there are 128 ruminant species in the family Bovidae, it is likely that some herpesviruses remain undiscovered. We conclude that currently known ruminant alphaherpesviruses occur only in their natural hosts and do not cross stably into other ruminant species. By contrast, gammaherpesviruses have a much broader host range as evidenced by the fact that antibodies reactive to alcelaphine herpesvirus type 1 have been detected in 4 subfamilies in the family Bovidae, namely Alcelaphinae, Hippotraginae, Ovibovinae and Caprinae. New gammaherpesviruses within these subfamilies are likely to be discovered in the future.     

Mycobacterial diseases of deer

The most significant mycobacterial diseases of free-living, captive and farmed deer are bovine tuberculosis, caused by Mycobacterium bovis, Johne's disease (paratuberculosis), caused by Mycobacterium avium subsp paratuberculosis (basonym M. paratuberculosis), and avian tuberculosis, caused principally by M. avium subsp avium. The first case of M. bovis infection in farmed deer was identified in New Zealand in 1978. In 1983, a voluntary scheme was introduced in New Zealand to control tuberculosis in farmed deer, followed by a compulsory tuberculosis control scheme in 1990. The primary control measure is the slaughter of infected animals, detected by skin testing and blood testing, together with movement control and vector control. The number of infected deer herds peaked in the mid 1990s at over 160 herds, but by 30 June 2002 this had been reduced to 79 (1.45%), and to 67 (1.23%) by June 2003. Deer-to-deer transmission occurs, but the majority of herd breakdowns are believed to be from infected vectors. Factors likely to affect the susceptibility of deer include age, environment, population density, exposure and genetics. Avian tuberculosis occasionally causes clinical disease in wild, captive and farmed deer in New Zealand and overseas. Mycobacterium intracellulare, and subspecies of M. avium other than M. paratuberculosis, are widespread throughout New Zealand and are thought to be largely responsible for the high level of sensitisation to avian purified protein derivative (PPD), which is used for comparison purposes in tuberculosis skin testing of deer in this country. Infections with these organisms are usually subclinical in farmed deer, although M. avium subsp avium commonly causes lesions in retropharyngeal, mesenteric and ileocaecal lymph nodes. These lesions cause problems because of their gross and microscopic similarity to those due to M. bovis infection. Birds and domestic animals are most likely to become infected via environmental contamination of food, water, bedding litter or soil, while carnivores or scavengers may also become infected by ingesting infected carcasses. Johne's disease has been reported in deer in the wild and in zoos, especially in North America, the United Kingdom (UK) and Europe. Since first being confirmed in farmed deer in New Zealand in 1979, the incidence of Johne's disease has increased steadily. To date, M. paratuberculosis has been identified in >600 farmed deer on 300 properties. The majority of cases have been identified from suspected tuberculous lesions submitted from deer slaughter plants. Clinically, Johne's disease in deer is similar to the disease in sheep and cattle, with typical signs of loss of weight and condition, and diarrhoea. However, outbreaks of Johne's disease frequently occur in young red deer, 8-15 months of age, whereas the clinical disease in sheep and cattle is sporadic and usually affects adults 3-5 years of age. The disease is characterised by a chronic granulomatous enteritis and lymphadenitis, especially affecting the jejunum and ileum and the mesenteric lymph nodes. Deer affected subclinically may have lesions in these lymph nodes at slaughter, which are grossly indistinguishable from those due to bovine tuberculosis. Because of the antigenic similarity between M. intracellulare and all the subspecies of M. avium, including M. paratuberculosis, the diagnostic tests for Johne's disease lack sensitivity and specificity, making control difficult.     

Leptospirosis in farmed deer in New Zealand : a review

Current knowledge of leptospirosis in farmed deer in New Zealand is reviewed. Over the past 25 years, leptospirosis has been reported to occur in individual cases as well as in herd outbreaks in farmed deer and in human cases linked to farmed deer. Serological studies and evidence from bacterial culture suggest infection is widespread. Mixing of young stock from several sources appears to be a significant risk factor for outbreaks. The culture of Leptospira interrogans serovars Hardjobovis, Pomona and Copenhageni has been reported. Infection with serovar Hardjobovis had the highest prevalence, either individually or mixed with serovar Pomona. Infection with serovar Copenhageni appears uncommon and its pathogenicity in deer is unproven. Titres to serovars Australis, Ballum, Balcanica and Tarassovi have been reported. Deer appear to be maintenance hosts for serovar Hardjobovis, incidental or accidental hosts and probably a maintenance population for serovar Pomona, since some infections persist for several months, and accidental hosts for serovar Copenhageni. Serovar Pomona appears to produce clinical and probably subclinical disease, whereas serovar Hardjobovis appears to cause only subclinical disease, although the relative risk of disease causation has not been determined. Clinical disease is usually manifested by haemolysis, jaundice, renal lesions, haemoglobinuria and often by sudden death. Renal lesions are commonly observed at slaughter and many are associated with leptospiral infections. Occupationally, slaughterhouse workers appear to be at greatest risk of contracting the disease from deer. Vaccination produces serological responses, but its effectiveness in protecting against disease, and prevention or reduction of shedding in urine, has not yet been confirmed in deer. More robust knowledge of the epidemiology of leptospiral infections in deer, and the effectiveness of vaccines and vaccination regimes, is needed to assist the deer industry to develop a strategy to manage this disease.     

Use of a polymerase chain reaction to subtype Mycobacterium avium subspecies paratuberculosis, an increasingly important pathogen from farmed deer in New Zealand

AIMS: To review the number of microbiologically-confirmed cases of Johne's disease in farmed deer since 2000, and determine the prevalence of the bovine and ovine subtypes of Mycobacterium avium subsp paratuberculosis (M. paratuberculosis), using a highly specific polymerase chain reaction (PCR) test on samples from infected herds. METHODS: The number of cases of M. paratuberculosis in farmed deer identified by culture or IS900 PCR was documented. A highly specific PCR test was applied to subtype M. paratuberculosis from BACTEC 12B cultures selected on the basis of one culture per deer herd, to give a wide coverage of herds in New Zealand. RESULTS: From January 2001 to October 2005, M. paratuberculosis was isolated from 1,141 farmed deer, and has now been identified by microbiological testing in over 600 deer herds in New Zealand. The bovine subtype of M. paratuberculosis was shown by a highly specific PCR test to be present in 91/95 herds examined; the ovine subtype was found in the remaining four herds. CONCLUSIONS: Since 2000, there has been a substantial increase in both the number of microbiologically-confirmed cases of Johne's disease in farmed deer and the number of infected herds. Johne's disease is now widespread and common in deer herds throughout New Zealand. Whilst the bovine subtype of M. paratuberculosis predominates in deer herds in New Zealand in which Johne's disease has been confirmed, the occasional finding of the ovine subtype highlights the need to consider both sheep and cattle as potential sources of infection for farmed deer.     

A serological comparison of some animal herpesviruses

Bovine herpesvirus 1 (BHV-1) isolates (Cooper-type strain 4975 and Oxford) were compared in neutralization tests with the bovine herpesvirus 4 (BHV-4) isolate (85/16 TV) and the herpesviruses of red deer (D2839/1) and goats (E/CH). Hyperimmune antiserum was prepared in rabbits against the plaque-selected viruses and endpoint and kinetic neutralization test were made. BHV-4 was clearly different from the other four viruses. The closely-related BHV-1 strains were also related in these tests to the red deer herpesvirus. The Oxford strain seemed rather closer antigenically than the Cooper-type strain to the red deer herpesvirus. Antiserum to the caprine herpesvirus failed to neutralize either BHV-1 strain or red deer virus, but antiserum to the Cooper-type and red deer herpesviruses did neutralize caprine virus to a limited extent.     

北美地区鹿的慢性消耗性疾病

鹿慢性消耗性疾病(CWD)是鹿类动物的传染性海绵状脑病(TSE)。它是由朊病毒(PrP)引起的,临床主要表现为慢性型消耗,体重逐渐下降,行为异常,最后致死。该病主要感染北美地区的黑尾鹿、白尾鹿和美洲马鹿,一些野生和家养的反刍动物如牛、绵羊和山羊与染病鹿直接或间接接触也可被感染。目前还不能确定CWD与人和其它动物的TSE类疾病的关系。它的起源、发病机理、传播机制和途径尚不清楚。尽管还没有证据证明CWD可传染给人类,但是它对人类有潜在威胁。     

Will Culling White‐Tailed Deer Prevent Lyme Disease?

White‐tailed deer play an important role in the ecology of Lyme disease. In the United States, where the incidence and geographic range of Lyme disease continue to increase, reduction of white‐tailed deer populations has been proposed as a means of preventing human illness. The effectiveness of this politically sensitive prevention method is poorly understood. We summarize and evaluate available evidence regarding the effect of deer reduction on vector tick abundance and human disease incidence. Elimination of deer from islands and other isolated settings can have a substantial impact on the reproduction of blacklegged ticks, while reduction short of complete elimination has yielded mixed results. To date, most studies have been conducted in ecologic situations that are not representative to the vast majority of areas with high human Lyme disease risk. Robust evidence linking deer control to reduced human Lyme disease risk is lacking. Currently, there is insufficient evidence to recommend deer population reduction as a Lyme disease prevention measure, except in specific ecologic circumstances.     

Malignant catarrhal fever: experimental transmission of the 'sheep-associated' form of the disease from cattle and deer to cattle, deer, rabbits and hamsters

Attempts to transmit malignant catarrhal fever (MCF) from 16 bovine cases of the 'sheep-associated' form of the disease are described. On two occasions disease was transmitted to bovine calves but transmission to red deer (Cervus elaphus) was not achieved. In addition, MCF was transmitted from one experimentally affected calf to a rabbit and on another occasion directly to rabbits with material from a field case which failed to transmit to a bovine calf or red deer. Subsequently each of these isolates was readily passaged through rabbits and one was also passaged to Syrian hamsters. Tissue from MCF-affected red deer consistently produced disease on inoculation into rabbits and deer but failed to cause disease in bovine calves. Contact infection between red deer occurred once and roe deer (Capreolus capreolus) were also shown to be susceptible to infection by inoculation. Passage of MCF in rabbits with an isolate from red deer failed to produce evidence of further adaptation even after 125 serial passages. Despite the failure to transmit disease from cattle to deer or from deer to cattle it is considered probable that there is only one sheep-associated agent which causes MCF in both species. The reasons for the anomalies in transmission of this form of the disease are discussed.     

Congenital contraction of the gastrocnemius and superficial digital flexor muscles in a friesian calf

The red deer (Cervus elaphus) is a host for two louse species, Damalinia longicornis and Solenopotes burmeisteri. Little is known of their prevalence or population dynamics; numbers are likely to peak in winter. Numbers may increase secondarily to malnutrition or disease. Lice are unlikely to seriously affect deer health under most conditions. “Pour-on” insecticides have been used for treatment but their efficacy has not been critically assessed. Animals can be sprayed using garden spray equipment, providing that such equipment has not been used for other toxic chemicals such as weed killers. Little is known of the toxicity of insecticides for deer, so they should be used with care and not used on stressed animals. No lice have been recorded from the fallow deer (Dama dama) in New Zealand.

Dictyocaulus viviparus infects red and fallow deer and can cause high mortalities of young farmed red deer in their first autumn and winter. In clinical cases respiratory signs are seldom obvious but loss of condition and dullness of coat may be evident. Clinical evidence and lung lesions suggest that the pathogenesis of disease may differ from that in cattle. Anthelmintics effective against D. viviparus in cattle are not necessarily effective in deer. Little is known of the significance of lungworm to farmed fallow deer. Research on lungworm in deer is urgently needed.     

Development of a management program for a mixed species wildlife park following an occurrence of malignant catarrhal fever

During late 2001 and early 2002, a mixed species wildlife park in North Carolina experienced an acute outbreak of morbidity and mortality in Pere David's deer (Elaphurus davidianus), axis deer (Axis axis), blackbuck antelope (Antelope cervicapra), white-tailed deer (Odocoileus virginianus), and Rocky Mountain elk (Cervus elaphus). Clinical signs varied from fulminant disease, progressing from depression to bloody scours to death in fewer than 4 days in Pere David's deer, to a more protracted form of disease, ranging from 2 wk to 3 mo, in axis deer. In moribund axis deer, high levels of anti-malignant catarrhal fever (MCF) virus antibody by competitive-inhibition enzyme-linked immunosorbent assay were detected. Ovine herpesvirus 2 (OvHV-2) DNA was detected in peripheral blood leukocytes of the affected axis deer. No other MCF viruses were detected. Retrospective examination of frozen tissue samples from the affected Pere David's deer and blackbuck antelope also confirmed the presence of OvHV-2 DNA. Initial control efforts were directed at preventing further deaths of clinically susceptible animals by removing MCF virus reservoir species, particularly ovine species. The most prevalent ovine species in the wildlife park was mouflon sheep (Ovis musimon). All sheep were removed from the park by June 2002, and the last MCF death occurred in October 2002. Since mouflon sheep had been a prominent attraction in the wildlife park, the owner wanted a means to reintroduce this species to the park. Derivation of OvHV-2-uninfected mouflon lambs was undertaken using the previously described program for production of OvHV-2-free sheep (Ovis ovis). The rederived MCF virus-negative mouflon sheep were introduced into the park in approximately January 2004. As of December 2007, no further cases of MCF have occurred since the removal of OvHV-2-positive mouflon sheep and reintroduction of the virus-free lambs. This paper describes the successful management and control of MCF in a densely populated mixed species animal park.     

4种重要虫媒病的核酸液相芯片高通量检测方法的建立

为建立可检测鹿流行性出血热病毒(EHDV)、阿卡斑病毒(AKV)、蓝舌病病毒(BTV)和水泡性口炎病毒(VSV)的液相芯片快速检测技术,用DNAStar软件对GenBank中BTV的VP7基因、EHDV的VP7基因、AKV的N基因和VSV的NP基因序列进行序列分析,设计针对这些基因的特异性探针并标记生物素,分别与不同编号的荧光编码微球偶联后再与这些病毒相应基因的PCR产物杂交反应,用液相芯片检测仪(Liquichip 200)检测荧光信号建立了以上4种虫媒病的快速液相芯片检测方法。检测结果显示,该方法具有较好的特异性,偶联特异性探针的微球只与相应的病毒基因的PCR产物反应,而不与其他虫媒病病毒反应;检测灵敏度达到50~100个TCID50。本研究建立了可以同时检测鹿流行性出血热病毒、阿卡斑病毒、蓝舌病病毒和水泡性口炎病毒的快速高通量液相芯片技术,为其他类似病毒的快速高通量检测提供了借鉴和经验。     

Caprine herpesvirus-2-associated malignant catarrhal fever in white-tailed deer (Odocoileus virginianus).

A subacute disease presenting primarily as alopecia and weight loss occurred in 2 white-tailed deer (Odocoileus virginianus) on farms in Minnesota and in Texas. A presumptive diagnosis of malignant catarrhal fever (MCF) was made on the basis of histological lesions. Antibody against an epitope conserved among the MCF group viruses was detected in the serum of both deer. DNA samples from the deer were subjected to a variety of PCR amplifications. Alignment of the amplified sequences from the diseased animals revealed that they were 100% identical to each other and to the same DNA fragment from the newly recognized member of the MCF virus group endemic in domestic goats (Capra hircus), provisionally named caprine herpesvirus 2 (CpHV-2). A seroprevalence survey from one of the deer farms showed a high rate of subclincal infection in the deer population. This study provides further confirmation that CpHV-2 is a pathogen, at least for deer, and emphasizes the risk of loss from MCF when mixing cervids with goats.     

Recent progress in henipavirus research

Following the discovery of two new paramyxoviruses in the 1990s, much effort has been placed on rapidly finding the reservoir hosts, characterising the genomes, identifying the viral receptors and formulating potential vaccines and therapeutic options for these viruses, Hendra and Nipah viruses caused zoonotic disease on a scale not seen before with other paramyxoviruses. Nipah virus particularly caused high morbidity and mortality in humans and high morbidity in pig populations in the first outbreak in Malaysia. Both viruses continue to pose a threat with sporadic outbreaks continuing into the 21st century. Experimental and surveillance studies identified that pteropus bats are the reservoir hosts. Research continues in an attempt to understand events that precipitated spillover of these viruses. Discovered on the cusp of the molecular technology revolution, much progress has been made in understanding these new viruses. This review endeavours to capture the depth and breadth of these recent advances.     

Retrospective study of pestivirus infection in Pyrenean chamois (Rupicapra pyrenaica) and other ungulates in the Pyrenees (NE Spain)

In 2001 a new Pestivirus (Family Flaviviridae) was associated with an outbreak of a previously unreported disease in Pyrenean chamois (Rupicapra pyrenaica) in the Pyrenees (NE Spain). Molecular characterization assigned this virus to the Border Disease Virus (BDV) cluster, BDV-4 genotype. A retrospective study was performed in archived sera and spleen of 74 Pyrenean chamois and in archived sera of 28 mouflon (Ovis ammon), 56 red deer (Cervus elaphus), 43 roe deer (Capreolus capreolus) and 29 fallow deer (Dama dama) from the Pyrenees between the years 1990 and 2000. Thirty six of 74 (48.6%) sera of Pyrenean chamois, one of mouflon and one of red deer were positive by an ELISA antibody test. Comparative virus neutralization tests were performed on 26 seropositive chamois, one mouflon and one red deer, using five pestivirus strains. An ELISA antigen test was performed on 37 seronegative chamois and yielded positive results in one chamois and inconclusive result in two. RT-PCR and virus isolation performed on spleen samples from these three animals gave positive results in the positive and one inconclusive animal. Sequence analysis in the 5' unstranslated region revealed that they were grouped into the BDV-4 genotype. Virological and serological data of the present study indicate that BDV infection has been present in the chamois population since at least 1990, 11 years before the first outbreak of disease. Therefore, the emergence of the disease in 2001 is apparently due to other factors rather than the introduction of a new virus in the chamois population.     

Isolation and characterisation of cervine herpesvirus-1 from red deer semen

AIM: This communication describes the isolation of herpesvirus during routine export examination of semen collected from red deer stags in New Zealand. METHODS: Virus isolation was carried out using bovine embryonic lung (BEL) cells and viruses were characterised by direct immunofluorescense, restriction-fragment-length polymorphism analysis (RFLP), polymerase chain reaction (PCR) analysis and nucleotide sequencing. RESULTS: Herpesvirus was isolated from red deer semen on 2 different occasions from different animals. In both cases the virus was identified as cervine herpesvirus-1 (CvHV-1), based on RFLP, PCR and sequence analysis. Nucleotide sequence analysis of the glycoprotein-D gene showed 99.7% homology to the Banffshire strain of CvHV-1 and 89.5%, 89.2%, 85.3% and 79.6% homology to bovine herpesvirus 1.2 (BoHV-1.2), bovine herpesvirus 1.1 (BoHV-1.1), cervine herpesvirus-2 (CvHV-2) and caprine herpesvirus-1 (CpHV-1), respectively. CONCLUSION: This is the first time that CvHV-1 has been isolated in New Zealand. Its inclusion in serological surveys will allow the prevalence of CvHV-1 in the red deer population to be assessed in this country. The clinical significance of CvHV1 infection in New Zealand red deer herds has yet to be determined.     

Bluetongue and related viruses in Nigeria: Experimental infection of West African dwarf sheep with Nigeria strains of the viruses of epizootic haemorrhagic disease of deer and bluetongue

West African dwarf sheep were inoculated by the subcutaneous route with epizootic haemorrhagic disease of deer (EHD) virus or bluetongue (BT) virus. No clinical disease was observed following primary EHD or BT infection, or subsequent challenge with either homologous or heterologous virus. However, viraemia was detected in non-immune sheep exposed to BT virus, but not in BT- or EHD-immune sheep challenged with either virus, or in non-immune sheep exposed to primary EHD virus infection. Complement fixing antibodies developed against both EHD and BT viruses following the primary infection with either virus, or subsequent challenge with homologous or heterologous virus. Following a primary infection, virus-neutralising (VN) antibodies developed only against the inoculated virus, while the detection of VN antibodied to both viruses followed the challenge of an EHD- or BT-immuned sheep with either the homologous or heterologous virus. These findings further support previous reports of a relationship between EHD and BT viruses. between EHD and BT viruses.     

Sarcoptic mange in red deer from Spain: improved surveillance or disease emergence?

Concern about emerging diseases has risen in recent years, and multihost situations have become increasingly relevant for wildlife management and conservation. We present data on Asturias, northern Spain, where 80 mangy red deer (Cervus elaphus) have been found since the beginning of the epizootic in chamois (Rupicapra pyrenaica parva) in 1993. We combine field and necropsy data with the results of a serosurvey using an in-house ELISA test to evaluate if deer mange due to Sarcoptes scabiei is an emerging disease in this area. The mean number of deer mange cases per year was 5, with a maximum of 16. No significant relationship was detected between monthly temperatures, rainfall or number of days with snow cover and the annual number of sarcoptic mange cases in red deer. Only 4 mangy red deer (5%) were detected outside the limits of scabietic chamois distribution during the same year, and all were less than 2500 m away from that limit. The longest distance reported between two consecutive mangy deer locations was 18 km. Mange cases were significantly more frequent in stags than in hinds and in adults than in juvenile deer. The time of the first mange detection in chamois in each sector, year with minimum number of chamois recorded, year with maximum chamois population decline rate and chamois density offered no significant correlation with red deer mange cases appearance moment and frequency. In the mange affected area, ELISA testing of 327 blood samples from hunter-harvested deer without obvious mange-compatible lesions revealed only 4 seropositive animals. All 83 sera from hunting preserves without clinical cases yielded negative ELISA results. According to these epidemiological data mange does not seem to threaten red deer populations in Asturias. However, continued monitoring of deer health and ELISA testing for sarcoptic mange is advisable.