Search for persistent epizootic Venezuelan encephalitis virus in Guatemala, El Salvador and Nicaragua during 1970-1975.

Evidence was sought during 1970-1975 of persistence of equine-virulent Venezuelan encephalitis (VE) virus in regions of Central America that were heavily involved in the epidemic-equine epizootic of 1969. (a) Four sentinel horses were exposed in an arid, upland region of the Atlantic drainage of Guatemala during August-October 1970, but no horse became infected. (b) The epicenter region of the 1969 outbreak, in southwestern Guatemala and southwestern El Salvador, was studied during July 1970-February 1974; no antibody developed in sentinel horses, sentinel hamsters did not die, mosquitoes yielded no virus, wild rats had no detectable VE virus HI antibody. Unexplained decreases in populations of wild terrestrial mammals possibly limited maintenance of VE virus. However, mosquitoes were plentiful and present in the same species composition found at a focus of enzootic VE virus about 35 km northwest of the epicenter region. (c) In studies at two Guatemalan ranches near the epicenter, where horses died in 1969, VE viruse infected sentinel horses along one of three lakes on one ranch during the wet season of 1972 but not during the dry or wet seasons of 1973; the titers of neutralizing antibodies in these four horses were higher against an enzootic strain of VE virus than against an epizootic strain. During 1970 and 1971, VE virus was isolated from sentinel hamsters exposed at a marsh on the other ranch, but Vero plaque characteristics were those of enzootic VE virus. (d) The only epizootic activity of VE virus discovered in Central America in 1970-1975 occurred in Nicaragua between April and June 1972. Several hundred horses died, and N antibody, like that engendered by epizootic virus, was found in two young, unvaccinated horses. Whether this represented persistence of epizootic VE virus or reintroduction of virus is unknown.     

Marker characteristics of Venezuelan encephalitis virus strains isolated before and after epidemics and equine epizootics in Middle America

Ninety-four strains of Venezuelan encephalitis (VE) virus isolated from sentinel hamsters exposed in the Middle American countries of Mexico, Guatemala, Belize, and Honduras were examined for the presence of virions with marker characteristics of strains that cause large epidemics and equine epizootics. Thirty-four strains came from before and 60 strains came from after the Middle American epidemics and equine epizootics of 1966 and 1969-1972. Twenty-three virion clones that resembled epizootic strains by hydroxylapatite chromatography and Vero monkey kidney cell plaque size determinations were characterized further. However, the predominant virions in these clones were like enzootic strains from Middle America north of the Panama Canal region, and not like Middle American epizootic VE strains, since they were in hemagglutination-inhibition antigenic subtype IE, usually had optimal pH of hemagglutination at 6.2, and were avirulent for English shorthair guinea pigs inoculated subcutaneously. These results provide evidence against the theory of origin of epidemic-equine epizootic VE virus strains that posits that epizootic virions emerge in Middle America from strains containing mixtures of enzootic and epizootic virions in enzootic habitats.     

Antigenic and biologic characteristics of Venezuelan encephalitis virus strains including a possible new subtype, isolated from the Amazon region of Peru in 1971.

Nine strains of Venezuelan encephalitis (VE) virus isolated from the Amazon region of Peru in 1971 were identified as antigenic subtype I based on plaque-reduction neutralization tests with four and 20 units of antibody. A tenth strain, 71D1252, was possibly a new subtype, but was related to subtypes I and III. Hemagglutinins of each strain made from infected mouse brains had optimals pHs of 6.2 and 6.4. Nine strains were pathogenic for adult hamsters and adult mice, but strain 71D1252 inapparently infected some adult hamsters and mice inoculated peripherally. Plaques of nine strains in Vero African green monkey kidney cell cultures were intermediate in size between representative epizootic and enzootic strains, but plaques of strain 71D1252 were small like epizootic strains.     

Postepizootic persistence of Venezuelan equine encephalitis virus, Venezuela

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

The crab hole mosquito blues

Venezuelan equine encephalomyelitis (VEE) epizoodemics were reported at 6-10-year intervals in northern South America beginning in the 1920s. In 1937, epizootic VEE virus was isolated from infected horse brain and shown as distinct from the North American equine encephalomyelitis viruses. Subsequently, epizootic and sylvatic strains were isolated in distinct ecosystems; isolates were characterized serologically as epizootic subtype I, variants A/B and C; or sylvatic (enzootic) subtype I, variants D, E, and F, and subtypes II, III, and IV. In 1969, variant I-A/B virus was transported from a major outbreak in northern South America to the borders of El Salvador, Guatemala, and Honduras. This musical poem describes the history and ecology of VEE viruses and the epidemiology of an unprecedented 1969 movement of VEE viruses from South America to equids and humans in Central America from Costa Rica to Guatemala and Belize and in Mexico and the United States that continued until 1972.     

Application of satellite precipitation data to analyse and model arbovirus activity in the tropics

Background  

Murray Valley encephalitis virus (MVEV) is a mosquito-borne Flavivirus (Flaviviridae: Flavivirus) which is closely related to Japanese encephalitis virus, West Nile virus and St. Louis encephalitis virus. MVEV is enzootic in northern Australia and Papua New Guinea and epizootic in other parts of Australia. Activity of MVEV in Western Australia (WA) is monitored by detection of seroconversions in flocks of sentinel chickens at selected sample sites throughout WA.     

Ecologic studies of Venezuelan encephalitis virus in Peru during 1970-1971.

Venezuelan encephalitis (VE) virus has intermittently produced epidemics and equine epizootics on the dry Pacific coastal plain of Peru since at least the 1930's. However, evidence that the virus exists in the Amazon region of Peru to the east of the Andes mountains was not obtained until antibodies were found in human sera collected in 1965, and 10 strains of the virus were isolated in a forest near the city of Iquitos, Peru during February and March 1971. Eight strains came from mosquitoes and two from dead sentinel hamsters. Three hamsters exposed in forests near Iquitos developed VE virus antibodies suggesting that hamster-benign strains also exist there. Antibody tests of equine sera revealed no evidence that VE virus was actively cycling during the late 1950's or 1960's in southern coastal Peru, where equine epizootics had occurred in the 1930's and 1940's. In northern coastal Peru bordering Ecuador, antibodies were present in equine sera, presumably residual from the 1969 outbreak caused by subtype I virus, since neutralizing antibody titers were higher to subtype I virus than to subtypes III or IV. No VE virus was detected in this northern region during the dry season of 1970 by use of sentinel hamsters. The possibility is considered that VE epidemics and equine epizootics on the Pacific coast of Peru are caused by movements of virus in infected vertebrates traversing Andean passes or in infected vertebrates or mosquitoes carried in airplanes from the Amazon region.     

Potential for Central American mosquitoes to transmit epizootic and enzootic strains of Venezuelan equine encephalitis virus.

Experimental studies were undertaken to compare the vector competence of Culex (Melanoconion) taeniopus Dyar and Knab, Culex (Melanoconion) ocossa Dyar and Knab, and Psorophora confinnis (Lynch Arribalzalga) from Central America for epizootic (IAB) and enzootic (IE) strains of Venezuelan equine encephalitis (VEE) virus. Virus infection and dissemination rates were significantly higher in Cx. taeniopus orally exposed to IE as compared to those orally exposed to IAB virus. In contrast, both infection and dissemination rates were similar in Cx. ocossa exposed to either IAB or IE strains of VEE virus. Thus, susceptibility to epizootic and enzootic strains of VEE virus seems to be species specific within the subgenus Culex (Melanoconion). Both species transmitted each strain of VEE virus after intrathoracic inoculation, indicating that a midgut barrier affected vector competence in these species. Psorophora confinnis was equally susceptible to both IAB and IE viruses, but apparently had a salivary gland barrier, as only 1 of 16 mosquitoes with a disseminated infection transmitted VEE virus by bite.     

Observations on the epidemiology of Rift Valley fever in Kenya.

The epizootic range of Rift Valley fever in Kenya is defined from the results of virus isolations during epizootics, and form an extensive serological survey of cattle which were exposed during an epizootic. A study of the sera from a wide range of wild bovidae sampled immediately after the epizootic, showed that they did not act as reservoir or amplifying hosts for RVF. Virus isolation attempts from a variety of rodents proved negative. Rift Valley fever did not persist between epizootics by producing symptomless abortions in cattle in areas within its epizootic range. A sentinel herd sampled annually after an epizootic in 1968 revealed not one single seroconversion from 1969 to 1974. Certain forest and forest edge situations were postulated as enzootic for Rift Valley fever, and a small percentage of seroconversions were detected in cattle in these areas, born four years after the last epizootic. This has been the only evidence for the persistence of the virus in Kenya since 1968, and may be a part of the interepizootic maintenance cycle for Rift Valley fever in Kenya, which otherwise remains unknown.     

Venezuelan Equine Encephalitis and 2 Human Deaths,Peru

Studies have suggested that enzootic strains of Venezuelan equine encephalitis (VEE) subtype ID in the Amazon region, Peru, may be less pathogenic to humans than are epizootic variants. Deaths of 2 persons with evidence of acute VEE virus infection indicate that fatal VEEV infection in Peru is likely. Cases may remain underreported.     

Natural enzootic vectors of Venezuelan equine encephalitis virus,Magdalena Valley,Colombia

To characterize the transmission cycle of enzootic Venezuelan equine encephalitis virus (VEEV) strains believed to represent an epizootic progenitor, we identified natural vectors in a sylvatic focus in the middle Magdalena Valley of Colombia. Hamster-baited traps were placed into an active forest focus, and mosquitoes collected from each trap in which a hamster became infected were sorted by species and assayed for virus. In 18 cases, a single, initial, high-titered mosquito pool representing the vector species was identified. These vectors included Culex (Melanoconion) vomerifer (11 transmission events), Cx. (Mel.) pedroi (5 transmissions) and Cx. (Mel.) adamesi (2 transmissions). These results extend the number of proven enzootic VEEV vectors to 7, all of which are members of the Spissipes section of the subgenus Melanoconion. Our findings contrast with previous studies, which have indicated that a single species usually serves as the principal enzootic VEEV vector at a given location.     

Passage in Vero cells alters the characteristics of measles AIK-C vaccine strain

Objective of this study is to evaluate the feasibility of measles vaccine production in Vero cell culture. We constructed the full-length cDNA, pIC-MVAIK-F278Leu (small plaque-type) and pIC-MVAIK-F278Phe (large plaque-type) from the AIK-C measles vaccine strain attenuated from the Edmonston wild-type. MVAIK-S/B2 was rescued from pIC-MVAIK-F278Leu after two passages in B95a cells and MVAIK-SL/B2V1 was obtained through large plaque cloning in Vero cells. MVAIK-SL/B2V8 was obtained after eight passages in Vero cells. It produced large plaques in Vero cells, grew well at 39 degrees C, and thus the characteristics of the AIK-C vaccine strain were lost. Thirteen amino acid changes were observed; one in the N, two in the P, one in the C, three in the F, one in the H, and five in the L protein regions. Twelve of these changes excluding one in the L gene were back mutated to the Edmonston strain. Change from Leu to Phe at position 278 of the F protein was an early event during adaptation to Vero cells and the P gene was back-mutated to the Edmonston wild-type. As for the control, MVAIK-L/B9 strain was obtained after passages in B95a cells from pIC-MVAIK-F278Phe (large plaque-type). It maintained the same temperature sensitivity as the AIK-C vaccine strain and only four amino acid changes, one in the N and three in the L protein region, were observed without any mutations in the P, C, M, F, and H genes. The passage of the measles vaccine AIK-C strain in Vero cells lost the characteristics of small plaque inducibility and temperature sensitivity (ts) phenotype.     

West Nile fever outbreak in horses and humans, Spain, 2010

TO THE EDITOR: West Nile virus (WNV) is a member of the genus Flavivirus within the Japanese encephalitis antigenic complex. The enzootic virus cycle involves transmission between avian hosts and ornithophilic mosquitoes, whereas humans and horses are considered dead-end hosts. Given the recent increase of WNV infection in humans and horses in Europe, concern has been raised regarding public and animal health.     

Recombinant measles AIK-C strain expressing current wild-type hemagglutinin protein

We constructed a recombinant measles virus cDNA, pIC-MVAIK-H/87-K, in which the hemagglutinin (H) gene of the AIK-C vaccine strain was replaced by the wild-type (MVi/Tokyo.JPN/87-K: genotype D3) H gene and the remaining genes were the same as the AIK-C vaccine strain. To investigate the feasibility of the recombinant vaccine strain expressing wild-type H protein instead of the AIK-C H protein, we constructed two recombinant measles cDNA, having Leu (small plaque-type) and Phe (large plaque-type) at position 278 of the F protein. Infectious chimeric virus strains, MVAIK-H/87-K/S (small plaque-type) and MVAIK-H/87-K/L (large plaque-type), were recovered, which were designed to induce small (S) and large (L) plaques in Vero cells. The MVAIK-H/87-K/S and MVAIK-H/87-K/L did not grow at 39-40 degrees C, similar to the original AIK-C strain, and retained the temperature sensitivity (ts) characteristics. They did not induce cytopathic effect (CPE) in Vero cells but produced CPE in B95a cells, similar to the current wild-type measles MVi/Tokyo.JPN/87-K. From the results of Western blotting, the mobility of the H protein of MVAIK-H/87-K/S and MVAIK-H/87-K/L was similar to that of MVi/Tokyo.JPN/87-K. Hyper-immune sera raised by MVAIK-H/87-K/S neutralized all types of current wild strains. Thus, the chimeric measles virus expressing the current wild H protein demonstrated wild-type H properties with ts characteristics of the vaccine strain, indicating that the construction strategy of recombinant measles virus can cope with the hyper-mutated measles virus.     

浙江省蚊媒携带流行性乙型脑炎病毒的分布特点

目的 了解浙江部分地区蚊媒及猪携带流行性乙型脑炎(乙脑)病毒情况以及浙江省存在的乙脑病毒基因型别.方法 于2007年5月至10月在浙江省仙居、龙泉和慈溪3个县人房及猪舍采集蚊虫标本和猪血清,共采集10 662只蚊虫和204份猪血清,蚊虫标本中以淡色库蚊和中华按蚊为主.利用病毒分离和荧光定量逆转录聚合酶链反应(RT-PCR)方法检测蚊虫携带乙脑病毒,应用酶联接免疫吸附剂测定(ELISA)方法对猪血清进行抗体检测.应用荧光定量RT-PCR方法对细胞分离株进行病毒鉴定;利用RT-PCR方法扩增新分离乙脑病毒PrM基因,并对细胞分离到的病毒进行基因分型.结果 在蚊虫标本中检出7批乙脑病毒核酸阳性样本,并分离出3株病毒,经鉴定3株病毒均为乙脑病毒,基因分析表明3株病毒均属于基因Ⅰ型乙脑病毒.猪血清有121份阳性,总阳性率为59.3%.6月份有50%以上的猪血清中乙脑病毒抗体呈阳性.结论 浙江省部分地区存在着乙脑的传播媒介,在蚊媒和猪中携带有乙脑病毒;采集的蚊虫标本中分离到3株病毒,经鉴定为基因Ⅰ型乙脑病毒,是近年来在浙江省首次分离到的基因Ⅰ型乙脑病毒.     

Human infection with monkeypox virus: laboratory investigation of six cases in West Africa

Between September 1970 and May 1971 six cases of human infection with monkeypox virus were identified in three West African countries—Liberia, Sierra Leone, and Nigeria. Four of the cases were confirmed by viral isolation, and two were diagnosed on epidemiological and serological evidence. Poxvirus strains isolated from the four cases were indistinguishable from reference monkeypox strains (Copenhagen and Utrecht), and all were easily differentiated from variola and vaccinia viruses. The isolated strains produced small necrotic haemorrhagic pocks on CAM, grew well at 39.0°C, formed large plaques in Vero cell cultures, showed markedly more virulence for chick embryos and mice than do variola strains, and produced large necrotic haemorrhagic local lesions with generalized illness and florid secondary exanthem when inoculated into rabbit skin.     

Yellow fever and Zika virus epizootics and enzootics in Uganda

Data of monkey serology are presented which, together with past evidence, support the view that yellow fever (YF) virus circulates in its primary sylvan host populations, i.e., forest monkeys, in an enzootic state in Bwamba County in western Uganda but as series of epizootics in the forest-savanna mosaic zone of central Uganda. Evidence of an epizootic of Zika virus at the Zika Forest near Entebbe is described which occurred in two episodes, the first (in 1969) apparently following the build-up of non-immune monkey populations since a previous epizootic of 1962-63 and the second (in 1970) when Aedes africanus biting densities rose. This was followed only 18 months later by an intensive epizootic of YF virus, contradictory to the hypothesis that Zika virus alone would suppress subsequent epizootics of YF virus in nature, at least when redtail monkeys are involved. Conclusions are finally reviewed in the light of more recent evidence of transovarial flavivirus transmission in mosquitoes, pointing out that phlebotomine sandflies also require fresh attention.     

TC-83 vaccine protects against airborne or subcutaneous challenge with heterologous mouse-virulent strains of Venezuelan equine encephalitis virus

Vaccination with TC-83 virus produced solid protection against subcutaneous challenge with Venezuelan equine encephalitis (VEEV) viruses from homologous and heterologous serogroups, but breakthrough infection and disease occurred after airborne challenge. Breakthrough occurred more often with time after vaccination, and was more frequent with epizootic, homologous serogroup 1A/B viruses than with enzootic, heterologous serogroup viruses. A decrease in VEEV-specific IgA levels in the respiratory tract of vaccinated mice may explain the increased frequency of breakthrough with time after vaccination. However increased breakthrough with the highly virulent homologous serogroup 1A/B viruses (compared to less virulent viruses from heterologous serogroups) may be a consequence of their greater ability to invade the brain via the olfactory neuroepithelium and olfactory nerve.     

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

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