Detection of Antibodies to Alphaviruses and Discrimination between Antibodies to Eastern and Western Equine Encephalitis Viruses in Rabbit Sera using a Recombinant Antigen and Virus‐specific Monoclonal Antibodies

Three arthropod‐borne alphaviruses, western equine encephalitis viruses (WEEV), eastern equine encephalitis viruses (EEEV) and Venezuelan equine encephalitis viruses are the aetiological agents of a sometimes severe encephalomyelitis in equines and humans in the New World. With regard to the different ecology and epidemiology of these viruses, a method applied in serological screening should be able to distinguish between them as well as other related members of the genus Alphavirus in the American continent. However, this has been hampered in the past by (a) the close antigenic relationship between alphaviruses in traditional serological assays, especially in the routinely used haemagglutination‐inhibition, and (b) the need of biosafety level 3 facilities to grow the viral antigens. An epitope blocking assay using an EEEV glycoprotein E1‐expressing recombinant Sindbis virus and virus‐specific monoclonal antibodies (mAbs) binding to the E1 of EEEV (strain NJ/60) and the E1 of Sindbis virus was established using automated flow cytometry. The test was evaluated using sera of infected and vaccinated rabbits. A cut‐off value of 30% inhibition for antigenic complex‐specific seroconversion was found to be sufficient for the detection of the respective infection. By using three different mAbs in parallel, we were able to detect alphavirus genus‐, EEEV‐ and WEEV‐complex‐specific serum antibodies. As this test is based on the inhibition of binding of virus‐specific mAbs, sera of every origin other than mouse can be tested. Thus, this assay may prove useful in the serological screening of a variety of animal species during an outbreak investigation.     

Phage display identifies an Eastern equine encephalitis virus glycoprotein E2-specific B cell epitope

The present study identified a linear B-cell epitope in the Eastern equine encephalitis virus (EEEV) E2 glycoprotein by screening a phage-displayed random 12-mer peptide library using an EEEV E2 specific monoclonal antibody (mAb) 7C11 and defined L/F-E/R-Y-T-W-G/R-N-H/W-P as the consensus binding motif. A sequence ((321)EGLEYTWGNHPP(332)) encompassing this consensus motif was found in the EEEV E2 glycoprotein and synthesized for further epitope confirmation. Meanwhile, the corresponding epitope peptides in E2 protein of associated alphaviruses were synthesized for specificity identification. Results showed the mAb 7C11 and murine antisera all reacted strongly against the synthesized polypeptide of EEEV antigen complex, but no reaction with Western equine encephalitis virus (WEEV) and Venezuelan equine encephalitis virus (VEEV) was detected. The knowledge and reagents generated in this study may have potential applications in differential diagnosis and the development of epitope-based marker vaccines against EEEV.     

Seroepidemiology of Selected Alphaviruses and Flaviviruses in Bats in Trinidad

A serosurvey of antibodies against selected flaviviruses and alphaviruses in 384 bats (representing 10 genera and 14 species) was conducted in the Caribbean island of Trinidad. Sera were analysed using epitope‐blocking enzyme‐linked immunosorbent assays (ELISAs) specific for antibodies against West Nile virus (WNV), Venezuelan equine encephalitis virus (VEEV) and eastern equine encephalitis virus (EEEV), all of which are zoonotic viruses of public health significance in the region. Overall, the ELISAs resulted in the detection of VEEV‐specific antibodies in 11 (2.9%) of 384 bats. Antibodies to WNV and EEEV were not detected in any sera. Of the 384 sera, 308 were also screened using hemagglutination inhibition assay (HIA) for antibodies to the aforementioned viruses as well as St. Louis encephalitis virus (SLEV; which also causes epidemic disease in humans), Rio Bravo virus (RBV), Tamana bat virus (TABV) and western equine encephalitis virus (WEEV). Using this approach, antibodies to TABV and RBV were detected in 47 (15.3%) and 3 (1.0%) bats, respectively. HIA results also suggest the presence of antibodies to an undetermined flavivirus(es) in 8 (2.6%) bats. Seropositivity for TABV was significantly (P < 0.05; χ²) associated with bat species, location and feeding preference, and for VEEV with roost type and location. Differences in prevalence rates between urban and rural locations were statistically significant (P < 0.05; χ²) for TABV only. None of the aforementioned factors was significantly associated with RBV seropositivity rates.     

Encephalitic alphaviruses

This review will cover zoonotic, encephalitic alphaviruses in the family Togaviridae. Encephalitic alphaviruses, i.e. Western- (WEEV), Eastern- (EEEV), Venezuelan equine encephalitis virus (VEEV) and, more rarely, Ross River virus, Chikungunya virus and Highlands J virus (HJV), are neuroinvasive and may cause neurological symptoms ranging from mild (e.g., febrile illness) to severe (e.g., encephalitis) in humans and equines. Among the naturally occurring alphaviruses, WEEV, EEEV and VEEV have widespread distributions in North, Central and South America. WEEV has found spanning the U.S. from the mid-West (Michigan and Illinois) to the West coast and extending to Canada with human cases reported in 21 states. EEEV is found along the Gulf (Texas to Florida) and Atlantic Coast (Georgia to New Hampshire), as well as in the mid-West (Wisconsin, Illinois and Michigan) and in Canada, with human cases reported in 19 states. In contrast, transmission of VEEV occurs predominantly in Central and South America. As with their geographical distribution, equine encephalitis viruses differ in their main mosquito vector species and their zoonotic potential.     

Molecular epidemiological studies of veterinary arboviral encephalitides

Recent studies using molecular genetic approaches have made important contributions to our understanding of the epidemiology of veterinary arboviral encephalitides. Viruses utilizing avian enzootic hosts, such as Western equine encephalitis virus (WEEV) and North American Eastern equine encephalitis virus (EEEV), evolve as relatively few, highly conserved genotypes that extend over wide geographic regions; viruses utilizing mammalian hosts with more limited dispersal evolve within multiple genotypes, each geographically restricted. Similar findings have been reported for Australian alphaviruses. This difference may be related to vertebrate host relationships and the relative mobility of mammals and avians. Whereas EEEV and Venezualan equine encephalitis virus (VEEV) utilize small mammalian hosts in the tropics, most WEEV genotypes probably utilize avian hosts in both North and South America. The ability of mobile, infected avian hosts to disperse alphaviruses may result in continual mixing of virus populations, and thus limit diversification. This high degree of genetic conservation is also exhibited by EEE and Highlands J viruses in North America, where passerine birds serve as amplifying hosts in enzootic transmission foci. Most equine arboviral pathogens, including EEEV, WEEV and Japanese encephalitis virus (JEV), occur in a naturally virulent enzootic state and require only appropriate ecological conditions to cause epizootics and epidemics. However, VEE epizootics apparently require genetic changes to convert avirulent enzootic strains into distinct epizootic serotypes. All of these arboviruses have the potential to cause severe disease of veterinary and human health importance, and further molecular epidemiological studies will undoubtedly improve our ability to understand and control future emergence.     

Serological evidence of widespread exposure of Grenada fruit bats to chikungunya virus

Antibody detection against selected potentially zoonotic vector‐borne alphaviruses and flaviviruses was conducted on sera from bats from all six parishes in Grenada, West Indies. Sera were tested for (i) antibodies to flaviviruses West Nile virus, St. Louis encephalitis virus, Ilhéus virus, Bussuquara virus (BSQV), Rio Bravo virus and all four serotypes of dengue virus (DENV) by plaque reduction neutralization test (PRNT); (ii) antibodies to alphaviruses western equine encephalitis virus, Venezuelan equine encephalitis virus and eastern equine encephalitis virus by epitope‐blocking enzyme‐linked immunosorbent assay (ELISA); and (iii) antibodies to the alphavirus chikungunya (CHIKV) by PRNT. Two species of fruit bats were sampled, Artibeus jamaicensis and Artibeus lituratus, all roosting in or within 1,000 m of human settlements. Fifteen (36%) of the 42 bats tested for neutralizing antibodies to CHIKV were positive. The CHIKV‐seropositive bats lived in localities spanning five of the six parishes. All 43 bats tested for epitope‐blocking ELISA antibody to the other alphaviruses were negative, except one positive for Venezuelan equine encephalitis virus. All 50 bats tested for neutralizing antibody to flaviviruses were negative, except one that had a BSQV PRNT₈₀ titre of 20. The CHIKV serology results indicate that bats living close to and within human settlements were exposed to CHIKV in multiple locations. Importantly, bats for this study were trapped a year after the introduction and peak of the human CHIKV epidemic in Grenada. Thus, our data indicate that bats were exposed to CHIKV possibly during a time of marked decline in human cases.     

Studies on the role of linear epitopes in neutralization of alphaviruses.

By using three synthetic peptides (16-19 amino acids in length) representing different regions of glycoproteins E1 (peptide 3) and E2 (peptides 1 and 2) of Sindbis and Semliki Forest virus and isolated glycoprotein fractions of both viruses in reduced and non-reduced form, the role of linear epitopes for the neutralization was investigated. The reaction patterns of sera induced by immunization with these antigens indicate that conformational epitopes do play the major role in neutralization of alphaviruses. Furthermore, no cross-neutralization of these alphaviruses classified in different antigenic complexes within this genus was found.     

National Seroprevalence and Risk Factors for Eastern Equine Encephalitis and Venezuelan Equine Encephalitis in Costa Rica

Eastern equine encephalitis and Venezuelan equine encephalitis are endemic neglected tropical diseases in the Americas, causing encephalitis in both horses and humans. In 2013, a cross-sectional study was performed in 243 horses located in the highlands and lowlands throughout Costa Rica. Serum samples were analyzed with an IgG ELISA and confirmed by the plaque-reduction neutralization test (PRNT80). Venezuelan equine encephalitis virus (VEEV) and Eastern equine encephalitis virus (EEEV) overall seroprevalences by the PRNT80 were 36% (95% confidence interval [CI]: 29.9–42.5; 78/217 horses) and 3% (95% CI: 1.3–5.9; 6/217 horses), respectively. Both the viruses occurred in the lowlands and highlands. Rainfall and altitude were associated with VEEV seropositivity in the univariate analysis, but only altitude <100 meters above sea level was considered a risk factor in the multivariate analysis. No risk factors could be identified for the EEEV in the multivariate analysis. This is the first study that estimates the seroprevalence of the EEEV and VEEV in Costa Rican horses. The VEEV is widely distributed, whereas the EEEV occurs at a much lower frequency and only in specific areas. Clinical cases and occasional outbreaks of both viruses are to be expected.     

抗东方马脑炎病毒结构蛋白E2单克隆抗体的制备及其抗原表位的鉴定

为制备抗东方马脑炎病毒(EEEV)结构蛋白E2的单克隆抗体(MAb)并鉴定其抗原表位,本研究以Bac-to-Bac真核表达系统表达EEEV E2蛋白,纯化后作为免疫原免疫BALB/c小鼠,取其脾淋巴细胞与小鼠骨髓瘤细胞SP2/0进行融合.以原核表达载体pET-30a表达并纯化的EEEV E2蛋白作为包被抗原建立间接ELISA方法筛选杂交瘤细胞,获得4株稳定分泌抗EEEV E2蛋白MAbs的杂交瘤细胞株,分别命名为6F3、6F11、7C11、8B11.Western blot与间接免疫荧光试验结果表明,获得的4株MAbs均与EEEV呈阳性反应,而与西方马脑炎病毒、乙型脑炎病毒以及登革热病毒1型～4型呈阴性反应.利用部分重叠的原核表达的短肽对E2蛋白抗原表位进行鉴定,初步确定MAb 6F11、7C11和8B11识别的抗原表位均为E-33 (321EGLEYTWGNHPPKRVW336),而MAb 6F3无短肽与其反应,推测可能为构象表位.本研究结果为建立EEEV型特异性检测方法、研究E2蛋白结构功能及该病的进一步防制奠定了基础.     

A survey of antibodies to arthropod-borne viruses in Japanese cattle

Sera collected from the southern parts of Japan were subjected to serological tests for antibodies to 24 arthropod-borne or suspected arthropod-borne viruses. A high incidence (82%) of hemagglutination-inhibiting (HI) antibodies was found with Japanese encephalitis (JE) virus. HI antibodies to other Flaviviruses, Murray Valley encephalitis, Apoi, Kunjin, Stratford and Kokobera, were also found in some of the sera, but seemed to be due to cross reaction with JE virus. High neutralizing (NT) antibody incidences were obtained with Akabane (60%) and Aino (30%) viruses known to be endemic in Japan. NT antibodies were also found for Bunyaviruses, Batai and Wongla; Reoviridae viruses, D'Aguilar, Warrego, and Mitchell River; and Kowanyama and Belmont viruses. Complement fixing antibodies were found for Reoviridae viruses bluetongue type 1 and Ibaraki; Picornavirus Nodamura and Rhabdovirus bovine ephemeral fever. No antibodies were detected with Reoviridae viruses Corriparta and Eubenangee; Bunyavirus Trubanaman; and Alfavirus Chikungunya.     

5种脑炎人兽共患病病毒多重RT-PCR检测方法的建立

为建立同时检测流行性乙型脑炎病毒(JEV)、森林脑炎病毒(TBEV)、东方马脑炎病毒(EEEV)、西方马脑炎病毒(WEEV)和基孔肯雅病毒(CHIKV)5种人兽共患脑炎病病毒的多重RT-PCR方法,本研究根据GenBank登录的相关病毒基因序列设计特异引物,通过优化引物组合及PCR反应条件,建立可同时检测5种病毒的方法,扩增片段长度分别为411 bp(JEV)、945 bp(TBEV)、193 bp(EEEV)、545 bp(WEEV)和769 bp(CHIKV);该方法具有良好的特异性,对病毒核酸最低检测拷贝数分别为7.1×103、3.6×103、2.2×103、5.6×103和5.1×103.该方法具有特异性强、灵敏度高、操作简便等优点,为以上5种人兽共患脑炎病病毒提供快速检测手段.     

Comparison of feline parvovirus subspecific strains using monoclonal antibodies against a feline panleukopenia virus

Four monoclonal antibodies (mAb) against a feline panleukopenia virus (FPLV) TU 1 strain, one of the host range variants of feline parvovirus (FPV), were produced and applied for antigenic analysis of FPLV, canine parvovirus (CPV) and mink enteritis virus (MEV). All mAbs were considered to be directed at epitopes on the virus capsid surface because they neutralized the infectivity and inhibited the hemagglutination (HA) of the homologous virus as well as other FPV strains. They were of the mouse IgG1 type. High antigenic homogeneity among FPLV strains was confirmed by HA-inhibition (HI) test with the mAbs and polyclonal immune sera against FPLV or CPV. But the TU 11 strain of FPLV was antigenically distinguished from the remaining 14 FPLV strains by both the HI test and the micro-neutralization test with one of the mAbs produced. MEV Abashiri strain was found to be antigenically indistinguishable from FPLV. Most of the CPV strains isolated after 1981 were considered to be antigenically different from earlier CPV isolates when some mAbs were applied in the serological tests, confirming the replacement of CPV by an antigenic variant in Japan. However, antigenically different CPVs were detected at the end of 1984 from unrelated epizootics occurred a month apart in the same area.     

Detection of arbovirus antibodies in avian sera by the complement fixation-inhibition test.

The complement fixation-inhibition (CFI) test was described for the detection of antibodies to arboviruses in bird sera. The CFI antibody present in bird sera inhibited the standard complement-fixation reaction of a reference complement-fixing antigen-antibody pair. Using reference antigens (St. Louis encephalitis, eastern equine encephalomyelitis, western equine encephalomyelitis, and yellow fever) prepared from infected mouse brains and reference antisera prepared in rabbits or horses, reproducible CFI antibody titers were obtained in artificially immunized chickens. Time-course studies on the CFI immune response in birds inoculated with live St. Louis encephalitis virus indicated that the CFI antibody was distinct from the antibody detected by the hemagglutination-inhibition test.     

Viruses associated with respiratory disease of horses in New Zealand: an update

Viruses causing or associated with respiratory disease in horses worldwide are reviewed. Results are presented from a serological survey of 121 New Zealand foals and horses that had been affected by respiratory disease, determining the prevalence of antibodies in this country to the major viruses associated with similar disease overseas. To date there is no evidence of equine influenza virus in New Zealand. Both equine herpesvirus type 1 and 2 have been frequently isolated and show high serological prevalences. Serological evidence of equine rhinovirus type 1 and type 2 is presented with a prevalence of 12.3% and 41.2% respectively observed in foal sera, and 37.7% and 84.9% in adult horse sera. Antibody reacting to equine viral arteritis virus antigen was detected in 3/121 test sera. Equine adenovirus has been isolated on occasions and has shown a 39% serological prevalence in one study reviewed. Progress in New Zealand equine virus research is discussed.     

Time dependent decreases of maternal canine virus antibodies in newborn pups

Levels of passively transferred maternal antibodies to three canine viruses, rabies virus (RV), canine distemper virus (CDV) and infectious canine hepatitis (ICH) virus, in serum specimens from 14 fetal pups and in serial serum specimens collected up to 45 days after whelping from 14 neonate pups were compared with levels of antibodies to these viruses in milk and sera collected concurrently from their respective dams. Radioimmunoassays using RV-, CDV- and ICH virus-specific antigens showed that sera from all fetal pups had detectable levels of antibodies to all three canine viruses and ICH neutralising antibodies were detected in sera from 10 of the 14 fetal pups. As the time after whelping increased, titres of RV-, CDV- and ICH virus antibodies measured by radioimmunoassay and ICH virus neutralising antibody tests in serially collected specimens of milk from dams rapidly decreased, while titres of the antibodies in serum specimens from newborn pups in their litters steadily decreased. Individual fetal and newborn pups with a high titre of antibody to one virus also had high titres to the other two viruses, although a wide range of titres was observed among pups in each of the litters studied. Markedly higher titres of antibody to all three viruses were observed in serially collected specimens of sera from dams than in sera from fetal and newborn pups in their litters. Results show that maternal RV, CDV and ICH virus antibodies are transferred from dams to pups in utero and by nursing. Levels of these maternal virus-specific antibodies in newborn pup sera decreased at similar rates as time after whelping increased.     

Inability of kaolin treatment to remove nonspecific inhibitors from equine serum for the hemagglutination inhibition test against equine H7N7 influenza virus.

The hemagglutination inhibition test is used by many diagnostic and surveillance laboratories for detection of antibodies to influenza viruses. It is well known that the hemagglutination inhibition test is affected by nonspecific inhibitors present in equine serum. Several serum treatments are in use to remove these inhibitors, including treatment with kaolin. Discrepant results were observed in the authors' laboratories when using kaolin treatment before testing equine sera for antibodies against equine influenza virus (EIV) subtype-1 (H7N7). It is demonstrated here that kaolin treatment leads to false positive results when testing for antibodies against EIV subtype-1, as compared to other standard serum treatments (trypsin-periodate, receptor-destroying enzyme). Against EIV subtype-2 (H3N8), however, false positive results were not evident. Trypsinperiodate and receptor-destroying enzyme (RDE) treatments appear to be superior to kaolin for removal of nonspecific inhibitors from equine serum and should be used for serological diagnosis and surveillance of equine influenza virus.     

Detection of antibodies to West Nile virus in equine sera using microsphere immunoassay.

One hundred and ninety-one sera from horses that recently were exposed to West Nile virus (WNV) by either vaccination or natural infection or that were not vaccinated and remained free of infection were used to evaluate fluorescent microsphere immunoassays (MIAs) incorporating recombinant WNV envelope protein (rE) and recombinant nonstructural proteins (rNS1, rNS3, and rNS5) for detection of equine antibodies to WNV. The rE MIA had a diagnostic sensitivity and specificity, respectively, of 99.3% and 97.4% for detection of WNV antibodies in the serum of horses that were recently vaccinated or naturally infected with WNV, as compared to the plaque reduction neutralization test (PRNT). The positive rE MIA results were assumed to be WNV-specific because of the close agreement between this assay and the PRNT and the fact that unvaccinated control horses included in this study were confirmed to be free of exposure to the related St Louis encephalitis virus. The NS protein-based MIA were all less sensitive than either the rE MIA or PRNT (sensitivity 0-48.0), although the rNSI MIA distinguished horses vaccinated with the recombinant WNV vaccine from those that were immunized with the inactivated WNV vaccine (P < 0.0001) or naturally infected with WNV (P < 0.0001). The rE MIA would appear to provide a rapid, convenient, inexpensive, and accurate test for the screening of equine sera for the presence of antibodies to WNV.     

Agents of equine viral encephalomyelitis: correlation of serum and cerebrospinal fluid antibodies.

A survey was conducted by testing 115 paired equine serum and cerebrospinal fluid samples by hemagglutination-inhibition for antibodies to Powassan and snowshoe hare viruses, and by virus neutralization for antibodies to equine herpesvirus type 1. Twenty-five samples were from horses with spontaneous neurological disease and the remainder from horses euthanized because of various nonneurological disorders. All sera and cerebrospinal fluids were negative for antibodies to Powassan virus. Fifty-one sera (44.3%) and 15 cerebrospinal fluids (13.0%) had antibodies to snowshoe hare virus. Ninety-eight sera (85.2%) and four cerebrospinal fluids (3.5%) were positive for antibodies to equine herpesvirus type 1. Powassan virus was inoculated intracerebrally into one, and intravenously into four ponies. Neurological signs associated with a nonsuppurative encephalomyelitis occurred in three ponies. Antibodies to Powassan virus were detected in sera of all animals but in cerebrospinal fluids of only two. Powassan virus was isolated from brain and spinal cord of only the intracerebrally inoculated animal.     

Serological investigations of red foxes (Vulpes vulpes L.) for determination of the spread of tick-borne encephalitis in Northrhine-Westphalia

Serum samples from 786 red foxes shot between January 1995 and August 1996 in the southern half of Northrhine-Westphalia, located in western Germany, were tested for the presence of antibodies against tick-borne encephalitis (TBE) virus using the Immunozym FSME IgG All Species-ELISA (Immuno, Heidelberg, Germany) as a screening test: 759 sera were negative, 23 (2.9%) were borderline, and four (0.5%) were positive. Nine of the 27 ELISA reactive sera were confirmed by the TBE Western-Blot (Immuno, Heidelberg, Germany). Furthermore these 27 sera were tested for neutralizing antibodies by means of a plaque reduction neutralization test (PRNT) against TBE and West Nile viruses. Only one single serum was found to have a neutralization titre (+1:800 PRNT80) against TBE virus. All other 26 sera were negative for neutralizing antibodies against TBE or West Nile virus. Since the titre of the single serum is low, it can be interpreted that if TBE virus is present, its prevalence is extremely low. Northrhine-Westphalia is not classified as a TBE-endemic area. Further calculated serological testing of game and virological investigation of collected ticks in the affected area seem to be meaningful and necessary.     

Serological Investigations of Red Foxes (Vulpes vulpes L.) for Determination of the Spread of Tick‐borne Encephalitis in Northrhine‐Westphalia

Serum samples from 786 red foxes shot between January 1995 and August 1996 in the southern half of Northrhine‐Westphalia, located in western Germany, were tested for the presence of antibodies against tick‐borne encephalitis (TBE) virus using the Immunozym FSME IgG All Species‐ELISA^® (Immuno, Heidelberg, Germany) as a screening test: 759 sera were negative, 23 (2.9 %) were borderline, and four (0.5 %) were positive. Nine of the 27 ELISA reactive sera were confirmed by the TBE Western‐Blot (Immuno, Heidelberg, Germany). Furthermore these 27 sera were tested for neutralizing antibodies by means of a plaque reduction neutralization test (PRNT) against TBE and West Nile viruses. Only one single serum was found to have a neutralization titre (+ 1 : 800 PRNT₈₀) against TBE virus. All other 26 sera were negative for neutralizing antibodies against TBE or West Nile virus. Since the titre of the single serum is low, it can be interpreted that if TBE virus is present, its prevalence is extremely low. Northrhine‐Westphalia is not classified as a TBE‐endemic area. Further calculated serological testing of game and virological investigation of collected ticks in the affected area seem to be meaningful and necessary.