Genetic heterogeneity among Saint Louis encephalitis virus isolates of different geographic origin

Movement of St. Louis encephalitis virus in the Western United States, 2014- 2018

St. Louis encephalitis virus (SLEV) is a flavivirus that circulates in an enzootic cycle between birds and mosquitoes and can also infect humans to cause febrile disease and sometimes encephalitis. Although SLEV is endemic to the United States, no activity was detected in California during the years 2004 through 2014, despite continuous surveillance in mosquitoes and sentinel chickens. In 2015, SLEV-positive mosquito pools were detected in Maricopa County, Arizona, concurrent with an outbreak of human SLEV disease. SLEV-positive mosquito pools were also detected in southeastern California and Nevada in summer 2015. From 2016 to 2018, SLEV was detected in mosquito pools throughout southern and central California, Oregon, Idaho, and Texas. To understand genetic relatedness and geographic dispersal of SLEV in the western United States since 2015, we sequenced four historical genomes (3 from California and 1 from Louisiana) and 26 contemporary SLEV genomes from mosquito pools from locations across the western US. Bayesian phylogeographic approaches were then applied to map the recent spread of SLEV. Three routes of SLEV dispersal in the western United States were identified: Arizona to southern California, Arizona to Central California, and Arizona to all locations east of the Sierra Nevada mountains. Given the topography of the Western United States, these routes may have been limited by mountain ranges that influence the movement of avian reservoirs and mosquito vectors, which probably represents the primary mechanism of SLEV dispersal. Our analysis detected repeated SLEV introductions from Arizona into southern California and limited evidence of year-to-year persistence of genomes of the same ancestry. By contrast, genetic tracing suggests that all SLEV activity since 2015 in central California is the result of a single persistent SLEV introduction. The identification of natural barriers that influence SLEV dispersal enhances our understanding of arbovirus ecology in the western United States and may also support regional public health agencies in implementing more targeted vector mitigation efforts to protect their communities more effectively.

Following the detection of West Nile virus in the United States, evidence of the historically endemic and closely related virus, St. Louis encephalitis virus (SLEV), dropped nationwide. However, in 2015, a novel genotype of SLEV, previously restricted to Argentina, was identified as the etiological agent of an outbreak of neurological disease in Arizona, United States. Since that time, the genotype has expanded throughout the Western United States, including into California, Nevada, Texas, Idaho, and Oregon. In this study, samples containing SLEV, provided by public health and mosquito abatement agencies, were sequenced and used in phylogenetic analyses to infer patterns of SLEV movement. Three independent routes of SLEV dispersal were identified: Arizona to Southern California, Arizona to Central California, and Arizona to all locations east of the Sierra Nevada mountains. The Sierra Nevada mountains and the Transverse Ranges appear to separate the three routes of SLEV movement, suggesting that geographic features may act as barriers to virus dispersal. Identification of patterns of SLEV dispersal can support regional public health agencies in improving vector mitigation efforts to protect their communities more effectively.

St. Louis encephalitis virus: first isolation from a human in São Paulo State, Brazil

This paper reports the isolation of St. Louis encephalitis virus (SLEV) from a febrile human case suspected to be dengue, in São Pedro, São Paulo State. A MAC-ELISA done on the patient's acute and convalescent sera was inconclusive and hemagglutination inhibition test detected IgG antibody for flaviviruses. An indirect immunofluorescent assay done on the C6/36 cell culture inoculated with the acute serum was positive for flaviviruses but negative when tested with dengue monoclonal antibodies. RNA extracted from the infected cell culture supernatant was amplified by RT-PCR in the presence of NS5 universal flavivirus primers and directly sequenced. Results of BLAST search indicated that this sequence shares 93% nucleotide similarity with the sequence of SLEV (strain-MSI.7), confirmed by RT-PCR performed with SLEV specific primers. Since SLEV was identified as the cause of human disease, it is necessary to improve surveillance in order to achieve early detection of this agent in the state of São Paulo and in Brazil. This finding is also an alert to health professionals about the need for more complete clinical and epidemiological investigations of febrile illnesses as in the reported case. SLEV infections can be unrecognized or confused with other ones caused by an arbovirus, such as dengue.

Analysis of two imported cases of yellow fever infection from Ivory Coast and The Gambia to Germany and Belgium

BACKGROUND

Yellow fever remains one of the great burdens for public health in the endemic regions in Africa and South America. The under reporting of yellow fever cases in the respective regions and lack of international interest leads to an underestimation of the constant danger in these areas. Non-vaccinated travelers take a high risk without the effective protection of YFV 17D vaccination.

OBJECTIVES

Two YF cases were imported to Europe in the last 4 years. We characterized two yellow fever virus (YFV) isolates from severely infected patients coming back from Africa, Ivory Coast and The Gambia, by genome sequencing and phylogenetic analysis.

STUDY DESIGN

The virus infections in different organs were analyzed with pathological, immunohistological, electronmicroscopical and quantitative real-time PCR methods.

RESULTS AND CONCLUSION

High virus loads in spleen and liver (2.4 x 10 (6) to 3 x 10 (7)GE/mL) demonstrated by real time PCR show massive virus replication leading to extraordinary progression of the disease in these patients. Immunohistological and electronmicroscopical analysis confirms virus particles in liver tissue. In all other organs no virus could be detected. A fast, specific and sensitive virus PCR detection is recommended for diagnostic of acute infections. The further sequence alignments show that the new isolates belong to the type II West African strain with great homology to over 40-year old YF isolates from Senegal and Ghana. The divergence observed was on average 3.3%, ranging from 0.0% to 5.0% in the coding region of Gambia 2001 strain and 2.9 %, ranging from 0.0% to 4.3% in the coding region of the Ivory C 1999 strain. Most mutations (5.0%/4.3%, respectively) occurred in the envelope protein.

West Nile virus activity in the United States, 2001

West Nile virus (WNV) first appeared in the naive environment of the Western Hemisphere in 1999 in New York. Genetic analysis determined that the virus was introduced into the United States from the Mediterranean Basin. This review discusses the spread of the virus in 2001 from the initial focus in Queens, New York, to widespread activity in the eastern and midwestern United States. It concentrates on viral ecology, epizootiology, pathology, prediction, and prevention. Research questions to further our understanding of the transmission cycle of WNV are discussed, including host-preference studies, molecular confirmation of implicated mosquito vectors, and survival of WNV in the temperate environment of the United States. Comparisons are drawn with two other arboviruses enzootic in the United States, eastern equine encephalitis, and St. Louis encephalitis viruses. Although not recently introduced, these two viruses also demonstrated increased activity in the United States in 2001.

Mouse neuroinvasive phenotype of West Nile virus strains varies depending upon virus genotype

Despite recent advances in the genetics of West Nile (WN) virus, relatively little is known about the molecular basis of virulence of this virus. In particular, although the genotype of the WN virus strain that was recently introduced into North America has been determined, there have been few experimental studies on the virulence phenotype of the virus. We compared genetic and neurovirulence properties of 19 strains of WN virus, including 2 from North America, and observed significant differences in their neuroinvasive phenotype in mice and hamsters that correlated with virus genotype. Virus isolated in North America was found to be highly neuroinvasive with a lack of age-related resistance to infection in mice normally associated with mosquito-borne flaviviruses.

Predicting St. Louis encephalitis virus epidemics: lessons from recent, and not so recent, outbreaks

St. Louis encephalitis virus was first identified as the cause of human disease in North America after a large urban epidemic in St. Louis, Missouri, during the summer of 1933. Since then, numerous outbreaks of St. Louis encephalitis have occurred throughout the continent. In south Florida, a 1990 epidemic lasted from August 1990 through January 1991 and resulted in 226 clinical cases and 11 deaths in 28 counties. This epidemic severely disrupted normal activities throughout the southern half of the state for 5 months and adversely impacted tourism in the affected region. The accurate forecasting of mosquito-borne arboviral epidemics will help minimize their impact on urban and rural population centers. Epidemic predictability would help focus control efforts and public education about epidemic risks, transmission patterns, and elements of personal protection that reduce the probability of arboviral infection. Research associated with arboviral outbreaks has provided an understanding of the strengths and weaknesses associated with epidemic prediction. The purpose of this paper is to review lessons from past arboviral epidemics and determine how these observations might aid our ability to predict and respond to future outbreaks.

Characterisation of Wongorr virus, an Australian orbivirus

Sequence analyses of VP3 gene segments of Wongorr virus isolates from the Northern Territory of Australia were compared with the cognate gene segments from Picola and Paroo River viruses. Previous serological investigations had demonstrated some relationships between these viruses, however VP3 gene sequence and phylogenetic analyses placed these viruses within the same serogroup which was distinct from other described orbivirus serogroups. A polymerase chain reaction (PCR) was developed for the detection of this serogroup and used to identify and determine partial sequence data for other isolates of the virus. Wongorr virus and the other tick and mosquito-borne orbiviruses (Kemerovo and Corriparta), were more closely related than the Culicoides transmitted orbiviruses, such as bluetongue (BTV) and African horse sickness virus (AHSV) which were shown to be on a separate branch of the orbivirus phylogenetic tree.

Genetic and phylogenetic analyses of hantaviral sequences amplified from archival tissues of deer mice (Peromyscus maniculatus nubiterrae) captured in the eastern United States

The S and M segments of a hantavirus, enzymatically amplified from tissues of Cloudland deer mice (Peromyscus maniculatus nubiterrae) captured during 1985 in West Virginia, diverged from strains of Four Corners virus from the southwestern United States by more than 16% and 6% at the nucleotide and amino acid levels, respectively. Phylogenetic analysis suggested that this virus strain (designated Monongahela) forms a possible evolutionary link between the Four Corners and New York hantaviruses.

Molecular epidemiology and evolution of mosquito-borne flaviviruses and alphaviruses enzootic in Australia

Three distinct patterns in the molecular epidemiology and evolution are evident among the alphaviruses and flaviviruses enzootic in Australia. One pattern, exemplified by MVE and KUN viruses, is of a single genetic type evolving slowly and uniformly in geographically widely separated regions of Australia with no evidence of independent divergence. The second pattern, exemplified by RR virus, is of separate genotypes evolving in different geographic regions with significant nucleotide divergence between genotypes. The third pattern, exemplified by SIN virus, is of a succession of temporally related genotypes that extend over most of the Australian continent, with relatively low levels of nucleotide divergence within a genotype, and which are each replaced by the subsequent genotype. These patterns are associated in part due to the nature and dispersal of their vertebrate hosts. Nucleotide divergence rates for Australian alphaviruses are similar to those reported elsewhere. Genomic relationships between Australian flavivirus members of the JE virus serological complex and between Australian alphaviruses are discussed, and evidence is presented for a possible new genomic lineage of SIN virus.

Restriction enzyme analysis of American region dengue viruses

Restriction fragment heterogeneity of Hae III digestion products of cDNA to virion RNA was used to map the distribution of dengue virus topotypes found in the American region. By comparing the electrophoretic patterns of fragments produced, dengue virus isolates were placed in groups that agreed with those previously determined by oligonucleotide fingerprinting. Dengue-1 and dengue-4 viruses occur throughout the western hemisphere as single genetic types, with most of the isolates sharing at least 70% of their Hae III restriction enzyme fragments. Dengue-2 virus exists as two topotypes in the region with apparently non-overlapping distributions. The Puerto Rico topotype, which has been in the Caribbean for at least 40 years, is genetically diverse, while the Jamaica topotype, first isolated in 1981, is more homogeneous and has expanded its range from the original Caribbean focus to South America.

Genetic heterogeneity among isolates of Ross River virus from different geographical regions

The RNase T1 maps of 80 isolates of Ross River virus from different regions of mainland Australia and the Pacific Islands were compared. Four different clusters of isolates with greater than an estimated 5 to 6% diversity at the nucleotide level were found. There was a pattern of differences between eastern and western Australian strains; however, the pattern was disturbed by overlaps and incursants. Pacific Islands isolates belonged to the eastern Australian topotype. Our findings suggest that certain genetic types of Ross River virus predominate in different geographical regions. In contrast, populations of other important Australian arboviruses (Murray Valley encephalitis, Kunjin, and Sindbis viruses) are distributed across the Australian continent as minor variants of one strain. Our data also show that in one region, strains of Ross River virus with identical RNase T1 maps circulate during both years when epidemics occur and years when they do not. This finding suggests that Ross River virus epidemics are not dependent on the introduction or evolution of new strains of the virus. Two strains, belonging to the eastern Australian topotype, were isolated in Western Australia. It is likely that viremic humans or possibly domestic livestock travelling by aircraft were responsible for this movement.

Nucleotide sequence of the virulent SA-14 strain of Japanese encephalitis virus and its attenuated vaccine derivative, SA-14-14-2

The attenuated SA-14-14-2 strain of Japanese encephalitis (JE) virus has been used to immunize people in the People's Republic of China. Oligonucleotide fingerprints of the parent SA-14 and vaccine strain indicate that multiple genetic changes occurred during attenuation of the virus. We have cloned and sequenced the genomes of both the virulent SA-14 and attenuated SA-14-14-2 viruses to define molecular differences in the genomes. Forty-five nucleotide differences, resulting in 15 amino acid substitutions, were found by comparing sequences of the SA-14 and SA-14-14-2 genomes. Transversion of U to A occurred at position 39 in the 5'-noncoding region of SA-14-14-2 and another SA-14 vaccine derivative SA-14-5-3. A single nucleotide change in the capsid gene of SA-14-14-2 altered a single amino acid which changed its predicted secondary structure. A silent nucleotide change was found in the prM gene sequence and the M-protein was unchanged. There are seven nucleotide differences, resulting in five amino acid changes, in the E glycoprotein sequence of the two viruses. Nine amino acid differences were found in the nonstructural proteins of SA-14 and SA-14-14-2: one in NS2A, two in NS2B, three in NS3, one in ns4a, and two in NS5. A single nucleotide change at position 10,428 in the 3'-noncoding region is vaccine virus-specific. The nucleotide and deduced amino acid sequences of the vaccine strain SA-14-14-2, the parent virus SA-14, and virulent strains JaOArS982 and Beijing-1 have been compared and are highly conserved.

Relationships amongst bluetongue viruses revealed by comparisons of capsid and outer coat protein nucleotide sequences

Sequence data from the gene segments coding for the capsid protein. VP3, of all eight Australian bluetongue virus serotypes were compared. The high degree of nucleotide sequence homology for VP3 genes amongst BTV isolates from the same geographic region supported previous studies (Gould, 1987; 1988b, c; Gould et al., 1988b) and was proposed as a basis for "topotyping" a bluetongue virus isolate (Gould et al., 1989). The complete nucleotide sequences which coded for the VP2 outer coat proteins of South African BTV serotypes 1 and 3 (vaccine strains) were determined and compared to cognate gene sequences from North American and Australian BTVs. These VP2 comparisons demonstrated that BTVs of the same serotype, but from different geographical regions, were closely related at the nucleotide and amino acid levels. However, close inter-relationships were also demonstrated amongst other BTVs irrespective of serotype or geographic origin. These data enabled phylogenic relationships of the BTV serotypes to be analysed using VP2 nucleotide sequences as a determinant.

Genetic variation and microevolution of dengue 2 virus in Southeast Asia

Dengue 2 (DEN 2) virus strains collected from dengue hemorrhagic fever (DHF) patients and Aedes aegypti mosquitoes in Thailand, Burma, and Vietnam over a 25-year period have been analyzed by computer assisted T1-RNase-resistant oligonucleotide fingerprinting. Fifty-seven DEN 2 virus strains of the Thailand topotype were separated into four major clusters by phylogenetic analysis of 97 unique oligonucleotides identified in a common well-resolved region of the fingerprints. Similarities in the 57 fingerprints indicated that DEN 2 virus of a single, continually evolving genetic population has been involved in endemic transmission of the disease. Virus isolates from DHF cases and mosquitoes are genetically very similar, indicating that different genetic topotypes are not selectively the cause of severe DEN disease in Thailand. Microevolution of the DEN 2 virus genome from 1962-1986 was gradual with detectable changes in the pattern of oligonucleotides through time. Segregation of the DEN 2 virus fingerprints into the three decades (1960s, 1970s, and 1980s) revealed the rate of genetic change to be one consensus oligonucleotide per year. Based on average association coefficient (Sab) values between the consensus fingerprints for each decade, the similarity between the consensus fingerprints decreased by 1.4% per year. Genetic variation during each of the three decades was found to be essentially the same (0.866 +/- 0.053). Constancy in the microevolutionary rate and genetic variability suggests that a balance of genetic drift and natural selection acting on the viral population did not significantly change throughout the 25-year period.

RNA virus evolution and the control of viral disease

RNA viruses and other RNA genetic elements must be viewed as organized distributions of sequences termed quasi-species. This means that the viral genome is statistically defined but individually indeterminate. Stable distributions may be maintained for extremely long time periods under conditions of population equilibrium. Perturbation of equilibrium results in rapid distribution shifts. This genomic organization has many implications for viral pathogenesis and disease control. This review has emphasized the problem of selection of viral mutants resistant to antiviral drugs and the current difficulties encountered in the design of novel synthetic vaccines. Possible strategies for antiviral therapy and vaccine development have been discussed.

Murray Valley encephalitis virus field strains from Australia and Papua New Guinea: studies on the sequence of the major envelope protein gene and virulence for mice

We have compared the nucleotide sequence of the gene encoding the major envelope (E) protein of a number of Murray Valley encephalitis virus (MVE) isolates from Australia and Papua New Guinea (PNG). The isolates, from widely separated geographic regions, were from four fatal human cases, a heron, and six mosquito pools and covered a period of 25 years. The sequences of the Australian strains were notable for their similarity, showing not more than 1.7% nucleotide sequence divergence in pairwise comparisons. There was 6.8% divergence in the E gene between the two available strains from PNG, and 9-10% divergence between each of the PNG strains and the Australian prototype. These data are consistent with previous conclusions based on HaeIII restriction digest analysis of cDNA to virion RNA (M. Lobigs, I. D. Marshall, R. C. Weir, and L. Dalgarno, 1986, Aust. J. Exp. Biol. Med. Sci. 64, 571-585). We conclude that a single MVE genetic type exists in Australia. Separate foci of MVE evolution appear to exist in PNG, generating greater strain variation. For all MVE isolates the deduced length of the E protein was 501 amino acids. The E protein differed at no more than three positions between any two Australian strains. The PNG strains differed from the Australian strains at 6-11 residues depending on the virus pair. Differences in amino acid sequence did not occur at a position corresponding to a previously demonstrated neutralization determinant in yellow fever virus (M. Lobigs, L. Dalgarno, J. J. Schlesinger, and R. C. Weir, 1987, Virology 161, 474-478). Thus selection for neutralization resistance may not be a major evolutionary pressure in the field situation. In comparisons between the E protein amino acid sequence of the prototype strain and those of a number of other MVE strains, 7 out of 14 differences were at residues seen at the corresponding position for Japanese encephalitis virus (JE), consistent with the close serological relationship of MVE and JE. Five Australian MVE strains and two from PNG were tested for virulence by comparing LD50 values after intraperitoneal and intracranial inoculation of 21-day-old mice; all strains were virulent by this test.

Sequence and secondary structure analysis of the 5'-terminal region of flavivirus genome RNA

The 5'-terminal noncoding region sequences were determined for the genome RNAs of seven strains of St. Louis encephalitis virus (SLEV) and one strain of West Nile virus (WNV) using a single synthetic cDNA primer complementary to the 5'-terminus of the coding region of a strain of WNV RNA. The 5'-terminal sequences obtained for the SLEV and WNV RNAs were compared with published sequences for yellow fever virus (YFV), Murray Valley encephalitis virus (MVEV), and dengue virus. While only short regions within the 5'-noncoding sequence were conserved among different flavivirus RNAs, significant homology was observed in this region among members of the same flavivirus subgroup and almost complete conservation was observed between different strains of the same virus. For example, seven strains of SLE, isolated from different geographic locations over a 17-year period and differing in their neurovirulence phenotype, contained only two to four nucleotide changes in the 5'-noncoding region. Interestingly, each of three low-virulence strains shared the same unique base substitution at position 16. Secondary structures predicted to be formed by the 5'-termini of each of the different flavivirus genome RNAs were of similar size and shape, in each case consisting of a stem with a small top loop and a larger side loop. The prediction of a common structure among a number of different flaviviruses, despite the lack of extensive sequence homology, suggests that this secondary structure is functionally important. An additional stem and loop structure is predicted to be formed in the region spanning the translation initiation codon. This structure showed significantly less conservation of size and shape than the 5'-terminal secondary structure.

Analysis of Ross River virus genomic RNA using HaeIII digests of single-stranded cDNA to infected-cell RNA and virion RNA

To study genetic relationships between isolates of Ross River virus (RRV), an alphavirus with a chromosome of approximately 12,000 nucleotides, total high-molecular-weight RNA from RRV-infected baby hamster kidney (BHK) cells was transcribed into 32P-labeled, complementary DNA using reverse transcriptase and random calf-thymus DNA primers. The cDNA was digested with HaeIII or TaqI (restriction nucleases which cleave single-stranded DNA), and the restriction fragments separated on a standard DNA sequencing gel. The resulting HaeIII or TaqI restriction digest profiles mainly comprised virus-specific bands; cell RNAs were transcribed poorly. In reconstruction experiments, purified 49 S RRV genomic RNA and a 10-fold mass excess of mock-infected-cell RNA were reverse transcribed in the same reaction mix. Under these conditions there was no interference with the transcription of viral RNA sequences. When the level of viral RNA was lowered to one-hundredth that of cell RNA in the reaction mix, there was no qualitative change in restriction digest profiles. The procedure is rapid, simple, uses small amounts of 32P, does not require purification of virus or viral RNA, and permits cross-comparison between several virus strains on a single one-dimensional gel. The method should be applicable to other single-stranded RNA viruses of moderate genome complexity.

Purification of the structural and nonstructural proteins of St. Louis encephalitis virus

We have developed a procedure for purifying both the structural and nonstructural proteins of flaviviruses from lysates of infected cell cultures. The procedure involves: immunoprecipitation to concentrate viral proteins and eliminate most of the cellular proteins, preparative polyacrylamide gel electrophoresis to separate the viral proteins, and hydroxyapatite chromatography, which eliminates most of the unlabeled cellular protein. This procedure offers an improvement over previous purification schemes in that there is no loss of viral proteins after the immunoprecipitation step, any combination of labeling isotopes may be used, and it is not necessary to soak proteins out of gel slices.

Applications of Oligonucleotide Fingerprinting to the Identification of Viruses

This chapter focuses on applications of oligonucleotide fingerprinting to the identification of viruses. Fingerprinting is a technique by which oligonucleotides, produced by cleavage of RNA molecules with specific ribonucleases, are separated in two dimensions. It is a definitive method of identifying RNA viruses according to their genotypes. It is not subject to the problems of antigenic drift or antigenic convergence that complicate serological identification. Furthermore, it provides a semiquantitative means of following the evolution of viral genomes in nature. Because all regions of the genome are represented by the large diagnostic oligonucleotides, a survey of the total genomic changes can be monitored. Fingerprinting has two limitations as a diagnostic tool. First, although highly definitive, fingerprinting is not as rapid or inexpensive as serological techniques and cannot be as easily scaled up for routine identification of a large number of samples. Second, the evolutionary range of fingerprinting is short and relationships may not be evident for isolates of rapidly evolving viruses obtained over long intervals. However, these limitations are not large, compared to the full benefits offered to the virologist by the fingerprinting method.

Genetic variation among dengue 2 viruses of different geographic origin

Genetic variation in dengue 2 isolates from various geographic areas was examined by oligonucleotide fingerprinting of the 40 S genome RNA. Oligonucleotide maps of geographically isolated and epidemiologically unrelated viruses were very distinct. Direct comparison of the oligonucleotide map of the dengue 2 prototype New Guinea 2 virus, isolated in 1944, with the fingerprints of more recent isolates from the South Pacific indicated that the genome of dengue 2 virus had undergone extensive change although the viruses are serologically indistinguishable. The oligonucleotide map of an isolate from a recent case in Jamaica and a mosquito isolate from Upper Volta, Africa, were recognized to be almost identical, suggesting that virus may have been introduced into the Caribbean from West Africa. Likewise, the fingerprints of isolates from Puerto Rico and the South Pacific shared 80 to 95% of their large oligonucleotides, suggesting that the virus involved in these epidemics may have spread throughout Tahiti, American Samoa, Fiji, and to Puerto Rico in the Caribbean or vice versa. On the basis of these studies, five genetic variants or topotypes of dengue 2 virus have been established: (1) Puerto Rico-South Pacific, (2) Burma-Thailand, (3) the Seychelles, (4) the Philippines, and (5) Jamaica-West Africa. Oligonucleotide fingerprinting offers a highly sensitive and reproducible technical approach to the investigation of dengue 2 virus intratypic variation and possibly to the understanding of the biological variation associated with dengue fever and hemorrhagic disease.

Identification of epitopes on the E glycoprotein of Saint Louis encephalitis virus using monoclonal antibodies

Twenty-one hybridomas producing monoclonal antibodies specific for the E glycoprotein of St. Louis encephalitis (SLE) virus, strain MSI-7, have been isolated. Serologic reactivities were initially determined by cross-reactivity indirect immunofluorescence assays using 22 strains of SLE virus and 8 other related flaviviruses. Four groups demonstrating type-, subcomplex-, supercomplex-, and group-specific reactivity patterns were identified. Analysis of hemagglutination-inhibition (HI) and virus neutralization (N) subdivided the cross-reactivity groups into eight epitopes (E-1a,b,c,d, E-2, E-3, and E-4a,b). The antibodies could detect strain differences between SLE viruses isolated from various geographic areas. Analysis of the spatial arrangements of these epitopes using competitive binding assays with representative antibodies possessing similar binding avidities, indicated that the protein was a continuum of six overlapping domains.

Monoclonal antibodies to the structural glycoprotein of tick-borne encephalitis virus

Hybridomas secreting antibodies to the structural glycoprotein of tick-borne encephalitis (TBE) virus were prepared by fusion of X63-Ag8/653 mouse myeloma cells with spleen cells from mice immunized with purified glycoprotein complexes of TBE virus. These antibodies were tested against 10 different TBE virus strains isolated in different European countries over a period of 26 years from different hosts. Quantitative evaluation of enzyme immunoassay results did not reveal any differences in reactivity among these strains, pointing further to the homogeneity of European TBE virus isolates, which has previously been inferred from results obtained by peptide mapping and competitive radioimmunoassay. Hybridomas defining three different antibody-combining sites (epitopes) on the glycoprotein of TBE virus were selected on the basis of cross-reactivity with another flavivirus. West Nile virus, as well as the ability to inhibit hemagglutination. Two epitopes were type specific, and the third was indistinguishably also present on West Nile virus. Hemagglutination was inhibited by monoclonal antibodies reacting with one of the type-specific epitopes as well as the cross-reactive determinant, which is apparently responsible for the broad cross-reactivity among different flaviviruses observed in hemagglutination inhibition tests with polyvalent immune sera.