Successful post-exposure prophylaxis of Ebola infected non-human primates using Ebola glycoprotein-specific equine IgG

Herein we describe production of purified equine IgG obtained from horses immunized with plasmid DNA followed by boosting with Kunjin replicon virus-like particles both encoding a modified Ebola glycoprotein. Administration of the equine IgG over 5 days to cynomolgus macaques infected 24 hours previously with a lethal dose of Ebola virus suppressed viral loads by more than 5 logs and protected animals from mortality. Animals generated their own Ebola glycoprotein-specific IgG responses 9-15 days after infection, with circulating virus undetectable by day 15-17. Such equine IgG may find utility as a post-exposure prophylactic for Ebola infection and provides a low cost, scalable alternative to monoclonal antibodies, with extensive human safety data and WHO-standardized international manufacturing capability available in both high and low income countries.

Kunjin virus replicon-based vaccines expressing Ebola virus glycoprotein GP protect the guinea pig against lethal Ebola virus infection

Pre- or postexposure treatments against the filoviral hemorrhagic fevers are currently not available for human use. We evaluated, in a guinea pig model, the immunogenic potential of Kunjin virus (KUN)-derived replicons as a vaccine candidate against Ebola virus (EBOV). Virus like particles (VLPs) containing KUN replicons expressing EBOV wild-type glycoprotein GP, membrane anchor-truncated GP (GP/Ctr), and mutated GP (D637L) with enhanced shedding capacity were generated and assayed for their protective efficacy. Immunization with KUN VLPs expressing full-length wild-type and D637L-mutated GPs but not membrane anchor-truncated GP induced dose-dependent protection against a challenge of a lethal dose of recombinant guinea pig-adapted EBOV. The surviving animals showed complete clearance of the virus. Our results demonstrate the potential for KUN replicon vectors as vaccine candidates against EBOV infection.

Recovery of infectious Ebola virus from complementary DNA: RNA editing of the GP gene and viral cytotoxicity

To study the mechanisms underlying the high pathogenicity of Ebola virus, we have established a system that allows the recovery of infectious virus from cloned cDNA and thus permits genetic manipulation. We created a mutant in which the editing site of the gene encoding envelope glycoprotein (GP) was eliminated. This mutant no longer expressed the nonstructural glycoprotein sGP. Synthesis of GP increased, but most of it accumulated in the endoplasmic reticulum as immature precursor. The mutant was significantly more cytotoxic than wild-type virus, indicating that cytotoxicity caused by GP is down-regulated by the virus through transcriptional RNA editing and expression of sGP.

Molecular characterization of guinea pig-adapted variants of Ebola virus

Serial passage of initially nonlethal Ebola virus (EBOV) in outbred guinea pigs resulted in the selection of variants with high pathogenicity. Nucleotide sequence analysis of the complete genome of the guinea pig-adapted variant 8mc revealed that it differed from wild-type virus by eight mutations. No mutations were identified in nontranscribed regions, including leader, trailer, and intragenic sequences. Among noncoding regions the only base change was found in the VP30 gene. Two silent base changes were found in the open reading frame (ORF) encoding NP protein. Nucleotide changes resulting in single-amino-acid exchanges were identified in both NP and L genes. Three other mutations found in VP24 caused amino acid substitutions, which are responsible for larger structural changes of this protein, as indicated by an alteration in electrophoretic mobility. A highly pathogenic EBOV variant K5 from another passaging series showed an amino acid substitution at nearly the same location in the VP24 gene, suggesting the importance of this protein in the adaptation process. In addition, sequence variability of the GP gene was found when plaque-purified clones of EBOV-8mc were analyzed. Three of five viral clones showed insertion of one uridine residue at the GP gene-editing site, which led to a significant change in the expression of virus glycoproteins. This observation suggests that the editing site is a hot spot for insertion and deletion of nucleotides, not only at the level of transcription but also of genome replication. Irrespective of the number of uridine residues at the editing site, all plaque-purified clones of EBOV variant 8mc resembled each other in their pathogenicity for guinea pigs, indicating either the absence or only supportive role of mutations in the GP gene on the adaptation process.

Human asymptomatic Ebola infection and strong inflammatory response

BACKGROUND

Ebola virus is one of the most virulent pathogens, killing a very high proportion of patients within 5-7 days. Two outbreaks of fulminating haemorrhagic fever occurred in northern Gabon in 1996, with a 70% case-fatality rate. During both outbreaks we identified some individuals in direct contact with sick patients who never developed symptoms. We aimed to determine whether these individuals were indeed infected with Ebola virus, and how they maintained asymptomatic status.

METHODS

Blood was collected from 24 close contacts of symptomatic patients. These asymptomatic individuals were sampled 2, 3, or 4 times during a 1-month period after the first exposure to symptomatic patients. Serum samples were analysed for the presence of Ebola antigens, virus-specific IgM and IgG (by ELISA and western blot), and different cytokines and chemokines. RNA was extracted from peripheral blood mononuclear cells, and reverse transcriptase-PCR assays were done to amplify RNA of Ebola virus. PCR products were then sequenced.

FINDINGS

11 of 24 asymptomatic individuals developed both IgM and IgG responses to Ebola antigens, indicating viral infection. Western-blot analysis showed that IgG responses were directed to nucleoprotein and viral protein of 40 kDa. The glycoprotein and viral protein of 24 kDa genes showed no nucleotide differences between symptomatic and asymptomatic individuals. Asymptomatic individuals had a strong inflammatory response characterised by high circulating concentrations of cytokines and chemokines.

INTERPRETATION

This study showed that asymptomatic, replicative Ebola infection can and does occur in human beings. The lack of genetic differences between symptomatic and asymptomatic individuals suggest that asymptomatic Ebola infection did not result from viral mutations. Elucidation of the factors related to the genesis of the strong inflammatory response occurring early during the infectious process in these asymptomatic individuals could increase our understanding of the disease.

Proteolytic processing of Marburg virus glycoprotein

Processing of the transmembrane glycoprotein (GP) of Marburg virus involved the conversion of an endo H-sensitive, ER-specific form into an endo H-resistant, Golgi-specific precursor that was cleaved into GP(1) and GP(2). Cleavage was mediated by furin or another subtilisin-like endoprotease with similar substrate specificity as indicated by mutational analysis of the cleavage site and inhibition using peptidyl chloromethylketones. Mature GP consisted of disulfide-linked GP(1) and GP(2) subunits.

Delta-peptide is the carboxy-terminal cleavage fragment of the nonstructural small glycoprotein sGP of Ebola virus

In the present study we have investigated processing and maturation of the nonstructural small glycoprotein (sGP) of Ebola virus. When sGP expressed from vaccinia virus vectors was analyzed by pulse-chase experiments using SDS-PAGE under reducing conditions, the mature form and two different precursors have been identified. First, the endoplasmic reticulum form sGP(er), full-length sGP with oligomannosidic N-glycans, was detected, sGP(er) was then replaced by the Golgi-specific precursor pre-sGP, full-length sGP containing complex N-glycans. This precursor was finally converted by proteolysis into mature sGP and a smaller cleavage fragment, Delta-peptide. Studies employing site-directed mutagenesis revealed that sGP was cleaved at a multibasic amino acid motif at positions 321 to 324 of the open reading frame. Cleavage was blocked by RVKR-chloromethyl ketone. Uncleaved pre-sGP forms a disulfide-linked homodimer and is secreted into the culture medium in the presence of the inhibitor as efficiently as proteolytically processed sGP. In vitro treatment of pre-sGP by purified recombinant furin resulted in efficient cleavage, confirming the importance of this proprotein convertase for the processing and maturation of sGP. Delta-peptide is also secreted into the culture medium and therefore represents a novel nonstructural expression product of the GP gene of Ebola virus. Both cleavage fragments contain sialic acid, but only Delta-peptide is highly O-glycosylated.

The glycoproteins of Marburg and Ebola virus and their potential roles in pathogenesis

Filoviruses cause systemic infections that can lead to severe hemorrhagic fever in human and non-human primates. The primary target of the virus appears to be the mononuclear phagocytic system. As the virus spreads through the organism, the spectrum of target cells increases to include endothelial cells, fibroblasts, hepatocytes, and many other cells. There is evidence that the filovirus glycoprotein plays an important role in cell tropism, spread of infection, and pathogenicity. Biosynthesis of the glycoprotein forming the spikes on the virion surface involves cleavage by the host cell protease furin into two disulfide linked subunits GP1 and GP2. GP1 is also shed in soluble form from infected cells. Different strains of Ebola virus show variations in the cleavability of the glycoprotein, that may account for differences in pathogenicity, as has been observed with influenza viruses and paramyxoviruses. Expression of the spike glycoprotein of Ebola virus, but not of Marburg virus, requires transcriptional editing. Unedited GP mRNA yields the nonstructural glycoprotein sGP, which is secreted extensively from infected cells. Whether the soluble glycoproteins GP1 and sGP interfere with the humoral immune response and other defense mechanisms remains to be determined.

A new Clethrionomys-derived hantavirus from Germany: evidence for distinct genetic sublineages of Puumala viruses in Western Europe

Puumala (PUU) viruses are the predominant etiologic agents of hantavirus infections in Europe. The most important reservoir is the bank vole, Clethrionomys glareolus (Cg), belonging to the subfamily Arvicolinae of the Muridae family. Here we report on the molecular characterization of the first rodent-derived sequence (PUU/Cg-Erft) from Germany. Comparison of the S and M segment coding regions revealed 92.5 and 92.8% identity, respectively, with PUU/H-9013, a human isolate from France. However, only 83.1% identity was found with the S segment of a previously reported PUU sequence from a German HFRS case (PUU/H-Berkel) indicating the co-existence of two distinct sublineages in Germany. Phylogenetic and alignment analyses of S and M segment coding regions enabled us to assign PUU viruses/sequences to at least six distinct genetic sublineages. Membership was defined by nucleotide sequence differences of < 8%, whereas a diversity of > 14% clearly outgrouped a virus/sequence. Based on S segment sequences the sublineage represented by Clethrionomys rufocanus-derived viruses from Japan diverged at a well supported node from the clade harbouring all Clethrionomys glareolus-derived European PUU viruses. A correlation between genetic relationship and geographic origin of PUU viruses was observed which may support a co-evolution of PUU viruses with distinct subspecies of their reservoir host.

Comparison of the transcription and replication strategies of marburg virus and Ebola virus by using artificial replication systems

The members of the family Filoviridae, Marburg virus (MBGV) and Ebola virus (EBOV), are very similar in terms of morphology, genome organization, and protein composition. To compare the replication and transcription strategies of both viruses, an artificial replication system based on the vaccinia virus T7 expression system was established for EBOV. Specific transcription and replication of an artificial monocistronic minireplicon was demonstrated by reporter gene expression and detection of the transcribed and replicated RNA species. As it was shown previously for MBGV, three of the four EBOV nucleocapsid proteins, NP, VP35, and L, were essential and sufficient for replication. In contrast to MBGV, EBOV-specific transcription was dependent on the presence of the fourth nucleocapsid protein, VP30. When EBOV VP30 was replaced by MBGV VP30, EBOV-specific transcription was observed but with lower efficiency. Exchange of NP, VP35, and L between the two replication systems did not lead to detectable reporter gene expression. It was further observed that neither MBGV nor EBOV were able to replicate the heterologous minigenomes. A chimeric minigenome, however, containing the EBOV leader and the MBGV trailer was encapsidated, replicated, transcribed, and packaged by both viruses.

Characterization of the L gene and 5' trailer region of Ebola virus

The nucleotide sequences of the L gene and 5' trailer region of Ebola virus strain Mayinga (subtype Zaire) have been determined, thus completing the sequence of the Ebola virus genome. The putative transcription start signal of the L gene was identical to the determined 5' terminus of the L mRNA (5' GAGGAAGAUUAA) and showed a high degree of similarity to the corresponding regions of other Ebola virus genes. The 3' end of the L mRNA terminated with 5' AUUAUAAAAAA, a sequence which is distinct from the proposed transcription termination signals of other genes. The 5' trailer sequence of the Ebola virus genomic RNA consisted of 676 nt and revealed a self-complementary sequence at the extreme end which may play an important role in virus replication. The L gene contained a single ORF encoding a polypeptide of 2212 aa. The deduced amino acid sequence showed identities of about 73 and 44% to the L proteins of Ebola virus strain Maleo (subtype Sudan) and Marburg virus, respectively. Sequence comparison studies of the Ebola virus L proteins with several corresponding proteins of other non-segmented, negative-strand RNA viruses, including Marburg viruses, confirmed a close relationship between filoviruses and members of the Paramyxovirinae. The presence of several conserved linear domains commonly found within L proteins of other members of the order Mononegavirales identified this protein as the RNA-dependent RNA polymerase of Ebola virus.

Recombinant Ebola virus nucleoprotein and glycoprotein (Gabon 94 strain) provide new tools for the detection of human infections

After cloning and sequencing the glycoprotein (GP) gene of one of the Gabonese strains of Ebola virus isolated during the 1994-1996 outbreak, it was shown that the circulating virus was of the Zaire subtype. This was confirmed in this study by cloning and sequencing the nucleoprotein (NP) gene of this strain. These two structural proteins were also expressed as recombinant proteins and used in ELISA tests. NP was expressed as a His-tagged fusion protein in Escherichia coli and was purified on resins charged with nickel ions. GP was expressed by means of recombinant baculoviruses in Spodoptera frugiperda cells. Both recombinant proteins reacted positively in ELISAs for the detection of IgG antibodies in convalescent human sera from Gabon and Zaire. The difference in the relative titres of anti-NP and -GP antibodies was variable, depending on the sera. In addition, the recombinant NP reacted with heterologous sera from Côte d'Ivoire and was used successfully to detect IgM antibodies by mu-capture ELISA in sera from Gabonese patients.

The nonstructural small glycoprotein sGP of Ebola virus is secreted as an antiparallel-orientated homodimer

The nonstructural small glycoprotein sGP, which unlike the transmembrane GP is synthesized from primary nonedited mRNA species, is secreted from infected cells as a disulfide-linked homodimer. Site-directed mutagenesis of all cysteine residues revealed that dimerization is due to an intermolecular disulfide linkage between cysteine residues at positions 53 and 306. Formic acid hydrolysis of sGP demonstrated that sGP dimers consist of monomers in antiparallel orientation. Another editing product of the GP gene of Ebola virus (ssGP), which shares 295 amino-terminal amino acid residues with sGP, is secreted from cells in a monomeric form due to the lack of the carboxyl-terminal part (present in sGP), including cysteine at position 306.

Release of viral glycoproteins during Ebola virus infection

Maturation and release of the Ebola virus glycoprotein GP were studied in cells infected with either Ebola or recombinant vaccinia viruses. Significant amounts of GP were found in the culture medium in nonvirion forms. The major form represented the large subunit GP1 that was shed after release of its disulfide linkage to the smaller transmembrane subunit GP2. The minor form were intact GP1,2 complexes incorporated into virosomes. Vector-expressed GP formed spikes morphologically indistinguishable from spikes on virus particles, indicating that spike assembly is independent of other viral proteins. Analysis of a truncation mutant revealed an early and almost complete release of GP1,2 molecules, showing that membrane anchoring is mediated by the carboxy-terminal hydrophobic domain of GP2. We have also compared wild-type virus which requires transcriptional editing for synthesis of full-length GP with a variant that does not depend on editing. Both viruses released comparable amounts of GP1, but the variant expressed only minute amounts of the small, soluble GP which is the expression product of nonedited mRNA species of the GP gene. The abundant shedding of soluble GP1 may play an important role in the immunopathology of Ebola hemorrhagic fever in experimentally and naturally infected hosts.

Processing of the Ebola virus glycoprotein by the proprotein convertase furin

In the present study, we have investigated processing and maturation of the envelope glycoprotein (GP) of Ebola virus. When GP expressed from vaccinia virus vectors was analyzed by pulse-chase experiments, the mature form and two different precursors were identified. First, the endoplasmic reticulum form preGPer, full-length GP with oligomannosidic N-glycans, was detected. preGPer (110 kDa) was replaced by the Golgi-specific form preGP (160 kDa), full-length GP containing mature carbohydrates. preGP was finally converted by proteolysis into mature GP1,2, which consisted of two disulfide-linked cleavage products, the amino-terminal 140-kDa fragment GP1, and the carboxyl-terminal 26-kDa fragment GP2. GP1,2 was also identified in Ebola virions. Studies employing site-directed mutagenesis revealed that GP was cleaved at a multibasic amino acid motif located at positions 497 to 501 of the ORF. Cleavage was blocked by a peptidyl chloromethylketone containing such a motif. GP is cleaved by the proprotein convertase furin. This was indicated by the observation that cleavage did not occur when GP was expressed in furin-defective LoVo cells but that it was restored in these cells by vector-expressed furin. The Reston subtype, which differs from all other Ebola viruses by its low human pathogenicity, has a reduced cleavability due to a mutation at the cleavage site. As a result of these observations, it should now be considered that proteolytic processing of GP may be an important determinant for the pathogenicity of Ebola virus.

[Immunobiological properties of vp24 protein of Ebola virus expressed by recombinant vaccinia virus]

Immunological and biochemical parameters were studied in guinea pigs immunized with recombinant vaccinia virus containing full-sized gene of Ebola virus vp24 protein and then infected with virulent strain of Ebola virus. The majority of the studied parameters changed similarly in guinea pigs immunized with recombinant vaccinia virus and control guinea pigs inoculated with vaccinia virus both before and after challenge with Ebola virus. However, in animals immunized with recombinant vaccinia virus producing vp24 some biochemical parameters, the mean life span after challenge with Ebola virus, the level of antibodies to the virus, and the phagocytic activity of neutrophils indicated the development of immunological processes other than in controls, namely, the development of immune response to vp24. Although these processes did not eventually lead to the survival of animals, they prolonged the mean life span and resulted in the production of anti-Ebola antibodies, though the level thereof was low. These data demonstrate that recombinant vaccines against Ebola fever are a promising trend of research.

GP mRNA of Ebola virus is edited by the Ebola virus polymerase and by T7 and vaccinia virus polymerases

The glycoprotein gene of Ebola virus contains a translational stop codon in the middle, thus preventing synthesis of full-length glycoprotein. Twenty percent of the mRNA isolated from Ebola virus-infected cells was shown to be edited, containing one additional nontemplate A in a stretch of seven consecutive A residues. Only the edited mRNA species encoded full-length glycoprotein, whereas the exact copies of the viral template coded for a smaller secreted glycoprotein. Expression of the glycoprotein by an in vitro transcription/translation system, by the vaccinia virus/T7 polymerase system, and by recombinant vaccinia virus revealed that full-length glycoprotein was synthesized not only when the edited glycoprotein gene (8A's) was used as a template for T7 and vaccinia virus polymerases, but also when the nonedited (genomic) glycoprotein gene was used. Analysis of mRNA produced by T7 and vaccinia virus polymerase from the 7A's construct revealed that 1-5% contained alterations at the same site that was also edited by the Ebola virus polymerase. Our data indicate that the editing site in the Ebola virus glycoprotein gene is recognized not only by Ebola virus polymerase but also by DNA-dependent RNA polymerases of different origin.

The complete nucleotide sequence of the Popp (1967) strain of Marburg virus: a comparison with the Musoke (1980) strain

The nucleotide sequence of genomic RNA of Marburg virus strain Popp was determined. Strain Popp was isolated in 1967 during the first filoviral outbreak. The virus was purified from blood of infected guinea pigs in which it had been maintained. The length of the determined sequence was 19112 nucleotides. Amino acid sequences of seven known virion proteins were deduced. Nucleotide and amino acid sequences were compared with those of strain Musoke of Marburg virus isolated in 1980 in Kenya and purified from Vero cells. Homology between nucleotide sequences of two strains was 93.9%. Comparisons revealed conserved and variable regions of the nucleotide and amino acid sequences. The GP, the envelope protein of the virion, was found to be the most variable protein. The greatest differences in the protein were located in the supposedly external part of the molecule. Amino acid substitutions in the L protein, the main component of viral RNA-dependent RNA polymerase, were also distributed extremely non-randomly. It was shown that the non-coding regions of the genome were more variable than the coding ones; 37.6% of nucleotide differences corresponded to the former. 72.6% of nucleotide substitutions located in the coding regions were found to be at the third codon position.

Characterisation of morbilliviruses isolated from Lake Baikal seals (Phoca sibirica)

Sequence analysis of the haemagglutinin protein (H) gene of the morbillivirus (PDV-2) isolated from a Siberian seal (Phoca sibirica) during the 1987/1988 epizootic in Lake Baikal revealed that it was most closely related to two recent isolates of canine distemper virus (CDV) from Germany and different from CDV vaccines currently in use in that region. The virus continued to circulate in seals in Lake Baikal after the 1987/1988 epizootic since sera collected from culled seals in the spring of 1992 were positive in morbillivirus ELISA tests, reacting most strongly with the CDV antigen.

[Isolation of purified Ebola virus]

Purified concentrates of Ebola virus were prepared by two methods, adsorption on polyethylenglycol-600 followed by ultracentrifugation in sucrose density gradient and ultrafiltration. The ultrafiltration method permits preparation of concentrated Ebola virus with better preserved virion structure and infective activity than the traditional method.

A comparison of the nucleotide sequences of eastern and western equine encephalomyelitis viruses with those of other alphaviruses and related RNA viruses

The complete nucleotide sequence of a 1982 Florida strain of eastern equine encephalomyelitis (EEE) virus, and partial sequence of the nonstructural protein genes of western equine encephalomyelitis (WEE) virus, were determined. The EEE virus genome was 11,678 nucleotides in length, excluding the cap nucleotide and poly(A) tail, and the nucleotide composition was 28% A, 24% G, 25% C, and 23% U. The organization of both EEE and WEE virus genomes was like that of other alphaviruses and included a termination codon between the nsP3 and nsP4 genes. Codon usage for 10 of 20 amino acids was nonrandom in the EEE genome, and dinucleotide CpG-containing codons were underutilized in both genomes. The slight CpG deficiency was similar to that seen in other alphaviruses and plant viruses in the alphavirus-like group, but less than that of poliovirus and yellow fever virus. This slight deficiency may reflect adaptation for replication in both CpG-deficient vertebrates, as well as insects which do not have CpG-deficient genomes. Phylogenetic analyses using nonstructural protein amino acid sequences indicated that alphaviruses evolved from a common ancestor which existed a few thousand years ago. An intercontinental introduction of an ancestral virus from the Old to New World, or vice versa, probably resulted in two main extant groups: one includes New World (EEE and Venezuelan equine encephalitis) viruses, while the other includes Old World (Sindbis, Middelburg, O'nyong-nyong, Ross River, and Semliki Forest) viruses. The position of WEE virus in the phylogenetic trees indicated that, in addition to its capsid gene (C. S. Hahn et al. (1988) Proc. Natl. Acad. Sci. USA 85, 5997-6001), WEE virus acquired its nonstructural genes from an EEE-like ancestor during recombination.

The GP-protein of Marburg virus contains the region similar to the 'immunosuppressive domain' of oncogenic retrovirus P15E proteins

cDNA was synthesized and cloned on the template of the genomic RNA of Marburg virus (strain Popp). Recombinant plasmids with specific cDNA inserts were selected and sequenced. The length of the open reading frame encoding the GP-protein is 681 amino acids. GP-protein is proposed to be an integral membrane protein. Computer-assisted comparison of the deduced amino acid sequence with those of different viruses revealed significant homology with the GP-protein of Ebola virus and with the 'immunosuppressive domain' of the P15E envelope proteins of some oncogenic retroviruses.

The VP35 and VP40 proteins of filoviruses. Homology between Marburg and Ebola viruses

The fragments of genomic RNA sequences of Marburg (MBG) and Ebola (EBO) viruses are reported. These fragments were found to encode the VP35 and VP40 proteins. The canonic sequences were revealed before and after each open reading frame. It is suggested that these sequences are mRNA extremities and at the same time the regulatory elements for mRNA transcription. Homology between the MBG and EBO proteins was discovered.

The envelope glycoprotein of Ebola virus contains an immunosuppressive-like domain similar to oncogenic retroviruses

Genomic RNA of a Zaire strain of Ebola virus was cloned, and cDNA inserts specific for the glycoprotein gene were isolated and sequenced. The determined sequence has only one open reading frame encoding 318 amino acids and is part of ORF-4 on the plus RNA strand. The putative transcriptional stop site (3' AAUUCUUUUU 5') and the transcriptional start site (3' AACUACUUCUAAUU..5') were identified. Computer-assisted comparison of the amino acid sequence of the C-terminal part of protein encoded by ORF-4 of Ebola virus with sequences of the proteins present in the SWISSPROT and EMBL banks revealed significant homology with the 'immunosuppressive domain' of the p15E envelope proteins of various oncogenic retroviruses. The possible role of such a homology is discussed.

[Complete nucleotide sequence of the Eastern equine encephalomyelitis virus genome]

The complete nucleotide sequence of the genomic 42S RNA of Eastern equine encephalitis virus has been defined for the first time. The strategy of this viral genome occurred analogous to the ones of the other alfa viruses. The comparison of amino acid sequences of E1 and E2 proteins from the two strains of the virus has revealed a number of differences. Partially, they are localized in the hydrophilic regions of the protein molecules and evidently participate in organization of the specific antigenic structures. The amino acid sequences of all viral proteins have been comparatively analysed with the sequences of the analogous proteins of other known alfa viruses.

[Marburg virus: the first determined nucleotide sequence of two genes]

The preparations of purified Marburg virus were isolated from blood plasma of infected guinea pigs and characterized. Viral RNA was extracted from the virions. The cDNA was synthesized on the isolated RNA matrix by the reverse transcriptase with the use of dissipated priming. The obtained cDNA was inserted into the plasmid pBR322 by the connector technique and the resulting recombinant plasmids were cloned in Escherichia coli cells. The specific clones selected by molecular hybridization method were analyzed by the restriction mapping and cross-hybridization. Four overlapping cDNA clones were found and the virus specific 5012 bp fragment of the viral genome was sequenced. Three open reading frames were found and the preliminary analysis of the coded amino acid sequence and corresponding genes was fulfilled.