Use of recombinant nucleocapsid proteins of the Hantaan and nephropathia epidemica serotypes of Hantaviruses as immunodiagnostic antigens

Hantavirus nucleocapsid protein has previously been identified as the major antigen recognized by the humoral immune response in hemorrhagic fever with renal syndrome (HFRS). It was therefore considered to be a suitable antigen for the development of rapid and reliable immunodiagnostic assays. Genes encoding the nucleocapsid proteins of two Hantavirus strains, one of the Puumala serotype [nephropathia epidemica virus (NEV)] and the other of the Hantaan serotype were expressed in E. coli, and the expression products were used as diagnostic antigens in solid-phase enzyme immunoassays. The assays were used to detect IgG- and IgM-antibodies in sera of HFRS patients originating from different geographic regions (China, Germany, Greece, Yugoslavia, Scandinavia). ELISA was highly sensitive and proved to be superior to the indirect immunofluorescence assay. Both antigens were necessary to diagnose all HFRS cases originating from the different countries. Most of the sera revealed a predominant reactivity with either 1 of the 2 antigens, allowing the characterization of the etiologic virus as Hantaan-like or NEV-like. The results of the analysis of sera obtained from China and Greece suggested that the Hantaviruses prevalent in these countries are closely related to the Hantaan serotype. In contrast, an NEV-like reactivity was observed in Central and Northern European patients. In the sera of Yugoslav patients both reactivity patterns were found, suggesting that both virus types occur in the Balkan region.

The genome of equine herpesvirus type 2 harbors an interleukin 10 (IL10)-like gene

A gene was identified within the DNA sequences of the EcoRI DNA fragment N (4.3 kbp) of the genome of equine herpesvirus type 2 (EHV-2) coding for a protein (179 amino acid residues) homologous to the cytokine synthesis inhibitory factor (CSIF; interleukin 10) of the human and mouse, and to the Epstein-Barr virus (EBV) protein BCRF1. This finding is further significant evidence that the interleukin 10 (IL-10) and/or IL-10-like gene can indeed be present in the genomes of members of the herpesviral family.

Determination of the position of the boundaries of the terminal repetitive sequences within the genome of molluscum contagiosum virus type 1 by DNA nucleotide sequence analysis

The repetitive DNA sequences of the genome of Molluscum contagiosum virus type 1 (MCV-1) have been localized within the terminal regions of the viral genome corresponding to the BamHI MCV-1 DNA fragments B (18 kbp; 0 to 0.095 map units (m.u.)) and E (10.5 kbp; 0.944 to 1 m.u.). The fine mapping of these particular regions of the genome of MCV-1 revealed that the boundaries of the terminal repetitive DNA sequences of the viral genome are located within the DNA sequences of the HindIII MCV-1 DNA fragments K (3.8 kbp; 0.014 to 0.036 m.u.) and J1 (4.1 kbp; 0.962 to 0.985 m.u.). The exact position of the boundary of the repetitive DNA sequences was determined by DNA nucleotide sequencing. The HindIII DNA fragments K and J1 compose 3859 and 4107 bp, respectively. The DNA sequences of HindIII MCV-1 DNA fragment K possess repetitive DNA sequences between the nucleotide positions 1 and 1675 which are homologous to the inverted and complementary DNA sequences of the HindIII MCV-1 DNA fragment J1 between the nucleotide positions 2437 and 4107 (1670 bp). The degree of DNA sequence homology detected between the repetitive DNA sequences in the HindIII DNA fragments K and J1 of the viral genome was found to be 98%. The number of open reading frames (ORFs) detected by the analysis of the DNA sequences of the HindIII MCV-1 DNA fragments K and J1 was found to be 14 (70 to 219 amino acid residues) and 11 (70 to 365 amino acid residues), respectively.

Characterization of the third origin of DNA replication of the genome of insect iridescent virus type 6

The structure of the third origin of DNA replication (CIV-ori-M) of the genome (209 kbp) of Chilo iridescent virus (CIV) was determined by DNA nucleotide sequence analysis. The CIV-ori-M is located within the DNA sequences of the EcoRI CIV DNA fragment M (7 kbp; 0.310-0.345 viral map units) between the genome coordinates 0.310 (EcoRI site) and 0.317 (NcoI site). The DNA nucleotide sequence of the EcoRI/NcoI CIV DNA fragment (1601 bp) was determined for identifying the DNA sequence of the corresponding origin of DNA replication. The analysis of the DNA sequences of this region revealed the presence of a 12-mer inverted repeat at nucleotide positions 485-496 and 503-513 (485-AGATATTTGACT-496-TATGT-503-AGTCAAATATCT-513) that are able to form a hairpin-loop structure. A double-stranded DNA fragment was synthesized that corresponds to the nucleotide positions 485-513 that were cloned into the phages M13mp18 and M13mp19, and were screened for their ability to be amplified in CF-124 cell cultures infected with CIV. The successful amplification of the DNA sequence of the CIV-ori-M is strong evidence that this particular region of the CIV genome indeed serves as the origin of DNA replication.

Mutations in the UL53 gene of HSV-1 abolish virus neurovirulence to mice by the intracerebral route of infection

The cell fusion protein, the product of the UL53 gene, is responsible for intracerebral (IC) pathogenicity of HSV-1. Recombinant HSV-1 R15 is apathogenic to mice by the IC route of inoculation, while intratypic recombinants, in which the UL53 gene in R15 was replaced by an analogous sequence from the pathogenic strain R19, regained IC pathogenicity. The nucleotide sequence of the UL53 gene of HSV-1 strains R15 (apathogenic) and R19 (pathogenic) was determined and compared to that of other pathogenic strains. Four mutations were found which are thought to be responsible for the apathogenic phenotype of HSV-1 strain R15. Northern blot hybridization of RNA extracted from BSC-1 cells infected with several HSV-1 strains indicated that all of the virus strains tested expressed equal amounts of UL53 mRNA in infected cell cultures. Demonstration of the expression of UL53 mRNA in brains of mice infected with HSV-1 strains was made possible by the combined use of a rapid method for mRNA extraction (Oligo dT-linked magnetic beads) and a highly sensitive technique for detection of the existence of the UL53-specific mRNA (cDNA synthesis followed by PCR). It was shown that both pathogenic (KOS and P42) and apathogenic (R15) HSV-1 strains expressed the UL53 gene in brains of IC infected mice.

Determination of the coding capacity of the BamHI DNA fragment B of apathogenic Herpes simplex virus type 1 strain HFEM by DNA nucleotide sequence analysis

Herpes simplex virus type 1 (HSV-1) strain HFEM acquired an apathogenic phenotype due to a deletion within the DNA sequences of the BamHI DNA fragment B of the viral genome. In order to investigate the coding strategy of this particular region of the genome of HSV-1 strain HFEM the DNA nucleotide sequence of the BamHI DNA fragment B was determined. This analysis revealed that the BamHI DNA fragment B of HSV-1 strain HFEM comprises 6593 bp, corresponding to the nucleotide positions (np) 113322 to 117088 and np 120643 to 123465 of the genome of HSV-1 strain 17. According to these data the deletion of the genome of HSV-1 strain HFEM occurred between the np 117089 and 120642. The promoter region of the UL56 gene of HSV-1 strain HFEM is a part of the deleted DNA sequences. Therefore, this gene of HSV-1 strain HFEM is affected and cannot be expressed. The first 35 amino acid (AA) residues of the deduced amino acid sequence of the UL56 open reading frame (ORF) were found to be identical to the amino acid sequence of the UL56 genes of HSV-1 strains 17 and F. However, due to a deletion at np 3494 of the BamHI DNA fragment B of HSV-1 strain HFEM the amino acid composition of the predicted UL56 gene of HSV-1 strain HFEM is different from HSV-1 strain 17 between amino acid positions 36 and 233. In addition the deduced amino acid sequence of the IRL (inverted repeat of the long segment) copy of the IE110 gene of HSV-1 strain HFEM was found to be about 342 amino acids shorter than the amino acid sequence of IE110 gene of HSV-1 strain 17 (775 AA). This was based on a point mutation which was detected within the DNA sequences of Exon 3 of this copy of IE110 gene of HSV-1 strain HFEM.

Direct detection of Molluscum contagiosum virus in clinical specimens by in situ hybridization using biotinylated probe

Molluscum contagiosum virus (MCV) is an unclassified poxvirus which has recently become recognized as causing a major sexually transmitted disease. At present no assay is available for specific detection of MCV because the virus cannot be serially propagated in cell culture. Since MCV produces an abortive, limited growth with some cytopathic effect in certain cell lines, we were able to develop an in situ hybridization assay for detection of MCV genome in clinical specimens. Human fetal diploid lung cell monolayers were infected with clinical specimens, and after proper incubation and fixation in paraformaldehyde, hybridization was performed under full stringency conditions with a molecularly cloned biotinylated probe. Only MCV infected cells showed homology to the MCV probe with a purple-brown cytoplasmic staining. Additionally, we have described an in situ hybridization assay for direct detection of MCV genome in formalin-fixed, paraffin-embedded biopsies. Characteristic intracytoplasmic Molluscum bodies (Henderson-Paterson bodies) were detected in stratum spinosum cells of the epidermis. Striking staining similarities have been observed between in situ hybridization and haematoxylin-eosin cytostaining. These procedures are the first successful identification of MCV genome in clinical samples by molecular hybridization, with sensitivity and specificity equal to or greater than electron microscopy.

Identification and mapping of origins of DNA replication within the DNA sequences of the genome of insect iridescent virus type 6

The origins of DNA replication of the genome (209 kbp) of Chilo iridescent virus (CIV), which is circularly permuted and terminally redundant, were identified. The defined genomic library of CIV, which represents 100% of DNA sequences of the viral genome (e.g., all 32 EcoRI CIV DNA fragments), was used for transfection of Choristoneura fumiferana insect cell cultures (CF-124) that were previously infected with CIV. The plasmid rescue experiments were carried out to select those recombinant plasmids that were amplified during viral replication in CIV-infected cell cultures. It was found that six recombinant plasmids harboring the EcoRI DNA fragments C [13.5 kbp, 0.909-0.974 map units (m.u.)], H (9.8 kbp, 0.535-0.582 m.u.), M (7.25 kbp, 0.310-0.345 m.u.), O (6.5 kbp, 0.196-0.228 m.u.), Q (5.9 kbp, 0.603-0.631 m.u.), and Y (2.0 kbp, 0.381-0.391 m.u.) were able to be amplified under the conditions used. This indicates that the CIV genome possesses six DNA replication origins. Subclones of the EcoRI CIV DNA fragments C and H were screened under the same conditions. It was found that DNA sequences within the EcoRI DNA fragments C and H at the genome coordinates 0.924-0.930 and 0.535-0.548, respectively, contain origins of viral DNA replication. The DNA nucleotide sequences of the EcoRI CIV DNA fragment Y (1986 bp) were determined for identifying the DNA sequence of the corresponding origin of DNA replication. The computer-aided analysis revealed the presence of a 15-mer inverted repeat at nucleotide positions 661-675 and 677-691 (661-TAAATTTAATGAGAA-G-TTCTCATTAAATTTA-692). The analysis of the DNA sequence of the EcoRI DNA fragment H corresponding to the particular region at the genome coordinates 0.535-0.548 (1) showed that this region contains a 16-mer inverted repeat at the nucleotide positions 1315 and 1332 (1315-TAAATTTTAATGGTTA-A-TAACCATTAAAATTTA-1347), which is very similar to the inverted repetition found within the EcoRI DNA fragment Y. The successful recognition and amplification of the single-stranded synthetic DNA sequences of both strands of CIV-ori-Y (nucleotide position 661-691) using phage M13 system in CIV-infected cells is strong evidence that the CIV-ori-Y is bidirectionally active, and this DNA sequence is considered to be the origin of DNA replication within the EcoRI CIV DNA fragment Y.

Direct detection of molluscum contagiosum virus in clinical specimens by dot blot hybridization

A dot blot hybridization protocol was developed for the direct detection of molluscum contagiosum virus (MCV) DNA in clinical specimens submitted for virus isolation. Samples were concentrated by high-speed centrifugation and treated with proteinase K; this was followed by a single phenol-chloroform extraction step. The DNA was denatured, and the entire volume was spotted onto a nitrocellulose membrane. A biotinylated DNA probe specific for the BamHI-C region of MCV type 1 was used for hybridization. Evidence of MCV DNA was visualized by using streptavidin alkaline phosphatase conjugate and 5-bromo-4-chloro-3-indolyl phosphate-nitroblue tetrazolium as the substrate. Results showed that nonspecific hybridization does not occur with herpes simplex virus- or orf virus-infected clinical specimens and that dot blotting is more sensitive and reproducible than electron microscopy.

Elimination of UL56 gene by insertion of LacZ cassette between nucleotide position 116030 to 121753 of the herpes simplex virus type 1 genome abrogates intraperitoneal pathogenicity in tree shrews and mice

In order to investigate whether or not the UL56 gene is involved in those processes determining the viral pathogenicity and latency, a recombinant virus HSV-1-M-LacZ was constructed in which the DNA sequences between nucleotide position (np) 116030 and 121753 were replaced by the E. coli beta-galactosidase (LacZ) gene. This deletion spans from the carboxyterminus of UL55 (np 116030) to the second exon of IE110 (np 121753) eliminating UL56 and the variable region of the BamHI DNA fragment B which were implicated in intraperitoneal pathogenicity and latency. The host range and growth kinetics of the recombinant virus HSV-1 M-LacZ were comparable to the parental strain HSV-1 F. As expected it was found that HSV-1-M-LacZ lost its virulent phenotype and was not able to develop acute infection in animals. The state of the UL56 gene was investigated by determining the cDNA sequence of the UL56 gene transcript of HSV-1 F using PCR products obtained after amplification of the cDNA with oligonucleotide primers corresponding to the translational start and stop codons of this gene. This analysis revealed that the DNA sequence of the UL56 gene of HSV-1 F differed from those DNA sequences determined for the genomic DNA of HSV-1 strain 17. Between nucleotide position 116343 and 116344 two nucleotides -AG- are inserted which prolong the ORF of the UL56 gene to 233 amino acids with a predicted molecular weight of 30 kDa.

Primary structure of the large (L) RNA segment of nephropathia epidemica virus strain Hällnäs B1 coding for the viral RNA polymerase

The L RNA segment of the nephropathia epidemica virus (NEV) strain Hällnäs B1 was characterized by molecular cloning of the corresponding cDNA and subsequent determination of the DNA nucleotide sequence. The L RNA segment is 6550 nucleotides long with complementarity of 20 bases at the 3' and 5' termini. The viral messenger sense RNA contains one major open reading frame (ORF) with a coding capacity of 2156 amino acid residues encoding a protein with a calculated molecular weight of 246 kDa and an IEP of pH 7.4. Comparison of the deduced amino acid sequences from NEV hantavirus and Bunyamwera virus (BWV) L segment messenger sense RNAs, revealed a high degree of diversity (overall amino acid identity, 17%). However, three clusters of 30-40% amino acid identity were detected. One of these domains, containing an Asp-Asp motif found in many RNA polymerases, also shares amino acid sequence homology with the PB1 polymerase component of influenza type A. These results indicate that the L RNA segment of the NEV codes for the viral RNA-dependent RNA polymerase. The data presented here complete our previous studies on the characterization of the NEV genome by cDNA sequencing of the viral M and S RNA segments.

The primary structure of the thymidine kinase gene of fish lymphocystis disease virus

The DNA nucleotide sequence of the thymidine kinase (TK) gene of fish lymphocystis disease virus (FLDV) which has been localized between the coordinates 0.678 to 0.688 of the viral genome was determined. The analysis of the DNA nucleotide sequence located between the recognition sites of HindIII (0.669 map unit; nucleotide position 1) and AccI (nucleotide position 2032) revealed the presence of an open reading frame of 954 bp on the lower strand of this region between nucleotide positions 1868 (ATG) and 915 (TAA). It encodes for a protein of 318 amino acid residues. The evolutionary relationships of the TK gene of FLDV to the other known TK genes was investigated using the method of progressive sequence alignment. These analyses revealed a high degree of diversity between the protein sequence of FLDV TK gene and the amino acid composition of other TKs tested. However, significant conservations were detected at several regions of amino acid residues of the FLDV TK protein when compared to the amino acid sequence of TKs of African swine fever virus, fowlpox virus, shope fibroma virus, and vaccinia virus and to the amino acid sequences of the cellular cytoplasmic TK of chicken, mouse, and man.

Identification and characterization of a Hantavirus strain of unknown origin by nucleotide sequence analysis of the cDNA derived from the viral S RNA segment

The genetic characterization of a serologically Hantaan-like virus but of unknown origin (termed DX) was carried out by molecular cloning and nucleotide sequencing of the corresponding cDNA of the viral S RNA segment. The S RNA was found to be 1765 nucleotides long with 3' and 5' termini being complementary for 24 bases. The virus messenger-sense RNA contains one major open reading frame (ORF) encoding 428 amino acids or a 50 kD polypeptide. A comparison of the DX S RNA segment to those of Sapporo rat, Hantaan, Puumala/Hällnäs B1, and Prospect Hill viruses reveals 95.4, 71.3, 55.3, and 60.9% homology at the nucleotide sequence level, and 94.7, 80.1, 58.4, and 59.8% at the deduced amino acid sequence level. Thus Hantavirus strain DX is very closely related to Sapporo rat virus. We also analyzed the S RNA segments of these Hantaviruses for the presence of a second ORF encoding a potential nonstructural NSs protein. All potential second ORFs detected in the different S RNA segments differ substantially in length and position among the viruses, despite the high conservation of the nucleotide sequences and the overall structure of the nucleocapsid proteins. This suggests that the nucleocapsid protein is the only polypeptide encoded by Hantavirus S RNA segments, setting them apart from the other members of the Bunyaviridae family.

In vitro transcription and translation of proteins encoded by the BamHI-B genomic fragment of herpes simplex virus-1

The BamHI-B DNA fragment of herpes simplex virus type-1 (HSV-1) is associated with intraperitoneal pathogenicity. Among the recently mapped RNA transcripts from this fragment (15), one was reported to be associated with latency. To relate the RNA transcripts to virus pathogenicity, the in vitro-transcribed RNAs from BamHI-B fragments of three HSV-1 strains--F (pathogenic), R19, and HFEM (apathogenic), were studied by in vitro translation. When the BamHI-HpaI (0.738-0.755 map units) DNA fragment from HSV-1 strain F was transcribed rightward and translated, three proteins of 70, 63, and 51 kD were detected. The 63 kD protein resembles in size and orientation the protein encoded by the ICP-27 (IE-2) gene (0.740-0.749 mu). The 51 kD polypeptide is assumed to be a prematurely terminated form of this protein. No proteins were obtained from RNA transcribed in the opposite direction. The SalI-NcoI (0.746-0.761 mu) fragment of the three HSV-1 strains yielded two proteins of 25 and approximately 15 kD when transcribed rightward and a 35 kD polypeptide from RNA transcribed in the opposite direction. As a result of the genomic deletion in HFEM, it was possible to obtain the 35 kD protein from the SalI-SalI DNA fragment (0.746-0.761 mu) as well. In vitro transcription and translation of the PstI-SalI (0.778-0.790 mu) DNA fragment (the right-hand side of HpaI-P) did not result in protein synthesis. The possibility that the UL56 gene is connected with the intraperitoneal pathogenicity of HSV-1 is discussed.

Antigenicity of hantavirus nucleocapsid proteins expressed in E. coli

DNA clones representing the small genomic segment of Nephropathia epidemica virus strain Hällnäs B1 (NEV) and Hantaan virus strain 76-118 (HTV) encoding their nucleocapsid proteins were inserted into the E. coli vector pIN-III-ompA for secretion of proteins into the periplasmic space. The complete HTV and NEV nucleocapsid proteins and two truncated versions of the NEV nucleocapsid proteins were expressed as fusion proteins. Unexpectedly, all products accumulated as insoluble aggregates. Most of the ompA signal peptide remained uncleaved. However, nucleocapsid fusion proteins could be purified from the insoluble fraction by extraction with 8 M urea followed by separation on SDS-PAGE and electroelution. Rabbits were immunized with the eluted proteins and the resulting antibodies reacted specifically with authentic viral nucleocapsid proteins of HTV and NEV. The recombinant nucleocapsid proteins were found to react specifically with various hantavirus-immune sera, but not with human control sera, indicating their suitability as potential diagnostic antigens. This is the first report on the expression of a protein of a NEV serotype strain of hantaviruses by use of recombinant DNA techniques.

Stability of molluscum contagiosum virus DNA among 184 patient isolates: evidence for variability of sequences in the terminal inverted repeats

The stability of the Molluscum contagiosum virus Type 1 genome (188 kbp) was studied in 184 DNA isolates from 131 patients. Variability of up to 1.5 kbp at both ends of the genome symmetrically was observed using restriction analysis of the DNA isolates and by Southern Blot experiments using cloned and labeled HindIII terminal DNA fragments of MCV-1 prototype DNA. The variable sequences were mainly confined to the terminal fragments and parts of the MCV-1 terminal repeats. Labeled probes did not detect terminal sequences of MCV Type 2 under the applied stringency. A less marked instability of the central MCV-1 BamHI DNA fragment F was observed within the genome coordinates 0.431 to 0.454 mu. Reiteration of tandem repeats similar to those described for vaccinia virus might explain the variability of the terminal sequences and might be involved in viral replication.

Identification and mapping of the UL56 gene transcript of herpes simplex virus type 1

The herpes simplex virus type 1 (HSV-1) strain HFEM is apathogenic for tree shrews and mice by the intraperitoneal application route. This is due to a 4.1 kbp deletion [0.762 to 0.789 map units (mu)] within the BamHI DNA fragment B of the viral genome. With exception of 71 bp the DNA sequences of the deleted region are located within the repetitive DNA sequences of the inverted repeat of the L segment of the HSV-1 genome (IRL). A 1.5 kb RNA hybridizing to the DNA sequences of the HSV-1 genome at map position 0.760-0.762 (BssHII DNA fragment F, part of the BamHI DNA fragment B) was found to be missing in cells infected with HSV-1 HFEM and other apathogenic HSV-1 strains. A detailed analysis of the transcriptional profile of this region of the pathogenic prototype strain HSV-1 F and strand-specific hybridizations revealed that this 1.5 kb RNA species is transcribed at 2 to 4 h p.i. in leftward orientation. The corresponding open reading frame in the HSV-1 genome had been predicted as the UL56 gene. The absence of this 1.5 kb RNA in HSV-1 HFEM-infected cells is due to the fact that the promoter region of the UL56 gene is located within those DNA sequences which are deleted in the HSV-1 HFEM genome. A specific DNA fragment (650 bp) was amplified by reverse polymerase chain reaction using oligonucleotide primers corresponding to the predicted translational start and termination region of the UL56 gene. The corresponding cDNA had been derived from cellular RNA from HSV-1 F-infected cells using oligo(dT) priming. This indicates that the 1.5 kb RNA is the real transcript of the UL56 gene of HSV-1.

Expression of human immunodeficiency virus type 1 gag gene using genetically engineered herpes simplex virus type 1 recombinants

Infectious herpes simplex virus type 1 (HSV-1) recombinants were constructed by inserting the cDNA sequence of the human immunodeficiency virus type 1 (HIV-1) gag gene (from nucleotide position 675 [SacI] to 3859 [Asp718] of the cDNA sequences of HIV-1 strain BH-10) within the DNA sequences of the BamHI DNA fragment B of the genome of an apathogenic HSV-1 strain HFEM. This HSV-1 strain possesses a 4.1-kbp deletion within the BamHI DNA fragment B between 0.762 and 0.789 map units of the viral genome, which allows the insertion of at least 4 kbp of foreign genetic material into this particular region. The DNA sequences of the immediate early promoter (IE4) of HSV-1 that were inserted upstream from the gag gene were used as a promoter. The screening of 205 virus stocks derived from individual plaques revealed that 46 recombinant viruses harbor HIV-1 gag-specific DNA sequences. However, it was found that only six of the recombinant viruses are able to express the gag gene product of HIV-1. This indicates that the ratio of the positive recombination events is about 2.9%.

Importance of the HpaI-P sequence for herpes simplex virus-1 replication in the adrenal glands

The ability of several strains and recombinants of herpes simplex virus 1 (HSV-1) to proliferate in the adrenal glands and to invade the spinal cord was studied. After intraperitoneal infection, pathogenic HSV-1 strains replicated in the adrenal glands, penetrated the spinal cord and migrated to the brain. The nonpathogenic strain HFEM could not replicate in the adrenal glands, but the recombinant virus MLC1 was able to do so after rescue by reinsertion of the HpaI-P sequence into the BamHI fragment of HFEM DNA. However the recombinant MLC1 virus could not penetrate the spinal cord. The effect of HSV-1 infection on the expression of the cellular genes for multidrug resistance (in the adrenal glands) and proenkephalin A (in the spinal cord) was also studied.

Rapid detection of genomic variations in different strains of hantaviruses by polymerase chain reaction techniques and nucleotide sequence analysis

The polymerase chain reaction (PCR) with subsequent nucleotide sequence analysis was employed to rapidly detect genomic variations among different Hantavirus strains. Using synthetic oligonucleotide primers derived from the M and S segment RNAs of nephropathia epidemica virus strain Hällnäs B1 (NEV) we succeeded in amplifying the corresponding sequences of Hantaan and Puumala viruses. The nucleotide sequences of the cDNAs derived from the Puumala M and S RNA segments were analyzed. It was found that the particular nucleotide sequences of Puumala M and S segments were 81% and 82% homologous to the corresponding genomic segments of NEV, respectively. The amino acid homology was 94% for both segments. In contrast, the degree of homology to the corresponding Hantaan M and S genomic RNA segments was 63% at the nucleotide level for both segments and 53 and 55% at the deduced amino acid level, respectively. This demonstrates that Puumala virus is very similar to NEV and significantly different from Hantaan virus at both the nucleotide and protein level.

Molecular characterization of the RNA S segment of nephropathia epidemica virus strain Hällnäs B1

The S segment RNA of nephropathia epidemica virus (NEV) strain Hällnäs B1 was isolated by molecular cloning of the corresponding cDNA. The RNA is 1785 nucleotides long with the 3' and 5' termini being complementary for 23 bases. The viral messenger-sense RNA contains one major open reading frame (ORF) with a coding capacity of 433 amino acids encoding a 49-kDa polypeptide. Compared to the Hantaan S segment cDNA sequence there is a nucleotide homology of 60 and 61% at the amino acid level. Many of the amino acid differences are conservative exchanges. The C-termini of the NEV and Hantaan nucleocapsid proteins are nearly identical and the hydrophilicity profiles are very similar. In contrast, the following differences are significant: The calculated isoelectric points of the NEV and Hantaan nucleocapsid proteins are 5.6 and 6.7, respectively. The most prominent antigenic determinants predicted by the hydrophilicity profiles are located close to the C-terminus of NEV and close to the N-terminus of Hantaan virus nucleocapsid polypeptides.

Genomic characterization of Molluscum contagiosum virus type 1: identification of the repetitive DNA sequences in the viral genome

The genomes (188 kbp) of the prototype Molluscum contagiosum virus type 1 (MCV-1) and a variant strain (MCV-1v) were characterized by construction of the physical maps of the viral DNA for the restriction enzymes BamHI, ClaI, EcoRI, and HindIII using a defined gene library harboring the DNA sequences of the MCV-1 genome and by DNA-DNA hybridizations. It was found that the genomes of both MCV strains are identical, with the exception of very few changes in the DNA fragmentation patterns of restriction endonuclease BamHI as a consequence of naturally occurring nucleotide exchanges in the genome of the variant strain. Detailed hybridization experiments revealed the existence of repetitive DNA sequences, which are located within the terminal regions of the viral genome at the map coordinates 0 to 0.027 and 0.973 to 1.

Determination of the coding capacity of the M genome segment of nephropathia epidemica virus strain Hällnäs B1 by molecular cloning and nucleotide sequence analysis

The M genome RNA segment of nephropathia epidemica virus (NEV) strain Hällnäs B1 was characterized by molecular cloning and DNA nucleotide sequencing of the corresponding cDNA clones. The size of the M RNA segment is 3682 nucleotides. The 3' and 5' terminal sequences are complementary for 21 bases and their predicted secondary structure is very stable. The viral complementary messenger RNA possesses a single long open reading frame with a coding capacity of 1148 amino acids (polypeptide of 126 kDa). A comparison of the NEV M segment to that of Hantaan virus strain 76-118 reveals 61% sequence homology at the nucleotide level and 53% at the deduced amino acid level. Four out of five potential asparagine-linked glycosylation sites of the encoded glycoproteins have been conserved between NEV and Hantaan M. The isoelectric points (IEP) are nearly identical. Furthermore it was found that 90% of all cysteine residues have been conserved. Putative NEV G1 and G2 are preceded by a short hydrophobic sequence as shown for G1 and G2 of Hantaan virus. Hydrophilicity profiles of the two segments are of striking similarity. These data indicate that NEV- and Hantaan virus M-encoded polypeptides seem to be very similar in structure and function despite the relatively low amino acid sequence homology.

Characterization of the repetitive DNA elements in the genome of fish lymphocystis disease viruses

The complete DNA nucleotide sequence of the repetitive DNA elements in the genome of fish lymphocystis disease virus (FLDV) isolated from two different species (flounder and dab) was determined. The size of these repetitive DNA elements was found to be 1413 bp which corresponds to the DNA sequences of the 5' terminus of the EcoRI DNA fragment B (0.034 to 0.052 m.u.) and to the EcoRI DNA fragment M (0.718 to 0.736 m.u.) of the FLDV genome causing lymphocystis disease in flounder and plaice. The degree of DNA nucleotide homology between both regions was found to be 99%. The repetitive DNA element in the genome of FLDV isolated from other fish species (dab) was identified and is located within the EcoRI DNA fragment B and J of the viral genome. The DNA nucleotide sequence of one duplicate of this repetition (EcoRI DNA fragment J) was determined (1410 bp) and compared to the DNA nucleotide sequences of the repetitive DNA elements of the genome of FLDV isolated from flounder. It was found that the repetitive DNA elements of the genome of FLDV derived from two different fish species are highly conserved and possess a degree of DNA sequence homology of 94%. The DNA sequences of each strand of the individual repetitive element possess one open reading frame.

Characterization of RNA transcripts from herpes simplex virus-1 DNA fragment BamHI-B

Herpes simplex virus type 1 (HSV-1) DNA fragment BamHI-B (0.738-0.809 map units) was recently reported to be associated with the phenotype of intraperitoneal pathogenicity and to encode a latency-associated RNA transcript. Part of this fragment resides within the internal repeat sequence of the long (L) region of the viral genome. In this study, RNA transcripts from BamHI-B were characterized. In addition to immediate-early mRNAs IE-1 and IE-2, eight novel RNA species were found. Three transcripts were mapped in the repeat regions of this fragment and five transcripts in the unique L region of BamHI-B. In addition, transcription activity from these regions was compared in several HSV-1 strains. These included the intraperitoneal virulent F and KOS strains, the avirulent strain HFEM, as well as the HFEM/F intratypic virulent recombinant R-MIC1. Several differences were noted and their possible relevance to virulence is discussed.