Recent advances in molluscum contagiosum virus research

Molluscum contagiosum virus (MCV) and variola virus (VAR) are the only two poxviruses that are specific for man. MCV causes skin tumors in humans and primarily in children and immunocompromised individuals. MCV is unable to replicate in tissue culture cells or animals. Recently, the DNA sequence of the 190 kbp MCV genome was reported by Senkevich et al. MCV was predicted to encode 163 proteins of which 103 were clearly related to those of smallpox virus. In contrast, it was found that MCV lacks 83 genes of VAR, including those involved in the suppression of the host response to infection, nucleotide biosynthesis, and cell proliferation. However, MCV possesses 59 genes predicted to code for novel proteins including MHC-class I, chemokine and glutathione peroxidase homologs not found in other poxviruses. The MCV genomic data allow the investigation of novel host defense mechanisms and provide new possibilities for the development of therapeutics for treatment and prevention of the MCV infection.

A major antigenic domain of hantaviruses is located on the aminoproximal site of the viral nucleocapsid protein

Hantavirus nucleocapsid protein has recently been shown to be an immunodominant antigen in hemorrhagic with renal syndrome (HFRS) inducing an early and long-lasting immune response. Recombinant proteins representing various regions of the nucleocapsid proteins as well as segments of the G1 and the G2 glycoproteins of hantavirus strains CG18-20 (Puumala serotype) and Hantaan 76-118 have been expressed in E. coli. The antigenicity of these proteins was tested in enzyme immunoassays and immunoblots. These studies revealed that human IgG immune response is primarily directed against epitopes located within the amino acid residues 1 to 119 of the amino terminus of viral nucleocapsid proteins. This fragment was recognized by all HFRS patient sera tested (n = 128). The corresponding enzyme immunoassays proved to be more sensitive than the indirect immunofluorescence assays. Furthermore, the majority of bank vole monoclonal antibodies raised against Puumala virus reacted specifically with this site. A recombinant G1 protein (aa 59 to 401) derived from the CG 18-20 strain was recognized by 19 out of 20 sera from HFRS patients.

Genome sequence of a human tumorigenic poxvirus: prediction of specific host response-evasion genes

Molluscum contagiosum virus (MCV) commonly causes asymptomatic cutaneous neoplasms in children and sexually active adults as well as persistent opportunistic acquired immunodeficiency syndrome (AIDS)-associated disease. Sequencing the 190-kilobase pair genome of MCV has now revealed that the virus potentially encodes 163 proteins, of which 103 have homologs in the smallpox virus. MCV lacks counterparts to 83 genes of the smallpox virus, including those important in suppression of host responses to infection, nucleotide biosynthesis, and cell proliferation. MCV possesses 59 genes that are predicted to encode previously uncharacterized proteins, including major histocompatibility complex class I, chemokine, and glutathione peroxidase homologs, which suggests that there are MCV-specific strategies for coexistence with the human host.

Conservation of DNA sequence in the predicted major late promoter regions of selected mastadenoviruses

The major late promoter (MLP) of the subgroup C human adenoviruses is a preeminent model for the study of the mechanisms of basal and activated transcription, both in vivo and in vitro. However, while the structure and function of the human virus MLP has been the subject of extensive investigation, the conservation of the various promoter elements among the adenoviruses from different species has not been examined. Conservation of specific elements would strongly suggest the importance and universality of their function. To address this issue, sequences were obtained from cloned DNAs of several representative Mastadenoviridae, mouse adenovirus type 1 (MAV-1), Tupaia adenovirus type 1 (TAV-1), and two bovine adenoviruses of two distinct subgroups, BAV-3 and BAV-7. The results of the sequencing studies showed that the TATA box and an upstream inverted CAAT box are conserved in all species and that the binding site for transcription factor USF is present in all except MAV-1, in which a sequence similar to an Sp1-binding site is present at a similar position. The initiator element (INR) sequence is not well conserved, and only one or other of the two downstream activating elements, DE1 and DE2, is predicted to be present in the nonprimate virus MLP regions. Ribonuclease protection assays on RNA isolated from MAV-1-infected cells late in infection indicated that the predicted MLP is functional, and transcription initiation and splice donor sites were identified. The human virus MLP is embedded in the essential DNA polymerase sequence on the opposite DNA strand. The primary amino acid sequences of the C-terminal regions of the predicted DNA polymerases show strong conservation of sequence motifs observed in replicative polymerases ranging from prokaryotes to mammals, and additional regions of strong conservation among the adenovirus polymerases. Pairwise comparisons between the newly sequenced regions of the polymerases and previously published sequences show that BAV-7 is most dissimilar to all others, while TAV-1 has a greater similarity to the primate sequences than to the others. The sequence data from both strands were also used to construct phylogenetic trees, based on BAV-7 as the outgroup. The trees constructed from the two sets of sequences are broadly similar, showing close relationships between primate viruses, but differing in the order of divergence of TAV-1 and MAV-1 branches.

Identification of the gene encoding the DNA (cytosine-5) methyltransferase of lymphocystis disease virus

The gene encoding the DNA (cytosine-5) methyltransferase (m5C-MTase) of lymphocystis disease virus (flounder isolate, LCDV-1) has been identified by polymerase chain reaction (PCR) using oligonucleotide primers synthesized corresponding to different regions of the m5C-MTase gene of frog virus 3 (FV3). A DNA fragment of 487 bp was amplified using oligonucleotide primers L3 and R4 which correspond to the nucleotide positions 87 to 109 and 530 to 550 of the m5C-MTase gene of FV3, respectively. The DNA nucleotide sequence of the PCR product was determined by direct cycle sequencing. The alignment of the deduced amino acid sequence derived from the PCR product and the m5C-MTase protein of FV3 revealed a homology of 55.4% identity and 29.1% similarity. The amino acid sequence which was found to be significantly homologous to the amino acid sequence deduced from the nucleotide sequence of the PCR product was located at the amino acid position 37 to 175 of the m5C-MTase of FV3 indicating the specificity of the amplified PCR product. The DNA nucleotide sequence of the LCDV-1 genome corresponding to the 5' and 3' termini of the m5C-MTase gene was determined by primer walking. The locus of the m5C-MTase gene of LCDV-1 was identified within the EcoRI DNA fragment G of LCDV-1 (7.9 kbp; 0.947 to 0.034 map units). The m5C-MTase gene of LCDV-1 comprises 684 nucleotides coding for a putative protein of 228 amino acid residues. A high degree of amino acid sequence homology (53.3% identity and 25.8% similarity) was detected between the m5C-MTase of LCDV-1 and FV3.

Strategy for identifying the gene encoding the DNA polymerase of molluscum contagiosum virus type 1

Molluscum contagiosum virus (MCV) is a member of the family Poxviridae and pathogenic to humans. MCV causes benign epidermal tumors mainly in children and young adults and is a common pathogen in immunecompromised individuals. The viral DNA polymerase is the essential enzyme involved in the replication of the genome of DNA viruses. The identification and characterization of the gene encoding the DNA polymerase of molluscum contagiosum virus type 1 (MCV-1) was carried out by PCR technology and nucleotide sequence analysis. Computer-aided analysis of known amino acid sequences of DNA polymerases from two members of the poxvirus family revealed a high amino acid sequence homology of about 49.7% as detected between the DNA polymerases of vaccinia virus (genus Orthopoxvirus) and fowlpoxvirus (genus Avipoxvirus). Specific oligonucleotide primers were designed and synthesized according to the distinct conserved regions of amino acid sequences of the DNA polymerases in which the codon usage of the MCV-1 genome was considered. Using this technology a 228 bp DNA fragment was amplified and used as hybridization probe for identifying the corresponding gene of the MCV-1 genome. It was found that the PCR product was able to hybridize to the BamHI MCV-1 DNA fragment G (9.2 kbp, 0.284 to 0.332 map units). The nucleotide sequence of this particular region of the MCV-1 genome (7267 bp) between map coordinates 0.284 and 0.315 was determined. The analysis of the DNA sequences revealed the presence of 22 open reading frames (ORFs-1 to -22). ORF-13 (3012 bp; nucleotide positions 6624 to 3612) codes for a putative protein of a predicted size of 115 kDa (1004 aa) which shows 40.1% identity and 35% similarity to the amino acid sequences of the DNA polymerases of vaccinia, variola, and fowlpoxvirus. In addition significant homologies (30% to 55%) were found between the amino acid sequences of the ORFs 3, -5, -9, and -14 and the amino acid sequences of the E6R, E8R, E10R, and a 7.3 kDa protein of vaccinia and variola virus, respectively. Comparative analysis of the genomic positions of the loci of the detected viral genes including the DNA polymerases of MCV-1, vaccinia, and variola virus revealed a similar gene organization and arrangement.

Restitution of the UL56 gene expression of HSV-1 HFEM led to restoration of virulent phenotype; deletion of the amino acids 217 to 234 of the UL56 protein abrogates the virulent phenotype

Recently it was shown that the avirulent phenotype of HSV-1 strain HFEM is correlated to the lack of DNA sequences of the promoter region of the UL56 gene. In order to investigate the role of the UL56 gene of HSV-1 in the process of viral pathogenicity in more detail, a complete copy of the UL56 gene of the virulent HSV-1 strain 17 was inserted within the DNA sequences of the incomplete UL56 gene of the genome of HSV-1 strain HFEM. The UL56 gene of HSV-1 strain 17 comprises 1428 bp corresponding to the nucleotide positions (NP) 11,5967-117,395 of the genome of HSV-1 strain 17 (SacII-DNA fragment) containing the promoter region and the entire UL56 gene with identical transcription termination signals. This particular DNA fragment was inserted into the corresponding region of the genome of HSV-1 strain HFEM by co-transfection experiments in which the beta-galactosidase gene served as reporter gene. Those recombinant viruses with the ability to express the UL56 gene were tested for their pathogenicity in vivo. The results of these experiments indicate that the restoration of the viral UL56 gene expression led to the restitution of the virulent phenotype of HSV-1 strain HFEM. The UL56 protein which has been shown to be a component of the virion possesses several characteristic signatures e.g. a hydrophobic domain at the carboxy-terminus between amino acid residues 217 and 234 (VFGVVAIVVVIILVFLWR). In order to investigate the role of this particular signature of the UL56 protein in the process of viral pathogenicity, site-specific mutagenesis was performed for removing the carboxy-terminus of the UL56 protein. The deleted region of the DNA sequences of the UL56 gene between NP 1122-1175 corresponds to NP 116 220-116 373 of the viral genome. The DNA sequences of the UL56 gene of virulent HSV-1 strain 17 and F were replaced by DNA sequences of the truncated UL56 gene by co-transfection experiments in which the beta-galactosidase gene served as a reporter gene. Those recombinant viruses with the ability to express the truncated UL56 gene were examined for their pathogenicity in vivo. The analysis revealed that the expression of the truncated UL56 protein (without hydrophobic domain 217-234 aa) was not sufficient for the maintenance of the virulent phenotype of HSV-1 strains.

Coding strategy of the S and M genomic segments of a hantavirus representing a new subtype of the Puumala serotype

The hantavirus strain Vranica was previously reported to have been isolated from a bank vole in Bosnia-Hercegovina and associated with the occurrence of hemorrhagic fever with renal syndrome (HRFS) in humans. The complete cDNA nucleotide sequences of the small (S) and medium (M) genomic RNA segments of this virus were determined. Major open reading frames were found in the S and M segment between nucleotide positions 43 and 1341 coding for a polypeptide of 433 amino acid residues and between nucleotide positions 41 and 3,484 coding for 1,148 amino acid residues, respectively. The analysis and the alignment of the nucleotide and the derived amino acid sequences with known sequences of other hantavirus strains demonstrate that Vranica resembles Swedish strains and represents a new virus subtype of the Puumala serotype distinct from the subtypes represented by virus strains CG18-20 and Sotkamo.

Identification and properties of the genes encoding the poly(A) polymerase and a small (22 kDa) and the largest subunit (147 kDa) of the DNA-dependent RNA polymerase of molluscum contagiosum virus

The DNA-dependent RNA polymerase (DdRP) is an essential enzyme for transcription of molluscum contagiosum virus (MCV), a member of the family Poxviridae which replicates in the cytoplasm of the infected cell. Using PCR technology and oligonucleotide primers, corresponding to two conserved domains (RQP[T/S]LH and NADFDGDE) of known largest subunits of eucaryotic and procaryotic DNA-dependent RNA polymerases, the DdRP gene of the genome of molluscum contagiosum virus type 1 (MCV-1) was identified and characterized. The oligonucleotide primers were designed according to the coding usage statistics of known open reading frames of the viral genome. The gene for the largest subunit of DdRP was localized within the DNA sequences of a part of the BamHI DNA fragment A (BamHI/HindIII DNA fragment A8a; 13.5 kbp, 0.454 to 0.525 viral map units) of the MCV-1 genome. The DNA nucleotide sequence analysis of a part (6709 bp) of this DNA fragment revealed the presence of 12 open reading frames (ORFs). It was found that ORF-4 (nucleotide position (NP) 2586 to 6452) and ORF-1 (NP 1192 to 1752) encode two polypeptides comprising 1289 (147 kDa) and 187 (22 kDa) amino acid residues, respectively. The comparative analysis of the amino acid sequences of these ORFs to the amino acid sequences of two subunits (RPO1, 147 kDa and RPO6, 22 kDa) of the DdRP of vaccinia virus revealed high amino acid sequence identity/similarity of about 71.9/21.5% and 46.5/39.6%, respectively. In addition it was found that the putative gene position of ORF-11, which is located on the lower strand between the loci of the ORF-1 and ORF-4 (NP 4256 to 4657, 134 aa, 15 kDa), is similar to the genomic arrangement of the J5L protein of vaccinia virus and L5L of variola virus. The value of amino acid sequence identity/similarity between the product of ORF-11 and the corresponding gene of vaccinia virus (J5L) was found to be 43.2/28.8%. The analysis of the amino acid sequence deduced from ORF-3 (NP 261 to 1289, 343 aa, 40 kDa), which is located upstream from the locus of the RPO6 of the MCV-1 genome, showed significant identity/similarity (47.5/35.7%) to the amino acid sequence of the 40-kDa subunit of the poly(A) polymerase (PAP2) of vaccinia virus. The arrangement of the identified loci of the PAP2, RPO6, ORF-11, and RPO1 of the genome of MCV-1 shows that this particular genomic region of the mollucsum contagiosum virus and vaccina virus is colinear.

Evolution of viral DNA-dependent RNA polymerases

The DNA-dependent RNA polymerase (DdRP or RNAP) is an essential enzyme of transcription of replicating systems of prokaryotic and eukaryotic organisms as well as cytoplasmic DNA viruses. DdRPs are complex multisubunit enzymes consisting of 8-14 subunits, including two large subunits and several smaller polypeptides (small subunits). An extensive search between the amino acid sequences of the known largest subunit of DNA-dependent RNA polymerases (RPO1) of different organisms indicates that all these polypeptides possess a universal heptapeptide NADFDGD in domain D. All RPO1 harbor a second well-conserved hexapeptide RQP(TS)LH upstream (26-31 amino acids) of the universal motif. The genes encoding the largest subunit of DdRP of insect iridescent virus type 6 (IIV6), fish lymphocystis disease virus (LCDV), and molluscum contagiosum virus (MCV-1), all members of the group of cytoplasmic DNA viruses, were identified by PCR technology. With the exception of IIV6, all other viral RPO1 possess the two C-terminal conserved regions G and H. The lack of C-terminal repetitive heptapeptide (YSPTSPS), which is a common feature of the largest subunit of eukaryotic RNAPII, is an additional characteristic of RPO1 proteins of LCDV and of MCV-1. All viral RPO1 proteins were found to be lacking the amino acid N at a distinct position in domain F. This amino acid is known to be highly conserved in alpha-amanitin-sensitive eukaryotic RNA polymerases II. Comparison of the amino acid sequences of the RPO1 polypeptides of IIV6, LCDV, and MCV-1 with the corresponding prokaryotic, eukaryotic, and viral proteins revealed differences in amino acid similarity and phylogenetic relationships. IIV6 RPO1 possesses the closest similarity to the homologous subunit of eukaryotic RNAPII and lower but also significant similarity to that of eukaryotic RNAPI and RNAPIII, archaeal, eubacterial, and viral polymerases. The similarity between RPO1 of IIV6 and the cellular polymerase subunits is consistently higher than to the RPO1 of other cytoplasmic DNA viruses, for example, vaccinia and variola virus, African swine fever virus (ASFV), and MCV-1. The RPO1 of LCDV shows the highest similarity to the RPO1 of IIV6 and significant lower similarity to the eukaryotic polymerases II and III as well as to the archaebacteral subunit. However, it is still considerably more similar to the cellular polymerase subunits than to the homologous viral proteins. The RPO1 of IIV6 possesses more similarity to cellular polymerases than the complete RPO1 of LCDV, indicating that there is a substantial difference in the organization of the RPO1 genes between these members of two genera of the Iridoviridae family. Analysis of the MCV-1 RPO1 revealed high amino acid homologies to the corresponding polypeptides of vaccinia and variola virus. The viral RPO1 proteins, including vaccinia and variola virus, MCV-1, ASFV, IIV6, and LCDV, share the common feature of showing the highest similarity to the largest subunit of eukaryotic RNAPII than to that of RNAPI, RNAPIII, and RPO1 of archaebacterias, eubacterias, ASFV, IIV6, and LCDV. Evolution of the individual largest subunit of DdRPs was tentatively investigated by generating phylogenetic trees using multiple amino acid alignments. These indicate that the RPO1 proteins of IIV6 and LCDV might have evolved from the largest subunit of eukaryotic RNAPII after divergence from the homologous subunits of RNAPI and RNAPIII. In contrast, evolutionary development of the RPO1 of vaccinia and variola virus, MCV-1, and ASFV seems to be quite different, with their common ancestor diverging from cellular homologues before the separation of the three types of eukaryotic ploymerases and having probably diverged earlier from their common lineage with cellular proteins.

Identification and properties of the largest subunit of the DNA-dependent RNA polymerase of fish lymphocystis disease virus: dramatic difference in the domain organization in the family Iridoviridae

Cytoplasmic DNA viruses encode a DNA-dependent RNA polymerase (DdRP) that is essential for transcription of viral genes. The amino acid sequences of the known largest subunits of DdRPs from different species contain highly conserved regions. Oligonucleotide primers, deduced from two conserved domains (RQP[T/S]LH and NADFDGDE) were used for detecting the corresponding gene of fish lymphocystis disease virus (FLCDV), a member of the family Iridoviridae, which replicates in the cytoplasm of infected cells of flatfish. The gene coding for the largest subunit of the DdRP was identified using a PCR-derived probe. The screening of the complete EcoRI gene library of the viral genome led to the identification of the gene locus of the largest subunit of the DdRP within the EcoRI DNA fragment B (12.4 kbp, 0.034 to 0.165 map units). The nucleotide sequence of a part (8334 bp) of the EcoRI DNA fragment B was determined and a large ORF on the lower strand (ATG = 5787; TAA = 2190) was detected which encodes a protein of 1199 amino acids. Comparison of the amino acid sequences of the largest subunits of the DdRP (RPO1) of FLCDV and Chilo iridescent virus (CIV) revealed a dramatic difference in their domain organization. Unlike the 1051 aa RPO1 of CIV, which lacks the C-terminal domain conserved in eukaryotic, eubacterial and other viral RNA polymerases, the 1199 aa RPO1 of FLCDV is fully collinear with its cellular and viral homologues. Despite this difference, comparative analysis of the amino acid sequences of viral and cellular RNA polymerases suggests a common origin for the largest RNA polymerase subunits of FLCDV and CIV.

Immunosuppression of mice by cyclophosphamide (CyP) and cyclosporin A (CsA) changes the course of HSV-1 infection and the distribution of viral DNA in target organs

The effects of the immunosuppressive drugs cyclophosphamide (CyP), cyclosporin A (CsA) and the Langerhans cells immunomodulator OK-432, a bacterial cell wall preparation, on herpes simplex virus type-1 (HSV-1) infection in mice were studied. An increased mortality of HSV-1-infected mice was observed following intraperitoneal injection of both the pathogenic HSV-1 (Justin) and the apathogenic UL56-deleted HSV-1-M-LacZ strains. Intraperitoneal injection of CyP prior to infection with HSV-1 increased the susceptibility to infection of normally resistant mouse strains, including the inbred strain C57BL/6 and the outbred Sabra strain, with the virus reaching the pancreas, the spinal cord and the spleen. Polymerase chain reaction (PCR) to detect viral DNA in mouse organs following IP HSV-1 injection after treatment with CyP and/or OK-432 showed that CyP treatment prevented the virus from reaching the pancreas, while a combination treatment of both chemicals allowed HSV-1 to reach the pancreas. These studies indicate that treatment of mice with immunosuppressive drugs (CyP and CsA), which affect dendritic cells and T cells, prevents the migration of HSV-1 to the pancreas, while the immunomodulator OK-432, which induces dendritic cell activity, did not prevent virus migration to the pancreas. Lung samples were consistently positive for viral DNA following treatment with either CyP or CsA. PCR to detect viral DNA in mice injected with HSV-1 via the footpad route following pretreatment with CyP and OK-432 also through the footpad revealed the presence of HSV-1 DNA in the spinal cord on days 1, 3, and 5 post-infection.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular characterization and determination of the coding capacity of the genome of equine herpesvirus type 2 between the genome coordinates 0.235 and 0.258 (the EcoRI DNA fragment N; 4.2 kbp)

The complete DNA nucleotide sequence of the EcoRI DNA fragment N (0.235 to 0.258 viral map units) of equine herpes virus type 2 (EHV-2) strain T400/3 was determined. This DNA fragment comprises 4237 bp with a base composition of 55.23% G+C and 44.77% A+T. Nineteen open reading frames (ORFs) of 50-287 amino acid (aa) residues were detected. ORF number 10 is located between the nucleotide position 2220 and 2756 coding for a protein of 179 amino acid residues. This protein shows significant homology to the cytokine synthesis inhibitory factor (CSIF; interleukin 10) of human (76.4%) and mouse (68.5%), and to the Epstein-Barr virus (EBV) protein BCRF1 (70.6%). The existence of an interleukin 10 (IL-10) analogous gene within the genome of the EHV-2 was confirmed by screening the genome of nine EHV-2 strains using specific oligonucleotide primers corresponding to the 5' and 3' region of this particular gene by polymerase chain reaction. In all experiments an 870 bp DNA product was amplified. The specifity of the amplified DNA fragments obtained from individual EHV-2 strains was confirmed by DNA-DNA hybridization experiments. The DNA sequence analysis of the amplified DNA products of the EHV-2 strain LK was carried out. This analysis revealed the identity of the corresponding IL-10 gene (540 bp) of this strain to the IL-10 gene of EHV-2 strain T400/3. The presented data indicate that the EHV-2 genome harbors a viral interleukin 10-like gene. This is further evidence that the IL-10 gene can be present in the genomes of members of the Herpesviridae family.

In vitro expression of UL56 gene of herpes simplex virus type 1; detection of UL56 gene product in infected cells and in virions

In order to investigate the functional properties of the UL56 gene of herpes simplex virus type 1 (HSV-1), it was necessary to express the UL56 protein in vitro. The DNA sequences corresponding to the open reading frame of the UL56 gene of HSV-1 strain F were amplified from genomic viral DNA by PCR using primers corresponding to the translational start and termination regions of the UL56 ORF. The PCR product (705 bp) was inserted into the EcoRI/XbaI recognition sites of the bacterial expression vector pMal-c2. This procedure allowed the expression of the viral UL56 gene fused to the maltose-binding protein (MBP) of Escherichia coli, and subsequent cleavage of the fusion protein with the specific protease factor Xa. The induced fusion protein was purified by affinity chromatography using amylose columns. The apparent molecular weight of the fusion protein was about 70 kDa. Factor Xa cleaves the fusion protein into two subfragments of 42 kDa (MBP) and 30 kDa (UL56). Rabbit antisera induced against recombinant UL56 protein were used for detection of the UL56 gene product during the infection cycles of HSV-1. The presence of the UL56 protein was detected in infected cells and in HSV-1 virions by Western blot experiments and by immunofluorescence assays. A strong and increasing cytoplasmic fluorescence was observed in RC-37 cells infected with HSV-1 strain F between 6 and 16 h post-infection. In addition it was found that human HSV-1 IgM/IgG positive convalescent sera recognized the recombinant UL56 protein.

Insect iridescent virus type 6 encodes a polypeptide related to the largest subunit of eukaryotic RNA polymerase II

Cytoplasmic DNA viruses encode a DNA-dependent RNA polymerase (DdRP) that is essential for transcription of viral genes. The amino acid sequences of known large subunits of DdRPs contain highly conserved regions. Oligonucleotide primers, deduced from two conserved domains [RQP(T/S)LH and NADFDGDE] were used in PCR experiments for the detection of the corresponding gene of the genome of insect iridescent virus type 6, also known as Chilo iridescent virus (CIV). A specific DNA product of about 150 bp could be amplified and was used as a hybridization probe against the CIV gene library to identify the corresponding gene. The gene encoding the DdRP was identified within the EcoRI fragments M (7099 bp) and L (7400 bp) of CIV DNA, between map units 0.310 and 0.347 (7990 bp). The DNA nucleotide sequence (3153 bp) of the gene encoding the largest subunit of DdRP (RPO1) was determined. Northern blot hybridization revealed the presence of a 3.4 kb RNA transcript in CIV-infected cells that hybridized to the CIV DdRP gene. This predicted viral protein consists of 1051 amino acid residues (120K) and showed considerably higher similarity to the largest subunit of eukaryotic RNA polymerase II than to the homologous proteins of vaccinia virus and African swine fever virus. Phylogenetic analysis suggested that the putative RPO1 of CIV could have evolved from RNA polymerase II after the divergence of the three types of eukaryotic RNA polymerases. The putative RPO1 of CIV lacked the C-terminal domain that is conserved in eukaryotic, eubacterial and other viral RNA polymerases and in this respect was analogous to the RNA polymerases of Archaea. It is hypothesized that the equivalent of the C-terminal domain may reside in another subunit of CIV DdRP encoded by an unidentified viral gene.

Chilo iridescent virus encodes a putative helicase belonging to a distinct family within the "DEAD/H" superfamily: implications for the evolution of large DNA viruses

The complete nucleotide sequence of the EcoRI DNA fragment M (7099 bp; 0.310-0.345 map units) of the genome of insect iridescent virus type 6--Chilo iridescent virus (CIV)--was determined. A 606 codon open reading frame located in this region encoded a protein (p69) related to a distinct family of putative DNA and/or RNA helicases belonging to the "DEAD/H" superfamily. Unique sequence signatures were derived that allowed selective retrieval of the putative helicases of the new family from amino acid sequence databases. The family includes yeast, Drosophila, mammalian, and bacterial proteins involved in transcription regulation and in repair of damaged DNA. It is hypothesized that p69 of CIV may be a DNA or RNA helicase possibly involved in viral transcription. A distant relationship was observed to exist between this family of helicases and another group of proteins that consists of putative helicases of poxviruses, African swine fever virus, and yeast mitochondrial plasmids. It is shown that p69 of CIV is much more closely related to cellular helicases than any of the other known viral helicases. Phylogenetic analysis suggested an independent origin for the p69 gene and the genes encoding other viral helicases.

Herpes simplex virus type 1 (HSV-1) UL56 gene is involved in viral intraperitoneal pathogenicity to immunocompetent mice

A comparison of the pathogenicity in mice of the recombinant herpes simplex virus type 1 (HSV-1) strain HSV-1-M-LacZ, in which the UL56 gene has been deleted, was made with its parental strain F, following infection in different mouse strains. The polymerase chain reaction (PCR) technique was used to study the migration of virus DNA in the mouse model. Tissues from adult mice infected intraperitoneally (IP) with one of three HSV-1 strains (F, HFEM or HSV-1-LacZ) were examined for the presence of viral DNA. DNA of the pathogenic strain F was detected in the adrenal glands, spinal cord, brain, liver and pancreas. DNA of HSV-1-M-LacZ was detected in the same tissues. However, DNA of the apathogenic strain HFEM was detected transiently (on days 2 and 3 p.i., but not days 1, 5 or 7), only in the adrenal glands and no viral DNA was detected in any of the other tissues. HSV-1 pathogenic strains injected intraperitoneally into newborn mice (7 days old) killed most of the mice. In the surviving mice viral DNA of the three virus strains was found in peritoneal exudate cells (PEC), adrenal glands, spinal cord, liver and spleen. It was found that HSV-1-M-LacZ, which lacks the UL56 gene, resembled in pathogenicity to the newborn mice the pathogenic HSV-1 strains F and KOS. The PCR technique was used to trace viral DNA in tissues of the mice which survived HSV-1 infection at 7 weeks of age. Only HSV-1 (KOS) DNA was detected in the pancreas. The brains of these mice did not contain viral DNA. It is suggested that HSV-1 DNA may reside in surviving HSV-1- infected newborn mice in a "latent" state in nonneural tissues.

Baculovirus expression of the nucleocapsid protein of a Puumala serotype Hantavirus

Recombinant baculoviruses were generated harboring the entire coding region of the S segment cDNA of Hantavirus strain CG 18-20 that belongs to the Puumala serotype. The recombinant nucleocapsid protein was expressed in Sf9 cells and shown to be antigenically identical with the authentic viral nucleocapsid protein by means of immunoblot analysis. Acute-phase and convalescent sera from European HFRS patients recognized the recombinant nucleocapsid protein in Western blots and the recombinant Baculovirus in indirect immunofluorescence assays. Insect cells infected with the recombinant Baculoviruses proved to be a suitable noninfectious substitute for Hantavirus-infected Vero E6 cells as an antigen source for immunodiagnostic assays allowing the detection of antibodies in HFRS patients.

Identification of the gene encoding the major capsid protein of fish lymphocystis disease virus

The gene encoding the major capsid protein (MCP) of fish lymphocystis disease virus (flounder isolate; FLCDV-f) has been identified by PCR using oligonucleotide primers corresponding to different regions of the MCP of Tipula iridescent virus (TIV), iridescent virus 22 (IV22) and Chilo iridescent virus (CIV). DNA fragments of 0.4 kbp, 0.5 kbp and 0.27 kbp in size were amplified using oligonucleotide primers corresponding to amino acids (aa) 146 to 153 (primer 1) and 274 to 268 (primer 6), or aa 146 to 153 (primer 1) and 313 to 304 (primer 8), or aa 304 to 312 (primer 7) and 385 to 381 (primer 9) of the MCP of TIV, respectively. The PCR products were used as hybridization probes for screening the gene library of FLCDV-f. The MCP gene of FLCDV-f(1377 bp; 459 aa; 51.4K) was identified within the DNA sequence of the EcoRI FLCDV-f DNA fragment C (11.2 kbp; 0.611 to 0.718 map units). A high degree of aa sequence identity/similarity was detected between the MCP of FLCDV-f and TIV (50.3%/33.8%), IV22 (49.1%/34.2%). CIV (53%/29.5%) and African swine fever virus (16%/38.1%).

[Recent information about the etiopathogenesis of paretic-paralytic forms of herpesvirus infection in horses]

From spring 1990 to summer 1991 we investigated 21 horses with clinical symptoms of EHV-infection by means of serological and virological methods including DNA-hybridization to identify the causative agents. The results indicated that, as already reported by us, EHV4 may also cause the paralytic form of the infection. The possibility of double infection with EHV4 and EHV1 cannot be excluded. In 3 out of 21 affected horses we could investigate brain tissue and/or spinal fluid by Dotblot hybridization with EHV1 and EHV4-DNA. The investigated samples of all three horses showed hybridization with EHV4-DNA, without or with less pronounced reaction with EHV1-DNA. The results were confirmed by serological investigation. Brain tissue and cerebrospinal fluid from two horses with paretic or paralytic disorders (1979 and 1980) was also investigated by DNA hybridization. In the liquor of one horse--a 5-month-old foal with neonatal ataxia--we detected EHV1-DNA. The other horse showed a strong reaction with EHV1 and a weaker reaction with EHV4 in its brain material and no hybridisation in the cerebrospinal fluid. The results are discussed.

A novel mu-capture enzyme-linked immunosorbent assay based on recombinant proteins for sensitive and specific diagnosis of hemorrhagic fever with renal syndrome

Hantavirus nucleocapsid protein has recently been identified as a major antigen inducing an early and long-lasting humoral immune response in patients with hemorrhagic fever with renal syndrome. A mu-capture enzyme-linked immunosorbent assay utilizing recombinant nucleocapsid proteins of Hantavirus strains Hantaan 76-118 (Hantaan serotype) and CG 18-20 (Puumala serotype) as diagnostic antigens and specific monoclonal antibodies as the detection system has been developed. Histidine-tailed recombinant proteins were expressed in Escherichia coli and purified in a single step by affinity chromatography on a nickel-chelate resin. The assay was evaluated with a panel of sera from patients with hemorrhagic fever with renal syndrome originating from various geographic regions. The overall sensitivity of the mu-capture enzyme-linked immunosorbent assay (both recombinant antigens) was 100%, and its specificity was also found to be 100%. Immunoglobulin M antibodies were detected as early as on day 3, and maximum titers were obtained between days 8 and 25 after onset of the disease. The assay was regularly found to be positive within 3 to 4 months but in some cases up to 2 years after the acute phase of the disease.

RNA binding of recombinant nucleocapsid proteins of hantaviruses

Genes encoding the nucleocapsid (N) proteins of two hantaviruses, Hantaan virus strain 76-118 (HTN) and Puumala virus strain CG 18-20 (PUU), were expressed in Escherichia coli as histidine-tagged proteins. They were purified by metal-chelate affinity chromatography under native or denaturing conditions to near homogeneity. The soluble form of HTN N protein was associated with RNA of E. coli. Renatured N proteins were shown to bind in vitro transcribed RNA representing the hantaviral small genomic (S) RNA segment. RNA binding was shown by affinity to filter-immobilized N proteins and by gel mobility shift assays. Competition experiments using tRNA, poly(U) and poly(A)+ U indicated that binding of RNA by the N protein is nonspecific. However, direct binding of ds-RNA resulted in efficient formation of large complexes suggesting that double-stranded nucleic acids are bound preferentially. Carboxyterminal fragments of HTN and PUU N proteins containing about 100 amino acids of the carboxy termini retained full binding capacity indicating that RNA binding occurs via a carboxyterminal domain.

Identification of the gene encoding the major capsid protein of insect iridescent virus type 6 by polymerase chain reaction

The gene encoding the major capsid protein of Chilo iridescent virus (CIV) has been identified by PCR using oligonucleotide primers corresponding to different regions of the major capsid proteins of Tipula iridescent virus (TIV) and iridescent virus 22 (IV22). A DNA fragment of 0.5 kbp was amplified using two oligonucleotide primers corresponding to the amino acid positions 146 to 153 and 304 to 313 of the major capsid protein of TIV, respectively. The radioactively labelled DNA fragment derived from PCR was hybridized to a CIV gene library. This analysis revealed that only the EcoRI CIV DNA fragment X [2.85 kbp; 0.589 to 0.603 viral map units (m.u.)] hybridized to the amplified DNA fragment. An RNA transcript of about 1.5 kb was identified when the PCR product was used as a hybridization probe. The same RNA transcript was detected when the EcoRI fragments X and Q (5.9 kbp; 0.603 to 0.631 viral m.u.) were used as probes. This indicates that the expected gene is located within map coordinates 0.589 to 0.631 and harbours part of the DNA sequences of fragments Q and X. The analysis of the DNA sequences of this particular region of the CIV genome revealed the presence of one open reding frame of 1401 bp. The DNA sequences of this region encode a protein of 467 amino acid residues with an M(r) of 51.4K. A high degree (64.7%) of amino acid sequence identity was detected between the major capsid protein of TIV and/or IV22 and the amino acid composition of the identified CIV protein.