Phylogenetic comparison of the genus Lyssavirus using distal coding sequences of the glycoprotein and nucleoprotein genes.

The phylogenetic relationships between all seven genotypes within the genus Lyssavirus were compared at the nucleotide level utilising two distal regions of the viral genome. The resulting analysis of each region produced similar, although not identical, phylogenetic results, suggesting that the evolutionary pressures on individual proteins within the genome vary. These differences are in part due to the increased variability observed within the glycoprotein sequence over the nucleoprotein sequence. Pair-wise comparison using the glycoprotein partial sequence between different isolates demonstrate that within genotypes, viruses show between 80 and 100% sequence identity, whilst between genotypes, viruses show between 50 and 75% identity. This provides a consistent guide to assigning new viruses to existing genotypes. Alignment of the amino acid sequence for the truncated glycoprotein sequence to the Pasteur Virus vaccine strain show significant residue variation between positions 139 and 170. However, residue variation tends to vary with genotype implying that these changes have not evolved due to immunological pressure from the host but have occurred following the separation of viruses into discrete groups. Comparison of the phylogenetic analysis for this partial region of the glycoprotein suggest that it gives comparable results to studies that have used larger regions of the Lyssavirus genome.

Sequence analysis of E2 glycoprotein genes of classical swine fever viruses: identification of a novel genogroup in Thailand.

Thirty classical swine fever viruses (CSFV) isolated in Thailand between 1988 and 1996 were characterised by genetic sequence analysis of a part of their E2 coding regions, comparing the new data with that for representative reference viruses from other countries and continents. Thai isolates were divided into three distinct genogroups, indicating multiple origins for the outbreaks. Eighteen isolates from 1988-1995 form a new genogroup not previously described from any other geographical region. Eleven isolates from 1988-1995 are in the same genogroup as old US and European strains represented by reference strains Alfort 187 and Brescia. The viruses of this group seem to have died out in Europe but still persist in Thailand. One recent isolate from 1996 represents another previously described genogroup being closely related to Italian viruses isolated in the same year.

Phylogenetic comparison and molecular epidemiology of classical swine fever virus.

The genetic diversity of classical swine fever virus (CSFV) was studied by RT-PCR amplification and sequencing of a 409 bp fragment of the NS5B polymerase region. A total of 106 viruses isolated from 20 countries over a period of 52 years (1945-1997) were included in the phylogenetic study. The results showed that the viruses could be divided into two main groups. Group 1 consisted of Asian and South American isolates from the 1980s, as well as of old European and American isolates. Group 2 consisted mostly of recent European viruses from the 1980s and 1990s, and was further divided into three subgroups largely according to geographic origin and/or year of isolation. Five 1997 CSFV isolates from Germany, Netherlands and Italy clustered together indicating a common origin for these outbreaks, but two other 1997 isolations in different regions of Germany are likely due to different epidemiological events. The results show that the NSSB region of the genome gives a good resolution for phylogenetic studies of CSFV. Molecular epidemiology based on nucleotide sequence diversity is a useful tool for tracing virus spread and for developing disease control strategies.

Classical swine fever in Sardinia: epidemiology of recent outbreaks.

A variable region of the gene encoding the major glycoprotein (E2) of Classical Swine Fever Virus (CSFV) was sequenced from 12 Sardinian isolates which had been obtained from three geographically distinct regions of the Island. Phylogenetic analysis of these viruses and others characterized in previous studies [1, 2] indicated that (a) the Sardinian viruses were all members of the common European subgroup 2.3 and were clearly distinct from live vaccines recently used in this area; (b) they could be resolved into four distinct groups in accordance with the region or date of isolation; (c) in at least two regions wild boar/domestic swine contact was implicated in virus spread; (d) the oldest isolate (1983) and some of the recent isolates were possibly introduced from mainland Italy. In addition, this study has wider implications for the interpretation of CSFV variation. We have been able to demonstrate that small variations within this region of the virus genome (possibly less than 2.7% or five nucleotide substitutions) can be used to separate isolates into groups that precisely fit their geographical distribution. This finding is especially important for deducing the epidemiological relationships between multiple outbreaks caused by similar viruses that occur in close proximity.

Genetic analysis of pestiviruses at the 3' end of the genome.

Specific PCR primers were selected for each pestivirus genotype which flanked the 3'-part of the NS5B gene and more than three quarters of the 3'-UTR. PCR products were sequenced in both directions using an automatic sequencing device and analyzed by computer package program DNASTAR. A comparative analysis of the 3' untranslated region (3'-UTR) of 82 viruses, representing the four genotypes of the Pestivirus genus, provided a similar phylogenetic grouping as other genomic regions. Intertypic recombination was not observed, but Border disease virus (BDV) and Bovine viral diarrhoea virus type I (BVDV I) showed great intragenotypic variability. In most pestiviruses the stop codon is TGA, but BDV isolates were found to have either a TAG or a TAA stop codon. Various deletions and insertions were observed in the 3'-UTR region. Viruses of the BVDV lb group contained a characteristic deletion of 41 nucleotides. Compared to the 5'-UTR, the 3'-UTR was less conserved. The first 50-60 nucleotides were particularly variable, whilst the most conserved part was found at the 3' end of the studied region. All 82 viruses contained AT-rich stretches, the positions and sizes of which differed between the genotypes.

Detection and identification of ruminant and porcine pestiviruses by nested amplification of 5' untranslated cDNA regions.

Based on published gene sequences of bovine viral diarrhoea virus (BVDV) type I and classical swine fever virus (CSFV), genus- and species-specific primers were designed to detect and identify pestivirus cDNA sequences in a nested polymerase chain reaction (PCR). The PCR primers were validated using cDNA synthesized from 146 pestivirus isolates, comprising representatives of all four so far described genotypes (BVDV type I, BVDV type II, CSFV and border disease virus), as well as others of uncertain classification. PCR products of the predicted size were amplified from all viruses with the genus-specific primers. All 53 cattle isolates, including 5 typed antigenically as BVDV type II were amplified by the internal BVDV-specific primers, but not the CSFV-specific primers. The same result was found for other BVDV type I and II viruses isolated from sheep and pigs. Seventy-seven CSF viruses were amplified by their respective internal primers. Available information strongly indicate that 4 CSF viruses also amplified by the BVDV-specific primers had been contaminated with BVDV in cell cultures. Border disease viruses were mostly not detected by the BVDV-specific primers, but were detected weakly by the CSFV-specific primer pair. Using carrier RNA for extraction of viral RNA, the sensitivity of detection of the single and nested PCR was, respectively, 5 and 50 times higher than obtained with a cell culture assay. The RT-PCR also detected BVDV in all of 15 commercial batches of fetal calf serum examined, and verified three earlier diagnoses of CSFV by detecting specific gene sequences in 30 year old frozen archival organ samples.

Discrimination between transmissible gastroenteritis virus isolates.

Twenty TGEV isolates were compared by sequencing a 393-414 nucleotide stretch near the 5' end of the S gene, after amplification by RT-PCR. This part of the S gene is known to show considerable variation between porcine, canine and feline coronaviruses and is completely deleted from porcine respiratory coronaviruses. The discrimination achieved by nucleotide sequence analysis was compared with that obtained by monoclonal antibody typing. The viruses could be split into several clusters, and recent isolates of TGEV from England, The Netherlands and Belgium showed the greatest differences compared to earlier reference types. However, not all viruses with unique isolation histories were distinct, suggesting either genetic stability over many years, laboratory cross-contaminations or repeated introductions of similar viruses into the field. Firm conclusions on evolutionary trends cannot be drawn without obtaining a larger number of isolates, preferably from outbreaks with known epidemiological links. The sequences of some field isolates from the 1980s contained both nucleotide deletions and insertions. The latter included a short sequence of fourteen nucleotides with identity to a region of the TGEV polymerase gene.

Classical swine fever virus diversity and evolution.

By analysing the nucleotide sequence data generated from both the E2 (gp55) and the NS5B genes of classical swine fever virus (CSFV), in addition to previously published data from the 5'NCR, we were able to divide 115 CSFV isolates into two major groups, five subgroups and two disparate isolates. Further discrimination was possible by analysis of sequence data from the E2 region. The three sequencing based methods were compared to monoclonal antibody (MAb) typing and to limited restriction enzyme (RE) mapping. Although both MAb and RE methods confirmed the previous classification the resolution was inferior. We estimated an approximate evolution rate for CSFV from an analysis of the virus variation observed in a single geographical area over a 6 year period. Applying this proposed rate to each of our deduced CSFV subgroups enabled us to calculate the approximate dates of divergence for each subgroup.

The Microphthalmia gene product interacts with the retinoblastoma protein in vitro and is a target for deregulation of melanocyte-specific transcription.

Little is known of the molecular mechanisms underlying the differentiation of the melanocyte from the melanoblast or the progression from the melanocyte to a malignant melanoma. Since the adenovirus E1A products have proved a useful tool for understanding control of differentiation in other systems, we explored the possibility of using E1A as a probe for factors controlling melanocyte-specific gene expression and differentiation. The results obtained show that the adenovirus E1A 13S, but not the 12S, product can transform the highly pigmented and TPA-dependent melanocyte cell line melan-a. Transformation is characterised by a morphological change, loss of TPA-dependence, the ability to grow in soft agar and strikingly, loss of pigmentation which correlates with loss of expression of the melanocyte-specific TRP-1 and tyrosinase genes. Cotransfection assays demonstrated that repression of TRP-1 by E1A correlated with E1A binding to p105Rb and p300, with the target in the TRP-1 promoter being the M-box, and 11 bp basic-Helix-loop-Helix (bHLH) factor-binding motif conserved between melanocyte-specific promoters. Consistent with the M-box acting as a target for E1a-mediated transcription repression, we also show that the basic-helix-loop-helix-leucine zipper (bHLH-LZ) protein (Mi) encoded by the microphthalmia gene (mi), which is required for pigment cell differentiation, is a positive acting transcription factor which can interact with the retinoblastoma product in vitro and activate the TRP-1 promoter. Moreover, expression of the mi gene was reduced around 50-fold in the non-pigmented E1a-transformed melan-a cells compared to the nontransformed melan-a cell line, with ectopic expression of Mi able to prevent repression of the tyrosinase and TRP-1 promoters in the presence of E1A. Mi therefore appears to play a crucial role in melanocyte-specific gene expression. The parallels between repression of myogenesis and muscle cell bHLH factors, and Mi and melanocyte differentiation are discussed.

Positive and negative elements regulate a melanocyte-specific promoter.

Melanocytes are specialized cells residing in the hair follicles, the eye, and the basal layer of the human epidermis whose primary function is the production of the pigment melanin, giving rise to skin, hair, and eye color. Melanogenesis, a process unique to melanocytes that involves the processing of tyrosine by a number of melanocyte-specific enzymes, including tyrosinase and tyrosinase-related protein 1 (TRP-1), occurs only after differentiation from the melanocyte precursor, the melanoblast. In humans, melanogenesis is inducible by UV irradiation, with melanin being transferred from the melanocyte in the epidermis to the surrounding keratinocytes as protection from UV-induced damage. Excessive exposure to UV, however, is the primary cause of malignant melanoma, an increasingly common and highly aggressive disease. As an initial approach to understanding the regulation of melanocyte differentiation and melanocyte-specific transcription, we have isolated the gene encoding TRP-1 and examined the cis- and trans-acting factors required for cell-type-specific expression. We find that the TRP-1 promoter comprises both positive and negative regulatory elements which confer efficient expression in a TRP-1-expressing, pigmented melanoma cell line but not in NIH 3T3 or JEG3 cells and that a minimal promoter extending between -44 and +107 is sufficient for cell-type-specific expression. Assays for DNA-protein interactions coupled with extensive mutagenesis identified three factors, whose binding correlated with the function of two positive and one negative regulatory element. One of these factors, termed M-box-binding factor 1, binds to an 11-bp motif, the M box, which acts as a positive regulatory element both in TRP-1-expressing and -nonexpressing cell lines, despite being entirely conserved between the melanocyte-specific tyrosinase and TRP-1 promoters. The possible mechanisms underlying melanocyte-specific gene expression are discussed.

Identification of new actin-associated polypeptides that are modified by viral transformation and changes in cell shape.

By using a monoclonal antibody we have identified a new polypeptide doublet (C4h and C4l) of Mr approximately 21 kD and pI 8 and 7, respectively, that is associated with and (at the immunofluorescence level) uniformly distributed on actin filament bundles in rat, mouse, and other vertebrate species. C4 is absent in neurones, erythrocytes, and skeletal muscle but the epitope is evolutionarily conserved as it is present in invertebrates such as molluscs and crustaceans. C4h is not found in cells such as lymphocytes and oncogenically transformed mesenchymal cells where actin stress fiber bundles are reduced in number or absent. C4l, on the other hand, is always present. C4h expression can also be blocked by switching normal nontransformed mesenchymal cells from adherent to suspension culture. Reexpression of C4h occurs 24 h after these cells are returned to normal adherent culture conditions, but can be blocked by either actinomycin D or cycloheximide, suggesting that the expression of this epitope is regulated at the transcriptional level.