Physical mapping of the DNA genome of insect iridescent virus type 9 from Wiseana spp. larvae

Genomic and proteomic analysis of invertebrate iridovirus type 9

Iridoviruses (IV) are nuclear cytoplasmic large DNA viruses that are receiving increasing attention as sublethal pathogens of a range of insects. Invertebrate iridovirus type 9 (IIV-9; Wiseana iridovirus) is a member of the major phylogenetic group of iridoviruses for which there is very limited genomic and proteomic information. The genome is 205,791 bp, has a G+C content of 31%, and contains 191 predicted genes, with approximately 20% of its repeat sequences being located predominantly within coding regions. The repeated sequences include 11 proteins with helix-turn-helix motifs and genes encoding related tandem repeat amino acid sequences. Of the 191 proteins encoded by IIV-9, 108 are most closely related to orthologs in IIV-3 (Chloriridovirus genus), and 114 of the 126 IIV-3 genes have orthologs in IIV-9. In contrast, only 97 of 211 IIV-6 genes have orthologs in IIV-9. There is almost no conservation of gene order between IIV-3, IIV-6, and IIV-9. Phylogenetic analysis using a concatenated sequence of 26 core IV genes confirms that IIV-3 is more closely related to IIV-9 than to IIV-6, despite being from a different genus of the Iridoviridae. An interaction between IIV and small RNA regulatory systems is supported by the prediction of seven putative microRNA (miRNA) sequences combined with XRN exonuclease, RNase III, and double-stranded RNA binding activities encoded on the genome. Proteomic analysis of IIV-9 identified 64 proteins in the virus particle and, when combined with infected cell analysis, confirmed the expression of 94 viral proteins. This study provides the first full-genome and consequent proteomic analysis of group II IIV.

[Red sea bream iridoviral disease]

The first outbreak of red sea bream iridoviral disease caused by red sea bream iridovirus (RSIV) was recorded in cultured red sea bream Pagrus major in Shikoku Island, Japan in 1990. Since 1991, the disease has caused mass mortalities of cultured marine fishes not only red sea bream but also many other species. The affected fish were lethargic and exhibited severe anemia, petechiae of the gills, and enlargement of the spleen. The causative agent was a large, icosahedral, cytoplasmic DNA virus classified as a member of the family Iridoviridae and was designated as red sea bream iridovirus (RSIV). The genome of RSIV is liner dsDNA and considered to be circularly permitted and terminally redundant like other iridoviruses. The length of physical map of RSIV genome is 112,415bp. An indirect immunofluorescence test with a monoclonal antibody and PCR are commonly used for the rapid diagnosis of RSIV infected fish in the field. For the control of this disease, a formalin-killed vaccine against red sea bream iridoviral disease was developed and now commercially available.

Molecular anatomy of Chilo iridescent virus genome and the evolution of viral genes

Chilo iridescent virus (CIV) or Insect iridescent virus 6 (IIV-6) is the type species of the genus iridovirus, a member of the Iridoviridae family. CIV is highly pathogenic for a variety of insect larvae and this implicates a possible use as a biological insecticide. CIV progeny and assembly occur in the cytoplasm of the infected cell and accumulate in the fatbody of the infected insects. Since the discovery of CIV in 1966, many attempts were made to elucidate the viral genome structure and the amino acid sequences of different viral gene products. The elucidation of the coding capacity and strategy of CIV was the first step towards understanding the underlying mechanisms of viral infection, replication and virus-host interaction. The virions contain a single linear ds DNA molecule that is circularly permuted and terminally redundant. The coding capacity of the CIV genome was determined by the analysis of the complete DNA nucleotide sequence consisting of 212,482 bp that represent 468 open reading frames encoding for polypeptides ranging from 40 to 2432 amino acid residues. The analysis of the coding capacity of the CIV genome revealed that 50% (234 ORFs) of all identified ORFs (468 ORFs) were non-overlapping. The identification of several putative viral gene products including a DNA ligase and a viral antibiotic peptide is a powerful tool for the investigation of the phylogenetic relatedness of this evolutionary and ecologically relevant eukaryotic virus.

Analysis of the first complete DNA sequence of an invertebrate iridovirus: coding strategy of the genome of Chilo iridescent virus

Chilo iridescent virus (CIV), the type species of the genus Iridovirus, a member of the Iridoviridae family, is highly pathogenic for a variety of insect larvae. The virions contain a single linear ds DNA molecule that is circularly permuted and terminally redundant. The coding capacity and strategy of the CIV genome was elucidated by the analysis of the complete DNA nucleotide sequence of the viral genome (212,482 bp) using cycle sequencing by primer walking technology. Both DNA strands were sequenced independently and the average redundancy for each nucleotide was found to be 1.85. The base composition of the viral genomic DNA sequence was found to be 71.37% A+T and 28.63% G+C. The CIV genome contains 468 open reading frames (ORFs). The size of the individual viral gene products ranges between 40 and 2432 amino acids. The analysis of the coding capacity of the CIV genome revealed that 50% (234 ORFs) of all identified ORFs were nonoverlapping. The comparison of the deduced amino acid sequences to entries in protein data banks led to the identification of several genes with significant homologies, such as the two major subunits of the DNA-dependent RNA polymerase, DNA polymerase, protein kinase, thymidine and thymidylate kinase, thymidylate synthase, ribonucleoside-diphosphate reductase, major capsid protein, and others. The highest homologies were detected between putative viral gene products of CIV and lymphocystis disease virus of fish (LCDV). Although many CIV putative gene products showed significant homologies to the corresponding viral proteins of LCDV, no colinearity was detected when the coding strategies of the CIV and LCDV-1 were compared to each other. An intriguing result was the detection of a viral peptide of 53 amino acid residues (ORF 160L) showing high homology (identity/similarity: 60.0%/30.0%) to sillucin, an antibiotic peptide encoded by Rhizomucor pusillus. Iridovirus homologs of cellular genes possess particular implications for the molecular evolution of large DNA viruses.

Identification of a gene cluster within the genome of Chilo iridescent virus encoding enzymes involved in viral DNA replication and processing

The nucleotide sequence of the genome of Chilo iridescent virus (CIV) between the genome coordinates 0.974 and 0.101 comprising 27,079 bp was determined. Computer-assisted analysis of the DNA sequence of this particular region of the CIV genome revealed the presence of 42 potential open reading frames (ORFs) with coding capacities for polypeptides ranging from 50 to 1,273 amino acid residues. The analysis of the amino acid sequences deduced from the individual ORFs resulted in the identification of 10 potential viral genes that show significant homology to functionally characterized proteins of other species. A cluster of five viral genes that encode enzymes involved in the viral DNA replication was identified including the DNA topoisomerase II (A039L,1,132 amino acids (aa)), the DNA polymerase (ORF A031L,1,273 aa), a helicase (ORF A027L, 530 aa), a nucleoside triphosphatase I (ORF A025L, 1,171 aa), and an exonuclease II (ORF A019L, 624aa), all ORFs possessing the same genomic orientation. The DNA polymerase of CIV showed the highest homology (24.8% identity) to the DNA polymerase of lymphocystis disease virus lymphocystis disease virus 1 (LCDV-1), a member of the family Iridoviridae, indicating the close relatedness of the two viruses. In addition, four putative gene products were found to be significantly homologous to previously identified hypothetical proteins of CIV.

Identification of a thymidylate synthase gene within the genome of Chilo iridescent virus

The thymidylate synthase (TS, EC 2.1.1.45) is essential for the de novo synthesis of dTMP in pro- and eucaryotic organisms. Consequently it plays a major role in the replication of the DNA genome of a cell or a DNA virus. The gene encoding the TS of Chilo iridescent virus (CIV) was identified by nucleotide sequence analysis of the viral genome and was mapped within the EcoRI CIV DNA fragments G and R. Computer assisted analysis of the DNA nucleotide sequence between the genome coordinates 0.482 and 0.489 revealed an open reading frame (ORF) of 885 nucleotides. This ORF was found to encode a polypeptide of 295 amino acid residues (33.9 kDa) that showed significant homologies to known TS of different species including mammals, plants, fungi, protozoa, bacteria, and DNA viruses. The highest amino acid homologies were found between the CIV-TS and the TS of herpesvirus ateles (54.0%), Saccharomyces cerevisiae (51.8%), herpesvirus saimiri (51.0%), rhesus monkey rhadinovirus (50.7%), mouse (50.5%), rat (50.2%), varicella-zoster virus (50.2%), equine herpesvirus 2 (50.0%), and the human TS (48.4%). The CIV-TS contains six amino acid domains that are highly conserved in the TS of other species. Within these domains the major amino acid residues are present for which a functional role has been reported. The CIV-TS was found to be more closely related to the TS of eucaryotes than to the TS of procaryotes indicating the phylogenetic origin of the CIV-TS gene. The identification of a TS gene in the genome of CIV is the first report of a viral TS that is not encoded by a herpesvirus or a bacteriophage.

Comparison of the major capsid protein genes, terminal redundancies, and DNA-DNA homologies of two New Zealand iridoviruses

Molecular comparisons were carried out on two iridoviruses isolated from endemic sympatric New Zealand pasture pests. These viruses, Costelytra zealandica iridescent virus (CzIV/IV16) and Wiseana iridescent virus (WIV/IV9), belong to the same virus genus but it is not known how related they are. The major capsid protein (MCP) gene from each virus was located, sequenced, and compared to the homologous gene from other iridoviruses. The MCP genes of WIV and CzIV were similar to each other (87.9% amino acid similarity) and to other iridovirus MCP genes. The MCP genes of both WIV and CzIV were most homologous to the MCP gene from Tipula iridescent virus (TIV/IV1), with amino acid similarities of 92.3 and 88.3% respectively. The genomes of WIV and CzIV were compared to other invertebrate iridoviruses using solution DNA-DNA hybridisations. Even after reducing the annealing stringency conditions hybridisation ratios never exceeded 10% indicating there is little sequence conservation between iridovirus genomes. Estimates of the size of terminal redundancies were also calculated for these viruses using pulsed-field agarose gel electrophoresis. These values ranged from 0 to 8%. These studies indicate that WIV and CzIV have distinct genomes and that the genus Iridovirus is comprised of a group of genetically diverse viruses.

Is the major capsid protein of iridoviruses a suitable target for the study of viral evolution?

Iridoviruses are large cytoplasmic DNA viruses that are specific for different insect or vertebrate hosts. The major structural component of the non-enveloped icosahedral virus particles is the major capsid protein (MCP) which appears to be highly conserved among members of the family Iridoviridae, Phycodnaviridae, and African swine fever virus. The amino acid sequences of the known MCPs were used in comparative analyses to elucidate the phylogenic relationships between different cytoplasmic DNA viruses including three insect iridoviruses (Tipula iridescent virus, Simulium iridescent virus, Chilo iridescent virus), seven vertebrate iridoviruses isolated either from fish (lymphocystis disease virus, rainbow trout virus, European catfish virus, doctor fish virus), amphibians (frog virus 3), or reptiles (turtle virus 3, turtle virus 5), one member of the family Phycodnaviridae (Paramecium bursaria Chlorella virus type 1), and African swine fever virus. These analyses revealed that the amino acid sequence of the MCP is a suitable target for the study of viral evolution since it contains highly conserved domains, but is sufficiently diverse to distinguish closely related iridovirus isolates. Furthermore the results suggest that a substantial revision of the taxonomy of iridoviruses based on molecular phylogeny is required.

The DNA sequence of Chilo iridescent virus between the genome coordinates 0.101 and 0.391; similarities in coding strategy between insect and vertebrate iridoviruses

Chilo iridescent virus (CIV), the type species of the genus Iridovirus within the family Iridoviridae, is highly pathogenic for larvae of important pest insects. The virions contain a single linear double-stranded DNA molecule (209 kbp) that is circularly permuted and terminally redundant. The nucleotide sequence of the viral genome between the genome coordinates 0.101 and 0.391 (60,170 bp) was determined by automated cycle sequencing. This particular region of the CIV genome contains 112 open reading frames (ORFs) with coding capacities for 50 to 1186 amino acids. The alignment of the deduced amino acid sequences with well-characterized proteins stored in protein databases led to the identification of several genes with significant homologies, such as the largest subunit of the DNA-dependent RNA polymerase, large subunit of the ribonucleoside-diphosphate reductase, endonuclease, protein-tyrosine phosphatase, helicase, global transactivator, two apoptosis inhibitor homologs, antibiotic peptide homolog, and others. The highest homologies were detected between putative viral gene products of CIV and the corresponding viral proteins of lymphocystis disease virus of fish (LCDV), which belongs to the genus Lymphocystivirus within the iridovirus family.

The complete DNA sequence of lymphocystis disease virus

Lymphocystis disease virus (LCDV) is the causative agent of lymphocystis disease, which has been reported to occur in over 100 different fish species worldwide. LCDV is a member of the family Iridoviridae and the type species of the genus Lymphocystivirus. The virions contain a single linear double-stranded DNA molecule, which is circularly permuted, terminally redundant, and heavily methylated at cytosines in CpG sequences. The complete nucleotide sequence of LCDV-1 (flounder isolate) was determined by automated cycle sequencing and primer walking. The genome of LCDV-1 is 102.653 bp in length and contains 195 open reading frames with coding capacities ranging from 40 to 1199 amino acids. Computer-assisted analyses of the deduced amino acid sequences led to the identification of several putative gene products with significant homologies to entries in protein data banks, such as the two major subunits of the viral DNA-dependent RNA polymerase, DNA polymerase, several protein kinases, two subunits of the ribonucleoside diphosphate reductase, DNA methyltransferase, the viral major capsid protein, insulin-like growth factor, and tumor necrosis factor receptor homolog.

RNA transcript mapping of the Wiseana iridescent virus genome

The replication of Wiseana iridescent virus (WIV) was studied in Lymantria dispar tissue culture cells. Using a combination of [35S]methionine pulse-labeling and Northern blotting with WIV DNA probes, a transcriptional map of the genome was constructed. WIV has a wide dispersal of immediate-early genes with seven different regions identified. WIV has been reported to have extensive repetitive DNA sequences but no early transcription was observed in these regions. Although fine-mapping is required, some early regions (Bam L and Eco O) have been identified which are transcriptionally active at 6- and 12-h but are shut down by 24 h. These regions could provide probes for early genes and the hypothesized switch from nuclear to cytoplasmic replication for iridoviruses.

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.

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.

A comparison of the structural polypeptides of three iridescent viruses (types 6, 9, and 16) and the mapping of the DNA region coding for their major capsid polypeptides

The iridoviruses from Wiseana cervinata (WIV, type 9), Costelytra zealandica (CzIV, type 16) and Chilo suppressalis (CIV, type 6) were compared by SDS-PAGE and Western protein blotting for antigenic determinants. The major capsid proteins were isolated and oligonucleotide probes were synthesized from the partial amino acid sequences. The DNA regions coding for the major capsid proteins of WIV (VP52), CzIV (VP53) and CIV (VP50) were located by hybridization of the oligonucleotide probes to blots of the viral DNA. The major capsid protein was used as the zero point for the proposed linearized maps of these viruses. Using antibody and 125I-labelling, several proteins were identified as being on the surface of the virion. It was also shown that CIV was not as antigenically distinct from these two viruses as previously reported.

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.

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.

Comparison of the genomes of two sympatric iridescent viruses (types 9 and 16)

A map of the sites in the genome of Costelytra zealandica iridescent virus (CzIV), using the restriction enzymes BamHI, KpnI, and PstI, showed the genome size to be 170.2 kbp in length. It was found that the genome was cyclically permuted and that 39% of the genome of CzIV contained repetitive sequence elements. The genome was found to hybridize with the genome of another iridescent virus, type 9 (WIV), in DNA-DNA hybridization experiments. A region of the WIV DNA genome (23.4 kbp) did not hybridize with CzIV DNA and this region is similar in size to the total genomic size difference between CzIV and WIV (22.4 kbp). A unique repeat sequence from iridescent virus type 6 (CIV) was shown to be present in the genome of WIV but not that of CzIV. Finally, the positions of the major capsid protein genes, VP53 and VP52, in the restriction enzyme maps for type 16 and type 9 respectively were determined.

Identification and characterization of the gene encoding the major structural protein of insect iridescent virus type 22

The major structural protein (MSP--apparent molecular weight 49,000) of insect iridescent virus type 22 (isolated from blackflies--Simulium spp.) was resolved from disrupted, purified virus particles by SDS-PAGE and transferred to nitrocellulose by Western blotting. The portion of the blot containing the MSP was identified and excised. Tryptic peptides, generated by digestion in situ, were purified by HPLC. Three of these peptides were sequenced and an oligonucleotide gene probe was designed using one of them. A SalI clone of IV22 DNA was identified as MSP-specific by hybridization. DNA from this and an overlapping DNA clone was sequenced and a large open reading frame was positively identified as the MSP coding sequence by comparison with the tryptic peptide sequences. The molecular weight of the predicted protein product of this gene is 51,993, comparable with the apparent weight obtained by SDS-PAGE. In infected Spodoptera frugiperda (Sf) cells MSP is synthesized from 12 hr postinfection onwards. The identification of this gene and analysis of its expression opens the way to elucidating the control of late gene expression in an insect iridescent virus.

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.

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.