Structural analysis and transcriptional mapping of the Marek's disease virus gene encoding pp38, an antigen associated with transformed cells

Marek's disease virus (MDV) latency-associated transcripts include at least two MDV small RNAs (MSRs) and a 10-kb RNA which map antisense to the ICP4 homolog gene and are relatively abundant in MDVtransformed lymphoblastoid cells. This report further describes the biological and structural properties of these RNAs. First, these RNAs were detected in primary lymphomas isolated from chickens infected with several oncogenic MDV strains. Second, the MSRs are nonpolyadenylated, whereas, the 10-kb RNA is predominantly polyadenylated. Third, MSRs localize to the nuclei of both lymphoblastoid cells and cytolytically infected chicken embryo fibroblasts. Fourth, the 3-region splice junctions of the MSRs during latent and productive infection were determined by sequencing RNA-PCR products generated with primers that flank the 3 splice region. The MSRs contain at least three introns, the largest of which overlaps the ICP4 putative translational start site. Fifth, the 5 end of the MSRs initiates approximately 5 kb upstream from the main body of the RNA. The extreme 5 exon is approximately 251 nucleotides (nt) long and is joined to the main body of the transcript upon removal of a 4,852-nt intron. Finally, the 10-kb RNA lies entirely within the repeats flanking the unique short region of the genome. We believe that the MSRs and 10-kb RNA belong to a family of spliced RNAs that map antisense to the ICP4 gene and comprise a complex transcriptional unit expressed during MDV-induced T-cell transformation.

show abstract

“…4B). In contrast, the 1.8-kb MDV pp38 transcript (13,16) was found in the cytoplasmic RNA fraction, as expected (Fig. 4C).…”

Section: Detection Of the Msrs And 10-kb Rna In Mdv-induced Primary Lsupporting

confidence: 86%

Marek's disease virus latency-associated transcripts belong to a family of spliced RNAs that are antisense to the ICP4 homolog gene

Cantello

Parcells

Anderson

et al. 1997

J Virol

View full text Add to dashboard Cite

show abstract

“…After determining the nucleotide sequence of the left half of the BamHI H fragment, where the B antigen gene was reported to be localized, we could not find a single open reading frame which is long enough to encode the 44-kDa peptide reported by Sithole et al (57) as a precursor (data not shown). Very recently, Cui et al (15) identified the gene encoding pp38 of MDV on the BamnHI H fragment, where the B antigen gene was reported to be localized (57). These findings strongly support our identification of the gB homolog as the B antigen.…”

Section: Discussionsupporting

confidence: 87%

Expression of the Marek's disease virus (MDV) homolog of glycoprotein B of herpes simplex virus by a recombinant baculovirus and its identification as the B antigen (gp100, gp60, gp49) of MDV

Niikura

Matsuura

Endoh

et al. 1992

J Virol

View full text Add to dashboard Cite

show abstract

“…Length polymorphism of restriction fragments between oncogenic and nononcogenic strains, as well as attenuated strains obtained by serial in vitro passage, has prompted efforts to identify genes that may be associated with tumorigenicity (6,7,18,19,61). In an alternative approach, viral gene products expressed in MDV-transformed cells were identified by characterizing mRNAs or by cDNA cloning techniques (6,13,40,56,62) or by monoclonal antibodies (14,15,30,45). One property of MDVtransformed cells has made it extremely difficult to analyze potential tumor-associated transcripts unambiguously; a few cells in a tumor or in an established cell line in which the virus undergoes the lytic cycle will make the obtained data difficult to interpret.…”

Section: Six Cell Lines Derived Frommentioning

confidence: 99%

Status of Marek's disease virus in established lymphoma cell lines: herpesvirus integration is common

Delecluse

Hammerschmidt

1993

J Virol

View full text Add to dashboard Cite

Six cell lines derived from Marek's disease lymphomas of chickens and turkeys were investigated for the status of Marek's disease virus (MDV) DNA. In the transformed T- and B-cell lines, viral DNA could be detected by conventional Southern blot hybridization, by Gardella gel electrophoresis, and by in situ hybridization of metaphase and interphase chromosomes. Integration of viral DNA into the host cell chromosome was observed in all cell lines. Two to 12 integration sites of viral DNA could be detected in metaphase chromosome spreads. The integration sites were characteristic for the individual cell lines and were preferentially located at the telomers of large- and mid-sized chromosomes or on minichromosomes. In four of six cell lines, a minor population of latently infected cells supported the lytic cycle of MDV, giving rise to linear virion DNAs. In one of these cell lines, a third species of MDV DNA could be detected with properties reminiscent of covalently closed circular DNA. The finding that MDV integrates regularly into the genomes of latently infected cells is crucial to understanding the molecular biology of herpesvirus-induced tumors in the natural host.

show abstract

Structural analysis and transcriptional mapping of the Marek's disease virus gene encoding pp38, an antigen associated with transformed cells

Cited by 101 publications

References 41 publications

Marek's disease virus latency-associated transcripts belong to a family of spliced RNAs that are antisense to the ICP4 homolog gene

Marek's disease virus latency-associated transcripts belong to a family of spliced RNAs that are antisense to the ICP4 homolog gene

Expression of the Marek's disease virus (MDV) homolog of glycoprotein B of herpes simplex virus by a recombinant baculovirus and its identification as the B antigen (gp100, gp60, gp49) of MDV

Status of Marek's disease virus in established lymphoma cell lines: herpesvirus integration is common

Contact Info

Product

Resources

About