Post-transcriptional mechanisms of deregulation of MYC following conversion of a human B cell line by Epstein-Barr virus.

By utilizing an Epstein-Barr virus (EBV)-negative Burkitt's lymphoma line (BJAB) and several EBV-positive sub-lines derived from it by in vitro infection, it has been shown previously that the presence of the EBV genome in this B cell line is reversibly associated with deregulation of MYC expression. Specifically, the decline in the level of MYC transcripts observed in the EBV-negative BJAB line as cells approach stationary phase of growth is abrogated in the presence of the virus. In the studies described herein, the mechanism of deregulation of MYC in EBV-converted BJAB cells was examined. It was shown that the presence of EBV in BJAB cells was not associated with changes in the rate of transcription from exons I, II or III of MYC as cells approached stationary phase of growth. In contrast, the stability of MYC mRNA was altered in EBV-positive BJAB cells. Specifically, the half-life of MYC mRNA increased from less than 36 to greater than 70 min in EBV-positive BJAB lines as cells progressed from early to late exponential phase of growth. This alteration in stability of MYC transcripts was reversibly associated with the presence of the virus, since an EBV-negative revertant BJAB line did not display an increase in stability of MYC transcripts in late exponential phase of growth. In addition, progression from early to late exponential phase of growth in two EBV-immortalized lymphoblastoid lines derived from normal human B cells was also associated with prolongation of the half-life of MYC.(ABSTRACT TRUNCATED AT 250 WORDS)

Amplification and deregulation of MYC following Epstein-Barr virus infection of a human B-cell line.

In Epstein-Barr virus (EBV)-positive Burkitt lymphoma (BL) the role of EBV in the translocation and deregulation of the MYC oncogene remains unknown. By utilizing an EBV-negative BL (BJAB) and several EBV-positive sublines derived from it by in vitro infection, it was possible to show that the presence of the virus was associated with altered expression and copy number of MYC. In the EBV-negative BJAB line, the level of MYC transcripts declined progressively as cells approached the stationary phase of growth. In contrast, in EBV-infected BJAB cells MYC expression remained elevated as cells entered stationary phase. This effect on MYC expression was reversibly linked to the presence of the virus. Furthermore, following EBV infection of BJAB cells by two different strains of EBV, amplification of MYC in association with the appearance of a homogeneously staining region on chromosome 8 at the mapped location of MYC had occurred. These studies suggest that both the deregulation of MYC transcription and the chromosomal rearrangement in the region of the MYC locus in this B-cell line may have occurred as a result of EBV infection.

Utilization of internal AUG codons for initiation of protein synthesis directed by mRNAs from normal and mutant genes encoding herpes simplex virus-specified thymidine kinase.

Previous studies (H.S. Marsden, L. Haarr, and C.M. Preston, J. Virol. 46:434-445, 1983) have shown that at least three polypeptides, with molecular weights of 43,000, 39,000, and 38,000, are encoded by the herpes simplex virus type 1 (HSV-1) thymidine kinase (TK) gene. It has been suggested that the 39,000- and 38,000-molecular-weight polypeptides arise from preinitiation complexes bypassing the first and second AUG codons before commencement of translation since, according to previous work (M. Kozak, Nucleic Acids Res. 9:5233-5252, 1981), these codons are not of the most efficient structure for initiation. This possibility was investigated by using specific herpes simplex virus mutants with alterations in the TK gene. Mutant TK4 has an amber mutation between the first and second AUG codons, whereas mutant delta 1 has a deletion which removes the first AUG codon but leaves other AUG codons, as well as transcriptional promoter sequences, intact. Both mutants synthesized only the 39,000- and 38,000-molecular-weight polypeptides, and the amounts produced were normal in TK4-infected cells but increased in delta 1-infected cells. Furthermore, the levels of TK produced after infection with the mutant viruses correlated with the amounts of the 39,000- and 38,000-molecular-weight polypeptides synthesized. The 43,000-, 39,000-, and 38,000-molecular-weight polypeptides were shown to be related by their positive reaction with anti-TK serum in both immunoprecipitation and immunoblotting experiments. The production of the 39,000- and 38,000-molecular-weight polypeptides through bypassing of the first AUG codon was examined by hybrid arrest experiments with a DNA fragment complementary to only 50 bases at the 5' terminus of TK mRNA. This fragment arrested the synthesis of the 30,000- and 38,000-molecular-weight polypeptides when annealed to mRNA from wild-type HSV-1- or TK4-infected cells, showing that those polypeptides arise from an mRNA initiated upstream from the first AUG codon. mRNA from cells infected with mutant delta 1, which lacks DNA sequences upstream from the first AUG, was not affected by the 50-base-pair fragment. The data therefore confirm that three polypeptides encoded by the HSV-1 TK gene arise by differential use of in-phase AUG codons for the initiation of protein synthesis. This mechanism for the production of related but distinct polypeptides has not previously been demonstrated in a eucaryotic system, and the implications for the regulation of TK enzyme activities are discussed.

Identification of Epstein-Barr nuclear antigen polypeptide in mouse and monkey cells after gene transfer with a cloned 2.9-kilobase-pair subfragment of the genome.

A new antigenic polypeptide was identified in mouse L cells and in monkey COS-1 cells in which Epstein-Barr nuclear antigen (EBNA) was expressed as the result of gene transfer with cloned fragments of Epstein-Barr virus (EBV) DNA. The same-size protein (Mr, approximately equal to 78,000) was seen in stably transformed mouse cells harboring only the BamHI K fragment [approximately equal to 5.2 kilobase pairs (kbp)] or its BamHI/HindIII subfragment, I1f (approximately equal to 2.9 kbp). Thus, the latter DNA fragment is sufficient to code for the protein. In transfected COS cells, a deletion mutant of the I1f fragment (approximately equal to 2.3 kbp) gave rise to a truncated protein (Mr, approximately equal to 52,000), whereas the BamHI K fragment yielded a full-sized Mr 78,000 species. This finding indicates that EBNA is encoded by viral genes. In Burkitt lymphoma lines or in immortalized lymphocytes, variation in the size of the I1f fragment correlated with the apparent molecular weight of the EBNA polypeptide. EBNA is truncated in two Burkitt lymphoma lines, Raji (Mr, 67,000) and P3JHR-1 (Mr, 70,000), which have deletion mutant I1f genes. EBNA in human lymphoid cells bearing a complete I1f fragment as part of the entire EBV genome is the same size (Mr, 78,000) as EBNA found after gene transfer of I1f alone into mouse or monkey cells. Therefore, these expression systems make an authentic EBNA after transfer of the appropriate EBV genes.

Two Epstein-Barr viral nuclear neoantigens distinguished by gene transfer, serology, and chromosome binding.

We recently identified, by means of cotransformation of LTK- cells, a region of the Epstein-Barr virus (EBV) genome (the BamHI K fragment) that encodes or induces an EBV nuclear neoantigen (EBNA) serologically related to the EBNA found in lymphoid cells carrying the entire EBV genome. We now find that a second EBV DNA fragment, BamHI M, is also able to give rise to cotransformed LTK- cells with stable expression of a nuclear antigen. The BamHI K and M fragments have no apparent DNA homology. Many human sera that are reactive to EBNA in Raji cells detect both antigens; however, certain anti-EBNA-positive human sera are discordant and react only with the BamHI M or only with the BamHI K nuclear antigen. Every Raji cell appears to express both "M" and "K" antigens; D98 Raji cells, a somatic cell hybrid, express only "K" antigen. The K antigen is found on metaphase chromosomes of LTK cells and Raji cells. The M-induced antigen is not located on chromosomes when the cells are in metaphase but is present as granules within the nucleus.

Stable expression in mouse cells of nuclear neoantigen after transfer of a 3.4-megadalton cloned fragment of Epstein-Barr virus DNA.

All cells that harbor the Epstein-Barr virus (EBV) genome contain a neoantigen in the nucleus (EBNA). By transfection we located a segment of the genome that encodes or induces an antigen serologically related to EBNA. The responsible genes are found in the 3.4-megaldalton BamHI fragment K of EBV DNA, specifically in the left 1.9 megadaltons represented by HindIII fragment I1. Mouse LTK- cells were cotransformed with recombinant plasmids, containing the herpes simplex virus thymidine kinase gene and either EcoRI fragment B or BamHI fragment of K of EBV DNA. The TK+ cells surviving in selective medium were cloned. About 50% of the clones expressed the neoantigen in every nucleus. These mouse cells were used as antigens in immunofluorescence tests. Antibody to the nuclear antigen was found in 30 human sera known to contain antibody to EBNA; it was not detected in 18 sera that did not have antibody to EBNA. Mouse cells expressing EBNA as the result of acquisition of cloned EBV DNA fragments should prove useful in the characterization of the structure of this antigen and as reagents for the diagnosis of EBV infections.

Characterization of pyrimidine deoxyribonucleoside kinase (thymidine kinase) and thymidylate kinase as a multifunctional enzyme in cells transformed by herpes simplex virus type 1 and in cells infected with mutant strains of herpes simplex virus.

Pyrimidine deoxyribonucleoside kinase (thymidine kinase [TK]) was purified from two herpes simplex virus type 1 (HVS-1)-transformed TK-deficient mouse (LMTK-) cell lines and from LMTK- cells infected with HSV-1 mutant viruses coding for variant TK enzymes. These preparations exhibited normal or variant virus-induced thymidylate kinase activities correlating with their relative TK activities. Neither virus-induced activity was detected in LMTK- cells infected with an HSV-1 TK-deficient mutant. These results suggest that HSV-1 thymidylate kinase activity and TK activity are mediated by the same protein.

A herpes simplex virus 1 integration site in the mouse genome defined by somatic cell genetic analysis.

Transfection experiments with HSV 1 in which one uses herpes simplex virus (HSV) thymidine kinase (TK) as a selectable prototrophic marker yield two classes of transformed cells: stable and unstable. In this report, we test the hypothesis that the stability phenotype can be explained by virus genome integration into a recipient cell chromosome. The method of analysis is by means of somatic cell genetics. We have isolated a series of microcell hybrids between a TK- Chinese hamster cell line and a transformed mouse cell line expressing the TK encoded by HSV 1. Several of the hybrid lines contain a single murine chromosome and express only the viral TK. Karyotypic analysis of these hybrids and of TK- derivatives generated by BrdUrd counterselection reveals that the TK+ phenotype is correlated with the presence of the terminal portion of the long arm of a specific murine chromosome. Results of extensive isozyme analyses of the hybrids and their TK- segregants fully corroborate the karyologic data. The results are consistent with the hypothesis that the viral tk gene is covalently integrated into this chromosomal region which itself does not appear to carry the endogenous murine tk locus. Other more complicated models are discussed. Our findings also show that somatic cell genetics can be used to localize viral integration sites in host chromosomes with high resolution.

The thymidine kinase gene of herpes simplex virus type 1: cell-free protein synthesis and substrate specificity studies.

The HSV thymidine kinase genetic system has a number of advantages for the study of virus and cell genetics. Both forward and reverse mutants are readily selected. The enzyme can be assayed directly in the presence of the cell TK by the choice of the appropriate substrate, for example, 125IdC. The gene product, HSV TK, can be identified by SDS-polyacrylamide gel electrophoresis and mutants can be found with alterations in the electrophoretogram. The in vitro synthesis of HSV TK in response to HSV mRNA has been achieved and can be used to analyse specific mutant virus.