Deletion of the Nontransforming Epstein-Barr Virus Strain P3HR-1 Causes Fusion of the Large Internal Repeat to the DSL Region

The nontransforming Epstein-Barr virus (EBV) strain P3HR-1 is known to have a deletion of sequences of the long unique region adjacent to the large internal repeats. The deleted region is believed to be required for initiation of transformation. To establish a more detailed map of the deletion in P3HR-1 virus, SalI-A of the transforming strain M-ABA and of P3HR-1 virus was cloned into the cosmid vector pHC79 and multiplied in Escherichia coli. The cleavage sites for BamHI, BglII, EcoRI, PstI, SacI, SacII, and XhoI were determined in the recombinant plasmid clones. Analysis of the boundary between large internal repeats and the long unique region showed that in M-ABA (EBV) the transition is different from that in B95-8 virus. The map established for SalI-A of P3HR-1 virus revealed that, in contrast to previous reports, the deletion has a size of 6.5 kilobase pairs. It involves the junction between large internal repeats and the long unique region and includes more than half of the rightmost large internal repeat. The site of the deletion in the long unique region is located between a SacI and a SacII site, about 200 base pairs apart from each other. The sequences neighboring the deletion in the long unique region showed homology to the nonrepeated sequences of the DS(R) (duplicated sequence, right) region. Sequences of the large internal repeat are thus fused to sequences of the DS(L) (duplicated sequence, left) region in P3HR-1 virus DNA under elimination of the DS(L) repeats. Jijoye, the parental Burkitt lymphoma cell line from which the P3HR-1 line is derived by single-cell cloning, is known to produce a transforming virus. Analysis of the Jijoye (EBV) genome with cloned M-ABA (EBV) probes specific for the sequences missing in P3HR-1 virus revealed that the sequences of M-ABA (EBV) BamHI-H2 are not represented in Jijoye (EBV). In Jijoye (EBV) the complete DS(L) region including the DS(L) repeats is, however, conserved. Further analysis of Jijoye (EBV) and of Jijoye virustransformed cell lines will be helpful to narrow down the region required for transformation.     

Recombinants between endogenous and exogenous avian tumor viruses: role of the C region and other portions of the genome in the control of replication and transformation.

Endogenous retroviruses of chickens are closely related to exogenous viruses isolated from spontaneous tumors in the same species, yet differ in a number of important characteristics, including the ability to transform cells in culture, ability to cause sarcomas or leukemias, host range, and growth rate in cell culture. To correlate these differences with specific sequence differences between the two viral genomes, the genome RNA of transforming subgroup E recombinants between the Prague strain of Rous sarcoma virus, subgroup B (Pr-RSV-B), and the endogenous Rous-associated virus-0 (RAV-0), Subgroup E, and seven nontransforming subgroup E recombinants between the transformation-defective mutant of Pr-RSV-B and RAV-0 was examined by oligonucleotide fingerprinting. The pattern of inheritance among the recombinant viruses of regions of the genome in which Pr-RSV-B and RAV-0 differ allowed us to draw the following conclusions. (i) Nonselected parts of the genome were, with a few exceptions, inherited by the recombinant virus progeny randomly from either parent, with no obvious linkage between neighboring sequences. (ii) A small region in the Pr-RSV-B genome which maps in the 5' region was found in all transforming but only some of the nontransforming recombinants, suggesting that it plays a role in the control of the expression of transformation. (iii) A region of the Pr-RSV-B genome which maps between env and src was similarly linked to the src gene and may be either part of the structural gene for src or a control sequence regulating the expression of src. (iv) The C region at the extreme 3' end of the virus genome which is closely related in all the exogenous avian retroviruses but distinctly different in the endogenous viruses is the major determinant responsible for the differences in growth rate between RAV-0 and Pr-RSV-B. This latter observation allowed us to redefine the C region as a genetic locus, c, with two alleles cn (in RAV-0) and cx (in exogenous viruses).     

Epstein-Barr virus intrastrain recombination in oral hairy leukoplakia.

In laboratory lymphoblastoid cell lines and in natural human infections, Epstein-Barr virus (EBV) strains have been identified by DNA restriction fragment length polymorphisms of the BamHI H fragment. Multiple, heterogeneous BamHI H fragments have been detected in oral hairy leukoplakia (HLP), raising the question of EBV coinfection with multiple strains. To investigate whether the heterogeneous BamHI H fragments represent different EBV strains or recombinant variants of the same strain, EBV DNA from HLP lesions was analyzed to characterize the viral strains and determine the source of possible recombinant variants. Clones of heterogeneous BamHI H fragments from a single HLP lesion were determined to have strain identity on the basis of sequence identity of the EBNA-2 genes. Intrastrain homologous recombination within the IR2 internal repeat region and nonhomologous recombination of other sequences accounted for the heterogeneity of the BamHI H fragments. PCR amplification from additional HLP specimens detected similar recombinant variants. A possible example of site-specific recombination joining the BamHI Y portion of the EBNA-2 gene to sequences within the BamHI S fragment was also detected in multiple HLP specimens. These data indicate that intrastrain recombination during productive replication confounds the use of restriction fragment length polymorphism analysis of the BamHI Y and H fragments to identify EBV strains in HLP. In patients with permissive epithelial EBV infections, EBV strains could be more accurately distinguished by sequence identity or divergence within known regions of genetic strain variation.     

A selectable marker allows investigation of a nontransforming Epstein-Barr virus mutant.

The derivation of specifically mutated Epstein-Barr virus (EBV) recombinants is dependent on strategies to identify, enumerate, and clone infected B lymphocytes. In recent experiments, EBV recombinants containing a positive selection marker were identified and cloned in B-lymphoma (BL) cells infected and then plated under selective conditions (F. Wang, A. Marchini, and E. Kieff, J. Virol. 65:1701-1709, 1991). We now use BL cells, for the first time, as hosts for assaying and cloning otherwise isogenic EBV recombinants carrying a hygromycin phosphotransferase (HYG) gene linked to either a nontransforming deletion mutant or a transforming wild-type EBV nuclear antigen 2 (EBNA-2) gene. Both types of recombinants converted BL cells to hygromycin resistance with similar efficiency, formed episomes, and usually expressed only EBNA-1. Only the wild-type EBNA-2 HYG gene EBV recombinant transformed primary B lymphocytes. This strategy of assaying virus on BL and primary B lymphocytes makes possible the direct assessment of the transforming efficiency of an EBV recombinant. The resultant infected BL cells are also useful for the characterization of the nontransforming recombinant EBV genomes. The HYG gene insertion in the BHLF1 open reading frame eliminated BHLF1 protein expression. The insertion and resulting BHLF1 mutation did not interfere with primary B-lymphocyte infection, growth transformation, induction of lytic infection, or virus production. Thus, these experiments also indicate that neither the BHLF1 open reading frame nor the HYG gene insertion critically affects B-lymphocyte infection in vitro.     

Epstein-Barr virus (EBV) recombinants: use of positive selection markers to rescue mutants in EBV-negative B-lymphoma cells.

The objective of these experiments was to develop strategies for creation and identification of recombinant mutant Epstein-Barr viruses (EBV). EBV recombinant molecular genetics has been limited to mutations within a short DNA segment deleted from a nontransforming EBV and an underlying strategy which relies on growth transformation of primary B lymphocytes for identification of recombinants. Thus, mutations outside the deletion or mutations which affect transformation cannot be easily recovered. In these experiments we investigated whether a toxic drug resistance gene, guanine phosphoribosyltransferase or hygromycin phosphotransferase, driven by the simian virus 40 promoter can be recombined into the EBV genome and can function to identify B-lymphoma cells infected with recombinant virus. Two different strategies were used to recombine the drug resistance marker into the EBV genome. Both utilized transfection of partially permissive, EBV-infected B95-8 cells and positive selection for cells which had incorporated a functional drug resistance gene. In the first series of experiments, B95-8 clones were screened for transfected DNA that had recombined into the EBV genome. In the second series of experiments, the transfected drug resistance marker was linked to the plasmid and lytic EBV origins so that it was maintained as an episome and could recombine with the B95-8 EBV genome during virus replication. The recombinant EBV from either experiment could be recovered by infection and toxic drug selection of EBV-negative B-lymphoma cells. The EBV genome in these B-lymphoma cells is frequently an episome. Virus genes associated with latent infection of primary B lymphocytes are expressed. Expression of Epstein-Barr virus nuclear antigen 2 (EBNA-2) and the EBNA-3 genes is variable relative to that of EBNA-1, as is characteristic of some naturally infected Burkitt tumor cells. Moreover, the EBV-infected B-lymphoma cells are often partially permissive for early replicative cycle gene expression and virus replication can be induced, in contrast to previously reported in vitro infected B-lymphoma cells. These studies demonstrate that dominant selectable markers can be inserted into the EBV genome, are active in the context of the EBV genome, and can be used to recover recombinant EBV in B-lymphoma cells. This system should be particularly useful for recovering EBV genomes with mutations in essential transforming genes.     

Non-immortalizing P3J-HR-1 Epstein-Barr virus: a deletion mutant of its transforming parent, Jijoye.

The P3J-HR-1 strain of Epstein-Barr virus (EBV) fails to immortalize human lymphocytes. We wished to understand the nature of the genomic alterations which correlated with the loss of this ability. As a first step, the heterogeneity of DNA molecules in the P3J-HR-1 line was eliminated by cell cloning. Then a physical map was prepared of virion DNA from one cell clone, designated FF452-3. By comparison with the genomes of two EBVs, B95-8 and FF41, which are competent to immortalize lymphocytes, we identified a total of eight modifications of BamHI and EcoRI restriction endonuclease fragments of EBV (FF452-3) DNA consisting of insertions, deletions, or loss of a restriction endonuclease recognition site. To determine which of these alterations might be responsible for the loss of transforming phenotype, we examined homologous DNA fragments of the Jijoye strain of EBV, the progenitor of the HR-1 strain which still retains the ability to immortalize lymphocytes. We also studied viral DNA in lymphocytes transformed in vitro by Jijoye virus. Six of the eight alterations were found both in Jijoye and in clonal HR-1 DNA and were presumably genomic traits characteristic of this lineage of EBV. A small deletion in the BamHI-K fragment of HR-1 DNA was not found in Jijoye virion DNA, but this deletion was present in intracellular Jijoye DNA. Thus only one major genomic lesion in HR-1 DNA, a deletion of at least 2.4 x 10(6) molecular weight of DNA from a fused BamHI-H-Y fragment, consistently distinguished Jijoye DNA from its non-immortalizing P3J-HR-1 derivative. This deletion is likely to affect EBV genes which are directly or indirectly involved in immortalizing lymphocytes.     

Transforming Sloan-Kettering viruses generated from the cloned v-ski oncogene by in vitro and in vivo recombinations.

The Sloan-Kettering viruses (SKVs) are replication-defective retroviruses that transform avian cells in vitro. Each of the three SKV isolates is a mixture of viruses with genomes ranging in size from 4.1 to 8.9 kilobases (kb) with a predominant genome of 5.7 kb. Using a cDNA representing a sequence, v-ski, that is SKV specific and held in common by the multiple SKV genomes, we generated a restriction map of the 5.7-kb SKV genome and molecularly cloned a ski-containing fragment from SKV proviral DNA. Southern hybridization and sequence analysis showed that the cloned DNA fragment consisted of the 1.3-kb ski sequence embedded in the p19gag sequence and followed by the remaining 5' half of the gag gene and small portions of both the pol and env genes. A large deletion encompassing the 3' half of gag and the 5' 80% of pol was mapped to a position about 1 kb downstream from the 3' ski-gag junction. To determine whether the cloned ski sequence had transforming activity, the ski-containing fragment and a cloned Rous-associated virus 1 (RAV-1) genome were used to construct an analog of the 5.7-kb SKV genome, RAV-SKV. Cotransfection of chicken embryo cells with RAV-SKV and RAV-1 yielded foci of transformed cells whose morphology was identical to that induced by the natural SKVs. The transformed transfected cells produced transforming virus with a 5.7-kb ski-containing genome and synthesized a gag-containing polyprotein of 110 kilodaltons (kDa). Several nonproducer clones of RAV-SKV-transformed cells were analyzed, and most were found to synthesize a 5.7-kb SKV RNA and a 110-kDa polyprotein. One clone was found to contain an 8.9-kb SKV RNA, and this clone synthesized a 125-kDa polyprotein. Since both the 5.7- and 8.9-kb genomes and the 110- and 125-kDa polyproteins had been identified in studies on the natural SKVs, the present results not only demonstrate the transforming activity of these individual SKVs but also suggest mechanisms for their generation.     

The EB virus genome in Daudi Burkitt''s lymphoma cells has a deletion similar to that observed in a non-transforming strain (P3HR-1) of the virus.

Epstein-Barr virus (EBV) DNA isolated from the frequently studied and unusual Burkitt's lymphoma cell line, Daudi, contains a 7.4-kb deletion, similar to (but larger than) that found in a non-transforming isolate of the virus, P3HR-1. A comparison of EBV sequence in Daudi cells with that from a comparable region in a wild-type, transforming strain of the virus (B95-8) indicates that at least two of the previously identified RNAs, a highly repetitive sequence, and other interesting coding or structural features should be absent in Daudi EBV DNA as a consequence of the deletion. The information removed by the deletion, as well as that which might be generated by juxtaposition of two regions of the genome that are not adjacent in most strains of the virus are discussed.     

Cloning of sporulation gene spoIIG in Bacillus subtilis.

Two specialized transducing phages carrying a sporulation gene, spoIIG , of Bacillus subtilis were constructed from B. subtilis temperate phages p11 and phi 105 by the "prophage transformation" method. Restriction enzyme analysis and transformation experiments showed that the spoIIG gene was present on a 6.2 X 10(6)-dalton (6.2-Md) EcoRI fragment in both transducing phage genomes. Further analysis showed that spoIIG + transforming activity resides on a 2.25-Md EcoRI-BamHI fragment within the 6.2-Md EcoRI fragment. The 2.25-Md fragment was subcloned into the region between the EcoRI and BamHI sites of pUB110, and deletion plasmids lacking PstI or HindIII fragments within the 2.25-Md fragment were constructed. The recombinant plasmid carrying the intact spoIIG gene restored sporulation of strain HU1002 ( spoIIG41 recE4 ) to a frequency of 10(4) spores per ml and inhibited sporulation of strain 4309 ( spo + recE4 ) to a level of 10(3) spores per ml.     

Novel swine virulence determinant in the left variable region of the African swine fever virus genome

Previously we have shown that the African swine fever virus (ASFV) NL gene deletion mutant E70DeltaNL is attenuated in pigs. Our recent observations that NL gene deletion mutants of two additional pathogenic ASFV isolates, Malawi Lil-20/1 and Pr4, remained highly virulent in swine (100% mortality) suggested that these isolates encoded an additional virulence determinant(s) that was absent from E70. To map this putative virulence determinant, in vivo marker rescue experiments were performed by inoculating swine with infection-transfection lysates containing E70 NL deletion mutant virus (E70DeltaNL) and cosmid DNA clones from the Malawi NL gene deletion mutant (MalDeltaNL). A cosmid clone representing the left-hand 38-kb region (map units 0.05 to 0.26) of the MalDeltaNL genome was capable of restoring full virulence to E70DeltaNL. Southern blot analysis of recovered virulent viruses confirmed that they were recombinant E70DeltaNL genomes containing a 23- to 28-kb DNA fragment of the Malawi genome. These recombinants exhibited an unaltered MalDeltaNL disease and virulence phenotype when inoculated into swine. Additional in vivo marker rescue experiments identified a 20-kb fragment, encoding members of multigene families (MGF) 360 and 530, as being capable of fully restoring virulence to E70DeltaNL. Comparative nucleotide sequence analysis of the left variable region of the E70DeltaNL and Malawi Lil-20/1 genomes identified an 8-kb deletion in the E70DeltaNL isolate which resulted in the deletion and/or truncation of three MGF 360 genes and four MGF 530 genes. A recombinant MalDeltaNL deletion mutant lacking three members of each MGF gene family was constructed and evaluated for virulence in swine. The mutant virus replicated normally in macrophage cell culture but was avirulent in swine. Together, these results indicate that a region within the left variable region of the ASFV genome containing the MGF 360 and 530 genes represents a previously unrecognized virulence determinant for domestic swine.     

Heterogeneity of Epstein-Barr virus. III. Comparison of a transforming and a nontransforming virus by partial denaturation mapping of their DNAs.

The DNAs of a transforming and a nontransforming Epstein-Barr virus strain, B95-8 AND P3HR-1, were compared by partial denturation mapping. B95-8 viral DNA showed a homogeneous denaturation pattern. In contrast, P3HR-1 viral DNA was heterogeneous, containing at least two classes of molecules, classified into groups A and B and present in a ratio of about 2:1 to 3:1. No evidence could be obtained that molecules from both groups A and B contain identical sequences present in different orientations as described for herpes simplex viral DNA. The majority of sequences present in B95-8 and in P3HR-1 viral DNA group A could be correlated by assuming that different sequences, about 12,000 base pairs long, were inserted or deleted, respectively, at different position of both viral genomes.     

Simple repeat sequence in Epstein-Barr virus DNA is transcribed in latent and productive infections.

The BamHI K region of Epstein-Barr virus DNA is transcribed in latently infected cells from Burkitt tumors and in growth-transformed B-lymphocytes latently infected with Epstein-Barr virus. We determined the nucleotide sequence of a 1,153-base pair HinfI fragment in BamHI fragment K from the B95-8 Epstein-Barr virus isolate. The fragment contains a remarkable 708-base pair simple sequence repeat array, designated IR3, which is composed of only three nucleotide triplet elements: GGG, GCA, and GGA. The triplets are organized into three repeat units: GCAGGA, GCAGGAGGA, and GGGGCAGGA. Immediately 3' of IR3 are tandem nearly perfect direct repeats of two different 24-base pair sequences. IR3 is conserved at a colinear position in the DNAs of other Epstein-Barr virus isolates, and a homologous sequence maps at the same location in the genome of a genetically related baboon herpesvirus, herpesvirus papio. IR3 is transcribed from left to right in latently infected, growth-transformed IB4 cells. It encodes part of a 2.0-kilobase exon of the 3.7-kilobase cytoplasmic polyadenylated RNA previously detected in IB4 cells (van Santen et al., Proc. Natl. Acad. Sci. U.S.A. 78:1930-1934, 1981). IR3 also encodes parts of 2.4- and 1.0-kilobase RNAs in productively infected B95-8 cells.     

Mapping genetic elements of Epstein-Barr virus that facilitate extrachromosomal persistence of Epstein-Barr virus-derived plasmids in human cells.

The Epstein-Barr virus (EBV) genome becomes established as a multicopy plasmid in the nucleus of infected B lymphocytes. A cis-acting DNA sequence previously described within the BamHI-C fragment of the EBV genome (J. Yates, N. Warren, D. Reisman, and B. Sugden, Proc. Natl. Acad. Sci. USA 81:3806-3810, 1984) allows stable extrachromosomal plasmid maintenance in latently infected cells, but not in EBV-negative cells. In agreement with the findings of Yates et al., deletion analysis permitted the assignment of this function to a 2,208-base-pair region (nucleotides 7315 to 9517 of the B95-8 strain of EBV) of the BamHI-C fragment that contained a striking repetitive sequence and an extended region of dyad symmetry. A recombinant vector, p410+, was constructed which carried the BamHI-K fragment (nucleotides 107565 to 112625 of the B95-8 strain, encoding the EBV-associated nuclear antigen EBNA-1), the cis-acting sequence from the BamHI-C fragment, and a dominant selectable marker gene encoding G-418 resistance in animal cells. After being transfected into HeLa cells, this plasmid persisted extrachromosomally at a low copy number, with no detectable rearrangements or deletions. Two mutations in the BamHI-K-derived portion of p410+, a large in-frame deletion and a linker insertion frameshift mutation, both of which alter the carboxy-terminal portion of EBNA-1, destroyed the ability of the plasmid to persist extrachromosomally in HeLa cells. A small in-frame deletion and linker insertion mutation in the region encoding the carboxy-terminal portion of EBNA-1, which replaced 19 amino acid codons with 2, had no effect on the maintenance of p410+ in HeLa cells. These observations indicate that EBNA-1, in combination with a cis-acting sequence in the BamHI-C fragment, is in part responsible for extrachromosomal EBV-derived plasmid maintenance in HeLa cells. Two additional activities have been localized to the BamHI-C DNA fragment: (i) a DNA sequence that could functionally substitute for the simian virus 40 enhancer and promoter elements controlling the expression of G-418 resistance and (ii) a DNA sequence which, although not sufficient to allow extrachromosomal plasmid maintenance, enhanced the frequency of transformation to G-418 resistance in EBV-positive (but not EBV-negative) cells. These findings suggest that the BamHI-C fragment contains a lymphoid-specific or EBV-inducible promoter or enhancer element or both.     

Polymorphic proteins encoded within BZLF1 of defective and standard Epstein-Barr viruses disrupt latency.

These experiments identify an Epstein-Barr virus-encoded gene product, called ZEBRA (BamHI fragment Z Epstein-Barr replication activator) protein, which activates a switch between the latent and replicative life cycle of the virus. Our previous work had shown that the 2.7-kilobase-pair WZhet piece of rearranged Epstein-Barr virus DNA from a defective virus activated replication when introduced into cells with a latent genome, but it was not clear whether a protein product was required for the phenomenon. We now use deletional, site-directed, and chimeric mutagenesis, together with gene transfer, to show that a 43-kilodalton protein, encoded in the BZLF1 open reading frame of het DNA, is responsible for this process. The rearrangement in defective DNA does not contribute to the structural gene for the protein. Similar proteins with variable electrophoretic mobility (37 to 39 kilodaltons) were encoded by BamHI Z fragments from standard, nondefective Epstein-Barr virus genomes. Plasmids expressing the ZEBRA proteins from B95-8 and HR-1 viruses were less efficient at activating replication in D98/HR-1 cells than those which contained the ZEBRA gene from the defective virus. It is not yet known whether these functional differences are due to variations in expression of the plasmids or to intrinsic differences in the activity of these polymorphic polypeptides.     

Evidence for a functional glucocorticoid responsive element in the Epstein-Barr virus genome.

Glucocorticoids induce the expression of Epstein-Barr virus early antigens in latently infected Daudi cells. By sequence analysis, we found that fragment C of the BamHI digested Epstein-Barr virus B95-8 genome contains a region with a large degree of homology to the glucocorticoid responsive element of known glucocorticoid-regulated genes. By transfection experiments in Daudi and HeLa cells, different lengths of this region, cloned in front of the bacterial chloramphenicol acetyl transferase linked to the Herpes Simplex virus thymidine kinase promoter (pBLCAT.2), were assayed for their responsiveness to dexamethasone; our results led us to the conclusion that the hormonal effect observed was mediated by a minimal sequence of 15 base pairs presenting 85% homology with the consensus glucocorticoid responsive element sequence.     

HPRS-103 (exogenous avian leukosis virus, subgroup J) has an env gene related to those of endogenous elements EAV-0 and E51 and an E element found previously only in sarcoma viruses.

The avian leukosis and sarcoma virus (ALSV) group comprises eight subgroups based on envelope properties. HPRS-103, an exogenous retrovirus recently isolated from meat-type chicken lines, is similar to the viruses of these subgroups in group antigen but differs from them in envelope properties and has been assigned to a new subgroup, J. HPRS-103 has a wide host range in birds, and unlike other nontransforming ALSVs which cause late-onset B-cell lymphomas, HPRS-103 causes late-onset myelocytomas. Analysis of the sequence of an infectious clone of the complete proviral genome indicates that HPRS-103 is a multiple recombinant of at least five ALSV sequences and one EAV (endogenous avian retroviral) sequence. The HPRS-103 env is most closely related to the env gene of the defective EAV-E51 but divergent from those of other ALSV subgroups. Probing of restriction digests of line 0 chicken genomic DNA has identified a novel group of endogenous sequences (EAV-HP) homologous to that of the HPRS-103 env gene but different from sequences homologous to EAV and E51. Unlike other replication-competent nontransforming ALSVs, HPRS-103 has an E element in its 3' noncoding region, as found in many transforming ALSVs. A deletion found in the HPRS-103 U3 EFII enhancer factor-binding site is also found in all replication-defective transforming ALSVs (including MC29, which causes rapid-onset myelocytomas).     

Cloning and expression of a Saccharomyces diastaticus glucoamylase gene in Saccharomyces cerevisiae and Schizosaccharomyces pombe.

A recombinant plasmid pool of the Saccharomyces diastaticus genome was constructed in plasmid YEp13 and used to transform a strain of Saccharomyces cerevisiae. Six transformants were obtained which expressed amylolytic activity. The plasmids each contained a 3.9-kilobase (kb) BamHI fragment, and all of these fragments were cloned in the same orientations and had identical restriction maps, which differed from the map of the STA1 gene (I. Yamashita and S. Fukui, Agric. Biol. Chem. 47:2689-2692, 1983). The glucoamylase activity exhibited by all S. cerevisiae transformants was approximately 100 times less than that of the donor strain. An even lower level of activity was obtained when the recombinant plasmid was introduced into Schizosaccharomyces pombe. No expression was observed in Escherichia coli. The 3.9-kb BamHI fragment hybridized to two sequences (4.4 and 3.9 kb) in BamHI-digested S. diastaticus DNA, regardless of which DEX (STA) gene S. diastaticus contained, and one sequence (3.9 kb) in BamHI-digested S. cerevisiae DNA. Tetrad analysis of crosses involving untransformed S. cerevisiae and S. diastaticus indicated that the 4.4-kb homologous sequence cosegregated with the glucoamylase activity, whereas the 3.9-kb fragment was present in each of the meiotic products. Poly(A)+ RNA fractions from vegetative and sporulating diploid cultures of S. cerevisiae and S. diastaticus were probed with the 3.9-kb BamHI fragment. Two RNA species, measuring 2.1 and 1.5 kb, were found in both the vegetative and sporulating cultures of S. diastaticus, whereas one 1.5-kb species was present only in the RNA from sporulating cultures of S. cerevisiae.     

Epstein-Barr virus (EBV)-negative B-lymphoma cell lines for clonal isolation and replication of EBV recombinants.

Previous experiments have demonstrated that positive selection markers recombined into the Epstein-Barr virus (EBV) genome enable the isolation of transforming or nontransforming mutant EBV recombinants in EBV-negative B-lymphoma (BL) cell lines (A. Marchini, J. I. Cohen, and E. Kieff, J. Virol. 66:3214-3219, 1992; F. Wang, A. Marchini, and E. Kieff, J. Virol. 65:1701-1709, 1991). However, virus has been recovered from a BL cell clone (BL41) infected with an EBV recombinant in only one instance (Wang et al., J. Virol. 65:1701-1709, 1991). We now compare the utility of four EBV-negative BL lines, BJAB, BL30, BL41, and Loukes, for isolating EBV recombinants and supporting their subsequent replication. Transforming or nontransforming EBV recombinants carrying a simian virus 40 promoter-hygromycin phosphotransferase (HYG) cassette were cloned by selecting newly infected BL cells for HYG expression. Most of the infected BL clones contained EBV episomes, and EBV gene expression was largely restricted to EBNA-1. Although the BJAB cell line was a particularly good host for isolating EBV recombinants (Marchini et al., J. Virol. 66:3214-3219, 1992), it was largely nonpermissive for virus replication, even in response to heterologous expression of the BZLF1 immediate-early transactivator. In contrast, approximately 50% of infected BL41, BL30, or Loukes cell clones responded to lytic cycle induction. Frequently, a substantial fraction of infected cells expressed the late lytic infection viral protein, gp350/220, and released infectious virus. Since BL cells do not depend on EBV for growth, transforming and nontransforming EBV recombinants were isolated and passaged.