Simian virus 40 tandem repeated sequences as an element of the early promoter

SV40 vector with early gene replacement efficient in transducing exogenous DNA into mammalian cells

An early replacement SV40 vector, SV40-Mu beta, was constructed by replacing part of the early genes of the virus with mouse interferon-beta (IFN-beta) cDNA. Upon transfection of COS-7 cells with this DNA, transducing viral particles were produced, which could infect various cells and cause efficient production of mouse IFN-beta. The viral stock contained no detectable wild-type SV40. The IFN production after the virus infection was very high in monkey kidney cells, but less so in human epithelial cells, and low in mouse, pig, hamster cells and in human lymphocytes. The efficiency of introduction of the DNA to monkey kidney cells was compared with that by the calcium phosphate precipitation method, and the viral vector was found to be more efficient by a factor of several tens to hundreds.

Enhancer-dependent expression of the rat preproinsulin gene in bovine papillomavirus type 1 vectors

The effect of position in a bovine papillomavirus type 1 (BPV-1) vector on foreign gene expression was assessed with the rat preproinsulin (rI1) gene. The rI1 gene was inserted at each of the BPV-1/pML2d junctions in either transcriptional orientation in derivatives of the pdBPV-1(142-6) vector which consists of the BamHI linear genome of BPV-1 DNA cloned into pML2d. Transformed lines of C127 cells were established and assayed for rI1 gene expression. Cells containing the rI1 gene at the 3' end of the BPV-1 transforming region expressed rat proinsulin, whereas cells with the gene at the 5' end of the nontransforming region did not. Variability in the plasmid copy number or in the extent of DNA rearrangement could not account for this difference. We conclude that the expression of the rat preproinsulin gene (which is normally tissue specific for pancreatic islet cells) in C127 cells depends on the transcriptional activation afforded by viral enhancer sequences located at the 3' end of the transforming region. Intervening BPV-1 or pML2d sequences appear to block this enhancer-mediated gene activation. In agreement with enhancer-dependent activation, a rat preproinsulin gene located in a blocked position (i.e., not adjacent to the BPV-1 enhancer) could be activated by the insertion of a DNA fragment containing the simian virus 40, Moloney murine sarcoma virus, or BPV-1 enhancer element adjacent to the rI1 gene. Thus, a gene which is normally not expressed in a particular cell may be activated when placed adjacent to a viral enhancer in a BPV-1 vector.

A modular system for the assay of transcription regulatory signals: the sequence TAATGARAT is required for herpes simplex virus immediate early gene activation

A modular system for assaying the activity of transcriptional regulatory signals based on herpes simplex virus (HSV) promoter and terminator sequences linked to the bacterial chloramphenicol acetyltransferase (CAT) gene has been used to study activation of HSV immediate early (IE) gene expression. Insertion of the SV40 72 base pair (bp) repeat increased mRNA levels by 15-fold thus demonstrating the ability of the HSV IE promoter to respond to a heterologous enhancer. A fragment containing part of the intergenic region located between HSV-2 immediate early (IE) genes-3 and -4/-5 increased mRNA levels by 5-fold in response to transactivation by an HSV virion structural polypeptide. The HSV activator fragment increased mRNA levels by 2-fold in the absence of transactivation indicating that cellular proteins are involved in IE gene expression. From HSV-1/HSV-2 DNA sequence comparisons we previously proposed that a DNA sequence, consensus TAATGARAT, present upstream of all HSV-1 and HSV-2 IE genes was required for the co-ordinate induction of IE genes. We show here that a synthetic oligonucleotide containing TAATGARAT conferred the ability to stimulate CAT activity only on transactivation: two copies of TAATGARAT stimulated expression by 2-fold while six copies gave an 8-fold increase. This activation, which was not dependent on orientation of the TAATGARAT sequence, directly demonstrates that TAATGARAT is a component of the IE gene activation sequence.

Cell type-specific transcriptional enhancement in vitro requires the presence of trans-acting factors

Cell-specific transcriptional enhancement was observed, depending on the enhancer sequences, using nuclear extracts prepared from B-cells, T-cells and HeLa cells. SV40 enhancer stimulated in vitro transcription up to 15-fold in all three cell extracts, whereas transcriptional potentiation in vitro by IgC mu and LPV enhancers was only seen in B- and T-cell extracts. Thus, the cell type specificity seen in vivo can be reproduced in vitro. The transcriptional enhancement requires the presence of enhancer sequences in cis and also of a common factor interacting in trans with all three enhancer sequences. Interestingly, first experiments indicate the additional presence of cellular factors in T-cell and most prominently in HeLa cell extracts which can reduce the enhancer activity of C mu and LPV.

Interaction between two transcriptional control sequences required for tumor-antigen-mediated simian virus 40 late gene expression

Transcriptional control signals required for tumor (T)-antigen trans-activation of the simian virus 40 (SV40) late promoter include T-antigen binding sites I and II and the SV40 72-base-pair (bp) repeats. We have used in vivo competition studies to examine how these signals function in relationship to one another. In vivo competition with recombinant plasmids containing the entire SV40 late regulatory region and promoter sequences [map position (mp) 5171-272] results in quantitative removal of limiting trans-acting factor(s) required for late gene expression in COS-1 cells. Deletion of either the T-antigen binding sites (mp 5171-5243) or the 72-bp tandem repeat (mp 128-272) from the competitor plasmid results in markedly less efficient binding of the trans-acting factor, as judged by the loss of competition. Cotransfection of two separate plasmids, one containing the T-antigen binding sites I and II and the other containing the 72-bp repeats, fails to compete for the trans-acting factors. Insertion of increasing lengths of DNA sequences between the T-antigen binding sites and the enhancer sequences also dramatically reduces the efficiency of competition. These results suggest that efficient binding of trans-acting factors requires the presence, in cis, of at least two SV40 regulatory domains. Our studies further suggest that the distance separating these two transcriptional signals is important.

A viral long terminal repeat in the interleukin 2 gene of a cell line that constitutively produces interleukin 2

The gibbon leukemia cell line MLA 144 differs from every other T-lymphocyte line in that it constitutively makes interleukin 2 (IL-2) (also called T-cell growth factor) without stimulation by antigen, lectin, or tumor promoters. Previous work in which glucocorticoids were used to inhibit IL-2 production has indicated that proliferation of this cell line is dependent upon endogenously produced IL-2. We have found that the MLA 144 cell line has a copy of the gibbon leukemia virus inserted into the 3' nontranslated region of the IL-2 gene. This integration event produces a composite mRNA made up of the protein coding sequences of the IL-2 gene transcript but incorporating the viral long terminal repeat (LTR) in the 3' nontranslated region of the mRNA. This composite mRNA transcript uses the polyadenylylation signal in the viral 5' LTR and incorporates the viral transcriptional control regions. The integration event must involve only one allele of the IL-2 gene, since transcripts essentially identical to normal human IL-2 mRNA are also produced in cloned sublines of MLA 144. That the viral LTR contains a 94-base-pair repeat reminiscent of enhancer sequences in several viruses suggests that the integration of the viral LTR at the 3' end of the IL-2 gene is responsible for the constitutive production of IL-2 in the MLA 144 cell line.

The bovine papillomavirus distal "enhancer" is not cis essential for transformation or for plasmid maintenance

We constructed a mutant of bovine papillomavirus type 1 (BPV-1) DNA that lacked a transcriptional enhancer located 3' to the polyadenylation site of the early viral RNAs expressed in transformed cells. This mutant DNA, when separated from the procaryotic sequences, transforms mouse cells with an efficiency comparable to that of the full BPV-1 genome, and it exists as a stable multicopy plasmid in transformed cells. The BPV-1 distal enhancer suppresses the effects of a cis-inhibitory element in pML2 sequences but is not essential for the expression of the viral genes involved in cellular transformation or plasmid maintenance.

Structural wrinkles and the genomic regulatory sites of eukaryotes

Calculations of DNA angular parameters in 50 eukaryotic sequences reveal regions of large conformational deviations from ideal DNA around regulatory sites. Frequently, discrete peaks of structural variation are present upstream of genes. Known regulatory regions often include variants of consensus sequences. Thus, imprecise sequences and structures are recognized within large genomic stretches. The existence of structurally "wrinkled" regions in the vicinity of regulatory sequences is likely to facilitate greatly their recognition by proteins and enzymes.

Murine leukemia virus long terminal repeat sequences can enhance gene activity in a cell-type-specific manner

We tested the ability of sequences in the long terminal repeat (LTR) of a mink cell focus-forming (MCF) murine leukemia virus to function as an enhancer in a cell-type-specific manner. In a stable transformation assay, the MCF or Akv LTR and the simian virus 40 enhancer had similar activities in murine fibroblasts. In contrast, the MCF LTR had a significantly greater activity in murine T lymphoid cells than did either the simian virus 40 enhancer or the Akv LTR.

Inhibition of DNA-dependent transcription by the leader RNA of vesicular stomatitis virus: role of specific nucleotide sequences and cell protein binding

The leader RNA transcript of vesicular stomatitis virus inhibits transcription of the adenovirus major late promoter and virus-associated genes in a soluble HeLa cell transcription system. We examined the specific nucleotide sequence involved and the potential role of leader-protein interactions in this inhibition of RNA polymerase II- and III-directed transcription. Using synthetic oligodeoxynucleotides homologous to regions of the leader RNA molecule, we extend our previous results (B.W. Grinnell and R.R. Wagner, Cell 36:533-543, 1984) that suggest a role for the AU-rich region of the leader RNA or the homologous AT region of a cloned cDNA leader in the inhibition of DNA-dependent transcription. Our results indicate that a short nucleotide sequence (AUUAUUA) or its deoxynucleotide homolog (ATTATTA) appears to be the minimal requirement for the leader RNA to inhibit transcription by both RNA polymerases, but sequences flanking both sides of this region increase the inhibitory activity. Nucleotide changes in the homologous AT-rich region drastically decrease the transcriptional inhibitory activity. Leader RNAs from wild-type virus, but not from a 5'-defective interfering particle, form a ribonuclease-resistant, protease-sensitive ribonucleoprotein complex in the soluble HeLa cell extract. Several lines of evidence suggest that the leader RNA specifically interacts with a 65,000-dalton (65K) cellular protein. In a fractionated cell extract, only those fractions containing this 65K protein could reverse the inhibition of DNA-dependent RNA synthesis by the plus-strand vesicular stomatitis virus leader RNA or by homologous DNA. In studies with synthetic oligodeoxynucleotides homologous to leader RNA sequences, only those oligonucleotides containing the inhibitory sequence were able to bind to a gradient fraction containing the 65K protein.

Accurate and efficient transcription of human c-myc genes injected into Xenopus laevis oocytes

We investigated the expression of the cloned human c-myc gene in Xenopus laevis oocytes microinjected with different recombinants. We found that microinjected plasmid DNA carrying an intact human c-myc gene directs efficient and faithful transcription from its own two promoters in X. laevis oocytes. This active transcription was unaffected by the presence of previously identified enhancing elements such as simian virus 72-base pair repeats or mouse immunoglobulin heavy-chain gene enhancer sequences in the construct in cis. This suggests that all necessary DNA sequences for accurate and faithful transcription recognized by the transcription machinery of the frog oocyte are self-contained. In addition, we have found that human c-myc transcripts synthesized in oocytes are properly polyadenylated at either one of two sites and also that the transcripts are spliced correctly but with low efficiency.

trans Activation of the simian virus 40 late transcription unit by T-antigen

We have investigated the role of simian virus 40 (SV40) T-antigen in the induction of late gene expression independent of its function in amplifying templates through DNA replication. Northern blot and S1 nuclease analyses showed that stimulation occurred at the transcriptional level. At least two template elements, the T-antigen-binding sites and the 72-base-pair repeats, appeared to be important for this induction. Using template mutants, we demonstrated that deletions within T-antigen-binding site II decreased T-antigen-mediated late gene expression approximately 10- to 20-fold. In addition, multiple point mutations within a single retained copy of the SV40 72-base-pair repeat decreased T-antigen-mediated late gene expression. Using in vivo competition studies, we demonstrated that competitor DNA fragments containing the SV40 control region (nucleotides 5171 through 272) quantitatively decreased SV40 late gene expression in COS-1 cells. In contrast, competition with a plasmid containing SV40 nucleotides 1 through 294 (which removes all of T-antigen-binding site I and half of site II) was much less efficient. Finally, we demonstrated that in vivo competition experiments employing competitor fragments distal to the T-antigen-binding sites within the late template region (SV40 nucleotides 180 through 2533) resulted in superinduction of late gene expression in COS-1 cells. This finding suggests that negative factors such as repressors or attenuators may modulate late SV40 gene expression before induction. Our results are consistent with a model in which induction of late gene expression involves an interaction of the SV40 origin region with DNA-binding proteins, one of which may be T-antigen. Activation of the SV40 late transcription unit may involve induction of the SV40 enhancer or removal of a repressor-like protein or both.

Repression of simian virus 40 early transcription by viral DNA replication in human 293 cells

The small DNA tumour virus simian virus 40 (SV40) has served as an excellent model for many studies on the mechanism and control of gene expression in eukaryotic cells. The SV40 early region produces two protein products. One product (large-T antigen) is known both to repress early viral transcription and to stimulate viral replication by binding to specific sites in the origin-promoter region. The early promoter has several similarities to other RNA polymerase II promoters, for example, it possesses a TATA box, an upstream element and an enhancer. However, the SV40 early promoter differs from other known RNA polymerase II promoters in that the origin of viral DNA replication is embedded within it. Here we show that the SV40 early region is expressed at an extremely low level following its introduction ito human 293 cells, contrasting with results observed in a large number of other cells lines. We show further that the lack of expression is due to repression of transcription from the SV40 early promoter by viral DNA replication which occurs efficiently in 293 cells.

Control of adenovirus late promoter expression in two human cell lines

We investigated the nucleotide sequence requirements of the adenovirus 2 late promoter when activated by either a trans-acting regulatory protein or a cis-acting enhancer element. Using deletion mutants in transient expression assays, we determined that the 5' limit of the region required for activation by a trans-acting regulatory protein, the adenovirus early region 1a gene product, and the simian virus 40 enhancer is the same in both 293 and HeLa cells. Surprisingly, the 3' limit of required sequences varied, depending on the mechanism of activation. Activation mediated by the early region 1a protein endogenous in 293 cells or produced after cotransfection of HeLa cells requires the region around the transcriptional start site, whereas activation brought about by an enhancer element in HeLa cells has no requirement for these sequences. Under no conditions tested did the simian virus 40 enhancer activate the late promoter in 293 cells, even when sequences sufficient for enhancer-mediated activation in HeLa cells, but not for early region 1a activation, were present. These results suggest the existence of at least two different mechanisms for positive regulation of promoter activity.

Control of eukaryotic messenger RNA synthesis by sequence-specific DNA-binding proteins

The enzymatic machinery that carries out RNA synthesis provides the cell with the means to adjust the patterns of transcription in response to environmental and developmental signals. In eukaryotes, this regulation is mediated in part by promoter-specific transcription factors, which are DNA-binding proteins with the ability to discriminate between distinctive DNA sequence elements found in the promoter regions of different genes. The presence of these factors bound to DNA enables other components of the transcriptional machinery, including the RNA polymerase, to initiate transcription with selectivity and accuracy.

SV40 enhancer and large-T antigen are instrumental in development of choroid plexus tumours in transgenic mice

We have shown recently that choroid plexus tumours frequently develop in transgenic mice which have developed from fertilized eggs injected with DNA molecules containing both simian virus 40 (SV40) early-region genes and metallothionein (MT) fusion genes, and several lines of mice have now been established in which all of the offspring that inherit the foreign DNA succumb to these tumours at 3-5 months of age (ref. 1 and our unpublished data). Several other tissues, notably thymus and kidney, occasionally also show pathological changes. SV40 large-T antigen protein and messenger RNA are always present in affected tissues at much greater concentrations than in unaffected tissues, suggesting that SV40 early-region genes are preferentially activated in choroid plexus, thymus and kidney and that this activation frequently leads to tumorigenesis in the choroid plexus. To determine which regions of the original constructs are important for this tumorigenesis, we have now tested several derivatives and report here that the large-T antigen is sufficient, that the MT fusion gene is dispensable and that the SV40 enhancer (72-base-pair repeat region) has an important role in directing tumours to the choroid plexus. Deletion of the SV40 enhancer region alone commonly leads to peripheral neuropathy, as well as liver and pancreatic tumours, which are the subject of the accompanying paper. Evidence is presented that these pathologies may result from an enhancing effect of the MT sequences on large-T antigen genes, made possible by removal of the otherwise dominant SV40 enhancer.

Analysis of an activatable promoter: sequences in the simian virus 40 late promoter required for T-antigen-mediated trans activation

The late promoter of simian virus 40 (SV40) is activated in trans by the viral early gene product, T antigen. We inserted the wild-type late-promoter region, and deletion mutants of it, into chloramphenicol acetyltransferase transient expression vectors to identify promoter sequences which are active in the presence of T antigen. We defined two promoter activities. One activity was mediated by a promoter element within simian virus 40 nucleotides 200 to 270. The activity of this element was detectable only in the presence of an intact, functioning origin of replication and accounted for 25 to 35% of the wild-type late-promoter activity in the presence of T antigen. The other activity was mediated by an element located within a 33-base-pair sequence (simian virus nucleotides 168 to 200) which spans the junction of the 72-base-pair repeats. This element functioned in the absence of both the origin of replication and the T-antigen-binding sites and appeared to be responsible for trans-activated gene expression. When inserted into an essentially promoterless plasmid, the 33-base-pair element functioned in an orientation-dependent manner. Under wild-type conditions in the presence of T antigen, the activity of this element accounted for 65 to 75% of the late-promoter activity. The roles of the 33-base-pair element and T antigen in trans-activation are discussed.

Transient gene expression control: effects of transfected DNA stability and trans-activation by viral early proteins

The effects of trans-acting factors and transfected DNA stability on promoter activity were examined with chloramphenicol acetyl transferase (CAT) transient expression analysis. With cotransfection into CV-1P and HeLa cells, simian virus 40 T antigen, adenovirus E1a, and herpes-virus IE proteins were compared for their ability to trans-activate a variety of eucaryotic promoters constructed into CAT plasmids. T antigen and the IE protein were promiscuous activators of all the promoters tested [the simian virus 40 late promoter, the adenovirus E3 promoter, the alpha 2(I) collagen promoter, and the promoter of the Rous sarcoma virus long terminal repeat]. Conversely the E1a protein was specific, activating only the adenovirus E3 promoter and suppressing the basal activity of the other promoters. This specificity of activation by E1a contrasted with the high activity generated by all of the promoter-CAT plasmids when transfected into 293 cells, which endogenously produce E1a protein. Examination of transfected 293 cells determined that they stabilized much greater amounts of plasmid DNA than any other cells tested (CV-1P, COS, NIH-3T3, KB). Thus the high activity of nonadenovirus promoter-CAT plasmids in 293 cells results from the cumulative effect of basal promoter activity from a very large number of gene copies, not from E1a activation. This conclusion was supported by similar transfection analysis of KB cell lines which endogenously produce E1a protein. These cells stabilize plasmid DNA at a level comparable to that of CV-1P cells and, in agreement with the CV-1P cotransfection results, did not activate a nonadenovirus promoter-CAT plasmid. These results indicate that the stability of plasmid DNA must be considered when transient gene expression is being compared between cell lines. The use of relative plasmid copy numbers for the standardization of transient expression results is discussed.

An enhancer-like sequence within the Xenopus U2 gene promoter facilitates the formation of stable transcription complexes

Enhancers are eukaryotic promoter elements that increase transcriptional efficiency in a manner relatively independent of their position and orientation with respect to a nearby gene. There is growing evidence that enhancer action is mediated by transacting factors, but the mode of action of these factors is not yet known. We report here on the Xenopus U2 gene promoter, which contains two sequence elements. The distal sequence element increases promoter activity 20-fold by facilitating the formation of stable transcription complexes. A synthetic 14-base-pair (bp) oligonucleotide corresponding to part of the distal sequence element, which shows homology to an immunoglobulin gene promoter element and to both the simian virus 40 (SV40) and the immunoglobulin heavy-chain gene enhancers, stimulates transcription in an orientation-independent manner.

Functional analysis of the regulatory region of polyoma mutant F9-1 DNA

Functional analysis of the transcriptional control region of the polyoma (Py) mutant F9-1 reveals that the mutation is located in a region of Py DNA required for at least two functions. First, an enhancer element which includes the F9-1 mutation was characterized by deletion analysis. This element, described previously as enhancer B is essential for viral early gene expression in F9 stem cells whereas enhancer A is unnecessary for transcriptional activity in embryonal carcinoma (EC) cells. Second, a CCACCC motif, present twice in the 3' part of enhancer B is also required in cis for the response to a heterologous enhancer. This suggests that a promoter element is present in this region of the polyoma genome which overlaps Py enhancer B. We also demonstrate the enhancement of the polyoma early promoter activity in F9 stem cells by MSV sequences. The significance of these observations is discussed.

A viral enhancer element specifically active in human haematopoietic cells

One particular class of DNA regulatory elements, the enhancers or activators, can, relatively independently of distance and orientation, dramatically increase the transcriptional activity of homologous and heterologous promoters located in cis (see refs 1-3 for reviews, also refs 4-6). Sequence differences between various heterologous enhancers may explain their apparent host- and/or tissue-specific action. Furthermore, differences in the transcriptional control elements may contribute to viral tropism. At least for murine leukaemia virus isolates, thymotropism and leukaemogenicity have been attributed to alterations within the viral long terminal repeat, which harbours their enhancers and other transcriptional control elements. We report here the identification of a viral enhancer element possessing a very restricted tissue range. The enhancer is active in all human cells of the haematopoetic system tested, but not in cells of fibroblast or epithelial origin.

Accurate and efficient transcription of human c-myc genes injected into Xenopus laevis oocytes

We investigated the expression of the cloned human c-myc gene in Xenopus laevis oocytes microinjected with different recombinants. We found that microinjected plasmid DNA carrying an intact human c-myc gene directs efficient and faithful transcription from its own two promoters in X. laevis oocytes. This active transcription was unaffected by the presence of previously identified enhancing elements such as simian virus 72-base pair repeats or mouse immunoglobulin heavy-chain gene enhancer sequences in the construct in cis. This suggests that all necessary DNA sequences for accurate and faithful transcription recognized by the transcription machinery of the frog oocyte are self-contained. In addition, we have found that human c-myc transcripts synthesized in oocytes are properly polyadenylated at either one of two sites and also that the transcripts are spliced correctly but with low efficiency.

trans Activation of the simian virus 40 late transcription unit by T-antigen

We have investigated the role of simian virus 40 (SV40) T-antigen in the induction of late gene expression independent of its function in amplifying templates through DNA replication. Northern blot and S1 nuclease analyses showed that stimulation occurred at the transcriptional level. At least two template elements, the T-antigen-binding sites and the 72-base-pair repeats, appeared to be important for this induction. Using template mutants, we demonstrated that deletions within T-antigen-binding site II decreased T-antigen-mediated late gene expression approximately 10- to 20-fold. In addition, multiple point mutations within a single retained copy of the SV40 72-base-pair repeat decreased T-antigen-mediated late gene expression. Using in vivo competition studies, we demonstrated that competitor DNA fragments containing the SV40 control region (nucleotides 5171 through 272) quantitatively decreased SV40 late gene expression in COS-1 cells. In contrast, competition with a plasmid containing SV40 nucleotides 1 through 294 (which removes all of T-antigen-binding site I and half of site II) was much less efficient. Finally, we demonstrated that in vivo competition experiments employing competitor fragments distal to the T-antigen-binding sites within the late template region (SV40 nucleotides 180 through 2533) resulted in superinduction of late gene expression in COS-1 cells. This finding suggests that negative factors such as repressors or attenuators may modulate late SV40 gene expression before induction. Our results are consistent with a model in which induction of late gene expression involves an interaction of the SV40 origin region with DNA-binding proteins, one of which may be T-antigen. Activation of the SV40 late transcription unit may involve induction of the SV40 enhancer or removal of a repressor-like protein or both.

DNA rearrangement in the control region for early transcription in a human polyomavirus JC host range mutant capable of growing in human embryonic kidney cells

A human polyomavirus JC virus (JCV) host range mutant (JC-HEK) can grow in human embryonic kidney cells, whereas the brain cell-tropic wild-type JCV strain (Mad-1) cannot; JC-HEK contains two complementing defective DNAs, JC-HEK-A and JC-HEK-B. We determined the nucleotide sequence of the putative transcriptional control region of JC-HEK-A DNA that can induce T-antigen synthesis in human embryonic kidney cells and compared it with the sequence of JCV Mad-1 DNA. The JC-HEK-A control region was found to have a complex DNA rearrangement, namely, a partial local duplication of a noncoding region generating two extra replication origins and translocation of segments from the large-T-antigen gene (415 base pairs) and the VP-1 gene (78 base pairs). In the rearranged segment, JC-HEK-A had seven sets of the sequence 5'TGGA(T)A(T)A(T)3', which is found in the simian virus 40 enhancer core, whereas JCV Mad-1 had only one set in its control region. JC-HEK-A also had a 5'TGGAAGTGTAA3' sequence resembling the adenovirus early region 1A enhancer core sequence 5'AGGAAGTGAA3'. Because the viral enhancer is host discriminatory and because another human polyomavirus, BK virus, that grows well in human embryonic kidney cells has these signals in its control region, it is likely that some of the newly acquired signals in JC-HEK play an important role in the altered host range of JCV.

Simian agent 12 is a BK virus-like papovavirus which replicates in monkey cells

We have begun to characterize the genomic structure and replication of the baboon papovavirus simian agent 12 (SA12). We have defined a wild-type clone of SA12 (SA12 wt100) by plaque purification from a heterogeneous stock. The functional map of SA12 wt100 can be aligned with those of the other primate papovaviruses by assigning one of the two EcoRI sites as 0/1.0 map units. The origin of bidirectional viral DNA replication maps near 0.67 map units, consistent with the limits of sequences homologous to origin sequences in the other papovaviruses. DNA sequence analysis shows that the organization of the SA12 genome is similar to that of the other primate papovaviruses studied. The arrangement and sequence of functional elements in the origin of replication region, as well as the sequences of the N-terminal regions of early protein products, indicate that SA12 is most closely related to the human virus BK, next most closely related to JC virus, and less closely related to simian virus 40. Unlike BK virus, SA12 is capable of productive infection of African green monkey kidney cells.

Transient gene expression control: effects of transfected DNA stability and trans-activation by viral early proteins

The effects of trans-acting factors and transfected DNA stability on promoter activity were examined with chloramphenicol acetyl transferase (CAT) transient expression analysis. With cotransfection into CV-1P and HeLa cells, simian virus 40 T antigen, adenovirus E1a, and herpes-virus IE proteins were compared for their ability to trans-activate a variety of eucaryotic promoters constructed into CAT plasmids. T antigen and the IE protein were promiscuous activators of all the promoters tested [the simian virus 40 late promoter, the adenovirus E3 promoter, the alpha 2(I) collagen promoter, and the promoter of the Rous sarcoma virus long terminal repeat]. Conversely the E1a protein was specific, activating only the adenovirus E3 promoter and suppressing the basal activity of the other promoters. This specificity of activation by E1a contrasted with the high activity generated by all of the promoter-CAT plasmids when transfected into 293 cells, which endogenously produce E1a protein. Examination of transfected 293 cells determined that they stabilized much greater amounts of plasmid DNA than any other cells tested (CV-1P, COS, NIH-3T3, KB). Thus the high activity of nonadenovirus promoter-CAT plasmids in 293 cells results from the cumulative effect of basal promoter activity from a very large number of gene copies, not from E1a activation. This conclusion was supported by similar transfection analysis of KB cell lines which endogenously produce E1a protein. These cells stabilize plasmid DNA at a level comparable to that of CV-1P cells and, in agreement with the CV-1P cotransfection results, did not activate a nonadenovirus promoter-CAT plasmid. These results indicate that the stability of plasmid DNA must be considered when transient gene expression is being compared between cell lines. The use of relative plasmid copy numbers for the standardization of transient expression results is discussed.

Functional RNA polymerase II promoters in solitary retroviral long terminal repeats (LTR-IS elements)

LTR-IS elements are middle repetitive sequences in the mouse genome with structural features of solitary retroviral LTRs. In order to get some insight in the possible functional role of these sequences the promotor activity of two LTR-IS representatives differing by 105 bp in their U3 region was investigated. Gene fusions between LTR-IS sequences and the bacterial gene coding for chloramphenicol acetyl transferase (CAT) were transfected into mouse 3T6 cells and the expression of CAT was measured. It is shown that the LTR-IS sequences represent weak RNA polymerase II promoters which require enhancement by cis-or trans-activating factors.

Transfection of mouse fibroblast cells with a promoterless herpes simplex virus thymidine kinase gene: number of integrated gene copies and structure of single and amplified gene sequences

Plasmids carrying the herpes simplex virus thymidine kinase (tk) gene were used to transfect thymidine kinase-deficient cells of the mouse fibroblast cell line LM(tk-). Individual cell clones were cultivated in selective hypoxanthine-aminopterin-thymidine medium to determine the number of integrated plasmid copies which was almost always in the range of one to three copies per genome. In contrast, cells transfected with plasmids carrying a promoterless "truncated" tk gene typically contained between 10 and 25 copies per genome. Surprisingly, when the truncated tk gene was transfected together with a simian virus 40 DNA segment, including its transcriptional enhancer, the number of integrated tk gene copies was always low, between one and three copies per genome. We have analyzed the genomic organization of integrated truncated tk genes by blot hybridization of restricted cellular DNA and concluded that integrated units of plasmid DNA molecules are arranged in tandem arrays which remain stable in most cases for many cell generations. In only 1 of ca. 20 cell clones did we observe a retraction and expansion of the number of integrated promoterless tk genes as a response to the removal or readdition of selective pressure. Surprisingly, the thymidine kinase activity determined in extracts from cells growing in selective hypoxanthine-aminopterin-thymidine medium (high numbers of integrated tk gene copies) was nearly the same as the enzymatic activity in cells growing in nonselective medium (low copy numbers). Moreover, Northern blots of polyadenylated RNA, extracted from cells growing under selective and nonselective conditions, showed that, in both cases, the major species of tk-specific transcripts was ca. 1.5 kilobases in size, as expected for a tk-specific mRNA containing the entire coding region of the gene. Thus, disproportionate DNA replication appeared not to be essential for an active tk gene expression in these cells. We discuss possible pathways leading to the formation of tandem arrays of integrated truncated tk genes and the conditions required for disproportionate DNA replication in the unique case in which we found a retraction and expansion of tk gene copy numbers as a response to selective growth conditions.

Both trans-acting factors and chromatin structure are involved in the regulation of transcription from the early and late promoters in simian virus 40 chromosomes

We isolated simian virus 40 (SV40) chromosomes from lytically infected CV-1 cells at various times during the late phase and transcribed them in vitro with either whole-cell or nuclear extracts of HeLa cells. The late promoter was 3- to 10-fold more active than the early promoter. With bare SV40 DNA templates, the early promoter was up to 10-fold stronger than the late promoter. The relative strengths of the early and late promoters on SV40 chromosomes were essentially independent of template concentration or length of the replicative phase of the infection. When monoclonal antibodies or antisera against T antigen (T Ag) were added to SV40 chromosomes or when T Ag, both free and chromatin bound, was removed by immunoprecipitation with anti-T, the activity of the late promoter remained essentially unchanged. Washing with 0.4 M NaCl removed T Ag from more than 90% of the mature chromosomes associated with T Ag. Transcription from the late promoter still predominated in the salt-washed T Ag-depleted chromosomes, even though there was a marked increase in early promoter activity. The depression of the early promoter could be reversed by adding the T Ag-containing extract back to the depleted chromosomes. Extraction of SV40 chromosomes with 1.5 M NaCl resulted in a decrease in the activity of the late promoter and a further increase in the activity of the early promoter so that the relative amounts of early and late RNA synthesized were similar to those for bare SV40 DNA templates. Late RNA synthesis from bare SV40 DNA templates was stimulated by high-speed supernatants prepared from nuclear extracts of SV40-infected cells but not from those of uninfected cells. Pretreatment of the supernatants with anti-T did not alter the result. Our findings indicate that the activity of the early and late SV40 promoters is regulated by at least two different mechanisms at the chromosomal level. One is mediated by a subclass of T Ag bound to SV40 chromosomes which represses early SV40 transcription but has no effect on late transcription. A second level of regulation, involving a tightly bound trans-acting chromosomal factor and a stable nucleoprotein structure, favors the late promoter over the early promoter by up to 10-fold.

Adenovirus EIIA early promoter: transcriptional control elements and induction by the viral pre-early EIA gene, which appears to be sequence independent

A molecular dissection of the adenovirus EIIA early (E) promoter was undertaken to study the sequence elements required for transcription and to examine the nucleotide sequences, if any, specific for its trans-activation by the viral pre-early EIA gene product. A chimeric gene in which the EIIA-E promoter region fused to the coding sequences of the bacterial chloramphenicol acetyltransferase (CAT) gene was used in transient assays to identify the transcriptional control regions. Deletion mapping studies revealed that the upstream DNA sequences up to -86 were sufficient for the optimal basal level transcription in HeLa cells and also for the EIA-induced transcription. A series of linker-scanning (LS) mutants were constructed to precisely identify the nucleotide sequences that control transcription. Analysis of these LS mutants allowed us to identify two regions of the promoter that are critical for the EIIA-E transcription. These regions are located between -29 and -21 (region I) and between -82 and -66 (region II). Mutations in region I affected initiation and appeared functionally similar to the "TATA" sequence of the commonly studied promoters. To examine whether or not the EIIA-E promoter contained DNA sequences specific for the trans-activation by the EIA, the LS mutants were analyzed in a cotransfection assay containing a plasmid carrying the EIA gene. CAT activity of all of the LS mutants was induced by the EIA gene in this assay, suggesting that the induction of transcription of the EIIA-E promoter by the EIA gene is not sequence-specific.

Simian virus 40 guanine-cytosine-rich sequences function as independent transcriptional control elements in vitro

We have recently shown that DNA sequences located within the simian virus 40 (SV40) G-C-rich, 21-base-pair repeats constitute an important transcriptional control element of the SV40 late promoter (Brady et al., Mol. Cell. Biol. 4:133-141, 1984). To gain further insight into the mechanism by which the SV40 G-C-rich repeats function, we have analyzed the transcriptional properties of several recombinant DNAs. The results presented in this report suggest that the SV40 G-C-rich sequences can function as independent RNA polymerase II transcriptional-control elements. In vitro competition studies demonstrated that sequences within the G-C-rich, 21-base-pair repeats, in the absence of either the SV40 early or late -25 transcriptional-control signals or the major RNA initiation sites, efficiently competed for transcription factors required for SV40 early and late RNA synthesis. Our transcription studies also demonstrated that in the absence of contiguous SV40 transcription control sequences, G-C-rich sequences stimulated initiation of transcription in a bidirectional manner, from proximally located sequences. Finally, we demonstrated that the 21-base-pair-repeat region can stimulate in vitro transcription from the heterologous adenovirus 2 major late promoter.

Enhanced gene expression by the poly(dT-dG).poly(dC-dA) sequence

The sequence poly(dT-dG).poly(dC-dA) (TG-element) is a ubiquitous component of eucaryotic genomes and has the potential to adopt a left-handed DNA conformation (Z-DNA). In this report, we have tested the hypothesis that the TG-element can modulate gene expression. Human genomic DNA fragments (1 to 1.5 kilobases) containing a (dT-dG)n.(dC-dA)n tract (30, 40, or 50 base pairs) or chemically synthesized (dT-dG)n.(dC-dA)n fragments (50 to 130 base pairs) were inserted in the pSV2-cat (simian virus 40 enhancer plus) or pA10-cat (enhancer minus) expression vector plasmid. These constructs were transfected into CV-1 cells or HeLa cells, and their transcription was monitored by assaying chloramphenicol acetyltransferase activity. The results showed that pSV2-cat with the TG-element and pA10-cat with the TG-element synthesized more chloramphenicol acetyltransferase activity (2 to 10 times, depending on the location of the TG-element) than did parental pSV2-cat and pA10-cat DNAs, respectively. Furthermore, the TG-element appeared to have characteristics similar to those of viral enhancers: (i) the TG-element enhanced transcription from a distance, (ii) its closer location to the promoter was more effective, and (iii) its orientation was not crucial. However, its enhancer-like activity was much weaker than that of the simian virus 40 enhancer, and, unlike many viral enhancers, it was equally active in monkey and in human cells. These results suggest that the TG-element may influence the expression of cellular genes.

Location of sequences in polyomavirus DNA that are required for early gene expression in vivo and in vitro

To define the DNA sequences required for the expression of the polyomavirus early transcription unit, we cloned part of the viral genome in a plasmid vector, isolated mutants bearing lesions introduced in vitro within DNA sequences upstream of the transcriptional start site, and measured the capacity of these various mutant genomes to transform cells and to function as templates for transcription in vitro by comparison with wild-type DNA. One set of mutants bore 5' unidirectional deletions beginning at position -810 and extending downstream to position +4. Another set of mutants bore 3' undirectional deletions starting at position +4 and progressing upstream to position -311. The last set of mutants bore internal deletions between positions -810 and +4. Analyses of the properties of these mutant DNAs led us to conclude that the region between positions -403 and -311 includes an enhancer of gene expression. Deletion of this area from the viral genome reduced gene expression in vivo to 1 to 2% of wild-type levels, as measured by transformation assays. Moreover, this region increased the frequency of transformation of thymidine kinase-negative Rat-2 cells by the herpes simplex virus thymidine kinase (tk) gene from 5- to 20-fold. This occurred only if the polyomavirus sequences were covalently linked to the tk gene and then occurred independently of their orientation or position relative to the tk gene. A second transcriptional element is located downstream of the enhancer between positions -311 and -213. This element together with the enhancer was sufficient to bring about transformation of Rat-1 cells at nearly wild-type frequencies, and together these elements constitute the minimal sequences required for gene expression in vivo. The sequences making up the second element may be functionally duplicated downstream of position -165 (between positions -165 and -60). This was revealed by the characterization of mutant genomes with deletions between positions -349 and -60. The role of these redundant elements is not known; however, they may be analogous to the 21-base-pair repeats of simian virus 40. Finally, sequences between positions -57 and -1 were required for accurate and efficient transcription in vitro. However, this DNA stretch, which includes the TATA box and major transcriptional start sites, was not absolutely required for gene expression in vivo. We conclude that the polyomavirus promoter comprises multiple functional elements which are distributed across a DNA stretch of about 400 base pairs.

Cell-type-specific contacts to immunoglobulin enhancers in nuclei

The introns separating the variable and constant regions of active immunoglobulin genes contain tissue-specific transcriptional enhancer elements, DNA segments which act in cis in an orientation- and distance-independent (up to a few kilobases (kb)) manner to enhance transcription initiation at adjacent promoters. The immunoglobulin heavy-chain enhancer is active only in lymphoid cells: in transfection assays it is capable of controlling in cis transcription from the simian virus 40 (SV40) T-antigen, rabbit beta-globin and immunoglobulin gene promoters up to at least 2 kb away. Genetic deletion analysis suggests that a region of as few as 140 base pairs (bp) is sufficient for the enhancement effect. These functional characteristics and DNA sequences are conserved between mouse and man. However, it is not known whether tissue-specific proteins bind to the enhancer. Proteins that interact with DNA at specific sequences can prevent or enhance the reactions of individual guanines or adenines with dimethyl sulphate (DMS), and this property has been used to display the DNA contacts of various regulatory proteins. Here we apply this DMS strategy in experiments involving single-copy genes within intact mammalian nuclei using genomic sequencing.

Differential activation of RNA polymerase III-transcribed genes by the polyomavirus enhancer and the adenovirus E1A gene products

We have compared the effect of the polyomavirus cis-acting transcriptional enhancer and the adenovirus trans-acting E1A gene on expression of RNA polymerase III-transcribed genes (the adenovirus VAI gene and a bacterial tRNA gene) using DNA transfection and transient expression assays. The polyomavirus enhancer has little effect upon transcription of the VAI gene by RNA polymerase III in any cell type tested (murine, hamster, or human). In contrast, expression of the E1A gene within adenovirus infected cells stimulates transcription of RNA polymerase III-transcribed genes from co-transfected DNAs. Human 293 cells, which constitutively produce adenovirus E1A gene products, also express high levels of RNA polymerase III transcripts from transfected DNAs.

Duplications of a mutated simian virus 40 enhancer restore its activity

Enhancers are cis-acting control elements which can stimulate at a distance the activity of a variety of eukaryotic promoters. First identified as a repeated 72 base pair (bp) sequence upstream of the simian virus 40 (SV40) early gene promoter, enhancers have since been shown to be associated with numerous other viral and cellular genes. Although there are no strong homologies between the sequences of different enhancers, a number of short and degenerate consensus sequences have been identified, including the 'core' element GTGGA/TA/TA/TG and stretches of alternating purines and pyrimidines which may have the potential to form left-handed Z DNA. To study the functional significance of two alternating purine and pyrimidine sequences in the SV40 enhancer, we have introduced various combinations of point mutations into a modified SV40 enhancer which contained only one copy of the 72 bp element (W.H., Y.G., A. Nordheim and A. Rich, unpublished results); one of these combinations impaired both the activity of the enhancer and growth of SV40. We describe here the structure of 18 revertants of this mutant and suggest that in each of the 18 revertants, the defects of the original mutant have been overcome by simple tandem duplications in the enhancer region, all of which include the 'core' element.

A trans-acting factor is responsible for the simian virus 40 enhancer activity in vitro

Stimulation of in vitro transcription by the simian virus 40 enhancer involves a rapid and stable binding of a trans-acting factor with both the 5'- and 3'-domains of the enhancer sequence. The enhancer factor, which differs from other types of transcriptional factors, can interact with other enhancer elements.

A human hepatitis B viral enhancer element

Fragments of the cloned hepatitis B virus (HBV) genome were assayed in vivo for the presence of a transcriptional enhancer element. We demonstrate that sequences positioned approximately 450 bp upstream from the HBcAg gene promoter are required for its efficient activity. These HBV stimulatory sequences activate transcription when inserted upstream to a heterologous SV40 early promoter. Like other known enhancer elements, this HBV sequence acts in an orientation-independent manner. Furthermore, the HBV enhancer element exhibits a preferred activity in a human hepatoma cell line.

Transfection of mouse fibroblast cells with a promoterless herpes simplex virus thymidine kinase gene: number of integrated gene copies and structure of single and amplified gene sequences

Plasmids carrying the herpes simplex virus thymidine kinase (tk) gene were used to transfect thymidine kinase-deficient cells of the mouse fibroblast cell line LM(tk-). Individual cell clones were cultivated in selective hypoxanthine-aminopterin-thymidine medium to determine the number of integrated plasmid copies which was almost always in the range of one to three copies per genome. In contrast, cells transfected with plasmids carrying a promoterless "truncated" tk gene typically contained between 10 and 25 copies per genome. Surprisingly, when the truncated tk gene was transfected together with a simian virus 40 DNA segment, including its transcriptional enhancer, the number of integrated tk gene copies was always low, between one and three copies per genome. We have analyzed the genomic organization of integrated truncated tk genes by blot hybridization of restricted cellular DNA and concluded that integrated units of plasmid DNA molecules are arranged in tandem arrays which remain stable in most cases for many cell generations. In only 1 of ca. 20 cell clones did we observe a retraction and expansion of the number of integrated promoterless tk genes as a response to the removal or readdition of selective pressure. Surprisingly, the thymidine kinase activity determined in extracts from cells growing in selective hypoxanthine-aminopterin-thymidine medium (high numbers of integrated tk gene copies) was nearly the same as the enzymatic activity in cells growing in nonselective medium (low copy numbers). Moreover, Northern blots of polyadenylated RNA, extracted from cells growing under selective and nonselective conditions, showed that, in both cases, the major species of tk-specific transcripts was ca. 1.5 kilobases in size, as expected for a tk-specific mRNA containing the entire coding region of the gene. Thus, disproportionate DNA replication appeared not to be essential for an active tk gene expression in these cells. We discuss possible pathways leading to the formation of tandem arrays of integrated truncated tk genes and the conditions required for disproportionate DNA replication in the unique case in which we found a retraction and expansion of tk gene copy numbers as a response to selective growth conditions.

Identification of regulatory regions within the Ty1 transposable element that regulate iso-2-cytochrome c production in the CYC7-H2 yeast mutant

The CYC7-H2 mutation in the yeast Saccharomyces cerevisiae was caused by insertion of a Ty1 transposable element in front of the iso-2-cytochrome c structural gene, CYC7. The Ty1 insertion places iso-2-cytochrome c production under control of regulatory signals that are normally required for mating functions in yeast cells. We have investigated the regions of the Ty1 insertion that are responsible for the aberrant production of iso-2-cytochrome c in the CYC7-H2 mutant. Five alterations of the CYC7-H2 gene were obtained by specific restriction endonuclease cleavage of the cloned DNA and ligation of appropriate fragments. The CYC7+, CYC7-H2, and modified CYC7-H2 genes were each inserted into the yeast vector YIp5 and used to transform a cytochrome c-deficient yeast strain. Expression and regulation of each allele integrated at the CYC7 locus have been compared in vivo by determination of the amount of iso-2-cytochrome c produced. These results show that distal regions of the Ty1 element are not essential for the CYC7-H2 overproducing phenotype. In contrast, alterations in the vicinity of the proximal Ty1 junction abolish the CYC7-H2 expression and give rise to different phenotypes.

Transcription control region within the protein-coding portion of adenovirus E1A genes

A single-base deletion within the protein-coding region of the adenovirus type 5 early region 1A (E1A) genes, 399 bases downstream from the transcription start site, depresses transcription to 2% of the wild-type rate. Complementation studies demonstrated that this was due to two effects of the mutation: first, inactivation of an E1A protein, causing a reduction by a factor of 5; second, a defect which acts in cis to depress E1A mRNA and nuclear RNA concentrations by a factor of 10. A larger deletion within the protein-coding region of E1A which overlaps the single-base deletion produces the same phenotype. In contrast, a linker insertion which results in a similar truncated E1A protein does not produce the cis-acting defect in E1A transcription. These results demonstrate that a critical cis-acting transcription control region occurs within the protein coding sequence in adenovirus type 5 E1A. The single-base deletion occurs in a sequence which shows extensive homology with a sequence from the enhancer regions of simian virus 40 and polyomavirus. This region is not required for E1A transcription during the late phase of infection.

Naturally occurring BK virus variants (JL and Dik) with deletions in the putative early enhancer-promoter sequences

The genomes of two independently isolated BK virus (BKV) variants (JL and Dik) were compared with prototype BKV DNA by restriction endonuclease mapping and sequence analysis. Differences were mainly detected in two regions: the BKV (JL) and BKV (Dik) putative early enhancer-promoter regions and the middle of the T-antigen-coding regions. Base sequence analysis of these two regions showed the following. (i) The putative enhancer-promoter regions of BKV (Dik) and BKV (JL) contained only one 68-base-pair (bp) unit of the 68-bp triplication (the central copy of which is missing 18 bp) present in prototype BKV. (ii) In the same region, BKV (JL) and BKV (Dik) contained unique stretches of DNA 33 and 63 bp long, respectively. In these 63 bp, a sequence which was very similar to the proposed simian virus 40 enhancer core sequence (GGAGTGGAAAG) was present. (iii) The altered restriction endonuclease recognition sites in the sequenced part of the T-antigen-coding region of BKV (JL) and BKV (Dik) were due to base sequence changes, leaving the amino acid sequence unchanged.

Attenuation may regulate gene expression in animal viruses and cells

In eukaryotes, an abundant population of promoter-proximal RNA chains have been observed and studied, mainly in whole nuclear RNA, in denovirus type 2, and in SV40. On the basis of these results it has been suggested that a premature termination process resembling attenuation in prokaryotes occurs in eukaryotes. Moreover, these studies have shown that the adenosine analog 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB) enhances premature termination, but its mode of action is not understood. The determination of the nucleotide sequences of SV40 and other viruses and cellular genes provide means for elucidating the nucleotide sequences involved in the attenuation mechanism. A model has recently been described in which attenuation and mRNA modulation in a feedback control system quantitatively regulate SV40 gene expression. The suggested mechanism described in this model opens up approaches to the investigation of attenuation and mRNA modulation as a possible mechanism whereby eukaryotes may regulate transcription in a variety of different circumstances.

Differences in regulatory sequences of naturally occurring JC virus variants

The regulatory region was sequenced for DNAs representative of seven independent isolates of JC virus, the probable agent of progressive multifocal leukoencephalopathy. The isolates included an oncogenic variant (MAD-4), an antigenic variant (MAD-11), and two different isolates derived from the urine (MAD-7) and from the brain (MAD-8) of the same patient. The representative DNAs were molecularly cloned directly from diseased brain tissue and from human fetal glial cells infected with the corresponding isolated viruses. The regulatory sequences of these DNAs were compared with those of the prototype isolate, MAD-1, sequenced previously (R. J. Frisque, J. Virol. 46:170-176, 1983). We found that the regulatory region of JC viral DNA is highly variable due to complex alterations of the previously described 98-base-pair repeat of MAD-1 DNA. On the basis of these alterations, there are two general types of JC virus. There were no consistent alterations in regulatory sequences which could distinguish brain tissue DNAs from tissue culture DNAs. Furthermore, for each isolate except MAD-1 (R. J. Frisque, J. Virol. 46:170-176, 1983), the regulatory regions of brain tissue and tissue culture DNAs were not identical. The arrangement, sequence, or both of potential regulatory elements (TATA sequence, GGGXGGPuPu, tandem repeats) of JC viral DNAs are sufficiently different from those in other viral and eucaryotic systems that they may effect the unique properties of this slow virus.

JC virus enhancer-promoter active in human brain cells

A human papovavirus, JCV, is the etiologic agent of the fatal demyelinating disease, progressive multifocal leukoencephalopathy. The JCV 98-base-pair tandem repeats, located to the late side of the viral replication origin, were shown to be a transcriptional regulatory element with enhancer-like activity in human fetal glial cells. These tandem repeats share significant homology with the 82-nucleotide rat brain-specific identifier RNA sequence.

The MLV and SV40 enhancers have a similar pattern of transcriptional activation

Activation of transcription by the Moloney Murine Leukemia Virus (MLV) and Simian Virus (SV40) enhancers was compared by transfecting recombinants containing these enhancers in either mouse or human cell-lines, and analysing RNA 48 h later by quantitative S1 nuclease mapping. The enhancers share the following properties. They stimulate transcription in an orientation-independent manner from the same startsites on the natural heterologous conalbumin (+62 to -102) or SV40 early promoter elements as well as on substitute promoter elements. The enhancers are most efficient when they are located directly upstream from the conalbumin (+62 to -102) promoter element, but they still stimulate transcription when they are either immediately downstream from the promoter element, or further upstream. Increasing the distance by interposing DNA sequences between the enhancers and the conalbumin promoter fragment results in decreased activation. Both enhancers show some cell-line specificity for activation of transcription. However, in all cell-lines and constructions tested the MLV enhancer was always less efficient than the SV40 enhancer. These results suggest that the MLV and SV40 enhancers stimulate transcription by similar mechanisms.

Upstream activation sites of the CYC1 gene of Saccharomyces cerevisiae are active when inverted but not when placed downstream of the "TATA box"

The ability of the upstream activation sites (UASs) of the yeast CYC1 gene to function when inverted or when positioned downstream of the "TATA box" is investigated. Inversion of a 130-base-pair DNA fragment bearing the UASs leaves the activity of the sites almost completely intact. In contrast, positioning the sites downstream of the TATA box or in the intron of a CYC1-ribosomal protein 51-lacZ tribrid gene almost totally abolishes their activity. In the latter construct, the separation between the UASs and TATA box is roughly equivalent to that between the elements in the intact CYC1 promoter region. The UASs are shown not to interrupt transcription of splicing in this construct since a GAL10 UAS positioned upstream of the TATA box gives rise to galactose-inducible expression of the tribrid gene. The inability of the UASs to function in the intron is partly due to sequences between the intron and the TATA box that block the activation signal. However, a large component of the inactivity of the sites in the intron appears to be their downstream location. This result is discussed in light of possible mechanisms of upstream activation in yeast.

Enhanced gene expression by the poly(dT-dG).poly(dC-dA) sequence

The sequence poly(dT-dG).poly(dC-dA) (TG-element) is a ubiquitous component of eucaryotic genomes and has the potential to adopt a left-handed DNA conformation (Z-DNA). In this report, we have tested the hypothesis that the TG-element can modulate gene expression. Human genomic DNA fragments (1 to 1.5 kilobases) containing a (dT-dG)n.(dC-dA)n tract (30, 40, or 50 base pairs) or chemically synthesized (dT-dG)n.(dC-dA)n fragments (50 to 130 base pairs) were inserted in the pSV2-cat (simian virus 40 enhancer plus) or pA10-cat (enhancer minus) expression vector plasmid. These constructs were transfected into CV-1 cells or HeLa cells, and their transcription was monitored by assaying chloramphenicol acetyltransferase activity. The results showed that pSV2-cat with the TG-element and pA10-cat with the TG-element synthesized more chloramphenicol acetyltransferase activity (2 to 10 times, depending on the location of the TG-element) than did parental pSV2-cat and pA10-cat DNAs, respectively. Furthermore, the TG-element appeared to have characteristics similar to those of viral enhancers: (i) the TG-element enhanced transcription from a distance, (ii) its closer location to the promoter was more effective, and (iii) its orientation was not crucial. However, its enhancer-like activity was much weaker than that of the simian virus 40 enhancer, and, unlike many viral enhancers, it was equally active in monkey and in human cells. These results suggest that the TG-element may influence the expression of cellular genes.