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

Genetic Diversity of the Noncoding Control Region of the Novel Human Polyomaviruses

The genomes of polyomaviruses are characterized by their tripartite organization with an early region, a late region and a noncoding control region (NCCR). The early region encodes proteins involved in replication and transcription of the viral genome, while expression of the late region generates the capsid proteins. Transcription regulatory sequences for expression of the early and late genes, as well as the origin of replication are encompassed in the NCCR. Cell tropism of polyomaviruses not only depends on the appropriate receptors on the host cell, but cell-specific expression of the viral genes is also governed by the NCCR. Thus far, 15 polyomaviruses have been isolated from humans, though it remains to be established whether all of them are genuine human polyomaviruses (HPyVs). The sequences of the NCCR of these HPyVs show high genetic variability and have been best studied in the human polyomaviruses BK and JC. Rearranged NCCRs in BKPyV and JCPyV, the first HPyVs to be discovered approximately 30 years ago, have been associated with the pathogenic properties of these viruses in nephropathy and progressive multifocal leukoencephalopathy, respectively. Since 2007, thirteen novel PyVs have been isolated from humans: KIPyV, WUPyV, MCPyV, HPyV6, HPyV7, TSPyV, HPyV9, HPyV10, STLPyV, HPyV12, NJPyV, LIPyV and QPyV. This review describes all NCCR variants of the new HPyVs that have been reported in the literature and discusses the possible consequences of NCCR diversity in terms of promoter strength, putative transcription factor binding sites and possible association with diseases.

RNA processing in the polyoma virus life cycle

Not only is gene regulation in polyoma interesting, but it has also proven to be highly informative and illustrative of a number of novel concepts in gene regulation. Of special interest and importance are the mechanisms by which this virus switches from the expression of early gene products to late gene products after the onset of viral DNA replication. This switch is mediated at least in part by changes in transcription elongation and polyadenylation in the late region, and by the formation and editing of dsRNA in the nucleus. In this review we will summarize the regulation of RNA synthesis and processing during polyoma infection, and will point out in particular those aspects that have been most novel.

Role of middle T-small T in the lytic cycle of polyomavirus: control of the early-to-late transcriptional switch and viral DNA replication

A comparative analysis of the lytic cycle of wild-type polyomavirus and middle T and small T defective mutants was carried out in the A2 genetic background. The results contrast with those obtained in comparisons between the hr-t type and their middle-T small-T-producing partners as previously described (20). The A2-derived mutants were found to share the maturation defect previously described for the hr-t mutants. However, their defect in DNA replication was more acute, resulting in a 5- to 100-fold decrease in the accumulation of viral genomes. Furthermore, their gene expression pattern was affected. A2-derived mutants displayed an early defect resulting in a 4- to 16-h delay in the expression of large T, and an alteration of the early-to-late transcriptional switch. In wild-type A2 infection, this switch is characterized by a large increase in the accumulation of early transcripts followed by late transcripts after the appearance of middle T and small T proteins and the onset of viral DNA replication (L. Chen and M. M. Fluck, J. Virol. 75: 8368-8379, 2001). In the mutant infection, increases in both classes of transcripts were delayed and reduced, but the effect on early transcripts was more pronounced. As has been described previously for the hr-t mutants (E. Goldman, J. Hattori, and T. Benjamin, Cell 13:505-513, 1979), the magnitude of these defects depended upon experimental conditions. Experiments using cytosine beta-arabinofuranoside to reduce genome amplification suggest that the effect of middle T-small T on the transcriptional switch is not solely mediated by the effect of these protein(s) on increasing the number of templates. These data provide the first direct demonstration of an effect of middle T and/or small T in the viral transcription pattern during viral infection. The results agree with previous results obtained with plasmid reporters and with our understanding that the downstream targets of the middle T signaling pathway include three transcription factors that have binding sites in the enhancer domain that play a key regulatory role in the expression of the viral genes.

Kinetic analysis of the steps of the polyomavirus lytic cycle

Kinetic studies of the accumulation of early and late transcripts, early and late proteins, genomes, and live virus, during the lytic cycle of murine polyomavirus wild-type A2, were carried out in synchronized NIH 3T3 cells released from G(0) by the addition of serum after infection. This first-time simultaneous analysis of all parameters of the virus life cycle led to new insights concerning the transcriptional control at the early-to-late transition. During the early phase, early transcripts were synthesized at very low levels, detectable only by reverse transcription-PCR, from 6 h postinfection (hpi). Large T protein could be detected by 8 hpi (while infected cells were in the G(1) phase). The level of expression of the middle T and small T proteins was lower than that of large T at all times, due, at least in part, to a splicing preference for the large-T 5' splice site at nucleotide 411. A large increase in the level of both early and late transcripts coincided closely with the detection in mid-S phase of viral genome amplification. Thereafter, both classes of transcripts continued to further accumulate up to the end of the experiments (48 hpi). In addition, during the late phase, "giant" multigenomic transcripts were synthesized from the early as well as the late promoter. Thus, a major type of transcriptional control appears to be applied similarly to the transcription of both early and late genes. This view differs from that in the literature, which highlights the enhancement of late transcription and the repression of early transcription. However, despite this parallel transcriptional control, additional regulations are applied which result in higher levels of late compared to early transcripts, as previously described. In the accompanying article, a key role for middle T and/or small T in this late-phase enhancement of early and late transcription is demonstrated (16). Other novel findings, e.g., the synthesis of a very abundant short early promoter proximal RNA, are also described.

Natural biology of polyomavirus middle T antigen

"It has been commented by someone that 'polyoma' is an adjective composed of a prefix and suffix, with no root between--a meatless linguistic sandwich" (C. J. Dawe). The very name "polyomavirus" is a vague mantel: a name given before our understanding of these viral agents was clear but implying a clear tumor life-style, as noted by the late C. J. Dawe. However, polyomavirus are not by nature tumor-inducing agents. Since it is the purpose of this review to consider the natural function of middle T antigen (MT), encoded by one of the seemingly crucial transforming genes of polyomavirus, we will reconsider and redefine the virus and its MT gene in the context of its natural biology and function. This review was motivated by our recent in vivo analysis of MT function. Using intranasal inoculation of adult SCID mice, we have shown that polyomavirus can replicate with an MT lacking all functions associated with transformation to similar levels to wild-type virus. These observations, along with an almost indistinguishable replication of all MT mutants with respect to wild-type viruses in adult competent mice, illustrate that MT can have a play subtle role in acute replication and persistence. The most notable effect of MT mutants was in infections of newborns, indicating that polyomavirus may be highly adapted to replication in newborn lungs. It is from this context that our current understanding of this well-studied virus and gene is presented.

An enhancer of recombination in polyomavirus DNA

Previous work from this laboratory has indicated that intramolecular homologous recombination of polyomavirus (Py) DNA is dependent upon promoter structure or function. In this report, we demonstrate that Py DNA contains not two but three binding sites for transcription factor YY1, all located on the late side of viral origin of replication (ori) and the third well within the VP1 coding sequence. This third site (Y3), which may or may not play a role in transcription regulation, is immediately adjacent to a previously described recombination hot spot (S1/S2). We found that Py replicons carrying an altered Y3 site recombined in a manner suggesting partial inactivation of the S1/S hot spot. Point mutations precluding the binding of YY1 to Y3 in vitro depressed hot spot activity in vivo; however, of the two reciprocal products reflecting recombination at this spot, only that carrying the mutated Y3 site arose at a reduced rate. These results are interpreted in light of a model assuming that recombination occurs within a transcriptionally active viral chromatin tethered to the nuclear matrix by YY1.

Different roles for two enhancer domains in the organ- and age-specific pattern of polyomavirus replication in the mouse

Viral replication in mice infected with murine polyomavirus strains with novel enhancer rearrangements was analyzed by direct in situ hybridization of whole mouse sections and by hybridization of nucleic acids extracted from a specific set of organs. The enhancer rearrangements included a deletion of the B domain as well as duplications within the A domain. Comparisons between enhancer variants demonstrate that the B domain plays an important role in replication in most organs, in particular in the kidney, at the neonatal stage (days 0 to 7 postbirth). In contrast, the B domain is not required in those organs which can sustain replication in the adult, i.e. mammary gland, skin, and bone (class I organs [J. J. Wirth, A. Amalfitano, R. Gross, M. B. A. Oldstone, and M. M. Fluck, J. Virol. 66:3278-3286, 1992]). Altogether, the results suggest that the B and A domains mediate very different functions in infection of mice, controlling the acute and persistent phases of infection, respectively. A model of mouse infection based on the crucial role of differentially expressed host transcription factors is presented.

Different roles for two enhancer domains in the organ- and age-specific pattern of polyomavirus replication in the mouse

Viral replication in mice infected with murine polyomavirus strains with novel enhancer rearrangements was analyzed by direct in situ hybridization of whole mouse sections and by hybridization of nucleic acids extracted from a specific set of organs. The enhancer rearrangements included a deletion of the B domain as well as duplications within the A domain. Comparisons between enhancer variants demonstrate that the B domain plays an important role in replication in most organs, in particular in the kidney, at the neonatal stage (days 0 to 7 postbirth). In contrast, the B domain is not required in those organs which can sustain replication in the adult, i.e. mammary gland, skin, and bone (class I organs [J. J. Wirth, A. Amalfitano, R. Gross, M. B. A. Oldstone, and M. M. Fluck, J. Virol. 66:3278-3286, 1992]). Altogether, the results suggest that the B and A domains mediate very different functions in infection of mice, controlling the acute and persistent phases of infection, respectively. A model of mouse infection based on the crucial role of differentially expressed host transcription factors is presented.

PEA1 and PEA3 enhancer elements are primary components of the polyomavirus late transcription initiator element

The circular polyomavirus genome is transcribed from divergent promoter regions. Early mRNAs are initiated from a transcription complex formed at a TATA motif, the site of binding of transcription factor TFIID. Early transcription is promoted at a distance by the viral enhancer, which includes DNA motifs bound by cellular proteins of the PEA1 and PEA3 families of transcription activators. In contrast, the predominant viral late mRNAs are initiated within the viral enhancer, which lacks a TATA motif, near the PEA1 and PEA3 DNA motifs. Here, we demonstrate that these PEA1 and PEA3 binding sites are primary components of an autonomous transcription initiator element (Inr). They cause transcription of most polyomavirus late mRNAs and can direct the transcription of heterologous reporter genes. Alternative roles of these DNA motifs as activators of early mRNA transcription and as an initiator element for late mRNA transcription help explain how polyomavirus gene expression is regulated during lytic growth and provides a model for cellular transcription during development.

Single strand binding protein specific for the polyoma early-coding strand of PEA1 (AP1) regulatory sequence

We have shown that nuclear and cytosolic proteins from embryonal carcinoma F9 cells are able to bind to the early-coding strand of polyoma enhancer A domain. As demonstrated by mobility shift specific competition experiments, DNase I footprinting, depurination and depyrimidation interference, and proteolytic clipping performed with single stranded oligonucleotides, some of these proteins bind specifically to the early-coding PEA1 (AP1) motif. In addition, 'Southwestern' analysis has made possible the identification of a 46 KD nuclear protein that binds to this sequence. These cellular proteins did not bind to the complementary single strand as demonstrated by mobility shift analysis, nor did they bind to RNA synthesized in vitro by using the complementary strand as template. They were also shown to be different from their corresponding double strand binding factors. This new dimension in the functional flexibility and complexity of the polyoma enhancer suggests new properties of the classic regulating sequences that could provide additional modulation of regulating activities.

Purification of a mouse nuclear factor that binds to both the A and B cores of the polyomavirus enhancer

We have previously identified a protein factor, PEBP2 (polyomavirus enhancer-binding protein), in the nuclear extract from mouse NIH 3T3 cells which binds to the sequence motif, PEA2, located within the polyomavirus enhancer A element. Upon cellular transformation with activated oncogene c-Ha-ras, this factor frequently undergoes drastic molecular modifications into an altered form having a considerably reduced molecular size. In this study, the altered form, PEBP3, was purified to near homogeneity. The purified PEBP3 comprised two sets of families of polypeptides, alpha-1 to alpha-4 and beta-1 to beta-2, which were 30 to 35 kilodaltons and 20 to 25 kilodaltons in size, respectively. Both kinds of polypeptides possessed DNA-binding activities with exactly the same sequence specificity. Individual alpha or beta polypeptides complexed with DNA showed faster gel mobilities than did PEBP3. However, the original gel retardation pattern was restored when alpha and beta polypeptides were mixed together in any arbitrary pair. These observation along with the results of UV- and chemical-cross-linking studies led us to conclude that PEBP3 is a heterodimer of alpha and beta subunits, potentially having a divalent DNA-binding activity. Furthermore, PEBP3 was found to bind a second, hitherto-unnoticed site of the polyomavirus enhancer that is located within the B element and coincides with the sequence previously known as the simian virus 40 enhancer core homology. From comparison of this and the original binding sites, the consensus sequence for PEBP3 was defined to be PuACCPuCA. These findings provided new insights into the biological significance of PEBP3 and PEBP2.

Replication-dependent transactivation of the polyomavirus late promoter

When a plasmid containing the wild-type polyomavirus intergenic regulatory region fused to the bacterial cat gene was introduced into mouse NIH 3T3 cells along with a plasmid coding for the early viral proteins (T antigens), chloramphenicol transacetylase enzyme activity and mRNA levels were increased about 10-fold over levels observed in the absence of early proteins. To investigate this transactivation phenomenon further, 11 specific deletion mutant derivatives of the wild-type parent plasmid were constructed and studied. One mutant (NAL) with a minimal level of chloramphenicol transacetylase expression in the absence of T antigens was capable of being transactivated more than 40-fold. A number of other mutants, however, had little capacity for transactivation. Each of these mutants had in common a defect in large T-antigen-mediated DNA replication. Interestingly, one of the transactivation-defective mutants showed a basal late promoter activity fivefold higher than that of wild type and replicated in mouse cells in the absence of large T antigen. Subsequently, a small deletion abolishing viral DNA replication was introduced into those mutants capable of transactivation. The effect of the second deletion was to eliminate both replication and transactivation. Finally, wild-type and mutant constructs were transfected into Fisher rat F-111 cells in the presence or absence of early proteins. No transactivation or replication was ever observed in these cells. We concluded from these studies that the observed transactivation of the polyomavirus late promoter by one or more of the viral early proteins was due to either higher template concentration resulting from DNA replication or replication-associated changes in template conformation.

Genetic analysis of the enhancer requirements for polyomavirus DNA replication in mice

In this report, we describe the first systematic analysis of the genetic requirements for polyomavirus (Py) enhancer-activated viral DNA replication during the acute phase of infection in mice. Four mutants were made which substituted XhoI sites for conserved enhancer consensus sequences (adenovirus type 5 E1A, c-fos, simian virus 40, and a glucocorticoidlike consensus sequence). Viral DNA replication in infected mouse organs was measured by DNA blot analysis. Only the loss of the glucocorticoidlike consensus sequence element significantly reduced Py DNA replication in the kidneys, the primary target organ for viral replication. The loss of the c-fos, adenovirus type 5 E1A, or simian virus 40 consensus sequences, however, expanded organ-specific viral DNA replication, relative to wild-type Py, by allowing high-level replication in the pancreas or heart or both. Analysis of Py variants selected for replication in undifferentiated embryonal carcinoma cell lines (PyF441, PyF111) showed that there was little change in levels of viral DNA replication in kidneys and other organs as compared with those in the wild-type virus. If the entire B enhancer is deleted, only low overall levels of viral replication are observed. Wild-type levels of replication in the kidneys can be reconstituted by addition of a single domain from within the A enhancer (nucleotides 5094 to 5132) to the B enhancer deletion virus, suggesting that a single domain from the A enhancer can functionally substitute for the entire B enhancer. This also indicates that the determinants for kidney-specific replication are not found in the B enhancer.

Requirements for species-specific papovavirus DNA replication

Replication of papovavirus DNA requires a functional replication origin, a virus-encoded protein, large T antigen, and species-specific permissive factors. How these components interact to initiate and sustain viral DNA replication is not known. Toward that end, we have attempted to identify the viral target(s) of permissive factors. The functionally defined replication origins of polyomavirus and simian virus 40, two papovaviruses that replicate in different species (mice and monkeys, respectively), are composed of two functionally distinct domains: a core domain and an auxiliary domain. The origin cores of the two viruses are remarkably similar in primary structure and have common binding sites for large T antigen. By contrast, their auxiliary domains share few sequences and serve as binding sites for cellular proteins. It seemed plausible, therefore, that if cellular permissive factors interacted with the replication origin, their targets were likely to be in the auxiliary domain. To test this hypothesis we constructed hybrid origins for DNA replication that were composed of the auxiliary domain of one virus and the origin core of the other and assessed their capacity to replicate in a number of mouse and monkey cell lines, which express the large T antigen of one or the other virus. The results of this analysis showed that the auxiliary domains of the viral replication origins could substitute for one another in DNA replication, provided that the viral origin core and its cognate large T antigen were present in a permissive cellular milieu. Surprisingly, the large T antigens of the viruses could not substitute for one another, regardless of the species of origin of the host cell, even though the two large T antigens bind to the same sequence motif in vitro. These results suggest that species-specific permissive factors do not interact with the origin-auxiliary domains but, rather, with either the origin core or the large T antigen or with both components to effect DNA replication.

Loss of responsiveness of an AP1-related factor, PEBP1, to 12-O-tetradecanoylphorbol-13-acetate after transformation of NIH 3T3 cells by the Ha-ras oncogene

The function of the A element (nucleotides 5107 to 5130) of the polyomavirus enhancer is augumented in NIH 3T3 cells by a tumor-promoting phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA). One of its targets is an AP1 consensus sequence motif recognized by a nuclear factor, PEBP1. In Ha-ras-transformed NIH 3T3 cells, however, A element function was not enhanced by TPA treatment, and at the same time PEBP1 was not detected in the nuclear extract by a mobility shift assay. PEBP1 was not detected in either the extract from NIH 3T3 cells treated in vivo with a protein kinase inhibitor, staurosporine, or the extract from NIH 3T3 cells after treatment in vitro with phosphatase. These results suggest that PEBP1 is required to be properly phosphorylated for DNA binding and that it is underphosphorylated, possibly due to the downregulation of protein kinase C in Ha-ras-transformed cells. In addition, we observed that PEBP2, which bound to the A element adjacent to PEBP1, was converted to apparently related PEBP3 when conditions favored underphosphorylation.

Deletion analysis of the polyomavirus late promoter: evidence for both positive and negative elements in the absence of early proteins

We have been interested in understanding more about the sequences that constitute the polyomavirus late promoter. Our approach has been to target specific deletions to the viral intergenic region by oligonucleotide-directed mutagenesis. Wild-type and mutant promoter cassettes with defined deletions were then inserted into a promoterless expression vector containing the bacterial chloramphenicol acetyltransferase (CAT) gene (cat). Plasmids were introduced into mouse NIH 3T3 cells by transfection, and promoter activities were assessed by quantitation of both CAT enzyme and cat mRNA levels. In this report, we present the results of experiments designed to map promoter elements which affect late transcription in the absence of early viral proteins and viral DNA replication. Using this approach, we mapped two major cis-acting elements (a positive and a negative one) which affect transcription in our transient expression system. The first, positive, element coincided with the enhancer A element, which is known to be important for early transcription and viral DNA replication. Removal of this element reduced late transcription by 50- to 100-fold. The second element was a negative one; removal of 89 base pairs that included two high-affinity large-T-antigen-binding sites just to the early side of the inverted repeat structure within the replication origin resulted in a 5- to 10-fold increase in late promoter activity. The implications of these findings for late promoter function and regulation are discussed.

Multiple subelements within the polyomavirus enhancer function synergistically to activate DNA replication

The polyomavirus origin for DNA replication comprises at least two essential, but functionally distinct, cis-acting components. One of these, the origin core, is required only for DNA replication. It includes binding sites for large T antigen and the origin of bidirectional DNA replication. The other component is required for both transcription and DNA replication and is represented by two functionally redundant regions, alpha and beta, which are elements of the polyomavirus enhancer. Whereas either enhancer element will activate DNA replication, both enhancer elements are required to constitute a functional enhancer of transcription. To identify the sequences that make up each enhancer element, we have subjected them separately to in vitro mutagenesis and measured their capacity to activate replication in cis of the origin core in MOP-8 cells, which provide all trans-acting replicative functions including large T antigen. The results reveal that the beta enhancer element is composed of three subelements, two auxiliary subelements, and a core subelement. The core subelement independently activated DNA replication, albeit poorly. The auxiliary subelements, which were inactive on their own, acted synergistically with the core subelement to increase its activity. Interestingly, dimers of the beta core subelement functioned as well as the combination of a beta auxiliary subelement and a core subelement, suggesting that the subelements are functionally equivalent. The alpha enhancer element is organized similarly; it too comprises an auxiliary subelement and a core subelement. These results lead us to suggest that the polyomavirus enhancer comprises two levels of organization; two or more enhancer elements form an enhancer, and two or more subelements make up an enhancer element. The subelements share few sequences and serve as binding sites for distinct cellular factors. It appears, therefore, that a number of different cellular proteins function cooperatively to activate polyomavirus DNA replication by a common mechanism.

Multiple subelements within the polyomavirus enhancer function synergistically to activate DNA replication

The polyomavirus origin for DNA replication comprises at least two essential, but functionally distinct, cis-acting components. One of these, the origin core, is required only for DNA replication. It includes binding sites for large T antigen and the origin of bidirectional DNA replication. The other component is required for both transcription and DNA replication and is represented by two functionally redundant regions, alpha and beta, which are elements of the polyomavirus enhancer. Whereas either enhancer element will activate DNA replication, both enhancer elements are required to constitute a functional enhancer of transcription. To identify the sequences that make up each enhancer element, we have subjected them separately to in vitro mutagenesis and measured their capacity to activate replication in cis of the origin core in MOP-8 cells, which provide all trans-acting replicative functions including large T antigen. The results reveal that the beta enhancer element is composed of three subelements, two auxiliary subelements, and a core subelement. The core subelement independently activated DNA replication, albeit poorly. The auxiliary subelements, which were inactive on their own, acted synergistically with the core subelement to increase its activity. Interestingly, dimers of the beta core subelement functioned as well as the combination of a beta auxiliary subelement and a core subelement, suggesting that the subelements are functionally equivalent. The alpha enhancer element is organized similarly; it too comprises an auxiliary subelement and a core subelement. These results lead us to suggest that the polyomavirus enhancer comprises two levels of organization; two or more enhancer elements form an enhancer, and two or more subelements make up an enhancer element. The subelements share few sequences and serve as binding sites for distinct cellular factors. It appears, therefore, that a number of different cellular proteins function cooperatively to activate polyomavirus DNA replication by a common mechanism.

Negative and positive factors determine the activity of the polyoma virus enhancer alpha domain in undifferentiated and differentiated cell types

The host range of polyoma virus is dependent upon the activity of its enhancer, which is inactive in undifferentiated embryonal carcinoma cells, such as F9 cells, and is active after their differentiation. We show here that the activity of the alpha domain of the polyoma virus enhancer displays a similar cell-specificity and inducibility as does the whole enhancer. We present evidence to show that its activity is determined by the balance between the activities of two factors, PEA2, a labile repressor, and PEA1, an inducible positive factor that we have characterized previously. Changes in repressor activity help account for the increase in alpha-domain activity after differentiation of F9 cells. These results suggest that PEA2 is crucial in the regulation of viral gene expression and perhaps more generally in the control of gene expression during differentiation.

Activation of the polyomavirus enhancer by a murine activator protein 1 (AP1) homolog and two contiguous proteins

The polyomavirus enhancer is composed of multiple DNA sequence elements serving as binding sites for proteins present in mouse nuclear extracts that activate transcription and DNA replication. We have identified three such proteins and their binding sites and correlate them with enhancer function. Mutation of nucleotide (nt) 5140 in the enhancer alters the binding site (TGACTAA, nt 5139-5145) for polyomavirus enhancer A binding protein 1 (PEA1), a murine homolog of the human transcription factor activator protein 1 (AP1). This mutation simultaneously reduces polyomavirus transcription and DNA replication. Reversion of this mutation simultaneously restores binding of PEA1 and both DNA replication and transcription. Binding of a second protein, PEA2, adjacent to the PEA1 site at nt 5147-5155 is enhanced by PEA1 binding, suggesting that these proteins interact. A third protein, PEA3, binds to the sequence AGGAAG (nt 5133-5138) adjacent to the PEA1 binding site; integrity of this late-proximal PEA3 binding site or an additional early-proximal site (nt 5228-5233) is important for enhancer function. We correlate binding of PEA1 and PEA2 with the induction of a DNase I-hypersensitive site in polyomavirus minichromosomes isolated from mouse fibroblasts.

The polyomavirus enhancer comprises multiple functional elements

The polyomavirus enhancer occupies 244 base pairs within noncoding sequences between the early and late transcription units. To define more precisely the DNA sequences that make up the enhancer, we cloned it together with the viral early promoter upstream of a reporter gene, isolated mutants bearing deletions introduced in vitro in the enhancer, and measured the capacity of the various mutant genomes to express the cat gene after transient transfection into mouse 3T3 cells. Analysis of a large number of deletion mutants revealed that the enhancer is between 102 and 172 base pairs long and can be divided into at least three functional elements. Relative to the entire enhancer, individual elements possessed little or no enhancer activity. However, pairs of elements enhanced transcription to levels much higher than the sum of individual elements approximating the activity of the complete enhancer. These findings support the view that the polyomavirus enhancer is composed of multiple sequence elements that function combinatorily and imply that a measure of cooperation exists in the interaction between cellular protein factors bound to their cognate sites in the enhancer and the transcriptional machinery of the cell.

Biological activities of oligonucleotides spanning the F9 point mutation within the enhancer region of polyomavirus DNA

A mutant of polyomavirus, F441, selected to grow in undifferentiated mouse F9 embryonal carcinoma cells, carries a single-base change in the enhancer region at nucleotide (nt) 5233 of the viral genome. Enhancers of most of the F9 mutants have a duplicated segment of viral DNA encompassing nt 5233. The minimum duplicated segment of all the known F9 mutants is from nt 5218 to nt 5239. We prepared oligonucleotides spanning the sequence from nt 5218 through nt 5239 of the genome of the wild type and F441 and examined the biological activities of the oligonucleotides by a transient assay of chloramphenicol acetyltransferase (CAT) gene expression in F9 cells. The oligonucleotide harboring the F441 mutation was shown to increase cat gene expression in F9 cells when linked at an upstream position in both orientations. When dimerized at an upstream position, the F441 oligonucleotide showed even higher cat gene expression enhancing activity. In contrast, no such effects were observed with the oligonucleotide of the wild-type sequence. In addition, the F441 oligonucleotide, but not the wild-type sequence, could inhibit the activity of whole enhancer fragment of F441 when cotransfected into F9 cells in excess amounts. On the basis of the results obtained, we suggest that the segment of F441 enhancer encompassing the point mutation contains a target for a cellular factor(s) which acts in a positive manner to increase the transcription of a gene in undifferentiated mouse F9 cells.

DNA sequence requirements for replication of polyomavirus DNA in vivo and in vitro

Cell extracts of FM3A mouse cells replicate polyomavirus (Py) DNA in the presence of immunoaffinity-purified Py large T antigen, deoxynucleoside triphosphates, ATP, and an ATP-generating system. This system was used to examine the effects of mutations within or adjacent to the Py core origin (ori) region in vitro. The analysis of plasmid DNAs containing deletions within the early-gene side of the Py core ori indicated that sequences between nucleotides 41 and 57 define the early boundary of Py DNA replication in vitro. This is consistent with previously published studies on the early-region sequence requirements for Py replication in vivo. Deleting portions of the T-antigen high-affinity binding sites A and B (between nucleotides 57 and 146) on the early-gene side of the core ori led to increased levels of replication in vitro and to normal levels of replication in vivo. Point mutations within the core ori region that abolish Py DNA replication in vivo also reduced replication in vitro. A mutant with a reversed orientation of the Py core ori region replicated in vitro, but to a lesser extent that wild-type Py DNA. Plasmids with deletions on the late-gene side of the core ori, within the enhancer region, that either greatly reduced or virtually abolished Py DNA replication in vivo replicated to levels similar to those of wild-type Py DNA plasmids in vitro. Thus, as has been observed with simian virus 40, DNA sequences needed for Py replication in vivo are different from and more stringent than those required in vitro.

DNA sequence requirements for replication of polyomavirus DNA in vivo and in vitro

Cell extracts of FM3A mouse cells replicate polyomavirus (Py) DNA in the presence of immunoaffinity-purified Py large T antigen, deoxynucleoside triphosphates, ATP, and an ATP-generating system. This system was used to examine the effects of mutations within or adjacent to the Py core origin (ori) region in vitro. The analysis of plasmid DNAs containing deletions within the early-gene side of the Py core ori indicated that sequences between nucleotides 41 and 57 define the early boundary of Py DNA replication in vitro. This is consistent with previously published studies on the early-region sequence requirements for Py replication in vivo. Deleting portions of the T-antigen high-affinity binding sites A and B (between nucleotides 57 and 146) on the early-gene side of the core ori led to increased levels of replication in vitro and to normal levels of replication in vivo. Point mutations within the core ori region that abolish Py DNA replication in vivo also reduced replication in vitro. A mutant with a reversed orientation of the Py core ori region replicated in vitro, but to a lesser extent that wild-type Py DNA. Plasmids with deletions on the late-gene side of the core ori, within the enhancer region, that either greatly reduced or virtually abolished Py DNA replication in vivo replicated to levels similar to those of wild-type Py DNA plasmids in vitro. Thus, as has been observed with simian virus 40, DNA sequences needed for Py replication in vivo are different from and more stringent than those required in vitro.

Nucleotides in the polyomavirus enhancer that control viral transcription and DNA replication

The polyomavirus enhancer is required in cis for high-level expression of the viral early region and for replication of the viral genome. We introduced multiple mutations in the enhancer which reduced transcription and DNA replication. Polyomaviruses with these mutant enhancers formed very small plaques in whole mouse embryo cells. Revertants of the viral mutants were isolated and characterized. Reversion occurred by any of the following events: restoration of guanosines at nucleotide (nt) 5134 and nt 5140 within the adenovirus 5 E1A enhancer core AGGAAGTGACT; acquisition of an A----G mutation at nt 5258, which is the same mutation that enables polyomavirus to grow in embryonal carcinoma F9 cells; duplication of mutated sequences between nt 5146 and 5292 (including sequences homologous with immunoglobulin G, simian virus 40, and bovine papillomavirus enhancer elements). Reversion restored both the replicative and transcriptional functions of the viruses. Revertants that acquired the F9 mutation at nt 5258 grew at least 20-fold better than the original mutant in whole mouse embryo cells, but replicated only marginally better than the original mutant in 3T6 cells. Viruses with a reversion of the mutation at nt 5140 replicated equally well in both types of cells. Since individual nucleotides in the polyomavirus enhancer simultaneously altered DNA replication and transcription in specific cell types, it is likely that these processes rely upon a common element, such as an enhancer-binding protein.

Nucleotides in the polyomavirus enhancer that control viral transcription and DNA replication

The polyomavirus enhancer is required in cis for high-level expression of the viral early region and for replication of the viral genome. We introduced multiple mutations in the enhancer which reduced transcription and DNA replication. Polyomaviruses with these mutant enhancers formed very small plaques in whole mouse embryo cells. Revertants of the viral mutants were isolated and characterized. Reversion occurred by any of the following events: restoration of guanosines at nucleotide (nt) 5134 and nt 5140 within the adenovirus 5 E1A enhancer core AGGAAGTGACT; acquisition of an A----G mutation at nt 5258, which is the same mutation that enables polyomavirus to grow in embryonal carcinoma F9 cells; duplication of mutated sequences between nt 5146 and 5292 (including sequences homologous with immunoglobulin G, simian virus 40, and bovine papillomavirus enhancer elements). Reversion restored both the replicative and transcriptional functions of the viruses. Revertants that acquired the F9 mutation at nt 5258 grew at least 20-fold better than the original mutant in whole mouse embryo cells, but replicated only marginally better than the original mutant in 3T6 cells. Viruses with a reversion of the mutation at nt 5140 replicated equally well in both types of cells. Since individual nucleotides in the polyomavirus enhancer simultaneously altered DNA replication and transcription in specific cell types, it is likely that these processes rely upon a common element, such as an enhancer-binding protein.

Interaction of distinct nuclear proteins with sequences controlling the expression of polyomavirus early genes

The interaction between cellular factors and polyoma virus (Py) DNA was investigated by using a gel retention assay. Nuclear extracts from various cell lines (NIH 3T3, NIH 3T6, LTK-, F9) contained proteins that formed specific and distinct complexes with Py B enhancer fragments of either wild-type or F9-1 mutant origin. The presence of an excess amount of other well-characterized DNA sequences, including the Py A enhancer, the murine sarcoma virus enhancer, and the simian virus 40 enhancer-promoter region, did not interfere with this protein-DNA interaction. However, a fragment previously defined as containing the lymphotropic papovavirus enhancer shares the binding of some common factor. This observation, in combination with the results of retention gel assays at different Mg2+ concentrations, indicates the interaction of several nuclear factors and Py DNA. The assay systems that were used allowed a distinction between some factors on the basis of their different biochemical and sequence requirements. The contact sites of these complexes were mapped to the B enhancer region of Py with Bal 31-derived mutant restriction fragments and ExoIII nuclease and are compatible with the functional domains determined in vivo.

Lymphoid and other tissue-specific phenotypes of polyomavirus enhancer recombinants: positive and negative combinational effects on enhancer specificity and activity

Heterologous enhancer recombinants and deletions of the polyomavirus (Py) noncoding region were constructed and analyzed for tissue specificity of DNA replication and transcription in a number of lymphoid and other cell lines. The simian virus 40 72-base-pair repeat, mouse immunoglobulin heavy-chain enhancer, and Moloney murine leukemia virus enhancer were inserted into the PvuII-D locus (nucleotides 5128 through 5265) of Py. The ability of these recombinants and the parental PvuII-D deletion mutant to replicate in permissive 3T6 cells and MOP-6 cells as well as in nonpermissive mouse B lymphoid, T lymphoid, mastocyte, and embryonal carcinoma cells was determined. Wild-type Py DNA was not permissive for replication in most lymphoid cell lines, except one hybridoma line. Simply deleting the Py PvuII-D region, however, gave Py an expanded host range, allowing high-level replication in some T lymphoid and mastocytoma cell lines, indicating that this element can be a tissue-specific negative as well as positive element. Substitution of the murine leukemia virus enhancer for Py PvuII-D yielded a Py genome which retained the ability to replicate in 3T6 cells but also replicated well in B lymphoid cells. Substitution with the immunoglobulin heavy-chain enhancer allowed replication in B lymphoid cells but interfered with replication in 3T6 cells and mastocytomas. Surprisingly, substitution with the simian virus 40 72-base-pair enhancer repeat gave a recombinant which would not replicate in any cell line tried, including MOP-6 cells, even though other recombinants with this enhancer would replicate. Thus, we observed both cooperation and interference in these combinations between enhancer components and the Py genome and that these combined activities were cell specific. These results are presented as evidence that there may be a positional dependence, or syntax, for the recognition of genetic elements controlling Py tissue specificity.

Interaction of a nuclear factor with the polyomavirus enhancer region

We have identified a factor present in nuclear extracts of undifferentiated F9 murine embryonal carcinoma cells that specifically interacts with the polyomavirus enhancer region. Nuclease "footprint" analysis was used to define the binding site that corresponds precisely to the boundaries of polyoma enhancer element C defined by Veldman et al. [Veldman, G. M., Lupton, S. & Kamen, R. (1985) Mol. Cell. Biol. 5, 649-658] that is required as an enhancer for efficient viral DNA replication and early and late region transcription. The region of nuclease protection contains a 6-base-pair inverted repeat, separated by 3 base pairs, and symmetrical flanking DNase I hypersensitive cleavage sites, suggesting that this factor may bind as a dimer. A cloned 29-base-pair polyoma DNA fragment contains an intact binding domain. Similar levels of binding activity were found in nuclear extracts prepared from differentiated murine F9 cells, as well as murine L cells and human HeLa cells. The factor has been termed "EF-C" for enhancer binding factor to polyoma element C.

Common regulatory elements control gene expression from polyoma early and late promoters in cells transformed by chimeric plasmids

In a previous report we showed that transcripts initiating from the late promoter of integrated polyoma plasmids could be detected at significant levels when neomycin resistance (neo) coding sequences were linked to this promoter. In this report we used chimeric plasmids that contain either a limited portion of the polyoma genome or deletions within the polyoma noncoding regulatory region to determine the sequence requirements for late promoter activity in this system. We observed no absolute requirement for either the polyoma early coding region or the origin of DNA replication for Neo-r colony formation. We were therefore able to independently assess the effects of deletions in the polyoma enhancer region on gene activity in both the early and late directions. We measured the ability of cells transfected with plasmids containing deletions in this region to form colonies in either semisolid or G418-containing medium under nonreplicative conditions. Our results indicate that either the PvuII 4 fragment, which contains the simian virus 40 core enhancer sequence, or a region from nucleotides 5099 to 5142, which contains the adenovirus type 5 E1A core enhancer sequence, can be deleted without significantly affecting gene expression in either direction. However, a deletion of nucleotides 5099 to 5172 reduced activities to similar extents in both directions, and a plasmid containing a larger deletion of nucleotides 5055 to 5182 showed a further reduction in activity. Although having no effect by itself, a second origin region deletion of nucleotides 5246 to 127 when present in these mutant backgrounds caused either a further reduction or elimination, respectively, of both G418 and agar colony-forming ability, suggesting the presence of an additional common regulatory element within this region. A comparison of 5' ends of neo transcripts present in cells transformed by these plasmids suggested that the reduction in activity was due to deletion of regulatory rather than structural elements of the late promoter. Our results indicate that the noncoding region of polyoma contains multiple complementing regulatory elements that control the level of both early and late gene expression.

Sequence-dependent DNA replication in preimplantation mouse embryos

Circular, double-stranded DNA molecules were injected into nuclei of mouse oocytes and one- or two-cell embryos to determine whether specific sequences were required to replicate DNA during mouse development. Although all of the injected DNAs were stable, replication of plasmid pML-1 DNA was not detected unless it contained either polyomavirus (PyV) or simian virus 40 (SV40) DNA sequences. Replication occurred in embryos, but not in oocytes. PyV DNA, either alone or recombined with pML-1, underwent multiple rounds of replication to produce superhelical and relaxed circular monomers after injection into one- or two-cell embryos. SV40 DNA also replicated, but only 3% as well as PyV DNA. Coinjection of PyV DNA with either pML-1 or SV40 had no effect on the replicating properties of the three DNAs. These results are consistent with a requirement for specific cis-acting sequences to replicate DNA in mammalian embryos, in contrast to sequence-independent replication of DNA injected into Xenopus eggs. Furthermore, PyV DNA replication in mouse embryos required PyV large T-antigen and either the alpha-beta-core or beta-core configuration of the PyV origin of replication. Although the alpha-core configuration replicated in differentiated mouse cells, it failed to replicate in mouse embryos, demonstrating cell-specific activation of an origin of replication. Replication or expression of PyV DNA interfered with normal embryonic development. These results reveal that mouse embryos are permissive for PyV DNA replication, in contrast to the absence of PyV DNA replication and gene expression in mouse embryonal carcinoma cells.

Lymphoid and other tissue-specific phenotypes of polyomavirus enhancer recombinants: positive and negative combinational effects on enhancer specificity and activity

Heterologous enhancer recombinants and deletions of the polyomavirus (Py) noncoding region were constructed and analyzed for tissue specificity of DNA replication and transcription in a number of lymphoid and other cell lines. The simian virus 40 72-base-pair repeat, mouse immunoglobulin heavy-chain enhancer, and Moloney murine leukemia virus enhancer were inserted into the PvuII-D locus (nucleotides 5128 through 5265) of Py. The ability of these recombinants and the parental PvuII-D deletion mutant to replicate in permissive 3T6 cells and MOP-6 cells as well as in nonpermissive mouse B lymphoid, T lymphoid, mastocyte, and embryonal carcinoma cells was determined. Wild-type Py DNA was not permissive for replication in most lymphoid cell lines, except one hybridoma line. Simply deleting the Py PvuII-D region, however, gave Py an expanded host range, allowing high-level replication in some T lymphoid and mastocytoma cell lines, indicating that this element can be a tissue-specific negative as well as positive element. Substitution of the murine leukemia virus enhancer for Py PvuII-D yielded a Py genome which retained the ability to replicate in 3T6 cells but also replicated well in B lymphoid cells. Substitution with the immunoglobulin heavy-chain enhancer allowed replication in B lymphoid cells but interfered with replication in 3T6 cells and mastocytomas. Surprisingly, substitution with the simian virus 40 72-base-pair enhancer repeat gave a recombinant which would not replicate in any cell line tried, including MOP-6 cells, even though other recombinants with this enhancer would replicate. Thus, we observed both cooperation and interference in these combinations between enhancer components and the Py genome and that these combined activities were cell specific. These results are presented as evidence that there may be a positional dependence, or syntax, for the recognition of genetic elements controlling Py tissue specificity.

Interaction of distinct nuclear proteins with sequences controlling the expression of polyomavirus early genes

The interaction between cellular factors and polyoma virus (Py) DNA was investigated by using a gel retention assay. Nuclear extracts from various cell lines (NIH 3T3, NIH 3T6, LTK-, F9) contained proteins that formed specific and distinct complexes with Py B enhancer fragments of either wild-type or F9-1 mutant origin. The presence of an excess amount of other well-characterized DNA sequences, including the Py A enhancer, the murine sarcoma virus enhancer, and the simian virus 40 enhancer-promoter region, did not interfere with this protein-DNA interaction. However, a fragment previously defined as containing the lymphotropic papovavirus enhancer shares the binding of some common factor. This observation, in combination with the results of retention gel assays at different Mg2+ concentrations, indicates the interaction of several nuclear factors and Py DNA. The assay systems that were used allowed a distinction between some factors on the basis of their different biochemical and sequence requirements. The contact sites of these complexes were mapped to the B enhancer region of Py with Bal 31-derived mutant restriction fragments and ExoIII nuclease and are compatible with the functional domains determined in vivo.

Nuclear activity from F9 embryonal carcinoma cells binding specifically to the enhancers of wild-type polyoma virus and PyEC mutant DNAs

Although wild-type polyoma virus does not productively infect murine embryonal carcinoma (EC) cells, a number of mutants (PyEC mutants) that do infect undifferentiated EC cells have been isolated. All PyEC mutants have DNA sequence alterations within the enhancer region of the viral genome. This report describes an activity present in nuclear extracts of F9 EC cells which, by "footprint" analyses, binds specifically to a small region of about 20 base pairs (nucleotides 5180-5200) within the subregion of the polyoma enhancer designated as the B or beta element. While no difference in binding of factor was detected between wild-type polyoma enhancer and the enhancers of the PyEC mutants, PyF111 and PyF441, which had been selected for productive infection of F9 cells, definite differences between wild-type and mutants were observed in the digestion patterns of their naked DNAs with either DNAase I or exonuclease III. This difference was restricted to the region around the point mutation (nucleotide 5258) common to these mutant DNAs.

Sequence-dependent DNA replication in preimplantation mouse embryos

Circular, double-stranded DNA molecules were injected into nuclei of mouse oocytes and one- or two-cell embryos to determine whether specific sequences were required to replicate DNA during mouse development. Although all of the injected DNAs were stable, replication of plasmid pML-1 DNA was not detected unless it contained either polyomavirus (PyV) or simian virus 40 (SV40) DNA sequences. Replication occurred in embryos, but not in oocytes. PyV DNA, either alone or recombined with pML-1, underwent multiple rounds of replication to produce superhelical and relaxed circular monomers after injection into one- or two-cell embryos. SV40 DNA also replicated, but only 3% as well as PyV DNA. Coinjection of PyV DNA with either pML-1 or SV40 had no effect on the replicating properties of the three DNAs. These results are consistent with a requirement for specific cis-acting sequences to replicate DNA in mammalian embryos, in contrast to sequence-independent replication of DNA injected into Xenopus eggs. Furthermore, PyV DNA replication in mouse embryos required PyV large T-antigen and either the alpha-beta-core or beta-core configuration of the PyV origin of replication. Although the alpha-core configuration replicated in differentiated mouse cells, it failed to replicate in mouse embryos, demonstrating cell-specific activation of an origin of replication. Replication or expression of PyV DNA interfered with normal embryonic development. These results reveal that mouse embryos are permissive for PyV DNA replication, in contrast to the absence of PyV DNA replication and gene expression in mouse embryonal carcinoma cells.

Common regulatory elements control gene expression from polyoma early and late promoters in cells transformed by chimeric plasmids

In a previous report we showed that transcripts initiating from the late promoter of integrated polyoma plasmids could be detected at significant levels when neomycin resistance (neo) coding sequences were linked to this promoter. In this report we used chimeric plasmids that contain either a limited portion of the polyoma genome or deletions within the polyoma noncoding regulatory region to determine the sequence requirements for late promoter activity in this system. We observed no absolute requirement for either the polyoma early coding region or the origin of DNA replication for Neo-r colony formation. We were therefore able to independently assess the effects of deletions in the polyoma enhancer region on gene activity in both the early and late directions. We measured the ability of cells transfected with plasmids containing deletions in this region to form colonies in either semisolid or G418-containing medium under nonreplicative conditions. Our results indicate that either the PvuII 4 fragment, which contains the simian virus 40 core enhancer sequence, or a region from nucleotides 5099 to 5142, which contains the adenovirus type 5 E1A core enhancer sequence, can be deleted without significantly affecting gene expression in either direction. However, a deletion of nucleotides 5099 to 5172 reduced activities to similar extents in both directions, and a plasmid containing a larger deletion of nucleotides 5055 to 5182 showed a further reduction in activity. Although having no effect by itself, a second origin region deletion of nucleotides 5246 to 127 when present in these mutant backgrounds caused either a further reduction or elimination, respectively, of both G418 and agar colony-forming ability, suggesting the presence of an additional common regulatory element within this region. A comparison of 5' ends of neo transcripts present in cells transformed by these plasmids suggested that the reduction in activity was due to deletion of regulatory rather than structural elements of the late promoter. Our results indicate that the noncoding region of polyoma contains multiple complementing regulatory elements that control the level of both early and late gene expression.

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.