Expression pattern of collagen IX and potential role in the segmentation of the peripheral nervous system

Segmentation of the peripheral nervous system of vertebrates requires guidance cues located in the adjacent somitic mesoderm. Recent experiments suggest that inhibitory molecules in the posterior somite may influence segmentation by restricting the outgrowth of axons and the migration of neural crest cells to the anterior somite. A potential candidate for an inhibitory molecule is collagen IX, a chondroitin sulfate proteoglycan made by sclerotome cells of the somite and by the notochord. Immunohistochemical localization of collagen IX demonstrated that its expression in the posterior sclerotome of the somite correlates with axon outgrowth and neural crest cell migration through the anterior sclerotome. In vitro, sensory neurites on fibronectin, and motor neurites on basal lamina extract, avoid regions which contain substrate-bound collagen IX. This effect can be abolished by chondroitinase treatment, suggesting that the glycosaminoglycan component of the molecule is responsible for this activity. Further, collagen IX elicits a similar avoidance behavior by neural crest cells in vitro. These data suggest that collagen IX contributes to the segmentation of the peripheral nervous system in vivo.

The activity of the Ets transcription factor PEA3 is regulated by two distinct MAPK cascades

PEA3, a member of the Ets family of transcriptional regulatory proteins, binds to the PEA3 promoter element and stimulates transcription through this site. The activity of the PEA3 element is regulated by mitogens, activated receptor tyrosine kinases, and oncogenic members of the Ras signal transduction pathway. However, it is not clear whether PEA3 mediates transcriptional regulation by these agents because a number of different Ets proteins can functionally interact with the PEA3 element. To specifically learn whether the activity of PEA3 is regulated, we investigated the ability of constitutively-activated Ras (Ha-RasV12) and signaling proteins downstream of Ras to alter PEA3-dependent reporter gene expression in COS cells. Ha-RasV12 and activated proteins in both the extra-cellular regulated kinase (ERK) and the stress-activated protein kinase (SAPK) or Jun N-terminal kinase (JNK) cascades independently stimulated PEA3-mediated gene expression. Ha-RasV12 stimulation of PEA3 activity was reduced by dominant-negative mutants in each of these protein kinase cascades, suggesting that Ras activates PEA3 through both pathways. Furthermore, the ability of unique activators of each kinase cascade to stimulate PEA3-dependent gene expression was selectively reduced by dominant-negative mutants within the homologous but not the heterologous pathway. Hence two distinct mitogen-activated protein kinase (MAPK) cascades regulate PEA3 activity. PEA3 was phosphorylated in vivo at serine residues consistent with the possibility that it may be a direct target of MAPKs.

Functional implications of mutations within polyomavirus large T antigen Rb-binding domain: effects on pRb and p107 binding in vitro and immortalization activity in vivo

In this study, we have extensively modified the Rb-binding domain of polyomavirus large T antigen. Mutant polyomavirus large T antigens were tested for their ability to bind pRb and p107 in vitro and assayed for their capacity to immortalize primary rat embryo fibroblasts in vivo. Polyomavirus large T antigen bound pRb and p107 through a common region located between amino acids 141 to 158, containing the consensus Rb-binding sequence D/N-L-X-C-X-E. Substitution of any amino acid within the core Rb-binding sequence abolished pRb and p107 binding in vitro and immortalization activity in vivo. Substitution of amino acids outside the core Rb-binding sequence reduced pRb and p107 binding in vitro and decreased or abolished immortalization of rat embryo fibroblasts in vivo. Although duplication of the Rb-binding domain within the polyomavirus large T antigen results in a molecule that can bind at least twice as much pRb and p107 in vitro, this mutant displayed an essentially wild-type level of immortalization activity. More importantly, we found that the addition of acidic residues within the casein kinase II consensus phosphorylation region flanking the Rb-binding domain, or the deletion of amino acids 256 to 272, increased the immortalizing activity of the mutant polyomavirus large T antigen. These two mutants displayed a greater than wild-type level of pRb binding in vitro, while in contrast, a decreased affinity for p107 binding in vitro was observed. Together, these results indicate that while pRb binding appears to be an essential event for immortalization, there is no tight correlation between the frequency of immortalization and the absolute level of pRb binding in vitro, indicating that other large T antigen functions are important for cellular immortalization.

The cDNA sequence of human endothelial cell multimerin. A unique protein with RGDS, coiled-coil, and epidermal growth factor-like domains and a carboxyl terminus similar to the globular domain of complement C1q and collagens type VIII and X

Multimerin is a massive, soluble protein found in platelets and in the endothelium of blood vessels. Multimerin is composed of varying sized, disulfide-linked multimers, the smallest of which is a homotrimer. Multimerin is a factor V/Va-binding protein and may function as a carrier protein for platelet factor V. The cDNA for human multimerin was isolated from lambda gt11 endothelial cell libraries using antibodies, and the isolated cDNA clones were used to obtain the full sequence. The full-length multimerin cDNA was 4.2 kilobase pairs. Northern analyses identified a 4.7-kilobase transcript in cultured endothelial cells, a megakaryocytic cell line, platelets, and highly vascular tissues. The multimerin cDNA can encode a protein of 1228 amino acids with the probable signal peptide cleavage site between amino acids 19 and 20. The protein is predicted to be hydrophilic and to contain 23 N-glycosylation sites. The adhesive motif RGDS (Arg-Gly-Asp-Ser) and an epidermal growth factor-like domain were identified. Sequence searches indicated that multimerin is a unique protein. Analyses identified probable coiled-coil structures in the central portion of the multimerin sequence. Additionally, the carboxyl-terminal region of multimerin resembles the globular, non-collagen-like, carboxyl-terminal domains of several other trimeric proteins, including complement C1q and collagens type VIII and X.

A transgenic mouse line harboring a smooth muscle alpha-actin promoter polyomavirus middle T antigen transgene develops an epithelial hyperplasia in the rectum and distal stomach

BACKGROUND

Transgenic mice are the product of the microinjection of foreign DNA directly into the pronuclei of a one-cell embryo. The foreign DNA can cause insertional inactivation or activation of the flanking genetic locus.

EXPERIMENTAL DESIGN

We isolated five lines of transgenic mice harboring the chicken alpha-actin vascular smooth muscle enhancer/promoter linked to the polyomavirus middle T antigen using a standard microinjection protocol. The expression of the transgene was assessed in RNA prepared from affected and nonaffected tissue by RNase protection and reverse transcriptase-polymerase chain reaction analyses. Cell morphology was determined in stained sections from fixed tissues.

RESULTS

In this article, we document the development of epithelial hyperplasia in the rectum and distal stomach together with female infertility in a single line of transgenic mice harboring the transgene. We were unable to demonstrate the expression of the transgene in any tissue examined, regardless of the degree of hyperplasia. The phenotype was present in the heterozygous state in both males and females.

CONCLUSIONS

In the absence of the expression of the transgene, we conclude that the insertion of the transgene may have caused the epithelial hyperplasia directly or may have contributed to a condition that promotes hyperplasia. The transgene may have activated a dominant-acting neighboring gene.

PEA3 is overexpressed in mouse metastatic mammary adenocarcinomas

Transgenic mice bearing the rat neu proto-oncogene under the transcriptional control of the mouse mammary tumor virus (MMTV) promoter develop focal mammary adenocarcinomas after long latency that are metastatic to the lung in a high percentage of the tumor-bearing animals. Because expression of the neu gene in the mammary epithelium precedes the occurrence of tumors, it appears that another genetic event in addition to neu transgene expression is required for tumorigenesis. We have investigated the expression of PEA3, a new member of the ets oncogene family of transcriptional regulatory factors, in neu-induced mammary tumors to learn whether PEA3 plays a role in tumor progression in this organ. We observed high levels of PEA3 RNA in neu-induced tumors, but little, if any, PEA3 RNA in the surrounding mammary epithelium. Moreover, mammary tumors that had metastasized to the lung also overexpressed the PEA3 gene, whereas normal lung tissue did not. Similar results were obtained after analyses of other transgenic mouse lines bearing metastatic mammary tumors induced by polyomavirus middle T antigen. These findings suggest that enhanced expression of PEA3 may be required to facilitate mammary tumor progression and metastasis.

The transactivator proteins VP16 and GAL4 bind replication factor A

Many transcription factors can activate the initiation of DNA replication. We have used affinity chromatography to show that the acidic activation domains of the transcription factors VP16, GAL4, and p53 each bind selectively to human and yeast replication factor A (RPA). The binding is direct and to the largest subunit of the trimeric RPA complex, RPA-1. Mutations in VP16 that reduce the ability of GAL4-VP16 to activate polyomavirus DNA replication also compromise the binding of VP16 to RPA. We suggest that transcription factors may interact with RPA either to stabilize single-stranded DNA at a replication origin or to recruit DNA polymerase alpha to the replication initiation complex.

Involvement of AP1 and PEA3 binding sites in the regulation of murine tissue inhibitor of metalloproteinases-1 (TIMP-1) transcription

Transcription of tissue inhibitor of metalloproteinases-1 (TIMP-1), a secreted protein that regulates the activities of the metalloproteinases, collagenase and stromelysin, is activated by serum growth factors. Transient transfection experiments have revealed several regions of cis-acting regulatory sequences involved in the response of the murine TIMP-1 gene to serum. One area is in the vicinity of the promoter, consisting of a non-consensus binding site (5'-TGAGTAA-3' at -59/-53) for transcription factor AP1 and an adjacent 24 bp region of dyad symmetry that contains a PEA3-binding site. A second is an upstream region (-1020 to -780) that acts as an enhancer when linked to a heterologous promoter, and contains a consensus AP1 binding site (at -803/ -797). Gel retardation assays revealed differences between nuclear factors in mouse C3H10T1/2 cells that bound to the TIMP(-59/ -53)AP1 site and a consensus collagenase TRE (TPA-response element). The TIMP(-59/ -53)AP1 site is a promiscuous motif that binds c-Fos/c-Jun AP1 translated in vitro and is an effective competitor for binding of nuclear AP1 factors to the consensus TRE, but in addition it binds factors that do not associate with the consensus TRE. The TIMP(-59/ -53)AP1 motif and the dyad symmetry region stimulated expression from a thymidine kinase promoter in an additive fashion, and competition experiments showed that excess copies of these factor binding sites reduced expression from a reporter plasmid driven by the TIMP-1 promoter. Our data show that binding sites for AP1 and PEA3 transcription factors are involved in the regulation of TIMP-1 transcription, which suggests that the coordinated induction of TIMP-1, collagenase and stromelysin may be achieved through the actions of a shared set of nuclear transcription factors. However, the properties of the TIMP-1(-59/ -53)AP1 motif likely reflect an additional type of transcriptional regulation restricted to TIMP-1.

Reversion of middle T antigen-transformed Rat-2 cells by Krev-1: implications for the role of p21c-ras in polyomavirus-mediated transformation

Polyomavirus middle T antigen mediates transformation of cells, at least in part, by its association with and activation of the intrinsic protein tyrosine kinase activity of pp60c-src. pp60c-src, by analogy with pp60v-src, elicits cell proliferation through a signal transduction pathway that includes p21c-ras. Therefore, we tested the possibility that middle T antigen acts upstream of and in the same proliferative signaling pathway as p21c-ras. Co-transfection of Rat-2 cells with plasmids expressing human Krev-1, a dominant suppressor of Ki-ras transformation, and mT antigen resulted in a dose-dependent reduction of mT antigen-induced foci. Krev-1 did not affect the transforming activity of SV40 large T antigen, demonstrating that the transformation-suppressing activity of Krev-1 is specific. To determine the effect of Krev-1 on stably transformed cell lines, Krev-1 DNA was introduced into middle T antigen-transformed Rat-2 cells along with a G418 resistance marker. Of the G418-resistant colonies examined, 1% were morphologically untransformed. Characterization of several morphological revertants revealed that, with the exception of one cell line, all of the cell lines expressed middle T antigen, which was associated with pp60c-src, whose tyrosine kinase activity was similar to that found in the parental transformed cell lines. To determine whether other phenotypic traits associated with transformation were altered in these cell lines, their growth rates and ability to form colonies in agar suspension were examined. The majority of the revertants had longer doubling times, and grew less efficiently in agar suspension compared with their transformed parents. A direct correlation was observed between Krev-1 RNA and protein expression and the efficiency with which the revertants formed colonies in suspension. These results suggest that p21c-ras lies downstream of middle T antigen and pp60c-src in the same proliferative signal transduction pathway.

Enhanced cell-free transcription of the ribosomal protein L32 gene by the polyoma virus enhancer PEA3 DNA-binding protein

The mouse-ribosomal-protein-L32-gene promoter contains a 12-bp sequence motif within the 5'-upstream region termed the beta element which shows significant similarity with the consensus sequence of the polyoma-virus-enhancer PEA3. A cloned PEA3 DNA-binding protein, expressed in Escherichia coli and purified, activates the expression of the ribosomal-protein-L32 gene in a cell-free system. Moreover, the PEA3 protein participates in the formation of the ribosomal-protein-L32-promoter-preinitiation-transcription complex. The preinitiation complex formed with PEA3 is resistant to competition by oligonucleotides containing the beta element. In addition anti-PEA3 serum interacts with a factor in mouse L1210 nuclear extract that binds to the beta element, causing a supershift in a mobility-shift assay. Our study demonstrates for the first time that the PEA3 protein can transactivate a cellular gene in a cell-free transcription system.

Molecular cloning and characterization of PEA3, a new member of the Ets oncogene family that is differentially expressed in mouse embryonic cells

The PEA3 motif, first recognized in the polyomavirus enhancer, is an oncogene, serum growth factor, and phorbol ester-responsive element. An activity capable of binding to this sequence, termed PEA3 (polyomavirus enhancer activator 3), was identified in mouse 3T6 cell nuclear extracts. We have cloned cDNAs that encode PEA3 from a mouse FM3A cell cDNA library. A continuous open reading frame in the longest cDNA predicts a 555-amino-acid protein with a calculated molecular mass of 61 kD. Recombinant PEA3 binds to DNA with the same sequence specificity as that endogenous to FM3A cells and activates transcription through the PEA3 motif in HeLa cells. Deletion mapping of the protein revealed that the DNA-binding domain is located within a stretch of 102 amino acids near the carboxyl terminus. This region shares extensive sequence similarity with the ETS domain, a conserved protein sequence common to all ets gene family members. PEA3 is encoded by a 2.4-kb mRNA that is expressed to differing extents in fibroblastic and epithelial cell lines but not in hematopoietic cell lines. In the mouse, PEA3 expression is highly restricted; only the epididymis and the brain contain readily detectable amounts of its mRNA. Interestingly, the amount of PEA3 mRNA is down-regulated during retinoic acid-induced differentiation of mouse embryonic cell lines. These findings suggest that PEA3 plays a regulatory role during mouse embryogenesis.

Cell specificity of transcription regulation by papovavirus T antigens and DNA replication

Simian virus 40 (SV40) and polyomavirus (Py) DNA replication require cellular proteins and a virus-encoded early gene product, large T antigen (SVT and PyT, respectively). Primate cells contain factors permissive for SV40 replication, whereas murine cells express those factors permissive for Py. We have compared the roles T antigen, cell permissiveness and replication play in transcription of SV40 and Py genes. We show that in their respectively permissive cells, SV40 replication causes a major shift in transcription initiation from the early to the late viral promoter, whereas when Py replicates a comparable shift does not occur. This difference is discussed in relation to differences in the organization of the origin and promoter region between these two papovaviruses. Reporter plasmids were constructed that carried both viral origins, one at the natural position in the promoter being tested and the other at a distal location. With the appropriate TAg, these vectors could be made to replicate in either primate (HeLa) or rodent (3T6) cells. The SV40 early to late shift occurred when replication was driven in HeLa cells, and was not seen on replicating templates in rodent cells. Thus, replication per se does not account for the shift. We show also that, like SVT, PyT is a potent activator of transcription, and that SVT and PyT can activate each other's late promoters independently of DNA replication, but only in cells permissive for DNA replication catalysed by the respective T antigen. Taken together, the data presented here suggest that papovaviruses may utilize permissive factors in transcription control mechanisms.

Determination of the origin-specific DNA-binding domain of polyomavirus large T antigen

To map the DNA-binding domain of polyomavirus large T antigen, we constructed a set of plasmids coding for unidirectional carboxy- or amino-terminal deletion mutations in the large T antigen. Analysis of origin-specific DNA binding by mutant proteins expressed in Cos-1 cells revealed that the C-terminal boundary of the DNA-binding domain is at or near Glu-398. Fusion proteins of large T antigen lacking the first 200 N-terminal amino acids bound specifically to polyomavirus origin DNA; however, deletions beyond this site resulted in unstable proteins which could not be tested for DNA binding. Testing of point mutants and internal deletions by others suggested that the N-terminal boundary of the DNA-binding domain lies between amino acids 282 and 286. Taken together, these results locate the DNA-binding domain of polyomavirus large T antigen to the 116-amino-acid region between residues 282 and 398.

Expression and structure of cartilage proteins

Cartilage has unique physical characteristics attributable to the presence of an unusually high content of proteoglycan embedded in the network of collagen fibrils. Advances in understanding the structure of these components and how their synthesis is regulated have been greatly assisted by the application of molecular biology. For example, an immortalized rat chondrocyte cell line was obtained by infection with a recombinant retrovirus encoding the myc gene product. Several positive and negative DNA regulatory elements of the collagen II gene have been identified that appear to be important in the regulation of this gene in chondrocytes. The complete primary structure of the cartilage proteoglycan (aggrecan) core protein deduced from cDNA sequence displays a complex multidomain structure including numerous repeats of Ser-Gly sequences and sequence homologies with link protein and animal lectins. Such studies advance our understanding of normal morphogenetic events and lay the groundwork for determining the basis of molecular and genetic defects.

Activation of polyomavirus DNA replication by yeast GAL4 is dependent on its transcriptional activation domains

The polyomavirus replication origin contains transcriptional regulatory sequences. To determine how these elements function in DNA replication, and to learn whether a common mechanism underlies the activation of transcription and DNA replication, we tested whether a well-characterized transcriptional activator, yeast GAL4, was capable of stimulating DNA replication and transcription in the same mammalian cell line. We observed that GAL4 activated polyomavirus DNA replication in mouse cells when its binding site was juxtaposed to the late border of the polyomavirus origin core. Synergistic activation of DNA replication was achieved by multimerization of the GAL4 binding site. Analysis of GAL4 mutant proteins, GAL4 hybrid proteins and mutants of the latter revealed that the activation domains of these transcriptional activators were required to stimulate DNA replication. In agreement with previously published data, the activation domains of GAL4 were also required to enhance transcription in the same mouse cell line. These observations implicate transcriptional activators in Py DNA replication and suggest that similar mechanisms govern the activation of transcription and DNA replication.

The amino terminus of polyomavirus middle T antigen is required for transformation

In polyomavirus-transformed cells, pp60c-src is activated by association with polyomavirus middle T antigen. These complexes have a higher tyrosine kinase activity compared with that of unassociated pp60c-src. Genetic analyses have revealed that the carboxy-terminal 15 amino acids of pp60c-src and the amino-terminal half of middle T antigen are required for this association and consequent activation of the tyrosine kinase. To define in greater detail the borders of the domain in middle T antigen required for activation of pp60c-src, we constructed a set of unidirectional amino-terminal deletion mutants of middle T antigen. Analysis of these mutants revealed that the first six amino acids of middle T antigen are required for it to activate the kinase activity of pp60c-src and to transform Rat-1 fibroblasts. Analysis of a series of insertion and substitution mutants confirmed these observations and further revealed that mutations affecting the first four amino acids of middle T antigen reduced or abolished its capacity to activate the kinase activity of pp60c-src and to transform Rat-1 cells in culture. Our results suggest that the first four amino acids of middle T antigen constitute part of a domain required for activation of the pp60c-src tyrosyl kinase activity and for consequent cellular transformation.

Simultaneous overexpression of avian pp60c-src and polyomavirus middle T antigen in mammalian cells

Recombinant adenoviruses bearing the avian c-src gene and polyomavirus middle-T-antigen gene were isolated and used to simultaneously overexpress both proteins in human 293 cells. Cells overexpressing both proteins had greater middle-T-antigen-associated tyrosine kinase activity than cells overexpressing only middle T antigen. By contrast, the intrinsic pp60c-src tyrosine kinase activity was not greater in cells overexpressing both proteins than in cells overexpressing only pp60c-src. This system of simultaneous overexpression provides a means of obtaining large quantities of pp60c-src, middle T antigen, and the complex between them.

Large T antigens of many polyomaviruses are able to form complexes with the retinoblastoma protein

Stable protein complexes between the large T antigens of mouse, monkey, baboon, or human polyomaviruses and the retinoblastoma protein were detected by an in vitro coimmunoprecipitation assay. All of the large T antigens tested were able to bind to both human and mouse retinoblastoma polypeptides, showing that these interactions have been conserved during evolution.

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.

The need for enhancers in gene expression first appears during mouse development with formation of the zygotic nucleus

Microinjection of the firefly luciferase gene coupled to a thymidine kinase (tk) promoter provided a quantitative assay to evaluate the requirements for gene expression in individual mouse oocytes and embryos. Polyoma virus (PyV) enhancers had no effect on the level of gene expression or competition for transcription factors as long as the DNA remained either in the oocyte germinal vesicle or the pronuclei of one-cell embryos. Expression of injected genes could be observed in pronuclei because the signal that normally triggers zygotic gene expression in two-cell embryos still occurred in one-cell embryos arrested in S phase. However, when the tk promoter was injected into zygotic nuclei of two-cell embryos, enhancers increased the number of embryos that expressed luciferase as well as the level of luciferase activity per embryo. PyV enhancer mutation F101, selected for growth in mouse embryonal carcinoma F9 cells, stimulated expression in developing two-cell embryos about seven times better than the wild-type PyV enhancer and competed effectively for factors required for transcription. These results were consistent with the fact that enhancers are required to activate the PyV origin of DNA replication in developing two-cell embryos but not in one-cell embryos. The maximum levels of gene expression in oocytes, one-cell embryos, and developing two-cell embryos (1:67:21) were inversely related to the extent of chromatin assembly, but the need for enhancers was independent of chromatin assembly. Therefore, it appears that the need for enhancers to activate promoters or origins of replication results from some negative regulatory factor that first appears as a component of zygotic nuclear structure.

The presence of heparan sulfate proteoglycans in the neuritic plaques and congophilic angiopathy in Alzheimer's disease

Two immunocytochemical probes were used to specifically identify and localize heparan sulphate proteoglycans (HSPGs) in 17 cases of Alzheimer's disease (AD). A monoclonal (HK-102) and an affinity-purified polyclonal antibody, each recognizing specific domains on the protein core of a basement membrane-derived HSPG, localized HSPGs to the amyloid fibrils present in neuritic plaques (NPs) and congophilic angiopathy (CA) in the brains of Alzheimer's patients, with weak to no immunostaining in neurofibrillary tangles from the same tissues. HSPGs were also demonstrated in "primitive plaques," suggesting that their accumulation takes place during early stages of plaque development. Immunolocalization of HSPGs to subsets of astrocytes and neuronal cells, particularly those in close proximity to NPs and CA, suggested possible involvement of these two cell types in deposition of HS-PGs into the amyloidotic lesions. The current study not only identifies a new component (HSPGs) present in the amyloid deposits of NPs and CA but also suggests that astrocytes, neurons, or both may be involved in its deposition at these sites.

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.

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.

Endothelial cell tumors develop in transgenic mice carrying polyoma virus middle T oncogene

Inoculation of newborn mice with the murine polyoma (Py) virus leads to tumor formation in a wide range of tissues. In order to investigate viral oncogenesis, we generated transgenic mice carrying either the Py large T antigen (LT) gene or the Py middle T antigen (MT) gene linked to Py early region regulatory sequences. While Py LT mice exhibit no phenotype, Py MT mice develop multifocal tumors of the vascular endothelium. These hemangiomas are lethal to the animals and can be passaged in vivo. Transgene RNAs and protein are present in both hemangiomas and the testes of these mice, and the Py middle T protein in both tissues is complexed to a cellular tyrosine kinase. The expression of complexed middle T protein in both tumorigenic endothelial cells and unperturbed testes implies that endothelial cells may be particularly susceptible to the action of the middle T oncogene. These observations indicate that Py middle T disrupts the normal strict controls on vascular growth, and suggest that Py MT transgenic mice will provide a model for studying the control of angiogenesis.