DNA fragments from F9 PyEC mutants increase expression of heterologous genes in transfected F9 cells

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.

The mouse elongation factor-2 gene: isolation and characterization of the promoter

Elongation factor 2 (EF-2) is a protein involved in peptide chain elongation in eukaryotes. We isolated the mouse EF-2 gene and characterized its promoter. We showed that the majority of enhancer elements were located within 500 bp of the flanking sequence and identified a factor binding site sequence (CGTCACGTGACGC) located between nucleotides -58 and -47 containing two CGTCA motifs separated by two nucleotides. The motif represents a half-site for binding of the cAMP response element (CRE) binding protein (CREB). Mutation analysis indicated that the presence of one CGTCA site alone conferred cAMP inducibility, but the presence of one or two CGTCA sites and spacing nucleotides elicited cAMP-independent, constitutive expression. UV cross-linking and DNA affinity chromatography revealed that three 40-, 43-, and 65-kD proteins bound to the CRE-like element. Of these, the 65-kD protein was unique to the CRE-like element. The 40-kD protein was ATF1 and the 43-kD protein with the molecular size of CREB was not CREB, on the basis of reactivity to their respective antibodies. Because ATF1 responds poorly to cAMP induction, it is likely the contributor to the constitutive expression rather than inductive expression of the CRE-like element, and, thus, the EF-2 gene.

AP-1, ETS, and transcriptional silencers regulate retinoic acid-dependent induction of keratin 18 in embryonic cells

The differentiation of both embryonal carcinoma (EC) and embryonic stem (ES) cells can be triggered in culture by exposure to retinoic acid and results in the transcriptional induction of both the endogenous mouse keratin 18 (mK18) intermediate filament gene and an experimentally introduced human keratin 18 (K18) gene as well as a variety of other markers characteristic of extraembryonic endoderm. The induction of K18 in EC cells is limited, in part, by low levels of ETS and AP-1 transcription factor activities which bind to sites within a complex enhancer element located within the first intron of K18. RNA levels of ETS-2, c-Jun, and JunB increase upon the differentiation of ES cells and correlate with increased expression of K18. Occupancy of the ETS site, detected by in vivo footprinting methods, correlates with K18 induction in ES cells. In somatic cells, the ETS and AP-1 elements mediate induction by a variety of oncogenes associated with the ras signal transduction pathway. In EC cells, in addition to the induction by these limiting transcription factors, relief from negative regulation is mediated by three silencer elements located within the first intron of the K18 gene. These silencer elements function in F9 EC cells but not their differentiated derivatives, and their activity is correlated with proteins in F9 EC nuclei which bind to the silencers and are reduced in the nuclei of differentiated F9 cells. The induction of K18, associated with the differentiation of EC cells to extraembryonic endoderm, is due to a combination of relief from negative regulation and activation by members of the ETS and AP-1 transcription factor families.

AP-1, ETS, and transcriptional silencers regulate retinoic acid-dependent induction of keratin 18 in embryonic cells

The differentiation of both embryonal carcinoma (EC) and embryonic stem (ES) cells can be triggered in culture by exposure to retinoic acid and results in the transcriptional induction of both the endogenous mouse keratin 18 (mK18) intermediate filament gene and an experimentally introduced human keratin 18 (K18) gene as well as a variety of other markers characteristic of extraembryonic endoderm. The induction of K18 in EC cells is limited, in part, by low levels of ETS and AP-1 transcription factor activities which bind to sites within a complex enhancer element located within the first intron of K18. RNA levels of ETS-2, c-Jun, and JunB increase upon the differentiation of ES cells and correlate with increased expression of K18. Occupancy of the ETS site, detected by in vivo footprinting methods, correlates with K18 induction in ES cells. In somatic cells, the ETS and AP-1 elements mediate induction by a variety of oncogenes associated with the ras signal transduction pathway. In EC cells, in addition to the induction by these limiting transcription factors, relief from negative regulation is mediated by three silencer elements located within the first intron of the K18 gene. These silencer elements function in F9 EC cells but not their differentiated derivatives, and their activity is correlated with proteins in F9 EC nuclei which bind to the silencers and are reduced in the nuclei of differentiated F9 cells. The induction of K18, associated with the differentiation of EC cells to extraembryonic endoderm, is due to a combination of relief from negative regulation and activation by members of the ETS and AP-1 transcription factor families.

Introduction and expression of the 400 kilobase amyloid precursor protein gene in transgenic mice [corrected]

Overexpression of the gene encoding the beta-amyloid precursor protein (APP) may have a key role in the pathogenesis of both Alzheimer's disease (AD) and Down Syndrome (DS). We have therefore introduced a 650 kilobase (kb) yeast artificial chromosome (YAC) that contains the entire, unrearranged 400 kb human APP gene into mouse embryonic stem (ES) cells by lipid-mediated transfection. ES lines were generated that contain a stably integrated, unrearranged human APP gene. Moreover, we demonstrate germ line transmission of the APP YAC in transgenic mice and expression of human APP mRNA and protein at levels comparable to endogenous APP. This transgenic strategy may prove invaluable for the development of mouse models for AD and DS.

Positive-negative selection gene targeting with the diphtheria toxin A-chain gene in mouse embryonic stem cells

The diphtheria toxin A-chain gene was used in a positive-negative selection gene targeting vector to alter the CD4 gene which is transcriptionally silent in mouse embryonic stem cells. Expression of the toxin gene was driven by a constitutively active enhancer, yet the targeting construct exhibited only minimal transient toxicity while enriching for targeted clones 9- to 29-fold. Germline transmission of the stem cell-derived genome was obtained. These data suggest the usefulness of this diphtheria toxin A-chain cassette in replacement-type positive-negative selection vectors. Its potential for novel applications, particularly in the enrichment for 'hit-and-run' insertion-type vectors, is discussed.

Analysis of transcription factors binding to the duplicated PEA1 and PEA3 sites that are required for polyomavirus mutant expression in PCC4 embryonic carcinoma cells

Embryonic carcinoma (EC) cell lines, representative of early embryonic undifferentiated cells, are nonpermissive for polyomavirus (PyV) infection as a result of a blockade of viral DNA early transcription and replication. All enhancers of PyV mutants (Py EC-PCC4), selected for the ability to grow on PCC4 EC cells, display a duplication of PEA1 and PEA3 binding sites (sites 1 and 3). However, the Py EC-PCC4 rearrangement is complex and results in variable mutant enhancer activities. We demonstrate here that duplication of sites 1 and 3 is absolutely required for a cooperative cis activation of early Py EC-PCC4 mutant transcription in PCC4 EC cells. In addition, we detect in PCC4 EC cells significant amounts of site 1- and 3-binding proteins, which we characterize as related to the Fos/Jun and Ets protein families, respectively. Wild-type PyV restriction in PCC4 EC cells may be relieved by a cooperation between site 2- and 3-binding proteins that would thereby be activated. Since site 1- or 3-binding factors could be derepressed, we improved the analysis of UV cross-linked DNA-protein complexes and were able to detect a novel factor, called PEA1/2 (for PyV enhancer A site 1- and 2-binding factor). Its DNA binding sequence overlaps sites 1 and 2 (PEA2 binding site) and is not duplicated in the M1 mutant, which exhibits the highest Py EC-PCC4 enhancer activity. he suggest that PEA1/2 is also involved in the regulation of PyV enhancer activity by repressing the site 1-binding activity.

Expression of the lacZ gene targeted to the HPRT locus in embryonic stem cells and their derivatives

Transgenes in mice often exhibit different expression patterns in different transgenic lines. While the basis for this phenomenon is not understood, it is widely believed that the site at which the transgene becomes integrated into the mouse genome is a major factor in determining the pattern of expression. Most transgenic mice have been produced by microinjection of DNA into the male pronucleus, which results in integration of tandem arrays of the transgene at random chromosomal sites. In the experiments described in this report, electroporation of embryonic stem (ES) cells was used to place single copies of a lacZ transgene into either random sites or into the HPRT (hypoxanthine phosphoribosyl transferase) locus of the mouse genome. Expression of lacZ was assayed by histochemical staining for Escherichia coli beta-galactosidase activity in ES cells and in differentiated derivatives obtained by teratocarcinoma formation. Several of the randomly integrated cell lines expressed lacZ at high levels in a variety of cell types present in the tumours, but most notably in epithelial cells. Targeted cell lines with lacZ in opposite orientation to the direction of HPRT gene transcription also expressed well in epithelial cells, but the targeted cell lines did not express in a wider variety of cell types than some of the nontargeted cell lines. Targeted cell lines transcribing lacZ in the same orientation as HPRT transcription did not express high levels of lacZ in any differentiated cell type. Analysis of transcripts suggested that this orientation effect may have been the result of transcriptional interference perpetrated by the HPRT gene promoter.

A DNA element that regulates expression of an endogenous retrovirus during F9 cell differentiation is E1A dependent

The retinoic acid-induced differentiation of F9 cells into parietal endoderm-like cells activates transcription of the endogenous mouse retrovirus, the intracisternal A-particle (IAP). To investigate the elements that control IAP gene differentiation-specific expression, we used methylation interference, Southwestern (DNA-protein), and transient-transfection assays and identified the IAP-proximal enhancer (IPE) element that directs differentiation-specific expression. We find that the IPE is inactive in undifferentiated F9 cells and active in differentiated parietal endoderm-like PYS-2 cells. Three proteins of 40, 60, and 68 kDa bind to the sequence GAGTAGAC located between nucleotides -53 and -47 within the IPE. The 40- and 68-kDa proteins from both the undifferentiated and differentiated cells exhibit similar DNA-binding activities. However, the 60-kDa protein from differentiated cells has greater binding activity than that from undifferentiated cells, suggesting a role for this protein in F9 differentiation-specific expression of the IAP gene. The IAP gene is negatively regulated by the adenovirus E1A proteins, and the E1A sequence responsible for repression is located at the N terminus, between amino acids 2 and 67. The DNA sequence that is the target of E1A repression also maps to the IPE element. Colocalization of the differentiation-specific and E1A-sensitive elements to the same protein-binding site within the IPE suggests that the E1A-like activity functions in F9 cells to repress IAP gene expression. Activation of the IAP gene may result when the E1A-like activity is lost or inactivated during F9 cell differentiation, followed by binding of the 60-kDa positive regulatory protein to the enhancer element.

A DNA element that regulates expression of an endogenous retrovirus during F9 cell differentiation is E1A dependent

The retinoic acid-induced differentiation of F9 cells into parietal endoderm-like cells activates transcription of the endogenous mouse retrovirus, the intracisternal A-particle (IAP). To investigate the elements that control IAP gene differentiation-specific expression, we used methylation interference, Southwestern (DNA-protein), and transient-transfection assays and identified the IAP-proximal enhancer (IPE) element that directs differentiation-specific expression. We find that the IPE is inactive in undifferentiated F9 cells and active in differentiated parietal endoderm-like PYS-2 cells. Three proteins of 40, 60, and 68 kDa bind to the sequence GAGTAGAC located between nucleotides -53 and -47 within the IPE. The 40- and 68-kDa proteins from both the undifferentiated and differentiated cells exhibit similar DNA-binding activities. However, the 60-kDa protein from differentiated cells has greater binding activity than that from undifferentiated cells, suggesting a role for this protein in F9 differentiation-specific expression of the IAP gene. The IAP gene is negatively regulated by the adenovirus E1A proteins, and the E1A sequence responsible for repression is located at the N terminus, between amino acids 2 and 67. The DNA sequence that is the target of E1A repression also maps to the IPE element. Colocalization of the differentiation-specific and E1A-sensitive elements to the same protein-binding site within the IPE suggests that the E1A-like activity functions in F9 cells to repress IAP gene expression. Activation of the IAP gene may result when the E1A-like activity is lost or inactivated during F9 cell differentiation, followed by binding of the 60-kDa positive regulatory protein to the enhancer element.

Enhancer dependence of polyomavirus persistence in mouse kidneys

We previously showed that alterations in the enhancer sequence of polyomavirus DNA can alter both the level and the organ specificity of viral DNA replication during the acute phase of infection of newborn mice (R. Rochford, B. A. Campbell, and L. P. Villarreal, J. Virol. 64:476-485, 1990). In this study, we examined whether these enhancer sequence alterations can also affect polyomavirus replication during the persistent phase of infection in vivo. After infection of newborn mice with a mixture of three enhancer variants, the individual organs could select for enhancer-specific viral DNA replication during both the acute and the persistent phases of infection. Contrary to expectations, the ability of some variants to establish a high-level acute infection in some organs (e.g., the pancreas) did not necessarily lead to a persistent infection in those organs. Thus, enhancers can affect acute and persistent infections differently. In addition, some enhancer variants tended to establish a high-level persistent infection in the kidneys immediately following an acute infection; however, in all cases considerable histopathology was associated with these elevated long-term infections, and these mice were always runty. A persistent infection in the kidneys thus appears able to exist in two distinguishable states, a high-level pathological state and a low-level nonpathological state, which can be affected by the viral enhancer sequence.

Transgenic indicator mice for studying activated retinoic acid receptors during development

Retinoic acid (RA) receptors (RARs) are ligand-inducible transcription factors that bind to specific DNA sequences associated with the regulatory regions of RA-regulatable genes. Since RA has been implicated as an important factor both in normal development and in teratological studies, one would like to have a model system that detects the presence of activated receptors during development. We have constructed a recombinant reporter gene that has three copies of the RA response element (RARE) from the RAR beta-2 promoter 5' to the herpes simplex virus thymidine kinase promoter; this regulatory region is coupled to the bacterial beta-galactosidase reporter gene. This construct was RA inducible in transient transfection assays in F9 embryonal carcinoma cells. Transgenic embryos with this reporter gene construct exhibited restricted and reproducible patterns of beta-galactosidase activity during embryogenesis, beginning between gestational ages day 7.5 and 8.5. At day 8.5, beta-galactosidase activity was detected in the closed neurotube and somites. Day 8.5 embryos, from pregnant females fed RA 14 hr earlier, exhibited a greater intensity and distribution of beta-galactosidase activity. Similarly, at later stages of gestation, maternal RA exposure resulted in enhanced embryonic beta-galactosidase expression. This type of transgenic indicator mouse should be useful in detailing the role of activated RARs during embryonic development.

Transcriptional selectivity in early mouse embryos: a qualitative study

The mouse zygotic genome is activated at the 2-cell stage. At this stage, microinjected DNA can be expressed and its transcription, analysed qualitatively with LacZ reporter genes, has the following characteristics (i) Sp1-sensitive promoters are active; (ii) the SV40 early promoter does not require upstream enhancers; (iii) genes driven by the -447, +563 region of murine leukemia virus (M-MuLV) are repressed and; (iv) activation of promoters is possible as shown for the promoter of acetylcholine receptor alpha-subunit by MyoD. This transactivation can occur before the formation of the zygotic genome. The transcriptional selectivity of 2-cell embryos also characterizes oocytes and 4-cell embryos. Therefore the elements involved are present in the oocytes and they persist after fertilization. This transcriptional selectivity has numerous common characteristics with that in EC cells, and may be indicative of a genetic control program specific for multipotential cells.

Sequences and factors required for the F9 embryonal carcinoma stem cell E1a-like activity

F9 embryonal carcinoma (EC) stem cells contain an E1a-like activity that is absent from differentiated derivatives. We have previously characterized proteins present in F9 EC cell extracts that bind to the E1a-dependent E2A promoter and have shown that two of them, TF68 and DRTF1, are required for efficient transcription in vitro (N. B. La Thangue, B. Thimmapaya, and P. W. J. Rigby, Nucleic Acids Res. 18:2929-2938, 1990). We now show that the E1a-like activity is detectable in transient transfection assays. Deletion mutations show that a distal sequence element, which includes the ATF/CREB consensus, is required for expression in both cell types, although it does not mediate the down-regulation of promoter activity that accompanies differentiation. A series of point mutations generated by in vitro mutagenesis confirm this and show that sequences around -60 are necessary for efficient expression in stem cells but not in differentiated derivatives. These sequences bind DRTF1, the activity of which is strongly down-regulated during differentiation. Surprisingly, mutations in a previously uncharacterized region of the promoter restore activity to a promoter carrying the -60 mutation and lead to the formation of a new DNA-protein complex.

Sequences and factors required for the F9 embryonal carcinoma stem cell E1a-like activity

F9 embryonal carcinoma (EC) stem cells contain an E1a-like activity that is absent from differentiated derivatives. We have previously characterized proteins present in F9 EC cell extracts that bind to the E1a-dependent E2A promoter and have shown that two of them, TF68 and DRTF1, are required for efficient transcription in vitro (N. B. La Thangue, B. Thimmapaya, and P. W. J. Rigby, Nucleic Acids Res. 18:2929-2938, 1990). We now show that the E1a-like activity is detectable in transient transfection assays. Deletion mutations show that a distal sequence element, which includes the ATF/CREB consensus, is required for expression in both cell types, although it does not mediate the down-regulation of promoter activity that accompanies differentiation. A series of point mutations generated by in vitro mutagenesis confirm this and show that sequences around -60 are necessary for efficient expression in stem cells but not in differentiated derivatives. These sequences bind DRTF1, the activity of which is strongly down-regulated during differentiation. Surprisingly, mutations in a previously uncharacterized region of the promoter restore activity to a promoter carrying the -60 mutation and lead to the formation of a new DNA-protein complex.

Cotransformation and gene targeting in mouse embryonic stem cells

We have investigated cotransformation in mammalian cells and its potential for identifying cells that have been modified by gene targeting. Selectable genes on separate DNA fragments were simultaneously introduced into cells by coelectroporation. When the introduced fragments were scored for random integration, 75% of the transformed cells integrated both fragments within the genome of the same cell. When one of the cointroduced fragments was scored for integration at a specific locus by gene targeting, only 4% of the targeted cells cointegrated the second fragment. Apparently, cells that have been modified by gene targeting with one DNA fragment rarely incorporate a second DNA fragment. Despite this limitation, we were able to use the cotransformation protocol to identify targeted cells by screening populations of colonies that had been transformed with a cointroduced selectable gene. When hypoxanthine phosphoribosyltransferase (hprt) targeting DNA was coelectroporated with a selectable neomycin phosphotransferase (neo) gene into embryonic stem (ES) cells, hprt-targeted colonies were isolated from the population of neo transformants at a frequency of 1 per 70 G418-resistant colonies. In parallel experiments with the same targeting construct, hprt-targeted cells were found at a frequency of 1 per 5,500 nonselected colonies. Thus, an 80-fold enrichment for targeted cells was observed within the population of colonies transformed with the cointroduced DNA compared with the population of nonselected colonies. This enrichment for targeted cells after cotransformation should be useful in the isolation of colonies that contain targeted but nonselectable gene alterations.

Cotransformation and gene targeting in mouse embryonic stem cells

We have investigated cotransformation in mammalian cells and its potential for identifying cells that have been modified by gene targeting. Selectable genes on separate DNA fragments were simultaneously introduced into cells by coelectroporation. When the introduced fragments were scored for random integration, 75% of the transformed cells integrated both fragments within the genome of the same cell. When one of the cointroduced fragments was scored for integration at a specific locus by gene targeting, only 4% of the targeted cells cointegrated the second fragment. Apparently, cells that have been modified by gene targeting with one DNA fragment rarely incorporate a second DNA fragment. Despite this limitation, we were able to use the cotransformation protocol to identify targeted cells by screening populations of colonies that had been transformed with a cointroduced selectable gene. When hypoxanthine phosphoribosyltransferase (hprt) targeting DNA was coelectroporated with a selectable neomycin phosphotransferase (neo) gene into embryonic stem (ES) cells, hprt-targeted colonies were isolated from the population of neo transformants at a frequency of 1 per 70 G418-resistant colonies. In parallel experiments with the same targeting construct, hprt-targeted cells were found at a frequency of 1 per 5,500 nonselected colonies. Thus, an 80-fold enrichment for targeted cells was observed within the population of colonies transformed with the cointroduced DNA compared with the population of nonselected colonies. This enrichment for targeted cells after cotransformation should be useful in the isolation of colonies that contain targeted but nonselectable gene alterations.

Adenovirus 12S E1A gene represses differentiation of F9 teratocarcinoma cells

The F9 teratocarcinoma cell line differentiates in vitro after treatment with retinoic acid and cAMP and has been a widely used model system for the study of the molecular events that are responsible for cellular commitment and differentiation during early development. Previous experiments have suggested intriguing parallels between the control of gene expression during F9 cell differentiation and the regulation of gene expression by adenovirus E1A. Transfection of a 12S E1A-expressing plasmid into terminally differentiated, nonproliferating F9 cells generates, at high frequency, colonies of dividing cells, each of which expresses E1A. Cell lines established from these colonies proliferate in the presence of retinoic acid and have lost the fully differentiated phenotype as characterized by the absence of expression of a series of differentiation-specific genes. We conclude that expression of the viral 12S E1A gene product interferes with retinoic acid-induced F9 cell differentiation. Moreover, the results suggest that the differentiation process, as defined by markers of terminal differentiation, may not be a permanent event but can be reversed by E1A expression.

Adenovirus infection of differentiated F9 cells results in a global shut-off of differentiation-induced gene expression

Previous experiments have demonstrated a link between transcriptional regulatory mechanisms acting during F9 cell differentiation and transcription control by the adenovirus E1A gene. We have isolated a number of differentiation-specific genes by cDNA cloning to determine if E1A exerts a coordinated control over differentiation specific gene expression. The mRNAs encoded by these cDNAs were undetectable or only barely detectable in undifferentiated cells but then rose in concentration upon differentiation. Analysis of transcription rates in isolated nuclei revealed that all but one of the genes was transcriptionally regulated during differentiation. Interestingly, alpha 2-type IV collagen expression was activated by a post-transcriptional mechanism since the gene was transcribed in both undifferentiated and differentiated cells whereas the cytoplasmic mRNA was undetectable in undifferentiated cells but rose in abundance in parallel with other regulated transcripts. Adenovirus infection of differentiated F9 cells reduced the cytoplasmic mRNA levels of each of the differentiation specific genes to near that found in the undifferentiated cell. Of those genes that were transcriptionally activated by differentiation, adenovirus infection specifically inhibited transcription. In contrast, although the alpha 2 collagen mRNA levels were reduced by adenovirus infection similar to the other mRNAs, the control was post-transcriptional since transcription of the gene was unaffected. Thus, the mechanism for loss of gene expression mediated by E1A reflects the mechanism by which the gene was activated during differentiation. Based on these results we suggest that E1A controls the expression of the F9 cell phenotype by targeting a regulatory activity acting early in the differentiation program.

Regulatory elements in the introns of the human HPRT gene are necessary for its expression in embryonic stem cells

We have examined the expression of transfected human hypoxanthine phosphoribosyltransferase minigenes (HPRT) in mouse embryonic stem (ES) cells. cDNA constructs of this gene that have been successfully used in somatic cell lines failed to confer hypoxanthine/aminopterin/thymidine (HAT) resistance in ES cells. In contrast, constructs containing introns 1 and 2 from the HPRT gene produced a high frequency of HAT-resistant colonies. This observation allowed us to identify two sequences in these introns that influence expression of the HPRT gene in ES cells. One element, located in intron 2, is required for effective HPRT expression in these cells; the other element, located in intron 1, acts as an enhancer of HPRT expression. Using this information, we have constructed an HPRT minigene that can be used for either positive or negative selection in ES cell experiments. This dual capability allows the design of "in-out" procedures to create subtle changes in target genes by homologous recombination with the aid of this selectable minigene.

A novel transcriptional regulatory factor that binds to the polyoma virus enhancer in a developmental stage-specific manner

By using gel mobility shift assay, it was shown that the nuclear extract from F9 embryonal carcinoma (EC) cells contains a novel transcriptional regulatory factor, BF-H, that binds to the 5' upstream region of the early gene of polyoma virus. Two binding sites were located in the transcriptional enhancer domain "A" (nucleotide 5034-5041) and in the 5' upstream of the domain "A" (4998-5005), having a consensus motif (AAPuATGG) between them. Combination of in vitro mutagenesis with chloramphenicol acetyltransferase (CAT) assay revealed that BF-H is a positive transcriptional factor. Interestingly, the binding of BF-H disappeared after differentiation of F9 cells by treatment with retinoic acid, whereas BF-H was present in the F9 cells differentiated with both retinoic acid and dibutyryl cyclic AMP (dbcAMP). These observations suggest that BF-H regulates the expression of genes in a developmental stage-specific manner in early embryos of the mouse.

Interaction of human embryonal carcinoma cells and differentiated derivatives in vitro with simian virus 40, human adenovirus type 7, or PARA

Polyclonal antibodies were used to assay human embryonal carcinoma (EC), differentiating EC, yolk sac carcinoma, and teratoma cells for expression of viral early antigen (T-Ag) after infection with simian virus 40 (SV40). Cells of four EC lines were induced to differentiate by cultivation at low density or by exposure to retinoic acid or dimethyl sulfoxide. After infection with SV40, T-Ag was expressed by 1%, or less, of the cells (presumed to be differentiated derivatives) in only some EC cultures whereas the antigen was synthesized by a significant percentage of the yolk sac carcinoma, teratoma, and differentiating EC cells. Also, viral late proteins were produced by EC cells infected with human adenovirus type 7 (Ad7), and SV40 T-Ag was expressed by EC cells after infection with PARA, which is an Ad7-SV40 hybrid virus containing the SV40 T-Ag sequence controlled by Ad7 late regulatory sequences. Thus, T-Ag is not synthesized by the parental EC cells infected with SV40, but it is expressed in cultures of infected differentiated derivatives. The EC cells produce T-Ag, however, when expression of the viral protein is controlled by the Ad7 regulatory sequences in PARA particles. These results demonstrate that expression of T-Ag after infection with SV40 is an indicator of EC cell differentiation and also raise the possibility that, as in mouse EC cells infected with the virus, the SV40 regulatory sequences controlling T-Ag synthesis are not active in human EC cells.

Insulin gene enhancer activity is inhibited by adenovirus 5 E1a gene products

Selective transcription of the insulin gene in pancreatic beta cells is regulated by its enhancer, located within the 5'-flanking region of the insulin gene. Transcription from the enhancer is controlled by both positive- and negative-acting cellular transcription factors. It was previously shown that both the 243- and 289-amino-acid adenovirus type 5 E1a proteins can repress insulin gene transcription in vivo. To localize the insulin DNA sequences involved in this response, we examined the effects of a number of mutations within the 5'-flanking region of the rat insulin II gene on E1a-mediated repression of insulin gene transcription. We have found that E1a proteins inhibit enhancer-stimulated transcription of the insulin gene. The enhancer appears to contain at least two genetically separable and independent E1a target sequence elements. Interestingly, these same regions of the insulin enhancer have been shown to be negatively regulated by cellular transcription factors. These results suggest that E1a-like cellular factors may function in the pancreatic beta-cell-specific expression of the insulin gene.

Inactivating the beta 2-microglobulin locus in mouse embryonic stem cells by homologous recombination

We have inactivated, by gene targeting, the endogenous beta 2-microglobulin gene in a mouse embryonic stem cell line. A cloned fragment of the beta 2-microglobulin gene with the coding sequence disrupted by the insertion of the neomycin-resistance gene was used to transfect the embryonic stem cells. G418-resistant colonies were selected and then screened using the polymerase chain reaction to identify those in which the incoming DNA had integrated into the embryonic stem cell genome by homologous recombination. Of a total of 234 G418-resistant colonies screened, 2 correctly targeted colonies were identified. Chimeric mice carrying the inactivated beta 2-microglobulin gene have been obtained from both of these targeted embryonic cell lines. Breeding of offspring from such animals will allow investigation of the effects of homozygous loss of beta 2-microglobulin.

Adenovirus E1A-mediated negative control of genes activated during F9 differentiation

The phenotype of a differentiated cell results from the expression of a unique set of genes in that cell. The differentiation of F9 teratocarcinoma cells in response to retinoic acid and cyclic AMP is an excellent example of this process, as the appearance of several gene products during the course of the differentiation process has been documented. In principle, the activation of gene expression could be due to the appearance of positive-acting factors, the loss of negative-acting factors, or a combination of both. Since F9 cells have been shown to express a cellular E1A analog whereas differentiated F9 cells do not, and it is known that the viral E1A gene exerts a negative effect on transcription of both viral and cellular genes, we determined whether the cellular genes activated during F9 cell differentiation are subject to E1A negative control. We found that infection of differentiated F9 cells with wild-type adenovirus resulted in a decline in the levels of collagen type IV mRNA and plasminogen activator mRNA, both of which are induced by differentiation. At least for the collagen gene, this phenomenon appears to involve a transcriptional repression.

Insulin gene enhancer activity is inhibited by adenovirus 5 E1a gene products

Selective transcription of the insulin gene in pancreatic beta cells is regulated by its enhancer, located within the 5'-flanking region of the insulin gene. Transcription from the enhancer is controlled by both positive- and negative-acting cellular transcription factors. It was previously shown that both the 243- and 289-amino-acid adenovirus type 5 E1a proteins can repress insulin gene transcription in vivo. To localize the insulin DNA sequences involved in this response, we examined the effects of a number of mutations within the 5'-flanking region of the rat insulin II gene on E1a-mediated repression of insulin gene transcription. We have found that E1a proteins inhibit enhancer-stimulated transcription of the insulin gene. The enhancer appears to contain at least two genetically separable and independent E1a target sequence elements. Interestingly, these same regions of the insulin enhancer have been shown to be negatively regulated by cellular transcription factors. These results suggest that E1a-like cellular factors may function in the pancreatic beta-cell-specific expression of the insulin gene.

Comparative analysis of retroviral vector expression in mouse embryonal carcinoma cells

A series of replication-defective retroviral vectors were assessed for their ability to efficiently transfer functional genes into undifferentiated cells. In these vectors (designated handicapped because of a deletion of enhancer and promoter sequences in the viral long terminal repeat) transcription of inserted genes is under the control of internal promoters. Although a composite promoter composed of a mutant polyoma virus enhancer (PyF441) coupled to the herpes simplex virus thymidine kinase promoter was anticipated to function efficiently, it was found to be significantly inferior to the mouse X-chromosome phosphoglycerate kinase (pgk-1) promoter, in its ability to express the selectable neomycin phosphotransferase gene in mouse embryonal carcinoma cells. The pHMB vector, which contains the pgk-1 promoter, was shown to confer the drug-resistant phenotype at high frequencies to F9 and P19 cells. This vector might prove to be of general utility for efficient gene expression in other developmental contexts.

Characterization of hepatitis B virus major surface antigen gene transcriptional regulatory elements in differentiated hepatoma cell lines

The regulatory DNA sequence elements that control the expression of the hepatitis B virus major surface antigen gene in the hepatoblastoma cell line HepG2 were analyzed by using transient transfection assays. In this system, the hepatitis B virus enhancer increases transcription from the surface antigen promoter approximately twofold. The promoter elements regulating the expression of this gene are within a 200-nucleotide sequence located immediately upstream of the transcription initiation sites. The promoter consists of an 85-nucleotide distal element which increases transcription from the surface antigen gene by two- to fourfold and a proximal element of approximately 115 nucleotides which is essential for transcriptional activity. The proximal and distal promoter elements were shown to bind factors present in HepG2 nuclear extracts, which is consistent with the regulatory role demonstrated for these sequences. The regulatory role of these promoter sequences in the hepatocellular carcinoma cell lines PLC/PRF/5 and Hep3B was also demonstrated, indicating similar transcriptional regulation of the surface antigen gene in each of these differentiated hepatoma cell lines.

Differentiation-responsive elements in the 5' region of the mouse tissue plasminogen activator gene confer two-stage regulation by retinoic acid and cyclic AMP in teratocarcinoma cells

F9 cells induced to differentiate with retinoic acid (RA) increase transcription of the tissue plasminogen activator (t-PA) gene. Further treatment of these cells with cyclic AMP (cAMP) results in an additional stimulation of t-PA gene transcription. To investigate the mechanism of this two-stage regulation, 4 kilobase pairs (kbp) of 5'-flanking sequence from the murine t-PA gene was isolated. Two major start sites for transcription were found, neither of which depended on a classical TATA motif for correct initiation. By using transient transfection assays, it was determined that 4-kbp of flanking sequence could confer on reporter genes the same two-stage differentiation-specific expression as was observed for the endogenous t-PA gene. Deletion analyses of this 4-kbp fragment showed that 190 bp of flanking sequence was sufficient to bestow the same degree of two-stage regulation on reporter gene constructs. Within this region of DNA, sequence analysis revealed a possible cAMP regulatory element, a CTF/NF-1 recognition sequence, two potential Sp1 sites, and five potential binding sites for transcription factor AP-2. The deletion experiments, coupled with the positions of these potential cis-acting elements, suggest that multiple transcription factors, including those that bind to cAMP regulatory element, CTF/NF-1, Sp1, and AP-2 sites, may be involved in regulation of the t-PA gene during F9 cell differentiation.

Adenovirus E1A-mediated negative control of genes activated during F9 differentiation

The phenotype of a differentiated cell results from the expression of a unique set of genes in that cell. The differentiation of F9 teratocarcinoma cells in response to retinoic acid and cyclic AMP is an excellent example of this process, as the appearance of several gene products during the course of the differentiation process has been documented. In principle, the activation of gene expression could be due to the appearance of positive-acting factors, the loss of negative-acting factors, or a combination of both. Since F9 cells have been shown to express a cellular E1A analog whereas differentiated F9 cells do not, and it is known that the viral E1A gene exerts a negative effect on transcription of both viral and cellular genes, we determined whether the cellular genes activated during F9 cell differentiation are subject to E1A negative control. We found that infection of differentiated F9 cells with wild-type adenovirus resulted in a decline in the levels of collagen type IV mRNA and plasminogen activator mRNA, both of which are induced by differentiation. At least for the collagen gene, this phenomenon appears to involve a transcriptional repression.

Two blocks in Moloney murine leukemia virus expression in undifferentiated F9 embryonal carcinoma cells as determined by transient expression assays

Transient expression assays were used to investigate the restriction of Moloney murine leukemia virus (MoMuLV) expression in undifferentiated mouse F9 embryonal carcinoma (EC) cells. We previously reported that the MoMuLV long terminal repeat (LTR) is inactive in undifferentiated F9EC cells due to inactivity of the tandemly repeated MoMuLV transcriptional enhancers. Others suggested that the inactivity was due to the presence of negative regulatory elements that interact with the MoMuLV tandem repeats. Two heterologous enhancer sequences that are active in undifferentiated F9 EC cells were inserted into the MoMuLV LTR: the B enhancers from the F101 variant of polyomavirus and a cellular enhancer sequence isolated from EC cells that we previously identified. The chimeric LTRs were then fused to the bacterial chloramphenicol acetyltransferase gene and tested for expression by transfection into F9 EC or NIH 3T3 cells. Insertion of these enhancers either upstream or downstream of the MoMuLV tandem repeats resulted in transcriptionally active LTRs in undifferentiated EC cells, which did not support the existence of negative regulatory elements interacting with the tandem repeats. In our previous MoMuLV enhancer deletion constructs, the GC-rich sequences downstream from the tandem repeats were also deleted, which might have contributed to the inactivity in EC cells. However, restoration of the GC-rich sequences did not yield an active LTR. The experiments also suggested that the EC cellular enhancer was preferentially active in undifferentiated EC cells and inactive in NIH 3T3 cells. The possibility of negative regulatory sequences in the vicinity of the MoMuLV primer-binding site was tested by inserting MoMuLV sequences from +30 to +419 base pairs into the LTR-chloramphenicol acetyltransferase gene constructs downstream of the transcriptional start site. Transient expression assays confirmed that these sequences reduced expression from functional LTRs in undifferentiated F9 EC cells but reduced expression significantly less in NIH 3T3 cells. Moreover, equivalent sequences from myeloproliferative sarcoma virus did not exhibit this effect. These results supported restriction of MoMuLV expression in undifferentiated F9 EC cells at two levels, inactivity of the MoMuLV enhancers and interaction of negative regulatory factors in the vicinity of the primer-binding site.

Differentiation-responsive elements in the 5' region of the mouse tissue plasminogen activator gene confer two-stage regulation by retinoic acid and cyclic AMP in teratocarcinoma cells

F9 cells induced to differentiate with retinoic acid (RA) increase transcription of the tissue plasminogen activator (t-PA) gene. Further treatment of these cells with cyclic AMP (cAMP) results in an additional stimulation of t-PA gene transcription. To investigate the mechanism of this two-stage regulation, 4 kilobase pairs (kbp) of 5'-flanking sequence from the murine t-PA gene was isolated. Two major start sites for transcription were found, neither of which depended on a classical TATA motif for correct initiation. By using transient transfection assays, it was determined that 4-kbp of flanking sequence could confer on reporter genes the same two-stage differentiation-specific expression as was observed for the endogenous t-PA gene. Deletion analyses of this 4-kbp fragment showed that 190 bp of flanking sequence was sufficient to bestow the same degree of two-stage regulation on reporter gene constructs. Within this region of DNA, sequence analysis revealed a possible cAMP regulatory element, a CTF/NF-1 recognition sequence, two potential Sp1 sites, and five potential binding sites for transcription factor AP-2. The deletion experiments, coupled with the positions of these potential cis-acting elements, suggest that multiple transcription factors, including those that bind to cAMP regulatory element, CTF/NF-1, Sp1, and AP-2 sites, may be involved in regulation of the t-PA gene during F9 cell differentiation.

An embryonic DNA-binding protein specific for a region of the human IFN beta 1 promoter

Embryonal carcinoma (EC) cells are unable to make interferon in response to inducing agents. This block disappears after differentiation. We have found that nuclear extracts from undifferentiated P19 EC cells contain a DNA-binding activity which specifically recognizes a region within the human interferon-beta 1 promoter. This activity is absent from differentiated cell types, both of EC and non-EC origin. The binding of the factor in undifferentiated EC cells leads to dramatic changes in the overall protein binding pattern of the interferon promoter as compared with differentiated cells, and may be responsible for repression of the endogenous interferon-beta gene prior to differentiation.

Anti-sense inhibition of tissue plasminogen activator production in differentiated F9 teratocarcinoma cells

F9 teratocarcinoma cells secrete the serine protease, tissue plasminogen activator (t-PA), upon differentiation induced in vitro by retinoic acid (RA) or RA and dibutyryl cAMP (RA/dbcAMP). A recombinant plasmid capable of directing the production of t-PA anti-sense RNA was constructed and transfected into F9 stem cells in an attempt to create a hypomorphic phenotype for t-PA synthesis. Several colonies were isolated which contained anti-sense RNA and which showed greater than a 50% reduction in t-PA activity upon differentiation. One such colony, 3b4, exhibited a 75% reduction in t-PA activity and was analyzed further. Large quantities of t-PA anti-sense transcript were expressed in the stem cells which are characterized by the absence of t-PA gene expression. In the induced cells, which normally express t-PA, the amount of detectable anti-sense transcript was significantly decreased. The amount of t-PA mRNA in differentiated cells containing t-PA anti-sense RNA was comparable to that in differentiated control cells. Subcellular localization of the mRNA in induced 3b4 cells appeared to be the same as induced control cells. Expression of collagen type IV, another marker of differentiation, was also monitored and was unaffected by the presence of t-PA anti-sense RNA in RA/dbcAMP-treated cells. The inhibition of differentiation-specific gene expression by anti-sense RNA may be useful for further studies of developmentally regulated genes.

The HeLa cell protein TEF-1 binds specifically and cooperatively to two SV40 enhancer motifs of unrelated sequence

We have purified a protein (TEF-1) that specifically binds to two sequence unrelated motifs (GT-IIC and Sph) of the simian virus 40 (SV40) enhancer. TEF-1 binds cooperatively to templates containing tandem but not inverted or spaced repeats of its cognate motifs. This cooperative binding correlates with the ability of the tandem repeats to generate enhancer activity in vivo. In contrast, TEF-1 and a second SV40 enhancer binding protein, TEF-2, bind independently to templates containing the cognate motifs of both proteins (GT-I and either GT-IIC or Sph motifs) even though these motifs cooperate in enhancer activity in vivo. These results allow us to distinguish different classes of enhancer factors.

Leukemogenicity of Moloney murine leukemia viruses carrying polyoma enhancer sequences in the long terminal repeat is dependent on the nature of the inserted polyoma sequences

The leukomogenicity of Moloney murine leukemia virus (M-MuLV) variants with chimeric long terminal repeats (LTRs) containing sequences from polyomavirus was studied. We previously showed that insertion of the B enhancer element from the PyF101 variant into the M-MuLV LTR between the M-MuLV enhancers and promoter abolished leukemogenicity. PyF101 differs from wild-type polyoma in that it can productively infect undifferentiated F9 embryonal carcinoma cells; this is due to alterations in the B enhancer element. Two additional chimeric M-MuLVs were generated that contained the B enhancers from wild-type polyoma and also from a second host range variant (PyF441), which differs from wild-type polyoma by only a single base change. In contrast to Mo+PyF101 M-MuLV, both Mo+Pywt and Mo+-PyF441 M-MuLV induced T-lymphoid leukemia in neonatal NIH Swiss mice with the same time course as wild-type M-MuLV. Thus the lack of leukemogenicity of Mo+PyF101 M-MuLV was related to the exact nature of the PyF101 B enhancers. While both Mo+Pywt and Mo+PyF441 M-MuLVs induced leukemia, they showed differences when the resulting tumors were examined. First, approximately one-third of the tumors induced by Mo+Pywt M-MuLV contained proviruses which lacked polyoma sequences, while all of the tumors induced by Mo+PyF441 M-MuLV contained proviruses with the chimeric LTR. Second, a majority of tumors induced by Mo+Pywt M-MuLV (and also wild-type, M-MuLV) showed proviral integrations near one or more of the cellular c-myc, pim-1, or pvt-1 loci. In contrast, tumors induced by Mo+PyF441 M-MuLV showed infrequent integrations at these loci.

Multiple domains in the polyomavirus B enhancer are required for productive infection of F9 embryonal carcinoma cells

A point mutation at nucleotide 5258 in the B enhancer of the polyomavirus host range mutant F441 leads to productive infection of F9 embryonal carcinoma cells, which are refractory to infection by wild-type polyomavirus. Specific oligonucleotides were used to construct mutations in two other potentially important domains within the B enhancer of F441 DNA. One of these domains is the binding site for a factor present in nuclear extracts of F9 cells, and the other is a region that has sequence similarity to putative core sequences observed in a number of different viral enhancers. Mutation within either of these two domains, even in the presence of the F441 mutation, was detrimental to polyomavirus enhancer activity in F9 cells, as determined by both transfection and infection assays.

Unique requirement for the PyF441 mutation for polyomavirus infection of F9 embryonal carcinoma cells

A point mutation at nucleotide 5258 in the enhancer of the polyomavirus host range mutant F441 permits productive infection of F9 embryonal carcinoma cells, which, when undifferentiated, are refractory to infection by wild-type polyomavirus. Synthetic oligonucleotides were used to construct viral genomes containing all four possible nucleotide pairs at nucleotide 5258. While all four of the viruses infected 3T6 cells efficiently, only F441, which has a guanosine in place of the wild-type adenosine in the early strand of DNA at position 5258, was able to infect F9 cells. Transfection assays with enhancer-dependent plasmid constructs expressing the chloramphenicol acetyltransferase gene under the control of the polyomavirus early promoter verified that only the F441 enhancer had any significant activity in F9 cells. DNase I footprinting showed that the F441 mutation creates a strong binding site for purified CCAAT box transcription factor, which is identical to nuclear factor 1. The three other mutations at nucleotide 5258 alter the affinity and the quality of factor binding at this site.

Differential expression of the homeobox gene Hox-1.3 in F9 embryonal carcinoma cells

The Hox-1.3 gene is located on mouse chromosome 6 and has been previously shown to be expressed in mouse embryos and adults. In this study, we have examined the steady-state levels of the Hox-1.3 transcripts in undifferentiated and differentiated F9 embryonal carcinoma cells. We find that there is a rapid increase of Hox-1.3 transcripts after differentiation induction of F9 cells. The level of the major 1.85-kilobase (kb) transcript peaks at 16-24 hr after differentiation induction of F9 cells. By using primer extension techniques the 5' ends of the major 1.85-kb transcript have been mapped to two sites in induced F9 cells. Cellular fractionation of RNA and transfer blot gel analysis has localized one minor transcript to the nucleus, whereas the major transcript and two additional minor transcripts appear in the nucleus and the cytoplasm of induced F9 cells. The results of nuclear run-off experiments with uninduced and induced F9 cell nuclei indicate that there is a substantial increase in the rate of Hox-1.3 transcription upon induction of F9 cells with retinoic acid.

Establishment of composite DNA derived from L factor as a plasmid in mouse embryonal carcinoma (F9) cells

We have recently reported a mammalian cell plasmid (L factor) whose structure is related to that of polyomavirus (T. Kusano, H. Uehara, H. Saito, K. Segawa, and M. Oishi, Proc. Natl. Acad. Sci. USA 84:1789-1793, 1987). When composite DNA constructed from L factor and a foreign gene was introduced into mouse embryonal carcinoma (F9) cells by transfection, the DNA was reestablished in the cells as a plasmid. The reestablished plasmid DNA in F9 cells could be rescued in Escherichia coli. The plasmid-bearing cells underwent normal in vitro differentiation in response to retinoic acid. The efficiency of plasmid establishment of the L-factor-derived DNA and transcriptional and transient replicational activities were compared with those of similar composite DNA constructed from polyomavirus and an embryonal carcinoma mutant of polyomavirus which is permissive in F9 cells. The results suggest an inverse relationship between the efficiency of the plasmid establishment and the activity of gene expression controlled by the intrinsic enhancer-promoter of the DNA.

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.

Negative and positive regulation by a short segment in the 5'-flanking region of the human cytomegalovirus major immediate-early gene

To analyze the significance of inducible DNase I-hypersensitive sites occurring in the 5'-flanking sequence of the major immediate-early gene of human cytomegalovirus (HCMV), various deleted portions of the HCMV immediate-early promoter regulatory region were attached to the chloramphenicol acetyltransferase (CAT) gene and assayed for activity in transiently transfected undifferentiated and differentiated human teratocarcinoma cells, Tera-2. Assays of progressive deletions in the promoter regulatory region indicated that removal of a 395-base-pair portion of this element (nucleotides -750 to -1145) containing two inducible DNase I sites which correlate with gene expression resulted in a 7.5-fold increase in CAT activity in undifferentiated cells. However, in permissive differentiated Tera-2, human foreskin fibroblast, and HeLa cells, removal of this regulatory region resulted in decreased activity. In addition, attachment of this HCMV upstream element to a homologous or heterologous promoter increased activity three- to fivefold in permissive cells. Therefore, a cis regulatory element exists 5' to the enhancer of the major immediate-early gene of HCMV. This element negative modulates expression in nonpermissive cells but positively influences expression in permissive cells.

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.

Proviral sequences that restrict retroviral expression in mouse embryonal carcinoma cells

Embryonal carcinoma (EC) cells are nonpermissive for retrovirus replication. Restriction of retroviral expression in EC cells was studied by using DNA transfection techniques. To investigate the activity of the Moloney murine leukemia virus (M-MuLV)enhancer and promoter sequences, the M-MuLV long terminal repeat and the defined long terminal repeat deletions were linked to neo structural gene sequences that encode resistance to the neomycin analog G418. Transient expression data and drug resistance frequencies support the findings that the M-MuLV enhancer is not active in EC cells but that promoter sequences are functional. In addition, a proviral DNA fragment that encodes the leader RNA sequence of a M-MuLV recombinant retrovirus was found to restrict expression specifically in EC cells. Deletion analysis of the leader fragment localized the inhibitory sequences to a region that spans the M-MuLV tRNA primer binding site. It is not known whether restriction occurs at a transcriptional or posttranscriptional level, but steady-state RNA levels in transient expression assays were significantly reduced.

Differential regulation of viral and cellular genes in F9 mouse embryonal carcinoma cells

Expression of genes driven by the SV40 promoter/enhancer appears to be under net negative regulatory control in undifferentiated F9 cells, but not in their differentiated derivatives. In cells containing integrated copies of an SV40 promoter-driven marker gene, induction of differentiation by retinoic acid treatment produced a modest increase in transcription from the viral promoter. A much greater increase was observed when differentiated or undifferentiated cells were treated with the protein synthesis inhibitor, cycloheximide. If cycloheximide acts through removal of negative-regulatory molecule(s), then it is apparent that these molecules are present in both differentiated and undifferentiated cells, and that retinoic acid treatment removes only a portion of the total transcriptional repression. RNA levels from a variety of cellular genes activated during F9 cell differentiation were either unaffected or only slightly increased by cycloheximide treatment. This suggests important qualitative or quantitative differences in the regulation mechanism for viral and cellular genes in differentiating F9 cells.

Site-directed mutagenesis by gene targeting in mouse embryo-derived stem cells

We mutated, by gene targeting, the endogenous hypoxanthine phosphoribosyl transferase (HPRT) gene in mouse embryo-derived stem (ES) cells. A specialized construct of the neomycin resistance (neor) gene was introduced into an exon of a cloned fragment of the Hprt gene and used to transfect ES cells. Among the G418r colonies, 1/1000 were also resistant to the base analog 6-thioguanine (6-TG). The G418r, 6-TGr cells were all shown to be Hprt- as the result of homologous recombination with the exogenous, neor-containing, Hprt sequences. We have compared the gene-targeting efficiencies of two classes of neor-Hprt recombinant vectors: those that replace the endogenous sequence with the exogenous sequence and those that insert the exogenous sequence into the endogenous sequence. The targeting efficiencies of both classes of vectors are strongly dependent upon the extent of homology between exogenous and endogenous sequences. The protocol described herein should be useful for targeting mutations into any gene.

Negative and positive regulation by a short segment in the 5'-flanking region of the human cytomegalovirus major immediate-early gene

To analyze the significance of inducible DNase I-hypersensitive sites occurring in the 5'-flanking sequence of the major immediate-early gene of human cytomegalovirus (HCMV), various deleted portions of the HCMV immediate-early promoter regulatory region were attached to the chloramphenicol acetyltransferase (CAT) gene and assayed for activity in transiently transfected undifferentiated and differentiated human teratocarcinoma cells, Tera-2. Assays of progressive deletions in the promoter regulatory region indicated that removal of a 395-base-pair portion of this element (nucleotides -750 to -1145) containing two inducible DNase I sites which correlate with gene expression resulted in a 7.5-fold increase in CAT activity in undifferentiated cells. However, in permissive differentiated Tera-2, human foreskin fibroblast, and HeLa cells, removal of this regulatory region resulted in decreased activity. In addition, attachment of this HCMV upstream element to a homologous or heterologous promoter increased activity three- to fivefold in permissive cells. Therefore, a cis regulatory element exists 5' to the enhancer of the major immediate-early gene of HCMV. This element negative modulates expression in nonpermissive cells but positively influences expression in permissive cells.

A c-erb-A binding site in rat growth hormone gene mediates trans-activation by thyroid hormone

The substance 3,5,3-triiodothyronine (T3) stimulates growth hormone gene transcription in rat pituitary tumour cells. This stimulation is thought to be mediated by the binding of nuclear T3 receptors to regulatory elements 5' to the transcriptional start site. Understanding of the mechanism by which thyroid hormone activates gene transcription has been limited by failure to purify nuclear T3 receptors because of their low abundance, and by the absence of defined T3 receptor-DNA binding sites affecting T3 regulation. Recently, human and avian c-erb-A gene products have been shown to bind thyroid hormone with high affinity and to have a molecular weight and nuclear association characteristic of the thyroid hormone receptor. In the present report, we describe the development of an avidin-biotin complex DNA-binding assay which can detect specific, high-affinity binding of rat pituitary cell T3 receptors to the sequence 5'CAGGGACGTGACCGCA3', located 164 base pairs 5' to the transcriptional start site of the rat growth hormone gene. An oligonucleotide containing this sequence transferred T3 regulation to the herpes simplex virus thymidine kinase promoter in transfected rat pituitary GC2 cells, and specifically bound an in vitro translation product of the human placental c-erb-A gene. The data provide supporting evidence that the human c-erb-A gene product mediates the transcriptional effects of T3 and also that GC2 cell nuclear extracts contain additional factors that modify the binding of pituitary T3 receptors to the rat growth hormone gene T3 response element.