Sequence-specific interactions between cellular DNA-binding proteins and the adenovirus origin of DNA replication

An insertion and deletion mutant of adenovirus in Muscovy ducks

Duck adenovirus 3 (DuAdV-3; strain HB) was isolated and sequenced. The genome of the Muscovy-duck-origin virus contains a 54-bp insertion in pVIII, a 3-bp deletion in the overlap region of 100K, 22K, and 33K, a 42-bp deletion at the junction of ORF64 and ORF67, and a 715-bp deletion in right noncoding region of the genome. Notably, HB has a strikingly shorter right inverted terminal repeat (ITR) of 50 bp, whereas all other DuAdV-3 isolates have a 721-bp ITR. These findings demonstrate that HB is an insertion and deletion mutant of DuAdV-3.

Are adenoviruses zoonotic? A systematic review of the evidence

Adenoviruses (AdVs) are major contributors to clinical illnesses. Novel human and animal AdVs continue to be identified and characterized. Comparative analyses using bioinformatic methods and Omics-based technologies allow insights into how these human pathogens have emerged and their potential for host cross-species transmission. Systematic review of literature published across ProQuest, Pubmed, and Web of Science databases for evidence of adenoviral zoonotic potential identified 589 citations. After removing duplicates, 327 citations were screened for relevance; of which, 74 articles received full-text reviews. Among these, 24 were included here, of which 16 demonstrated evidence of zoonotic transmission of AdVs. These documented instances of AdV crossing host species barriers between humans and non-human primate, bat, feline, swine, canine, ovine, and caprine. Eight studies sought to but did not find evidence of zoonosis. The findings demonstrate substantial evidence suggesting AdVs have previously and will continue crossing host species barriers. These have human health consequences both in terms of novel pathogen emergence and epidemic outbreaks, and of appropriate and safe use of non-human adenoviruses for therapeutics. As routine human clinical diagnostics may miss a novel cross-species adenovirus infection in humans, next generation sequencing or panspecies molecular diagnostics may be necessary to detect such incursions.

Genomic characterization of human adenovirus type 4 strains isolated worldwide since 1953 identifies two separable phylogroups evolving at different rates from their most recent common ancestor

Species Human mastadenovirus E (HAdV-E) comprises several simian types and a single human type: HAdV-E4, a respiratory and ocular pathogen. RFLP analysis for the characterization of intratypic genetic variability has previously distinguished two HAdV-E4 clusters: prototype (p)-like and a-like. Our analysis of whole genome sequences confirmed two distinct lineages, which we refer to as phylogroups (PGs). PGs I and II comprise the p- and a-like genomes, respectively, and differ significantly in their G + C content (57.7% ± 0.013 vs 56.3% ± 0.015). Sequence differences distinguishing the two clades map to several regions of the genome including E3 and ITR. Bayesian analyses showed that the two phylogroups diverged approximately 602 years before the present. A relatively faster evolutionary rate was identified for PG II. Our data provide a rationale for the incorporation of phylogroup identity to HAdV-E4 strain designation to reflect the identified unique genetic characteristics that distinguish PGs I and II.

Computational analysis of four human adenovirus type 4 genomes reveals molecular evolution through two interspecies recombination events

Computational analysis of human adenovirus type 4 (HAdV-E4), a pathogen that is the only HAdV member of species E, provides insights into its zoonotic origin and molecular adaptation. Its genome encodes a domain of the major capsid protein, hexon, from HAdV-B16 recombined into the genome chassis of a simian adenovirus. Genomes of two recent field strains provide a clue to its adaptation to the new host: recombination of a NF-I binding site motif, which is required for efficient viral replication, from another HAdV genome. This motif is absent in the chimpanzee adenoviruses and the HAdV-E4 prototype, but is conserved amongst other HAdVs. This is the first report of an interspecies recombination event for HAdVs, and the first documentation of a lateral partial gene transfer from a chimpanzee AdV. The potential for such recombination events are important when considering chimpanzee adenoviruses as candidate gene delivery vectors for human patients.

The POU transcription factor Oct-1 represses virus-induced interferon A gene expression

Alpha interferon (IFN-alpha) and IFN-beta are able to interfere with viral infection. They exert a vast array of biologic functions, including growth arrest, cell differentiation, and immune system regulation. This regulation extends from innate immunity to cellular and humoral adaptive immune responses. A strict control of expression is needed to prevent detrimental effects of unregulated IFN. Multiple IFN-A subtypes are coordinately induced in human and mouse cells infected by virus and exhibit differences in expression of their individual mRNAs. We demonstrated that the weakly expressed IFN-A11 gene is negatively regulated after viral infection, due to a distal negative regulatory element, binding homeoprotein pituitary homeobox 1 (Pitx1). Here we show that the POU protein Oct-1 binds in vitro and in vivo to the IFN-A11 promoter and represses IFN-A expression upon interferon regulatory factor overexpression. Furthermore, we show that Oct-1-deficient MEFs exhibit increased in vivo IFN-A gene expression and increased antiviral activity. Finally, the IFN-A expression pattern is modified in Oct-1-deficient MEFs. The broad representation of effective and potent octamer-like sequences within IFN-A promoters suggests an important role for Oct-1 in IFN-A regulation.

Physical interaction of tumour suppressor p53/p73 with CCAAT-binding transcription factor 2 (CTF2) and differential regulation of human high-mobility group 1 (HMG1) gene expression

The CCAAT-binding transcription factor (CTF)/nuclear factor I (NF-I) group of cellular DNA-binding proteins recognizes the sequence GCCAAT and is implicated in eukaryotic transcription, as well as DNA replication. Molecular analysis of human CTF/NF-I cDNA clones revealed multiple mRNA species that contain alternative coding regions, apparently as a result of differential splicing. Expression and functional analysis established that individual gene products can bind to GCCAAT recognition sites and serve as both promoter-selective transcriptional activators and initiation factors for DNA replication. The interaction between CTF2 and p53/p73 was shown to modulate their ability to regulate transcription of their respective target genes. In the present paper, we report that p53 down-regulates the activity of the high mobility group 1 (HMG1) gene promoter, whereas p73alpha up-regulates the activity of this promoter. Furthermore, CTF2 transactivates p53-induced p21 promoter activity, but inhibits p73alpha-induced p21 promoter activity. Using deletion mutants, we found that the DNA-binding domains of both p53 and p73alpha are required for physical interaction with CTF2 via the regions between amino acid residues 161 and 223, and 228 and 312 respectively. CTF2 enhances the DNA-binding activity of p53 and inhibits the DNA-binding activity of p73alpha. These results provide novel information on the functional interplay between CTF2 and p53/p73 as important determinants of their function in cell proliferation, apoptosis, DNA repair and cisplatin resistance.

Recruitment of the priming protein pTP and DNA binding occur by overlapping Oct-1 POU homeodomain surfaces

The human transcription factor Oct-1 can stimulate transcription from a variety of promoters by interacting with the coactivators OBF-1/OCA-B/BOB-1, SNAP190 and VP16. These proteins contact Oct-1 regions different from the DNA binding surface. Oct-1 also stimulates the DNA replication of adenovirus through its DNA binding site in the origin. The Oct-1 POU homeodomain (POUhd) binds the adenovirus precursor terminal protein pTP, which serves as the protein primer of DNA replication and recruits pTP to the origin. To map the interaction with pTP at the POUhd surface, we screened a library of randomly mutated POU domains and identified mutations that interfered with pTP interaction and DNA replication stimulation. These mutants clustered at a surface different from those recognized by OBF-1, SNAP190 and VP16. Unexpectedly, the pTP binding region largely overlapped with the DNA binding surface of POUhd. In agreement with this, pTP binding and DNA binding were mutually exclusive. We propose a model to reconcile pTP recruitment and DNA binding by Oct-1.

Disruption of the murine nuclear factor I-A gene (Nfia) results in perinatal lethality, hydrocephalus, and agenesis of the corpus callosum

The phylogenetically conserved nuclear factor I (NFI) family of transcription/replication proteins is essential both for adenoviral DNA replication and for the transcription of many cellular genes. We showed previously that the four murine NFI genes (Nfia, Nfib, Nfic, and Nfix) are expressed in unique but overlapping patterns during mouse development and in adult tissues. Here we show that disruption of the Nfia gene causes perinatal lethality, with >95% of homozygous Nfia(-/-) animals dying within 2 weeks after birth. Newborn Nfia(-/-) animals lack a corpus callosum and show ventricular dilation indicating early hydrocephalus. Rare surviving homozygous Nfia(-/-) mice lack a corpus callosum, show severe communicating hydrocephalus, a full-axial tremor indicative of neurological defects, male-sterility, low female fertility, but near normal life spans. These findings indicate that while the Nfia gene appears nonessential for cell viability and DNA replication in embryonic stem cells and fibroblasts, loss of Nfia function causes severe developmental defects. This finding of an NFI gene required for a developmental process suggests that the four NFI genes may have distinct roles in vertebrate development.

Improved production of gutted adenovirus in cells expressing adenovirus preterminal protein and DNA polymerase

Production of gutted, or helper-dependent, adenovirus vectors by current methods is inefficient. Typically, a plasmid form of the gutted genome is transfected with helper viral DNA into 293 cells; the resulting lysate is serially passaged to increase the titer of gutted virions. Inefficient production of gutted virus particles after cotransfection is likely due to suboptimal association of replication factors with the abnormal origins found in these plasmid substrates. To test this hypothesis, we explored whether gutted virus production would be facilitated by transfection into cells expressing various viral replication factors. We observed that C7 cells, coexpressing adenoviral DNA polymerase and preterminal protein, converted plasmid DNA into replicating virus approximately 50 times more efficiently than did 293 cells. This property of C7 cells can be used to greatly increase the efficiency of gutted virus production after cotransfection of gutted and helper viral DNA. These cells should also be useful for generation of recombinant adenovirus from any plasmid-based precursor.

Cellular components interact with adenovirus type 5 minimal DNA packaging domains

Adenovirus type 5 DNA packaging is initiated from the left end of the viral genome and depends on the presence of a cis-acting packaging domain located between nucleotides 194 and 380. Multiple redundant packaging elements (termed A repeats I through VII [AI through AVII]) are contained within this domain and display differential abilities to support DNA packaging in vivo. The functionally most important repeats, AI, AII, AV, and AVI, follow a bipartite consensus motif exhibiting AT-rich and CG-rich core sequences. Results from previous mutational analyses defined a fragment containing AV, AVI, and AVII as a minimal packaging domain in vivo, which supports a functional independence of the respective cis-acting sequences. Here we describe multimeric versions of individual packaging elements as minimal packaging domains that can confer viability and packaging activity to viruses carrying gross truncations within their left end. These mutant viruses directly rate the functional role that different packaging elements play relative to each other. The A repeats are likely to be binding sites for limiting, trans-acting packaging factors of cellular and/or viral origin. We report here the characterization of two cellular binding activities interacting with all of the minimal packaging domains in vitro, an unknown binding activity termed P-complex, and the transcription factor chicken ovalbumin upstream promoter transcription factor. The binding of both activities is dependent on the integrity of the AT-rich, but not the CG-rich, consensus half site. In the case of P-complex, binding affinity for different minimal packaging domains in vitro correlates well with their abilities to support DNA packaging in vivo. Interestingly, P-complex interacts not only with packaging elements but also with the left terminus of the viral genome, the core origin of replication. Our data implicate cellular factors as components of the viral packaging machinery. The dual binding specificity of P-complex for packaging and replication sequences may further suggest a direct involvement of left-end replication sequences in viral DNA encapsidation.

Cellular transcription factors enhance herpes simplex virus type 1 oriS-dependent DNA replication

The herpes simplex virus type 1 (HSV-1) origin of DNA replication, oriS, contains three binding sites for the viral origin binding protein (OBP) flanked by transcriptional regulatory elements of the immediate-early genes encoding ICP4 and ICP22/47. To assess the role of flanking sequences in oriS function, plasmids containing oriS and either wild-type or mutant flanking sequences were tested in transient DNA replication assays. Although the ICP4 and ICP22/47 regulatory regions were shown to enhance oriS function, most individual elements in these regions, including the VP16-responsive TAATGARAT elements, were found to be dispensable for oriS function. In contrast, two oriS core-adjacent regulatory (Oscar) elements, OscarL and OscarR, at the base of the oriS palindrome were shown to enhance oriS function significantly and additively. Specifically, mutational disruption of either element reduced oriS-dependent DNA replication by 60 to 70%, and disruption of both elements reduced replication by 90%. The properties of protein-DNA complexes formed in gel mobility shift assays using uninfected and HSV-1-infected Vero cell nuclear extracts demonstrated that both OscarL and OscarR are binding sites for cellular proteins. Whereas OscarR does not correspond to the consensus binding site of any known transcription factor, OscarL contains a consensus binding site for the transcription factor Sp1. Gel mobility shift and supershift experiments using antibodies directed against members of the Sp1 family of transcription factors demonstrated the presence of Sp1 and Sp3, but not Sp2 or Sp4, in the protein-DNA complexes formed at OscarL. The abilities of OscarL and OscarR to bind their respective cellular proteins correlated directly with the efficiency of oriS-dependent DNA replication. Cooperative interactions between the Oscar-binding factors and proteins binding to adjacent OBP binding sites were not observed. Notably, Oscar element mutations that impaired oriS-dependent DNA replication had no detectable effect on either basal or induced levels of transcription from the ICP4 and ICP22/47 promoters, as determined by RNase protection assays. The Oscar elements thus appear to provide binding sites for cellular proteins that facilitate oriS-dependent DNA replication but have no effect on transcription of oriS-flanking genes.

The binding-site sizes of Escherichia coli single-stranded-DNA-binding protein and mammalian replication protein A are 65 and >/= 54 nucleotides respectively

The electrophoretic mobilities of complexes formed with single-stranded (ss) DNA and tetrameric Escherichia coli ssDNA-binding protein (EcoSSB) or mammalian replication protein A (RPA) were analysed. The electrophoretic mobilities of the complexes in a native polyacrylamide gel increased as the lengths of the DNA increased from 28 to 70 nt, thus revealing paradoxical 'descending-staircase' patterns. Increases in the electrophoretic mobilities of EcoSSB.ssDNA complexes were observed when the lengths of the bound DNA were increased by 1 nt. Quantitative analyses of the complexes suggested that the binding-sites sizes of EcoSSB and RPA were 65 and >=54 nt respectively. The binding-site size for RPA is at least 24 nt larger than previously reported.

Multimerization of the adenovirus DNA-binding protein is the driving force for ATP-independent DNA unwinding during strand displacement synthesis

In contrast to other replication systems, adenovirus DNA replication does not require a DNA helicase to unwind the double-stranded template. Elongation is dependent on the adenovirus DNA-binding protein (DBP) which has helix-destabilizing properties. DBP binds cooperatively to single-stranded DNA (ssDNA) in a non-sequence-specific manner. The crystal structure of DBP shows that the protein has a C-terminal extension that hooks on to an adjacent monomer which results in the formation of long protein chains. We show that deletion of this C-terminal arm results in a monomeric protein. The mutant binds with a greatly reduced affinity to ssDNA. The deletion mutant still stimulates initiation of DNA replication like the intact DBP. This shows that a high affinity of DBP for ssDNA is not required for initiation. On a single-stranded template, elongation is also observed in the absence of DBP. Addition of DBP or the deletion mutant has no effect on elongation, although both proteins stimulate initiation on this template. Strand displacement synthesis on a double-stranded template is only observed in the presence of DBP. The mutant, however, does not support elongation on a double-stranded template. The unwinding activity of the mutant is highly reduced compared with intact DBP. These data suggest that protein chain formation by DBP and high affinity binding to the displaced strand drive the ATP-independent unwinding of the template during adenovirus DNA replication.

Tyrosine kinase-dependent release of an adenovirus preterminal protein complex from the nuclear matrix

Adenovirus (Ad) replicative complexes form at discrete sites on the nuclear matrix (NM) through the interaction of Ad preterminal protein (pTP). The NM is a highly salt-resistant fibrillar network which is known to anchor transcription, mRNA splicing, and DNA replication complexes. Incubation of rATP with NM to which pTP was bound caused the release of pTP as a pTP-NM complex with a size of 220 to 230 kDa; incubation with 5' adenylylimidodiphosphate (rAMP-PNP) showed no significant release, indicating that rATP hydrolysis was required. With NM extracts, it was shown that a pTP-NM complex which was capable of binding Ad origin DNA could be reconstituted in vitro. A number of high-molecular-weight NM proteins ranging in size from 120 to 200 kDa were identified on Far Western blots for their ability to bind pTP. rATP-dependent release of pTP from the NM was inhibited in a dose-dependent fashion by the addition of tyrosine kinase inhibitors, such as quercetin, methyl-2,5-dihydroxycinnamate, or genistein. NM-mediated phosphorylation of a poly(Glu, Tyr) substrate was also significantly abrogated by the addition of these compounds. rATP-dependent release of Ad DNA termini bound to the NM via pTP was also blocked by the addition of these inhibitors. These results indicate that a tyrosine kinase mechanism controls the release of pTP from its binding sites on the NM. These data support the concept that phosphorylation may play a key role in the modulation of pTP binding sites on the NM.

Human adenovirus type 5 variants with sequence alterations flanking the E2A gene: effects on E2 expression and DNA replication

The human adenovirus type 5 (Ad5) E2 transcription unit is divided into a promoter-proximal region, E2A, and a distal region, E2B, each with its own polyadenylation site. Together these regions encode the three virus-derived proteins necessary for genome replication. Ad5 variants were produced that carried linker insertion mutations immediately 5' and/or 3' to the coding sequence for the E2A gene DNA binding protein (DBP). Two variants carrying solely a 5' lesion showed decreased usage of the adjacent 3' splice site, via which the DBP mRNA is produced, and an increased usage of the alternative downstream splice sites in the E2B region, wherein viral DNA polymerase and terminal protein precursor are encoded; these viruses showed somewhat reduced growth. A variant carrying a 3' lesion showed a marginal increase in DBP expression and slightly accelerated growth. When lesions 5' and 3' to the DBP coding sequence were combined in cis, the resulting virus was severely defective for growth and expressed E2B products to the virtual exclusion of E2A DBP. These data indicate that interactions must occur between the E2A 3' splice site and polyadenylation site before this region can be treated as an exon by the RNA processing machinery, and that a sequence alteration at the polyadenylation site that alone has only minor effects on the pattern of RNA processing can drastically affect terminal exon usage when placed in cis with a mutation that reduces splicing efficiency at the upstream 3' splice site. The data further indicate that, in vivo, Ad5 DNA replication is limited by prevailing DBP levels rather than by levels of polymerase or terminal protein precursor.

Early dissociation of nuclear factor I from the origin during initiation of adenovirus DNA replication studied by origin immobilization

The DNA-binding domain of Nuclear Factor I (NFIBD) enhances initiation of adenovirus DNA replication up to 50-fold by binding to the auxiliary region of the origin and positioning the viral DNA polymerase. To study if and when NFIBD dissociates from the template, we immobilized origin DNA to glutathione-agarose beads by means of a GST-NFIBD fusion protein. This immobilized template is active in replication. By analyzing the release of prelabeled templates from the beads under different conditions, we show that NFIBD dissociates already early during initiation. During preinitiation NFIBD remains bound, but as soon as dCTP, dATP or dTTP are added, efficient dissociation occurs. A much lower dissociation level was induced by addition of dGTP. Since dCTP, dATP and dTTP are required for formation of a pTP-CAT initiation intermediate, we explain our results by conformational changes occurring in the polymerase during initiation leading to disruption of both the interaction between the polymerase and NFI as well as the interaction between NFI and the DNA.

Stably integrated mouse mammary tumor virus long terminal repeat DNA requires the octamer motifs for basal promoter activity

In the mouse mammary tumor virus promoter, a tandem of octamer motifs, recognized by ubiquitous and tissue-restricted Oct transcription factors, is located upstream of the TATA box and next to a binding site for the transcription factor nuclear factor I (NF-I). Their function was investigated with mutant long terminal repeats under different transfection conditions in mouse Ltk- cells and quantitative S1 nuclease mapping of the transcripts. In stable transfectants, which are most representative of the state of proviral DNA with respect to both number of integrated DNA templates and chromatin organization, a long terminal repeat mutant of both octamer sites showed an average 50-fold reduction of the basal transcription level, while the dexamethasone-stimulated level was unaffected. DNase I in vitro footprinting assays with L-cell nuclear protein extracts showed that the mutant DNA was unable to bind octamer factors but had a normal footprint in the NF-I site. I conclude that mouse mammary tumor virus employs the tandem octamer motifs of the viral promoter, recognized by the ubiquitous transcription factor Oct-1, for its basal transcriptional activity and the NF-I binding site, as previously shown, for glucocorticoid-stimulated transcription. A deletion mutant with only one octamer site showed a marked base-level reduction at high copy number but little reduction at low copies of integrated plasmids. The observed transcription levels may depend both on the relative ratio of transcription factors to DNA templates and on the relative affinity of binding sites, as determined by oligonucleotide competition footprinting.

Stably integrated mouse mammary tumor virus long terminal repeat DNA requires the octamer motifs for basal promoter activity

In the mouse mammary tumor virus promoter, a tandem of octamer motifs, recognized by ubiquitous and tissue-restricted Oct transcription factors, is located upstream of the TATA box and next to a binding site for the transcription factor nuclear factor I (NF-I). Their function was investigated with mutant long terminal repeats under different transfection conditions in mouse Ltk- cells and quantitative S1 nuclease mapping of the transcripts. In stable transfectants, which are most representative of the state of proviral DNA with respect to both number of integrated DNA templates and chromatin organization, a long terminal repeat mutant of both octamer sites showed an average 50-fold reduction of the basal transcription level, while the dexamethasone-stimulated level was unaffected. DNase I in vitro footprinting assays with L-cell nuclear protein extracts showed that the mutant DNA was unable to bind octamer factors but had a normal footprint in the NF-I site. I conclude that mouse mammary tumor virus employs the tandem octamer motifs of the viral promoter, recognized by the ubiquitous transcription factor Oct-1, for its basal transcriptional activity and the NF-I binding site, as previously shown, for glucocorticoid-stimulated transcription. A deletion mutant with only one octamer site showed a marked base-level reduction at high copy number but little reduction at low copies of integrated plasmids. The observed transcription levels may depend both on the relative ratio of transcription factors to DNA templates and on the relative affinity of binding sites, as determined by oligonucleotide competition footprinting.

Functional analysis of the V gamma 3 promoter of the murine gamma delta T-cell receptor

The initial day 14 wave of fetal thymocytes express a gamma delta T-cell receptor (TCR). This surface TCR is generated by preferential rearrangement of V gamma 3 and V delta 1 recombination segments. To delineate the role of regulatory sequences in this expression, we have analyzed the V gamma 3 promoter control region under the regulation of its cognate C gamma 1 enhancer. Transcription initiates 25 bases downstream from a TATTAA sequence at a consensus initiator motif. The minimal 5' promoter sequences supporting expression by transient analysis extend -243 nucleotides from the +1 start site. Three regulatory sequences in this region have been defined by deletion and mutagenesis: a consensus CTF/NF-1 site at -55, an Ets homology sequence at -65, and a degenerate, but crucial, SP-1 site at -100. The presence of additional sequences downstream of the start site which extend through the leader intron were necessary for expression. In contrast to other TCR or immunoglobulin variable regions, one or more strong upstream suppressor sequences resembling silencer elements have been observed. A 311-bp fragment, positions -586 to -897, exhibited strong repressing activity regardless of orientation when placed upstream of heterologous promoters.

Functional analysis of the V gamma 3 promoter of the murine gamma delta T-cell receptor

The initial day 14 wave of fetal thymocytes express a gamma delta T-cell receptor (TCR). This surface TCR is generated by preferential rearrangement of V gamma 3 and V delta 1 recombination segments. To delineate the role of regulatory sequences in this expression, we have analyzed the V gamma 3 promoter control region under the regulation of its cognate C gamma 1 enhancer. Transcription initiates 25 bases downstream from a TATTAA sequence at a consensus initiator motif. The minimal 5' promoter sequences supporting expression by transient analysis extend -243 nucleotides from the +1 start site. Three regulatory sequences in this region have been defined by deletion and mutagenesis: a consensus CTF/NF-1 site at -55, an Ets homology sequence at -65, and a degenerate, but crucial, SP-1 site at -100. The presence of additional sequences downstream of the start site which extend through the leader intron were necessary for expression. In contrast to other TCR or immunoglobulin variable regions, one or more strong upstream suppressor sequences resembling silencer elements have been observed. A 311-bp fragment, positions -586 to -897, exhibited strong repressing activity regardless of orientation when placed upstream of heterologous promoters.

Transcriptional control of human papillomavirus (HPV) oncogene expression: composition of the HPV type 18 upstream regulatory region

The malignant transformation potential of high-risk human papillomaviruses (HPVs) is closely linked to the expression of the viral E6 and E7 genes. To elucidate the molecular mechanisms resulting in HPV oncogene expression, a systematic analysis of the cis-regulatory elements within the HPV type 18 (HPV18) upstream regulatory region (URR) which regulate the activity of the E6/E7 promoter was performed. As the functional behavior of a given cis-regulatory element can be strongly influenced by the overall composition of a transcriptional control region, individual elements were inactivated by site-directed mutagenesis in the physiological context of the complete HPV18 URR. Subsequently, the effects of these mutations on the activity of the E6/E7 promoter were assessed by transient transfection assays. We found that the transcriptional stimulation of the E6/E7 promoter largely depends on the integrity of cis-regulatory elements bound by AP1, SP1, and in certain epithelial cells, KRF-1. In contrast to previous reports by implying a key role for NF1 and Oct-1 recognition motifs in the stimulation of papillomavirus oncogene expression, the inactivation of these elements in the context of the HPV18 URR did not strongly affect the transcriptional activity of the E6/E7 promoter. Mutation of a promoter-proximal glucocorticoid response element completely abolished dexamethasone inducibility of the HPV18 E6/E7 promoter and resulted in an increase of its basal activity. Functional dissection of the HPV18 constitutive enhancer region indicates that its transcriptional activity is largely generated by functional synergism between a centrally located AP1 module and thus far undetected cis-active elements present in the 5' flank of the enhancer. Furthermore, comparative analyses using homologous and heterologous promoters show that the transcriptional activity of HPV18 enhancer elements is influenced by the nature of the test promoter in a cell-type-specific manner.

Overexpression of Myc suppresses CCAAT transcription factor/nuclear factor 1-dependent promoters in vivo

Overexpression of Myc in cells can suppress the transcription of specific genes. Because several of these genes have common transcriptional regulatory elements, we investigated the possibility that this effect of Myc is mediated through a specific transcription factor. In vitro DNA-binding assays detect only one form of CCAAT transcription factor/nuclear factor 1 (CTF/NF-1) in quiescent 3T3-L1 cells. By contrast, quiescent 3T3-L1 cells that stably overexpress either c-Myc or N-Myc contain at least three forms of CTF/NF-1. Biochemical characterization of the various CTF/NF-1 forms showed that they have the same native molecular weight but differ in charge density. The more negatively charged CTF/NF-1 forms present in Myc-overexpressing cells are converted into that found in normal cells by treatment with acid phosphatase, suggesting that they represent a more phosphorylated form of the CTF/NF-1 protein. The various CTF/NF-1 forms have a similar DNA-binding affinity. Transfection experiments demonstrated that transcription from CTF/NF-1-dependent promoters is specifically suppressed in cells that stably overexpress c-Myc. This effect requires CTF/NF-1 binding. CTF/NF-1-dependent promoter activity is also suppressed in 3T3-L1 cells during active growth (relative to the quiescent state). Interestingly, actively growing 3T3-L1 cells contain forms of CTF/NF-1 similar to those in quiescent cells that stably overexpress c-Myc. Thus, the CTF/NF-1 forms present in cells that express high amounts of c-Myc correlate with a lower transcription rate of CTF/NF-1-dependent promoters in vivo. Our results provide a basis for the suppression of specific gene transcription by c-Myc.

Overexpression of Myc suppresses CCAAT transcription factor/nuclear factor 1-dependent promoters in vivo

Overexpression of Myc in cells can suppress the transcription of specific genes. Because several of these genes have common transcriptional regulatory elements, we investigated the possibility that this effect of Myc is mediated through a specific transcription factor. In vitro DNA-binding assays detect only one form of CCAAT transcription factor/nuclear factor 1 (CTF/NF-1) in quiescent 3T3-L1 cells. By contrast, quiescent 3T3-L1 cells that stably overexpress either c-Myc or N-Myc contain at least three forms of CTF/NF-1. Biochemical characterization of the various CTF/NF-1 forms showed that they have the same native molecular weight but differ in charge density. The more negatively charged CTF/NF-1 forms present in Myc-overexpressing cells are converted into that found in normal cells by treatment with acid phosphatase, suggesting that they represent a more phosphorylated form of the CTF/NF-1 protein. The various CTF/NF-1 forms have a similar DNA-binding affinity. Transfection experiments demonstrated that transcription from CTF/NF-1-dependent promoters is specifically suppressed in cells that stably overexpress c-Myc. This effect requires CTF/NF-1 binding. CTF/NF-1-dependent promoter activity is also suppressed in 3T3-L1 cells during active growth (relative to the quiescent state). Interestingly, actively growing 3T3-L1 cells contain forms of CTF/NF-1 similar to those in quiescent cells that stably overexpress c-Myc. Thus, the CTF/NF-1 forms present in cells that express high amounts of c-Myc correlate with a lower transcription rate of CTF/NF-1-dependent promoters in vivo. Our results provide a basis for the suppression of specific gene transcription by c-Myc.

The adenovirus DNA binding protein effects the kinetics of DNA replication by a mechanism distinct from NFI or Oct-1

Initiation of adenovirus DNA replication in vitro minimally requires the viral TP-DNA template and the precursor terminal protein-DNA polymerase heterodimer (pTP-pol). Optimal initiation occurs in the presence of the cellular transcription factors NFI and Oct-1 and the viral DNA binding protein (DBP). We have studied the influence of these three stimulatory proteins on the kinetics of formation of the pTP-dCMP initiation complex. NFI increases the Vmax of the reaction but does not affect the apparent Km for dC-TP. This indicates that NFI acts by enlarging the amount of active initiation complex in agreement with its stabilizing effect on binding of pTP-pol to the template. Similar kinetic effects were observed for Oct-1. Since Oct-1 does not stabilize binding of pTP-pol to the origin this suggests that Oct-1 increases the rate of pTP-dCMP formation. DBP stimulates the initiation reaction in two ways. First, it moderately increases the Vmax at suboptimal NFI concentrations, which is related to its enhancing effect on binding of NFI to the origin. Second, a much larger stimulation was caused by DBP itself based on a reduction of the Km for dCTP, which was independent of the concentration of pTP-pol or NFI. The Km for dCTP during initiation is lower than during elongation.

Two upstream elements activate transcription of a major histocompatibility complex class I gene in vitro

Expression of major histocompatibility complex (MHC) class I genes exhibits unique tissue and developmental specificity. In an effort to study molecular mechanisms of MHC class I gene regulation, an in vitro transcription system has been established. In B cell nuclear extracts a template DNA containing the mouse H-2Ld promoter sequence accurately directed RNA polymerase II-dependent transcription of a G-free cassette. A conserved class I regulatory complex previously shown to moderately enhance promoter activity in vivo enhanced transcription in vitro by 2-3 fold. Much of this enhancement was accounted for by a 40 bp fragment within the complex, which was capable of activating a basal H-2Ld promoter in either orientation. Farther downstream, another element called site B was identified, which independently activated MHC class I transcription in vitro by 2-4 fold. Site B bound a specific nuclear factor(s) through an NF-1 binding site but not through a neighboring CCAAT site. The functional significance of site B in vivo was demonstrated in transfection experiments in which site B enhanced MHC class I promoter activity to a degree comparable to that seen in vitro. With the identification of the two upstream activators, MHC class I genes may serve as a model to study roles of sequence-specific DNA-binding proteins in transcription in vitro.

Nuclear factor I is specifically targeted to discrete subnuclear sites in adenovirus type 2-infected cells

During the S phase of the eukaryotic cell cycle and in virus-infected cells, DNA replication takes place at discrete sites in the nucleus, although it is not clear how the proteins involved in the replicative process are directed to these sites. Nuclear factor I is a cellular, sequence-specific DNA-binding protein utilized by adenovirus type 2 to facilitate the assembly of a nucleoprotein complex at the viral origin of DNA replication. Immunofluorescence experiments reveal that in uninfected cells, nuclear factor I is distributed evenly throughout the nucleus. However, after a cell is infected with adenovirus type 2, the distribution of nuclear factor I is dramatically altered, being colocalized with the viral DNA-binding protein in a limited number of subnuclear sites which bromodeoxyuridine pulse-labeling experiments have identified as sites of viral DNA replication. Experiments with adenovirus type 4, which does not require nuclear factor I for viral DNA replication, indicate that although the adenovirus type 4 DNA-binding protein is localized to discrete nuclear sites, this does not result in the redistribution of nuclear factor I. Localization of nuclear factor I to discrete subnuclear sites is therefore likely to represent a specific targeting event that reflects the requirement for nuclear factor I in adenovirus type 2 DNA replication.

Interaction of a common factor with ATF, Sp1, or TATAA promoter elements is required for these sequences to mediate transactivation by the adenoviral oncogene E1a

The adenovirus protein E1a stimulates transcription of both viral and cellular genes. Unlike most other transcription factors, it induces transactivation through several different promoter elements. The mechanism by which elements of diverse sequence mediate the effect of E1a is the focus of this study. Three E1a-responsive elements (an ATF site, an Sp1 site, and a TATA box containing the sequence TATAA) were studied to determine whether their interaction with a common factor is necessary for transactivation. In transfection assays, each element was used as a competitor against promoter constructs containing the other elements. The elements as competitors had no effect on basal transcription, but each competitor completely inhibited transactivation by E1a. Competitors that were not E1a responsive failed to inhibit transactivation. Therefore, either E1a itself or an E1a-inducible factor interacts with each of the elements to cause transactivation, most likely though an association with each element's specific binding protein.

Interaction of a common factor with ATF, Sp1, or TATAA promoter elements is required for these sequences to mediate transactivation by the adenoviral oncogene E1a

The adenovirus protein E1a stimulates transcription of both viral and cellular genes. Unlike most other transcription factors, it induces transactivation through several different promoter elements. The mechanism by which elements of diverse sequence mediate the effect of E1a is the focus of this study. Three E1a-responsive elements (an ATF site, an Sp1 site, and a TATA box containing the sequence TATAA) were studied to determine whether their interaction with a common factor is necessary for transactivation. In transfection assays, each element was used as a competitor against promoter constructs containing the other elements. The elements as competitors had no effect on basal transcription, but each competitor completely inhibited transactivation by E1a. Competitors that were not E1a responsive failed to inhibit transactivation. Therefore, either E1a itself or an E1a-inducible factor interacts with each of the elements to cause transactivation, most likely though an association with each element's specific binding protein.

The transcriptionally-active MMTV promoter is depleted of histone H1

We have used an ultraviolet light cross-linking and immunoadsorption assay to demonstrate that histones H1 and H2B are bound to the repressed MMTV promoter. Hormone activation results in reduced H1 content with little or no change in H2B. High resolution analysis of the glucocorticoid-inducible DNaseI hypersensitive region demonstrates an NF-1 footprint as well as specific sites of enhanced cleavage on nucleosome B and in the nucleosome B/nucleosome A linker. These results are consistent with a model in which binding of the glucocorticoid receptor to glucocorticoid regulatory elements on the surface of nucleosome B induces a chromatin transition that is necessary for transcription factor (NF-1 and TFIID) recruitment to the MMTV promoter. We hypothesize that association of histone H1 with important cis-elements on the promoter masks these sites, and glucocorticoid-induced displacement of H1 is necessary to expose factor binding sites at the 3' edge of nucleosome B, in the nucleosome B/nucleosome A linker and at the 5' edge of nucleosome A.

Identification of functional cis-acting elements within the rat liver S14 promoter

The structure of DNAase I hypersensitive site 1 (Hss-1), located adjacent to the 5' end of the rat liver S14 gene, is regulated by tissue-specific factors, and its formation correlates with the transcriptional activation of the S14 gene. We propose that tissue-specific trans-acting factors interacting with key cis-linked elements within this site function in the initiation of S14 gene transcription. To examine this hypothesis we used DNAase I footprint, gel shift and in vitro transcriptional analyses to identify cis-linked elements that function in the control of S14 gene transcription. Binding of rat liver nuclear proteins to the S14 promoter (from -8 to -464 bp) produced four DNAase I footprints (designated A-D). Gel shift studies showed that DNA-protein binding was tissue- and sequence-specific, differentially heat-sensitive, and abolished by proteinase K. The function of the four cis-acting elements was assessed by using an in vitro transcription initiation assay in which the S14 promoter was fused to a reporter gene (G-free cassette). Deletion studies showed that nuclear factors binding to regions A (-48 to -63 bp), B (-88 to -113 bp) and D (-286 to -310 bp) enhanced the rate of initiation of transcription, while proteins binding to region C (-227 to -244 bp) suppressed the rate of initiation of transcription. Based on oligonucleotide competition studies, we suggest that hepatic NF-1 (or a related protein) binding to the A region enhances the rate of initiation of S14 gene transcription. Since trans-acting factors interacting with regions B and D are found in liver but not in spleen or kidney, we suggest that the proteins interacting with these regions may be involved in the tissue-specific augmentation of S14 gene transcription.

Identification of a protein that interacts with the nuclear factor-1 (NF-1) binding site in cells that do not express NF-1: comparison to NF-1, cellular distribution, and effect on transcription

We examined expression of nuclear factor-1 (NF-1) in different cell lines. Expression was low or undetectable in T and B lymphocyte cell lines, whereas fibroblasts and other adherent cell lines generally had a relatively high level of NF-1 mRNA. In cell lines that did not express NF-1, gel retardation assays, nevertheless, indicated complexes between a protein or proteins and the NF-1 site. These complexes were less abundant than those formed with NF-1, they migrated more slowly, and they appeared as single species instead of the multiple species observed with NF-1. NF-1 site-binding proteins were compared in the fibrosarcoma cell line HT-1080 (expressed the highest level of NF-1 in our study) and the B cell line Raji (does not express NF-1). UV-crosslinking studies indicated that the NF-1 site-binding proteins in both cell lines were similar in size. Proteolytic clipping band shift assays suggested that the Raji protein and NF-1 share structural similarity in their DNA binding domains, but are distinct proteins. The NF-1 site mediated transcriptional stimulation in cell lines where NF-1 is expressed; however, this element did not affect transcription in cell lines that do not express NF-1, suggesting that the NF-1 site-binding protein in these cells is functionally distinct from NF-1.

Identification of two distinct regions within the adenovirus minimal origin of replication that are required for adenovirus type 4 DNA replication in vitro

The adenovirus type 4 origins of replication are located at each end of the linear, protein-linked viral DNA molecule and consist of the terminal 18 bp of the viral genome. The sequence of the first 8 bp of the viral genome varies among different adenovirus serotypes, but the sequence from bp 9 to 18 is conserved in all human serotypes, suggesting that it may be of critical importance to origin function. Using an in vitro system in which purified fractions or crude extracts of adenovirus type 4-infected HeLa cells can support initiation and elongation on linearized plasmid templates containing cloned origin sequences, we examined the effect of single base changes in positions 9 to 18 of the adenovirus origin on DNA replication in vitro. Changes in positions 12 to 16 have little effect, whereas alterations at positions 9, 10, 11, 17, and 18 all reduce the efficiency of initiation of DNA replication by between 50 and 90%. Our results show that the region from bp 9 to 18 contains two sets of bases essential for DNA replication which are separated by 5 bp in which single base changes can be accommodated. The likely role of the region from bp 9 to 18 as containing the recognition sequence for a DNA-protein interaction essential for viral DNA replication is discussed.

Replication of adenovirus type 4 DNA by a purified fraction from infected cells

An extract from Adenovirus type 4 infected HeLa cells was fractionated by ion-exchange and DNA affinity chromatography. One fraction, which bound tightly to single stranded DNA, contained predominantly a protein of apparent molecular weight 65,000 and three less abundant proteins. Immunological cross-reactivity with adenovirus type 2 proteins confirmed the presence of preterminal protein and indicated that the abundant species was the virus coded DNA binding protein. This fraction contained an aphidicolin resistant DNA polymerase activity and in the presence of a linearised plasmid containing the adenovirus type 4 origin of DNA replication efficient transfer of dCMP onto preterminal protein, indicative of initiation, was observed. Furthermore, addition of all four deoxyribonucleotide triphosphates and an ATP regenerating system resulted in the elongation of initiated molecules to generate plasmid molecules covalently attached to preterminal protein. Adenovirus type 4 DNA binding protein was extensively purified from crude adenovirus-4 infected HeLa extract by immunoaffinity chromatography using a monoclonal antibody raised against adenovirus type 2 DNA binding protein. A low level of initiation of DNA replication was detected in the fraction depleted of DNA binding protein but activity was restored by addition of purified DNA binding protein. DNA binding protein therefore plays an important role in the initiation of Ad4 DNA replication.

Herpes simplex virus type 1 origin-specific binding protein: oriS-binding properties and effects of cellular proteins

The herpes simplex virus type 1 (HSV-1) origin of replication, oriS, contains three highly homologous sequences, sites I, II, and III. The HSV-1 origin-binding protein (OBP), the product of the UL9 gene, has been shown to bind specifically to sites I and II. In this study, gel shift analysis was used to characterize interactions between site I DNA and proteins in infected and uninfected cell extracts. The formation of two protein-DNA complexes, bands A and B, was demonstrated with infected cell extracts, and one predominant protein-DNA complex, band M, was identified with mock-infected extracts. Protein interactions with the highly homologous site II and III DNAs were also characterized. Incubation of infected cell extracts with the lower-affinity site II DNA as a probe resulted in the appearance of two protein-DNA complexes with mobilities identical to those of the A and B complexes, while incubation with site III DNA resulted in the formation of a single complex with the mobility of band B; no A-like band was observed. Incubation of high concentrations of partially purified OBP with site I DNA resulted in the formation of two novel complexes, bands 9-1 and 9-2. Addition of uninfected or HSV-1-infected cell extracts to the purified OBP-site I DNA mix significantly enhanced the formation of complex 9-1. The enhanced formation of complex 9-1 by uninfected cell extracts implicates a cellular factor or factors in the formation or stabilization of the OBP-site I DNA complex.

Activation of octamer-containing promoters by either octamer-binding transcription factor 1 (OTF-1) or OTF-2 and requirement of an additional B-cell-specific component for optimal transcription of immunoglobulin promoters

Several distinct octamer-binding transcription factors (OTFs) interact with the sequence ATTTGCAT (the octamer motif), which acts as a transcription regulatory element for a variety of differentially controlled genes. The ubiquitous OTF-1 plays a role in expression of the cell cycle-regulated histone H2b gene as well as several other genes, while the tissue-specific OTF-2 has been implicated in the tissue-specific expression of immunoglobulin genes. In an attempt to understand the apparent transcriptional selectivity of these factors, we have investigated the physical and functional characteristics of OTF-1 purified from HeLa cells and both OTF-1 and OTF-2 purified from B cells. High-resolution footprinting and mobility shift-competition assays indicated that these factors were virtually indistinguishable in binding affinities and DNA-protein contacts on either the H2b or an immunoglobulin light-chain (kappa) promoter. In addition, each of the purified factors showed an equivalent intrinsic capacity to activate transcription from either immunoglobulin promoters (kappa and heavy chain) or the H2b promoter in OTF-depleted HeLa and B-cell extracts. However, with OTF-depleted HeLa extracts, neither factor could restore immunoglobulin gene transcription to the relatively high level observed in unfractionated B-cell extracts. Restoration of full immunoglobulin gene activity appears to require an additional B-cell regulatory component which interacts with the OTFs. The additional B-cell factor could act either by facilitating interaction of OTF activation domains with components of the general transcriptional machinery or by contributing a novel activation domain.

Activation of octamer-containing promoters by either octamer-binding transcription factor 1 (OTF-1) or OTF-2 and requirement of an additional B-cell-specific component for optimal transcription of immunoglobulin promoters

Several distinct octamer-binding transcription factors (OTFs) interact with the sequence ATTTGCAT (the octamer motif), which acts as a transcription regulatory element for a variety of differentially controlled genes. The ubiquitous OTF-1 plays a role in expression of the cell cycle-regulated histone H2b gene as well as several other genes, while the tissue-specific OTF-2 has been implicated in the tissue-specific expression of immunoglobulin genes. In an attempt to understand the apparent transcriptional selectivity of these factors, we have investigated the physical and functional characteristics of OTF-1 purified from HeLa cells and both OTF-1 and OTF-2 purified from B cells. High-resolution footprinting and mobility shift-competition assays indicated that these factors were virtually indistinguishable in binding affinities and DNA-protein contacts on either the H2b or an immunoglobulin light-chain (kappa) promoter. In addition, each of the purified factors showed an equivalent intrinsic capacity to activate transcription from either immunoglobulin promoters (kappa and heavy chain) or the H2b promoter in OTF-depleted HeLa and B-cell extracts. However, with OTF-depleted HeLa extracts, neither factor could restore immunoglobulin gene transcription to the relatively high level observed in unfractionated B-cell extracts. Restoration of full immunoglobulin gene activity appears to require an additional B-cell regulatory component which interacts with the OTFs. The additional B-cell factor could act either by facilitating interaction of OTF activation domains with components of the general transcriptional machinery or by contributing a novel activation domain.

Transcription factors NFI and NFIII/oct-1 function independently, employing different mechanisms to enhance adenovirus DNA replication

Initiation of adenovirus DNA replication is strongly enhanced by two transcription factors, nuclear factor I (NFI) and nuclear factor III (NFIII/oct-1). These proteins bind to two closely spaced recognition sequences in the origin. We produced NFI and NFIII/oct-1, as well as their biologically active, replication-competent DNA-binding domains (NFI-BD and the POU domain), in a vaccinia virus expression system and purified these polypeptides to apparent homogeneity. By DNase I footprinting and gel retardation, we show that the two proteins, as well as their purified DNA-binding domains, bind independently and without cooperative effects to their recognition sequences. By using a reconstituted system consisting of the purified viral proteins (precursor terminal protein-DNA polymerase complex (pTP-pol) and DNA-binding protein, we show that NFIII/oct-1 or the POU domain stimulates DNA replication in the absence of NFI or NFI-BD and vice versa. When added together, the enhancing effect of the two transcription factors was independent and nonsynergistic. Interestingly, stimulation by NFI or NFI-BD was strongly dependent on the concentration of the pTP-pol complex. At low pTP-pol concentrations, NFI or NFI-BD stimulated up to 50-fold, while at high concentrations, the stimulation was less than twofold, indicating that the need for NFI can be overcome by high pTP-pol concentrations. In contrast, stimulation by NFIII/oct-1 or the POU domain was much less dependent on the pTP-pol concentration. These data support a model in which NFI enhances initiation through an interaction with pTP-pol. Glutaraldehyde cross-linking experiments indicate contacts between pTP-pol and NFI but not NFIII/oct-1. The site of interaction is located in the NFI-BD domain.

An initiation zone of chromosomal DNA replication located upstream of the c-myc gene in proliferating HeLa cells

Studies on origins of DNA replication in mammalian cells have long been hampered by a lack of methods sensitive enough for the localization of such origins in chromosomal DNA. We have employed a new method for mapping origins, based on polymerase chain reaction amplification of nascent strand segments, to examine replication initiated in vivo near the c-myc gene in human cells. Nascent DNA, pulse-labeled in unsynchronized HeLa cells, was size fractionated and purified by immunoprecipitation with anti-bromodeoxyuridine antibodies. Lengths of the nascent strands that allow polymerase chain reaction amplification were determined by hybridization to probes homologous to amplified segments and used to calculate the position of the origin. We found that DNA replication through the c-myc gene initiates in a zone centered approximately 1.5 kilobases upstream of exon I. Replication proceeds bidirectionally from the origin, as indicated by comparison of hybridization patterns for three amplified segments. The initiation zone includes segments of the c-myc locus previously reported to drive autonomous replication of plasmids in human cells.

An initiation zone of chromosomal DNA replication located upstream of the c-myc gene in proliferating HeLa cells

Studies on origins of DNA replication in mammalian cells have long been hampered by a lack of methods sensitive enough for the localization of such origins in chromosomal DNA. We have employed a new method for mapping origins, based on polymerase chain reaction amplification of nascent strand segments, to examine replication initiated in vivo near the c-myc gene in human cells. Nascent DNA, pulse-labeled in unsynchronized HeLa cells, was size fractionated and purified by immunoprecipitation with anti-bromodeoxyuridine antibodies. Lengths of the nascent strands that allow polymerase chain reaction amplification were determined by hybridization to probes homologous to amplified segments and used to calculate the position of the origin. We found that DNA replication through the c-myc gene initiates in a zone centered approximately 1.5 kilobases upstream of exon I. Replication proceeds bidirectionally from the origin, as indicated by comparison of hybridization patterns for three amplified segments. The initiation zone includes segments of the c-myc locus previously reported to drive autonomous replication of plasmids in human cells.

DNA octamer element can confer E1A trans-activation, and adenovirus infection results in a stimulation of the DNA-binding activity of OTF-1/NFIII factor

Adenovirus E1A-dependent trans-activation of viral transcription involves the utilization and alteration of multiple sequence-specific transcription factors. Cellular genes are also activated by E1A, one example being the immunoglobulin heavy-chain locus when assayed by transfection into fibroblast cells. We have explored the basis for the E1A-dependent activation of this cellular transcription unit. We demonstrate that the ATTTGCAT ("octamer") element found in the heavy-chain enhancer and promoter is a target for E1A trans-activation since this sequence can confer inducibility to the normally unresponsive simian virus 40 early promoter. In addition, adenovirus infection stimulates the DNA-binding activity of the ubiquitous octamer-specific factor, OTF-1, and we presume that this is the basis for the stimulation of transcription. Although there are no octamer elements in the adenovirus genome that are known to be important for transcription, there are octamer elements in the viral terminal repeat sequences. These elements bind the NFIII factor and are important for the initiation of DNA replication. Since the NFIII factor has been shown to be identical to OTF-1, we suggest that the stimulation of OTF-1/NFIII activity during an adenovirus infection may be important for efficient initiation of adenovirus DNA synthesis.

Analysis of multiple forms of nuclear factor I in human and murine cell lines

Nuclear factor I (NFI) is a group of related site-specific DNA-binding proteins that function in adenovirus DNA replication and cellular RNA metabolism. We have measured both the levels and forms of NFI that interact with a well-characterized 26-base-pair NFI-binding site. Five different NFI-DNA complexes were seen in HeLa nuclear extracts by using a gel mobility shift (GMS) assay. In addition, at least six forms of NFI were shown to cross-link directly to DNA by using a UV cross-linking assay. The distinct GMS complexes detected were composed of different subspecies of NFI polypeptides as assayed by UV cross-linking. Different murine cell lines possessed varying levels and forms of NFI binding activity, as judged by nitrocellulose filter binding and GMS assays. The growth state of NIH 3T3 cells affected both the types of NFI-DNA complexes seen in a GMS assay and the forms of the protein detected by UV cross-linking.

A yeast ARS-binding protein activates transcription synergistically in combination with other weak activating factors

ABFI (ARS-binding protein I) is a yeast protein that binds specific DNA sequences associated with several autonomously replicating sequences (ARSs). ABFI also binds sequences located in promoter regions of some yeast genes, including DED1, an essential gene of unknown function that is transcribed constitutively at a high level. ABFI was purified by specific binding to the DED1 upstream activating sequence (UAS) and was found to recognize related sequences at several other promoters, at an ARS (ARS1), and at a transcriptional silencer (HMR E). All ABFI-binding sites, regardless of origin, provided weak UAS function in vivo when examined in test plasmids. UAS function was abolished by point mutations that reduced ABFI binding in vitro. Analysis of the DED1 promoter showed that two ABFI-binding sites combine synergistically with an adjacent T-rich sequence to form a strong constitutive activator. The DED1 T-rich element acted synergistically with all other ABFI-binding sites and with binding sites for other multifunctional yeast activators. An examination of the properties of sequences surrounding ARS1 left open the possibility that ABFI enhances the initiation of DNA replication at ARS1 by transcriptional activation.

Analysis of multiple forms of nuclear factor I in human and murine cell lines

Nuclear factor I (NFI) is a group of related site-specific DNA-binding proteins that function in adenovirus DNA replication and cellular RNA metabolism. We have measured both the levels and forms of NFI that interact with a well-characterized 26-base-pair NFI-binding site. Five different NFI-DNA complexes were seen in HeLa nuclear extracts by using a gel mobility shift (GMS) assay. In addition, at least six forms of NFI were shown to cross-link directly to DNA by using a UV cross-linking assay. The distinct GMS complexes detected were composed of different subspecies of NFI polypeptides as assayed by UV cross-linking. Different murine cell lines possessed varying levels and forms of NFI binding activity, as judged by nitrocellulose filter binding and GMS assays. The growth state of NIH 3T3 cells affected both the types of NFI-DNA complexes seen in a GMS assay and the forms of the protein detected by UV cross-linking.

Invertrons, a class of structurally and functionally related genetic elements that includes linear DNA plasmids, transposable elements, and genomes of adeno-type viruses

Invertrons are genetic elements composed of DNA with inverted terminal repeats at both ends, covalently bonded to terminal proteins involved in the initiation of DNA replication at both their 5' termini when they exist in the cytoplasm of their host in free form. They function as viruses, linear DNA plasmids, transposable elements, and sometimes combinations of two of these properties. They differ from retroviruses and related retro-type transposons which have direct repeats on both their genomic ends and exploit RNA intermediates for replication of their DNA. A model for replication and integration of invertrons is presented, as well as a model for transposition of transposable elements.

A yeast ARS-binding protein activates transcription synergistically in combination with other weak activating factors

ABFI (ARS-binding protein I) is a yeast protein that binds specific DNA sequences associated with several autonomously replicating sequences (ARSs). ABFI also binds sequences located in promoter regions of some yeast genes, including DED1, an essential gene of unknown function that is transcribed constitutively at a high level. ABFI was purified by specific binding to the DED1 upstream activating sequence (UAS) and was found to recognize related sequences at several other promoters, at an ARS (ARS1), and at a transcriptional silencer (HMR E). All ABFI-binding sites, regardless of origin, provided weak UAS function in vivo when examined in test plasmids. UAS function was abolished by point mutations that reduced ABFI binding in vitro. Analysis of the DED1 promoter showed that two ABFI-binding sites combine synergistically with an adjacent T-rich sequence to form a strong constitutive activator. The DED1 T-rich element acted synergistically with all other ABFI-binding sites and with binding sites for other multifunctional yeast activators. An examination of the properties of sequences surrounding ARS1 left open the possibility that ABFI enhances the initiation of DNA replication at ARS1 by transcriptional activation.

Adenovirus DNA-binding protein forms a multimeric protein complex with double-stranded DNA and enhances binding of nuclear factor I

The 72-kilodalton adenovirus DNA-binding protein (DBP) binds to single-stranded DNA as well as to RNA and double-stranded DNA and is essential for the replication of viral DNA. We investigated the binding of DBP to double-stranded DNA by gel retardation analysis. By using a 114-base-pair DNA fragment, five or six different complexes were observed by gel retardation. The mobility of these complexes is dependent on the DBP concentration, suggesting that the complexes arise by sequential binding of DBP molecules to the DNA. In contrast to binding to single-stranded DNA, the binding of DBP to double-stranded DNA appears to be noncooperative. DBP binds to linear DNA as well as to circular DNA, while linear DNA containing the adenovirus terminal protein was also recognized. No specificity for adenovirus origin sequences was observed. To study whether the binding of DBP could influence initiation of DNA replication, we analyzed the effect of DBP on the binding of nuclear factor I (NFI) and NFIII, two sequence-specific origin-recognizing proteins that enhance initiation. At subsaturating levels of NFI, DBP increases the rate of binding of NFI considerably, while no effect was seen on NFIII. This stimulation of NFI binding is specific for DBP and was not observed with another protein (NFIV), which forms a similar DNA-multimeric protein complex. In agreement with enhanced NFI binding, DBP stimulates initiation of adenovirus DNA replication in vitro especially strongly at subsaturating NFI concentrations. We explain our results by assuming that DBP forms a complex with origin DNA that promotes formation of an alternative DNA structure, thereby facilitating the binding of NFI as well as the initiation of DNA replication via NFI.

Identification of an octamer-binding site in the mouse kappa light-chain immunoglobulin enhancer

A 215-base-pair (bp) region of the mouse MOPC 41 kappa light-chain immunoglobulin gene enhancer has been analyzed for specific binding of lymphoid and nonlymphoid nuclear factors. Mobility shift assays with a series of overlapping DNA fragments have mapped DNA-binding sites for three unique factors. The B-cell-specific (OTF-2) and ubiquitous (OTF-1) octamer-binding transcription factors specifically bound to a site centered about 136 bp 5' of the nuclear factor NF-kappa B site. A third specific factor, NF-kappa E, bound to a site that was about 75 bp 5' of the NF-kappa B site and within a region important for enhancer function. This novel factor was found in both mature B and HeLa cell nuclei. B-cell OTF-2, B-cell OTF-1, and HeLa OTF-1 bound to the kappa enhancer and kappa promoter octamer sites with similar affinities despite a 2-bp difference in the kappa enhancer octamer sequence. However, DNase I footprint analyses indicated that affinity-purified OTF-2 bound both to the enhancer OTF site and, surprisingly, to 80 bp of A + T-rich flanking sequence. Moreover, methylation interference studies demonstrated distinct differences in OTF interactions between the consensus octamer in the kappa promoter and the nonconsensus octamer identified in the enhancer. This novel observation of an OTF-binding site in the kappa enhancer provides a common link with the OTF sites in the promoter-proximal regions of all kappa promoters and thus mirrors the structural arrangement of OTF sites found in the promoters and enhancers of immunoglobulin heavy-chain genes.

Binding sites of HeLa cell nuclear proteins on the upstream region of adenovirus type 5 E1A gene

Twenty one binding sites of HeLa cell nuclear proteins were identified on the upstream region of adenovirus type 5 E1A gene using DNase I footprint assay. The proximal promoter region contained five binding sites that overlapped the cap site, TATA box, TATA-like sequence, CCAAT box, and -100 region relative to the E1A cap site(+1). The -190 region was a potential site for octamer-motif binding proteins, such as NFIII and OBP100. An upstream copy of the E1A enhancer element 1 was the site for a factor (E1A-F) with the binding specificity of XGGAYGT (X = A, C; Y = A, T). E1A-F factor also bound to three other sites, one of which coincided with the distal E1A enhancer element. The distal element also contained a potential site for ATF factor. The adenovirus minimal origin of DNA replication competed for DNA-protein complex formation on the CCAAT and TATA box region and the -190 region, suggesting that these regions interacted with a common or related factor.

Mutations of the precursor to the terminal protein of adenovirus serotypes 2 and 5

Using a series of transient expression plasmids and adenovirus-specific DNA replication assays for both initiation and elongation, we measured the relative activities of mutant polypeptides of the precursor to the terminal protein (pTP) in vitro. Mutations that removed two to six amino acids of the amino terminus gradually decreased pTP activity; a deletion of 18 amino acids was completely inactive. Replacement of cysteine at residue 8 with a serine had little effect on pTP activity. Two amino-terminal in-frame linker insertion mutant polypeptides previously characterized in vivo as either replication defective or temperature sensitive had considerable activity at the permissive temperature in vitro. For one mutant pTP with a temperature-sensitive phenotype in vivo, elongation activity was decreased more than initiation in vitro, suggesting a role for this protein after the initiation step. Replacement mutations of serine 580, the site of covalent attachment of dCTP, completely abolished pTP function for both initiation and elongation.

Identification of HeLa cell nuclear factors that bind to and activate the early promoter of human polyomavirus BK in vitro

Human polyomavirus BK (BKV), an oncogenic DNA virus, differs from other papovaviruses in the organization of the regulatory region and in tissue tropism for kidney cells. The noncoding regulatory region of the viral genome in prototype strains includes three 68-base-pair (bp) repeats, each containing a number of potential regulatory elements. Some of these signals are unique to human papovaviruses, and others are homologous to those identified in many viral and cellular genes. We evaluated the contribution of individual 68-bp repeats to the initiation of transcription from the early promoter in a HeLa cell extract and identified cis-acting elements to which human cellular factors bind to activate transcription. The early promoter with only one copy of the 68-bp repeat could accurately initiate transcription in vitro, but additional copies were required for its stimulation. DNA-binding assays and DNase I protection experiments identified six domains in the regulatory region protected by human cellular factors. Two of these footprints were located within the proximal and distal 68-bp repeats, and one was located at the late side of the repeats. These footprints were centered over a TGGA(N)5-6GCCA core and were produced by a protein of the nuclear factor 1 (NF-1) family. This protein is either identical or similar to that which binds to the high-affinity site at the origin of adenovirus DNA replication. Three other domains, two at the junctions of the 68-bp repeats and one in the late side of the repeats, were partially protected by proteins with AP-1- and Sp-1-like activities. Transcription initiation from the early promoter was drastically reduced when a complete 68-bp repeat or the NF-1 binding site was used as a competitor in the in vitro assay. However, a point mutation within the NF-1 binding site, which reduced NF-1 binding in vitro to a level comparable to that of nonspecific DNA, also eliminated its ability to compete with early transcription. The murine homolog of the AP-1 binding site had a modest effect on in vitro transcription. Our results suggest that, among the multiple HeLa cell nuclear factors, NF-1 acts as a major activator of the early promoter in vitro.