Adenovirus origin of DNA replication: sequence requirements for replication in vitro

Possible mechanism of adenovirus generation from a cloned viral genome tagged with nucleotides at its ends

The entire cloned human adenovirus type 5 (Ad5) genome is known to be able to generate infectious virus after transfection into 293 cells when the both ends of the genome are exposed by digestion with appropriate restriction enzymes. However, when one or both ends of the genome are tagged with nucleotides and are not intact, whether the tagged end of the viral genome was remained tagged or corrected to be intact during the generation of viral clones has been unclear and, if such oligonucleotide removal occurs, how does the virus remove these tagged sequences and thereby restore its proper structure? Here, we show in our semi-quantitative study that the generation efficiency of virus clones decreases depending on the length of nucleotide tags at the both ends and that both the oligonucleotide tags were precisely removed during virus generation with restoration of the proper terminal sequences. Interestingly the viral genome of which one end was tagged, while the other was attached about 12-kb sequences, did generate intact viral clones at a reduced but significant efficiency. From these results, we here propose a possible mechanism whereby the terminal-protein-deoxycytidine complex enters from the enzyme-cleaved end and reaches deoxyguanine at the initiating position of DNA synthesis in vivo. A replication origin at one end, embedded deeply in double-stranded DNA, can be activated by two cycles of one-directional full-length DNA synthesis initiated by the other exposed replication origin about 30 kilobases away. We also describe new cassette cosmids which can use not only Pac I but also Bst BI for construction of an adenovirus vector, without reducing construction efficiency.

Relaxed template specificity in fowl adenovirus 1 DNA replication initiation

The fowl adenovirus 1 (FAdV-1) isolates PHELPS and OTE are highly similar, but have striking differences in the repeat region of the inverted terminal repeat (ITR). Whilst the repeat region in OTE conforms to the conventional human adenovirus repeat region (5'-CATCATC), that of PHELPS contains guanidine residues at positions 1, 4 and 7 (5'-GATGATG). This implies that the FAdV-1 isolates PHELPS and OTE have either distinct template specificity at replication initiation or, alternatively, a relaxed specificity for replication initiation. In this study, the distinct sequence variation at the origin of DNA replication in the ITRs of the FAdV-1 PHELPS and OTE isolates was confirmed. Sequence analyses of the pTP and Pol genes of both PHELPS and OTE did not reveal differences that could explain the distinct template specificity. Replication assays demonstrated that linear DNA fragments flanked by either 5'-CATCATC or 5'-GATGATG termini replicated in cells upon infection with FAdV-1 OTE and FAdV-1 PHELPS. This was evident from the appearance of DpnI-resistant fragments in a minireplicon assay. From these data, it is concluded that FAdV-1 has relaxed, rather than changed, its template specificity at replication initiation.

Adenovirus DNA replication

Replication of the adenovirus genome is catalysed by adenovirus DNA polymerase in which the adenovirus preterminal protein acts as a protein primer. DNA polymerase and preterminal protein form a heterodimer which, in the presence of the cellular transcription factors NFI/CTFI and NFIII/Oct-1, binds to the origin of DNA replication. DNA replication is initiated by DNA polymerase mediated transfer of dCMP onto preterminal protein. Further DNA synthesis is catalysed by DNA polymerase in a strand displacement mechanism which also requires adenovirus DNA binding protein. Here, we discuss the role of individual proteins in this process as revealed by biochemical analysis, mutagenesis and molecular modelling.

Mechanism of DNA replication in eukaryotic cells: cellular host factors stimulating adenovirus DNA replication

Replication of adenovirus (Ad) DNA depends on interactions between three viral and three cellular proteins. Human transcription factors NFI and Oct-1 recruit the Ad DNA polymerase to the origin of DNA replication as a complex with the Ad protein primer pTP. High affinity and specificity DNA binding to recognition sites in this origin by the transcription factors stimulate and stabilize pre-initiation complex formation to compensate for the low binding specificity of the pTP/pol complex. In this review, we discuss the properties of NFI and Oct-1 and the mechanism by which they enhance initiation of DNA replication. We propose a model that describes the dynamics of initiation and elongation as well as the assembly and disassembly of the pre-initiation complex.

The complete nucleotide sequence of the egg drop syndrome virus: an intermediate between mastadenoviruses and aviadenoviruses

The complete nucleotide sequence of an avian adenovirus, the egg drop syndrome (EDS) virus, was determined. The total genome length is 33,213 nucleotides, resulting in a molecular weight of 21.9 x 10(6). The GC content is only 42.5%. Between map units 3.5 and 76.9, the distribution of open reading frames with homology to known genes is similar to that reported for other mammalian and avian adenoviruses. However, no homologies to adenovirus genes such as E1A, pIX, pV, and E3 could be found. Outside this region, several open reading frames were identified without any obvious homology to known adenovirus proteins. In the region organized similarly as other adenoviral genomes, most homologies were found to an ovine adenovirus (OAV strain 287). The highest level of amino acid identity was found for the hexon proteins of EDS and OAV. The virus-associated RNA (VA RNA) was identified thanks to the homology with the VA RNA of fowl adenovirus serotype 1 (FAV1). Similarities with FAV1 were also found in the fiber protein. Our results demonstrate that the avian EDS virus represents an intermediate between mammalian and avian adenoviruses. The nucleotide sequence and genomic organization of the EDS virus reflect the heterogeneity of the aviadenovirus genus and the Adenoviridae family.

Cloning, sequence determination and functional expression of the genes encoding adenovirus type-4 polymerase and the terminal protein precursor

Sequences of the open reading frames encoding adenovirus type 4 (Ad4) DNA polymerase and the terminal protein precursor were determined. Sequence comparisons with the corresponding genes and proteins from Ad2 and Ad5 show high overall identity, but significant differences in those portions of the two proteins thought to be essential for their biological activities. Both Ad4 proteins were functionally expressed in insect cells from the corresponding cDNAs.

Nuclear transcription factor Oct-1 binds to the 5'-upstream region of CYP1A1 and negatively regulates its expression

The cytochrome P450-dependent monooxygenases, which represent an extended superfamily, catalyze the biotransformation of many endogenous and exogenous substances. One of these hemoproteins, cytochrome P4501A1, is most closely associated with the bioactivation of polycyclic aromatic hydrocarbons such as benzo[a]pyrene, which may play a role in environmental carcinogenesis. A negative regulatory element (NRE) has been localized in the 5'-upstream region of the cytochrome P4501A1 gene (CYP1A1) at -843 to -746 base pairs from the site of transcription. The purpose of this research was to define any interactions of trans-acting proteins with this cis element. Rat liver nuclei were used as the source of trans-acting proteins and a biotinylated NRE-bearing fragment (-782 to -843 bp) from a plasmid which contained the CYP1A1 was prepared by the polymerase chain reaction technique. Gel mobility shift assays were used to demonstrate interactions between this NRE fragment and nuclear proteins. The specific binding to an octamer-containing motif in the 5'-upstream region of CYP1A1 was demonstrated; this was used as a step in the partial purification from rat liver of the transcription factor, Oct-1. Conventional chromatographic procedures and DNA recognition site affinity chromatography were also used. HepG2 human hepatoma cells were transfected with both pMCoLUC+ which contains the luciferase gene as a reporter gene driven by the CYP1A1 promoter (including the NRE), and an Oct-1 expression vector. Luciferase activity/mg protein in the doubly-transfected cells was significantly lower than in cells containing only pMCoLUC+. A nuclear transcription factor Oct-1 interacts with a portion of the NRE of the rat CYP1A1, suppressing the expression of this gene. These findings may help to explain the low level of basal expression of CYP1A1 in mammalian systems.

Regulation of immunoglobulin gene transcription

Analysis of the immunoglobulin gene suggests that their expression is controlled through the combinatorial action of tissue- and stage-specific factors (OTF-2, TF-microB, NF-kappa B), as well as more widely expressed E motif-binding factors such as E47/E12. Two basic issues cloud understanding of how these factors are involved in immunoglobulin gene regulation. First, cloning of these factors shows them to be members of families of proteins, all with similar DNA-binding specificities. OTF-2 is a member of the POU domain family, NF-kappa B is a related protein, and the microE5/kappa E2-binding factors are members of the bHLH family. Second, these binding sites and associated factors are involved in the regulation of many genes, not only the immunoglobulin genes, and in fact not only lymphoid-specific genes. These facts complicate understanding which member of a family is in fact responsible for interaction with, and activation of, a particular binding element in an enhancer/promoter. Recently, more detailed analysis of the interactions between such proteins and their related binding sites suggest that a certain level of specificity may in fact be encoded by the DNA element such that one family member of a protein is preferentially bound, or alternatively that the protein-DNA interactions that occur give subtle alterations in protein conformation that unmask an activation or protein-protein interactive domain. An additional level of regulation is imparted by combinatorial mechanisms such as adjacent DNA-binding elements and factors that may alter activity, as well as "cofactors" that, by forming a complex with the bound factor, affect its activation of a gene in a particular cell type. A third level of specificity may be obtained by factors such as NF-kappa B and the bHLH family due to their ability to create heterogeneous complexes, creating unique complexes in a tissue- or stage-specific manner. The multiple functions transcription factors such as NF-kappa B and OTF-2 play in the transcriptional regulation of multiple genes seems complex in contrast to a one factor, one gene regulation model. However, this type of organization may limit the number of factors lymphocytes would require if each lymphoid-specific gene were activated by a unique factor. Thus what appears to be complexity at the molecular level may reflect an economical organization at the cellular level. Investigation of the key factors controlling these genes suggests an ordered cascade of transcription factors becomes available in the cell during B cell differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)

Initiation of bacteriophage PRD1 DNA replication on single-stranded templates

In vitro studies have demonstrated that single-stranded DNA molecules containing the 3' terminal nucleotides of the PRD1 DNA replication origin can support initiation by a protein-primed mechanism. We have determined the minimal requirements for priming by analyzing the template activity of various deletion derivatives. Our results showed that the 3'-terminal 15 nucleotides of the replication origin are sufficient for priming. The finding that the requirements for recognition of replication origin are different from those for priming suggests that there are two distinct steps during initiation of PRD1 DNA replication: first, recognition of the replication origin on double-stranded DNA and second, the priming event on single-stranded DNA. In addition our results showed that additional bases at the 3' end of templates did not affect priming activity, suggesting that the priming site is searched for from inside the template.

Overproduction of adenovirus DNA polymerase and preterminal protein in HeLa cells

Adenovirus (Ad) DNA polymerase (AdPol) and the preterminal protein (pTP) form a complex that is involved in the in vitro initiation of Ad DNA replication. Recombinant vaccinia viruses (vv) were constructed in which the genes encoding AdPol and pTP were cloned into a vaccinia/T7 hybrid expression-based vector downstream from the T7 promoter (pT7)/encephalomyocarditis virus (EMCV) 5'-untranslated region (UTR). HeLa cells infected with the recombinant vv-AdPol or vv-pTP or a mixture of both, together with the vv expressing T7 RNA polymerase produced significant levels of pTP and AdPol which were biologically active in the in vitro initiation of Ad DNA replication. These amounts of pTP and AdPol were only about two-fold less than the levels produced in insect cells infected with the recombinant baculovirus constructs expressing AdPol and pTP.

Enhancement of DNA replication by transcription factors NFI and NFIII/Oct-1 depends critically on the positions of their binding sites in the adenovirus origin of replication

The origin of DNA replication of many human adenoviruses is composed of a highly conserved core origin and an auxiliary region, containing the binding sites for NFI and NFIII/Oct-1. We examined enhancement of DNA replication in vitro by the purified functional DNA-binding domains of NFI (NFI-BD) and NFIII/Oct-1 (the POU domain), using origins in which the positions of the binding sites for these proteins were transposed. Insertion or deletion of two or three base pairs between the core origin and the NFI binding site resulted in a 3-5-fold decrease of stimulation, whereas larger insertions gradually reduced the stimulation further. Mutants in which the NFI binding site was separated approximately one or two helical turns from the core origin by AT-rich sequences could still be stimulated by NFI. In contrast, insertion of two or more base pairs between the NFI and NFIII/Oct-1 binding sites abolished stimulation by NFIII/Oct-1 almost completely. Furthermore, stimulation by this protein was lost when the Ad2 NFIII/Oct-1 binding site was transposed to a position closer to the core origin, destroying the NFI binding site. This shows that the position of the NFIII/Oct-1 binding site is essential for stimulation. Models to explain these position-dependent effects on stimulation are discussed.

Elements in the transcriptional regulatory region flanking herpes simplex virus type 1 oriS stimulate origin function

Like other DNA-containing viruses, the three origins of herpes simplex virus type 1 (HSV-1) DNA replication are flanked by sequences containing transcriptional regulatory elements. In a transient plasmid replication assay, deletion of sequences comprising the transcriptional regulatory elements of ICP4 and ICP22/47, which flank oriS, resulted in a greater than 80-fold decrease in origin function compared with a plasmid, pOS-822, which retains these sequences. In an effort to identify specific cis-acting elements responsible for this effect, we conducted systematic deletion analysis of the flanking region with plasmid pOS-822 and tested the resulting mutant plasmids for origin function. Stimulation by cis-acting elements was shown to be both distance and orientation dependent, as changes in either parameter resulted in a decrease in oriS function. Additional evidence for the stimulatory effect of flanking sequences on origin function was demonstrated by replacement of these sequences with the cytomegalovirus immediate-early promoter, resulting in nearly wild-type levels of oriS function. In competition experiments, cotransfection of cells with the test plasmid, pOS-822, and increasing molar concentrations of a competitor plasmid which contained the ICP4 and ICP22/47 transcriptional regulatory regions but lacked core origin sequences resulted in a significant reduction in the replication efficiency of pOS-822, demonstrating that factors which bind specifically to the oriS-flanking sequences are likely involved as auxiliary proteins in oriS function. Together, these studies demonstrate that trans-acting factors and the sites to which they bind play a critical role in the efficiency of HSV-1 DNA replication from oriS in transient-replication assays.

Sequence requirements for protein-primed DNA replication of bacteriophage PRD1

In vitro studies have demonstrated that linear duplex, protein-free DNA molecules containing an inverted terminal repeat (ITR) sequence of the PRD1 genome at one end can undergo replication by a protein-primed mechanism. No DNA replication was observed when the ITR sequence was deleted or was not exposed at the terminus of the template DNA. We have determined the minimal origin of replication by analyzing the template activity of various deletion derivatives. Our results showed that the terminal 20 base-pairs of ITR are required for efficient in vitro DNA replication. We have found that, within the minimal replication origin region, there are complementary sequences. A site-specific mutagenesis analysis showed that most of the point mutations in the complementary sequences markedly reduced the template activity. The analyses of the results obtained with synthetic oligonucleotides have revealed that the specificity of the replication origin is strand specific and even on a single-stranded template a particular DNA sequence including a 3'-terminal C residue is required for the initiation of PRD1 DNA replication in vitro.

Replication of an adenovirus type 34 mutant DNA containing tandem reiterations of the inverted terminal repeat

A mutant of human adenovirus type 34 (Ad34) has been isolated which contains DNA molecules with tandem reiterations of from two to eight copies of a 131-bp sequence within the right-sided inverted terminal repetition. Terminal heterogeneity was not eliminated by repeated plaque purifications indicating that the population of DNA molecules with various numbers of reiterations could rapidly evolve from the DNA of a single virus particle. These enlarged DNA molecules were capable of replication both in vivo and in vitro. The nucleotide sequence of the mutant Ad34 inverted terminal repetitions contained most of the essential features of the Ad origin of DNA replication. These features include the ATAATATACC sequence which is present between the highly conserved bases 9-18 in all human adenoviruses, as well as the consensus sequences for the binding of nuclear factor I and nuclear factor III. However, the reiterated sequences lacked a dG appropriately placed on the template strand to serve as a potential site for internal initiation. It appears that the rapid amplification of two to eight copies of the reiterated terminal sequences does not arise from internal initiation during replication but probably from homologous recombination.

Mutational analysis of single-stranded DNA templates active in the in vitro initiation assay for adenovirus DNA replication

Three distinct domains, A, the minimal origin, as well as B and C, the binding sites for the host nuclear factors, are required for efficient initiation of adenovirus (Ad) DNA replication at the termini. The initiation reaction was examined using partially purified nuclear extracts and various single-stranded oligomers as DNA templates. We observed that single-stranded oligomers containing Ad2 minimal origin (Ori) sequences (bp 1-18) from the I-strand of the Ad2 genome supported preterminal protein-dCMP complex formation in vitro. Using oligomers containing point mutations in the Ad2 minimal Ori sequence, six positions were identified as important to the function of the Ad2 minimal Ori sequence. Point mutations at position 7, 8, or 11 virtually abolished the ability of the oligomer to support the initiation reaction. Point mutations at position 4, 9, or 17 were found to decrease the ability of the oligomers to support the initiation reaction to 33, 67, and 58% of control, respectively. An oligomer complementary to the I-strand of the Ad2 minimal Ori was found to block initiation on minimal Ori template. A number of randomly selected nonspecific oligomers did not, in general, serve as templates for initiation with the exception of two oligomers, one of which was found to be about threefold more active than the control minimal Ori template. The biological significance of the in vitro initiation of Ad2 DNA replication on single-stranded DNA templates is discussed.

HeLa nuclear protein recognizing DNA termini and translocating on DNA forming a regular DNA-multimeric protein complex

Employing an exonuclease III protection assay we detected a protein in crude HeLa nuclear extracts binding, with apparent sequence specificity, to molecular ends of adenovirus type 2 (Ad2) DNA. This protein, designated nuclear factor IV (NFIV), was purified to homogeneity and was shown to be a hetero-dimer of 72,000 and 84,000 Mr. Binding to terminal Ad2 sequences was strongly enhanced by the presence of either of the sequence-specific DNA-binding proteins nuclear factor I and nuclear factor III. These proteins appeared to function as blockades for translocation of NFIV on DNA, thus producing apparent sequence specificity. In the absence of such a blockade, NFIV moved freely, without energy input, on any double-stranded DNA forming a regular DNA-multimeric protein complex as shown by methidiumpropyl EDTA footprinting and electron microscopy. Binding is completely dependent upon the presence of molecular ends. Evidence was obtained for a two-step mechanism in which termini are recognized by NFIV and used as a starting point for subsequent translocation. The possible functions of the protein in adenovirus DNA replication and in cellular processes requiring DNA termini are discussed.

Interactions between the termini of adeno-associated virus DNA

The adeno-associated virus (AAV) genome is a linear, single polynucleotide chain with inverted terminal repeats of 145 bases. In order to test whether the terminal repeats at opposite ends of the genome have to be able to completely base-pair during DNA replication, we have created chimeric genomes in which an 11 base symmetrical sequence has been deleted from the terminal repeat at one end of the genome and replaced by a different 12 base symmetrical sequence. We have used these chimeric constructs either as a duplex insert in pBR322 or as purified duplex virion DNA to transfect adenovirus-infected HeLa cells. When chimeric duplex virion DNA was used, all of the progeny virions obtained after two cell passages contained DNA with wild-type sequences in both terminal repeats. When plasmid clones were used, the structure of virion DNA depended on the original orientation. If the mutant terminal repeat was originally at the right end of the genome (terminus of genetic map), all progeny terminal repeat sequences were again wild-type. However, if the original construct contained the mutant sequence in the left terminal repeat, the majority of progeny molecules were parental in type (i.e. mutant left and wild-type right terminal repeat). We conclude (1) although the terminal repeats at opposite ends of the genome may interact during DNA replication, it is not necessary that they be perfectly complementary. (2) In direct competition, the wild-type sequence displays an advantage over the mutant allele. (3) In a plasmid clone, the terminal repeat on the left end of the genome is at an advantage in a competitive situation. We note that the left terminal repeat is adjacent to a transcriptional promoter.

Nuclear factor I can functionally replace transcription factor Sp1 in a U2 small nuclear RNA gene enhancer

Polymerase II transcription of a human gene for the small nuclear RNA U2 is dependent on two different promoter elements: a TATA-equivalent proximal sequence element and a distal enhancer element, which has been shown to contain Sp1- and octamer-binding sites. We have investigated the functional interplay between these transcription factor-binding sites of the enhancer, following transfection of U2 maxigene constructions into HeLa cells. There is a functional non-additive co-operation between the octamer-binding factor and Sp1, which is not dependent on the evolutionally conserved steric arrangement of these binding sites. We demonstrate that the conserved Sp1-binding site of the U2 enhancer can be fully substituted by a nuclear factor I (NFI) binding site, and that the octamer-binding factor functions in stimulating transcription in conjunction with either Sp1 or NFI. Since the octamer-binding factor is most probably the same protein as nuclear factor III (NFIII), the results imply that the NFI/NFIII complex, involved in adenovirus DNA replication, also can function as an efficient activator of transcription.

Nuclear transport of adenovirus DNA polymerase is facilitated by interaction with preterminal protein

The mRNAs for the 80 kd adenovirus preterminal protein (pTP) and the 140 kd DNA polymerase (AdPol) contain several exons spliced to the main open reading frames (m-ORFs) located in the early transcription unit E2B. These proteins were transiently expressed in monkey kidney cells (CV1) utilizing the first ATG (pTP1 and AdPol1) or the ATG of a linker inserted at the beginning of the m-ORFs (pTP2 and AdPol2). Only pTP2 and AdPol2 were functionally active in an in vitro replication initiation assay. Both pTP1 and pTP2 were transported to the nucleus. The sequence RLPV(R)6VP, which is present in both pTPs, is identified as their nuclear localization signal. In contrast, AdPol1 was cytoplasmically localized, whereas AdPol2 was distributed in both compartments, suggesting that the nuclear localization signal for AdPol is within the first 139 amino acids. Interestingly, when AdPol1 and pTP1 or AdPol2 and pTP2 were coexpressed in the transfected cells, the nuclear distribution of AdPol1 or AdPol2 was significantly increased. We demonstrate that the nuclear transport of AdPol is facilitated, irrespective of the presence of its nuclear localization signal, by interaction with pTP.

Adenovirus DNA replication in vitro: duplication of single-stranded DNA containing a panhandle structure

Adenovirus DNA replicates by displacement of one of the parental strands followed by duplication of the displaced parental single strand (complementary strand synthesis). Displacement synthesis has been performed in a reconstituted system composed of viral and cellular proteins, employing either the viral DNA-terminal protein complex as template or linearized plasmids containing the origin. Previously, evidence was obtained that in vivo complementary strand synthesis requires formation of a panhandle structure originating from hybridization of the inverted terminal repeats. To study the conditions for complementary strand synthesis in vitro, we have constructed an artificial panhandle molecule that contains a double-stranded inverted terminal repetition (ITR) region and a single-stranded loop derived from the left and right terminal XmaI fragments of Ad2. Such a molecule appeared to be an efficient template and could initiate by the same protein-priming mechanism as double-stranded DNA, employing the precursor terminal protein. The efficiency of both types of template was comparable. Like for replication of the duplex molecule initiation of panhandle replication was stimulated by nuclear factors I and III, proteins that bind to specific double-stranded regions of the ITR. The Ad DNA-binding protein is essential and the 39 kDa C-terminal domain of this protein that harbors the DNA-binding properties is sufficient for its function. These results support the hypothesis that panhandle formation is required for duplication of the displaced strand.

Palindrome-hairpin linear plasmids possessing only a part of the ORF1 gene of the yeast killer plasmid pGKL1

The yeast Kluyveromyces lactis harboring linear DNA plasmids pGKL1 and pGKL2 exhibits killer and killer-resistant phenotypes. Two new linear plasmids pK192L and pK192S were found in the weak killer mutant KUV192 induced by UV irradiation. pK192S was always accompanied by pK192L in subclones of KUV192. Both plasmids were derived from pGKL1 by deletion of the large right part of it. pK192L was 4.9 kb in size and had a palindromic structure consisting of 2.35 kb inverted terminal repetitions and a 215 base unique sequence. Analysis of denatured and renatured DNA strands suggested that pK192S was a hairpin-like form of pK192L. The pK192 plasmids were maintained only in cells haboring either pGKL1 or pGKL1Sin addition to pGKL2 and completed with pFKL1 or pGKL1S for their maintenance. Since no complete ORF1 was conserved in pK192 plasmids, these results lead to the conclusion that the ORF1 gene is necessary for the replication and/or maintenance of pGKL1.

Gene overlap results in a viral protein having an RNA binding domain and a major coat protein domain

L-A double-stranded RNA (dsRNA) replicates in vivo in yeast in a conservative, asynchronous (first [+] strand then [-] strand), intraviral process. New particles are formed by packaging (+) strands. Added viral (+) single-stranded RNA (ssRNA) is specifically bound by empty virus-like particles (VLPs) and, in a reaction requiring a host factor, is converted in vitro to dsRNA. We find that the isolated binding complex replicates only if it was formed in the presence of the host factor. The VLP minor 180 kd protein, but not the major coat protein, has ssRNA binding activity on Western blots. The 180 kd protein shares a common antigenic domain with the major coat protein, the latter known to be encoded by L-A dsRNA. The 180 kd protein, but not the major coat protein, also shares an antigenic domain with a sequence encoded by the 3' end of the L-A (+) strand. Thus the 180 kd protein is also encoded by L-A dsRNA and consists of a major coat protein domain and a ssRNA binding domain.

TGGCA protein is present in erythroid nuclei and binds within the nuclease-hypersensitive sites 5' of the chicken beta H- and beta A-globin genes

The developmentally regulated 5'-flanking DNase-I-hypersensitive site of the chicken beta H-globin gene in nuclei contains a subregion which is resistant to DNase I and which disappears when nuclei are extracted with 0.3 M NaCl, suggesting that there are salt-extractable proteins bound to sequences within this region. The 0.3 M NaCl extract contains two proteins which bind in vitro to these sequences. One of the binding sequences has an inverted repeat very similar to that bound by TGGCA protein. Partially purified TGGCA protein from chicken liver binds to this sequence in vitro giving exactly the same footprint as that obtained with erythroid nuclear proteins. Similarly TGGCA protein binds to an inverted repeat with the beta A-globin 5'-hypersensitive site giving a footprint identical to that obtained with erythroid nuclear protein extracts. From competition footprinting experiments and the electrophoretic mobility of the protein-DNA complex, it is concluded that the erythroid proteins previously described as binding to the beta H- and beta A-globin inverted repeats within the 5'-flanking hypersensitive sites both belong to the TGGCA protein family.

DNA sequences required for the initiation of adenovirus type 4 DNA replication in vitro

In-vivo studies have demonstrated that adenovirus type 2 and adenovirus type 4 have different DNA sequence requirements for the initiation of DNA replication. To investigate the basis of these differences an in-vitro system has been developed which will faithfully initiate adenovirus type 4 DNA replication. A plasmid containing 140 base-pairs of the right terminus of adenovirus type 4 supported initiation of DNA replication in vitro, provided that the plasmid was linearized in such a way as to locate the viral terminal sequences at the molecular ends of the DNA. Initiation by adenovirus type 4-infected cell extracts was also supported by a plasmid containing the complete adenovirus type 2 inverted terminal repeat (ITR). Deletion analysis of both adenovirus types 2 and 4 ITRs revealed that only the terminal 18 base-pairs of the genomes (perfectly conserved between the 2 viruses) were required for initiation in vitro. Thus, initiation was not enhanced by the presence of either the NFI site, the NFIII site or both sites together. Fractionation of a HeLa cell nuclear extract, by ion-exchange chromatography, identified a nuclear factor that stimulated the initiation reaction four- to fivefold. The stimulatory factor did not correspond to either of the cellular proteins NFI or NFIII which stimulate adenovirus type 2 DNA replication in vitro. Initiation in vitro was also supported by single-stranded DNA templates, albeit at a lower efficiency. Studies with synthetic oligonucleotides indicated a surprising specificity for initiation: whereas the strand used as template during initiation in vivo was active as a template for initiation in vitro, the complementary strand was inactive.

Purification and characterization of OTF-1, a transcription factor regulating cell cycle expression of a human histone H2b gene

An octamer-binding transcription factor, OTF-1, which stimulates transcription of a human histone H2b gene, has been purified from HeLa nuclear extracts. This purification was achieved through the use of DNA affinity chromatography, and the factor was unambiguously identified by renaturation of activity following SDS-polyacrylamide gel electrophoresis. The purified factor retained the ability to efficiently stimulate H2b transcription in a reconstituted in vitro system. This effect was dependent upon an intact octamer element and was observed in the absence of the other H2b promoter elements (except the TATA motif). Furthermore, this activity was not detected in nuclear extracts prepared from cells synchronized in G2, in agreement with the in vivo data showing S-phase-specific utilization of the octamer element. From these data, we conclude that we have purified the bona fide H2b transcriptional regulatory factor.

Amplification of a chorion gene cluster in Drosophila is subject to multiple cis-regulatory elements and to long-range position effects

We have used P-element transformation to study cis-acting elements involved in the control of amplification of the third chromosome chorion gene cluster (66D12-15) in Drosophila melanogaster. To reduce position effects large fragments (5.7 to 12 kb; kb = 10(3) bases) of chorion DNA and the 7.2 kb ry+ fragment were used to "buffer" these putative elements from sequences at the insertion site. Nevertheless, even the longest constructs were profoundly affected by the insertion sites and showed amplification levels ranging from undetectable to higher than in the endogenous locus. Any amplification was tissue and temporally correct and extended into the neighboring ry+ sequences. Analysis of amplification levels at various points along two constructs bearing the same 10 kb chorion insert in opposite orientations showed maximal levels occurring at one end of the chorion fragment, irrespective of whether that end was buffered at the middle of the transposon or exposed close to the insertion site. The maximally amplifying region encompasses the amplification control element (ACE), which has been shown to be necessary for amplification, in agreement with its putative role as a replication origin. We have additionally identified amplification-enhancing elements present elsewhere in the 10 kb chorion fragment, which are needed for attainment of high copy number. These elements, distinct from the ACE, have been only coarsely localized within two 2.25 to 2.3 kb regions. Some interesting sequence similarities between these two regions and the ACE element are pointed out.