Cloned origin of DNA replication in c-myc gene can function and be transmitted in transgenic mice in an episomal state.

The c-myc protein has recently been shown to interact with a region possessing putative origin of DNA replication and enhancer activities located 2 kb upstream of the c-myc gene itself. Transgenic mice were obtained by injecting constructs containing this region, termed pmyc(H-P), into fertilized mouse eggs. The transgenic elements were capable of efficient replication in all mouse tissues examined and were maintained in an episomal state even in highly differentiated cells. Moreover, pmyc(H-P) was transmittable to the progeny throughout several generations, which suggests that the fragment derived from the region upstream of the c-myc gene possesses sequences necessary for partition, stability and DNA replication of the plasmid in the cells. In addition, we have shown that the plasmid might be captured only by eggs, not by sperm.     

Two enhancer elements for DNA replication of pSC101, par and a palindromic binding sequence of the Rep protein.

The minimal replication origin (ori) of the plasmid pSC101 has been previously defined as an approximately 220-bp region by using plasmids defective in the par region, which is a cis-acting determinant of plasmid stability. This ori region contains the DnaA binding sequence, three repeated sequences (iterons), and an inverted repeat (IR) element (IR-1), one of the binding sites of an initiator protein, Rep (or RepA). In the present study, we show that plasmids containing par can replicate at a nearly normal copy number in the absence of IR-1 but still require a region (the downstream region) between the third iteron and IR-1. Because par is dispensable in plasmids retaining IR-1, par and IR-1 can compensate each other for efficient replication. The region from the DnaA box to the downstream region can support DNA replication at a reduced frequency, and it is designated "core-ori." Addition of either IR-1 or par to core-ori increases the copy number of the plasmid up to a nearly normal level. However, the IR-1 element must be located downstream of the third iteron (or upstream of the rep gene) to enhance replication of the plasmid, while the par region, to which DNA gyrase can bind, functions optimally regardless of its location. Furthermore, the enhancer activity of IR-1 is dependent on the helical phase of the DNA double helix, suggesting that the Rep protein bound to IR-1 stimulates the activation of ori via its interaction with another factor or factors capable of binding to individual loci within ori.     

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

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

DNA replication in phage P4: characterization of replicon II

The genetic element P4 propagates in its host Escherichia coli both as a satellite phage and as a plasmid. Two partially overlapping replicons coexist, namely replicon I and replicon II. The former is composed of two sites, ori1 and crr, and depends on P4 alpha gene product for replication. The P4 alpha protein has primase and helicase activities, and binds specifically to both ori1 and crr. Replicon II is composed of two sites, ori2 and crr, and its replication also depends on P4 alpha primase and helicase activities. In replicon II, the alpha protein binds only crr. Here we show that for replicon II the relative orientation of ori2 and crr is essential for replication to occur. Furthermore we delimit ori2 to a 22 bp region (6234-6255), internal to the alpha gene, sufficient for replicon II replication. We mutagenized this region and identified two mutants, which carry one and two base substitutions, respectively, that prevent replicon II replication. In electrophoretic mobility shift experiments of ori2, ori1, and crr DNA fragments with E. coli extracts, ori2 was not shifted, whereas both ori1 and crr were specifically bound, suggesting that other host protein(s), beside P4 alpha, are able to bind to these cis essential regions. Apparently, no binding to ori2 could be identified, thus suggesting that neither alpha nor other bacterial proteins specifically bind to this region.     

DNA bending of pSC101 ori induced by Rep,a replication initiator protein and IHF

Purified Rep (or RepA) protein, a replication initiator of plasmid pSC101, is present almost solely in the dimer form, and its binding activity for the directly repeated sequences (iterons) in the replication origin (ori) is very low. When Rep protein was treated with guanidine hydrochloride followed by renaturation, it was shown to bind to the iterons with very high efficiency. A gel shift experiment suggested that guanidine-treated Rep bound to iterons as a monomer form. The Rep monomer bound noncooperatively to the three iterons and induced bending of the DNA helix axis in the same direction (about 100 degrees ). The configuration of the IHF box that is a binding site of another DNA bending protein IHF, the three iterons and an AT-rich region between these sequences was important for efficient bending of the ori region. Furthermore, a mutant Rep protein (Rep(IHF)) which can support the plasmid replication in IHF-deficient host cells was purified, and it was found that affinity of the Rep(IHF) monomer for iterons was similar to that of wild-type Rep and bent DNA only 14 degrees more strongly than did the wild-type Rep. Rep(IHF)-dependent plasmid replication, however, required both enhancer regions, par and IR-1, in addition to "core ori" as a minimal essential ori, whereas only one of these two enhancers was necessary for wild-type Rep-dependent replication. How Rep(IHF) can support plasmid replication in the absence of IHF is discussed.     

Origin of adenovirus DNA replication. Role of the nuclear factor I binding site in vivo

An assay is described that detects in vivo a single round of initiation and DNA synthesis directed by a linear molecule containing an exposed single copy of an adenovirus (Ad) origin of replication. This and a previously described assay, which measures multiple rounds of DNA replication, were used to identify DNA sequences within the Ad2 and Ad4 origins of replication that are important for ori function. Linear DNA molecules containing sequences from the Ad2 or Ad4 genome termini were cotransfected with homologous and heterologous helper virus, and net amounts of DNA synthesis were compared. Linear molecules containing the Ad4 inverted terminal repeats were replicated 20-fold better in the presence of the homologous helper, whereas both Ad2 and Ad4 inverted terminal repeats were utilized efficiently by Ad4. DNA sequence analysis of the Ad2 ori and the corresponding region in Ad4 indicated that, although there are only ten variant base-pairs, eight are located within the Ad2 DNA sequence recognized by the cellular protein nuclear factor I. This protein is required to achieve the maximal rate of Ad2 DNA replication in vitro, and these differences therefore identify DNA sequences that are crucial to Ad2 ori function. The Ad4 ITR does not contain a functional nuclear factor I binding site, and deletion analysis has demonstrated that this region of the Ad4 genome is not required for ori function. In contrast to Ad2, the DNA sequences required for the initiation of Ad4 DNA replication were shown to reside entirely within the terminal 18 base-pairs of the Ad4 inverted terminal repeat.     

Identification of the origin of replication of bovine papillomavirus and characterization of the viral origin recognition factor E1.

Expression of the viral polypeptides E1 and E2 is necessary and sufficient for replication of BPV in mouse C127 cells. By providing these factors from heterologous expression vectors we have identified a minimal origin fragment from BPV that contains all the sequences required in cis for replication of BPV in short term replication assays. This same sequence is also required for stable replication in the context of the entire viral genome. The identified region is highly conserved between different papillomaviruses, and is unrelated to the previously identified plasmid maintenance sequences. The minimal ori sequence contains a binding site for the viral polypeptide E1, which we identify as a sequence specific DNA binding protein, but surprisingly, an intact binding site for the viral transactivator E2 at the ori is not required. The isolated origin shows an extended host region for replication and replicates efficiently in both rodent and primate cell lines.     

Purified bacteriophage lambda O protein binds to four repeating sequences at the lambda replication origin.

The bacteriophage lambda O protein is needed for initiation of lambda DNA replication. Several lines of evidence suggest that initiation requires that this protein interacts with a specific sequence called ori (for origin) in lambda DNA. We have purified this protein to near homogeneity and studied the protection against nuclease cleavage of the origin DNA sequences. Our data demonstrate that the O protein binds within an interval of about 95 base pairs (bp), which contains four tandemly arranged 19bp repeating sequences, ATCCCTCAAAACGA (G)GG GAT(A). At a low concentration of O protein, the inner two repeats are primarily covered, while binding to the outer two repeats requires a high concentration of O protein. From the molecular size of O protein (32,000 daltons), and the internal symmetry in each 19bp repeat, we inferred that the O protein may bind in dimeric form, and that the 95bp region may be filled only when four such dimers have bound. This interaction is discussed in connection with the "activation" of the ori by O protein leading to initiation of DNA synthesis.     

Bacteriophage P4 DNA replication. Nucleotide sequence of the P4 replication gene and the cis replication region

A 3100 base piece of DNA from the 11,500 base genome of bacteriophage P4 was analyzed for its nucleotide sequence. This segment of DNA contains two open reading frames of 106 and 777 amino acid residues; the latter of which is the coding sequence for the Mr 84,841 alpha protein, which is necessary for P4 DNA replication and is thought to act as a P4-specific DNA primase. A region of about 300 base-pairs localized just beyond the alpha gene and about 4500 bases from the origin of replication (ori), was defined as the locus for P4's cis replication region (crr). This region is required for replication both in vivo and in vitro, and consists of two directly repeated sequences of 120 base-pairs that match one another at 98 positions. These directly repeated sequences are separated by 60 base-pairs, which are not necessary for replication. Each repeat in crr contains three copies of the octamer TGTTCACC that is found six times in ori. Either of the 120 base-pair repeat sequences in crr is sufficient for replication, and the entire crr can function in an inverted orientation. crr is also active at a distance of 1800 bases from the P4 origin of replication.     

Sequence-specific DNA-binding proteins which interact with (G + C)-rich sequences flanking the chicken c-myc gene

The interaction of nuclear sequence-specific DNA-binding proteins from definitive chicken erythrocytes, thymus and proliferating transformed erythroid precursor (HD3) cells with the 700-base-pair (700-bp) DNA 5'-flanking region of the chicken c-myc gene was investigated by in vitro footprint analysis. The major HD3 protein-binding activity binds to a site (site V) 200 bp upstream from the 'cap' site but, after further fractionation, a second distinct binding activity is detected to a site (site VIII) which contains both the 'CAAT' and 'SP1-binding' consensus sequences. Protein from thymus and erythrocyte cells which express c-myc at lower levels, bind to seven and eight sites respectively. In common with HD3 cell protein, they both bind to site VIII and, although binding to the sequence at site V is also detected, the footprint protection pattern is sufficiently different (site V') to suggest the involvement of different proteins in terminally differentiated and proliferating cells. The DNA-binding activities were partially fractionated by high-performance liquid chromatography gel filtration and include an erythrocyte-specific protein which binds to a c-myc gene poly(dG) homopolymer sequence similar to that found upstream of the chicken beta A-globin gene.     

The structure and function of the replication initiator protein (Rep) of pSC101: an analysis based on a novel positive-selection system for the replication-deficient mutants

Plasmid pSC101 encodes a 37.5 kDa Rep (RepA) protein, which binds to three 21-base repeats (DR-1, DR-2, and DR-3) in the replication origin region (ori) of the plasmid to initiate replication. Rep also binds to two palindromic sequences (IR-1 and IR-2) which overlap the rep promoter. The binding of Rep to IR-2 represses the production of Rep itself. It is highly likely that the balance of these functions of Rep plays a major role in controlling the copy number of pSC101. In this study, we developed a positive-selection system for replication-deficient mutants of the initiator protein. This system can be applied to the study of other replication systems by changing ori and rep of pSC101 to the corresponding genes. Thirty-four replication-deficient (Ini(-)) mutants were isolated with this system, and analyzed as to the relation between the structure and function of the Rep protein. Seventeen of these 34 Ini(-) mutants were found to lack auto-repressor activity as well as initiator activity. DNA sequence analysis showed that one-third (from the C-terminus) of Rep is dispensable for the auto-repressor activity, while the initiator activity seems to require the whole protein.     

The integration host factor of Escherichia coli binds to bent DNA at the origin of replication of the plasmid pSC101

The integration host factor (IHF) of Escherichia coli is necessary for maintenance of pSC101. The protein binds specifically to the replication origin of the plasmid, in the AT-rich region located immediately adjacent to the left, weak binding site for the plasmid-encoded initiator protein. DNAase I and OH- radical footprinting experiments showed that IHF protects 49 bp of the DNA at the origin region. Methylation protection analyses revealed that IHF contacts purine residues in both the major and minor grooves of the DNA. Electrophoretic analyses showed that IHF binds to bent DNA, and the protein binding further enhances the degree of DNA bending. Site-directed mutagenesis of three of the contact points not only abolished binding of the protein to the DNA but also inactivated the replication origin. Therefore, binding of IHF to the ori sequence most probably is necessary for initiation of plasmid replication.     

Essential DNA sequence for the replication of Rts1.

The promoter sequence of the mini-Rts1 repA gene encoding the 33,000-dalton RepA protein that is essential for replication was defined by RNA polymerase protection experiments and by analyzing RepA protein synthesized in maxicells harboring mini-Rts1 derivatives deleted upstream of or within the presumptive promoter region. The -10 region of the promoter which shows homology to the incII repeat sequences overlaps two inverted repeats. One of the repeats forms a pair with a sequence in the -35 region, and the other forms a pair with the translation initiation region. The replication origin region, ori(Rts1), which was determined by supplying RepA protein in trans, was localized within 188 base pairs in a region containing three incII repeats and four GATC sequences. Dyad dnaA boxes that exist upstream from the GATC sequences appeared to be dispensable for the origin function, but deletion of both dnaA boxes from ori(Rts1) resulted in reduced replication frequency, suggesting that host-encoded DnaA protein is involved in the replication of Rts1 as a stimulatory element. Combination of the minimal repA and ori(Rts1) segments, even in the reverse orientation compared with the natural sequence, resulted in reconstitution of an autonomously replicating molecule.