Showing papers on "Primase published in 1982"

A DNA primase activity associated with DNA polymerase alpha from Drosophila melanogaster embryos.

Abstract: Preparations of DNA polymerase alpha from early embryos of Drosophila melanogaster catalyze the ATP-dependent synthesis of DNA with single-stranded M13 DNA or poly(dT) templates. In the case of M13 DNA, GTP, but not UTP or CTP, can replace ATP. The reaction is completely dependent on added template and is not inhibited by alpha-amanitin. Alkaline hydrolysis of the product synthesized in the presence of [alpha-32P]dATP and poly(dT) generates 32P-labeled 3'(2') adenylate, showing that a covalent ribo-deoxynucleotide linkage is formed. Furthermore, incorporation of ribonucleotides occurs at the 5' end of the newly synthesized polynucleotide chain. These findings are consistent with the hypothesis that a ribo-oligonucleotide primer is synthesized by primase action and subsequently elongated by DNA polymerase. Under the appropriate conditions, DNA polymerase I from Escherichia coli can elongate primers formed by primase in the presence of ATP and poly(dT). Primase activity copurifies with DNA polymerase alpha and may be part of the multisubunit polymerase molecule.

Two alternative mechanisms for initiation of DNA replication forks in bacteriophage T4: priming by RNA polymerase and by recombination.

Abstract: We show that bacteriophage T4 has two alternative mechanisms to initiate DNA replication; one dependent on Escherichia coli RNA polymerase (RNA nucleotidyltransferase, EC 2.7.7.6), and one dependent on general recombination. Continued DNA synthesis under recombination-defective conditions was sensitive to rifampin, an inhibitor of RNA polymerase. On the other hand, DNA synthesis accelerated in spite of the present of rifampin if recombination occurred.

DNA primase activity associated with DNA polymerase alpha from Xenopus laevis ovaries

Abstract: One of the two forms of DNA polymerase alpha from ovaries of the frog Xenopus laevis catalyzed ribonucleoside triphosphate-dependent DNA synthesis on single-stranded circular fd phage DNA templates. DNA synthesis was dependent on ATP and added template. CTP, GTP, and UTP stimulated DNA synthesis but were not required and could not substitute for ATP. DNA synthesis was not inhibited by alpha-amanitin. Neither poly(dT) nor double-stranded DNA served as template. Analysis of [32P]-dTMP-labeled product by neutral and alkaline agarose gel electrophoresis showed that 0.1- to 1-kilobase DNA fragments (average size of approximately equal to 0.25 kilobase) were synthesized. The fragments were not covalently linked to the template. Either [alpha-32P]NMP, [gamma-32P]ATP, or [gamma-32P]GTP were incorporated also into the product. Analysis of the product after hydrolysis by KOH, alkaline phosphatase, or bacteriophage T4 3' leads to 5' exonuclease showed the presence of a small oligoribonucleotide primer at the 5' end of the newly synthesized DNA. NTP-dependent DNA-synthesizing activity copurified on six columns and cosedimented during glycerol gradient centrifugation with one form of DNA polymerase alpha activity but not with the other form. These results suggest that DNA primase activity is associated with one of the two forms of X. laevis DNA polymerase alpha.

Sequences of the Escherichia coli dnaG primase gene and regulation of its expression

Abstract: The nucleotide sequence of a cloned section of the Escherichia coli chromosome containing the dnaG primase gene [Lupski, J., Smiley, B., Blattner, F. & Godson, G. N. (1982) Mol. Gen, Genet. 185, 120--128] has been determined. The region coding for the dnaG primase has been identified by NH2-terminal and tryptic peptide amino acid analysis of the dnaG protein. The coding region is 1,740 base pairs long (580 amino acids) and is preceded by an unusual ribosome-binding site sequence (G-G-G-G). The dnaG gene is read in the same direction as the adjacent rpoD gene, but no obvious promoter sequences can be found for either gene within several hundred nucleotides upstream. Other unusual features of the dnaG gene that may explain the maintenance of its product at low copy number are the presence of a RNA polymerase terminator 31 nucleotides upstream from the ATG initiator codon and greater use (3--10 times) of certain condons that occur infrequently in other E. coli genes. The nucleotide sequence has also been correlated with data from transposon Tn5 insertional inactivation mapping.

Synthesis by the DNA primase of Drosophila melanogaster of a primer with a unique chain length

Abstract: The primase associated with the DNA polymerase alpha from embryos of Drosophila melanogaster catalyzes the synthesis of ribo-oligonucleotide primers on single-stranded M13 DNA or polydeoxythymidylate templates, which can be elongated by DNA polymerase action [Conaway, R. C. & Lehman, I. R. (1982) Proc, Natl. Acad. Sci, USA 79, 2523--2527]. The primers synthesized in a coupled primase-DNA polymerase alpha reaction with an M13 DNA template are of a unique size (15 residues); those synthesized with poly(dT) range from 8 to 15 nucleotides. Primer synthesis is initiated at multiple but nonrandom sites. Like the DNA primase of Escherichia coli and the comparable activity in intact nuclei of polyoma-infected mouse cells, the DNA primase of D. melanogaster can substitute deoxynucleotides for ribonucleotides during primer synthesis.

Origin of replication of Escherichia coli plasmid RSF 1030.

Abstract: The nucleotide sequence of a region of plasmid RSF 1030 that includes the origin of DNA replication was determined using the DNA of a small derivative, pST19. The nucleotide sequence of the pST 19 origin region is very similar to that of the ColE1 origin except for a 25 base pair (bp) deletion about 350 bp upstream of the origin and a considerable difference in the region between 400 and 600 bp upstream of the origin. Replication of pST19 starts at one of three consecutive nucleotides (dA, dA or dC) located at a unique position in the region where the nucleotide sequence is identical to that of the ColE1 origin. There are two major sites of initiation of transcription in the region. Transcription from one of the sites yields the primer precursor that can be cleaved by RNase H to form the primer of about 530 nucleotides long. Transcription from the other site proceeds on the opposite strand and terminates close to the primer initiation site to yield species I RNA (or RNA I) about 105 nucleotides long. The presumed RNA polymerase binding sites in the promoters of these transcripts differ from those of the corresponding ColE1 transcripts. Incompatibility specified by pST19 is different from that specified by ColE1. Hypothetical peptides encoded by the origin region of these plasmids are unlikely to be involved in the determination of incompatibility. It has been shown that RNA I is an incompatibility-group specific inhibitor of primer formation. Despite a significant difference in nucleotide sequence, the primer RNA and RNA I of pST19 can be folded into structures analogous to those of the ColE1 transcripts.

Transcription in bacteria at different DNA concentrations.

Abstract: The effect of changing the DNA concentration on RNA synthesis, protein synthesis, and cell growth rate was studied in Escherichia coli B/r. The DNA concentration was varied by changing the replication velocity or by changing replication initiation in a thymine-requiring strain with a mutation in replication control. The results demonstrate that changes in DNA concentration (per mass) have no effect on the cell growth rate and the rates of synthesis (per mass) of stable RNA (rRNA, tRNA), bulk mRNA, or protein or on the concentration of RNA polymerase (total RNA polymerase per mass). Thus, transcription in E. coli is not limited by the concentration of DNA, but rather by the concentration of functional RNA polymerase in the cytoplasm. Changing the DNA concentration does, however, affect fully induced lac gene activity, here used as a model for constitutive gene expression. The magnitude of the effect of DNA concentration on lac gene activity depends on the distribution of replication forks over the chromosome, which is a function of the replication velocity. Analysis of these date reinforces the conclusion that transcription is limited by the concentration of functional RNA polymerase in the cytoplasm.

Specific cleavage of the p15A primer precursor by ribonuclease H at the origin of DNA replication.

Abstract: We report studies on the mechanism of initiation of DNA replication by p15A, a small plasmid whose origin of replication is known to function much as does that of ColE1. Previous work has shown that an RNA primer for DNA synthesis is generated by the action of RNase H (EC 3.1.26.4) on a precursor transcript. The precursor initiates well upstream of the origin of replication and somehow forms a hybrid with its template during transcription. Here we show that when RNase H cleaves the hybrid at 0 degrees C, an additional cleavage product besides the primer can be identified. Using two-dimensional RNA sequencing techniques, we have established the sequence of this product to within a few nucleotides of each end. The position of the 5' end indicates that the nuclease introduces a nick or very small gap in the precursor at the origin. This suggests that some sequence or structure directs the enzyme to the origin. The position of its 3' end indicates that the precursor terminates at or near a series of six dAs in the template strand about 190 nucleotides from the origin of replication. The data indicate that hybrid formation may be necessary for termination of the precursor at this downstream site.

Purification of ribonuclease H as a factor required for initiation of in vitro Co1E1 DNA replication.

Abstract: Escherichia coli ribonuclease H was purified to near-homogeneity and identified as the only additional factor required for initiation of in vitro Co1E1 DNA replication from the unique origin by RNA polymerase and DNA polymerase I. Both ribonuclease H activity and stimulating activity for Co1E1 DNA synthesis comigrate with the single protein band in gel electrophoresis. These two activities coincide throughout the process of purification. Some DNA synthesis takes place on covalently closed-circular DNA molecules other than Co1E1 DNA with the three purified enzymes. This DNA synthesis is suppressed by an Escherichia coli single-strand DNA binding protein and/or a high concentration of ribonuclease H. Negative superhelicity of template DNA is required for efficient primer formation. No evidence that supports involvement of ribonuclease III in initiation of Co1E1 DNA replication or its regulation was found.

The mutagenic effect of deoxynucleotide susbtrate imbalances during DNA synthesis with mammalian DNA polymerases

Abstract: The frequency of reversion of ΦX174 amber mutants to wild-type, resulting from in vitro DNA synthesis catalyzed by eucaryotic DNA polymerase-α or -β, varies over a 10- to 1000-fold range. This variation is dependent on the relative ratio of deoxyribonucleotide substrates present during in vitro DNA synthesis. The effect is observed at two different loci in the genome and with several different DNA polymerases. In addition, the effect is observed using an unfractioned cellular extract. These results provide support for the hypothesis that altered nucleotide pools cause mutations in mammalian cells by decreasing the fidelity of DNA synthesis.

Mouse DNA polymerase accompanied by a novel RNA polymerase activity: purification and partial characterization.

Abstract: A mouse DNA polymerase accompanied by a novel RNA polymerase activity and its specific protein factor (stimulating factor) were purified from Ehrlich ascites tumor cells and partially characterized. The DNA polymerase was thought to be a subspecies of DNA polymerase alpha, and to be accompanied by or copurified with RNA polymerase activity capable of synthesizing RNA, which was probably utilized as a primer for subsequent DNA polymerization on a template of poly(dT) or poly(dC). This coupled reaction by RNA and DNA polymerase activities required the stimulating factor in addition to ribo- and deoxyribonucleotide substrates, although the degree of requirement depended on the kind of template and ribonucleotide substrate: the activity to incorporate dATP with poly(dT) plus ATP depended greatly on the stimulating factor, while the activity to incorporate dGTP with poly(dC) did not when GTP was added at high concentrations. GDP could be substituted for GTP, but the activity with poly(dC) plus GDP depended largely on the stimulating factor. Involvement of known RNA polymerases in the activity with poly(dT) was excluded, because addition of purified mouse RNA polymerases I and II had no effect on the incorporation of dATP, and alpha-amanitin (100 micrograms/ml) did not inhibit the incorporations of dATP and ATP. Analysis of the inhibition by the nucleotide analog 2',3'-dideoxynucleoside 5'-triphosphate (ddNTP) further supported the involvement of new RNA polymerase; ddNTPs inhibited the activities with poly(dT) and poly(dC) significantly more than RNA polymerases I and II or DNA polymerase alpha activity with poly(dT) . oligo(rA) and poly(dC) . oligo(dG) as template. Lineweaver-Burk analysis of the inhibitions showed that ddATP inhibited competitively with respect to ATP, and ddGTP inhibited competitively with respect to GDP but noncompetitively with respect to GTP.

RNA polymerase: linear competitive inhibition by bis-(3′→5′)-cyclic dinnucleotides,NpNp

Abstract: We have investigated the possible role of the bis-(3' to 5')-cyclic dinucleotides UpUp and ApUp as kinetic inhibitors of the DNA dependent RNA polymerase enzyme of E. coli, using T7 delta D111 deletion mutant DNA and several synthetic DNA polymers as templates. We have established that UpUp is a linear competitive inhibitor of the initiation phase of the polymerization (Ki = 28 microM using T7 delta D111 DNA as a template), but that it has no effect when added during the elongation phase. The compound ApUp is an inhibitor of the reaction only when poly(dA-T).poly(dA-T) is used as a template, and UpUp is an inhibitor of the reaction when poly(dA).poly(dT) was employed as the DNA template.

Adenoviral protein-primed initiation of DNA chains in vitro

Abstract: The initiation of DNA chains by the 80-kilodalton form of the adenovirus terminal protein has been studied. This protein, which can be covalently linked to dCMP, is isolated complexed to a 140-kilodalton protein possessing DNA polymerase activity. In the presence of adenovirus DNA-protein, the formation of the 80-kilodalton protein-dCMP complex requires the addition of ATP and nuclear extract from uninfected cells in addition to Mg2+ and dCTP. When single-stranded DNA is used in place of the adenovirus DNA-protein, the formation of the 80-kilodalton protein-dCMP complex occurs in the absence of ATP and nuclear extract. In the presence of the four dNTPs, the complex yields DNA chains of various sizes between 100 and 300 nucleotides. The products formed with bacteriophage phi X174 single-stranded circular DNA as the template are site specific, predominantly derived from the sequences between nucleotides 2363 and 2977 and between nucleotides 3760 and 4206. These small dNA chains are blocked at their 5' ends with the 80-kilodalton protein but possess free 3'-OH ends that are susceptible to degradation by exonuclease III and can be elongated to replicative form II products with DNA polymerase I of Escherichia coli or eukaryotic DNA polymerase beta preparations. A protein priming model explaining the different requirements for initiation with adenovirus DNA-protein and with phi X174 DNA is presented.

Regulation of expression of the Escherichia coli dnaG gene and amplification of the dnaG primase.

Abstract: We have isolated lambda transducing phages carrying the Escherichia coli primase gene (dnaG) and mapped restriction sites in the cloned bacterial DNA segments. Several different DNA fragments containing the dnaG gene were inserted into multicopy plasmids. An analysis of the primase levels in cells harboring such plasmids indicates that sequences far upstream from the dnaG gene are required for optimal primase expression. Using this knowledge, we constructed a plasmid with a thermoinducible copy-number, pRLM61, which was employed to amplify intracellular primase levels approximately 100-fold. The dnaG gene is transcribed clockwise with respect to the E. coli genetic map, and a HindIII site located 180 base pairs upstream from the dnaG gene separates the gene from its primary promoter. An apparent transcription termination signal is positioned 30-70 base pairs in front of the primase gene. Transcription proceeds past this strong terminator only when RNA polymerase has first transcribed the bacterial DNA segment proximal to the HindIII site. We suggest that primase expression in E. coli is positively regulated by a mechanism of transcription antitermination mediated by a bacterial factor. We propose, furthermore, that the neighboring structural genes for primase and for the sigma subunit of RNA polymerase are coordinately regulated as part of an operon. This arrangement may enable the bacterial cell to readily control the level of initiation of DNA and RNA synthesis and thus to respond quickly and efficiently to changing conditions.

Laser crosslinking of E.coli RNA polymerase and T7 DNA

Abstract: The first photochemical crosslinking of a protein to a nucleic acid using laser excitation is reported. A single, 120 mJ, 20 ns pulse at 248 nm crosslinks about 10% of bound E. coli RNA polymerase to T7 DNA under the conditions studied. The crosslinking yield depends on mercaptoethanol concentration, and is a linear function of laser intensity. The protein subunits crosslinked to DNA are beta, beta' and sigma.

DNA primase of plasmid ColIb is involved in conjugal DnA synthesis in donor and recipient bacteria.

Abstract: The sog gene of the IncI alpha group plasmid ColIb is known to encode a DNA primase that can substitute for defective host primase in dnaG mutants of Escherichia coli during discontinuous DNA replication. The biological significance of this enzyme was investigated by using sog mutants, constructed from a derivative of ColIb by in vivo recombination of previously defined mutations in a cloned sog gene. The resultant Sog- plasmids failed to specify detectable primase activity and were unable to suppress a dnaG lesion. These mutants were maintained stably in E. coli, implying that the enzyme is not involved in vegetative replication of ColIb. However, the Sog- plasmids were partially transfer deficient in E. coli and Salmonella typhimurium matings, consistent with the hypothesis that the normal physiological role of this enzyme is in conjugation. This was confirmed by measurements of conjugal DNA synthesis. Studies of recipient cells have indicated that plasmid primase is required to initiate efficient synthesis of DNA complementary to the transferred strand, with the protein being supplied by the donor parent and probably transmitted between the mating cells. Primase specified by the dnaG gene of the recipient can substitute partially for the mutant enzyme, thus providing an explanation for the partial transfer proficiency of the mutant plasmids. Conjugal DNA synthesis in dnaB donor cells was deficient in the absence of plasmid primase, implying that the enzyme also initiates synthesis of DNA to replace the transferred material.

De novo DNA synthesis by a novel mouse DNA polymerase associated with primase activity

Abstract: Several studies have shown that short nascent DNAs (Okazaki fragments) of mammalian cells1–3 and papovaviruses4,5 possess an 8–11-nucleotide RNA sequence covalently linked to their 5′ end, suggesting that this RNA sequence acts in priming in DNA synthesis. Although many studies have indicated that DNA polymerase α probably participates in the synthesis of Okazaki fragments6–10, to date, the reconstitution of de novo DNA synthesis by coupled reaction of DNA polymerase and classical RNA polymerases of mammalian cells has been unsuccessful. Here we report that a novel mouse DNA polymerase associated with primase activity11,12 synthesized DNA of ∼600 nucleotides after synthesis of initiator RNA (iRNA) of 8–10 nucleotides in the presence of a specific stimulating factor. The similarity of this DNA synthesis to that in vivo suggests the involvement of this novel DNA polymerase in the reaction required to initiate synthesis of Okazaki fragments in chromosomal DNA replication.

Site-specific mutagenesis by error-directed DNA synthesis

Abstract: An important experimental strategy for defining functional regions of a DNA sequence involves deleting or mutating particular sequences in vitro and observing the effects of the changes in a functional assay. We have approached the problem of making specific changes at defined sites in a nucleotide sequence by attempting to make use of the mistakes made by DNA polymerase enzymes while copying a sequence. Our approach is to initiate DNA synthesis from an isolated restriction fragment, and to elongate the fragment to a designated position by sequentially adding complementary nucleotides, then to incorporate the non-complementary nucleotide using an error-prone DNA polymerase followed by continuation of faithful synthesis. Here we demonstrate by DNA sequence analysis that both transitions and transversions can be produced at a designated position on the DNA template using this method.

A mammalian DNA polymerase alpha holoenzyme functioning on defined in vivo-like templates.

Abstract: In analogy to the Escherichia coli replicative DNA polymerase III we define two forms of DNA polymerase alpha: the core enzyme and the holoenzyme. The core enzyme is not able to elongate efficiently primed single-stranded DNA templates, in contrast to the holoenzyme which functions well on in vivo-like template. Using these criteria, we have identified and partially purified DNA polymerase alpha holoenzyme from calf thymus and have compared it to the corresponding homogeneous DNA polymerase alpha (defined as the core enzyme) from the same tissue. The holoenzyme is able to use single-stranded parvoviral DNA and M13 DNA with a single RNA primer as template. The core enzyme, on the other hand, although active on DNAs treated with deoxyribonuclease to create random gaps, is unable to act on these two long, single-stranded DNAs. E. coli DNA polymerase III holoenzyme also copies the two in vivo-like templates, while the core enzyme is virtually inactive. The homologous single-stranded DNA-binding proteins from calf thymus and from E. coli stimulate the respective holoenzymes and inhibit the core enzymes. These results suggest a cooperation between a DNA polymerase holoenzyme and its homologous single-stranded DNA-binding protein. The prokaryotic and the mammalian holoenzyme behave similarly in several chromatographic systems.

Circular single stranded phage M13-DNA as a template for DNA synthesis in protein extracts from Xenopus laevis eggs: evidence for a eukaryotic DNA priming activity

Abstract: Unfractionated protein extracts from activated Xenopus laevis eggs contain all functions required for the chain elongation reactions in replicative DNA synthesis (A.Richter, B. Otto and R.Knippers, 1981, Nucl.Ac.Res. 9, 3793-3807). In order to further explore the DNA synthesizing capacity of this in vitro system and to obtain information on the DNA priming activity in these extracts single stranded phage M13-DNA was used as template for in vitro DNA synthesis. The main results of this investigation are: (i) single stranded circular template DNA is converted to a double stranded DNA form in an alpha-amanitin-insensitive reaction which is absolutely dependent on ribonucleoside triphosphates; (ii) the in vitro synthesized complementary strands are DNA fragments of 1000-2000 nucleotides lengths; (iii) the DNA primase activity copurifies through several column steps and sucrose gradient centrifugation with a DNA polymerase alpha. These activities may therefore be closely associated in a quarternary enzyme complex.

Overlapping genes at the DNA primase locus of the large plasmid CoII

Abstract: The sog gene of the large plasmid ColIdrd-1 has previously been shown to encode a DNA primase and a smaller antigenically related polypeptide. Genesis of these two products has been examined using Sog+ recombinant plasmids. Effects of amber mutations, isolated after in vitro mutagenesis, and deletions into or within sog suggest that the smaller polypeptide is a separate translation product which is encoded by DNA specifying the C-terminal region of the larger protein. Under control of the lac promotor, synthesis of both polypeptides is reduced when transcription is repressed. These findings imply that transcription of sog yields a single transcript which is translated from two initiation sites.

An oligoribonucleotide polymerase from SV40-infected cells with properties of a primase

Abstract: A transient decaribonucleotide (iRNA) is covalently linked to nascent eukaryotic DNA chains at their 5' end. Searching for the putative iRNA polymerase (primase), we detected in extracts from SV40-infected cells a DNA-dependent incorporation of UMP residues from UTP into free and DNA linked deca- or similarly sized ribonucleotides. Denatured salmon sperm DNA served as the standard template in this reaction. SV40 FIII DNA was also an effective template, SV40 FII DNA was ineffective while FI yielded mainly free decaribonucleotides. The incorporation depended on the other rNTPs and was resistant to high concentrations of alpha-amanitin and rifamycin AF/013, drugs inhibitory to RNA polymerases I, II and III. The results implicate the decaribonucleotide polymerase in the priming of nascent DNA chains and suggest that the unique size of iRNA is encoded within its primase.

DNA Synthesis at a Fork in the Presence of DNA Helicases

Abstract: In a mixture of Escherichia coli DNA polymerase III holoenzyme, single-strand-binding protein, artificially forked λ bacteriophage DNA with primer annealed to the leading side of the fork, dNTPs and ATP, DNA synthesis is enhanced by helicaseII, less so by helicases I, III or rep protein of E. coli or T4 phage helicase. The effect of helicase II depends on ATP, it is enhanced by helicase III, and it is not observed using DNA poly- merase I or T4 DNA polymerase. In the absence of dNTPs helicase II is less active than helicase I or T4 helicase in unwinding the forked DNA. We believe that helicase II both shifts the forks and stimulates DNA polymerase III. The results support the conclusion derived from previous studies that helicase II is part of the DNA-synthesizing system of E. coli.