Discriminatory function of ribonuclease H in the selective initiation of plasmid DNA replication.

The initiation stage of ColE1-type plasmid replication was reconstituted with purified protein fractions from Escherichia coli. The reconstituted system included DNA polymerase I, DNA ligase, RNA polymerase, DNA gyrase, and a discriminating activity copurifying with RNAase H (but free of RNAase III). Initiation of DNA synthesis in the absence of RNAase H did not occur at the normal replication origin and was non-selective with respect to the plasmid template. In the presence of RNAase H the system was selective for ColE1-type plasmids and could not accept the DNA of non-amplifiable plasmids. Electron microscopic analysis of the reaction product formed under discriminatory conditions indicated that origin usage and directionally of ColE1, RSF1030, and CloDF13 replication were consistent with the normal replication pattern of these plasmids. It is proposed that the initiation of ColE1-type replication depends on the formation of an extensive secondary structure in the origin primer RNA that prevents its degradation by RNAase H.     

Purification and characterization of DNA polymerase II from the yeast Saccharomyces cerevisiae. Identification of the catalytic core and a possible holoenzyme form of the enzyme

We have purified yeast DNA polymerase II to near homogeneity as a 145-kDa polypeptide. During the course of this purification we have detected and purified a novel form of DNA polymerase II that we designate as DNA polymerase II. The most highly purified preparations of DNA polymerase II are composed of polypeptides with molecular masses of 200, 80, 34, 30, and 29 kDa. Immunological analysis and peptide mapping of DNA polymerase II and the 200-kDa subunit of DNA polymerase II indicate that the 145-kDa DNA polymerase II polypeptide is derived from the 200-kDa polypeptide of DNA polymerase II. Activity gel analysis shows that the 145- and the 200-kDa polypeptides have catalytic function. The polypeptides present in the DNA polymerase II preparation copurify with the polymerase activity with a constant relative stoichiometry during chromatography over five columns and co-sediment with the activity during glycerol gradient centrifugation, suggesting that this complex may be a holoenzyme form of DNA polymerase II. Both forms of DNA polymerase II possess a 3'-5' exonuclease activity that remains tightly associated with the polymerase activity during purification. DNA polymerase II is similar to the proliferating cell nuclear antigen (PCNA)-independent form of mammalian DNA polymerase delta in its resistance to butylpheny-dGTP, template specificity, stimulation of polymerase and exonuclease activity by KCl, and high processivity. Although calf thymus PCNA does not stimulate the activity of DNA polymerase II on poly(dA):oligo(dT), possibly due to the limited length of the template, the high processivity of yeast DNA polymerase II on this template can be further increased by the addition of PCNA, suggesting that conditions may exist for interactions between PCNA and yeast DNA polymerase II.     

A rapid method for the isolation of ribonuclease from yeast (Saccharomyces carlsbergensis).

A ribonuclease (RNAase; EC 3.1.14.1) from brewer's yeast was purified 90-fold. Crude RNAase was initially separated from other proteins by precipitation at pH 4.0 after incubation of the mechanically disrupted yeast cells at pH 6.0 and 52 degrees C for 30 min. The RNAase was purified from the supernatant by ultrafiltration with a PM-30 membrane and adsorption chromatography on hydroxyapatite. RNAase preparation was free of phosphatase, deoxyribonuclease and phosphodiesterase activities. It showed maximum activity at pH 6.0 and a temperature optimum of 52 degrees C with yeast RNA as substrate. This RNAase hydrolysed yeast RNA to nucleoside 3'-phosphates and showed no evidence of base specificity.     

Characteristics of Deoxyribonucleic Acid Polymerase Isolated from Spores of Rhizopus stolonifer

Deoxyribonucleic acid (DNA)-dependent DNA polymerase was purified several hundredfold from germinated and ungerminated spores of the fungus Rhizopus stolonifer. The partially purified enzymes from both spore stages exhibited identical characteristics; incorporation of [(3)H]deoxythymidine monophosphate into DNA required Mg(2+), DNA, a reducing agent, and the simultaneous presence of deoxyguanosine triphosphate, deoxycytidine triphosphate, and deoxyadenosine triphosphate. Heat-denatured and activated DNAs were better templates than were native DNAs. The buoyant density of the radioactive product of the reaction was similar to that of the template DNA. The enzyme is probably composed of a single polypeptide chain with an S value of 5.12 and an estimated molecular weight of 70,000 to 75,000. During the early stages of purification, the enzyme fraction from ungerminated spores required exogenous DNA for maximum activity, whereas the corresponding enzyme fraction from germinated spores did not require added DNA. Apparently DNA polymerase from germinated spores was more tightly bound to endogenous DNA than was the enzyme from ungerminated spores.     

Regulation of poly(ADP-ribose) polymerase. Histone-specific adaptations of reaction products

The post-translational poly ADP-ribosylation of proteins by the nuclear enzyme poly(ADP-ribose) polymerase (EC 2.4.2.30) involves a complex pattern of ADP-ribose polymers. We have determined how this enzyme produces the various polymer size patterns responsible for altered protein function. The results show that histone H1 and core histones are potent regulators of both the numbers and sizes of ADP-ribose polymers. Each histone induced the polymerase to synthesize a specific polymer size pattern. Various other basic and/or DNA binding proteins as well as other known stimulators of poly(ADP-ribose) polymerase (spermine, MgCl2, nicked DNA) were ineffective as polymer size modulators. Testing specific proteolytic fragments of histone H1, the polymer number and polymer size modulating activity could be mapped to specific polypeptide domains. The results suggest that histones specifically regulate the polymer termination reaction of poly(ADP-ribose) polymerase.     

SMC proteins constitute two subunits of the mammalian recombination complex RC-1.

Recombination protein complex RC-1, purified from calf thymus nuclear extracts, catalyzes cell-free DNA strand transfer and repair of gaps and deletions through DNA recombination. DNA polymerase E, DNA ligase III and a DNA structure-specific endonuclease co-purify with the five polypeptide complex. Here we describe the identification of two hitherto unknown subunits of RC-1. N-terminal amino acid sequences of the 160 and 130 kDa polypeptides display up to 100% identity to proteins of the structural maintenance of chromosomes (SMC) subfamilies 1 and 2. SMC proteins are involved in mitotic chromosome segregation and condensation, as well as in certain DNA repair pathways in fission (rad18 gene) and budding (RHC18 gene) yeast. The assignment was substantiated by immuno-cross-reactivity of the RC-1 subunits with polyclonal antibodies specific for Xenopus laevis SMC proteins. These antibodies, and polyclonal antibodies directed against the bovine 160 and 130 kDa polypeptides, named BSMC1 and BSMC2 (bovine SMC), inhibited RC-1-mediated DNA transfer, indicating that the SMC proteins are necessary components of the reaction. Two independent assays revealed DNA reannealing activity of RC-1, which resides in its BSMC subunits, thereby demonstrating a novel function of these proteins. To our knowledge, this is the first evidence for the association of mammalian SMC proteins with a multiprotein complex harboring, among others, DNA recombination, DNA ligase and DNA polymerase activities.     

Induction of glutathione S-transferases A, B and C in rat liver cytosol by trans-stilbene oxide

RNAase H, which catalyzes the hydrolysis of the RNA moiety of an RNA-DNA hybrid, was measured in the mammary gland of virgin, pregnant, lactating, and weaning Fischer rats and in the R3230AC mammary tumor grown in the same animals. In the normal mammary gland when DNA levels were low, as in the virgin state or during involution, RNAase H activity was also low. During pregnancy and lactogenesis when DNA levels increased, RNAase H activity, either on the basis of mammary gland weight or DNA content, also increased. During lactation when cellular proliferation ceases but rates of RNA and protein synthesis continue to reach peak values, RNAase H activity decreased. Compared to the corresponding enzyme from host glands, RNAase H from the R3230AC mammary tumor grown in pregnant and lactating hosts changes similarly, but to a lesser extent. The RNAase H activity which, ona tissue weight basis, was higher than in normal tissue also increased during pregnancy and directly after parturition, but decreased during lactation. During pregnancy these changes were accompanied by an increase in tumor DNA values. During lactation the tumor DNA values returned to the level seen in virgin hosts. These results are consistent with a role for RNAase H in DNA replication in rat mammary gland and in R3230Ac mammary tumor.     

Immunochemical studies of DNA polymerase delta: relationships with DNA polymerase alpha

A panel of murine hybridoma cell lines which produce antibodies against polypeptides present in human placental DNA polymerase delta preparations was developed. Eight of these antibodies were characterized by virtue of their ability to inhibit DNA polymerase delta activity and immunoblot the 170-kDa catalytic polypeptide. Six of these eight antibodies inhibit DNA polymerase delta but not DNA polymerase alpha, showing that the two proteins are distinct. However, the other two monoclonal antibodies inhibited both DNA polymerase delta and alpha activities, providing the first evidence that these two proteins have a structural relationship. In addition to antibodies against the catalytic polypeptide we also identified 11 antibodies which recognize 120-, 100-, 88-, 75-, 62-, 36-, and 22-kDa polypeptides in DNA polymerase delta preparations, suggesting that these proteins might be part of a replication complex. The antibody to the 36-kDa polypeptide was shown to be directed against proliferating cell nuclear antigen/cyclin. These antibodies should prove useful for studies aimed at distinguishing between DNA polymerases alpha and delta and for the investigation of the functional roles of DNA polymerase delta polypeptides.     

Nucleotide sequence from the genetic left end of bacteriophage T7 DNA to the beginning of gene 4

The nucleotide sequence running from the genetic left end of bacteriophage T7 DNA to within the coding sequence of gene 4 is given, except for the internal coding sequence for the gene 1 protein, which has been determined elsewhere. The sequence presented contains nucleotides 1 to 3342 and 5654 to 12,100 of the approximately 40,000 base-pairs of T7 DNA. This sequence includes: the three strong early promoters and the termination site for Escherichia coli RNA polymerase: eight promoter sites for T7 RNA polymerase; six RNAase III cleavage sites; the primary origin of replication of T7 DNA; the complete coding sequences for 13 previously known T7 proteins, including the anti-restriction protein, protein kinase, DNA ligase, the gene 2 inhibitor of E. coli RNA polymerase, single-strand DNA binding protein, the gene 3 endonuclease, and lysozyme (which is actually an N-acetylmuramyl-l-alanine amidase); the complete coding sequences for eight potential new T7-coded proteins; and two apparently independent initiation sites that produce overlapping polypeptide chains of gene 4 primase. More than 86% of the first 12,100 base-pairs of T7 DNA appear to be devoted to specifying amino acid sequences for T7 proteins, and the arrangement of coding sequences and other genetic elements is very efficient. There is little overlap between coding sequences for different proteins, but junctions between adjacent coding sequences are typically close, the termination codon for one protein often overlapping the initiation codon for the next. For almost half of the potential T7 proteins, the sequence in the messenger RNA that can interact with 16 S ribosomal RNA in initiation of protein synthesis is part of the coding sequence for the preceding protein. The longest non-coding region, about 900 base-pairs, is at the left end of the DNA. The right half of this region contains the strong early promoters for E. coli RNA polymerase and the first RNAase III cleavage site. The left end contains the terminal repetition (nucleotides 1 to 160), followed by a striking array of repeated sequences (nucleotides 175 to 340) that might have some role in packaging the DNA into phage particles, and an A · T-rich region (nucleotides 356 to 492) that contains a promoter for T7 RNA polymerase, and which might function as a replication origin.     

Characterization of a 70S polyuridylic acid polymerase isolated from foot-and-mouth disease virus-infected cells

A polyuridylic acid polymerase complex isolated from foot-and-mouth disease virus-infected cells sedimented at 70S in a sucrose gradient and appeared in the exclusion volume of an agarose column whose molecular weight cutoff was 5 x 10(6). Phenol extraction of the complex yielded a heterogeneous band of virus-specific RNA and an apparently host cell-derived 4.5 to 5S RNA, both of which are essentially single stranded. Neither RNA served as a template in the cell-free enzyme reaction. Polyacrylamide gel analysis revealed five polypeptides with molecular weights of 50,000, 56,000, 60,000, 70,000, and 74,000 and with molar ratios of 1:2:2:1:1, respectively. Autoradiography showed P56 to be the only major virus-induced polypeptide; the other proteins are apparently of host cell origin. Electron microscopic examination suggested a cartwheel shape for the polymerase complex which was seen to dissociate as polyadenylic acid was added. Antibody previously shown to inhibit enzyme activity aggregated the 70S units.     

DNA polymerase I and DNA primase complex in yeast

Chromatographic analysis of poly(dT) replication activity in fresh yeast extracts showed that the activities required co-fractionate with the yeast DNA polymerase I. Since poly(dT) replication requires both a primase and a DNA polymerase, the results of the fractionation studies suggest that these two enzymes might exist as a complex in the yeast extract. Sucrose gradient analysis of concentrated purified yeast DNA polymerase I preparations demonstrates that the yeast DNA polymerase I does sediment as a complex with DNA primase activity. Two DNA polymerase I peptides estimated at 78,000 and 140,000 Da were found in the complex that were absent from the primase-free DNA polymerase fraction. Rabbit anti-yeast DNA polymerase I antibody inhibits DNA polymerase I but not DNA primase although rabbit antibodies are shown to remove DNA primase activity from solution by binding to the complex. Mouse monoclonal antibody to yeast DNA polymerase I binds to free yeast DNA polymerase I as well as the complex, but not to the free DNA primase activity. These results suggest that these two activities exist as a complex and reside on the different polypeptides. Replication of poly(dT) and single-stranded circular phage DNA by yeast DNA polymerase I and primase requires ATP and dNTPs. The size of the primer produced is 8 to 9 nucleotides in the presence of dNTPs and somewhat larger in the absence of dNTPs. Aphidicolin, an inhibitor of yeast DNA polymerase I, is not inhibitory to the yeast DNA primase activity. The primase activity is inhibited by adenosine 5'-(3-thio)tri-phosphate but not by alpha-amanitin. The association of yeast DNA polymerase I and yeast DNA primase can be demonstrated directly by isolation of the complex on a column containing yeast DNA polymerase I mouse monoclonal antibody covalently linked to Protein A-Sepharose. Both DNA polymerase I and DNA primase activities are retained by the column and can be eluted with 3.5 M MgCl2. Part of the primase activity can be dissociated from DNA polymerase on the column with 1 M MgCl2 and this free primase activity can be detected as poly(dT) replication activity in the presence of Escherichia coli polymerase I.     

Protein modifications by activated carcinogens. II. The acetylation of ribonuclease by N-acetoxy-3-fluorenylacetamide.

The reaction of N-[3H]acetoxy-3-fluorenylacetamide (N-[3H]acetoxy-3-FAA), a potent carcinogen for the rat, with RNAase yielded three modified proteins separable from RNAase by ion exchange chromatography on Bio-Gel CM-30 with a gradient of increasing sodium ion concentration. Only minor amounts of RNAase were recovered. The modified proteins were labeled with 3H to a varying degree, and their order of elution was inversely related to the extent of labeling. The modification of the proteins was the result of the transfer of the acetyl group from N-[3H]acetoxy-3-FAA to RNAase. The evidence for this conclusion was (a) the release of 84-86% of the radioactivity as [3H] acetic acid from the two major proteins upon acid hydrolysis and (b) the isolation of eplision-N-[3H] acetyl-L-lysine from enzymatic hydrolysates of these proteins. A comparison of the present data with those previously reported for the acetylaton of RNAase by the isomeric carcinogen, N-acetoxy-2-FAA, showed that N-acetoxy-3-FAA is the more potent acetyl-lating agent. The present study in conjunction with the previous results, suggests that structural alteration of cellular nucleopholes by acylation may be a biochemical mechanism underlying the biological activity of N-acetoxy-3-FAA and related activated carcinogens.     

Purification and characterization of the 180- and 86-kilodalton subunits of the Saccharomyces cerevisiae DNA primase-DNA polymerase protein complex. The 180-kilodalton subunit has both DNA polymerase and 3'----5'-exonuclease activities.

The yeast Saccharomyces cerevisiae catalytic DNA polymerase I 180-kDa subunit and the tightly associated 86-kDa polypeptide have been purified using immunoaffinity chromatography, permitting further characterization of the DNA polymerase activity of the DNA primase-DNA polymerase protein complex. The subunits were purified to apparent homogeneity from separate overproducing yeast strains using monoclonal antibodies specifically recognizing each subunit. When the individual subunits were recombined in vitro a p86p180 physical complex formed spontaneously, as judged by immunoprecipitation of 180-kDa polypeptide and DNA polymerase activity with the anti-86-kDa monoclonal antibody. The 86-kDa subunit stabilized the DNA polymerase activity of the 180-kDa catalytic subunit at 30 degrees C, the physiological temperature. The apparent DNA polymerase processivity of 50-60 nucleotides on poly(dA).oligo(dT)12 or poly(dT).oligo(A)8-12 template-primer was not affected by the presence of the 86-kDa subunit but was reduced by increased Mg2+ concentration. The Km of the catalytic 180-kDa subunit for dATP or DNA primer terminus was unaffected by the presence of the 86-kDa subunit. The isolated 180-kDa polypeptide was sufficient to catalyze all the DNA synthesis that had been observed previously in the DNA primase-DNA polymerase protein complex. The 180-kDa subunit possessed a 3'----5'-exonuclease activity that catalyzed degradation of polynucleotides, but degradation of oligonucleotide substrates of chain lengths up to 50 was not detected. This exonuclease activity was unaffected by the presence of the 86-kDa subunit. Despite the striking physical similarity of the DNA primase-DNA polymerase protein complex in all eukaryotes examined, the data presented here indicate differences in the enzymatic properties detected in preparations of the DNA polymerase subunits isolated from S. cerevisiae as compared with the properties of preparations from Drosophila cells. In particular, the 3'----5'-exonuclease activity associated with the yeast catalytic DNA polymerase subunit was not masked by the 86-kDa subunit.