Further purification and characterization of a multienzyme complex for DNA synthesis in human cells

The 21 S complex of enzymes for DNA synthesis in the combined low salt nuclear extract-post microsomal supernatant from HeLa cells [Malkas et al. (1990) Biochemistry 29:6362-6374] was purified by poly (ethylene glycol) precipitation, Q-Sepharose chromatography, Mono Q Fast Protein Liquid Chromatography (FPLC), and velocity gradient centrifugation. The procedure gives purified enzyme complex at a yield of 45%. The 21 S enzyme complex remains intact and functional in the replication of simian virus 40 DNA throughout the purification. Sedimentation analysis showed that the 21 S enzyme complex exists in the crude HeLa cell extract and that simian virus 40 in vitro DNA replication activity in the cell extract resides exclusively with the 21 S complex. The results of enzyme and immunological analysis indicate that DNA polymerase alpha-primase, a 3',5' exonuclease, DNA ligase I, RNase H, and topoisomerase I are associated with the purified enzyme complex. Denaturing polyacrylamide gel electrophoresis of the purified enzyme complex showed the presence of about 30 polypeptides in the size range of 300 to 15 kDa. Immunofluorescent imaging analysis, with antibodies to DNA polymerase alpha,beta and DNA ligase I, showed that polymerase alpha and DNA ligase I are localized to granular-like foci within the nucleus during S-phase. In contrast, DNA polymerase beta, which is not associated with the 21 S complex, is diffusely distributed throughout the nucleoplasm.     

T4 ribonucleotide reductase. Physical and kinetic linkage to other enzymes of deoxyribonucleotide biosynthesis

This laboratory has described a multienzyme aggregate from T4 phage-infected Escherichia coli which seems to participate in deoxyribonucleotide biosynthesis and efficient delivery of DNA precursors to the replication apparatus. This paper describes improved methodology for isolation of this aggregate, and we present three lines of evidence supporting a role for ribonucleoside diphosphate reductase in functioning of the presumed complex. 1) Ribonucleoside diphosphates are readily incorporated into DNA as deoxyribonucleotides in an in situ DNA-synthesizing system from T4 phage-infected cells. 2)Ribonucleotide reductase is associated with the complex, as shown by co-sedimentation of reductase activity with other activities in the multienzyme aggregate we have described. 3)Ribonucleotide reductase is kinetically coupled to at least four other enzymes involved in a sequential pathway. The aggregated enzymes catalyze the five-step conversion of uridine diphosphate to deoxythymidine triphosphate with but a brief lag before dTTP production reaches its maximal rate. These studies have also confirmed the existence of dCTPase-dUTPase and dCMP deaminase activities in the putative complex.     

Characterization of DNA polymerase associated with nuclear membrane fractions from uninfected and adenovirus 2-infected KB cells

We have isolated a nuclear membrane fraction from KB cells infected with human adenovirus 2 that synthesizes exclusively small viral DNA chains (approx. 9 S) in vitro (Yamashita, T., Arens, M. and Green, M. (1975) J. Biol. Chem. 250, 3273-3279). The DNA polymerase activity present in the adenovirus 2 DNA-nuclear membrane complex was purified through chromatography on phosphocellulose and DEAE-cellulose, glycerol gradient centrifuation and DNA-cellulose chromatography. A single peak of enzymatic activity sedimented in glycerol gradients at about 6.7 S which corresponds to a molecular weight of 125000. The enzyme preparation in the step of glycerol gradient centrifugation utilized activated calf thymus, KB cell and adenovirus 2 DNA as template-primer in the presence of Mg2+; Km values for these DNAs were 5.5, 4.0, and 0.8 mug/ml, respectively. The partially purified enzyme preparation was characterized by several criteria which were compared to the properties of the three major mammalian DNA polymerases, alpha, beta, and psi. On the basis of template-primer preference, effect of salt, inhibition by N-ethylmaleimide and Km for dTTP, the DNA polymerase activity from the membrane complex can be distinguished from the alpha and beta DNA polymerases. The elution profile from DNA cellulose revealed a minor peak (I) and a major peak (II) of DNA polymerase activity utilizing poly(A) -(dT)10 as template-primer in the presence of Mn2+ - Peak II from DNA cellulose, which contained about 90% of the total DNA polymerase activity eluted from the column, was 2-3 times as active with poly(A) - (dT)10 as template-primer in the presence of Mn2+ than with activated calf thymus DNA in the presence of Mg2+. On the other hand, peak I had a low ratio of poly(A) - (dT)10 to activated calf thymus DNA activity. DNA polymerase was also purified from the nuclear membrane fraction of uninfected KB cells by the same procedures as those used in enzyme purification from the adenovirus 2 DNA-nuclear membrane complex. A minor peak and a major peak of DNA polymerase activity utilizing poly(A) - (dT)10 as template primer in the presence of Mn2+ were again observed that eluted from DNA cellulose at the same KCl concentrations as peak I and II from adenovirus 2-infected cells. The enzymes of the nuclear membrane fraction of uninfected KB cells could not be differentiated from the enzymes of the adenovirus 2 DNA-nuclear membrane complex through any of the purification steps nor by their template specificities. These results indicate that the predominant enzyme in the adenovirus 2 DNA-nuclear membrane complex and in the KB cell nuclear membrane complex belongs to the class of DNA polymerase psi.     

Molecular mechanism of regulation of the pyruvate dehydrogenase complex from E. coli

The pyruvate dehydrogenase multienzyme complex from E. coli shows a sigmoidal dependency of the reaction rate on the substrate concentration when product formation is followed in the presence of physiological concentrations of the cofactor thiamin diphosphate. To elucidate the molecular mechanism of this regulation, the influence of the substrate pyruvate on the coenzyme-protein interaction has been investigated using several coenzyme analogues. The observed binding constants of all coenzymatically active analogues are increased in the presence of the substrate pyruvate, whereas those of all coenzymatically inactive analogues are not altered in the presence of pyruvate. This points to an increased binding affinity of a reaction-intermediate-coenzyme complex to the protein. Since cofactor binding and dissociation at physiological concentrations of thiamin diphosphate are slow compared to the catalytic reaction, a slow transition to the active state of the enzyme occurs. After lowering the pyruvate concentration, the opposite effect, a dissociation of the thiamin diphosphate from the enzyme is observed. This slow substrate dependent enhancement of cofactor binding enables efficient regulation of the pyruvate dehydrogenase complex by its substrate pyruvate.     

Species-specific replication of simian virus 40 DNA in vitro requires the p180 subunit of human DNA polymerase alpha-primase

Human cell extracts efficiently support replication of simian virus 40 (SV40) DNA in vitro, while mouse cell extracts do not. Since human DNA polymerase alpha-primase is the major species-specific factor, we set out to determine the subunit(s) of DNA polymerase alpha-primase required for this species specificity. Recombinant human, mouse, and hybrid human-mouse DNA polymerase alpha-primase complexes were expressed with baculovirus vectors and purified. All of the recombinant DNA polymerase alpha-primases showed enzymatic activity and efficiently synthesized the complementary strand on an M13 single-stranded DNA template. The human DNA polymerase alpha-primase (four subunits [HHHH]) and the hybrid DNA polymerase alpha-primase HHMM (two human subunits and two mouse subunits), containing human p180 and p68 and mouse primase, initiated SV40 DNA replication in a purified system. The human and the HHMM complex efficiently replicated SV40 DNA in mouse extracts from which DNA polymerase alpha-primase was deleted, while MMMM and the MMHH complex did not. To determine whether the human p180 or p68 subunit was required for SV40 DNA replication, hybrid complexes containing only one human subunit, p180 or p68, together with three mouse subunits (HMMM and MHMM) or three human subunits and one mouse subunit (MHHH and HMHH) were tested for SV40 DNA replication activity. The hybrid complexes HMMM and HMHH synthesized oligoribonucleotides in the SV40 initiation assay with purified proteins and replicated SV40 DNA in depleted mouse extracts. In contrast, the hybrid complexes containing mouse p180 were inactive in both assays. We conclude that the human p180 subunit determines host-specific replication of SV40 DNA in vitro.     

A nuclear membrane-associated DNA complex in cultured mammalian cells capable of synthesizing DNA in vitro

A DNA-nuclear membrane complex has been isolated by two different methods from the nuclei of cultured mouse fibroblast (3T3) cells. One method, utilizing the detergent sarkosyl (sodium lauroyl sarkosinate), yields a DNA-nuclear membrane complex (the M band), which contains virtually all of the DNA in the nuclei. However, treatment of the M band by sonication, vortexing, or freeze-thaw reduces the amount of DNA in the complex by approximately 50-80%, depending upon the phase of the cell cycle from which the complex was extracted. The remaining DNA is tightly bound to the nuclear membrane and resists further shearing procedures. Over 90% of the choline-labeled phospholipid present in nuclei is also found in these sheared M bands. The percentage of DNA associated with the nuclear membrane varies during the cell cycle and correlates well with the onset, continuation, and cessation of DNA synthesis. Thus, although DNA-membrane complexes can be detected throughout the cell cycle, the percentage of DNA bound to membrane increases during late G1 and S and decreases during G2. In addition, there are distinct qualitative differences in the type of DNA present in the membrane fraction, with a more highly d(A-T) rich DNA being present in confluent (G0) cells than in cells during the S phase. This d(A-T) rich DNA may be related to the mouse satellite DNA identified by others. The M band can be separated into two DNA-nuclear membrane subfractions by centrifugation through a continuous sucrose gradient. The relative proportions of these two subfractions depend upon the percentage of sarkosyl present in the M band prior to centrifugation, with complete removal of sarkosyl resulting in a very large increase in the sedimentation velocity of the complex and in the formation of only one fraction. Evidence that this is a complex of DNA with membrane is given by the finding that DNA is dissociated from the complex with Pronase, deoxycholate, or high levels of sarkosyl. Removal of virtually all of the DNA with DNase from this rapidly sedimenting complex does not dissociate any of the phospholipid which still sediments rapidly as a single band. A second method, which yields a DNA-membrane fraction from nuclei, utilizes sedimentation of lysed nuclei to equilibrium in CsCl density gradients. This low-density CsCl fraction contains only 10-15% of the total DNA, but contains most of the nascent DNA, which may be chased into a membrane-free fraction. The DNA-membrane fraction from CsCl gradients possesses properties in common with the M-band fraction and can be converted into an M band. DNA membrane complexes from sucrose gradients, as well as the crude M-band preparation and a non-membrane-associated DNA fraction from nuclei can synthesize DNA in vitro without the addition of an external DNA template or DNA polymerase. In contrast to the activity in the non-membrane-associated DNA fraction, the membrane-associated polymerase activity is strongly stimulated by adenosine triphosphate and is unaffected by ethidium bromide...     

Isolation of (copper, zinc-) thioneins from pig liver

Serum samples of 403 asymptomatic blood donors carrying hepatitis B surface antigen (HB5Ag) were concentrated threefold and tested for e antigen and antibody to e antigen (anti-e) by immunodiffusion. Hepatitis B antigen (HBAg)-associated deoxyribonucleic acid (DNA) polymerase activity was specifically determined by the difference in incorporation of [methyl-3H]thymidine 5' -triphosphate into DNA by an aliquot of centrifuged serum samples after it had been treated either with normal rabbit serum or with rabbit antibody to HBSAg. All of 58 serum samples containing e antigen revealed HBAg-associated DNA polymerase activity, whereas none of 96 samples containing anti-e did. In the remaining 249 samples in which neither e antigen nor anti-e was found, 62 showed specific DNA polymerase activity, although at lower levels than the samples containing e antigen.     

Isolation of mitochondria and mitochondrial RNA from Crithidia fasciculata

Two methods were used to isolate mitochondria from Crithidia fasciculata. In the first method, cells were weakened by exposure to hypotonic conditions and then disrupted by blending; mitochondria were subsequently isolated using disodium 3,5-diacetoamido-2,4,6-triiodobenzoate gradients. In the second, cells were treated with digitonin before disruption; mitochondria were purified by differential centrifugation. Both preparations were examined with the electron microscope and were also shown to possess several characteristic biochemical properties of mitochondria. Kinetoplast DNA was present in the mitochondria, uncontaminated by nuclear DNA. Analysis by polyacrylamide gel electrophoresis showed two RNA components of molecular weights of 0-47 X 10(6) and 0-22 X 10(6), in addition to cytoplasmic RNA contamination. Four mitochondrial components with sedimentation coefficients of 14-6S, 11-4S, 10-1S and 9-9S were identified on sucrose density gradients. Ethidium bromide abolished the incorporation of [5-3H]uridine into the presumed mitochondrial RNA.     

Fluorescence in situ hybridization mapping of the alpha and beta subunits (HADHA and HADHB) of human mitochondrial fatty acid beta-oxidation multienzyme complex to 2p23 and their evolution

Mitochondrial fatty acid beta-oxidation multienzyme complex/trifunctional protein has an alpha4beta4 structure and catalyzes the second through fourth reactions of the fatty acid beta-oxidation cycle. The alpha and beta subunits (HADHA and HADHB) are members of the enoyl-CoA hydratase/3-hydroxyacyl-CoA dehydrogenase and 3-ketoacyl-CoA thiolase families, respectively. We analyzed the localization of each of these two genes (HADHA and HADHB) by in situ hybridization and found that both can be assigned to human chromosome band 2p23. Since the distance between the two loci is quite short, the two genes seem to exist side by side, as do the two (A and B subunit) genes of the bacterial fatty acid beta-oxidation multienzyme complex. This is an important and interesting finding in that two entirely different genes, encoding two independent proteins forming a multienzyme complex, are adjacent on chromosome band 2p23.     

In situ detection of tandem DNA repeat length

A simple method for scoring short tandem DNA repeats is presented. An oligonucleotide target, containing tandem repeats embedded in a unique sequence, was hybridized to a set of complementary probes, containing tandem repeats known lengths. Single-stranded loops structures formed on duplexes containing a mismatched (different) number of tandem repeats. No loop structure formed on duplexes containing a matched (identical) number of tandem repeats. The matched and mismatched loop structures were enzymatically distinguished and differentially labeled by treatment with S1 nuclease and the Klenow fragment of DNA polymerase.     

Effect of PCR conditions on the formation of heteroduplex and single-stranded DNA products in the amplification of bacterial ribosomal DNA spacer regions

PCR amplifications of 16S/23S rDNA spacer regions were carried out from conserved 16S and 23S sequences for genomic DNA samples from strains representing 16 bacterial species (12 genera). Multiple products were produced containing conserved homologous sequences at the 3' and 5' ends, separated by highly variable internal spacer sequences. These products cross-hybridized forming heteroduplex DNA structures containing double-stranded ends surrounding an internal single-stranded loop. Single-stranded DNA was also produced in the amplification of rDNA spacer sequences. Fragments comprising the nonhomoduplex DNA components were identified by their susceptibility to removal by digestion with a single-stranded endonuclease. The relative formation of heteroduplex and single-stranded DNA was reduced by reaction conditions favoring primer/template annealing, for example, higher ionic strength, higher primer concentration, and lower annealing temperature, as well as by decreasing the number of amplification cycles. Heteroduplex and single-stranded DNA structures were also generated by denaturing and reannealing spacer amplification products in the absence of polymerase activity. Whereas heteroduplex and single-stranded DNA structures provide additional information that is helpful in distinguishing between species of bacteria that produce similar homoduplex products, the mobility of heteroduplex and single-stranded DNA structures DNA structures is extremely sensitive to electrophoretic conditions.     

The ordered assembly of the phiX174-type primosome. I. Isolation and identification of intermediate protein-DNA complexes

The phiX-type primosome was discovered during the resolution and reconstitution in vitro of the complementary strand DNA replication step of the phiX174 viral life cycle. This multienzyme bidirectional helicase-primase complex can provide the DNA unwinding and Okazaki fragment-priming functions at the replication fork and has been implicated in cellular DNA replication, repair, and recombination. We have used gel mobility shift assays and enhanced chemiluminescence Western analysis to isolate and identify the pathway of primosome assembly at a primosome assembly site (PAS) on a 300-nucleotide-long single-stranded DNA fragment. The first three steps do not require ATP and are as follows: (i) PriA recognition and binding to the PAS, (ii) stabilization of the PriA-PAS complex by the addition of PriB, and (iii) formation of a PriA-PriB-DnaT-PAS complex. Subsequent formation of the preprimosome involves the ATP-dependent transfer of DnaB from a DnaB-DnaC complex to the PriA-PriB-DnaT-PAS complex. The final preprimosomal complex contains PriA, PriB, DnaT, and DnaB but not DnaC. A transient interaction between the preprimosome and DnaG generates the five-protein primosome. As described in an accompanying article (Ng, J. Y., and Marians, K. J. (1996) J. Biol. Chem. 271, 15649-15655), when assembled on intact phiX174 phage DNA, the primosome also contains PriC.     

Purification and characterization of a new DNA polymerase from budding yeast Saccharomyces cerevisiae. A probable homolog of mammalian DNA polymerase beta

A new DNA polymerase activity was identified and purified to near homogeneity from extracts of mitotic and meiotic cells of the yeast Saccharomyces cerevisiae. This activity increased at least 5-fold during meiosis, and it was shown to be associated with a 68-kDa polypeptide as determined by SDS-polyacrylamide gel electrophoresis. This new DNA polymerase did not have any detectable 3'-->5' exonuclease activity and preferred small gapped DNA as a template-primer. The activity was inhibited by dideoxyribonucleoside 5'-triphosphates and N-ethylmaleimide but not by concentrations of aphidicolin which completely inhibit either DNA polymerases I (alpha), II (epsilon), or III (delta). Since no polypeptide(s) in the extensively purified DNA polymerase fractions cross-reacted with antibodies raised against yeast DNA polymerases I, II, and III, we called this enzyme DNA polymerase IV. The DNA polymerase IV activity increased at least 10-fold in a yeast strain overexpressing the gene product predicted from the YCR14C open-reading frame (identified on S. cerevisiae chromosome III and provisionally called POLX), while no activity was detected in a strain where POLX was deleted. These results strongly suggest that DNA polymerase IV is encoded by the POLX gene and is a probable homolog of mammalian DNA polymerase beta.     

Scanning force microscopy of Escherichia coli RNA polymerase.sigma54 holoenzyme complexes with DNA in buffer and in air

Scanning force microscopy (SFM) was used to visualize complexes of Escherichia coli RNA polymerase.sigma54 (RNAP.sigma54) and a 1036 base-pair linear DNA fragment containing the glnA promoter. In order to preserve the native hydration state of the protein-DNA complexes, the samples were injected directly into the SFM fluid cell and imaged in buffer. With this protocol, an apparent bending angle of 26(+/-34) degrees was determined for the specific complexes at the promoter. The bending angle of the unspecifically bound RNAP.sigma54 showed a somewhat broader distribution of 49(+/-48) degrees, indicating the existence of conformational differences as compared to the closed complex. In about two-thirds of the closed complexes, the RNA polymerase holoenzyme was located in a lateral position with respect to the DNA and the bend of the DNA was pointing away from the protein. This conformation was consistent with the finding that for the complexes at the promoter, the apparent contour length was reduced by only about 6 nm in buffer as compared to the free DNA. From these results we conclude that in the closed complex of RNAP. sigma54, the DNA was not wrapped around the polymerase, and we present a model for the trajectory of the DNA with respect to the RNA polymerase. The images acquired in buffer were compared to samples that were washed with water and then dried before imaging. Two artefacts of the washing and drying process were detected. First, extensive washing of the sample reduced the number of the specific complexes bound at the promoter (closed complex of RNAP.sigma54) from about 70% to 30%. This is likely to be a result of sliding of the RNAP.sigma54 holoenzyme along the DNA induced by the washing process. Second, the apparent DNA shortening of the contour length of RNAP.sigma54-DNA complexes at the promoter as compared to the contour length of the free DNA was 22 nm for the dried samples as opposed to only 6 nm for the undried samples imaged in buffer. This suggests an artefact of the drying process.     

Poly(ADP-ribose) polymerase stimulates DNA polymerase alpha by physical association

The direct effect of the eukaryotic nuclear DNA-binding protein poly(ADP-ribose) polymerase on the activity of DNA polymerase alpha was investigated. Homogenously purified poly(ADP-ribose) polymerase (5 to 10 micrograms/ml) stimulated the activity of immunoaffinity-purified calf or human DNA polymerase alpha by about 6 to 60-fold in a dose-dependent manner. It had no effect on the activities of DNA polymerase beta, DNA polymerase gamma, and primase, indicating that its effect is specific for DNA polymerase alpha. Apparently, poly(ADP-ribosyl)ation of DNA polymerase alpha was not necessary for the stimulation. The stimulatory activity is due to poly(ADP-ribose) polymerase itself since it was immunoprecipitated with a monoclonal antibody directed against poly(ADP-ribose) polymerase. Kinetic analysis showed that, in the presence of poly(ADP-ribose) polymerase, the saturation curve for DNA template primer became sigmoidal; at very low concentrations of DNA, it rather inhibited the reaction in competition with template DNA, while, at higher DNA doses, it greatly stimulated the reaction by increasing the Vmax of the reaction. By the automodification of poly(ADP-ribose) polymerase, however, both the inhibition at low DNA concentration and the stimulation at high DNA doses were largely lost. Furthermore, stimulation by poly(ADP-ribose) polymerase could not be attributed to its DNA-binding function alone since its fragment, containing only the DNA-binding domain, could not exert full stimulatory effect on DNA polymerase, as of the intact enzyme. Poly(ADP-ribose) polymerase is co-immunoprecipitated with DNA polymerase alpha, using anti-DNA polymerase alpha antibody, clearly showing that poly(ADP-ribose) polymerase may be physically associated with DNA polymerase alpha. In a crude extract of calf thymus, a part of poly(ADP-ribose) polymerase activity existed in a 400-kDa, as well as, a larger 700-kDa complex containing DNA polymerase alpha, suggesting the existence in vivo of a complex of these two enzymes.