The DNA-membrane fraction of Pneumococcus contains a DNA replication complex

Replitase: complete machinery for DNA synthesis

Replication of nuclear DNA in eukaryotes presents a tremendous challenge, not only due to the size and complexity of the genome, but also because of the time constraint imposed by a limited duration of S phase during which the entire genome has to be duplicated accurately and only once per cell division cycle. A challenge of this magnitude can only be met by the close coupling of DNA precursor synthesis to replication. Prokaryotic systems provide evidence for multienzyme and multiprotein complexes involved in DNA precursor synthesis and DNA replication. In addition, fractionation of nuclear proteins from proliferating mammalian cells shows co-sedimentation of enzymes involved in DNA replication with those required for synthesis of deoxynucleoside triphosphates (dNTPs). Such complexes can be isolated only from cells that are in S phase, but not from cells in G(0)/G(1) phases of cell cycle. The kinetics of deoxynucleotide metabolism supporting DNA replication in intact and permeabilized cells reveals close coupling and allosteric interaction between the enzymes of dNTP synthesis and DNA replication. These interactions contribute to channeling and compartmentation of deoxynucleotides in the microvicinity of DNA replication. A multienzyme and multiprotein megacomplex with these unique properties is called "replitase." In this article, we summarize some of the relevant evidence to date that supports the concept of replitase in mammalian cells, which originated from the observations in Dr. Pardee's laboratory. In addition, we show that androgen receptor (AR), which plays a critical role in proliferation and viability of prostate cancer cells, is associated with replitase, and that identification of constituents of replitase in androgen-dependent versus androgen-independent prostate cancer cells may provide insights into androgen-regulated events that control proliferation of prostate cancer cells and potentially offer an effective strategy for the treatment of prostate cancer.

Characterization of a multienzyme complex derived from a Bacillus subtilis DNA-membrane extract that synthesizes RNA and DNA precursors

The activity of a variety of enzymes involved in the synthesis of RNA and DNA precursors was found to copurify with initiation of DNA replication activity. These enzymes included ribo- and deoxyribonucleoside kinases, kinases for their phosphorylated intermediates, and ribonucleoside diphosphate reductase. This precursor-synthesizing complex is part of a Bacillus subtilis DNA-membrane extract originally shown to contain all of the enzymes and template necessary for initiation of DNA replication (J. Laffan and W. Firshein, J. Bacteriol. 169:2819-2827, 1987). Although the complex incorporated deoxyribonucleoside triphosphates into DNA, deoxyribonucleosides were incorporated even faster, suggesting catalytic facilitation. Both ribonucleosides and deoxyribonucleosides were found by thin-layer chromatography separation to be converted by the complex into their mono-, di-, and triphosphate derivatives. Ribonucleotides were incorporated into DNA via the action of ribonucleoside diphosphate reductase. Some regulatory mechanisms of the kinase system may also be retained by the complex. Electron microscope studies revealed that the precursor-synthesizing-initiation subcomplex is contained within a particulate fraction consisting of different-size vesicles resembling liposomes and that these particles may be structurally important in maintaining the synthetic activity of the subcomplex.

Origin-specific DNA-binding membrane-associated protein may be involved in repression of initiation of DNA replication in Bacillus subtilis

Previous binding studies with labeled double-stranded Bacillus subtilis DNA fragments to a protein blot of renatured Bacillus membrane proteins showed selective binding of two adjacent origin fragments to a 64-kDa protein. The selective binding of the 64-kDa protein could be blocked by prior incubation of the blots with a specific polyclonal antibody. An in vitro replication system derived from a B. subtilis DNA-membrane complex showed initiation activity without addition of exogenous enzymes or template. When the complex was first incubated with the 64-kDa antibody or with its Fab fragments, initiation activity was enhanced. Antibodies to several other Bacillus membrane proteins as well as nonspecific antibodies did not show any significant stimulatory effect. A heavy-density-label experiment indicated that the complex initiated multiple rounds of replication in the presence of the 64-kDa antibody but not in its absence. The 64-kDa antibody plus an initiation inhibitor (streptovaricin) showed only repair and elongation activity. The 64-kDa protein may act in vivo as a repressor/regulator of initiation activity.

Membrane protein binding to the origin region of Bacillus subtilis

Binding of membrane proteins extracted from Bacillus subtilis to an 11.6-kilobase region containing the origin of replication was examined by Western blotting (protein blotting) procedures. Two adjacent origin probes in the double-stranded form (spanning a length of 4 kilobases) were found to bind very strongly to a 63-kilodalton (kDa) protein in that they resisted dissociation after a high-concentration salt wash. This region encompasses both a site implicated in initiation in vivo and a gene coding for a DNA gyrase subunit (gyrA). In contrast, flanking origin and nonorigin double-stranded probes were dissociated after washing with a high salt concentration. Another protein of 67 kDa bound less intensely to the putative initiation site but not to the gyrA region. All of the origin and nonorigin probes in the double- or single-stranded form were found to bind nonspecifically to a subset of 10 to 12 proteins of 50 to 60 separated by gel electrophoresis after a low-concentration salt wash. They ranged in size from 14 to over 100 kDa (including 63 kDa). However, in contrast to the double-stranded forms, most of the single-stranded probes resisted dissociation from the protein subset after a high-concentration salt wash.

DNA replication by a DNA-membrane complex extracted from Bacillus subtilis: site of initiation in vitro and initiation potential of subcomplexes

A DNA-membrane complex extracted from Bacillus subtilis was studied further as a model system for initiation of bacterial DNA replication in vitro. Of three subcomplexes purified from the crude complex by a combination of CsCl and sucrose gradient centrifugation, the synthetic capability of only one was inhibited significantly by streptovaricin, a known inhibitor of RNA primer formation. A selective enrichment in the level of this subcomplex was obtained by manipulating a thymine-requiring mutant. The synthetic capabilities of an enriched and nonenriched DNA-membrane complex were compared in the presence and absence of streptovaricin. Although the rate and extent of DNA synthesis per unit of protein were approximately the same in the absence of the antibiotic, there was a much greater inhibition of synthesis shown by the enriched complex in the presence of streptovaricin. Although the amount of DNA present in the putative initiation subcomplex was less than 0.3 to 0.4% of the total DNA present in the crude complex, such DNA, except for a few quantitative differences, was still representative of genomic DNA. Newly synthesized DNA hybridized to specific origin- and non-origin-derived restriction fragments of the B. subtilis genome. However, when an elongation inhibitor (ddCTP) was added, hybridization of such DNA to almost all of the nonorigin fragments disappeared or was reduced drastically, whereas origin region hybridization patterns remained strong. The highest level of hybridization in the origin region occurred with a BamHI (B7) restriction fragment of 5.6 kilobases that has been implicated by others as one site initiation in vivo (N. Ogasawara, M. Seiki, and H. Yoshikawa, Nature (London) 281:702-704, 1979; S. J. Seror-Laurent and G. Henckes, Proc. Natl. Acad. Sci. USA 82:3586-3590, 1985).

Replication of plasmid RK2 in vitro by a DNA-membrane complex: evidence for initiation of replication and its coupling to transcription and translation

The following results with an in vitro replication system utilizing a plasmid RK2 DNA-membrane complex indicate that the essential trfA-encoded replication protein of RK2 is present and active in the complex. (i) A complex extracted from a conditional replication mutant of RK2, which contains a temperature-sensitive mutation in trfA, displayed extensive DNA synthesis at the permissive temperature but little activity at the restrictive temperature. A control wild-type RK2 complex showed no inhibition of DNA synthesis at the restrictive temperature. (ii) Analysis of plasmid-encoded proteins revealed that the trfA-specified replication protein and other proteins which may be involved in the replication and maintenance of RK2 are located physically in the complex. Semiconservative plasmid DNA replication by the DNA-membrane complex was indicated by density shift experiments; DNA synthesized in the presence of a heavy-density precursor banded primarily in a heavier-density area of a neutral CsCl density gradient and consisted mostly of heavy- and light-density single-stranded DNA as determined by alkaline CsCl density gradient centrifugation. Plasmid RK2 DNA replication by the DNA-membrane complex appears to be coupled to transcription and translation as indicated by the following results: the inhibitory effects of chloramphenicol on both DNA and protein synthesis by the complex; the stimulation of replication by components normally required for protein synthesis (tRNA and all the common amino acids); the synthesis of RNA and protein by the complex; and the synthesis of specific RK2-encoded proteins.

Molecular fate of heterologous bacterial DNA in competent Bacillus subtilis: further characterization of unstable association between donor and recipient DNA and the involvement of the cellular membrane

Although heterospecific transformation is extremely inefficient and very little heterologous donor DNA integrates into the recipient chromosome in a stable way, we have previously shown that B. pumilus DNA entering competent B. subtilis efficiently associates with the recipient chromosome in an unstable way. This association can be stabilized by photocrosslinking in the presence of 4,5',8-trimethylpsoralen; it depends on the recombination proficiency of the recipient strain and on strand-separation of the recipient chromosome (te Riele and Venema 1982b). The present study provides further evidence that the heterologous donor DNA and the recipient DNA are associated by regions of base-pairing. Based on the high sensitivity of the donor moiety in the complex to nuclease S1 (90%) and the high sensitivity of the complex to moderate denaturing conditions (Tm = 48 degrees C), we presume that donor and recipient DNA are associated either by several short sequences of 15-25 fairly well matched base pairs or by a region of base-pairing of about 200 bases, which contains 25% of mismatches. During incubation, the unstable complex disappears, probably due to nucleolytic degradation. The unstable heterologous donor-recipient complex (DRC) was found to be membrane-bound. However, in contrast to homologous DRC, the unstable heterologous DRC remains membrane bound during incubation. Apparently, the predominantly single-stranded character of the heterologous DRC prevents release of the complex from the membrane.

Initiation of DNA replication in vitro by a DNA-membrane complex extracted from Bacillus subtilis

Initiation of DNA replication has been observed in vitro with a DNA-membrane complex extracted from Bacillus subtilis. Antibiotics known to interfere with various aspects of initiation inhibited DNA synthesis significantly in vitro, whereas a mutant resistant to one inhibitor failed to respond to its presence. The inhibitory effects occurred primarily when the immediate RNA precursors (ribonucleoside triphosphates) were present in the assay solution but not significantly when the precursors were omitted. Complexes extracted from a temperature-sensitive initiation mutant were almost incapable of synthesizing DNA at the restrictive temperature but displayed extensive synthesis at the permissive temperature. A strong indication of semiconservative DNA synthesis was obtained in vitro after density-shift experiments involving incubation of the complex with a heavy-density DNA precursor, followed by neutral and alkaline CsCl density gradient centrifugation. A significant amount of chain elongation or repair (or both) was also observed.

Site-specific in vitro binding of plasmid pUB110 to Bacillus subtilis membrane fraction

The in vitro membrane binding of pSL103, a composite plasmid consisting of Staphylococcus aureus plasmid pUB110 and a Bacillus pumilus trpC+ DNA fragment, to the Bacillus subtilis membrane fraction was studied with a total lysate of B. subtilis cells. The binding reaction required a heat treatment at 45 degrees C and had an optimum KCl concentration of 60 mM. Nonradioactive pSL103, but not Escherichia coli plasmid pACYC184, competed with 3H-labeled pSL103 for binding to the membrane. By the use of 32P-labeled restriction fragments of pSL103 and pUB110, it has been found that only the pUB110 portion of pSL103 binds to the membrane and that there are four specific regions in pUB110 which bind to the membrane. Two of the four binding regions flank the replication origin. This in vitro binding was high-salt sensitive and apparently independent of the configurations of the plasmid. We have previously shown that the functional product of the initiation gene dna-1 is required in vivo both for replication initiation and the binding of a DNA region near the replication origin to the membrane. Unlike in vivo binding, which is high-salt resistant and dependent on the product of dna-1 gene (type-I binding), the in vitro binding reported in this paper was high-salt sensitive and independent of the dna-1 gene product (type-II binding).

Cell wall-DNA association in Bacillus subtilis

Autolysis of cell walls of Bacillus subtilis 168 resulted in solubilization of wall-associated DNA. Most of the DNA was solubilized only in the later stages of autolysis. Solubilization of up to 70% of the wall by autolysins resulted in only 25 to 30% solubilization of wall-associated DNA. When the wall fragments remaining after 70% autolysis were analyzed by electron microscopy, it was observed that the preparations were highly enriched for completed septa, or poles. Partial autolysis at pH 5.2 or pH 8.6, both of which reflect hydrogen ion levels that permit either N-acetylglucosaminidase or N-acetylmuramyl-L-alanine amidase, but not both, to act, gave rise to enrichment of cell poles. When walls were incubated with subtilisin, DNase, or RNase, release of DNA (or DNA fragments) was accelerated. Density gradient centrifugation patterns of lysates of cells pulse-labeled with N-[3H]acetylglucosamine and then chased revealed that a small, but significant, proportion of the radioactivity sedimented to a density position equivalent to that of DNA-membrane complexes. Because the pulse-chase sequence enriched for radioactivity in cell poles, the results suggest that at least some molecules from polar cell walls have an affinity for DNA-membrane complexes. We suggest that DNA binds strongly, possibly via a DNA-membrane complex, to cell poles of B. subtilis. The results provide support for a view offered previously (Koch et al., FEMS Microbiol. Lett. 12:201-208, 1981) that some special structure in or very near the poles of gram-positive bacilli is involved in the segregation of DNA during cell division.

Enrichment of DNA polymerase III activity in a DNA membrane complex purified from Pneumococcus: the possible existence of subcomplexes

Three DNA polymerase activities, one related to DNA pol III, have been extracted from a DNA membrane complex purified from Streptococcus pneumoniae. DNA pol III was purified 3300-fold, DNA pol II 2800-fold and DNA pol I 1800-fold. Based on inhibition analysis with a drug known to inhibit DNA pol III activity in Gram positive organisms. 6(p-hydroxyphenyl azo) uracil (HpU), 55% of the total DNA polymerase activity is represented by pol III. In contrast, only 3-5% of the total DNA polymerase activity is inhibited by HpU in crude extracts. The purification of the DNA membrane complex from pneumococcus is modified from an earlier procedure (Firshein 1972). The modified procedure results in the separation of three distinct DNA-protein-phospholipid subcomplexes of which the one described above contains most of the radioactivity derived from cells pulsed for a short time with (3H)-thymidine. Proteins are involved in binding DNA in each complex and the conformation of DNA in each complex may be different. All of the subcomplexes contain DNA polymerase activity partially sensitive to HpU. These results provide direct evidence for the structural integrity of a complex that may be involved in DNA replication in vivo.

Adsorption of proteins from the Spiroplasma citri cell membrane by magnesium lauroyl-sarcosinate crystals

Interactions between the ionic detergent Sarkosyl (sodium lauroyl sarcosinate), Mg2+ ions, and the Spiroplasma citri cell membrane were analyzed microscopically and electrophoretically. Studies were performed under conditions where membrane proteins were apparently not released from the membrane by the detergent (molar ratio of MgCl2/Sarkosyl = 0.5). Although the S. citri membrane interfered with the crystallization phenomenon to some extent, the formation of Sarkosyl-Mg2+ crystals occurred regardless to the sequence of addition of the three components. Concomitantly the structure of the membrane disintegrated and membrane components were adsorbed to the crystal surfaces. The membrane protein fraction bound to the crystals was composed of the majority of the putatively intrinsic polypeptides, including the amphiphilic protein spiralin, and several extrinsic polypeptides. The polypeptide compositions of M-bands (crystal fractions loaded with membrane material) prepared from S. citri cells and from isolated S. citri membranes were similar, as shown by sodium dodecyl-sulfate electrophoresis and crossed immunoelectrophoresis. These results show that, the S. citri cell membrane, in contrast to bacterial membranes, is not protected from the effect of Sarkosyl by Mg2+ ions.

Genetic transformation with cell wall-associated deoxyribonucleic acid in Bacillus subtilis

Cell walls from bacillus subtilis 168 were prepared by conventional methods and found to contain deoxyribonucleic acid (DNA). In transformation assays, after autolysis, it was found that two major regions of the chromosome were selectively enriched in the wall preparations. One region clustered around the replication origin and is represented by the markers purA16, ts8132, thiC5, sacA321, and hisA1. The other region included the replication terminus with representative loci metB10, citK5, gltA292, and pyrA1. All other (internal) loci which were examined showed no statistical enrichment. The two areas of enrichment were similar to but more extensive than those reported for membrane-DNA complexes. The wall preparations also contained protein and lipid, indicating a possible membrane involvement. Analyses of the cell walls revealed that the fatty acid composition of the membrane component was not typical of the for B. subtilis protoplast membranes or for lipoteichoic acids. In addition, radioiodination of cell wall autolysates, followed by gel electrophoresis and autoradiography, demonstrated the presence of proteins not readily detectable in bulk protoplast membranes or on the surfaces of intact cells. These data suggest that a unique component of the membrane and regions of the B. subtilis genome involved in DNA replication events are tightly associated with cell walls. The binding of DNA-membrane complexes to the "rigid" cell wall and the replication of the wall could be a mechanism by which the segregation of growing chromosomes occurs.

Association of the folded chromosome with the cell envelope of Escherichia coli: nature of the membrane-associated DNA

Membrane-associated folded chromosomes isolated from Escherichia coli in the presence of spermidine sedimented at about 5,800S. The folded chromosome and the membrane fragment were each stable in the absence of the other; a 1,700S folded chromosome was obtained after removal of the membrane by a Sarkosyl treatment, and a 4,000S membrane fragment remained after digestion of the chromosomal DNA with deoxyribonuclease I. The interaction between the folded chromosome and the membrane fragment was stable, and, even when the DNA was unfolded, both components remained associated and cosedimented. The large frictional effect of the unfolded DNA reduced the sedimentation rate of the complex to about 2,000S. Partial removal of this unfolded DNA with restriction endonucleases caused the membrane fragments and the remaining associated DNA to sediment faster, at about 3,500S. The DNA remaining associated with the membrane fragments after restriction endonuclease treatment, about 4.5% of the total DNA when EcoRI was used, was indistinguishable from the DNA released from the membranes by three criteria: (i) DNA size distribution in agarose gels after electrophoresis, (ii) reassociation kinetics, and (iii) thermal elution from hydroxylapatite. This finding, that random DNA sequences rather than specific ones were responsible for the majority of the DNA-membrane interactions, argues against the folded chromosome's being a static structure with specific DNA sequences interacting with the cell envelope.

Differential association of F' plasmid and R plasmid deoxyribonucleic acid with a rapidly sedimenting fraction of a Proteus mirabilis lysate

We have examined the association of an F' plasmid and an R plasmid in Proteus mirabilis with a rapidly sedimenting material that is generated by sodium dodecyl sulfate lysis and low speed centrifugation. Virtually all of the chromosomal deoxyribonucleic acid (DNA) and the F' plasmid DNA are associated with the rapidly sedimenting material after gentle lysis and centrifugation. A portion of R plasmid NR1 DNA (usually 5 to 25%) is not bound to the rapidly sedimenting material and is recovered in the supernatant fraction. This difference in binding is not related to the size of the plasmid DNA, since F' plasmids and R plasmids of different molecular weights showed the same behavior. R plasmid DNA labeled by a brief pulse of [(3)H]thymine is recovered in the supernatant fraction to a lower extent than the total R plasmid DNA. It would appear that R plasmid replication takes place in association with the rapidly sedimenting material. With prolongation of the [(3)H]thymine pulse, the [(3)H]thymine-labeled R plasmid DNA is recovered in the supernatant fraction with the same probability as the total R plasmid DNA. This finding indicates that a change in R plasmid attachment to the rapidly sedimenting material occurs some time after its replication. The differences observed in the replication of F' plasmids and R plasmids in P. mirabilis may be related to their different modes of association with the rapidly sedimenting material.

Two membrane sites for DNA synthesis in Pneumococcus

A DNA membrane fraction extracted from pneumococci can be separated into two subfractions with respect to macromolecular composition and DNA synthesis by centrifugation in a 30-60% w/v neutral sucrose gradient. Each fraction can be rebanded in a sucrose gradient or centrifuged to equilibrium in a CsCl density gradient without altering the ability of the fractions to synthesize DNA. The fast sedimenting (heavy) fraction contains 45% of the DNA, and the bulk of the phospholipid, protein, and RNA. The light fraction contains 50% of the DNA, and lower, but significant amounts of phospholipid, RNA, and protein. Both fractions contain a DNA replication complex consisting of a number of enzymes involved in synthesizing DNA or DNA precursors, as well as RNA polymerase activity. However, the specific activity of DNA polymerase in the light fraction is much greater than that in the heavy fraction. In addition, the following results suggest that the former is concerned primarily with replication of the genome while the latter has characteristics of a repair function for the genome. (1) newly synthesized DNA can be detected within 30 s in the light fraction but not until 4 min in the heavy fraction. (2) an RNA-DNA single-stranded hybrid can be demonstrated during initial stages of DNA synthesis in the light, but not heavy fraction. (3) extensive semiconservative DNA replication occurs in the light fraction, whereas little such replication is detected in the heavy fraction. (4) DNA polymerase activity in the light fraction has several of the characteristics of a polymerase identified by others as being concerned with normal DNA replication, such as inhibition by N-ethylmaleimide, and relatively high rates of chain elongation (4.9 x 10(4) nucleotides/min). In contrast, DNA polymerase activity in the heavy fraction has characteristic properties associated with DNA polymerase I, a possible repair enzyme. These include higher activity for a d(A-T)n template than that detected in the light fraction, no effect of N-ethylmaleimide, and relatively low rates of chain elongation (9 x 10(3) nucleotides/min).

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...

Role of polyadenylic acid in a deoxyribonucleic acid-membrane fraction extracted from pneumococci

After the addition of radioactive polyadenylic acid to cell suspensions of pneumocci, part of the radioactivity becomes associated with a deoxyribonucleic acid (DNA)-membrane fraction extracted from the cells. A variety of techniques show that a portion of this associated radioactivity may represent oligoadenylates complexed to DNA, probaby as part of a ribonucleic acid (RNA) component. Polyadenylic acid, which had previously been shown to enhance DNA synthesis in cell suspensions (Firshein and Benson, 1968), also enhances the extent of DNA synthesis by the DNA-membrane fraction in vitro under specific conditions of concentration and conformation. The mechanism of action of this enhancement may be related to the ability of oligoadenylates to increase the number of initiation sites for DNA replication by stimulating the production of an RNA primer, thus providing additional 3'-OH groups with which DNA polymerase can react.

Role of deoxyribonucleic acid ligase in a doxyribonucleic acid membrane fraction extracted from pneumococci

Deoxyribonucleic acid (DNA) ligase has been detected in a DNA membrane fraction extracted from Pneumococcus. The specific activity of the enzyme in this fraction is 10-fold greater than in the remaining cell extract. It remains firmly bound (with other enzymes) to the complex after a purification procedure in which a considerable percentage of the macromolecules are dissociated. The ligase acts in two ways in the DNA membrane fraction in vitro. One, it catalyzes the linkage of small-molecular-weight pieces of newly synthesized DNA into heavier-molecular-weight DNA strands as shown by others (M Gellert, 1976; R. Okazaki, A. Sugino, S. Hirose, T. Okazaki, Y. Imae, R. Kainuma-Kuroda, T. Ogawa, M. Arisawa, and Y. Kurosowa, 1973; B. Olivera and I. Lehman, 14; and A. Sugino, S. Hirose, and R. Okazaki, 1972) and, two, it protects DNA from degradation by deoxyribonucleases. This latter effect is due to a competition between the ability of the nucleases to degrade DNA and the ability of DNA ligase to seal the nicks produced by these degradative enzymes. The ligase acts cooperatively with other enzymes in the DNA membrane fraction to synthesize DNA.

In situ activity of enzymes on polyacrylamide gels of a deoxyribonucleic acid-membrane fraction extracted from pneumococci

A deoxyribonucleic acid (DNA)-membrane fraction extracted from Diplococcus pneumoniae was subjected to polyacrylamide gel electrophoresis after treatment with 0.16% sodium dodecyl sulfate. At least two DNA polymerase activities were detected by in situ assays with appropriate substrates, templates, and inhibitors, including a co-polymer of deoxyadenylic and thymidylic acid and N-ethylmaleimide. This activity coincided with a fraction in the gel containing 7.5, 9.4, and 24%, respectively of the DNA, phospholipid, and protein present in the DNA-membrane fraction before electrophoresis and sodium dodecyl sulfate treatment. Assays with minced gels showed that several nuclease activities, deoxyribonucleotide kinase activity, and DNA ligase activity also coincided with this fraction. However, ribonucleoside diphosphate reductase activity did not. These results demonstrate that a complex of enzymes involved in DNA replication is firmly bound to the DNA-membrane fraction in pneumococci.