Size and base composition of RNA in supercoiled plasmid DNA

Characterization of repetitive sequence families in mouse heart small polydisperse circular DNAs: age-related studies

Using alkaline denaturation-renaturation, exonuclease III digestion and density gradient centrifugations, we have isolated covalently closed circular DNA (cccDNA) molecules from 1-, 8-, 16-, and 24-month C57BL/6 mouse heart tissues. Electron microscopic analyses demonstrated that all these preparations contained small polydisperse circular DNAs (spcDNAs). spcDNAs showed similar size distributions at all ages, but more discrete size classes and slightly larger circles were observed in the 24-month heart spcDNA preparations. Based upon the final yields of spcDNAs, there appeared to be no age-related changes in the quantity of these circular molecules in vivo. Furthermore, [3H]-pBR322 recovery studies revealed no endogenous factors that might have affected the yield of spcDNAs from young and old tissues. To determine if there were any age-related changes in the quantity of repetitive sequences in spcDNAs, we probed heart spcDNAs with B1, B2, IAP, L1 and satellite sequences of the mouse genome. The hybridization results showed that these sequence families were differentially represented at all ages in spcDNAs. B2 sequences were the highest across all the age groups while L1 sequences were the lowest. The quantity of B1-, B2-, IAP-, and L1-spcDNAs appeared to decrease at 24-months. Satellite sequences appeared to decrease from 1-month to 8-months, but no change beyond 8-months.

Evidence for direct involvement of T7 RNA polymerase bacteriophage DNA replication

Experiments in a number of different systems have suggested that the initiation of DNA replication is often dependent upon transcription at the origin of replication. During infection with bacteriophage T7, the T7 genome is transcribed first by the bacterial RNA polymerase and then by a phage-coded enzyme, the product of gene 1. The bacterial enzyme does not appear to be directly involved in the initiation of replication as phage DNA synthesis is not inhibited by rifampin. For testing whether the T7 RNA polymerase plays a role in replication, a T7 gene 1 temperature-sensitive mutant was used, and the RNA polymerase was inactivated at intervals after infection by rapidly raising the temperature of the culture. The experiments indicated that the inactivation of the T7 RNA polymerase caused the cessation of phage DNA synthesis, even at later times during infection when the inhibition of protein synthesis with chloramphenicol had no effect on DNA replication. This suggests that in addition to its role in gene expression, the T7 RNA polymerase plays a direct role in T7 DNA replication.

The enzymatic replication of DNA

Enzymatic mechanisms of DNA replication have been investigated using small bacteriophages as probes to illuminate the cellular systems upon which they must rely during infection. Conversion of the circular, single-stranded DNAs of phages M13, G4, and phi X174 to their duplex forms has revealed the participation of diverse ways to start a new chain and a complex DNA polymerase III holoenzyme upon which all these systems depend for chain elongation. The phi X174 system, which is the most exacting and revealing of the host chromosomal replication pattern, includes at least twenty polypeptides for making the viral DNA into a duplex and multiplying the duplex. Resolution and purification of these numerous proteins is in train and their reconstitution into a "replisome"-like structure is envisioned.

Low molecular weight RNA species encoded by a multiple drug resistance plasmid

Multiple drug resistance plasmid NR1 is shown to code for at least 10 low molecular weight RNAs. These species, ranging in size from 60 to 120 nucleotides, have been purified from minicells by two-dimensional gel electrophoresis and characterized by RNase T1 fingerprinting. Hybridization of purified RNAs to restriction endonuclease digests of NR1 DNA indicates that most are derived from the resistance transfer factor region of the plasmid genome. One RNA was found to be coded by the transposable tetracycline resistance element Tn10, and several are associated with DNA fragments that contain origins of replication.

Structure of nascent replicative form DNA of coliphage M13

Nascent replicative form type II (RFII) DNA of coliphage M13 synthesized in an Escherichia coli mutant deficient in the 5' leads to 3' exonuclease associated uith DNA polymerase I contains ribonucleotides that are retained in the covalently closed RFI DNA sealed in vitro by the joint action of T5 phage DNA polymerase and T4 phage DNA ligase. These RFI molecules are labile to alkali and RNase H, unlike the RFI produced either in vivo or from RFII with E. coli DNA polymerase I and E. coli DNA ligase. The ribonucleotides are located at one site and predominantly in one strand of the nascent RF DNA. Furthermore, these molecules contain multiple small gaps, randomly located, and one large gap in the intracistronic region.

DNA strand scission by benzo[a]pyrene diol epoxides

Syn-and anti-benzo[a]pyrene diol epoxides elicit a concentration-dependent nicking of superhelical Col E1 DNA in an in vitro reaction monitored by agarose gel electrophoresis and electron microscopy. This strand scission represents less than 1 percent of the DNA modification by diol epoxide. Kinetic analysis implicates the formation of unstable phosphotriesters, hydrolysis of which nick the DNA.

Plasmid ColE1 DNA replication in Escherichia coli strains temperature-sensitive for DNA replication

Mutants of the dnaA, dnaC, dnaD, polC, dnaF and dnaG gene loci were tested for their capacity for colicinogenic plasmid E1 (ColE1) replication at a non-permissive temperature. It was found that ColE1 replication was independent of the dnaA gene function and dependent on dnaC, D, F and G. ColE1 replication in the polC mutant E486 continued for several hours but at a greatly reduced rate. No effect was found of the dnaG mutation on thymine-deprivation-induced "priming" of ColE1 replication at the non-permissive temperature. The mutants also were tested for aberrant replication intermediates of plasmid DNA as well as a temperature sensitive supercoiled DNA-protein relaxation complex. RNA-containing supercoils were found to accumulate in a poIC mutant also blocked for protein synthesis.

Replication of colicinogenic factor E1 DNA in plasmolysed Escherichia coli cells. Coupling of DNA replication and RNA synthesis

Plasmolysed chloramphenicol-treated Escherichia coli cells carrying the colicinogenic factor E1 utilize deoxynucleoside triphosphates for the semi-conservative synthesis of Col E1 DNA. Col E1 DNA replication in plasmolysed cells can be dissociated into two temporally separated processes: (a) a rifampicin-sensitive RNA synthesis, which is stimulated by adenosine 3':5'-monophosphate (cyclic AMP) and requires all four ribonucleoside triphosphates and (b) an ATP-dependent DNA synthesis, which is inhibited by arabinosylnucleoside triphosphates and sulfhydryl-blocking reagents. Thes two processes exhibit different sensitivities to inhibition by polyamines and actinomycin D.

Studies on reverse transcriptase of RNA tumor viruses III. Properties of purified Moloney murine leukemia virus DNA polymerase and associated RNase H

DNA polymerase was purified from a cloned isolate of Moloney murine leukemia virus (M-MuLV). Purified M-MuLV DNA polymerase, upon analysis by polyacrylamide gel electrophoresis, showed one major polypeptide of mol wt 80,000. Estimation of molecular weight from the sedimentation rate of the purifed enzyme in a glycerol gradient was consistent with a structure containing one polypeptide. M-MuLV DNA polymerase could transcribe ribopolymers, deoxyribopolymers, and heteropolymers as efficiently as did purified DNA polymerase from avian myeloblastosis virus (AMV). M-MuLV DNA polymerase, however, transcribed native 70S viral RNA less efficiently than did AMV DNA polymerase. Addition of oligo(dT) enhanced five to tenfold the transcription of 70S viral RNA by M-MuLV DNA polymerase. Purified enzyme also exhibited nuclease activity (RNase H) that selectively degraded the RNA moiety of the RNA-DNA hybrid. It did not degrade single-stranded RNA, single-stranded DNA, double-stranded RNA, and double-stranded DNA. M-MuLV DNA polymerase-associated RNase H acted as a random exonuclease. When [3-H]poly(A)-poly(dT) was used as a substrate, the size of the M-MuLV DNA polymerase-associated RHase H digested product was larger than the size of the digestion products by AMV DNA polymerase. The oligonucleotide digestion products could be further digested to 5'-AMP by snake venom phosphodiesterase, indicating that the products were terminated by 3'-OH groups. Alkaline hydrolysis of the oligonucleotide digestion products generated pAp, suggesting that M-MuLV DNA polymerase-associated RNase H cleaves at the 3' side of the 3',5'-phosphodiester bond. The ratios of the rates of DNA polymerase activity and RNase H activity were not significantly different in the murine and avian enzymes.

Nature of R-factor replication in the presence of chloramphenicol

Covalently closed circular deoxyribonucleic acid molecules of RSF1030, a nonconjugative R-factor, initiate and complete rounds of semiconservative replication in the absence of protein synthesis long after the bacterial chromosome has ceased its replication. RSF1030 replication under these conditions is sensitive to the inhibitor of ribonucleic acid synthesis, rifampicin. The product of this replication, a covalently closed DNA molecule, shows, in contrast to those molecules produced during the replication in a logarithmically growing culture of Escherichia coli, a transition to the open circular form upon treatment with ribonucleases of alkali. Analysis of the product resulting from alkali treatment indicates that there is a single break in one strand of the original circular duplex. This alkali-sensitive site occurs with equal probability in either of the complementary strands. These results are interpreted as a requirement for an RNA primer for the initiation of RSF1030 DNA synthesis and as showing that its removal from the covalently closed molecule is inhibited in the absence of protein synthesis.

Reinitiation of deoxyribonucleic acid synthesis by deoxyribonucleic acid initiation mutants of Escherichia coli: role of ribonucleic acid synthesis, protein synthesis, and cell division

The dnaA and dnaC genes are thought to code for two proteins required for the initiation of chromosomal deoxyribonucleic acid replication in Escherichia coli. When a strain carrying a mutation in either of these genes is shifted from a permissive to a restrictive temperature, chromosome replication ceases after a period of residual synthesis. When the strains are reincubated at the permissive temperature, replication again resumes after a short lag. This reinitiation does not require either protein synthesis (as measured by resistance to chloramphenicol) or ribonucleic acid synthesis (as measured by resistance to rifampin). Thus, if there is a requirement for the synthesis of a specific ribonucleic acid to initiate deoxyribonucleic acid replication, this ribonucleic acid can be synthesized prior to the time of initiation and is relatively stable. Furthermore, the synthesis of this hypothetical ribonucleic acid does not require either the dnaA of dnaC gene products. The buildup at the restrictive temperature of the potential to reinitiate deoxyribonucleic acid synthesis at the permissive temperature shows rather complex kinetics the buildup roughly parallels the rate of mass increase of the culture for at least the first mass doubling at the restrictive temperature. At later times there appears to be a gradual loss of initiation potential despite a continued increase in mass. Under optimal conditions the increase in initiation potential can equal, but not exceed, the increase in cell division at the restrictive temperature. These results are most easily interpreted according to models that postulate a relationship between the initiation of deoxyribonucleic acid synthesis and the processes leading to cell division.

Multienzyme systems of DNA replication

Replication is accomplished by multienzyme systems whose operations are usefully considered in respect to three stages of the process: initiation, elongation, anid termination. 1) Initiation entails synthesis of a short RNA fragment that serves as primer for the elongation step of DNA synthesis. This stage, probed by SS phage DNA templates, reveals three distinctive and highly specific systems in E. coli. The Ml3 DNA utilizes RNA polymerase in a manner that may reflect how plasmid elements are replicated in the cell. The ØX174 DNA does not rely on RNA-polymerase, but requires instead five distinctive proteins which may belong to an apparatus for initiating a host chromosome replication cycle at the origin. The G4 DNA, also independent of RNA polymerase, needs simply the dnaG protein for its distinctive initiation and may thus resemble the system that initiates the replication fragments at the nascent growing fork. In each case it is essential that in vitro the DNA-unwinding protein coat the viral DNA and influence its structure. 2) Elongation is achieved in every case by the multisubunit, holoenzyme form of DNA polymerase III. Copolymerase III, which is an enzyme subunit, and adenosine triphosphate are required to form a proper complex with the primer template but appear dispensable for the ensuing chain growth by DNA polymerase (33). 3) Termination requires excision of the RNA priming fragment, filling of gaps and sealing of interruptions to produce a covalently intact phosphodiester backbone. DNA polymerase I has the capacity for excision and gapfilling and DNA ligase is required for sealing. What once appeared to be a simple DNA polymerase-mediated conversion of a single-strand to a duplex circle (34) is now seen as a complex series of events in which diverse multienzyme systems function. Annoyance with the difficulties in resolving and reconstituting these systems is tempered by the conviction that these are the very systems used ,by the cell in replicating its chromosome and extrachromosomal elements. Thus, understanding of the regulation of replication events in the cell, their localization at membrane surfaces and integration with cell division, and their coordination with phage DNA maturation and particle assembly will all be advanced by knowledge of the components of the replicative machinery.

Effect of inhibitors of ribonucleic acid and protein synthesis on the cyclic adenosine monophosphate stimulation of plasmid ColE1 replication

Addition of cyclic adenosine 3'-5'-monophosphate (c-AMP) to growing Escherichia coli cells, colicinogenic for the plasmid ColE1, results in a fourfold stimulation in the rate of synthesis of the plasmid deoxyribonucleic acid (DNA). The stimulation is transient (30 min) and is succeeded by a brief period (30 min) of cessation of plasmid DNA replication. The stimulation of ColE1 DNA replication also occurs in chloramphenicol-treated cells. Rifampin inhibits ColE1 DNA replication in the presence or absence of c-AMP. Employing thymine starvation conditions to stop ColE1 DNA synthesis, it was found that c-AMP, added during the period of thymine starvation, effected a stimulation in the amount of subsequent replication which took place when replicating conditions were restored. The stimulatory effect of c-AMP under these conditions was not prevented by chloramphenicol but was completely eliminated when rifampin was present. Under these conditions, when rifampin was added after the effect of c-AMP was allowed to occur, subsequent replication of the plasmid could take place, but only one round of replication occurred. A model to account for the c-AMP effects is presented.