Size Distribution and Molecular Polarity of Newly Replicated DNA in Escherichia coli

Newly synthesized DNA, in E. coli lysogenic for the phage lambda, was labeled by short pulses of [(3)H]-thymidine, isolated, and separated on the basis of size by alkaline sucrose density gradient centrifugation. The molecular polarity of this DNA was determined by hybridization with each of the separated strands of lambda DNA. The results show that, in the 3' to 5' direction, replication proceeds by synthesis of short chains that are subsequently joined to long DNA. This is true for both a polA(+) and a polA(-) strain. (The polA locus codes for DNA polymerase I.) In the 5' to 3' direction, replication proceeds continuously, by addition of nucleotides to long DNA, for the polA(+) strain. In the polA(-) strain, however, replication in the 5' to 3' direction is also discontinuous, but the discontinuities are 1-40 times less frequent than in the other direction.     

MECHANISM OF DNA CHAIN GROWTH, III. EQUAL ANNEALING OF T4 NASCENT SHORT DNA CHAINS WITH THE SEPARATED COMPLEMENTARY STRANDS OF THE PHAGE DNA

Nascent short DNA chains isolated from T4-infected E. coli under a variety of conditions anneal equally to the separated complementary phage DNA strands. The samples examined include: pulse-labeled short chains isolated by alkaline sucrose gradient sedimentation from the T4D (wild type)-infected cells in both the early and late stages of phage DNA synthesis; nascent chains accumulated during ligase inhibition of T4 ts B20-infected cells; and the single-stranded nascent short chains isolated from T4D-infected cells by mild procedures involving no denaturation treatment. The results are consistent with the hypothesis that both strands of DNA are synthesized discontinuously.     

Origin and direction of synthesis of bacteriophage fl DNA.

The origin and direction of synthesis in vivo of the viral and complementary strands of f1 DNA were studied by measuring the distribution of radioactivity along the genome after a short pulse of [3H]thymidine. The results indicate that the origins of replication of viral and complementary strands are located close to one another, probably both within a restriction fragment (HaeIII-G) which is about 120 bases long. Replication of both viral and complementary strands proceeds in the 5' leads to 3' overall direction. Thus, the viral strand is elongated in the counterclockwise and the complementary strand in the clockwise direction on the standard genetic map. A model is proposed in which only two mechanisms are invoked to generate all f1 DNA species: (1) the conversion of single-stranded viral DNA into double-stranded molecules and (2) the synthesis of viral single strands from double strands.     

Discontinuous replication of replicative form DNA from bacteriophage phiX174.

Bacteriophage phiX174 DNA has been labeled with short pulses of [3H]thymidine during synthesis of replicative form molecules in infected Escherichia coli HF4704 cells. The replicating phiX174 DNA was isolated and analyzed by sedimentation in an alkaline sucrose gradient. During a brief pulse (5 sec at 30 degrees), the radioactivity incorporated into the complementary strand was found in chains much shorter than one genome length. Of the radioactivity incorporated into the viral strand, two-thirds was in the short pieces and the rest was in chains of one genome length or longer. RNA attachment to the 5' end of both strand components of the nascent short pieces was shown by the appearance of spleen exonuclease-digestable nascent molecules after alkali treatment. These observations suggest that the viral as well as the complementary strand is synthesized by the discontinuous mechanism with RNA primers during replication of duplex phiX174 DNA.     

RNA-Linked Nascent DNA Fragments in Escherichia coli

Nucleic acid that is extracted from E. coli labeled by a brief pulse of [(3)H]dT and depatured by treatment with heat, formamide, or formaldehyde bands in a region with a density higher than that of single-stranded E. coli DNA in a Cs(2)SO(4) equilibrium density gradient. If treated with alkali or RNase, it then exhibits the density of single-stranded DNA. These results suggest the presence of a short strand of RNA covalently linked to the nascent DNA. Evidence for the presence of covalently linked RNA-DNA molecules is also obtained by pulse labeling with [(3)H]U. Analyses of nascent nucleic acids from cells pulse labeled for various times, and of the molecules with different sizes, support the hypothesis that the short DNA fragments are formed by extension of even shorter RNA chains, which are synthesized on the parental DNA strands and are removed before ligation of the DNA fragments. The synthesis of the RNA segment of the RNA-DNA molecule is much less sensitive to rifampicin than is the synthesis of bulk RNA.     

RNA-Linked Short DNA Fragments During Polyoma Replication

During in vitro incubation, nuclei from polyoma-infected cells elongate the daughter strands of the replicative intermediate of polyoma DNA. This process is now shown to involve the transient formation of short fragments (4-5 S), a process that is stimulated by the addition of ribonucleoside triphosphates. The presence of stretches of RNA at the 5'-end of short DNA chains was determined from Cs(2)SO(4) equilibrium centrifugation and from the finding that isotope from alpha-(32)P-labeled deoxynucleoside triphosphates was recovered in 2'(3')-ribonucleotides after alkaline hydrolysis. Transfer occurred preferentially with [alpha-(32)P]dCTP as substrate. Starvation for deoxynucleotides by in vivo treatment with hydroxyurea resulted in the accumulation of short fragments that are deficient in RNA. Our results suggest that a late step during the discontinuous synthesis of polyoma DNA is selectively inhibited when deoxynucleotides are in short supply.     

Initiator RNA in Discontinuous Polyoma DNA Synthesis

During replication of polyoma DNA in isolated nuclei, RNA was found attached to the 5' ends of growing progeny strands. This RNA starts with either ATP or GTP and can be labeled at its 5' end with (32)P from beta-labeled nucleotides. Digestion of progeny strands with pancreatic DNase released (32)P-labeled RNA that, on gel electrophoresis, gave a distinct peak in the position expected for a decanucleotide. We believe that this short RNA is involved in the initiation of the discontinuous synthesis of DNA and propose the name "initiator RNA" for it. The covalent linkage of initiator RNA to 5' ends of growing DNA chains was substantiated by the finding that (32)P was transferred to ribonucleotides by alkaline hydrolysis of purified initiator RNA obtained by DNase digestion of polyoma progeny strands synthesized from [alpha-(32)P]dTTP. While initiator RNA was quite homogeneous in size, it had no unique base sequence since digestion with pancreatic RNase of initiator RNA labeled at its 5' end with (32)P released a variety of different [(32)P]oligonucleotides. The switch from RNA to DNA synthesis during strand elongation may thus depend on the size of initiator RNA rather than on a specific base sequence.     

Replication of DNA in Mammalian Chromosomes: Isolation of Replicating Segments

From Chinese hamster cells, blocked at the beginning of the S phase by treatment with fluorodeoxyuridine and pulse-labeled with [³H]thymidine, one can release segments of native DNA containing template polyuncleotide chains and the most recently replicated DNA. The segments, which can be released without shear by lysis at temperatures below the melting point for the double helix, can be separated from both the nascent single chains (Okazaki pieces) and the long strands of native DNA in sodium perchlorate gradients. These 26S segments are equivalent to about 6 μm of native DNA, but may be replication forks rather than linear pieces.     

Novel structure at 5''-ends of nascent DNA chains.

Because of their association with protein short nascent DNA chains in Escherichia coli can be separated from other cellular DNA by chromatography on hydroxylapatite. Protein-free DNA chains of less than 500 nucleotides in length are resistant to degradation from the 5'-end by alkaline phosphatase [orthophosphoric-monoester phosphohydrolase (alkaline optimum); EC 3.1.3.1] and spleen phosphodiesterase (oligonucleate 3'-nucleotidohydrolase; EC 3.1.4.18). In contrast, DNA chains containing more than 500 nucleotides are degradable. From these results we conclude that short nascent DNA chains are structurally modified at their 5'-ends. The nature of this structure and its possible functions are discussed.     

A DNA polymerase alpha pause site is a hot spot for nucleotide misinsertion.

In this study we examined whether the arrest of DNA polymerase alpha (pol alpha)-catalyzed DNA synthesis at template pause sites entails terminal nucleotide misincorporation. An approach was developed to identify the 3'-terminal nucleotide in nascent DNA chains that accumulate at pause sites. A radioactive 5'-end-labeled primer was annealed to a bacteriophage M13mp2 single-stranded DNA template and elongated by pol alpha. Individual DNA chains that were accumulated at pause sites were resolved by sequencing gel electrophoresis, isolated, and purified. These DNA chains were elongated by pol alpha by using four annealed synthetic DNA templates, each of which contained a different nucleotide at the position opposite the 3' terminus of the arrested chain. Owing to the high preference of pol alpha for matched-over-mismatched primer termini, only those templates that contain a nucleotide that is complementary to the 3' terminus of the isolated pause-site chain are copied. Electrophoresis of product DNA showed the extent of copying of each template and thus identified the 3'-terminal nucleotide of the pause-site chains. We found that product DNA chains terminate with a noncomplementary 3'-terminal nucleotide opposite pause sites within the sequence 3'-d(AAAA)-5' at positions 6272-6269 of the M13mp2 genome. pol alpha catalyzed misincorporation of dG or dA into the 3' terminus of nascent chains opposite two of the M13mp2 template dA residues. A similar analysis of a different pause site did not reveal significant misincorporation opposite template dC. These results suggest that some but not all sites at which pol alpha pauses may constitute loci of mutagenesis.     

Adenovirus DNA replication in vitro: characterization of a protein covalently linked to nascent DNA strands.

The 5' terminus of each nascent daughter strand of adenovirus DNA replicated in vitro is covalently linked to a protein with an apparent Mr of 80,000. This protein may represent a precursor to the 55,000-dalton protein known to be linked to the 5' ends of mature adenovirus DNA strands. Partial proteolysis experiments indicate that the 80,000-dalton and 55,000-dalton proteins are structurally related. Furthermore, both proteins are attached to DNA by the same linkage: a phosphodiester bond between the beta-OH of a serine residue in the protein and the 5'-OH of the terminal deoxycytidine residue of the DNA. The role of the 80,000-dalton protein in adenovirus DNA replication is not yet clear, although one reasonable possibility is that it serves as the primer for daughter strand synthesis.     

DNA breakage and closure by rat liver type 1 topoisomerase: separation of the half-reactions by using a single-stranded DNA substrate.

Circular single strands of bacteriophage phi X174 DNA are broken by rat liver DNA nicking-closing enzyme (type 1 topoisomerase) in low salt (50 mM KCl) at 37 degrees C, generating linear strands containing covalently bound enzyme [Been, M. D. & Champoux, J. J. (1980) Nucleic Acids Res. 8, 6129-6142]. The linear strands can be recircularized in the presence of 10 mM MgCl2 at 24 degrees C and 37 degrees C or 250 mM KCl at 24 degrees C. Recircularization is blocked when the hydroxyl group at the 5' terminus is phosphorylated. The linears generated by the nicking-closing enzyme can also be joined to other DNA fragments containing 5' hydroxyls, but not 5' phosphates. The linkage formed in both the intrastrand and interstrand reactions is stable to alkali. Reclosure of broken single strands is presumed to be analogous to the closure step that occurs durng nicking and closing cycles on duplex DNA.     

Mouse DNA polymerase alpha-primase terminates and reinitiates DNA synthesis 2-14 nucleotides upstream of C2A1-2(C2-3/T2) sequences on a minute virus of mice DNA template.

The distribution of termination and initiation sites in a 5081-nucleotide minute virus of mice DNA template being copied by a highly purified mouse DNA polymerase alpha-DNA primase complex in the presence of GTP has been examined. The 3'-hydroxyl termini (17 in all) were clustered at six sites that were located 2-14 nucleotides upstream of C2A2C2, C2AC3, or C2A2T2 sequences. When either [alpha-32P]- or [gamma-32P]GTP was included in the DNA polymerase reaction mixtures, nascent DNA became radiolabeled. Analysis of the 32P-labeled material following treatment of the DNA with tobacco acid pyrophosphatase, bacterial alkaline phosphatase, or ribonuclease T1 revealed the presence of oligoribonucleotide chains averaging 5-7 nucleotides long and beginning with 5' GTP residues. Eight presumptive DNA primase initiation sites were located opposite C4 or C5 sequences 3-9 nucleotides upstream of one of the three closely related hexanucleotides C2A2C2, C2AC3, and C2A2T2. RNA-DNA junctions were found 3-10 nucleotides downstream of DNA primase initiation sites. The results indicate that hexanucleotides having the general formula C2A1-2(C2-3/T2), herein referred to as psi, are involved in promoting termination of DNA synthesis and/or de novo initiation of RNA-primed DNA chains by DNA polymerase alpha-primase.     

Rescue of stalled replication forks by RecG: Simultaneous translocation on the leading and lagging strand templates supports an active DNA unwinding model of fork reversal and Holliday junction formation

Modification of damaged replication forks is emerging as a crucial factor for efficient chromosomal duplication and the avoidance of genetic instability. The RecG helicase of Escherichia coli, which is involved in recombination and DNA repair, has been postulated to act on stalled replication forks to promote replication restart via the formation of a four-stranded (Holliday) junction. Here we show that RecG can actively unwind the leading and lagging strand arms of model replication fork structures in vitro. Unwinding is achieved in each case by simultaneous interaction with and translocation along both the leading and lagging strand templates at a fork. Disruption of either of these interactions dramatically inhibits unwinding of the opposing duplex arm. Thus, RecG translocates simultaneously along two DNA strands, one with 5'-3' and the other with 3'-5' polarity. The unwinding of both nascent strands at a damaged fork, and their subsequent annealing to form a Holliday junction, may explain the ability of RecG to promote replication restart. Moreover, the preferential binding of partial forks lacking a leading strand suggests that RecG may have the ability to target stalled replication intermediates in vivo in which lagging strand synthesis has continued beyond the leading strand.     

Isothermal in vitro amplification of DNA by a restriction enzyme/DNA polymerase system.

An isothermal in vitro DNA amplification method was developed based upon the following sequence of reaction events. Restriction enzyme cleavage and subsequent heat denaturation of a DNA sample generates two single-stranded target DNA fragments (T1 and T2). Present in excess are two DNA amplification primers (P1 and P2). The 3' end of P1 binds to the 3' end of T1, forming a duplex with 5' overhangs. Likewise, P2 binds to T2. The 5' overhangs of P1 and P2 contain a recognition sequence (5'-GTTGAC-3') for the restriction enzyme HincII. An exonuclease-deficient form of the large fragment of Escherichia coli DNA polymerase I (exo- Klenow polymerase) [Derbyshire, V., Freemont, P. S., Sanderson, M. R., Beese, L., Friedman, J. M., Joyce, C. M. & Steitz, T. A. (1988) Science 240, 199-201] extends the 3' ends of the duplexes using dGTP, dCTP, TTP, and deoxyadenosine 5'-[alpha-thio]triphosphate, which produces hemiphosphorothioate recognition sites on P1.T1 and P2.T2. HincII nicks the unprotected primer strands of the hemiphosphorothioate recognition sites, leaving intact the modified complementary strands. The exo- Klenow polymerase extends the 3' end at the nick on P1.T1 and displaces the downstream strand that is functionally equivalent to T2. Likewise, extension at the nick on P2.T2 results in displacement of a downstream strand functionally equivalent to T1. Nicking and polymerization/displacement steps cycle continuously on P1.T1 and P2.T2 because extension at a nick regenerates a nickable HincII recognition site. Target amplification is exponential because strands displaced from P1.T1 serve as targets for P2 and strands displaced from P2.T2 serve as targets for P1. A 10(6)-fold amplification of a genomic sequence from Mycobacterium tuberculosis or Mycobacterium bovis was achieved in 4 h at 37 degrees C.     

Initiation sites for discontinuous DNA synthesis of bacteriophage T7

We have previously shown that the discontinuous replication of bacteriophage T7 DNA is primed by tetraribonucleotides (major component) or pentaribonucleotides. Both tetramers and pentamers start with pppA-C and are rich in A and C at the third and fourth nucleotides. In this study, the sites of transition from primer RNA to DNA in vivo have been located on a 340-nucleotide segment of the H strand of the T7 genome by 32P-labeling in vitro of the 5'-hydroxyl ends of DNA resulting from alkaline hydrolysis of RNA-linked T7 DNA fragments. Five strong transition sites were detected with a common sequence 5'-G-A-C-N1-N2-N3-N4-3', in which N1 was either C or A, N2 ws A, C, or G, and either N3 or N4 was the nucleotide for the switchover to DNA synthesis. We conclude that the complementary sequence 3'-C-T-G-G/T-N'2-(N'3)-5' in the template strand is the most frequently used signal for synthesis of primer RNA. Whereas primer-RNA synthesis starts at a precisely defined nucleotide, the transition to DNA synthesis varies within two nucleotides. Because the observed signal sequence would be present on a statistical basis once per 128 nucleotides, only about 10% of the existing signals are used for primer synthesis in each round of replication so that nascent fragments 1000-2000 long result. This provides an unexpected flexibility for RNA priming of DNA synthesis.     

Directionality and polarity in recA protein-promoted branch migration.

The recA protein of Escherichia coli promotes the complete exchange of strands between full-length linear duplex and single-stranded circular phi X174 DNA molecules. Analysis of the reaction by electron microscopy confirms that D loops containing short heteroduplex regions are rapidly formed at the ends of the linear duplex, followed by a relatively slow branch migration that converts the D loops to nicked circular duplexes (RFII) and displaced linear single strands. Heteroduplex extension and displacement of the linear single strand are concerted. Heterologous sequences within the linear duplex halt branch migration and lead to the accumulation of D loops. Although D loops can be formed at either end of the linear duplex, recA protein-promoted branch migration proceeds uniquely in the 3' leads to 5' direction relative to the (--) strand of the linear duplex.