Agrobacterium T-strand production in vitro: sequence-specific cleavage and 5' protection of single-stranded DNA templates by purified VirD2 protein

Virulence proteins VirD1 and VirD2 are subunits of a relaxosome-like protein complex that mediates conjugational transfer of a Ti plasmid segment, the T-DNA, from Agrobacterium into higher plants. The VirD1-VirD2 complex binds to 25-bp repeats at the borders of the T-DNA and catalyzes sequence-specific nicking of the conjugative DNA strand (the T-strand) at the third base of these repeats. Nuclear localization signals present in VirD2 target the T-strand to plant cell nuclei. In addition, VirD2 probably plays a role in the high-frequency integration of the T-DNA into the plant genome by illegitimate recombination. Whereas Agrobacterium transformation of dicots is very efficient, T-DNA integration in most monocots can barely be detected. To develop an artificial T-DNA delivery system for monocots, a technique for efficient in vitro production of T-strand DNAs was established by using VirD1 and VirD2 proteins purified from overexpressing Escherichia coli strains. The topoisomerase-like VirD2 enzyme was shown to mediate precise, sequence-specific cleavage of T-DNA border sequences carried by single-stranded DNA templates, even in the absence of VirD1 protein. During this reaction, VirD2 remains covalently bound to the 5' end of artificial T-strand DNAs. In contrast, VirD2, alone or in complex with VirD1, fails to nick linear double-stranded DNA templates in vitro.     

High-mobility group 1/2 proteins are essential for initiating rolling-circle-type DNA replication at a parvovirus hairpin origin

Rolling-circle replication is initiated by a replicon-encoded endonuclease which introduces a single-strand nick into specific origin sequences, becoming covalently attached to the 5' end of the DNA at the nick and providing a 3' hydroxyl to prime unidirectional, leading-strand synthesis. Parvoviruses, such as minute virus of mice (MVM), have adapted this mechanism to amplify their linear single-stranded genomes by using hairpin telomeres which sequentially unfold and refold to shuttle the replication fork back and forth along the genome, creating a continuous, multimeric DNA strand. The viral initiator protein, NS1, then excises individual genomes from this continuum by nicking and reinitiating synthesis at specific origins present within the hairpin sequences. Using in vitro assays to study ATP-dependent initiation within the right-hand (5') MVM hairpin, we have characterized a HeLa cell factor which is absolutely required to allow NS1 to nick this origin. Unlike parvovirus initiation factor (PIF), the cellular complex which activates NS1 endonuclease activity at the left-hand (3') viral origin, the host factor which activates the right-hand hairpin elutes from phosphocellulose in high salt, has a molecular mass of around 25 kDa, and appears to bind preferentially to structured DNA, suggesting that it might be a member of the high-mobility group 1/2 (HMG1/2) protein family. This prediction was confirmed by showing that purified calf thymus HMG1 and recombinant human HMG1 or murine HMG2 could each substitute for the HeLa factor, activating the NS1 endonuclease in an origin-specific nicking reaction.     

Hin-mediated inversion on positively supercoiled DNA

Hin recombinase requires negatively supercoiled DNA for an efficient inversion. We have generated positively supercoiled plasmid DNA using reverse gyrase from Sulfolobus shibatae and subjected it to the Hin-mediated inversion reaction. Both Hin and Fis showed the same DNA binding activity regardless of the superhelical handedness of the substrate plasmid. However, inversion activity on positively supercoiled DNA was less than 1% of negatively supercoiled DNA. Assays designed to probe steps in inversion, showed that on positively supercoiled DNA, Hin was able to cleave the recombination sites with the same efficiency shown on negatively supercoiled DNA but was not able to exchange the cleaved DNA. Based on the theoretical differences between positive and negative supercoiling, our data may suggest that unwinding of the double helix at recombination sites is needed after DNA cleavage for strand exchange to occur.     

The characterization of a mammalian DNA structure-specific endonuclease

The repair of some types of DNA double-strand breaks is thought to proceed through DNA flap structure intermediates. A DNA flap is a bifurcated structure composed of double-stranded DNA and a displaced single-strand. To identify DNA flap cleaving activities in mammalian nuclear extracts, we created an assay utilizing a synthetic DNA flap substrate. This assay has allowed the first purification of a mammalian DNA structure-specific nuclease. The enzyme described here, flap endonuclease-1 (FEN-1), cleaves DNA flap strands that terminate with a 5' single-stranded end. As expected for an enzyme which functions in double-strand break repair flap resolution, FEN-1 cleavage is flap strand-specific and independent of flap strand length. Furthermore, efficient flap cleavage requires the presence of the entire flap structure. Substrates missing one strand are not cleaved by FEN-1. Other branch structures, including Holliday junctions, are also not cleaved by FEN-1. In addition to endonuclease activity, FEN-1 has a 5'-3' exonuclease activity which is specific for double-stranded DNA. The endo- and exonuclease activities of FEN-1 are discussed in the context of DNA replication, recombination and repair.     

Nicking by transesterification: the reaction catalysed by a relaxase

DNA relaxases play an essential role in the initiation and termination of conjugative DNA transfer. Purification and characterization of relaxases from several plasmids has revealed the reaction mechanism: relaxases nick duplex DNA in a site- and strand-specific manner by catalysing a transesterification. The product of the reaction is a nicked double-stranded DNA molecule with a sequestered 3'-OH and the relaxase covalently bound to the 5' end of the cleaved strand via a phosphotyrosyl linkage. The relaxase-catalysed transesterification is isoenergetic and reversible; a second transesterification ligates the nicked DNA. However, the covalent nucleoprotein complex is relatively long-lived, a property that is likely to be essential for its role as an intermediate in the process of conjugative DNA transfer. Subsequent unwinding of the nicked DNA intermediate is required to produce the single strand of DNA transferred to the recipient cell. This reaction is catalysed by a DNA helicase, an activity intrinsic to the relaxase protein in some, but not all, plasmid systems. The first relaxase-catalysed transesterification is essential for initiation of conjugative strand transfer, whereas the second is presumably required for termination of the process. The relaxase, in conjunction with several auxiliary proteins, forms the relaxation complex or relaxosome first described nearly 30 years ago as being associated with conjugative and mobilizable plasmids.     

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.     

DNA strand invasion promoted by Escherichia coli RecT protein

The RecT protein of Escherichia coli is a DNA-pairing protein required for the RecA-independent recombination events promoted by the RecE pathway. The RecT protein was found to bind to both single-stranded DNA (ssDNA) and double-stranded DNA (dsDNA) in the absence of Mg2+. In the presence of Mg2+, RecT binding to dsDNA was inhibited drastically, whereas binding to ssDNA was inhibited only to a small extent. RecT promoted the transfer of a single-stranded oligonucleotide into a supercoiled homologous duplex to form a D (displacement)-loop. D-loop formation occurred in the absence of Mg2+ and at 1 mM Mg2+ but was inhibited by increasing concentrations of Mg2+ and did not require a high energy cofactor. Strand transfer was mediated by a RecT-ssDNA nucleoprotein complex reacting with a naked duplex DNA and was prevented by the formation of RecT-dsDNA nucleoprotein complexes. Finally, RecT mediated the formation of joint molecules between a supercoiled DNA and a linear dsDNA substrate with homologous 3'-single-stranded tails. Together these results indicate that RecT is not a helix-destabilizing protein promoting a reannealing reaction but rather is a novel type of pairing protein capable of promoting recombination by a DNA strand invasion mechanism. These results are consistent with the observation that RecE (exonuclease VIII) and RecT can promote RecA-independent double-strand break repair in E. coli.     

The ribosomal S16 protein of Escherichia coli displaying a DNA-nicking activity binds to cruciform DNA

We have recently shown that the ribosomal S16 protein of Escherichia coli is a magnesium-dependent DNase which introduces nicks into supercoiled DNA molecules [Oberto, J., Bonnefoy, E., Mouray, E., Pellegrini, O., Wikstrom, P. M. & Rouvière-Yaniv, J. (1996) Mol. Microbiol. 19, 1319-1330]. In this work we analysed the DNA-binding and DNA-nicking properties of S16 using two different approaches. Gel-retardation assays showed that S16 is a structure-specific DNA-binding protein displaying a preferential binding for cruciform DNA structures. This specific binding to cruciform DNA was further investigated using a supercoiled plasmid carrying the origin of replication of E. coli (oriC) which is an (A+T)-rich DNA region with abundant palindromic sequences susceptible of forming cruciform-like structures in vivo. We show that the nicks introduced by S16 in oriC are not randomly positioned but are precisely localised near such palindromic sequences. In addition, the nicking activity of S16 appeared to be sequence dependent since the cuts introduced by S16 occurred next to an adenine, in most cases an unpaired adenine, usually followed by a GTT sequence. Overall these experiments indicate that S16 requires a cruciform-like DNA structure to bind DNA and the presence of a particular sequence in order to introduce specific single-stranded cuts into a DNA molecule.     

Branch migration during Rad51-promoted strand exchange proceeds in either direction

The Saccharomyces cerevisiae Rad51 protein is important for genetic recombination and repair of DNA double-strand breaks in vivo and can promote strand exchange between linear double-stranded DNA and circular single-stranded DNA in vitro. However, unlike Escherichia coli RecA, Rad51 requires an overhanging complementary 3' or 5' end to initiate strand exchange; given that fact, we previously surmised that the fully exchanged molecules resulted from branch migration in either direction depending on which type of end initiated the joint molecule. Our present experiments confirm that branch migration proceeds in either direction, the polarity depending on whether a 3' or 5' end initiates the joint molecules. Furthermore, heteroduplex DNA is formed rapidly, first at the overhanging end of the linear double-stranded DNA's complementary strand and then more slowly by progressive lengthening of the heteroduplex region until strand exchange is complete. Although joint molecule formation occurs equally efficiently when initiated with a 3' or 5' overhanging end, branch migration proceeds more rapidly when it is initiated by an overhanging 3' end, i.e., in the 5' to 3' direction with respect to the single-stranded DNA.     

A novel nuclease activity from Xenopus laevis releases short oligomers from 5'-ends of double- and single-stranded DNA

BACKGROUND: Double-strand breaks in chromosomal DNA of eucaryotic cells are assumed to be repaired by mechanisms of illegitimate recombination capable of direct rejoining of the broken ends. Cell-free extracts of Xenopus laevis eggs efficiently perform these end joining reactions with any pair of noncomplementary DNA termini whose single-stranded 5'- or 3'-overhangs do not exceed a length of approximately 10 nt. RESULTS: Using hairpin-shaped oligonucleotides that allow the construction of double-strand break termini with 5'- or 3'-overhangs of defined length and sequence we show that 5'-overhangs of more than 9-10 nt are exonucleolytically resected in the extract to produce shorter 5'-overhangs that can be metabolized in the end joining reaction. 5'-recessed ends in double-stranded DNA with 3'-overhangs of more than 2nt as well as the 5'-ends of single-stranded DNA also serve as substrates for the exonuclease activity. In all cases, oligomers of about 10 nt are released from the 5'-ends. CONCLUSIONS: We describe here a novel 5'-exonuclease activity present in eggs from Xenopus laevis that reproducibly removes decameric oligonucleotides from 5'-ends of double- and single-stranded DNA. A possible function of this unusual activity is discussed in the context of homologous and illegitimate genetic recombination processes.     

Cell cycle-regulated generation of single-stranded G-rich DNA in the absence of telomerase

Current models of telomere replication predict that due to the properties of the polymerases implicated in semiconservative replication of linear DNA, the two daughter molecules have one end that is blunt and one end with a short 3' overhang. Telomerase is thought to extend the short 3' overhang to produce long single-stranded overhangs. Recently, such overhangs, or TG1-3 tails, were shown to occur on both telomeres of replicated linear plasmids in yeast. Moreover, indirect evidence suggested that the TG1-3 tails also occurred in a yeast strain lacking telomerase. We report herein a novel in-gel hybridization technique to probe telomeres for single-stranded DNA. Using this method, it is shown directly that in yeast strains lacking the TLC1 gene encoding the yeast telomerase RNA, TG1-3 single-stranded DNA was generated on chromosomal and plasmid telomeres. The single-stranded DNA only appeared in S phase and was sensitive to digestion with a single-strand-specific exonuclease. These data demonstrate that during replication of telomeres, TG1-3 tails can be generated in a way that is independent of telomerase-mediated strand elongation. In wild-type strains, these TG1-3 tails could subsequently serve as substrates for telomerase and telomere binding proteins on all telomeres.     

Processing of branched DNA intermediates by a complex of human FEN-1 and PCNA

In eukaryotic cells, a 5' flap DNA endonuclease activity and a ds DNA 5'-exonuclease activity exist within a single enzyme called FEN-1 [flap endo-nuclease and 5(five)'-exo-nuclease]. This 42 kDa endo-/exonuclease, FEN-1, is highly homologous to human XP-G, Saccharomyces cerevisiae RAD2 and S.cerevisiae RTH1. These structure-specific nucleases recognize and cleave a branched DNA structure called a DNA flap, and its derivative called a pseudo Y-structure. FEN-1 is essential for lagging strand DNA synthesis in Okazaki fragment joining. FEN-1 also appears to be important in mismatch repair. Here we find that human PCNA, the processivity factor for eukaryotic polymerases, physically associates with human FEN-1 and stimulates its endonucleolytic activity at branched DNA structures and its exonucleolytic activity at nick and gap structures. Structural requirements for FEN-1 and PCNA loading provide an interesting picture of this stimulation. PCNA loads on to substrates at double-stranded DNA ends. In contrast, FEN-1 requires a free single-stranded 5' terminus and appears to load by tracking along the single-stranded DNA branch. These physical constraints define the range of DNA replication, recombination and repair processes in which this family of structure-specific nucleases participate. A model explaining the exonucleolytic activity of FEN-1 in terms of its endonucleolytic activity is proposed based on these observations.     

A novel endonuclease from kinetoplastid hemoflagellated protozoan parasite Leishmania

A nuclease activity has been purified from the nuclei-kinetoplast fraction of Leishmania. This enzyme, termed endonuclease M (Endo M), is shown by electrophoresis in a denaturing polyacrylamide gel to be associated with a single polypeptide of molecular mass 52 kDa. Physical analysis of the enzyme indicates that it has a sedimentation coefficient S20,w of 4.5S, a Stoke's radius of 32.5 A, and a native molecular mass of 53 kDa. The final Mono Q purified Endo M possesses both DNase and RNase activities. It acts as an endonuclease by introducing random single-stranded nicks into the supercoiled DNA molecules, that often leads to its linearization due to nicking at the opposite strands, and subsequent degradation of the DNA with further incubation. Single-stranded DNA is twice preferred to double-stranded DNA as substrate. Single-stranded RNA is also degraded rapidly and is competitive as a substrate with single-stranded DNA. RNA:DNA hybrids, however, are largely resistant to the Endo M digestion.     

The carboxyl-terminal residues of Escherichia coli DNA topoisomerase III are involved in substrate binding

The nucleic acid-binding domain of Escherichia coli DNA topoisomerase III (Topo III) has been identified using a selection procedure designed to isolate inactive Topo III polypeptides. Deletion of this binding domain, contained in the carboxyl terminus of Topo III, results in a drastic reduction in the ability of the enzyme to bind to single-stranded DNA and RNA substrates. Successive truncation of the enzyme within this region results in the gradual loss of nucleic acid binding activity and in a gradual change in the mechanism of Topo III-catalyzed relaxation of negatively supercoiled DNA. The reduction of nucleic acid binding activity of the truncated polypeptides does not result in a loss of cleavage site specificity for the enzyme, suggesting that other amino acids are involved in the positioning of the nucleic acid within the nicking/closing site of the topoisomerase.     

The largest (70 kDa) product of the bacteriophage T4 DNA terminase gene 17 binds to single-stranded DNA segments and digests them towards junctions with double-stranded DNA

Bacteriophage terminases are oligomeric multifunctional proteins that bind to vegetative DNA, cut it and, together with portal proteins, translocate the DNA into preformed heads. Most terminases are encoded by two partially overlapping genes. In phage T4 they are genes 16 and 17. We have shown before that the larger of these, gene 17, can yield, in addition to a full-length 70 kDa product, several shorter peptides. At least two of these, gene product (gp) 17' and gp17", are initiated in the same reading frame as the 70 kDa gp17 from internal ribosome binding sites. Most of the shorter gp17 s contain predicted ATPase motifs, but only the largest (70 kDa) peptide has a predicted single-stranded DNA binding domain. Here we describe the DNA binding and cutting properties of the purified 70 kDa protein, expressed from two different clones containing gene 17 but no other T4 gene. Epitope-specific antibodies, which recognize several different gene 17 products in extracts of induced clones or of T4-infected cells, precipitate the purified 70 kDa gp17. When Mg2+ is chelated by EDTA this 70 kDa protein binds to single-stranded DNA, preferentially to junctions of single- and double-stranded DNA segments. It does not bind to blunt-ended double-stranded DNA. When Mg2+ is present the purified 70 kDa gp17 digests single-stranded segments preferentially up to junctions with double-stranded DNA. A 70 kDa gp17 from a P379L temperature sensitive (ts) mutant, which has lost the nuclease and ATPase activities, retains the single-stranded DNA binding activity. Taken together with earlier findings these results support a model for packaging of T4 DNA from single-stranded regions in recombinational or replicative intermediates, which occur at nearly random positions of the genome. This mechanism may be an alternative to site-specific initiation of packaging proposed by other investigators.     

High-speed separation of linear and supercoiled DNA by capillary electrophoresis. Buffer, entangling polymer, and electric field effects

Capillary electrophoresis in dilute and semidilute (slightly entangled) hydroxyethyl cellulose (HEC) is shown to separate linear double-stranded DNA (ds-DNA) and supercoiled plasmid DNA in the size range 1-16 thousand base pairs in 3 min. The mobilities of linear ds-DNA fragments are stronger functions of electric field strength and buffer concentration than the mobilities of supercoiled plasmids. The effects of HEC concentration and molecular weight are similar for both forms of DNA. The behavioral differences, which are attributed to the greater stiffness of the plasmids, can be used to define conditions that maximize resolution of supercoiled and linear ds-DNA of the same or similar number of base pairs.     

Initiator RNA of discontinuous DNA synthesis in human lymphocytes

A short RNA covalently associated with nascent DNA has been isolated after synthesis in vitro with labeled ribonucleaside triphosphates and the removal of DNA by DNAase digestion. The RNA migrates in polyacrylamide gels or chromatographs on DEAE-Sephadex columns as a relatively discrete oligonucleotide 8-11 nucleotides in length. The RNA is associated primarily with nascent DNA with stoichiometry of approximately one per DNA chain. The RNA has a triphosphate group at the 5' end and 2 or 3 deoxynucleotide residues at the 3' end that are not removed by DNAase. These results further support a role for the RNA as an initiator of discontinuous DNA synthesis. Examination of sequences present at the 3' end of the RNA using RNAase to effect transfer of 32PO4 from 32P-labeled DNA to covalently attached RNA indicates that a diverse, rather than unique, set of sequences are present in the RNA.     

Agrobacterium VirD2 protein interacts with plant host cyclophilins

Agrobacterium tumefaciens induces crown gall tumors on plants by transferring a nucleoprotein complex, the T-complex, from the bacterium to the plant cell. The T-complex consists of T-DNA, a single-stranded DNA segment of the tumor-inducing plasmid, VirD2, an endonuclease covalently bound to the 5' end of the T-DNA, and perhaps VirE2, a single-stranded DNA binding protein. The yeast two-hybrid system was used to screen for proteins interacting with VirD2 and VirE2 to identify components in Arabidopsis thaliana that interact with the T-complex. Three VirD2- and two VirE2-interacting proteins were identified. Here we characterize the interactions of VirD2 with two isoforms of Arabidopsis cyclophilins identified by using this analysis. The VirD2 domain interacting with the cyclophilins is distinct from the endonuclease, omega, and the nuclear localization signal domains. The VirD2-cyclophilin interaction is disrupted in vitro by cyclosporin A, which also inhibits Agrobacterium-mediated transformation of Arabidopsis and tobacco. These data strongly suggest that host cyclophilins play a role in T-DNA transfer.