Left-handed Z-DNA binding by the recA protein of Escherichia coli

recA binding to left-handed Z-DNA was measured using nitrocellulose filter binding assays with four DNA polymers with defined nucleotide sequences and four recombinant plasmids. Two to 7-fold preferential binding of recA to Z-DNA polymers was observed. Left-handed Z-DNA polymer binding by recA required ATP or its nonhydrolyzable analog, ATP(gamma S), while ADP inhibited binding. Complex formation with both B- and Z-forms was influenced by polymer length; recA bound longer DNAs better. recA binding to recombinant plasmids containing supercoil-stabilized Z-DNA was essentially similar to that found for the control vector; thus, no preferential binding of recA to the Z-form was observed. Comparative experiments with the rec1 protein of Ustilago maydis and the Escherichia coli recA protein were performed. In our hands, recA and rec1 have a similar capacity for binding left-handed Z-DNA polymers and for binding recombinant plasmids containing B- and/or Z-regions. recA contains a left-handed Z-DNA-stimulated ATPase activity. This activity differs from the right-handed B-DNA-stimulated activity since it is less sensitive to increasing pH. The kinetics of ATP hydrolysis in B-DNA/Z-DNA mixing experiments showed that the turnover of the Z-DNA recA complex was slower than for B-DNA suggesting that left-handed Z-DNA is more stably bound by recA. Our results are consistent with the postulate that left-handed Z-DNA is involved in genetic recombination.     

The effect of anti-Z-DNA antibodies on the B-DNA-Z-DNA equilibrium

Four different preparations of rabbit and goat anti-Z-DNA antibodies were examined to determine the effects of antibody binding on the B-DNA-Z-DNA equilibrium. One of the four antibodies, a goat IgG, caused a marked lowering in the ionic strength required for the B-DNA to Z-DNA transition in poly(dG-dC) X poly(dG-dC), shifting the midpoint from 2.25 to 2.0 M NaCl. This IgG had a more prominent high affinity antibody population than did the other goat IgG, which caused little change in the midpoint of this transition. The presence of anti-Z-DNA antibodies also reduced the degree of negative supercoiling required for the formation of Z-DNA in (dG-dC)n sequences inserted into closed circular plasmid DNA. The goat IgG with the more marked effect on the salt-induced transition also had a greater effect in favoring Z-DNA formation in negatively supercoiled plasmids. A shift toward Z-DNA formation was observed in circular dichroism measurements upon antibody binding to poly(dG-dC) X poly(dG-dC) in very low ionic strength solution as well. We propose that the stabilization of Z-DNA by antibody binding in poly(dG-dC) X poly(dG-dC) occurs cooperatively, several antibody molecules binding to a single polymer molecule and stabilizing the entire molecule in Z-DNA through their combined binding energies. The stabilization of Z-DNA by antibody binding in a supercoiled plasmid can be significant, and failure to consider this effect and to choose appropriate conditions for measurement can lead to errors in estimating when Z-DNA will form in response to negative supercoiling.     

Isolation and characterization of Z-DNA binding proteins from wheat germ

The preparation of a heterogeneous non-histone protein extract from wheat germ utilizing Br-poly(dG-dC).poly(dG-dC) (Z-DNA) affinity chromatography is described. The binding characteristics of antibodies against Z-DNA are used as a model system to define important criteria that the DNA binding behavior of a Z-DNA binding protein should display. We show that the wheat germ extract contains DNA binding proteins specific for left-handed Z-DNA by these criteria. The affinity of the proteins measured by competition experiments was approximately 10(5) greater for Br-poly(dG-dC).poly(dG-dC) (Z-DNA) than for poly(dG-dC).poly(dG-dC) (B-DNA). The affinity of the proteins for plasmid DNA increases with increasing negative superhelicity which is known to stabilize Z-DNA. The proteins are shown to compete with Z-DNA antibodies for binding to supercoiled plasmids. Finally, the affinity for two plasmids at a given superhelical density is greater for the plasmid containing an insert known to form Z-DNA than for a plasmid without the insert. The proteins exhibit a 2-3-fold greater affinity for stretches of (dC-dA)n.(dT-dG)n over stretches of (dG-dC)n.(dG-dC)n when both sequences are induced to form Z-DNA by supercoiling.     

DNA binding by dihydrofolate reductase from Lactobacillus casei

The protein-dependent retention of double-stranded DNA molecules on nitrocellulose filters has been used to show that pure dihydrofolate reductase from Lactobacillus casei has affinity for DNA. Dihydrofolate reductase will bind to end-labeled linear double-stranded DNA and to DNA in supercoiled form. Coenzymes and certain inhibitors do not affect the affinity of the protein to DNA, indicating that the DNA-binding region of the protein is distinct from the binding sites for these molecules. Comparison of the retention on filters by dihydrofolate reductase of two plasmid DNAs, differing only in a 3000-base pair insert containing the L. casei gene for dihydrofolate reductase, showed that in the presence of this DNA region lower concentrations of the protein were required to give significant retention; it is possible that a specific DNA-protein interaction underlies this effect. This presents the possibility of studying the interaction with DNA of a protein for which a crystal structure and considerable nuclear magnetic resonance data are already available.     

Interaction of the non-histone protein PS1 with some chromatin components

The binding of non-histone protein from mouse spleen chromatin located in the sites highly sensitive to micrococcal nuclease and DNA-ase I, to DNA and histones was studied. The binding of the DNA-protein complexes to nitrocellulose filters demonstrated the absence of protein binding to DNA. A highly selective binding of protein PS1 to histones H1 and H2A and to one of the non-histone proteins (presumably HMG 14) was revealed. It is concluded that protein PS1 is incorporated into chromatin by the protein-protein interactions.     

Cytosine methylation enhances Z-DNA formation in vivo.

The influence of cytosine methylation on the supercoil-stabilized B-Z equilibrium in Escherichia coli was analyzed by two independent assays. Both the M.EcoRI inhibition assay and the linking-number assay have been used previously to establish that dC-dG segments of sufficient lengths can exist as left-handed helices in vivo. A series of dC-dG plasmid inserts with Z-form potential, ranging in length from 14 to 74 base pairs, was investigated. Complete methylation of cytosine at all HhaI sites, including the inserts, was obtained by coexpression of the HhaI methyltransferase (M.HhaI) in cells also carrying a dC-dG-containing plasmid. Both assays showed that for all lengths of dC-dG inserts, the relative amounts of B and Z helices were shifted to more Z-DNA in the presence of M.HhaI than in the absence of M.HhaI. These results indicate that cytosine methylation enhances the formation of Z-DNA helices at the superhelix density present in E. coli. The B-Z equilibrium, in combination with site-specific base methylation, may constitute a concerted mechanism for the modulation of DNA topology and DNA-protein interactions.     

In situ DNA-RNA hybridization using in vivo bromodeoxyuridine-labeled DNA probe

An in vivo 5'-bromodeoxyuridine (BrdUrd) labeled DNA probe was used for in situ DNA-RNA hybridization. BrdUrd was incorporated into plasmid DNA by inoculating E. coli with Luria-Bertani (LB) culture medium containing 500 mg/L of BrdUrd. After purification of the plasmid DNA, specific probes of the defined DNA fragments, which contained the cloned insert and short stretches of the vector DNA, were generated by restriction endonuclease. The enzymatic digestion pattern of the BrdUrd-labeled plasmid DNA was the same as that of the non-labeled one. BrdUrd was incorporated in 15%-20% of the total DNA, that is, about 80% of the thymidine was replaced by BrdUrd. Picogram amounts of the BrdUrd-labeled DNA probe itself and the target DNA were detectable on nitrocellulose filters in dot-blot spot and hybridization experiments using a peroxidase/diaminobenzidine combination. The BrdUrd-labeled DNA probe was efficiently hybridized with both single stranded DNA on nitrocellulose filters and cellular mRNA in in situ hybridization experiments. Through the reaction with BrdUrd in single stranded tails, hybridized probes were clearly detectable with fluorescent microscopy using a FITC-conjugated monoclonal anti-BrdUrd antibody. The in vivo labeling method did not require nick translation steps or in vitro DNA polymerase reactions. Sensitive, stable and efficient DNA probes were easily obtainable with this method.     

Analysis of Z-DNA in fixed polytene chromosomes with monoclonal antibodies that show base sequence-dependent selectivity in reactions with supercoiled plasmids and polynucleotides

Five monoclonal anti-Z-DNA antibodies were characterized with respect to their binding of synthetic nucleic acid polymers and of supercoiled circular plasmid DNA. All of the antibodies reacted only with DNA in the Z-conformation; however, they fell into two classes on the basis of sequence specificity. One class, with broad specificity, reacted well with all sequences in the Z-form, including poly(dG-dC), poly(dG-dm5C), and poly (dG-dBr5C) in linear polymers and poly(dG-dC)n and poly[(dC-dA)n.(dT-dG)n] sequences in supercoiled plasmids. The other class bound only Z-DNA formed by poly(dG-dC). Binding of the monoclonal antibodies specifically to inserts of Z-DNA-forming sequences in plasmids was mapped directly by cross-linking of antibody to the DNA, digestion with restriction nuclease, and electrophoretic analysis of both the unbound fragments and the bound fragments recovered from immune complexes. The monoclonal antibodies were used for indirect immunofluorescence staining of Drosophila polytene chromosomes fixed by two procedures. One procedure yielded chromosomes with Z-specific antibody binding in many interbands, a few specific bands, and parts of some puffs. On chromosomes fixed by the second procedure, antibody staining appeared to follow the DNA concentration, staining all bands brightly. For each fixation procedure, chromosomes showed the same staining pattern with each of the broad specificity monoclonal antibodies that had been seen with polyclonal antibodies. The antibodies that reacted only with poly(dG-dC) and poly (dG-dC)n plasmid inserts did not stain chromosomes fixed by either protocol. We conclude that stretches of poly(dG-dC)n sequences do not contribute significantly to the presence of Z-DNA in fixed polytene chromosomes of Drosophila melanogaster.     

Chemical footprinting of the interaction between left-handed Z-DNA and anti-Z-DNA antibodies by diethylpyrocarbonate carbethoxylation

Diethylpyrocarbonate (DEPC) carbethoxylates Z-DNA to an increased extent because the reactive N-7 atoms of purine residues appear structurally more accessible on Z-DNA as opposed to B-DNA. This chemical probe was used in DEPC footprinting experiments, which confirm the specificity of binding of anti-Z-DNA monoclonal antibodies and which probe regions of close contact in this DNA-protein complex. Antibody binding to segments of Z-DNA existing in supercoiled plasmids resulted in specific protection from DEPC hyper-reactivity within the Z-DNA segment and induction of hyper-reactivity in purines lying adjacent to the Z-segment. Two different monoclonal immunoglobulin preparations, Z22 and Z44, are shown to generate specific and distinct footprint patterns when bound to the Z-helix. Binding of these antibodies was also found to affect DNA conformation within the Z-DNA segment by influencing the equilibrium between the B- and Z-helical conformations.     

Anti-Z-DNA antibody binding can stabilize Z-DNA in relaxed and linear plasmids under physiological conditions.

It is shown that anti-Z-DNA antibody binding can stabilize sequences of d(CG/GC)n and d(CA/GT)n in the Z-DNA conformation in a plasmid in the complete absence of supercoiling. This effect is quantitated by using antibody preparations of different affinities and varying concentrations. The d(CG/GC)n sequence can be stabilized under physiological conditions. This is the first demonstration that a region of Z-DNA can be stabilized by protein binding in a completely relaxed plasmid under physiological conditions. The antibody-Z-DNA complex in the relaxed plasmid is shown to be an equilibrium state and not a long-lived kinetic intermediate since specific binding of the antibody to linearized plasmids containing Z-forming sequences is observed.     

Sequence dependence of Drosophila topoisomerase II in plasmid relaxation and DNA binding

The sequence dependence of Drosophila topoisomerase II supercoil relaxation and binding activities has been examined. The DNA substrates used in binding experiments were two fragments from Drosophila heat shock locus 87A7. One of these DNA fragments includes the coding region for the heat shock protein hsp70, and the other includes the intergenic non-coding region that separates two divergently transcribed copies of the hsp70 gene at the locus. The intergenic region was previously shown to have a much higher density of topoisomerase cleavage sites than the hsp70 coding region. Competition nitrocellulose filter binding assays demonstrate a preferential binding of the intergene fragment, and that binding specificity increases with increasing ionic strength. Dissociation kinetics indicate a greater kinetic stability of topoisomerase II complexes with the intergene DNA fragment. To study topoisomerase II relaxation activity, we used supercoiled plasmids that contained the same fragments from locus 87A7 cloned as inserts. The relative relaxation rates of the two plasmids were determined under several conditions of ionic strength, and when the plasmid substrates were included in separate reactions or when they were mixed in a single reaction. The relaxation properties of these two plasmids can be explained by a coincidence of high-affinity binding sites, strong cleavage sites, and sites used during the catalysis of strand passage events by topoisomerase II. Sequence dependence of topoisomerase II catalytic activity may therefore parallel the sequence dependence of DNA cleavage by this enzyme.     

Fate of cloned bacteriophage T4 DNA after phage T4 infection of clone-bearing cells

Plasmid pBR322 replication is inhibited after bacteriophage T4 infection. If no T4 DNA had been cloned into this plasmid vector, the kinetics of inhibition are similar to those observed for the inhibition of Escherichia coli chromosomal DNA. However, if T4 DNA has been cloned into pBR322, plasmid DNA synthesis is initially inhibited but then resumes approximately at the time that phage DNA replication begins. The T4 insert-dependent synthesis of pBR322 DNA is not observed if the infecting phage are deleted for the T4 DNA cloned in the plasmid. Thus, this T4 homology-dependent synthesis of plasmid DNA probably reflects recombination between plasmids and infecting phage genomes. However, this recombination-dependent synthesis of pBR322 DNA does not require the T4 gene 46 product, which is essential for T4 generalized recombination. The effect of T4 infection on the degradation of plasmid DNA is also examined. Plasmid DNA degradation, like E. coli chromosomal DNA degradation, occurs in wild-type and denB mutant infections. However, neither plasmid or chromosomal degradation can be detected in denA mutant infections by the method of DNA--DNA hybridization on nitrocellulose filters.     

DNA plasmid transmission in yeast is associated with specific sub-nuclear localisation during cell division

Circular plasmids in yeast carrying only an origin of DNA replication (ARS) exhibit maternal inheritance bias (MIB) and are poorly transmitted from mother to daughter cell during division. A variety of different sequences that overcome MIB have been described, including centromeric sequences (CEN), telomere-associated repeats, silencer sequences and a specific system encoded by the endogenous 2 micron circle plasmid requiring the cis-acting locus STB and the proteins Rep1 and Rep2. In each case, DNA segregation between mother and daughter cells is dependent on DNA-protein interactions. Using plasmids carrying multiple copies of a lac repressor binding sequence, we have localised DNA molecules in the yeast nucleus using a green fluorescent protein (GFP)-lac repressor fusion protein. We compared GFP localised plasmids carrying a centromere sequence with plasmids based on 2 micron circle carrying or lacking the STB sequences required for their segregation. We show that GFP localised plasmid carrying the complete STB locus co-localises with the plasmid proteins Rep1 and Rep2 to discrete chromatin sites. These sites are distinct from both the telomeres and from sites of cohesin binding. Deletion of the region of STB essential for the stability of the plasmid, leads to a loss of plasmid association with chromatin, relocalisation of plasmids towards the nuclear periphery, and a decrease in the Rep1 protein associated with the plasmid. We conclude that specific plasmid localisation is likely to be important in the overcoming of MIB in yeast.     

Hysteretic behaviour of a Z-DNA-antibody complex

The amount of complex observed between Z-DNA in the supercoiled DNA from plasmid pFP332 (with d(C-G)16 cloned into pUC8) with the radiolabelled monoclonal antibody Z-D11 (with very high affinity for left-handed Z-DNA) depends on the temporal order of addition of the ligands. If the antibody is bound first a 20-30-fold higher cloroquine concentration is necessary to dissociate half of the complex compared to the case where the suprahelical density is changed first and the complex formed afterwards. This hysteretic behavior is observed for weeks and presents a kind of molecular memory system, which is based on the topological and conformational properties of DNA and the high-affinity protein binding to Z-DNA.     

DNA intermediates in transposition of phage Mu

Transposable genetic elements can insert into DNA sites that have no homology to themselves. Evidence that there is a physical linkage between a transposable element and its target DNA sequence during transposition comes from studies on bacteriophage Mu DNA transposition in which plasmids containing Mu DNA have been shown to attach to host DNA. We report the isolation of key structures, seen after induction of Mu DNA replication, after cloning lac operator into Mu DNA and using the lac repressor-operator interaction to trap Mu DNA on nitrocellulose filters. We have localized Mu sequences within these structures in the electron microscope by visualizing the lac operator-repressor interaction after binding with ferritin-conjugated antibody. This analysis shows that key structures contain replicating Mu DNA linked to non-Mu DNA and that replication can begin at either end of Mu.     

Determination of recognition-sequences for DNA-binding proteins by a polymerase chain reaction assisted binding site selection method (BSS) using nitrocellulose immobilized DNA binding protein.

We have developed a simple procedure for rapid determination of a DNA sequence recognized by a DNA binding protein based on immobilization of the protein on nitrocellulose filters. The procedure consists of the following steps: A recombinant protein with a functional DNA binding domain is expressed in E. coli. The protein is purified to homogeneity, immobilized on nitrocellulose paper, and exposed to a pool of double stranded oligonucleotides carrying in the central part a 20 bp random sequence, which is flanked by conserved sequences with restriction endonuclease recognition sites for analytical and subcloning purposes and sequences complementary to polymerase chain reaction primers. Oligonucleotides retained by the DNA-binding protein are liberated by increasing the ionic strength and used in a new binding process after amplification by the polymerase chain reaction technique. Finally the amplified product is cloned for determination of the DNA sequence selected by the DNA-binding protein. Murine Zn-finger and basic helix-loop-helix DNA binding proteins were used to demonstrate the efficiency of the method. We show that the yield of oligonucleotides binding to the protein was increased by several consecutive rounds of filter binding and amplification, and that the protein extracted a specific sequence from the pool of random oligonucleotides.