Sequences that adopt non-B-DNA conformation in form V DNA as probed by enzymic methylation

pBR322 form V DNA is a highly torsionally strained molecule with a linking number of zero. We have used sequence-specific DNA methylases as probes for B-DNA in this molecule, exploiting the inability of methylases to methylate single-stranded DNA and Z-DNA, both of which are known to occur in form V DNA. Some sequences in form V DNA were shown to be totally in the B-form, others were totally in an altered, unmethylatable conformation, while still other sites appeared to exist partly in altered and partly in normal B-conformation. Some potential Z-forming sequences (alternating pyrimidine/purine) of less than seven base-pairs were not in the Z conformation in form V DNA, whereas others did adopt an altered structure, indicating a modulating influence of flanking sequences. Furthermore, regions of imperfect alternating pyrimidine/purine structure were sometimes capable of adopting an altered structure. In addition, some regions of altered structure had no apparent Z-forming sequences, nor were they in polypurine stretches, which have also been proposed to form left-handed DNA. These non-B-DNA conformations may represent novel left-handed helical structures or sequences that become single stranded under torsional strain. Long regions of either altered (unmethylatable) DNA or B-DNA were not always observed. In fact, one region showed three transitions between B-like DNA and altered structure within 26 base-pairs.     

超螺旋DNA的碱变构研究

对超螺旋ＤＮＡ（ＤＮＡⅠ）的碱处理产物进行了琼脂糖凝胶电泳,氯化铯－溴化乙锭密度梯度超离心分析,紫外吸收光谱分析和电镜观察。实验结果表明超螺旋ＤＮＡ在碱性环境中的结构改变发生在很窄的ｐＨ范围内（ｐＨ１２．８８─１３．００）．超过ｐＨ临界点的超螺旋ＤＮＡ碱变构产物紫外吸收高于同浓度天然ＤＮＡ紫外吸收的２９％。变构产物在ＣｓＣｌ－ＥＢ密度梯度超离心中的高密度区形成稳定的区带．用透射电镜的观察表明碱变构的超螺旋ｐＢＲ３２２ＤＮＡ具有高电子密度并呈中空颗粒状,以上事实表明,ＤＮＡ在高ｐＨ下可产生一种结构有序的相对稳定的产物．这些结果意味着在碱处理过程中,超螺旋ＤＮＡ在构象上发生了改变,使其分子由扭曲线形变成球形颗粒状。根据实验事实本文对超螺旋ＤＮＡ的碱变构产物（ＤＮＡⅣ）提出一个新的结构模型──压缩模型。这个模型能更合理地解释一些实验现象。     

Left handed DNA in synthetic and topologically constrained form V DNA and its implications in protein recognition

We have investigated structural transitions in Poly(dG-dC) and Poly(dG-Me⁵dC) in order to understand the exact role of cations in stabilizing left-handed helical structures in specific sequences andthe biological role, if any, of these structures. From a novel temperature dependent Z ⇌ B transition it has been shown that a minor fluctuation in Na⁺ concentration at ambient temperature can bring about B to Z transition. Forthe first time, wehave observed a novel Z⇌B⇌Zuble transition in poly(dG-Me⁵dC) as the Na⁺ concentration is gradually increased. This suggests that a minor fluctuation in Na⁺ concentration in conjunction with methylation may transform small stretches of CG sequences from one conformational state to another. These stretches could probably serve as sites for regulation. Supercoiled formV DNA reconstituted from pBR322 and pβG plasmids have been studied as model systems, in order to understand the nature and role of left-handed helical conformation in natural sequences. A large portion of DNA in form V, obtained by reannealing the two complementary singlestranded circles is forced to adopt left-handed double helical structure due to topological constraints (L _k = 0). Binding studies with Z-DNA specific antibody and spectroscopic studies confirm the presence of left-handed Z-structure in the pβG and pβR322 form V DNA. Cobalt hexamine chloride, which induces Z-form in Poly(dG-dC) stabilizes the Z-conformation in form V DNA even in the non-alternating purine-pyrimidine sequences. A reverse effect is observed with ethidium bromide. Interestingly, both topoisomerase I and II (from wheat germ) act effectively on form V DNA to give rise to a species having an electrophoretic mobility on agarose gel similar to that of open circular (form II) DNA. Whether this molecule is formed as a result of the left-handed helical segments of form V DNA undergoing a transition to the right-handed B-form during the topoisomerase action remains to be solved.     

Tetracycline promoter mutations decrease non-B DNA structural transitions, negative linking differences and deletions in recombinant plasmids in Escherichia coli

The ability to clone a variety of sequences with varying capabilities of adopting non-B structures (left-handed Z-DNA, cruciforms or triplexes) into three loci of pBR322 was investigated. In general, the inserts were stable (non-deleted) in the EcoRI site (an untranslated region) of pBR322. However, sequences most likely to adopt left-handed Z-DNA or triplexes in vivo suffered deletions when cloned into the BamHI site, which is located in the tetracycline resistance structural gene (tet). Conversely, when the promoter for the tet gene was altered by filling-in the unique HindIII or ClaI sites, the inserts in the BamHI site were not deleted. Concomitantly, the negative linking differences of the plasmids were reduced. Also, inserts with a high potential to adopt Z-DNA conformations were substantially deleted in the PvuII site of pBR322 (near the replication origin and the copy number control region), but were less deleted if the tet promoter was insertion-mutated. The deletion phenomena are due to the capacity of these sequences to adopt left-handed Z-DNA or triplexes in vivo since shorter inserts, less prone to form non-B DNA structures, or random sequences, did not exhibit this behavior. Sequences with the potential to adopt cruciforms were stable in all sites under all conditions. These results reveal a complex interrelationship between insert deletions (apparently the result of genetic recombination), negative supercoiling, and the formation of non-B DNA structures in living Escherichia coli cells.     

Differential reactivities at restriction enzyme sites

A method has been developed to measure the rates of digestion by restriction enzymes at individual sites. This involves a simple arithmetical treatment of the integrated areas from a densitometer scan of an ethidium bromide stained gel. We have used this method to study the digestion by HpaI, HincII and SalI of pBR322 and phi X174 DNA, and the effect of various DNA binding ligands. One of the two HpaI sites in phi X174 DNA is much more sensitive to inhibition by ligands such as netropsin, which display a preference for AT base pairs, than is the other site. Inspection of the sequences flanking the restriction sites shows that the former contains a much higher proportion of AT base-pairs than dose the latter. The opposite phenomenon is observed with the two HincII sites in pBR322. This illustrates the importance of neighbouring sequences in the interaction between restriction enzymes and their cleavage sites in DNA.     

Supercondensed structure of plasmid pBR322 DNA in an Escherichia coli DNA topoisomerase II mutant

An unusual structural component, supercondensed pBR322 DNA, has been found in plasmid pBR322 DNA samples isolated from a DNA topoisomerase II mutant of Escherichia coli, SD108 (topA+, gyrB225). The supercondensed pBR322 DNA moved faster than supercoiled pBR322 DNA as a homogeneous band in agrose gels when the DNA samples were analysed by electrophoresis. The mobility of the supercondensed DNA was not substantially affected by chloroquine intercalation. The supercondensed pBR322 DNA migrated as a high density "third DNA band" when the samples were subjected to caesium chloride/ethidium bromide gradient equilibrium centrifugation. The unusual pBR322 DNA visualized by electron microscopy was a globoid-shaped particle. These observations suggest that the pBR322 plasmid can assume a tertiary structure other than a supercoiled or relaxed structure. DNA topoisomerases may be involved in the supercondensation of plasmid DNA and chromosomal DNA.     

Ethidium binding sites on plasmid DNA determined by photoaffinity labeling

Photoaffinity labeling of pBR322 with ethidium monoazide (8-azido-3-amino-5-ethyl-6-phenylphenanthridinium chloride) was used to provide evidence for the sequence specificity of ethidium binding to native DNA. DNA-drug interactions were examined at concentrations of eight covalently bound ethidium drugs per molecule of pBR322 (4363 base pairs). Restriction enzyme cutting was blocked by the covalent binding of a drug molecule at (or near) the enzyme recognition sequence. This phenomenon was observed with all restriction enzymes tested and was not limited to specific regions of the pBR322 molecule. Double-digestion experiments indicated that a drug molecule may bind 2 to 3 base pairs outside the recognition sequence and still block restriction enzyme digestion. Intact plasmid was treated with [3H]ethidium monoazide and digested with restriction enzymes. The amount of covalently-linked ethidium analog was quantitated for different restriction fragments and the G-C content of each fragment was determined from the DNA sequence. In approximately half of the fragments the drug appeared to preferentially bind at a G-C base pair. However, no preference for specific sequences such as 5'-C-G-3' was detected, as had been suggested by previous modeling studies with ethidium bromide. The other fragments were located in specific map regions of the plasmid and did not bind drug with a strict dependence on GC content suggesting that binding specificity may depend on more than one structural feature of the DNA.     

Amplification of DNA at a prophage attachment site in Haemophilus influenzae.

The Escherichia coli plasmids pBR322 and pBR327 can be taken up by Haemophilus influenzae but do not replicate in this organism; however, integration of pBR into the H. influenzae chromosome was achieved by ligation to a fragment of the Haemophilus phage S2 that carried a phage attachment site (attP). Once these sequences were integrated, they could serve as sites of recombination and amplification for homologous (pBR or phage) DNA. Amplification appeared to occur in one of two prophage sites (attB) present in the H. influenzae chromosome. The extent of amplification was different in different cells and reflected the ability of these sequences to undergo rearrangement leading to the formation of a DNA ladder. The ladder was obtained by treatment of DNA with restriction enzymes that cut outside of the inserted DNA, i.e., did not cut in the repeat sequence, and represented different numbers of repeat elements. Reversed-field gel electrophoresis was instrumental in resolving amplified structures. Inasmuch as single-cell isolates gave rise to the same ladder structure, it was assumed that amplification was under regulatory control and that it reproduced the same equilibrium of repeat structures. Transformation of E. coli with the amplified H. influenzae DNA resulted in precise excision and replication of the original monomeric plasmids. This excision was independent of the recA and recBC genes.     

Structure and Functions of the Kirsten Murine Sarcoma Virus Genome: Molecular Cloning of Biologically Active Kirsten Murine Sarcoma Virus DNA

The unintegrated closed circular form of viral DNA prepared from NIH3T3 cells infected with Kirsten murine sarcoma virus was cloned into bacterial plasmid pBR322. The closed circular DNA, which consisted of two different-sized populations, was enriched from the virus-infected cells, linearized with BamHI, and inserted into pBR322 DNA. Four different recombinant DNAs (clones 2, 4, 6, and 7) were obtained, and a physical map of each was constructed by using various restriction enzymes. Clone 4 DNA had the largest insertion, corresponding to a complete copy of the linear DNA. This suggested that this insertion contained two copies of the 0.55-kilobase pair long terminal redundant sequence. Clone 2 and clone 6 insertion DNAs had deletions of 0.2 and 0.5 kilobase pair, respectively, which mapped near the right end (3' side of viral RNA) of the linear DNA. Clone 7 DNA appeared to have a deletion of a single copy of the large terminal redundant sequence. Transfection of BALB3T3 cells with the clone 4 DNA insertion showed that this DNA had transforming activity. The efficiency of transfection with clone 4 Kirsten murine sarcoma virus DNA was enhanced eightfold by inserting EcoRI-cleaved viral DNA into the EcoRI site of pBR322. The EcoRI-inserted DNA produced foci with single-hit kinetics, suggesting that a single molecule of Kirsten murine sarcoma virus DNA can induce transformation. Results of transfections with EcoRI-inserted Kirsten murine sarcoma virus DNA cleaved with various restriction enzymes suggested that the first 3.3-kilobase pair region at the left end of the linear DNA is important for the initiation of transformation or maintenance of transformation or both.     

Structure of cloned ribosomal DNA cistrons from Bacillus thuringiensis.

A library of B. thuringiensis DNA has been prepared by using the plasmid pBR322 as a cloning vehicle and E. coli as a host cell. By screening this collection with specific probes, 17 clones were identified whose hybrid plasmids contain rRNA genes of B. thuringiensis. Several of these plasmids have been mapped with restriction endonucleases and by DNA-RNA hybridization. By using maps of overlapping fragments, we have been able to establish an overall map of the ribosomal gene cluster.     

Specific interactions between DNA left-handed supercoils and actinomycin D

The interactions between the natural cyclopentapeptide antibiotic actinomycin D (ACT) and circular pBR322 DNA have been studied by freezing the topological state of the DNA in the complex by topoisomerase I reaction. Both supercoiled and relaxed DNAs, in the complexes at low antibiotic/DNA base-pair ratios, showed a dramatic decrease in linking number that cannot be explained by taking into account only the generally accepted unwinding of 28 degrees for each ACT molecule bound. Recent results derived from the crystallographic analysis of the complex between GpC and ACT suggest that ACT could mediate non-covalent cross-links between distant sections of DNA. Bridges between ACT and different sections of the pBR322 double helix could also explain our results. Two-dimensional gel electrophoresis of ACT-relaxed pBR322 DNA complexes reveals that all supercoils induced by ACT are negative. Two models of the complexes which correspond to the stabilization of DNA crossing by one or two molecules of ACT are proposed. In both cases the ability of ACT to stabilize only DNA left-handed supercoils is derived from the chirality of ACT, when it interacts with DNA.     

Selective inhibition of restriction endonuclease cleavage by DNA intercalators

The preferred dye binding sites and the microenvironment of known nucleotide sequences within mitochondrial and plasmid pBR322 DNA was probed in a gross fashion with restriction endonucleases. The intercalating dyes, ethidium bromide and propidium iodide, do not inhibit a given restriction endonuclease equally at all of the restriction sites within a DNA molecule. The selective inhibition may be explained, in part, by the potential B to Z conformation transition of DNA flanking the restriction site and by preferred dye binding sites. Propidium iodide was found to be a more potent inhibitor than ethidium bromide and the inhibition is independent of the type of cut made by the enzyme.     

Plasmid DNA supercoiling and survival in long-term cultures of Escherichia coli: role of NaCl

The relationship between the survival of Escherichia coli during long-term starvation in rich medium and the supercoiling of a reporter plasmid (pBR322) has been studied. In aerated continuously shaken cultures, E. coli lost the ability to form colonies earlier in rich NaCl-free Luria-Bertani medium than in NaCl-containing medium, and the negative supercoiling of plasmid pBR322 declined more rapidly in the absence of NaCl. Addition of NaCl at the 24th hour restored both viability and negative supercoiling in proportion to the concentration of added NaCl. Addition of ofloxacin, a quinolone inhibitor of gyrase, abolished rescue by added NaCl in proportion to the ofloxacin added. This observation raises the possibility that cells had the ability to recover plasmid supercoiling even if nutrients were not available and could survive during long-term starvation in a manner linked, at least in part, to the topological state of DNA and gyrase activity.     

Supercoiling unwinds two-micrometer plasmid yeast DNA at the origin of replication

All studied origins of replication of DNA in Saccharomyces cerevisiae contain DNA unwinding elements. The introduction of unrestrained negative supercoiling leads to melting of the two DNA strands in DNA unwinding elements. To understand the mechanism of DNA replication it is important to know whether the most unstable region of DNA coincides with the origin of replication. Two-micrometer plasmid DNA from S. cerevisiae inserted in pBR322 was investigated by cleaving with snake venom phosphodiesterase. Its single-strand endonucleolytic activity allows cutting of negatively supercoiled DNA in the DNA unwinding elements. The sites of the venom phosphodiesterase hydrolysis were mapped by restriction enzymes. This study shows that the unwinding of the two-micrometers plasmid DNA of S. cerevisiae takes place only in the origin of replication as a result of unrestrained negative supercoiling.     

B-Z DNA junctions contain few, if any, nonpaired bases at physiological superhelical densities

The reactions of bromoacetaldehyde (BAA) with recombinant plasmids that contain sequences which can adopt left-handed Z structures or, at other locations, cruciforms were studied as a function of supercoil density. The sequence in pRW756 that undergoes a supercoil induced transition from a right to left-handed helix was (dC-dG)16 and regions near the replication origin of the pBR322 vector were converted from linearforms to cruciforms. The locations of the most nonpaired structural features were mapped by S1 nuclease cleavage of the "wedged open" duplexes after linearization of the DNAs. Three cruciforms in the pBR322 portions of the plasmids were specifically detected by BAA reaction at physiological supercoil densities (sigma = -0.067). However, the B-Z junctions did not react with BAA under these conditions although the junctions were present since the (dC-dG)16 was shown to be left-handed. Thus, the B-Z junctions have less single-stranded character than the pBR322 cruciforms (3-6 nonpaired bases) and may be fully paired. At much higher superhelical densities (sigma = -0.11-0.12), the B-Z junctions as well as the cruciforms react with BAA indicating a change in the nature of the junctions. Studies were also performed with pRW777 which harbors the mouse kappa immunoglobin sequence (dT-dG)32 . (dC-dA)32 that adopts a left-handed helix under appropriate conditions; the results were similar to those found with pRW756.     

Cloning of Herpes simplex virus 2 DNA fragments in a plasmid vector

DNA isolated from virions of Herpes simplex type 2 (HSV-2) strain 333 was digested with various restriction enzymes and joined to the EK2 plasmid vector pBR322. The viral DNA sequences present in the hybrids were analyzed by restriction enzyme mapping and hybridization to fragments of HSV-2 DNA. The collection of recombinant molecules represents approx. 75% of the HSV-2-genome. In most cases, the structure of the recombinants seemed identical to the organization of authentic fragments of HSV-2 DNA, however, a few hybrids contained rearrangements of viral and plasmid sequences.     

Recombination between bacteriophage T4 and plasmid pBR322 molecules containing cloned T4 DNA

Reciprocal recombination between T4 DNA cloned in plasmid pBR322 and homologous sequences in bacteriophage T4 genomes leads to integration of complete plasmid molecules into phage genomes. Indirect evidence of this integration comes from two kinds of experiments. Packaging of pBR322 DNA into mature phage particles can be detected by a DNA--DNA hybridization assay only when a T4 restriction fragment is cloned in the plasmid. The density of the pBR322 DNA synthesized after phage infection is also consistent with integration of plasmid vector DNA into vegetative phage genomes. Direct evidence of plasmid integration into phage genomes in the region of DNA homology comes from genetic and biochemical analysis of cytosine-containing DNA isolated from mature phage particles. Agarose gel electrophoresis of restriction endonuclease-digested DNA, followed by Southern blot analysis with nick-translated probes, shows that entire plasmid molecules become integrated into phage genomes in the region of T4 DNA homology. In addition, this analysis shows that genomes containing multiple copies of complete plasmid molecules are also formed. Among phage particles containing at least one integrated copy, the average number of integrated plasmid molecules is almost ten. A cloning experiment done with restricted DNA confirms these conclusions and illustrates a method for walking along the T4 genome.