Left-handed Z-DNA

Since the Watson-Crick proposal of right-handed B-DNA, numerous studies have been devoted to the conformation of DNA. Both natural DNAs of heterogeneous sequences and synthetic DNAs are capable of adopting more than one conformation. The specific conformation a DNA adopts appears to depend mainly on its base sequence and its environmental conditions. For a given DNA, changes in environmental conditions can induce conformational transitions which occur according to cooperative or non-cooperative processes (for general reviews see Ref. 1a, b). Despite many results, molecular biologists did not put much emphasis on the polymorphism of DNA. The discovery of the intraconversion in helical sense between the right-handed B and left-handed Z conformers of DNA has brought a new interest in the polymorphism of DNA. It is now proposed that this polymorphism has important functions in biological reactions. A recent review, 'The Chemistry and Biology of Left-handed Z-DNA', by Rich et al. has just been published. We here report some of the results published in 1984 on Z-DNA.     

Polyamine-induced B-DNA to Z-DNA conformational transition of a plasmid DNA with (dG-dC)n insert.

We investigated the ability of natural polyamines putrescine, spermidine, and spermine to provoke a left-handed Z-DNA conformation in a recombinant plasmid (pDHg16) with a 23-base pair insert of (dG-dC)n.(dG-dC)n sequences. Using a monoclonal anti-Z-DNA antibody (Z22) and an enzyme-linked immunosorbent assay protocol, we found that spermidine and spermine were capable of converting pDHg16 to the Z-DNA form. The concentrations of spermidine and spermine at the midpoint of the B-DNA to Z-DNA transition were 280 and 5 microM, respectively, in buffer containing 50 mM NaCl, 1 mM sodium cacodylate, and 0.15 mM EDTA, pH 7.4. A plot of ln[Na+] versus ln [spermine4+], where [Na+] is the bulk NaCl concentration and [spermine4+] is the spermine concentration at the midpoint of the B-DNA to Z-DNA transition, gave a straight line with a slope of 1.2. Structural specificity was clearly evident in the efficacy of three spermidine homologs to induce the Z-DNA conformation in pDHg16. Putrescine and acetylspermidines had no effect on the conformation of the plasmid DNA up to a 3 mM concentration. Control experiments with the parental plasmid (pDPL6) showed no binding of the plasmid DNA with Z22. These results indicate that spermidine and spermine are capable of provoking the left-handed Z-DNA conformation in small blocks of (dG-dC)n sequences embedded in a right-handed B-DNA matrix. Since blocks of (dG-dC)n sequences are found in certain native DNAs, conformational alterations of these regions to the Z-DNA form in the presence of polyamines may have important gene regulatory effects.     

Determination of the DNA conformation of the simian virus 40 (SV40) enhancer in SV40 minichromosomes

The simian virus 40 (SV40) enhancer contains three 8-bp purine-pyrimidine alternating sequences which are known to adopt the left-handed Z-DNA conformation in vitro. In this paper, we have undertaken the determination of the DNA conformation adopted by these Z-motifs in the SV40 minichromosome. We have analyzed the presence of Z-DNA through the change in linkage which should accompany formation of this left-handed conformation. Our results indicate that, regardless of the precise moment of the viral lytic cycle at which minichromosomes are harvested and the condition of the transfected DNA, either relaxed or negatively supercoiled, none of the three Z motifs of the SV40 enhancer exist to a significant extent as Z-DNA in SV40 minichromosomes. The SV40 enhancer adopts predominantly a right-handed B-DNA conformation in vivo.     

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.     

Interaction of the Zalpha domain of human ADAR1 with a negatively supercoiled plasmid visualized by atomic force microscopy

Interest to the left-handed DNA conformation has been recently boosted by the findings that a number of proteins contain the Zα domain, which has been shown to specifically recognize Z-DNA. The biological function of Zα is presently unknown, but it has been suggested that it may specifically direct protein regions of Z-DNA induced by negative supercoiling in actively transcribing genes. Many studies, including a crystal structure in complex with Z-DNA, have focused on the human ADAR1 Zα domain in isolation. We have hypothesized that the recognition of a Z-DNA sequence by the Zα_ADAR1 domain is context specific, occurring under energetic conditions, which favor Z-DNA formation. To test this hypothesis, we have applied atomic force microscopy to image Zα_ADAR1 complexed with supercoiled plasmid DNAs. We have demonstrated that the Zα_ADAR1 binds specifically to Z-DNA and preferentially to d(CG)_n inserts, which require less energy for Z-DNA induction compared to other sequences. A notable finding is that site-specific Zα binding to d(GC)₁₃ or d(GC)₂C(GC)₁₀ inserts is observed when DNA supercoiling is insufficient to induce Z-DNA formation. These results indicate that Zα_ADAR1 binding facilities the B-to-Z transition and provides additional support to the model that Z-DNA binding proteins may regulate biological processes through structure-specific recognition.     

Non-contiguous regions of Z-DNA in a DNA dodecamer.

The conformation of the self-complimentary DNA dodecamer d(br5CGbr5CGAATTbr5CGbr5CG) has been investigated in a variety of salt and solvent conditions by one and two-dimensional 1H NMR. In low salt aqueous solutions, the molecule forms a regular B-DNA structure similar to the unmodified dodecamer. However, in aqueous solution containing high salt concentration and methanol, the dodecamer adopts a structure in which the br5CGbr5CG ends of the molecule are in a Z-DNA like conformation and the AATT region is neither standard B-DNA nor Z-DNA. The implications of these results for the structure of junctions between B and Z-DNA and the sequence specificity of Z-DNA are discussed.     

Nonalternating purine pyrimidine sequences can form stable left-handed DNA duplex by strong topological constraint

In vivo, left-handed DNA duplex (usually refers to Z-DNA) is mainly formed in the region of DNA with alternating purine pyrimidine (APP) sequence and plays significant biological roles. It is well known that d(CG)_n sequence can form Z-DNA most easily under negative supercoil conditions, but its essence has not been well clarified. The study on sequence dependence of Z-DNA stability is very difficult without modification or inducers. Here, by the strong topological constraint caused by hybridization of two complementary short circular ssDNAs, left-handed duplex part was generated for various sequences, and their characteristics were investigated by using gel-shift after binding to specific proteins, CD and T_m analysis, and restriction enzyme cleavage. Under the strong topological constraint, non-APP sequences can also form left-handed DNA duplex as stable as that of APP sequences. As compared with non-APP sequences, the thermal stability difference for APP sequences between Z-form and B-form is smaller, which may be the reason that Z-DNA forms preferentially for APP ones. This result can help us to understand why nature selected APP sequences to regulate gene expression by transient Z-DNA formation, as well as why polymer with chirality can usually form both duplexes with left- or right-handed helix.     

Enantioselective binding of chiral 1,14-dimethyl[5]helicene–spermine ligands with B- and Z-DNA

Duplex DNA adopts a right-handed B-DNA conformation under physiological conditions. Z-DNA, meanwhile, has a left-handed helical structure and is in equilibrium with right-handed B-DNA. We recently reported that the bisnaphthyl maleimide–spermine conjugate (1) induced a B- to Z-DNA transition with high efficiency at low salt concentrations. It was also found that the bisnaphthyl ligand (1) spontaneously transformed into the corresponding [5]helicene derivative (2). Because [5]helicene 2 can potentially be chiral and because the chiral discrimination of B- and Z-DNA is also of interest, we became interested in whether enatiomerically pure [5]helicene–spermine conjugates might discriminate the chirality of B- or Z-DNA. In this study, we have demonstrated an efficient synthesis of chiral DNA-binding ligands by the conjugation of a [5]helicene unit with a spermine unit. These chiral helicene ligands exhibited recognition of B- and Z-DNA, with (P)-3 displaying preference for B-DNA and (M)-3 for Z-DNA. The characteristic features of the helicene–spermine ligands developed in this study include two points: the cationic spermine portion produces electrostatic interactions along the phosphate backbone of the minor groove, and the helicene forms complexes in an end-stacking mode. Such binding modes, together with the thermodynamic parameters, account for the mode of chiral recognition of (P)- and (M)-3 for B- and Z-DNA.     

Concordance of experimentally mapped or predicted Z-DNA sites with positions of selected alternating purine-pyrimidine tracts.

The recent electronmicroscopic and biochemical mapping of Z-DNA sites in phi X174, SV40, pBR322 and PM2 DNAs has been used to determine two sets of criteria for identification of potential Z-DNA sequences in natural DNA genomes. The prediction of potential Z-DNA tracts and corresponding statistical analysis of their occurrence have been made on a sample of 14 DNA genomes. Alternating purine and pyrimidine tracts longer than 5 base pairs in length and their clusters (quasi alternating fragments) in the 14 genomes studied are under-represented compared to the expectation from corresponding random sequences. The fragments [d(G X C)]n and [d(C X G)]n (n greater than or equal to 3) in general do not occur in circular DNA genomes and are under-represented in the linear DNAs of phages lambda and T7, whereas in linear genomes of adenoviruses they are strongly over-represented. With minor exceptions, potential Z-DNA sites are also under-represented compared to random sequences. In the 14 genomes studied, predicted Z-DNA tracts occur in non-coding as well as in protein coding regions. The predicted Z-DNA sites in phi X174, SV40, pBR322 and PM2 correspond well with those mapped experimentally. A complete listing together with a compact graphical representation of alternating purine-pyrimidine fragments and their Z-forming potential are presented.     

Differential immunoreactivity for Z-DNA in rat myoblast nuclei during their terminal differentiation

L6 myoblasts in vitro accomplish the process of terminal differentiation from dividing mononucleated cells to quiescent plurinucleated myotubes, synthesizing muscle-specific proteins. They have been tested, using paraformaldehyde and acetic acid fixations and immunocytochemical techniques, for the presence of Z-DNA at different stages: namely after 3, 5 and 8-9 days of culture. The nuclei of the actively dividing 3-day myoblasts were strongly Z-DNA and B-DNA-positive. The inhibition of replication by araC did not diminish the reaction. In the myotubes, the nuclei became Z-DNA-negative but were still B-DNA-positive. In contrast, the nuclei of a non-fusing alpha-amanitin-resistant mutant (Ama102) stayed Z-DNA-positive. These results tend to show that during the process of terminal differentiation Z-DNA either becomes less accessible or is present in undetectable amounts. In circular DNAs, it has been shown that the presence of Z-DNA depends on their negative supercoiling. In addition, the presence of closed superhelical loops of nuclear DNA has been demonstrated in several mammalian cell types; moreover, the density of DNA topological turns in these loops varies during cellular differentiation and malignant transformation. The relationship between these results and ours is discussed.     

Cooperative chiral order in the B-Z transition in random sequences of DNA.

We present a theory for cooperative chiral order in the transition between right-handed B-DNA and left-handed Z-DNA. This theory, based on the random-field Ising model, predicts the characteristic length scale of Z-DNA segments. This length scale depends on whether the DNA is a homopolymer or a random sequence: it is approximately 4000 nucleotides in a homopolymer but only approximately 25 nucleotides in a random sequence. These theoretical results are consistent with experiments on DNA homopolymers and random sequences.     

Z—DNA及其生物学功能

Z-DNA是一种处于高能状态、不稳定的DNA分子构象。形成Z-DNA的原因有很多：首先,转录过程中,移动的RNA聚合酶在模板DNA的5’端产生负超螺旋扭曲力,导致Z-DNA的形成;其次,含有d（GC）。序列的核酸分子在高浓度的NaCl、[Co（NH3）6]^2＋盐溶液中也能够形成Z-DNA;最后,化学修饰也可以使DNA产生稳定的Z-DNA。Z-DNA是在体外首先发现的,但随着研究的不断深入,发现Z-DNA在体内也广泛存在并可能具有功能的多样性,包括参与基因表达调控、染色体断裂、基因重组、抗病毒、病毒发生等生物学过程。     

Reaction path ensemble of the B–Z-DNA transition: a comprehensive atomistic study

Since its discovery in 1979, left-handed Z-DNA has evolved from an in vitro curiosity to a challenging DNA structure with crucial roles in gene expression, regulation and recombination. A fundamental question that has puzzled researchers for decades is how the transition from B-DNA, the prevalent right-handed form of DNA, to Z-DNA is accomplished. Due to the complexity of the B–Z-DNA transition, experimental and computational studies have resulted in several different, apparently contradictory models. Here, we use molecular dynamics simulations coupled with state-of-the-art enhanced sampling techniques operating through non-conventional reaction coordinates, to investigate the B–Z-DNA transition at the atomic level. Our results show a complex free energy landscape, where several phenomena such as over-stretching, unpeeling, base pair extrusion and base pair flipping are observed resulting in interconversions between different DNA conformations such as B-DNA, Z-DNA and S-DNA. In particular, different minimum free energy paths allow for the coexistence of different mechanisms (such as zipper and stretch–collapse mechanisms) that previously had been proposed as independent, disconnected models. We find that the B–Z-DNA transition—in absence of other molecular partners—can encompass more than one mechanism of comparable free energy, and is therefore better described in terms of a reaction path ensemble.     

Synthesis, structure and thermodynamic properties of 8-methylguanine-containing oligonucleotides: Z-DNA under physiological salt conditions.

Various oligonucleotides containing 8-methylguanine (m8G) have been synthesized and their structures and thermodynamic properties investigated. Introduction Of M8G into DNA sequences markedly stabilizes the Z conformation under low salt conditions. The hexamer d(CGC[M8G]CG)2 exhibits a CD spectrum characteristic of the Z conformation under physiological salt conditions. The NOE-restrained refinement unequivocally demonstrated that d(CGC[m8G]CG)2 adopts a Z structure with all guanines in the syn conformation. The refined NMR structure is very similar to the Z form crystal structure of d(CGCGCG)2, with a root mean square deviation of 0.6 between the two structures. The contribution of m8G to the stabilization of Z-DNA has been estimated from the mid-point NaCl concentrations for the B-Z transition of various m8G-containing oligomers. The presence of m8G in d(CGC[m8G]CG)2 stabilizes the Z conformation by at least deltaG = -0.8 kcal/mol relative to the unmodified hexamer. The Z conformation was further stabilized by increasing the number of m8Gs incorporated and destabilized by incorporating syn-A or syn-T, found respectively in the (A,T)-containing alternating and non-alternating pyrimidine-purine sequences. The results suggest that the chemically less reactive m8G base is a useful agent for studying molecular interactions of Z-DNA or other DNA structures that incorporate syn-G conformation.     

Changes in DNA conformation induced by gamma irradiation in the presence of copper

Gamma irradiation of DNA solutions containing copper causes changes in DNA conformation in oligonucleotides and in natural and synthetic DNAs. Diagnostic for these conformational changes is a ubiquitous 187-nm peak in the circular dichroism (CD) difference spectrum that has been predicted for a transformation from a right-handed to a left-handed helical DNA conformation. Changes in CD are correlated with changes in the UV spectrum. Reduction of DNA-bound Cu(II) to Cu(I) with ascorbic acid produces similar changes in CD spectra. These changes can be produced by the peroxy radical anion (O2*-) and the OH radical in the presence of copper. O2*- is approximately twice as efficient as *OH in initiating these changes in natural DNA. The changes in DNA conformation induced by ionizing radiation are remarkable in that they are dependent on the copper-ion concentration in a highly nonlinear manner at low copper concentrations and are not observed in the absence of copper ions. Possible implications of our results for radiobiological and oxidative damage in the cell nucleus are discussed.     

A two B-Z junction containing DNA resolves into an all right-handed double-helix

Natural and artificial oligonucleotides are capable of assuming many different conformations and functions. Here we present results of an NMR restrained molecular modelling study on the conformational preferences of the modified decanucleotide d((m)C1G2(m)C3G4C5(L)G6(L)(m)C7G8(m)C9G10) .d((m)C11G12(m)C13G14C15(L)G (L)16(m)C17-G18(m)C19G20 ) which contains L deoxynucleotides in its centre. This chimeric DNA was expected to form a right-left-right-handed B-type double-helix (BB*B) at low salt concentration. Actually, it matured into a fully right-handed double helix with its central C(L)pG(L) core forming a right-handed Z-DNA helix embedded in a B-DNA matrix (BZ*B). The interplay between base-base and base-sugar stackings within the core and its immediately adjacent residues was found to be critical in ensuring the stabilisation of the right-handed helix. The structure could serve as a model for the design of antisense oligonucleotides resistant to nucleases and capable of hybridising to natural DNAs and RNAs.     

Non-B DNA conformations, mutagenesis and disease

Recent discoveries have revealed that simple repeating DNA sequences, which are known to adopt non-B DNA conformations (such as triplexes, cruciforms, slipped structures, left-handed Z-DNA and tetraplexes), are mutagenic. The mutagenesis is due to the non-B DNA conformation rather than to the DNA sequence per se in the orthodox right-handed Watson-Crick B-form. The human genetic consequences of these non-B structures are approximately 20 neurological diseases, approximately 50 genomic disorders (caused by gross deletions, inversions, duplications and translocations), and several psychiatric diseases involving polymorphisms in simple repeating sequences. Thus, the convergence of biochemical, genetic and genomic studies has demonstrated a new paradigm implicating the non-B DNA conformations as the mutagenesis specificity determinants, not the sequences as such.