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

The Binding of Monoclonal and Polyclonal Anti-Z-DNA Antibodies to DNA of Various Species Origin

DNA is a polymeric macromolecule that can display a variety of backbone conformations. While the classical B-DNA is a right-handed double helix, Z-DNA is a left-handed helix with a zig-zag orientation. The Z conformation depends upon the base sequence, base modification and supercoiling and is considered to be transient. To determine whether the presence of Z-DNA can be detected immunochemically, the binding of monoclonal and polyclonal anti-Z-DNA antibodies to a panel of natural DNA antigens was assessed by an ELISA using brominated poly(dG-dC) as a control for Z-DNA. As these studies showed, among natural DNA tested (Micrococcus luteus, calf thymus, Escherichiacoli, salmon sperm, lambda phage), micrococcal (MC) DNA showed the highest binding with both anti-Z-DNA preparations, and E. coli DNA showed binding with the monoclonal anti-DNA preparation. The specificity for Z-DNA conformation in MC DNA was demonstrated by an inhibition binding assay. An algorithm to identify propensity to form Z-DNA indicated that DNA from Mycobacterium tuberculosis could form Z-DNA, a prediction confirmed by immunoassay. Together, these findings indicate that anti-Z-DNA antibodies can serve as probes for the presence of Z-DNA in DNA of various species origin and that the content of Z-DNA varies significantly among DNA sources.

Deep learning approach for predicting functional Z-DNA regions using omics data

Computational methods to predict Z-DNA regions are in high demand to understand the functional role of Z-DNA. The previous state-of-the-art method Z-Hunt is based on statistical mechanical and energy considerations about B- to Z-DNA transition using sequence information. Z-DNA CHiP-seq experiment results showed little overlap with Z-Hunt predictions implying that sequence information only is not sufficient to explain emergence of Z-DNA at different genomic locations. Adding epigenetic and other functional genomic mark-ups to DNA sequence level can help revealing the functional Z-DNA sites. Here we take advantage of the deep learning approach that can analyze and extract information from large volumes of molecular biology data. We developed a machine learning approach DeepZ that aggregates information from genome-wide maps of epigenetic markers, transcription factor and RNA polymerase binding sites, and chromosome accessibility maps. With the developed model we not only verify the experimental Z-DNA predictions, but also generate the whole-genome annotation, introducing new possible Z-DNA regions, which have not yet been found in experiments and can be of interest to the researchers from various fields.

Sequence and expression analysis of gaps in human chromosome 20

The finished human genome-assemblies comprise several hundred un-sequenced euchromatic gaps, which may be rich in long polypurine/polypyrimidine stretches. Human chromosome 20 (chr 20) currently has three unfinished gaps remaining on its q-arm. All three gaps are within gene-dense regions and/or overlap disease-associated loci, including the DLGAP4 locus. In this study, we sequenced ∼99% of all three unfinished gaps on human chr 20, determined their complete genomic sizes and assessed epigenetic profiles using a combination of Sanger sequencing, mate pair paired-end high-throughput sequencing and chromatin, methylation and expression analyses. We found histone 3 trimethylated at Lysine 27 to be distributed across all three gaps in immortalized B-lymphocytes. In one gap, five novel CpG islands were predominantly hypermethylated in genomic DNA from peripheral blood lymphocytes and human cerebellum. One of these CpG islands was differentially methylated and paternally hypermethylated. We found all chr 20 gaps to comprise structured non-coding RNAs (ncRNAs) and to be conserved in primates. We verified expression for 13 candidate ncRNAs, some of which showed tissue specificity. Four ncRNAs expressed within the gap at DLGAP4 show elevated expression in the human brain. Our data suggest that unfinished human genome gaps are likely to comprise numerous functional elements.

Theoretical analysis of the stress induced B-Z transition in superhelical DNA

We present a method to calculate the propensities of regions within a DNA molecule to transition from B-form to Z-form under negative superhelical stresses. We use statistical mechanics to analyze the competition that occurs among all susceptible Z-forming regions at thermodynamic equilibrium in a superhelically stressed DNA of specified sequence. This method, which we call SIBZ, is similar to the SIDD algorithm that was previously developed to analyze superhelical duplex destabilization. A state of the system is determined by assigning to each base pair either the B- or the Z-conformation, accounting for the dinucleotide repeat unit of Z-DNA. The free energy of a state is comprised of the nucleation energy, the sequence-dependent B-Z transition energy, and the energy associated with the residual superhelicity remaining after the change of twist due to transition. Using this information, SIBZ calculates the equilibrium B-Z transition probability of each base pair in the sequence. This can be done at any physiologically reasonable level of negative superhelicity. We use SIBZ to analyze a variety of representative genomic DNA sequences. We show that the dominant Z-DNA forming regions in a sequence can compete in highly complex ways as the superhelicity level changes. Despite having no tunable parameters, the predictions of SIBZ agree precisely with experimental results, both for the onset of transition in plasmids containing introduced Z-forming sequences and for the locations of Z-forming regions in genomic sequences. We calculate the transition profiles of 5 kb regions taken from each of 12,841 mouse genes and centered on the transcription start site (TSS). We find a substantial increase in the frequency of Z-forming regions immediately upstream from the TSS. The approach developed here has the potential to illuminate the occurrence of Z-form regions in vivo, and the possible roles this transition may play in biological processes.

Closing gaps in the human genome using sequencing by synthesis

A novel method for closing non-structural gaps in the human genome assembly using 454 sequencing is presented here.

The most recent release of the finished human genome contains 260 euchromatic gaps (excluding chromosome Y). Recent work has helped explain a large number of these unresolved regions as 'structural' in nature. Another class of gaps is likely to be refractory to clone-based approaches, and cannot be approached in ways previously described. We present an approach for closing these gaps using 454 sequencing. As a proof of principle, we closed all three remaining non-structural gaps in chromosome 15.

Bias of purine stretches in sequenced chromosomes

We examined more than 700 DNA sequences (full length chromosomes and plasmids) for stretches of purines (R) or pyrimidines (Y) and alternating YR stretches; such regions will likely adopt structures which are different from the canonical B-form. Since one turn of the DNA helix is roughly 10 bp, we measured the fraction of each genome which contains purine (or pyrimidine) tracts of lengths of 10 bp or longer (hereafter referred to as 'purine tracts'), as well as stretches of alternating pyrimidines/purine (pyr/pur tracts') of the same length. Using this criteria, a random sequence would be expected to contain 1.0% of purine tracts and also 1.0% of the alternating pyr/pur tracts. In the vast majority of cases, there are more purine tracts than would be expected from a random sequence, with an average of 3.5%, significantly larger than the expectation value. The fraction of the chromosomes containing pyr/pur tracts was slightly less than expected, with an average of 0.8%. One of the most surprising findings is a clear difference in the length distributions of the regions studied between prokaryotes and eukaryotes. Whereas short-range correlations can explain the length distributions in prokaryotes, in eukaryotes there is an abundance of long stretches of purines or alternating purine/pyrimidine tracts, which cannot be explained in this way; these sequences are likely to play an important role in eukaryotic chromosome organisation.

Analytical expression of the purine/pyrimidine codon probability after and before random mutations

Recently, we proposed a new model of DNA sequence evolution (Arquès and Michel. 1990b. Bull. math. Biol. 52, 741-772) according to which actual genes on the purine/pyrimidine (R/Y) alphabet (R = purine = adenine or guanine, Y = pyrimidine = cytosine or thymine) are the result of two successive evolutionary genetic processes: (i) a mixing (independent) process of non-random oligonucleotides (words of base length less than 10: YRY(N)6, YRYRYR and YRYYRY are so far identified; N = R or Y) leading to primitive genes (words of several hundreds of base length) and followed by (ii) a random mutation process, i.e., transformations of a base R (respectively Y) into the base Y (respectively R) at random sites in these primitive genes. Following this model the problem investigated here is the study of the variation of the 8 R/Y codon probabilities RRR, ..., YYY under random mutations. Two analytical expressions solved here allow analysis of this variation in the classical evolutionary sense (from the past to the present, i.e., after random mutations), but also in the inverted evolutionary sense (from the present to the past, i.e., before random mutations). Different properties are also derived from these formulae. Finally, a few applications of these formulae are presented. They prove the proposition in Arquès and Michel (1990b. Bull. math. Biol. 52, 741-772), Section 3.3.2, with the existence of a maximal mean number of random mutations per base of the order 0.3 in the protein coding genes. They also confirm the mixing process of oligonucleotides by excluding the purine/pyrimidine contiguous and alternating tracts from the formation process of primitive genes.

Chromatin reconstitution on small DNA rings. IV. DNA supercoiling and nucleosome sequence preference

Nucleosome formation on inverted repeats or on some alternations of purines and pyrimidines can be inhibited in vitro by DNA supercoiling through their supercoiling-induced structural transitions to cruciforms or Z-form DNA, respectively. We report here, as a result of study of single nucleosome reconstitutions on a DNA minicircle, that a physiological level of DNA supercoiling can also enhance nucleosome sequence preference. The 357 base-pair minicircle was composed of a promoter of phage SP6 RNA polymerase joined to a 256 base-pair fragment containing a sea urchin 5 S RNA gene. Nucleosome formation on the promoter was found to be enhanced on a topoisomer with in vivo superhelix density when compared to topoisomers of lower or higher superhelical densities, to the nicked circle, or to the linear DNA. In contrast, nucleosomes at other positions appeared to be insensitive to supercoiling. This observation relied on a novel procedure for the investigation of nucleosome positioning. The reconstituted circular chromatin was first linearized using a restriction endonuclease, and the linear chromatin so obtained was electrophoresed as nucleoprotein in a polyacrylamide gel. The gel showed well-fractionated bands whose mobilities were a V-like function of nucleosome positions, with the nucleosome near the middle migrating less. This behavior is similar to that previously observed for complexes of sequence-specific DNA-bending proteins with circularly permuted DNA fragments, and presumably reflects the change in the direction of the DNA axis between the entrance and the exit of the particle. Possible mechanisms for such supercoiling-induced modulation of nucleosome formation are discussed in the light of the supercoiling-dependent susceptibility to cleavage of the naked minicircle with S1 and Bal31 nucleases; and a comparison between DNase I cleavage patterns of the modulated nucleosome and of another, non-modulated, overlapping nucleosome.

Inhibition and enhancement of eukaryotic gene expression by potential non-B DNA sequences

In a transient or constitutive expression assay we have examined the effect of non-B DNA sequences d(CA)40 and d(CAAAAATGCC)n on gene expression in eukaryotic cells. These sequences were cloned adjacent to the weak eukaryotic promoter (CGTATTTATTTG) and located upstream from the coding sequence of galactokinase enzyme. Recombinants were micro-injected in cultured cells (Chinese hamster fibroblasts R1610, mutant gal-K-) and expression levels have been determined. The alternating purine-pyrimidine tract found in d(CA)40 able to assume the Z-DNA conformation shows an inhibitory effect on gene expression. In addition, our results suggest a new potential role of Z-DNA motifs in vivo to stimulate recombination. The sequences d(CAAAAATGCC)n able to adopt another non-B structure, corresponding to curved (or bended) helix conformation, strongly enhance gene expression and this enhancement depends on sequence redundancy.

Inhibition and enhancement of eukaryotic gene expression by potential non-B DNA sequences

In a transient or constitutive expression assay we have examined the effect of non-B DNA sequences d(CA)40 and d(CAAAAATGCC)n on gene expression in eukaryotic cells. These sequences were cloned adjacent to the weak eukaryotic promoter (CGTATTTATTTG) and located upstream from the coding sequence of galactokinase enzyme. Recombinants were micro-injected in cultured cells (Chinese hamster fibroblasts R1610, mutant gal-K-) and expression levels have been determined. The alternating purine-pyrimidine tract found in d(CA)40 able to assume the Z-DNA conformation shows an inhibitory effect on gene expression. In addition, our results suggest a new potential role of Z-DNA motifs in vivo to stimulate recombination. The sequences d(CAAAAATGCC)n able to adopt another non-B structure, corresponding to curved or bended helix conformation, strongly enhance gene expression and this enhancement depends on sequence redundancy.

Occurrence of oligopurine.oligopyrimidine tracts in eukaryotic and prokaryotic genes

A program to analyse the length and frequency distribution of specific base tracts in genomic sequences is described. The frequency of oligopurine.oligopyrimidine tracts (R.Y. tracts) in a data base of 163 transcribed genes is analysed and compared. The complete genomes of SV40 virus, N. tobacum chloroplast, yeast 2 micron plasmid, bacteriophage lambda, plasmid pBR322 and the E. coli lac operon are also analyzed. A highly significant overrepresentation of oligopurine and oligopyrimidine tracts is observed in all eukaryotic genes examined, as well as in the chloroplast genome. The overrepresentation is evident in all gene subregions of the chloroplast, in the following order: intergenic regions, 3' downstream and 5' upstream (promoter), 5' and 3' untranslated, introns and coding regions. In genes coding for basic proteins, oligopurine rather than oligopyrimidine tracts are found on the coding stand. In prokaryotic genes only the longest R.Y. tracts (greater than or equal to 12) are found in excess, and are concentrated near regulatory regions. While a structural role for R.Y. tracts is most likely in intergenic regions, a functional role, as initiation sites for strand separation, is proposed for regulatory gene regions.

Paranemic structures of DNA and their role in DNA unwinding

A DNA structure is defined as paranemic if the participating strands can be separated without mutual rotation of the opposite strands. The experimental methods employed to detect paranemic, unwound, DNA regions is described, including probing by single-strand specific nucleases (SNN), conformation-specific chemical probes, topoisomer analysis, NMR, and other physical methods. The available evidence for the following paranemic structures is surveyed: single-stranded DNA, slippage structures, cruciforms, alternating B-Z regions, triplexes (H-DNA), paranemic duplexes and RNA, protein-stabilized paranemic DNA. The problem of DNA unwinding during gene copying processes is analyzed; the possibility that extended paranemic DNA regions are transiently formed during replication, transcription, and recombination is considered, and the evidence supporting the participation of paranemic DNA forms in genes committed to or undergoing copying processes is summarized.

Probing DNA structure and function with a multi-wavelength fluorescence confocal laser microscope

Three levels of organization in DNA structure in the interphase cell nucleus are assessed by confocal laser scanning microscopy: (i) the conformational state of the double helix; (ii) the distribution of eu- and heterochromatin; and (iii) the localization of replication complexes throughout S phase. Multi-parameter measurements were carried out in each optical section using two laser sources and combined stereoscopic reconstructions were used to assess the co-localization of nuclear components. DNA is highly polymorphic and can adopt a variety of different helical conformations as well as unusual structures (curved, cruciform, multi-stranded). We have assessed by laser scanning microscopy the presence of left-handed Z-DNA in polytene chromosomes of Diptera as well as the spatio-temporal distribution of Z-DNA binding proteins in whole-mount Drosophila embryos and ovaries. We have determined the 3-D distribution of replication sites relative to heterochromatin regions, nucleoli and nuclear membrane by using short pulses of BrdU incorporation in synchronized mouse and human fibroblasts. Replication sites were visualized with a monoclonal anti-BrdU antibody combined with DNA fluorescent staining and antibody labelling of nuclear lamin. The implications of dynamic DNA movement and structural rearrangement to the organization of the nucleus in domains are discussed.

The multiple codes of nucleotide sequences

Nucleotide sequences carry genetic information of many different kinds, not just instructions for protein synthesis (triplet code). Several codes of nucleotide sequences are discussed including: (1) the translation framing code, responsible for correct triplet counting by the ribosome during protein synthesis; (2) the chromatin code, which provides instructions on appropriate placement of nucleosomes along the DNA molecules and their spatial arrangement; (3) a putative loop code for single-stranded RNA-protein interactions. The codes are degenerate and corresponding messages are not only interspersed but actually overlap, so that some nucleotides belong to several messages simultaneously. Tandemly repeated sequences frequently considered as functionless "junk" are found to be grouped into certain classes of repeat unit lengths. This indicates some functional involvement of these sequences. A hypothesis is formulated according to which the tandem repeats are given the role of weak enhancer-silencers that modulate, in a copy number-dependent way, the expression of proximal genes. Fast amplification and elimination of the repeats provides an attractive mechanism of species adaptation to a rapidly changing environment.

Comparative analysis of alternating purine-pyrimidine tracts and potential Z-DNA sequences in DNA plant viruses

The DNAs of several plant viruses were analyzed for the presence of alternating purine-pyrimidine sequences that can potentially undergo B to Z transition. The DNA of the caulimoviruses (plant retroviruses) was compared with that of the geminiviruses, with the cDNA of an RNA plant virus, and with several computer-generated random sequences. Our analysis indicates that potential Z-DNA sites tend to be restricted in the DNA of the caulimoviruses, whereas the same does not occur significantly in the other viral DNAs examined. This result is discussed in relation to the mode of replication of the caulimoviral DNA and offers additional evidence of the existence of selection processes regulating the frequency and distribution of the Z-DNA sites in the different genomes.

A domain that assumes a Z-conformation includes a specific deletion in some cloned variants of a complex satellite

Sequence analyses show that deletions of 10 and 12 bp occur at homologous sites in a domain that is rich in alternating purines and pyrimidines (Pu/Py) in B42 and EXT, two cloned variants of a complex satellite DNA. A 3-bp deletion occurs 27 bp upstream from the site of the specific deletions in B42 and RU, a third cloned satellite variant that has not suffered the 10-bp deletion. Under torsional stress, the Pu/Py-rich domain adopts a Z-conformation as shown by (i) inhibition of cutting at a BssHII site that accounts for 2/5 of a 15-bp tract of pure Pu/Py in the domain; (ii) binding of polyclonal and monoclonal anti-Z-DNA antibodies to the domain; and (iii) antibody stabilization and subsequent relaxation of the Z-region.

Chromatin reconstitution on small DNA rings. I

Chromatin was reconstituted using the four core histones on 359 base-pair nicked and closed rings by salt dialysis and/or at physiological ionic strength by means of polyglutamic acid. The products, which consisted of mono- and dinucleosomes, were characterized by gel electrophoresis, sedimentation in sucrose gradients and high-resolution electron microscopy. The results were as follows. (1) The efficiency of the reconstitution was found first to increase with the negative linking difference of the closed rings relative to their relaxed configuration to reach a maximum for -2 turns, and then to decrease for the largest difference of -3 turns. Discrepancies between topoisomers were also observed with regard to differential formation of mono- and dinucleosomes. Topoisomer -1 reconstituted monomers easily but reconstituted dimers with difficulty, whilst this discrimination was virtually absent in the case of topoisomers -2 and -3. Moreover, mononucleosomes on the nicked ring were, with respect to their electrophoretic mobility, similar to mononucleosomes formed on topoisomer -1 but not to those on the other topoisomers, whose mobilities were greater. These features were interpreted in terms of the linking number change associated with the formation of a nucleosome monomer and dimer, approximately -1 and -2 turns, respectively. (2) Two dinucleosome subtypes were found to form in a sequential manner. Their different electrophoretic mobilities and sedimentation coefficients suggested that the early subtype is lighter, probably because of an incomplete histone complement in the second nucleosome of that subtype as a result of an impaired co-operativity in octamer assembly due to the small ring size. (3) An electron microscopic examination of the chromatin reconstituted on topoisomer -2 revealed that both mono- and dinucleosomes adopt two different, salt-dependent, morphologies each: in type I, entering and exiting DNAs do not cross, whilst they do in type II. Type I configuration is favoured in lower salt, whereas type II is favoured in higher salt. Such behaviour explains why nucleosomes in dimers were found to be always diametrically opposed on the rings rather than sometimes apposed, as would have been expected from a random deposition of the histone cores.

Compilation of DNA strand exchange sites for non-homologous recombination in somatic cells

DNA sequences of 496 somatic cell illegitimate crossing over regions were compiled and analyzed. Sites for non-homologous recombination on linear DNAs transfected into mammalian cells (Transfected Linear DNAs; TLD) were analyzed separately from the remaining illegitimate recombination regions (IRR). Trinucleotides that are preferentially cleaved by rat liver topoisomerase I in vitro (CAT, CTY, GTY, RAT where R = purine, Y = pyrimidine) were present in the 10 base pair (bp) vicinity of the cross-over sites in 92% of IRR and 93% of TLD. Multiple repeats of these trinucleotides have been observed in 39% of IRR and 38% of TLD. Runs of five or more contiguous purines (or pyrimidines on the complementary strand) were found in 26% of IRR and 14% of TLD. Adenine-Thymine rich regions of five or more bases were found in 14% of IRR and 21% of TLD. Alternating purine-pyrimidine tracks longer than four nucleotides in length were found in 11% of IRR, though only in 4% of TLD. I discuss the possible biological significance of these findings and present an appendix containing the sequences in the 10 bp vicinity of the non-homologous recombination sites analyzed.

Properties of supercoiled DNA in gel electrophoresis. The V-like dependence of mobility on topological constraint. DNA-matrix interactions

The dependence of the electrophoretic mobility of small DNA rings on topological constraint was investigated in acrylamide or agarose gels as a function of DNA size (from approximately 350 to 1400 base-pairs), gel concentration and nucleotide sequence. Under appropriate adjustment between the size of the DNA and the gel concentration, this dependence was found to be V-shaped in a limited interval around constraint O, the minimum mobility at the apex of the V being obtained for relaxed DNA. Analysis of the DNA size dependence of the V suggests that it is the result of a modulated compaction of the DNA rings by the gel matrix. Compaction appears to be maximum upon relaxation, and to decrease with increase in supercoiling. Consistent with this interpretation, gels were found to oppose structural departures from the B helix, such as Z transition and cruciform extrusion, which tend to relax the DNA molecule and make it more expanded. In contrast, when DNA size or gel concentration are large enough relative to one another, U shapes are observed instead of Vs, as a consequence of an increase in the mobility of the rings closer to relaxation. The relevance of these results to the situation of superhelical DNA in vivo is discussed. Application of the V to the measurement of the DNA helical twist is mentioned.

Immunofluorescence localization of Z-DNA in chromosomes: quantitation by scanning microphotometry and computer-assisted image analysis

Anti-Z-DNA polyclonal and monoclonal immunoglobulins raised against left-handed polynucleotides show various degrees of specificity for base sequence and substitution. Class 1 IgGs recognize all Z-DNA with equal affinity; class 2 IgGs show a preference for d(G-C)n sequences and class 3 IgGs for d(G-C)n sequences with substitutions at the C5 position of the pyrimidine. These antibodies served as probes for the localization of Z-DNA in polytene and metaphase chromosomes and in interphase chromatin by indirect immunofluorescence. A quantitative assessment of the binding of anti-Z-DNA IgGs to polytene chromosomes of Chironomus and Drosophila was made by scanning microphotometry and by computer-assisted image analysis of double immunofluorescence and DNA-specific dye fluorescence images. The three classes of antibodies bind to most of the bands in acid fixed polytene chromosomes of C. thummi; however, preferential binding of one class of antibody over another can be observed in certain regions. These differences can be quantitated by arithmetic division or subtraction of the normalized digital images. If a class 2 antibody is first bound at saturating concentrations the binding of class 1 antibody is reduced throughout most bands by 40-50%. However, the telomeres of the three large chromosomes bind greater than 10 times as much class 1 antibody as class 2 antibody, indicating that the Z-DNA tracts in these regions are comprised largely of alternating sequences containing the A X T basepair, e.g., A-C. High-resolution image analysis of class 1 and class 2 immunofluorescence patterns and the total DNA distribution from polytene chromosomes of D. melanogaster show that the two antibody distributions are very similar in a large majority of the bands, but they often deviate from the mean DNA distribution profile. Z-DNA sequences of both G-C and A-C type are detectable at all levels of ploidy from 2n to 2(13)n and in species as diverse as insects and man. We conclude that the vast majority of polytene chromosome bands (genes) contain one or a few DNA sequences with potential for undergoing the B----Z transition and contain both alternating purine-pyrimidine G-C and A-C tracts or mixed sequences. Highly heterochromatic bands and telomeres have more Z potential sequences than do other bands.

Electron microscopy of SV40 DNA cross-linked by anti-Z DNA IgG

Electron microscopy has revealed the specific binding of bivalent anti-Z DNA immunoglobulin G (IgG) to different sites on supercoiled Form I SV40 DNA. The anti-Z IgG links together left-handed regions located within individual or on multiple SV40 DNA molecules at the superhelix density obtained upon extraction. Velocity sedimentation, electrophoresis, and electron microscopy all show that two or more Z DNA sites in the SV40 genome can be intermolecularly cross-linked with bivalent IgG into high mol. wt. complexes. The formation and stability of the intermolecular antibody-DNA complexes are dependent on DNA superhelix density, as judged by three criteria: (1) relaxed circular (Form II) DNA does not react; (2) release of torsional stress by intercalation of 0.25 microM ethidium bromide removes the antibody; and (3) linearization with specific restriction endonucleases reverses antibody binding and DNA cross-linking. Non-immune IgG does not bind to negatively supercoiled SV40 Form I DNA, nor are complexes observed in the presence of competitive synthetic polynucleotides constitutively in the left-handed Z conformation; B DNA has no effect. Using various restriction endonucleases, three major sites of anti-Z IgG binding have been mapped by electron microscopy to the 300-bp region containing nucleotide sequences controlling SV40 gene expression. A limited number of minor sites may also exist (at the extracted superhelix density).