Z-DNA immunoreactivity in fixed metaphase chromosomes of primates

Z-nucleic acids: Uncovering the functions from past to present

Since Z-nucleic acid was identified in the 1970s, much is still unknown about its biological functions and nature in vivo. Recent studies on adenosine deaminase acting on RNA 1 (ADAR1) and Z-DNA-binding protein 1 (ZBP1) have highlighted its function in immune responses. Specifically, Z-RNAs, either endogenous or induced by viral infection, are sensed by ZBP1 and activate necroptosis. Z-RNAs act as the stimuli that induce innate immune responses through various pathways, including melanoma differentiation-associated protein 5 (MAD5)-mitochondrial antiviral-signaling protein (MAVS)-mediated type I IFN activation and proteinase kinase R (PKR)-dependent integrated stress response, and their immunostimulatory potential is curtailed by RNA editing conducted by ADAR1. Aberrant immune responses induced by Z-RNAs are associated with human diseases. They also induce pathogenesis in mice. Unlike Z-RNAs, the biological functions of Z-DNAs were barely studied, especially in mammals. Moreover, the origin or sequence preference of Z-nucleic acids requires further investigation. Such knowledge will expand our understanding of Z-nucleic acids, including from which genomic loci and under which circumstances they form, and the mechanisms by which they participate in the physiological activities. In this review, we provide insights in Z-nucleic acid research and highlight the unsolved puzzles.

Sensing of viral and endogenous RNA by ZBP1/DAI induces necroptosis

Nucleic acids are potent triggers for innate immunity. Double‐stranded DNA and RNA adopt different helical conformations, including the unusual Z‐conformation. Z‐DNA/RNA is recognised by Z‐binding domains (ZBDs), which are present in proteins implicated in antiviral immunity. These include ZBP1 (also known as DAI or DLM‐1), which induces necroptosis, an inflammatory form of cell death. Using reconstitution and knock‐in models, we report that mutation of key amino acids involved in Z‐DNA/RNA binding in ZBP1's ZBDs prevented necroptosis upon infection with mouse cytomegalovirus. Induction of cell death was cell autonomous and required RNA synthesis but not viral DNA replication. Accordingly, ZBP1 directly bound to RNA via its ZBDs. Intact ZBP1‐ZBDs were also required for necroptosis triggered by ectopic expression of ZBP1 and caspase blockade, and ZBP1 cross‐linked to endogenous RNA. These observations show that Z‐RNA may constitute a molecular pattern that induces inflammatory cell death upon sensing by ZBP1.

Patterns of C-heterochromatin and telomeric DNA in two representative groups of small apes, the genera Hylobates and Symphalangus

The course of chromosome evolution in small apes is still not clear, though painting analyses have opened the way for elucidating the puzzle. Even the C-banding pattern of the lar-group of gibbons (the genus Hylobates) is not clarified yet, although our previous studies suggested that lar-group gibbons have a unique C-banding pattern. We therefore made observations to establish C-banded karyotypes of the agile gibbons included in the lar-group. The data were compared with those of siamangs (the genus Symphalangus), which carry distinctive C-bands, to determine the chromosomal patterns in each group. C-banded chromosomes of agile gibbons showed several terminal, interstitial and paracentric bands, whose patterns are specific for each chromosome, whereas the C-bands of siamangs were located only at the terminal and centromeric regions in most chromosomes. Moreover, the C-bands of agile gibbons and siamangs were shown to be G+C-rich and A+T-rich DNA, respectively, by DAPI/C-band sequential staining. Additionally, PRINS labelling with a telomere primer revealed that agile gibbons have telomeric DNA only at chromosome ends where there is no C-band (non-telomeric heterochromatin), whereas the telomeric DNA of siamangs is located in the terminal C-banded regions (telomeric heterochromatin). Although the evolutionary mechanisms in small apes are still unknown, C-banding patterns and distribution of telomeric DNA sequences should provide valuable data to deduce the evolutionary pathways of small apes.

C-banding plus fluorochrome staining shows differences in C-, G-, and R-bands in human and mouse metaphase chromosomes

C-banded slides stained with DAPI or chromomycin A3 show different banding patterns between human and L929 mouse cell line metaphase chromosomes, which are also different from those obtained with standard Giemsa C-banding or fluorochrome staining. Human metaphase chromosomes pretreated for C-banding and stained with DAPI show simultaneous C- and DA-DAPI banding patterns, whilst the mouse metaphase chromosomes show both C-banding and G/Q banding like patterns. However, the chromomycin A3 staining of pre-C-banded metaphase chromosomes reveals conspicuous R-banding in man that is absent in mouse. Chromatin species-specific structural factors would explain these results, which prevent simple comparisons of R-, G-, and C-bands among different organisms. The markers induced by this technique may be of practical use for chromosome identification in human-mouse somatic cell hybridization cultures.

The non-B-DNA structure of d(CA/TG)n does not differ from that of Z-DNA

A number of recent studies have shown that simple repetitive d(CA/TG) dinucleotide sequences adopt a left-handed non-B-DNA structure under negative superhelical stress. The pattern of chemical reactivities and the helical parameters observed for these sequences differ significantly from those of standard Z-DNA. In this study, the data for two naturally occurring d(CA/TG)n sequences are reevaluated by a statistical mechanics treatment of the B- to Z-DNA transition. The behavior of these sequences under negative superhelical stress is accurately simulated by this model, including the multiple and discrete transitions observed for the rat prolactin promoter. Furthermore, the average helical twist for the left-handed structure of d(CA/TG)n deviates < 2% from that expected for standard Z-DNA. Finally, the predicted distribution of the junctions between B- and Z-DNA are shown to account for differences observed in the patterns of chemical reactivity of d(CA/TG)n and d(CG)n. Thus, no new left-handed structure that differs from Z-DNA is needed to describe the supercoil-induced conformation in d(CA/TG)n sequences.

Patterns of immunocytochemically detected Z-DNA in the recrudescing testicular epithelium of the Turkish hamster (Mesocricetus brandti)

Z-DNA has been considered a labile but essential structural form of DNA in recombination and gene expression, two significant activities in mammalian seminiferous epithelium. The present study has utilized the recrudescing testes of Mesocricetus brandti to study in detail the potential Z-DNA sites in specific testicular cell types as detected by an immunoprobe. Testicular regression was physiologically induced by modifying environmental photoperiods and/or temperature. Partial atrophy of seminiferous epithelium occurred in all experimental groups but Sertoli cells persisted throughout regression. Recrudescence of testicular activity was marked in all experimental groups by characteristic sequences of reappearance of potential Z-DNA sites to a final positive or negative mature state of the cell type. It is suggested that Z-DNA is a functionally important from of DNA in many cell types of the active seminiferous epithelium of the Turkish hamster, and perhaps other mammals.

Immunofluorescent localization of triplex DNA in polytene chromosomes of Chironomus and Drosophila

Purine.pyrimidine (pur.pyr) DNA tracts are prevalent in eukaryotic genomes. They can adopt a triplex conformation in vitro under conditions that may exist in vivo, suggesting that triplex (H-) DNA may exist naturally in chromosomes. To explore this possibility and gain insight concerning potential functions, the distribution of triplex DNA was studied in fixed polytene chromosomes of Chironomus tentans and Drosophila melanogaster by indirect immunofluorescence microscopy using an anti-triplex DNA monoclonal antibody (Jel 318). Chromosomes stained with this antibody exhibited immunopositive regions corresponding to condensed chromatin bands; interbands were less immunofluorescent. These results imply that there is more triplex DNA in bands than in interbands. In Chironomus, nucleolar organizer regions and Balbiani rings were immunonegative, indicating that triplex DNA is not present in decondensed, transcriptionally active chromatin. A few specific bands in both Chironomus and Drosophila were intensely immunofluorescent. In Drosophila, one such region was 81F on chromosome 3R. Competition during staining with exogenously added sequences corresponding to a constituent 1.672 g/cm3 satellite DNA in region 81F failed to abolish the immunofluorescence, suggesting that the satellite DNA does not fortuitously react with Jel 318 and implying that unidentified pur.pyr sequences forming triplex DNA are also present at this location. Region 81F exhibits ectopic pairing with nonrelated chromosome regions that have also proven to be intensely immunopositive; this suggests that the formation of triplex DNA between common, shared pur.pyr sequences in these otherwise nonhomologous bands might account for the ectopic pairing phenomenon. Together with our previous results, these data are consistent with the hypothesis that triplex DNA may play a role in chromosome organization by participating in regional chromatin condensation.

Location of B- and Z-DNA in the chromosomes of a primitive eukaryote dinoflagellate

The usual conformation of DNA is a right-handed double helix (B-DNA). DNA with stretches of alternating purine-pyrimidine (G-C or A-T) can form a left-handed helix (Z-DNA). The transition B----Z, facilitated by the presence of divalent cations, cytosine methylation, or constraints on DNA such as superhelicity may play a role in the regulation of gene expression and/or in DNA compaction (Zarling, D. A., D. J. Arndt-Jovin, M. Robert-Nicoud, L. P. McIntosh, R. Tomae, and T. M. Jovin. 1984. J. Mol. Biol. 176:369-415). Divalent cations are also important in the structure of the quasi-permanently condensed chromosomes of dinoflagellate protists (Herzog, M., and M.-O. Soyer. 1983. Eur. J. Cell Biol. 30:33-41) which also have superhelicity in their DNA. The absence of histones in dinoflagellate chromosomes suggest that the search for Z-DNA sequences might be fruitful and could provide one indication of the physiological role of this particular DNA conformation. We report a complete immunofluorescent and immunogold analysis of the nuclei of the dinoflagellate Prorocentrum micans E. using monoclonal and polyclonal anti-B and anti-Z-DNA antibodies. Positive labeling was obtained with immunofluorescence using squash preparations and cryosections, both of which showed the intranuclear presence of the two DNA conformations. In ultrathin sections of aldehyde-prefixed, osmium-fixed, and epoxy-embedded cells, we have localized B-DNA and Z-DNA either with single or double immunolabeling using IgG labeled with 5- and 7-nm gold particles, respectively. Chromosomal nucleofilaments of dividing or nondividing chromosomes, as seen in ultrathin sections in their arch-shaped configuration, are abundantly labeled with anti-B-DNA antibody. Extrachromosomal anti-B-DNA labeling is also detected on the nucleoplasm that corresponds to DNA loops; we confirm the presence of these loops previously described external to the chromosomes (Soyer, M.-O., and O. K. Haapala. 1974. Chromosoma (Berl.). 47:179-192). B labeling is also visible in the nucleolus organizer region (NOR) and in the fibrillo-granular area (containing transcribing rDNA) of the nucleolus. Z-DNA was localized in limited areas inside the chromosomes, often at the periphery and near the segregation fork of dividing chromosomes. In the nucleolus, Z-DNA is observed only in the NOR area and never in the fibrillo-granular area. For both types of antibody experiments, controls using gold-labeled IgG without primary antibody were negative. A quantitative evaluation of the distribution of the gold-labeled IgG and a parametric test support the validity of these experiments.(ABSTRACT TRUNCATED AT 400 WORDS)

Regional differences in immunostainability of isolated metaphase chromosomes of Indian muntjac with anti-Z-DNA antibody

The distribution of Z-form DNA along the length of metaphase chromosomes of Indian muntjac was studied by indirect immunofluorescence procedures using an antibody specific to the Z-DNA conformation. Several fixation conditions were compared for reproducible detection of Z-DNA in isolated metaphase chromosomes. Fixation of chromosomes with 45% acetic acid alone gave reproducible reactivity with the antibody. When fixation was done either with Carnoy's solution (3:1 methanol:acetic acid) or with 75% alcohol alone, the antibody binding was at background level. Acetic acid-fixed chromosomes exhibited intense fluorescence both at C-band heterochromatin and at nucleolus organizer regions (NORs). The euchromatic regions had weakly, but clearly, stained bands, which were quite similar to the chromomycin A3 R-bands. After treatment with topoisomerase I, the immunofluorescence at NORs and R-bands disappeared, but only a slight decrease in immunofluorescence intensity was observed at C-band regions. We suggest that this difference in the immunoreactivity of NORs and R-bands from C-bands reflects a difference in gene activity among these regions. Possible molecular mechanisms involved in Z-DNA immunoreactivity are discussed, based on SDS-polyacrylamide gel electrophoretic analysis of chromosomal proteins after extraction of metaphase chromosomes with different fixative solutions.

Immunofluorescent staining of mammalian nuclei and chromosomes with a monoclonal antibody to triplex DNA

Triplex DNA is an unusual conformation of DNA formed when two pyrimidine nucleotide strands share a common purine strand. A monoclonal antibody, demonstrated by numerous criteria to be specific for triplex DNA, was used to investigate the presence and distribution of this unique DNA configuration in nuclei and chromosomes of mouse LM cells and human lymphocytes. Indirect immunofluorescence microscopy revealed that constitutive heterochromatin in acetic-methanol fixed mouse nuclei was usually, but not always immunofluorescent, suggesting possible cell cycle related variations in the amount of triplex DNA or its accessibility in this condensed chromatin. In fixed mouse and human chromosomes, there was a positive correlation between immunofluorescent staining patterns, Hoechst 33258 banding, and G- and/or C-banding patterns. Unfixed, isolated mouse chromosomes also reacted positively with the antibody, particularly when they were gently decondensed by exposure to low ionic conditions at neutral pH. This result indicates that fixation is not mandatory for antibody staining, suggesting that some mammalian chromosomal DNA may be naturally organized in a triplex configuration. However, there is a possibility that fixation may facilitate the formation of additional triplex DNA complexes in potential sequences or expose previously inaccessible triplex DNA. The precise correspondence between the immunofluorescent patterns produced by anti-triplex DNA antibodies and G- and C-bands known to represent regions of chromatin condensation, suggests a potential role of triplex DNA in chromosome structure and regional chromatin condensation.

Detection of Z DNA binding proteins in tissue culture cells

A gel electrophoresis DNA binding assay to detect Z DNA binding proteins has been developed utilising [32P] labelled poly [d(G-C)] which was converted to the Z form by incubation in 100 microM Co(NH3)6Cl3. The parameters of the assay were established using a Z DNA antibody as a model system and then applied to extracts of Hela and BHK21 cells. Using an anti-Z DNA antibody conditions were established which allowed resolution of antibody-DNA complexes and free DNA in the presence of 100 microM Co(NH3)6Cl3. The inclusion of unlabelled complementary homopolymers eliminated non-specific binding to the labelled Z-DNA probe. Competition experiments demonstrated that the assay was highly specific for double stranded non-B DNA. Application of the technique to extracts of mammalian cells demonstrated that human and hamster cells contain Z-DNA binding proteins; further characterisation by a blotting technique indicated that a 56,000 molecular weight cell protein preferentially binds Z-DNA.

IR and UV studies on stability and conformations of short DNA duplexes containing a no-base residue: coexistence of B and Z conformations

Tridecamers containing a central no-base residue (X) have been synthesized and hybridized to their complementary strands, so as to constitute duplexes consisting of two hexamers separated by central mismatched X-A or X-T pairs. The effect of the introduction of this deoxyribose derivative on duplex stability was investigated by measuring UV absorbance as a function of salt concentration and temperature. As expected, the duplexes containing the abnormal base pairs (X-T and X-A) are less stable when compared to the totally complementary duplexes (A-T and T-A). The X-T mismatched duplex shows the most unstable thermodynamical behaviour. The conformational changes of these duplexes were studied by IR spectroscopy in condensed phase as a function of water content. At high relative humidity, the IR spectra show that these tridecamers form B-type double stranded duplex structures. If the water content is decreased, only the duplexes m5CGm5CGCTXAGCTTC GCGCGAATCGAAG and, to a lesser degree, m5CGm5CGCTXAGCTTC GCGGCATTCGAAG undergo a partial B---Z transition involving the methylated hexamer, the conformation of the second segment remaining of the B type. These results show that only one apurinic residue leads to a flexible junction between B and Z forms in a short duplex containing 5-methyl-2'-deoxycytidines.

Z DNA and loop structures by immunoelectronmicroscopy of supercoiled pRW751, a plasmid containing left-handed helices

Single and multiple loops were seen when the plasmid pRW751 was allowed to react with anti-Z-DNA or with a Z-specific cross-linking agent. Loop formation was dependent upon negative supercoiling and the presence of Z-specific antibody or cross-linking agent. Restriction enzyme mapping located 18 sites at the bottoms of loops, in addition to the two (dG-dC)n inserts of pRW751. No more than 5 loops were seen in any of the measured molecules; thus, not all potential Z-sites assume the Z conformation at any particular time. Stretches of alternating purine-pyrimidine sequences occur at all 20 sites. Almost all of the Z sites could be mapped to regions located at the beginnings or ends of reading frames or at various regulatory sites. Our findings support the concept that supercoiling brings distant sequences to within 5A of one another, allowing joint participation in regulatory processes controlled by DNA-binding proteins.

Z-DNA in transcriptionally active chromosomes

Due to the striking correlation between the distribution of transcriptionally active subdivisions of the polytene chromosomes and Z-DNA, we have addressed the question of whether the Z-DNA configuration exists in native, transcriptionally active chromosomes of Drosophila hydei prepared without interference by procedures known to induce the B to Z conformation. Our experiments indicate that Z-DNA forms are present in a specific set of sites on the native chromosomes. They occur on interbands and other subdivisions of dispersed DNA, but there is no correlation between the amount of Z-DNA detected and DNA compaction. The results suggest, moreover, that Z-DNA forms are restricted to specific genes, because various subdivisions induced to transcription in puffs show different patterns of Z-DNA. We show, in addition, that removal of chromosomal proteins by proteinase K has a strong influence on the level of anti-Z-DNA reactivity.

Different reactivity of Z-DNA antibodies with human chromosomes modified by actinomycin D and 5-bromodeoxyuridine

Antibodies against Z-DNA react with fixed metaphase chromosomes of man and other mammals. Indirect immunofluorescence staining shows that chromosomal segments corresponding to R- and T-bands preferentially fix Z-DNA antibodies. In this work Z-DNA antibodies were used as a probe for DNA conformation in euchromatin of fixed human chromosomes whose condensation or staining were modified by actinomycin D (AMD) and by 5-bromodeoxyuridine (BrdU). Treatments with AMD and BrdU were performed to induce a G-banding by modification of chromosomal segments corresponding to R- and T-bands. Long BrdU treatments were used to induce asymmetrical and partially undercondensed chromosomes by substitution of thymidine in one or both DNA strand. Our results show a clear difference of Z-DNA antibodies reactivity after AMD or BrdU treatment. The G-banding obtained after AMD treatment is not reversed by Z-DNA antibodies staining since these antibodies bind very weakly to the undercondensed R-bands. On the other hand, the G-banding obtained by BrdU is completely reversed giving typical R-banding, as on untreated chromosomes. For asymmetrical chromosomes an R-, T-banding pattern is always observed but there is a decrease of the fluorescence intensity proportional to the degree of BrdU incorporation. We conclude that AMD treatment greatly disturbs Z-DNA antibodies binding suggesting a change in DNA conformation, whereas BrdU treatments do not suppress but only weaken the specific binding of Z-DNA antibodies on R- and T-bands. The direct involvement of thymidine substitution in DNA sequences recognized by Z-DNA antibodies is discussed.

Binding of anti-Z-DNA antibodies in quiescent and activated lymphocytes: relationship to cell cycle progression and chromatin changes

Although regions of DNA reacting with anti-Z-DNA antibodies have been identified in the polytene chromosomes of Drosophila spp. and the metaphase chromosomes from a number of different mammalian species, the biological role of this DNA is unknown. Flow cytometry was used in the present studies to quantitate the binding of anti-Z-DNA antibodies in quiescent and activated human peripheral blood lymphocytes; the antibody binding was then correlated with cell cycle phase. The data show that quiescent (G0 or G1Q) lymphocytes are heterogeneous with respect to their reaction with anti-Z-DNA antibodies. The transition from quiescence (G1Q) into the cell cycle (G1), which involves decondensation of chromatin, did not result in any significant change in binding of these antibodies. In contrast, progression of cells from G1 through S and G2 is correlated with a 27% decrease in anti-Z-DNA antibody reactivity relative to total DNA content. No significant change was observed during the transition from G2 to mitosis (M).

Enhanced expression of the bacterial chloramphenicol acetyltransferase gene in mouse cells cotransfected with synthetic polynucleotides able to form Z-DNA

Recent studies have demonstrated that the left-handed, Z-DNA conformation is favored in polymers containing alternating purine/pyrimidine sequences that can exist in vivo and may play a role in gene expression. On the basis of this assumption, we have studied the effect of various cotransfected polynucleotides on the transient expression of the chloramphenicol acetyltransferase (CAT) gene in thymidine kinase-deficient murine L cells. Cotransfections were performed by calcium phosphate coprecipitation of CAT gene plasmids with various polymers, and the CAT enzymatic activity was measured in cell lysates after 48 hr. About 2- to 10-fold stimulation of CAT gene expression was observed when the cells were cotransfected with 10 micrograms (per 10-cm culture dish) of plasmid pSV2cat, which contains simian virus 40 (SV40) promoter and enhancer sequences, and 2-10 micrograms of polymers that can form Z-DNA, such as poly(dG-m5dC) X poly(dG-m5dC) or poly(dG-dC) X poly(dG-dC), as compared to transfection with pSV2cat alone. Further, enhanced CAT gene expression was also observed when cotransfections were performed with these polymers and two other plasmid vectors, one containing the SV40 promoter but no enhancer and the other lacking any SV40 regulatory sequences. However, poly(dA-dC) X poly(dG-dT), which can form Z-DNA, did not induce any stimulation. Similarly, no or very little stimulation was observed after cotransfection of pSV2cat with either poly(dG) X poly(dC) or poly(dA-dT) X poly(dA-dT), which do not adopt the Z conformation. These results suggest that certain polynucleotides may enhance transcription of the CAT gene.

Nucleotide sequence of an heterochromatic segment recognized by the antibodies to Z-DNA in fixed metaphase chromosomes

The purpose of this work was to analyse at the molecular level the DNA recognized by the antibodies to Z-DNA in in situ experiments. Antibodies to Z-DNA interact strongly with R-band positive heterochromatic segments of fixed metaphase chromosomes of Cebus (Viegas-Pequignot et al., 1983). These segments are constituted of a satellite DNA the repeat unit of which is about 1520 base pairs long. The base sequence of the repeat unit has been determined. It contains a (AC)n rich region which, in vitro, adopts the Z conformation under topological constraints. Experiments with nuclei suggest that this sequence is not predominantly in the Z conformation in vivo. The polymorphic structure of the (AC)n rich region argues for an active recombination sequence.

NMR, CD and IR spectroscopies of a tridecanucleotide containing a no-base residue: coexistence of B and Z conformations

The synthesis of the tridecadeoxynucleotide d(CGm5CGCGxACATGT), where x is the 1-cyano-2-deoxy-beta-D-erythropentofuranose, is described. The NMR, IR, CD studies at various salt concentrations and temperatures of this oligomer show that the B and Z conformations are simultaneously present in the same short DNA fragment. A single apurinic residue is sufficient for the coexistence of the B and Z helices on this oligomer.

New cytogenetic techniques in the study of primate genome evolution

Fixed metaphase chromosomes of different species and genera of Primates (five species of Macaca genus and Callithrix jacchus) have been studied after Alu I restriction enzyme digestion and DA-DAPI counterstaining, in the attempt to determine some qualitative characteristics of their DNAs and specifically of the DNA localized in the heterochromatic components of the karyotypes. The results have been discussed in the light of those already published on humans, confirming the potentiality of this approach in the study of the phyloevolutive relationships in Primates.

Antibodies to DNA

Antibodies that recognize specific conformational variations of DNA structure provide sensitive reagents for testing the extent to which such conformational heterogeneity occurs in nature. A most dramatic recent example has been the development and application of antibodies to left-handed Z-DNA. They provided the first identification of Z-DNA in fixed nuclei and chromosomes, and of DNA sequences that form Z-DNA under the influence of supercoiling. Antibodies have also been induced by chemically modified DNA and by synthetic polydeoxyribonucleotides that differ from the average B-DNA structure. These antibodies recognize only the features that differ from native DNA. In most experiments, native DNA itself is not immunogenic. Antibodies that do react with native DNA occur in sera of patients with autoimmune disease, but even monoclonal anti-DNA autoantibodies usually react with other polynucleotides as well. Anti-DNA antibodies, especially those of monoclonal origin, provide a model for the study of protein-nucleic acid recognition.

Binding of anti-Z-DNA antibodies in quiescent and activated lymphocytes: relationship to cell cycle progression and chromatin changes

Although regions of DNA reacting with anti-Z-DNA antibodies have been identified in the polytene chromosomes of Drosophila spp. and the metaphase chromosomes from a number of different mammalian species, the biological role of this DNA is unknown. Flow cytometry was used in the present studies to quantitate the binding of anti-Z-DNA antibodies in quiescent and activated human peripheral blood lymphocytes; the antibody binding was then correlated with cell cycle phase. The data show that quiescent (G0 or G1Q) lymphocytes are heterogeneous with respect to their reaction with anti-Z-DNA antibodies. The transition from quiescence (G1Q) into the cell cycle (G1), which involves decondensation of chromatin, did not result in any significant change in binding of these antibodies. In contrast, progression of cells from G1 through S and G2 is correlated with a 27% decrease in anti-Z-DNA antibody reactivity relative to total DNA content. No significant change was observed during the transition from G2 to mitosis (M).

Inhibition of the herpes simplex virus thymidine kinase gene transfection in Ltk- cells by potential Z-DNA forming polymers

It has been demonstrated that certain alternating purine and pyrimidine sequences may assume a left-handed Z-DNA conformation. In order to evaluate the possibility that Z-DNA is involved in the modulation of gene expression, we examined the ability of various synthetic DNA polymers to affect the transfection of herpes simplex virus thymidine kinase (HSVtk) gene in Ltk- cells using the DNA-calcium phosphate cotransfection technique. We found that potential Z-DNA forming polymers such as, poly(dG-m5dC) X poly(dG-m5dC) and poly(dG-dC) X poly(dG-dC), cotransfected with the tk gene decreased the level of Tk+ transformed colonies. In contrast, cotransfection of the tk gene with polymers which do not assume Z-conformation such as, poly(dG) X poly(dC) or poly(dA-dT) X poly(dA-dT) showed no effect on the number of colonies formed. About 50% inhibition of the Tk+ colony formation was obtained by 0.4 micrograms of poly(dG-m5dC) X poly(dG-m5dC), or by 2 micrograms of poly(dG-dC) X poly(dG-dC). DNA uptake into Ltk- cells was not significantly affected by any of these polymers. Approximately 20-42 base pairs (bp) long alternating dG-dC sequence linked at either the 5'-end or 3'-end of tk gene were cloned into plasmids. These recombinant plasmids, however, showed no remarkable effect upon the transfection of Ltk- cells. The DNAs of Tk+ colonies obtained by transfecting these recombinant plasmids were digested with BssH II and analyzed by Southern blotting. We demonstrated that the dG-dC sequences proximal to the tk gene were integrated into cellular DNA. All the presented results indicate that only larger polymers with the potential to assume a Z-DNA conformation may affect tk gene transfection either by inhibiting transcription or more probably by affecting the stable integration of the tk gene into the host chromosome.

Chromosomal R-banding with a monoclonal antidouble-stranded DNA antibody

A monoclonal anti-DNA antibody (HB2) specific for poly dG- poly dC nucleotides was used to stain metaphasic lymphocyte or amniotic cell human chromosomes. HB2 fixation was revealed using either a peroxidase- or a rhodamine-labeled anti-mouse immunoglobulin antiserum. The staining pattern of the chromosomes was dependent on the HB2 concentration: R-banding could be observed at high antibody dilution. Previous trypsinization of metaphasic preparations demonstrated a precise and reproducible typical R-banding independent of the HB2 concentration. This technique appears to be an interesting alternative to other R-banding procedures. The specificity of the antibody allows a better understanding of the biochemical mechanism of R-banding.

Construction of a viable simian virus 40 variant that carries a poly[d(GT) . d(CA)] insertion

A 90-base-pair tract of a simple sequence composed of alternating guanosine and thymidine nucleotide residues (poly[d(GT) . d(CA)]) was inserted into the simian virus 40 genome at nucleotide 2666 (0.17 map units). The poly[d(GT) . d(CA)] insertion was stably maintained in the viral genome, but the variant virus grew more slowly than simian virus 40.

Ring-opened alkylated guanine is not repaired in Z-DNA

Since the discovery of Z-DNA by X-ray analysis of the alternated hexanucleotide d(C-G)3 crystals, numerous studies have shown that fragments of natural DNAs can adopt the Z conformation, topological constraints being a major factor stabilizing this conformation. Immunochemical assays using antibodies to Z-DNA provide strong evidence for the presence of Z fragments in chromosomes. The biological role of Z-DNA is not yet known, but it might be involved in gene regulation. Proteins which bind specifically to Z-DNA have been isolated and interactions between Z-DNA and several cellular proteins have been studied. The ability of DNA repair enzymes to maintain the genome's integrity is of major importance to the cell. On alkylation of DNA by chemical carcinogens such as dimethyl sulphate, methyl methanesulphonate, methylnitrosourea or methylnitrosoguanidine, the main target is the N7 of the guanosine residue, yielding 7-methylguanine (mG). In alkaline conditions, the imidazole ring of mG opens up, yielding the ring-opened form 2,6-diamino-4-oxo-5-methylformamidopyrimidine (rom7G); this lesion is a block to DNA replication. It occurs in vivo and is enzymatically removed by the DNA glycosylase. Here we report that the lesion is not excised when present in DNA in the left-handed Z conformation.

Functional groups on 'Z' DNA recognized by monoclonal antibodies

Both brominated poly[d(GC)] and poly[d( Gm5C )] form stable left-handed Z-DNA structures at physiological ionic strengths. These two antigens were used to prepare monoclonal antibodies from immunized mice. The specificity of the antibodies was studied in detail with a solid-phase radioimmune assay as well as by means of competition experiments. Both immunogens produced several relatively non-specific antibodies but two types of very specific antibody were also distinguished. The first binds poly[d( Gm5C )] but not brominated poly[d(GC)] while the other has the opposite specificity and will only bind the brominated polymer.