Interactions of anti-poly[d(G-br5C)] IgG with synthetic, viral and cellular Z DNAs

Enzymatically synthesized poly[d(G-br5C)] was used to prepare specific polyclonal and monoclonal anti-Z DNA IgGs. The binding specificities of these antibodies were characterized using left-handed polynucleotides with the sequences d(G-x5C)n and d(A-x5C)n.d(G-T)n (mean = aza, methyl, bromo, or iodo). Polyclonal anti-poly[d(G-br5C)] IgG binds the convex surface of the Z helix as evidenced by the strong requirement for a methyl or halogen group at the C5 position of cytosine. Little or no anti-poly[d(G-br5C)] IgG binding occurs to left-handed DNAs carrying a phosphorothioate substitution in the dGpdC bond or an N-5 aza substitution in the cytosine ring. Anti-poly[d(G-br5C)] IgG can stabilize transient Z DNA structures in both polymer families, thereby displacing the equilibrium in solution between the right-and left-handed DNA conformations. Anti-poly[d(G-br5C)] IgG binding sites are found in all tested covalently closed circular natural DNAs (Form I) at their extracted negative superhelical densities, but not in any of the corresponding relaxed Form II or linear Form III DNAs. Binding of anti-poly[d(G-br5-C)] IgG leads to a reduction in the electrophoretic mobility of Form I DNA (e.g. SV40, phi X174, or pBR322) and to the formation of dimers comprised of the bivalent antibody and two supercoiled Form I DNA molecules. The dimers are converted to monomers by DTT treatment. The formation of IgG-DNA complexes is dependent on external conditions (ionic strength, temperature), the properties of the DNA (torsional stress, sequence), and the immunoglobulin (specificity, valency, and concentration). Higher order oligomeric species, indicative of two or more left-handed segments per DNA molecule are formed in reactions of anti-poly[d(G-br5C)] IgG with M13 RF I DNA but not with SV40, pBR322, or phi X174 DNAs. However, oligomers of the latter are generated with other anti-Z DNA IgGs having a broader spectrum of anti-Z DNA reactivity. Conditions which destabilize natural Z sequences in deproteinized supercoiled genomes are: monovalent salt concentrations at or above the 'physiological' range, high temperature, and topological relaxation with DNA gyrase (in the absence of ATP) or with type I topoisomerases. DNA gyrase (plus ATP) catalyses an increase in DNA negative superhelical density which leads to greater anti-Z DNA IgG binding, indicating the formation of additional left-handed regions. Polytene chromosomes of insect larvae bind anti-poly[d(G-br5C)] IgG specifically and stably at Z DNA sites. The distribution of this IgG binding differs in certain regions from that displayed by anti-Z DNA IgG probes with other sequence specificities.(ABSTRACT TRUNCATED AT 400 WORDS)     

Einfluß von Ionenstärke und pH auf die differentielle Dekondensation der Nukleoproteide isolierter Speicheldrüsen-Zellkerne und -Chromosomen von Chironomus thummi

A new method of isolating nuclei and chromosomes of salivary gland cells is described. — The influence of ionic strength and pH of the medium on the state of decondensation of chromosomal bands is studied. In the isolation medium (a modified Ringer solution), all the bands are in a condensed state; as the ionic strength is increased the bands decondense. This reaction of the bands to increasing ionic strength is dependent on the pH which determines: 1) the range of ionic strengths which causes decondensation of the bands; i.e., the lower the pH, the higher the ionic strength is required for decondensation (at pH 7.3, 150–350 mM NaCl, at pH 4.3, 500–800 mM NaCl), and 2) the extent of structural changes caused by increasing ionic strength; that is, at neutral pH the bands become diffuse (“fading”) and at moderate acidic pH (optimum 4.3) the bands unravel to yield pufflike structures (“swelling”). — All ion species tested induce decondensation of bands, but each one is effective differently; specifically, Mg⁺ is more effective than Na⁺ and K⁺, and ClO₄ ^? is more effective than Cl^?. — “Swelling” as induced at pH 4.3 by high ionic strength cannot be reversed by a mere lowering of ionic strength (to 150 mM NaCl) and a subsequent raise of pH (to 7.5); it can be reversed only by an addition of histones. The various histone fractions act differently on the recondensation process. — “Swelling” is correlated with an increase in template activity as evidenced by an increased incorporation of ³H-UTP, measured in the presence of ATP, CTP, GTP and exogeneous RNA polymerase. — The individual bands differ in their sensitivity to an increasing ionic strength. This differential sensitivity expresses itself only if one of the following conditions is met: 1) a moderately acidic pH (optimum 4.3) or 2) the presence of divalent cations at neutral pH. — In a few bands the sensitivity to an increasing ionic strength is dependent on the ionic species (Na⁺, K⁺, Mg⁺⁺ and Ca⁺⁺). — It is attempted to explain the above reactions on the basis of the physico-chemical properties of chromosomes.     

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).     

Antibodies against Z DNA react with the macronucleus but not the micronucleus of the hypotrichous ciliate stylonychia mytilus

Using indirect immunofluorescence, we studied the reaction of antibodies specific for left-handed Z DNA with the nuclei of the hypotrichous ciliate Stylonychia mytilus. In the vegetative cell, the macronucleus reacts strongly with these antibodies, but no reaction can be detected with micronuclei. However, an antibody that binds to denatured and right-handed B DNA reacts with both types of nuclei. No reaction of the anti-Z DNA antibody is seen in the macronuclear replication band. Digestion of macronuclei with DNAase I leads to a decrease in the anti-Z DNA antibody reaction. Some stages of the developing macronucleus were also investigated. No reaction is seen at the polytene chromosome stage, but following DNA elimination the nucleus is seen to react with the antibody.     

Structure and optical activity of the DNA-aminoacridine complex

The electronic absorption and circular dichroism spectra of the DNA-acridine orange complex have been measured over a range of ionic strength, pH, and DNA phosphate to dye (P/D) ratios. Three circular dichroism bands associated with the long wavelength absorption band of acridine orange are induced on complex formation with DNA. Two of the dichroism bands, due mainly to dimeric dye molecules, are favored by low ionic strength, low pH (3.2), and a low P/D ratio (～3), while the third, deriving primarily from monomeric dye, is optimum at high ionic strength, neutral pH, and a larger P/D ratio (9). The data suggest that monomeric acridine orange binds to DNA in the form of a left-handed helical array with four dye molecules per turn, while the bound dimer has a skewed sandwich conformation which is itself dissymmetric. The stereochemical relations between the bound monomer dye and the DNA are consistent with a modified intercalation model for the DNA-acridine complex.     

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.     

Assembly and characterization of nucleosomal cores on B- vs. Z-form DNA

The ability of right- vs. left-handed alternating purine/pyrimidine copolymers to support the formation of nucleosomes has been examined by using a trout testis assembly factor. The protein, which is thermostable, has a molecular weight of 29000 and will assemble nucleosomes onto both SV40 and calf thymus DNA. This assembly factor has been used to assemble nucleosomes onto the B and Z conformations of poly[d(Gm5C)] and the B conformation of poly[d(GC)]. The isolated B-form particles, which sediment at approximately 11 S in a sucrose density gradient, contain DNA of 140-200 bases in length and the four core histones. The isolated Z-form particles, which also sediment at approximately 11 S, contain the four core histones and DNA of 170-250 bases in length. Physical analysis of the particles by absorbance and circular dichroic spectroscopy indicates that the DNA remains in the original conformation throughout the isolation procedure. Further, the particles reconstituted onto left-handed DNA compete effectively for an anti-Z DNA antibody, while the corresponding right-handed particles do not. Analytical sedimentation velocity determinations indicate that the B-form poly[d(Gm5C)] and poly[d(GC)] particles sediment at 11.2 and 11.1 S, respectively. In contrast, the poly[d(Gm5C)] Z-form particles have an S20,w of 10.6 S. The differences in the sedimentation velocity and the density of the cores, and in the lengths of DNA associated with the particles, suggest that the conformation of the DNA affects the manner in which it associates with the histone octamer.     

Bands,interbands and puffs in native Drosophila polytene chromosomes are recognized by a monoclonal antibody to an epitope in the carboxy-terminal tail of histone H1

A monoclonal antibody was raised against Drosophila melanogaster histone H1. Immunoscreening of proteolytic cleavage fragments of H1 and of a set of all possible overlapping synthetic octapeptides corresponding to the amino acid sequence of H1, revealed that the antibody recognizes an epitope within the sequence ²⁰⁷VTAAKPKA²¹⁴ near the centre of the carboxy-terminal tail. This antibody gives positive immunofluorescence over the entire length of native D. melanogaster polytene chromosomes isolated from salivary glands by microdissection at physiological pH and ionic strength. Bands, interbands and puffs are all seen to contain H1. The immunofluorescence over puffs, albeit lower than that over bands and interbands, indicates that chromatin decondensation can occur without complete loss of H1 in these structures. The reaction of the antibody with bands suggests that the segment of the C-terminal tail containing the epitope may be exposed in the condensed 30 nm chromatin filament.     

Immunoglobulin recognition of synthetic and natural left-handed Z DNA conformations and sequences

The relative immunogenicities of the poly[d(G-C)] and poly[d(A-C) · d(G-T)] families of helices have been determined. The specificities of the resultant immunoglobulins have been characterized for recognition of different synthetic and natural left-handed sequences and conformations. Certain modifications of poly[d(G-C)] in the sugar-phosphate bacbone and cytosine C-5 potentiate the right(R)-to-left(L) (B → Z) transition under physiological conditions. The resulting polynucleotides, poly[d(G^S-C)], poly[d(G-io⁵C)], poly[d(G-br⁵C)] and poly[d(G-m⁵C)], are also highly immunogenic. In contrast, DNAs incapable of assuming the left-handed conformation under physiological salt concentrations are weakly or non-immunogenic. These include unmodified poly[d(G-C)] as well as members of the poly[d(A-C) · d(G-T)] family of sequences bearing pyrimidine C-5 substitutions (methyl, bromo, iodo). These polynucleotides undergo the R → L isomerization under more stringent ionic and thermal conditions.The specificities of purified polyclonal and monoclonal anti-Z DNA immunoglobulins (IgG) were measured by binding to radiolabeled polynucleotides, by electrophoretic analysis of IgG bound to covalent closed circular DNAs, and by immunofluorescent staining of polytene chromosomes. The salt-induced left-handed forms of poly[d(G-C)] and its derivatives (including the cytidine C-5 methyl, bromo, iodo, and N-5 aza substituted polynucleotides) and of the modified poly[d(A-C) · d(G-T)] polymers are bound to varying degrees by different antibodies. The patterns of substrate recognition demonstrate the existence of several antigenic domains in left-handed DNAs, including the helix convex surface and the sugar-phosphate backbone. Substitutions in these regions can produce enhancing (required substitutions), neutral, or inhibitory effects on subsequent IgG binding. Additionally, certain modifications of either the convex surface of Z DNA at the C-5 position of cytidine (i.e. a methyl group) or of the backbone (i.e. phosphorothioate substitution) can lead to polymorphic lefthanded conformations that are compatible with antibody binding when present individually but not in combination. The recognition patterns exhibited with DNA substrates from the two DNA families indicate that some, but not all, IgGs show specificity for different nucleotide sequences.The anti-Z DNA IgGs were used to probe for specific left-handed Z DNA determinants on plasmid (e.g. pBR322) or viral (e.g. simian virus 40 (SV40)) DNAs and on the acid-fixed polytene chromosomes of dipteran larvae. At their extracted superhelical density, the negatively supercoiled form I, but not the relaxed, nicked, or linear forms of all tested plasmid and viral DNAs specifically bind sequence-independent anti-Z IgGs. Dimers, trimers and higher oligomers of form I DNA cross-linked by bivalent anti-Z IgGs are formed with numerous (e.g. φX174, SV40, pBR322) genomes. Their occurrence depends upon IgG concentration and specificity, the conditions of ionic strength and temperatures and the DNA genome. The IgG cross-linked DNA multimers are converted to monomers by dithiothreitol reduction. Sequence-independent monovalent anti-Z Fab fragments bind form I DNA but do not generate oligomeric species. Multimers of order >2 indicate the existence of at least two anti-Z Ig binding sites per molecule, as in the case of SV40. IgGs differ in their ability to form stable complexes with some sites on natural DNAs, presumably due to their sequence and conformation binding specificities. A differential binding of these antibodies is also observed in certain bands of polytene chromosomes, such as the telomeric regions that are involved in chromosome associations.     

Synthesis and characterization of poly[d(G-z5C)]. B-Z transition and inhibition of DNA methylase

Deoxy-5-azacytidine 5'-triphosphate was synthesized and used as a substrate for the enzymatic synthesis of the polynucleotide poly[d(G-z5C)]. Whereas the triphosphate decomposes in solution, the azacytosine analogue incorporated into DNA is stable under conditions preserving the double-helical structure. Poly[d(G-z5C)] undergoes the transition to the left-handed Z conformation at salt (NaCl and MgCl2) concentrations approximately 30% higher than those required for unsubstituted poly[d(G-C)]. However, the incorporation of azacytidine potentiates the formation at room temperature of the Z helix stabilized by the transition metal Mn2+; in the case of poly[d(G-C)], a heating step is required. The spectral properties of the two polymers in the B and Z forms are similar. Both left-handed forms are recognized by anti-Z DNA immunoglobulins, indicating that the DNAs bear common antigenic features. Poly[d(G-z5C)] is not a substrate for the DNA cytosine 5-methyltransferase from human placenta. It is a potent inhibitor of the enzyme when tested in a competitive binding assay. These results are compatible with a very strong, possibly covalent, mode of interaction between methyltransferases and DNA containing 5-azacytosine.     

Histone localization in polytene chromosomes by immunofluorescence

Polytene chromosomes of Chironomus thummi were treated with antisera elicited by purified calf thymus histone fractions, and the location of each histone type was visualized by the indirect immunofluorescence technique. Each of the antisera produced specific and distinct patterns of fluorescence, suggesting that it is possible to use the indirect immunofluorescence technique to study the in situ organization of each histone in the various regions of the chromosomes. H1 and H2A antisera produced diffuse fluorescence patterns in acetic acid-fixed chromosomes which become more defined in formaldehyde-fixed preparations. Antisera to H2B, H3 and H4, when reacted with either formaldehyde- or acetic acid-fixed chromosomes, produce distinct banding patterns closely resembling the banding of acetoorcein-stained or phase-contrast-differentiated chromosomal preparations. These antisera produce corresponding patterns of fluorescence for each chromosome, suggesting that the overall organization of the histones is similar in the various bands. Because the dense band regions stain more brightly with antihistone sera than the less compacted interband areas, we believe that the number of antigenic sites of chromosome-bound histones is related to the amount of DNA present, and that the accessibility of histone determinants does not differ between the bands and interbands.     

Identification of left-handed Z-DNA by indirect immunofluorescence in polytene chromosomes of Chironomus thummi thummi

In this work, antibodies against Z-DNA were used to stain polytene chromosomes of Chironomus thummi thummi. By indirect immunofluorescence we report the first identification of left-handed conformation of DNA in a band region. The Chironomus pattern also contrasts with the general staining observed in Drosophila. In Chironomus the antibodies to Z-DNA bind to one interband region of the chromosome II and two bands regions of the chromosome IV.     

Structural basis for molecular recognition in an affibody:affibody complex

Affibody molecules constitute a class of engineered binding proteins based on the 58-residue three-helix bundle Z domain derived from staphylococcal protein A (SPA). Affibody proteins are selected as binders to target proteins by phage display of combinatorial libraries in which typically 13 side-chains on the surface of helices 1 and 2 in the Z domain have been randomized. The Z(Taq):anti-Z(Taq) affibody-affibody complex, consisting of Z(Taq), originally selected as a binder to Taq DNA polymerase, and anti-Z(Taq), selected as binder to Z(Taq), is formed with a dissociation constant K(d) approximately 100 nM. We have determined high-precision solution structures of free Z(Taq) and anti-Z(Taq), and the Z(Taq):anti-Z(Taq) complex under identical experimental conditions (25 degrees C in 50 mM NaCl with 20 mM potassium phosphate buffer at pH 6.4). The complex is formed with helices 1 and 2 of anti-Z(Taq) in perpendicular contact with helices 1 and 2 of Z(Taq). The interaction surface is large ( approximately 1670 A(2)) and unusually non-polar (70 %) compared to other protein-protein complexes. It involves all varied residues on anti-Z(Taq), most corresponding (Taq DNA polymerase binding) side-chains on Z(Taq), and several additional side-chain and backbone contacts. Other notable features include a substantial rearrangement (induced fit) of aromatic side-chains in Z(Taq) upon binding, a close contact between glycine residues in the two subunits that might involve aliphatic glycine Halpha to backbone carbonyl hydrogen bonds, and four hydrogen bonds made by the two guanidinium N(eta)H(2) groups of an arginine side-chain. Comparisons of the present structure with other data for affibody proteins and the Z domain suggest that intrinsic binding properties of the originating SPA surface might be inherited by the affibody binders. A thermodynamic characterization of Z(Taq) and anti-Z(Taq) is presented in an accompanying paper.     

Mobility of histones on the chromosome of simian virus 40.

Linear simian virus 40 (SV40) chromosomes were prepared by Eco R1 nuclease cleavage of the circular SV40 chromosomes released from virions with dithiothreitol at pH 9,8. Chromatin-DNA hybrids were constructed with segments of 3H-labeled, naked SV40 DNA covalently joined via the Eco R1-generated cohesive ends to segments of linear SV40 chromosome. Upon incubation of chromatin-DNA hybrids at 37 degrees C and moderate ionic strength, histones migrated onto the labeled DNA while retaining the nucleosome structure. This was shown first, by the pattern of micrococcal nuclease digestion of labeled DNA; second by nitrocellulose filter binding of labeled DNA after redigestion of the chromatin-DNA hybrids with Eco R1; and third, by examination of chromatin-DNA hybrids in the electron microscope. Migration was slow, being apparent after several hours. Parallel experiments in which naked DNA and chromosomes were mixed without joining showed no transfer of nucleosomal histones between DNA molecules. The kinetics of Eco R1 cleavage of the DNA in virion-derived SV40 chromosomes are also consistent with the notion that nucleosomal histones, in the absence of other proteins, can move on DNA.     

Theoretical studies of the electrostatic stability of A,B, C,and Z-DNA conformers as a function of monovalent ion concentration and ion type

Theoretical calculations using a two-state model of counterion phosphate interactions have been performed in order to determine the electrostatic stability of DNA in various ionic environments. Comparison of the stabilities of different conformations leads to results consistent with the B→Z transitions observed in high-salt environments and suggest that at very low ionic strnegths the left-handed Z(II) form is an electrostatically preferred conformation. An ion-type dependence of the high-salt B→Z transition midpoint is predicted. Calculations of the energies of the A and C conformations are also discussed in relation to experimentally observed transitions.     

Interactions between core histones and chromatin at physiological ionic strength

Addition of core histones to chromatin or chromatin core particles at physiological ionic strength results in soluble nucleohistone complexes when polyglutamic acid is included in the sample. The interaction between nucleosomes and added core histones is strong enough to inhibit nucleosome formation on a closed circular DNA in the same solution. Complexes consisting of core particles and core histones run as discrete nucleoprotein particles on polyacrylamide gels. Consistent with the electrophoretic properties of these particles, protein cross-linking with dimethyl suberimidate indicates that added core histones are bound as excess octamers. Histones in the excess octamers do not exchange with nucleosomal core histones at an ionic strength of 0.1 M and can be selectively removed from core particles by incubating the complexes in a solution containing sufficient DNA. Under conditions where added histones are confined to the surface of chromatin, the excess histones are mobile and can migrate onto a contiguous extension of naked DNA and form nucleosomes.     

Thermodynamics of folding and binding in an affibody:affibody complex

Affibody binding proteins are selected from phage-displayed libraries of variants of the 58 residue Z domain. Z(Taq) is an affibody originally selected as a binder to Taq DNA polymerase. The anti-Z(Taq) affibody was selected as a binder to Z(Taq) and the Z(Taq):anti-Z(Taq) complex is formed with a dissociation constant K(d)=0.1 microM. We have determined the structure of the Z(Taq):anti-Z(Taq) complex as well as the free state structures of Z(Taq) and anti-Z(Taq) using NMR. Here we complement the structural data with thermodynamic studies of Z(Taq) and anti-Z(Taq) folding and complex formation. Both affibody proteins show cooperative two-state thermal denaturation at melting temperatures T(M) approximately 56 degrees C. Z(Taq):anti-Z(Taq) complex formation at 25 degrees C in 50 mM NaCl and 20 mM phosphate buffer (pH 6.4) is enthalpy driven with DeltaH degrees (bind) = -9.0 (+/-0.1) kcal mol(-1)(.) The heat capacity change DeltaC(P) degrees (,bind)=-0.43 (+/-0.01) kcal mol(-1) K(-1) is in accordance with the predominantly non-polar character of the binding surface, as judged from calculations based on changes in accessible surface areas. A further dissection of the small binding entropy at 25 degrees C (-TDeltaS degrees (bind) = -0.6 (+/-0.1) kcal mol(-1)) suggests that a favourable desolvation of non-polar surface is almost completely balanced by unfavourable conformational entropy changes and loss of rotational and translational entropy. Such effects can therefore be limiting for strong binding also when interacting protein components are stable and homogeneously folded. The combined structure and thermodynamics data suggest that protein properties are not likely to be a serious limitation for the development of engineered binding proteins based on the Z domain.