A theoretical model of DNA curvature

Distortions from the uniform idealized B-DNA structure are investigated in terms of differential interactions between adjacent nucleotide pairs on the basis of conformational energy calculations. A theoretical model of DNA curvature is proposed based on the evaluation of the curvature vector defined in the complex plane and the corresponding variance. The model appears to contain the basic physical features for translating the deterministic fluctuations of DNA sequences in superstructure elements. It allows the quantitative reproduction of all the available gel electrophoresis experiments on both periodical polynucleotides and tracts of DNAs as well as the theoretical prediction of the sequence dependent DNA writhing in good agreement with the experimental data. The general pattern of agreement between the theoretical and experimental data and the biological significance of the results obtained allow an extensive application of the model for the screening of DNA regions which are possible candidates for protein recognition.     

Solution measurement of DNA curvature in papillomavirus E2 binding sites

‘Indirect readout’ refers to the proposal that proteins can recognize the intrinsic three-dimensional shape or flexibility of a DNA binding sequence apart from direct protein contact with DNA base pairs. The differing affinities of human papillomavirus (HPV) E2 proteins for different E2 binding sites have been proposed to reflect indirect readout. DNA bending has been observed in X-ray structures of E2 protein–DNA complexes. X-ray structures of three different E2 DNA binding sites revealed differences in intrinsic curvature. DNA sites with intrinsic curvature in the direction of protein-induced bending were bound more tightly by E2 proteins, supporting the indirect readout model. We now report solution measurements of intrinsic DNA curvature for three E2 binding sites using a sensitive electrophoretic phasing assay. Measured E2 site curvature agrees well the predictions of a dinucleotide model and supports an indirect readout hypothesis for DNA recognition by HPV E2.     

CENP-B box is required for de novo centromere chromatin assembly on human alphoid DNA

Centromere protein (CENP) B boxes, recognition sequences of CENP-B, appear at regular intervals in human centromeric alpha-satellite DNA (alphoid DNA). In this study, to determine whether information carried by the primary sequence of alphoid DNA is involved in assembly of functional human centromeres, we created four kinds of synthetic repetitive sequences: modified alphoid DNA with point mutations in all CENP-B boxes, resulting in loss of all CENP-B binding activity; unmodified alphoid DNA containing functional CENP-B boxes; and nonalphoid repetitive DNA sequences with or without functional CENP-B boxes. These four synthetic repetitive DNAs were introduced into cultured human cells (HT1080), and de novo centromere assembly was assessed using the mammalian artificial chromosome (MAC) formation assay. We found that both the CENP-B box and the alphoid DNA sequence are required for de novo MAC formation and assembly of functional centromere components such as CENP-A, CENP-C, and CENP-E. Using the chromatin immunoprecipitation assay, we found that direct assembly of CENP-A and CENP-B in cells with synthetic alphoid DNA required functional CENP-B boxes. To the best of our knowledge, this is the first reported evidence of a functional molecular link between a centromere-specific DNA sequence and centromeric chromatin assembly in humans.     

A novel flow cytometric assay to quantify interactions between proteins and membrane lipids

A diverse set of experimental systems has been developed to probe protein-lipid interactions. These include measurements with the headgroups of membrane lipids in solution, immobilized membrane lipids, and analysis of protein binding to membrane lipids reconstituted in liposomes. Each of these methodologies has strengths but also substantial limitations. For example, measurements between proteins and lipid headgroups or with immobilized membrane lipids do not probe interactions in their natural environment, the lipid bilayer. The use of liposomes, however, was so far mostly restricted to biochemical flotation experiments that do not provide quantitative and/or kinetic data. Here, we present a fast and sensitive flow cytometric method to detect protein-lipid interactions. This technique allows for quantitative measurements of interactions between multiple fluorescently labeled proteins and membrane lipids reconstituted in lipid bilayers. The assay can be used to quantify binding efficiencies and to determine kinetic constants. The method is further characterized by a short sampling time of only a few seconds that allows for high-content screening procedures. Finally, using light scatter measurements, the described method also allows for monitoring changes of membrane curvature as well as tethering of liposomes evoked by binding of proteins.     

Interaction of a cysteine-containing peptide with DNA

Cystine peptide dimer (Lys-Gly-Val-Cys-Val-N2H2Dns)2 with S-S bridge was synthesized and its interactions with DNA and synthetic polynucleotides have been studied by optical spectroscopy methods. By recording fluorescent titration curves we have shown that the affinity of the peptide to different synthetic polynucleotides decreases in the order: poly(dG).poly(dC) greater than poly(dA).poly(dT) greater than poly(dGC).poly(dGC). The stability of complexes to increasing concentrations of NaCl diminishes in the same order. The association constant is about 20-fold greater for peptide binding to poly(dG).poly(dC) than to poly(dA).poly(dT). By using circular dichroism and fluorescence measurements we have shown that the peptide competes for the binding sites on DNA with two minor-groove binding antibiotics--distamycin A and sybiromycin. These results have suggested that the peptide also binds in the DNA minor groove. Investigation of the interactions between such peptides and DNA may be useful for constructing ligands with combined specificity to DNA.     

Monoclonal antibodies to DNA and RNA from NZB/NZW F1 mice: antigenic specificities and NH2 terminal amino acid sequences

Two anti-DNA hybridoma autoantibodies ( A52 , D42 ) were prepared by fusing spleen cells from unimmunized NZB/NZW F1 female mice with BALB/c myeloma cells. The monoclonal antibodies were purified to homogeneity and were analyzed for their antigen-binding specificities. The two anti-DNA antibodies bound single-stranded, double-stranded, and supercoiled DNA, with a marked preference for the single-stranded conformation. Competition experiments performed with synthetic polynucleotides, as well as chain reconstitution experiments, indicated that both the sugar-phosphate backbone and the heterocyclic bases of the nucleic acid are essential for antibody recognition. Amino terminal sequence analysis of A52 and two RNA-binding hybridoma proteins revealed that the heavy chains from all three were members of the VHII subgroup and that the A52 light chain was homologous to the VK8 subgroup. The D42 heavy chain was found to be similar to a phosphocholine-binding hybridoma of the VHIII subgroup.     

The interaction of the benzimidazole dye Hoechst 8208 with nucleic acids

The interaction of Hoechst 8208 (H8208) with DNA and synthetic polynucleotides has been studied by absorption, fluorescence, flow dichroism, circular dichroism (CD), and viscosity measurements. The results are compatible with an intercalative mode of H8208 binding.     

Identification of A1 protein as the fourth member of 13 kDa-type acidic ribosomal protein family in yeast Saccharomyces cerevisiae

The identity of protein A1 predicted by a cDNA clone from yeast Saccharomyces cerevisiae which has common carboxyl-terminus to 13 kDa-type acidic ribosomal proteins has been examined. The unique gene for A1 was isolated using the cDNA clone and found to possess two boxes similar to upstream activation sequences for ribosomal protein genes (UASrpg) in the 5'-flanking region. The in vitro-translation product directed by hybrid-selected mRNA with A1 cDNA comigrated with a minor component of split proteins from ribosome by electrofocusing. In addition, the mRNA level for A1 was found to be lower than other two major acidic ribosomal proteins suggesting that A1 is the fourth member of the protein family so far identified which is expressed at relatively low level.     

Characterization of SAF-A, a novel nuclear DNA binding protein from HeLa cells with high affinity for nuclear matrix/scaffold attachment DNA elements.

We identified four proteins in nuclear extracts from HeLa cells which specifically bind to a scaffold attachment region (SAR) element from the human genome. Of these four proteins, SAF-A (scaffold attachment factor A), shows the highest affinity for several homologous and heterologous SAR elements from vertebrate cells. SAF-A is an abundant nuclear protein and a constituent of the nuclear matrix and scaffold. The homogeneously purified protein is a novel double stranded DNA binding protein with an apparent molecular weight of 120 kDa. SAF-A binds at multiple sites to the human SAR element; competition studies with synthetic polynucleotides indicate that these sites most probably reside in the multitude of A/T-stretches which are distributed throughout this element. In addition we show by electron microscopy that the protein forms large aggregates and mediates the formation of looped DNA structures.     

Theoretical investigation on the hypochromism of dinucleoside phosphates]

The hypochromism of stacked dimers of the nucleotide bases taken as models of the dinucleoside phosphates and dinucleotides was studied with the use of the configuration interaction and pertubation theory methods. General expression for the hypochromism of the polynucleotides is given in the first order perturbation theory with three different ways for approximation of the matrix elements of the perturbation operator. This expression was used for calculation of the dimer hypochromism in terms of theoretically calculated monomer characteristics. Dependence of the hypochromism on the dimer conformation was investigated. The results obtained so far demonstrate that it is important to take into account the electronic transitions in the vacuum UV region. This approach will enable one to elucidate the contribution of neighbouring bases into the DNA hypochromism.     

Nucleotide sequence-dependent opening of double-stranded DNA at an electrically charged surface

It has been shown earlier that the DNA double helix is opened due to a prolonged contact of the DNA molecule with the surface of the mercury electrode. At neutral pH, the opening process is relatively slow (around 100 s), and it is limited to potentials close to -1.2 V (against SCE). The opening of the double helix has been explained by strains in the DNA molecule due to strong repulsion of the negatively charged phosphate residues from the electrode surface where the polynucleotide chain is anchored via hydrophobic bases. Interaction of the synthetic ds polynucleotides with alternating nucleotide sequences/poly(dA-dT).poly (dA-dT), poly (dA-dU).poly (dA-dU), poly (dG-dC).poly (dG-dC)/ and homopolymer pairs/poly (dA).poly (dT), poly (rA).poly (rU) and poly (dG).poly (dC)/ with the hanging mercury drop electrode has been studied. Changes in reducibility of the polynucleotides were exploited to indicate opening of the double helix. A marked difference in the behaviour was observed between polynucleotides with alternating nucleotide sequence and homopolymer pairs: opening of the double-helical structures of the former polynucleotides occurs at a very narrow potential range (less than 100 mV) (region U), while with the homopolymer pairs containing A X T or A X U pairs, the width of this region is comparable to that of natural DNA (greater than 200 mV). In contrast to natural DNA, the region U of homopolymer pairs is composed of two distinct phases. No region U was observed with poly (dG).poly (dC). In polynucleotides with alternating nucleotide sequence, the rate of opening of the double helix is strongly dependent on the electrode potential in region U, while in homopolymer pairs, this rate is less potential-dependent. It has been assumed that the difference in the behaviour between homopolymer pairs and polynucleotides with alternating nucleotide sequence is due to differences in absorbability of the two polynucleotide chains in the molecule of a homopolymer pair (resulting from different absorbability of purine and pyrimidine bases) in contrast to equal adsorbability of both chains in a polynucleotide molecule with alternating nucleotide sequence. It has been shown that the mercury electrode is a good model of biological surfaces (e.g. membranes), and that the nucleotide sequence-dependent opening (unwinding) of the DNA double helix at electrically charged surfaces may play an important role in many biological processes.     

Mechanism of origin unwinding: sequential binding of DnaA to double- and single-stranded DNA

The initiator protein DnaA of Escherichia coli binds to a 9mer consensus sequence, the DnaA box (5'-TT(A/T)TNCACA). If complexed with ATP it adopts a new binding specificity for a 6mer consensus sequence, the ATP-DnaA box (5'-AGatct). Using DNase footprinting and surface plasmon resonance we show that binding to ATP-DnaA boxes in the AT-rich region of oriC of E.coli requires binding to the 9mer DnaA box R1. Cooperative binding of ATP-DnaA to the AT-rich region results in its unwinding. ATP-DnaA subsequently binds to the single-stranded region, thereby stabilizing it. This demonstrates an additional binding specificity of DnaA protein to single-stranded ATP-DnaA boxes. Binding affinities, as judged by the DnaA concentrations required for site protection in footprinting, were approximately 1 nM for DnaA box R1, 400 nM for double-stranded ATP-DnaA boxes and 40 nM for single-stranded ATP-DnaA boxes, respectively. We propose that sequential recognition of high- and low-affinity sites, and binding to single-stranded origin DNA may be general properties of initiator proteins in initiation complexes.     

Conserved gene arrangement in the origin region of the Streptomyces coelicolor chromosome.

A 23-kb fragment of the Streptomyces coelicolor chromosome spanning the dnaA region has been isolated as a cosmid clone. Nucleotide sequence analysis of a 5-kb portion shows that the genes for the RNase P protein (rnpA), ribosomal protein L34 (rpmH), the replication initiator protein (dnaA), and the beta subunit of DNA polymerase III (dnaN) are present in the highly conserved gene arrangement found in all eubacterial genomes studied so far. The dnaA-dnaN intergenic region is approximately 1 kb and contains a cluster of at least 12 DnaA boxes with a consensus sequence of TTGTCCACA matching the consensus DnaA box in the phylogenetically related Micrococcus luteus. Two DnaA boxes precede the dnaA sequence. We propose that the chromosomal origin (oriC) of S. coelicolor lies between dnaA and dnaN. In related work, J. Zakrzewska-Czerwinska and H. Schrempf (J. Bacteriol. 174:2688-2693, 1992) have identified the homologous sequence from the closely-related Streptomyces lividans as capable of self-replication.     

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.