Equilibrium binding of carcinogens and antitumor antibiotics to DNA: site selectivity, cooperativity, allosterism.

The equilibrium binding of the carcinogens N-hydroxy-N-acetyl-2-amino-fluorene (HAAF) and 4-nitroquinoline-1-oxide (NQO) to phi X174RF DNA have been studied by phase partition techniques. Both molecules bind in a cooperative manner with only a few carcinogen molecules binding to each phi X174RF DNA molecule. The binding data for both HAAF and NQO fit a model in which two carcinogens cluster into a small number of sites--four sites for HAAF and twelve sites for NQO. Phase partition techniques were also used to study the binding of actinomycin D to both calf thymus DNA and poly (dG-dC) . poly (dG-dC) at much lower r values than had been previously reported. These data exhibit humped Scatchard plots which are indicative of cooperative binding; the overall shape of the Scatchard plots are consistent with a model for drug induced allosteric transitions in the DNA structure. The cooperativity in the actinomycin D binding to calf thymus DNA increases with decreasing sodium chloride concentration, suggesting a role for DNA flexibility in allosteric binding.     

Cooperativity in nucleosomes assembly on supercoiled pBR322 DNA.

Many studies have shown that in reconstituted chromatin model systems, containing only purified DNA and histone octamer, nucleosomes can adopt well defined locations with respect to DNA nucleotide sequence. Recently, nucleosome-nucleosome interactions were suggested as one of the factors underlying preferential nucleosomes positioning. In the present paper this aspect has been studied by topological analysis and electron microscopy visualization of minichromosomes reconstituted at different histone/DNA ratios. Both methods suggest that cooperativity plays a role in nucleosomes formation. A linear cooperative model in which nucleosomes are formed on discrete sites with cooperative interactions occurring only between nearest neighbours allows to calculate the cooperative constant. The reported results show that basic interactions, which are of relevance in the process of chromatin folding, are present also in very simple model system.     

Identification of a Region of the Herpes Simplex Virus Single-Stranded DNA-Binding Protein Involved in Cooperative Binding

We have identified a region of the herpes simplex virus major DNA-binding protein (ICP8) which is involved in cooperative binding to single-stranded DNA. This has been accomplished by analysis of ICP8 which was covalently modified by reaction with the extrinsic fluorophore fluorescein-5-maleimide (FM). Reaction conditions which result in the incorporation of 1 mol of FM per mol of ICP8 have been established. The binding properties of the modified protein were analyzed by polyacrylamide gel shift analysis with model oligonucleotides. This analysis indicates that while intrinsic binding is similar to that observed with unmodified protein, the cooperative binding of the modified protein to single-stranded DNA is significantly altered. Helix-destabilizing assays, whose results are a reflection of cooperative binding, also indicate that this property of ICP8 is decreased upon modification with FM. Mapping of the site of modification by cyanogen bromide cleavage and peptide sequencing has shown that the major site of modification is cysteine 254. This position in the primary structure of ICP8 is distinct from the regions previously shown to be involved in the interaction of this protein with single-stranded DNA.     

Insight into the cooperative DNA binding of the O6-alkylguanine DNA alkyltransferase

The O⁶-alkylguanine DNA alkyltransferase (AGT) is a highly conserved protein responsible for direct repair of alkylated guanine and to a lesser degree thymine bases. While specific DNA lesion-bound complexes in crystal structures consist of monomeric AGT, several solution studies have suggested that cooperative DNA binding plays a role in the physiological activities of AGT. Cooperative AGT–DNA complexes have been described by theoretical models, which can be tested by atomic force microscopy (AFM). Direct access to structural features of AGT–DNA complexes at the single molecule level by AFM imaging revealed non-specifically bound, cooperative complexes with limited cluster length. Implications of cooperative binding in AGT–DNA interactions are discussed.     

The antitumor agent mitoxantrone binds cooperatively to DNA: evidence for heterogeneity in DNA conformation

The equilibrium binding of the antitumor compound DHAQ, or mitoxantrone [1,4-dihydroxy-5,8-bis[[2-[(2-hydroxyethyl)amino]ethyl]amino]-9,10- anthracenedione], to various DNAs has been examined by optical titration and equilibrium dialysis methods. At low r (bound drug/DNA base pair) values, r less than 0.03, DHAQ binds, in a highly cooperative manner, to calf thymus and Micrococcus lysodeikticus DNAs. The binding isotherms for the interaction of DHAQ with Clostridium perfringens DNA and poly(dA-dT).poly(dA-dT) exhibit a small positive slope at low r values, suggestive of cooperative binding. In contrast, the binding of DHAQ to poly(dG-dC).poly(dG-dC) shows no evidence of cooperative binding even at very low r values. At higher r values (r greater than 0.05), the binding of DHAQ to all the DNAs studied is characterized by a neighbor-exclusion process. A model is proposed to account for the two modes of binding exhibited in the cooperative binding isotherms. The main feature of the proposed model is that local sequence and structural heterogeneity of the DNA give rise to sets of binding sites to which DHAQ binds in a highly cooperative manner, while the majority of the DNA sites bind DHAQ via a neighbor-exclusion process. This two-site model reproduces the observed binding isotherms and leads to the conclusion that DHAQ binds in clusters to selected regions of DNA. It is suggested that clustering may play a role in the physiological activity of drugs.     

Nucleoprotein fusion. III. Causes and conditions for development of the multiphase character of the DNA--protein fusion curve

The influence of proteins reversibly and irreversibly bound to DNA on the shape of melting curve has been considered. It is shown that the melting curve becomes biphasic in two cases: (i) cooperative binding of proteins with DNA (II) STRONG DIFFERENCE IN THE BINDING CONSTANTS WITH HELICAL AND COILED REGIONS. Simple formulae permitting to determine which of two causes stipulate for biphasic profile of a given experimental melting curve are obtained. Melting curves of DNA-basic oligopeptides complexes have been investigated. It is shown that the oligopeptides, when their chain length does not exceed 10, are able to migrate along DNA and biphasic shape of the melting curve is stipulated by the cooperative manner of their binding with DNA.     

Cooperative binding of m-AMSA to nucleic acids.

The equilibrium binding of the antitumor agent m-AMSA (4'-(9-acridinylamino) methane-sulfon-m-ansidide) has been examined by optical methods. These studies which have focused on the low bound drug concentrations (r values less than 0.02, base pairs) reveal m-AMSA to bind calf thymus DNA in a highly cooperative manner as indicated by the initial positive slope of the Scatchard plot. In contrast, the studies on the parent 9-aminoacridine under identical conditions demonstrate that this compound binds DNA in a noncooperative (neighbor exclusion) manner. The positive cooperative binding phenomenon of m-AMSA is probed as a function of ionic concentration and shown to exist over the range of salt concentrations examined (0.01 to 0.1 M); however, the magnitude of the cooperative binding is altered. This observation of cooperativity is consistent with earlier studies on biologically active compounds and may be related to such binding parameters as binding sequence selectivity and/or structural perturbations to the DNA structure.     

Studies on the noncooperative binding of the Escherichia coli DNA unwinding protein to single-stranded nucleic acids.

The noncooperative binding of the Escherichia coli DNA unwinding protein to single-stranded DNA oligomers has been studied by means of equilibrium dialysis. Dialyses were performed under a number of solution and temperature conditions using oligomers of varying length and base compositions. The results of these studies, which include a Scatchard analysis of the binding, have allowed us to propose a model for the cooperative binding of the protein to single-stranded DNA. The results of experiments dealing with the interaction of the protein with single-stranded RNA are also presented.     

Nucleoprotein melting. I. Theory of helix-coil transition of DNA in the presence of proteins with cooperative character of interaction under conditions of reversible binding]

Helix-coil transition of DNA with attached extended ligands able to interact with one another during adsorption on DNA (cooperative or uncooperative binding) has been considered. The general formulae describing dependence of polymer melting curve on concentration of attached ligands have been obtained. It has been shown that cooperativity of interaction with DNA stipulates for two phase profile of the melting curve. The results obtained show that proteins which interact with DNA cooperatively may cause two phase helix-coil transition under conditions of reversible binding.     

Estimating Genetic Variability with Restriction Endonucleases

The estimation of the amount of sequence variation in samples of homologous DNA segments is considered. The data are assumed to have been obtained by restriction endonuclease digestion of the segments, from which the numbers and frequencies of the cleavage sites in the sample are determined. An estimator, p, of the proportion of sites that are polymorphic in the sample is derived without assuming any particular population genetic model for the evolution of the population. The estimator is very close to the EWENS, SPIELMAN and HARRIS (1981) estimator that was derived with the symmetric WRIGHT-FISHER neutral mode. ENGELS (1981) has also recently proposed an estimator of the same quantity, and he arrived at his estimator without assuming a particular population genetic model. The sampling variance of p and ENGELS' estimator are derived. It is found that the sampling variance of p is lower than the sampling variance of ENGELS' estimator. Also, the sampling variance of theta, an estimate of theta (=4Nu) is obtained for the symmetric WRIGHT-FISHER neutral model with free recombination and with no recombination.     

Adriamycin and daunorubicin bind in a cooperative manner to deoxyribonucleic acid

Phase partition techniques have been used to measure the binding of the antitumor drugs adriamycin (NSC-123127) and daunorubicin (NSC-82151) to various DNAs. These methods provide reliable equilibrium binding data at the low levels of drug binding that may be expected in vivo. Both adriamycin and daunorubicin exhibit positive cooperativity (and/or allosterism) in their equilibrium binding to DNA as indicated by the positive slope in the initial region of the binding isotherms (Scatchard plots) under conditions simulating physiological ionic strengths. The cooperative binding (i.e., the appearance of initial positive curvature in the binding isotherms) is dependent upon the ionic strength, which suggests a role for DNA flexibility in the cooperative binding process. An analysis of the slope of the initial portion of the binding isotherms for the interaction of adriamycin with synthetic deoxypolynucleotides shows that the degree of cooperative binding decreases in the order poly(dGdT) X poly(dAdC) greater than or equal to poly(dAdT) X poly(dAdT) greater than poly(dGdC) X poly(dGdC). Marky and Breslauer [Marky, L.A., & Breslauer, K. J. (1982) Biopolymers 21, 2185-2194] found that the average base stacking enthalpies of these synthetic poly-nucleotides were in the same order, which also suggests that the properties of the DNA influence the cooperative binding (and/or allosteric effects). Adriamycin binds with a higher degree of cooperativity than daunorubicin (0.1 M NaCl); although this correlates with the effectiveness of the drugs as antitumor agents, the exact relationship between the observation of cooperative binding and pharmacological activity is yet to be determined.     

Mechanism of inhibition of DNA gyrase by quinolone antibacterials: a cooperative drug--DNA binding model

We have proposed a cooperative quinolone-DNA binding model for the inhibition of DNA gyrase. The essential feature of the model is that bound gyrase induces a specific quinolone binding site in the relaxed DNA substrate in the presence of ATP. The binding affinity and specificity are derived from two unique and equally important functional features: the specific conformation of the proposed single-stranded DNA pocket induced by the enzyme and the unique self-association phenomenon (from which the cooperativity is derived) of the drug molecules to fit the binding pocket with a high degree of flexibility. Supporting evidence for and implications of this model are provided.     

Interaction of DNA with the movement proteins of geminiviruses revisited

Geminiviruses manage the transport of their DNA within plants with the help of three proteins, the coat protein (CP), the nuclear shuttle protein (NSP), and the movement protein (MP). The DNA-binding capabilities of CP, NSP, and MP of Abutilon mosaic virus (AbMV; family Geminiviridae; genus Begomovirus) were scrutinized using gel mobility shift assays and electron microscopy. CP and NSP revealed a sequence-independent affinity for both double-stranded and single-stranded DNA, as has been previously reported for other begomoviruses. MP interacted selectively with dimeric supercoiled plasmid DNA in the electrophoretic assay. Further apparent size- and form-selective binding capacities of MP have been previously reported for another geminivirus (Bean dwarf mosaic virus), but in the case of AbMV, they have been identified as the result of electrophoretic interference rather than of complex formation. Without these complications, electron microscopy confirmed the assembly of double-stranded supercoiled DNA with NSP and MP into conspicuous structures and provided the first direct evidence for cooperative interaction of MP, NSP, and DNA. Based on these results and previous ones, a transport model of geminiviruses is discussed in which NSP packages DNA and MP anchors this complex to the protoplasmic leaflets of plasma membranes and microsomes for cell-to-cell movement.     

Cooperativity and specificity in the interactions between DNA and the glucocorticoid receptor DNA-binding domain

We have employed fluorescence spectroscopy to study the chemical equilibrium between a 115 amino acid protein fragment containing the DNA-binding domain of the human glucocorticoid receptor (DBDr) and a 24-base-pair DNA oligomer containing the glucocorticoid response element (GRE) from the mouse mammary tumor virus promoter region and compared it with the binding to nonspecific DNA at various ionic conditions. We find that binding to both DNAs is cooperative but that DBDr shows a higher affinity for the GRE than for nonspecific DNA and that this difference is more pronounced at increased salt concentrations. Sequence-specific binding to the GRE sequence at 570 mM monovalent cations can be described by a two-site cooperative model, and this supports the notion that DBDr binding to the GRE is enhanced by dimer formation at the recognition site. The product between the (average) association constant for binding to a GRE half-site and the cooperativity parameter was estimated to be K omega = (1-4) x 10(7) M-1 at this salt concentration and 20 degrees C. The sequence-specific binding is not very sensitive to salt concentration in the interval 270-570 mM monovalent cations. However, at lower salt (70 mM) additional binding takes place, presumably nonspecific (cooperative) association to DNA adjacent to the GRE sequence. DBDr binding to nonspecific DNA can be described by the McGhee-von Hippel model for cooperative binding to a chain polymer and is very sensitive to ionic conditions.(ABSTRACT TRUNCATED AT 250 WORDS)     

The crystal structure of the herpes simplex virus 1 ssDNA-binding protein suggests the structural basis for flexible, cooperative single-stranded DNA binding

All organisms including animal viruses use specific proteins to bind single-stranded DNA rapidly in a non-sequence-specific, flexible, and cooperative manner during the DNA replication process. The crystal structure of a 60-residue C-terminal deletion construct of ICP8, the major single-stranded DNA-binding protein from herpes simplex virus-1, was determined at 3.0 A resolution. The structure reveals a novel fold, consisting of a large N-terminal domain (residues 9-1038) and a small C-terminal domain (residues 1049-1129). On the basis of the structure and the nearest neighbor interactions in the crystal, we have presented a model describing the site of single-stranded DNA binding and explaining the basis for cooperative binding. This model agrees with the beaded morphology observed in electron micrographs.     

Analysis of Cre-loxP interaction by surface plasmon resonance: influence of spermidine on cooperativity

To study target site selectivity of one important class of DNA-binding proteins, site-specific DNA recombinases, we developed an automated real-time kinetic assay based on surface plasmon resonance (BIACORE) and formulated a curve-fitting model that takes into account cooperative interactions. Monitoring the interaction between the Cre DNA recombinase and its specific target site loxP by BIACORE, we found that Cre associates with loxP tightly and highly cooperatively. We observed that the cooperative moment of the Cre-loxP interaction is strongly dependent on the concentration of spermidine, a small polyamine influencing DNA conformation. Thus, DNA conformation can have a profound impact on substrate recognition and subsequent recombination.     

Effect of excluded volume on topological properties of circular DNA

We have performed computer simulations of closed polymer chains with allowance for the excluded volume effects within the framework of the free-joint model. The probability of knot formation, the linking probability of a pair of chains and the variance in the writhing number proved to be significantly affected by the excluded volume effects. This is true even for DNA with completely screened charges for which the b/d ratio (where b is the Kuhn statistical length and d is the diameter of the double helix) is as large as 50. Allowance for the electrostatic repulsion (change of the DNA effective diameter d) further increases the effects. The most dramatic dependence on d is found for the probability of knot formation. The data on the dependence of the variance of writhing, mean value of (WR)2, on d indicate that the DNA superhelix energy should be significantly ionic strength-dependent. Special calculations have shown that the free-joint model underestimates the mean value of (Wr)2 value by about 20% as compared with the wormlike model.     

Cooperative kinking at distant sites in mechanically stressed DNA

In cells, DNA is routinely subjected to significant levels of bending and twisting. In some cases, such as under physiological levels of supercoiling, DNA can be so highly strained, that it transitions into non-canonical structural conformations that are capable of relieving mechanical stress within the template. DNA minicircles offer a robust model system to study stress-induced DNA structures. Using DNA minicircles on the order of 100 bp in size, we have been able to control the bending and torsional stresses within a looped DNA construct. Through a combination of cryo-EM image reconstructions, Bal31 sensitivity assays and Brownian dynamics simulations, we have been able to analyze the effects of biologically relevant underwinding-induced kinks in DNA on the overall shape of DNA minicircles. Our results indicate that strongly underwound DNA minicircles, which mimic the physical behavior of small regulatory DNA loops, minimize their free energy by undergoing sequential, cooperative kinking at two sites that are located about 180° apart along the periphery of the minicircle. This novel form of structural cooperativity in DNA demonstrates that bending strain can localize hyperflexible kinks within the DNA template, which in turn reduces the energetic cost to tightly loop DNA.