Spermidine-Deoxyribonucleic acid interaction in vitro and in Escherichia coli.

The binding of spermidine to deoxyribonucleic acid (DNA) was studied by equilibrium dialysis in a wide range of salt concentrations. The association constants ranged from 6 x 10(5) M-1 in 1 mM sodium cacodylate, pH 7.5, to 3 x 10(2) M-1 in 0.3 M NaCl. MgCl2 reduced spermidine-DNA interaction even more than NaCl so that in moderate-ionic-strength solutions (0.3 M NaCl, 0.002 M MgCl2) there was little detectable binding. Low-ionic-strength media were used to isolate DNA from Escherichia coli by a method shown to minimize loss of spermidine from the DNA. Considerable spermidine was associated with E. coli DNA, but control experiments indicated that complex formation had taken place during or after lysis of the cells. Exogenous DNA or ribonucleic acid added to spheroplasts at the time of their lysis caused most of the cellular spermidine to be scavenged by the extra nucleic acid. The data suggest that spermidine is relatively free in the cell and thereby capable of strong (high-affinity) associations with nucleic acids only after the ionic strength of the cell environment is lowered.     

Structural organization of copper(II) ions in complexes with DNA

The interaction of Cu(II) ions with native and denatured DNA as a function of ionic strength of the solution was studied by the equilibrium dialysis method. Graphical analysis of binding isotherms confirmed the occurrence of interstrand and intrastrand binding of Cu(II) with DNA and made possible determination of the respective binding constants. To facilitate interpretation of the data, a new molecular model of Cu(II)-DNA binding has been proposed, assuming interstrand intercalation of one Cu(II) ion between two GC pairs both in the successive even and odd groups of GC pairs, and interstrand binding of Cu(II) to the isolated GC pairs, with the exception of T-C-T and T-G-T sequences. In agreement with this model, the DNA-Cu(II) complex is most stable under the equilibrium with free Cu(II) ions at 4 degrees C, pH 6 when the molar ratio of GC pairs to Cu(II) ions bound interstrandially attains GC/Cuinter = 2 +/- 0.1.     

Evidence for the reversible binding of paraquat to deoxyribonucleic acid

Evidence for the reversible binding of paraquat to calf thymus DNA has been obtained using equilibrium dialysis and thermal melting point determinations. The data indicated the presence of at least two populations of binding site with affinity constants of 6.2 X 10(4) and 7.1 X 10(3) M-1, respectively. The binding capacities of DNA for paraquat were 66 and 480 nmol/mumol DNA nucleotide, respectively, and were equivalent to one ligand bound per 2 DNA phosphate groups. Putrescine inhibited paraquat binding to the low affinity sites without altering binding to the high affinity sites. Scatchard plots of paraquat binding characteristics indicated the presence of positive cooperativity between the compound and DNA. Thermal melting curves of DNA in the presence of paraquat and the endogenous amines putrescine, spermidine and spermine, provided evidence that paraquat cross-linked to DNA with a similar affinity as spermidine. The thermal melting point data also suggested the presence of positive cooperativity between ligand and macromolecule that possibly resulted from a conformation change in the structure of the DNA molecule. Paraquat competitively inhibited the binding of ethidium bromide to DNA and this effect was reversed by Na+. From the data, it is suggested that paraquat binds primarily to the negatively charged phosphates on the DNA backbone but is displaced into the interbase region occupied by the intercalator ethidium bromide. DNA binding of paraquat may, in part, account for its weak mutagenic activity.     

Effects of the Escherichia coli SSB protein on the binding of Escherichia coli RecA protein to single-stranded DNA. Demonstration of competitive binding and the lack of a specific protein-protein interaction

The effect of the Escherichia coli single-stranded DNA binding (SSB) protein on the stability of complexes of E. coli RecA protein with single-stranded DNA has been investigated through direct DNA binding experiments. The effect of each protein on the binding of the other to single-stranded DNA, and the effect of SSB protein on the transfer rate of RecA protein from one single-stranded DNA molecule to another, were studied. The binding of SSB protein and RecA protein to single-stranded phage M13 DNA is found to be competitive and, therefore, mutually exclusive. In the absence of a nucleotide cofactor, SSB protein binds more tightly to single-stranded DNA than does RecA protein, whereas in the presence of ATP-gamma-S, RecA protein binds more tightly than SSB protein. In the presence of ATP, an intermediate result is obtained that depends on the type of DNA used, the temperature, and the magnesium ion concentration. When complexes of RecA protein, SSB protein and single-stranded M13 DNA are formed under conditions of slight molar excess of single-stranded DNA, no effect of RecA protein on the equilibrium stability of the SSB protein-single-stranded DNA complex is observed. Under similar conditions, SSB protein has no observed effect on the stability of the RecA protein-etheno M13 DNA complex. Finally, measurements of the rate of RecA protein transfer from RecA protein-single-stranded DNA complexes to competing single-stranded DNA show that there is no kinetic stabilization of the RecA protein-etheno M13 DNA complex by SSB protein, but that a tenfold stabilization is observed when single-stranded M13 DNA is used to form the complex. However, this apparent stabilizing effect of SSB protein can be mimicked by pre-incubation of the RecA protein-single-stranded M13 DNA complex in low magnesium ion concentration, suggesting that this effect of SSB protein is indirect and is mediated through changes in the secondary structure of the DNA. Since no direct effect of SSB protein is observed on either the equilibrium or dissociation properties of the RecA protein-single-stranded DNA complex, it is concluded that the likely effect of SSB protein in the strand assimilation reaction is on a slow step in the association of RecA protein with single-stranded DNA. Direct evidence for this conclusion is presented in the accompanying paper.     

Interaction of pseudomonic acid A with Escherichia coli B isoleucyl-tRNA synthetase.

Sodium pseudomonate was shown to be a powerful competitive inhibitor of Escherichia coli B isoleucyl-tRNA synthetase (Ile-tRNA synthetase). The antibiotic competitively inhibits (Ki 6 nM; cf. Km 6.3 microM), with respect top isoleucine, the formation of the enzyme . Ile approximately AMP complex as measured by the pyrophosphate-exchange reaction, and has no effect on the transfer of [14C]isoleucine from the enzyme . [14C]Ile approximately AMP complex to tRNAIle. The inhibitory constant for the pyrophosphate-exchange reaction was of the same order as that determined for the inhibition of the overall aminoacylation reaction (Ki 2.5 nM; cf. Km 11.1 microM). Sodium [9'-3H]pseudomonate forms a stable complex with Ile-tRNA synthetase. Gel-filtration and gel-electrophoresis studies showed that the antibiotic is only fully released from the complex by 5 M-urea treatment or boiling in 0.1% sodium dodecyl sulphate. The molar binding ratio of sodium [9'-3H]pseudomonate to Ile-tRNA synthetase was found to be 0.85:1 by equilibrium dialysis. Aminoacylation of yeast tRNAIle by rat liver Ile-tRNA synthetase was also competitively inhibited with respect to isoleucine, Ki 20 microM (cf. Km 5.4 microM). The Km values for the rat liver and E. coli B enzymes were of the same order, but the Ki for the rat liver enzyme was 8000 times the Ki for the E. coli B enzyme. This presumably explains the low toxicity of the antibiotic in mammals.     

Pi binding by the F1-ATPase of beef heart mitochondria and of the Escherichia coli plasma membrane

Pi binding by the F(1)-ATPase of beef heart mitochondria and of the Escherichia coli plasma membrane (E. coli F(1)) was examined by two methods: the centrifuge column procedure [Penefsky, H.S. (1977) J. Biol. Chem. 252, 2891-2899] and the Paulus pressure dialysis cell [Paulus, H. (1969) Anal. Biochem. 32, 91-100]. The latter is an equilibrium dialysis-type procedure. Pi binding by beef heart F(1) could be determined by either procedure. However, direct binding of Pi to E. coli F(1) could be determined adequately only in the Paulus cell which indicated more than two binding sites per mol of enzyme with a K(d) in the range of 0.1 mM. It is concluded that previous failure to observe Pi binding to E. coli F(1) with the centrifuge column procedure is due to a rapid rate of dissociation of Pi from the E. coli enzyme which results in loss of Pi during transit of the enzyme-Pi complex through the column.     

Ligand-modulated binding of a gene regulatory protein to DNA. Quantitative analysis of cyclic-AMP induced binding of CRP from Escherichia coli to non-specific and specific DNA targets

This paper describes a generally applicable method for quantitative investigation of ligand-dependent binding of a regulatory protein to its target DNA at equilibrium. It is used here to analyse the coupled binding equilibria of cAMP receptor protein from Escherichia coli K12 (CRP) with DNA and the physiological effector cAMP. In principle, the DNA binding parameters of CRP dimers with either one or two ligands bound are determinable in such an approach. The change of protein fluorescence was used to measure CRP binding to its recognition sequence in the lac control region and to non-specific DNA. Furthermore, the binding of cAMP to preformed CRP-DNA complexes was independently studied by equilibrium dialysis. The data were analysed using a simple interactive model for two intrinsically identical sites and site-site interactions. The intrinsic binding constant K and the co-operativity factor alpha for binding of cAMP to free CRP depend only slightly on salt concentration between 0.01 M and 0.2 M. In contrast, the affinity of cAMP for CRP pre-bound to non-specific DNA increases with the salt concentration and the co-operativity changes from positive to negative. This results from cation rebinding to the DNA lattice upon forming the cAMP-CRP-DNA complex from cAMP and the pre-formed CRP-DNA complex. The CRP-cAMP1 complex shows almost the same affinity for specific and non-specific DNA as the CRP-cAMP2 complex, and both displace the same number of cations. It is concluded that the allosteric activation of CRP is induced upon binding of the first cAMP. These results are used to estimate the occupation of the CRP site in the lac control region in relation to the cAMP concentration in vivo. Under physiological conditions the lac promoter is activated by the CRP dimer complexed with only one cAMP. Furthermore, a model for the differential activation of various genes expressed under catabolite repression is presented and discussed.     

Daunomycin-induced unfolding and aggregation of chromatin.

Using equilibrium dialysis and sedimentation velocity analysis, we have characterized the binding of the anti-tumor drug daunomycin to chicken erythrocyte chromatin before and after depletion of linker histones and to its constitutive DNA under several ionic strengths (5, 25, and 75 mM NaCl). The equilibrium dialysis experiments reveal that the drug binds cooperatively to both the chromatin fractions and to the DNA counterpart within the range of ionic strength used in this study. A significant decrease in the binding affinity was observed at 75 mM NaCl. At any given salt concentration, daunomycin exhibits higher binding affinity for DNA than for linker histone-depleted chromatin or chromatin (in decreasing order). Binding of daunomycin to DNA does not significantly affect the sedimentation coefficient of the molecule. This is in contrast to binding to chromatin and to its linker histone-depleted counterpart. In these instances, preferential binding of the drug to the linker DNA regions induces an unfolding of the chromatin fiber that is followed by aggregation, presumably because of histone-DNA interfiber interactions.     

Copper-activated DNA photocleavage by a pyridine-linked bis-acridine intercalator

We report the synthesis of new photonuclease 4 consisting of two acridine rings joined by a pyridine-based copper binding linker. We have shown that photocleavage of plasmid DNA is markedly enhanced when this ligand is irradiated in the presence of copper(II) (419 nm, 22 degrees C, pH 7.0). Viscometric data indicate that 4 binds to DNA by monofunctional intercalation, and equilibrium dialysis provides an estimated binding constant of 1.13 x 105 M-1 for its association with calf thymus DNA. In competition dialysis experiments, 4 exhibits preferential binding to GC-rich DNA sequences. When Cu(II) is added at a ligand to metal ratio of 1:1, electrospray ionization mass spectrometry demonstrates that compound 4 undergoes complex formation, while thermal melting studies show a 10 degrees C increase in the Tm of calf thymus DNA. Groove binding and intercalation are suggested by viscometric data. Finally, colorimetric and scavenger experiments indicate that the generation of Cu(I), H2O2, and superoxide contributes to the production of DNA frank strand breaks by the Cu(II) complex of 4. Whereas the strand breaks are distributed in a relatively uniform fashion over the four DNA bases, subsequent piperidine treatment of the photolysis reactions shows that alkaline labile lesions occur predominantly at guanine.     

Specific and non specific Escherichia coli ribonucleic acid polymerase DNA complexes are not hydrodynamically equivalent in analytical band sedimentation

We have measured the sedimentation coefficients (s) of different DNA molecules of a few thousand base bairs in the presence of increasing amounts of E. coli RNA polymerase under conditions where tight binding complexes are formed. The measured s does not increase linearly with n(n=RNA Polymerase/DNA molar ratio); the s vs n plot can be decomposed into two parts; first the increase in s is small until n reaches a value n0 approximately equal to the number of strong promoters of the DNA molecule under consideration, then when n greater than n0 the slope of s(n) is much higher. The observations are in agreement with a model which postulates that strong specific polymerase binding leads to an increase in frictional coefficient of the RNA Polymerase-DNA complex, while non specific(or less specific)RNAP binding leads to a contraction of the RNA Polymerase-DNA complexes.     

Effects of thermodynamic nonideality in ligand binding studies

Effects of thermodynamic nonideality are considered in relation to the quantitative characterization of the interaction between a small ligand. S, and a macromolecular acceptor. A, by two types of experimental procedure. The first involves determination of the concentration of ligand in dialysis equilibrium with the acceptor/ligand mixture, and the second, measurement of the concentration of unbound ligand in the reaction mixture by ultrafiltration or the rate of dialysis method. For each situation explicit expressions are formulated for the appropriate binding function with allowance for composition-dependent nonideality effects expressed in terms of molar volume, charge-charge interaction and covolume contributions. The magnitudes of these effects are explored with the aid of experimental studies on the binding of tryptophan and of methyl orange to bovine serum albumin. It is concluded for experiments conducted utilizing either equilibrium dialysis or frontal gel chromatography that, provided a correction is made for any Donnan redistribution of ligand, theoretically predicted acceptor-concentration dependence is likely to be negligible and that use of the conventional binding equation written for an ideal system is appropriate to the analysis of the results. Use of ultrafiltration or the rate of dialysis method requires examination of the assumption that the activity coefficient ratio y(A)y(s)/y(AS) for the reaction mixture approximates unity; but again reassurance is provided that nonideality manifested as a dependence of the binding function on acceptor concentration is unlikely to be significant.     

Structural and electrostatic effects on binding of trivalent cations to double-stranded and single-stranded poly[d (AT)

We have measured the thermal melting profile for poly[d(AT)].poly[d(TA)] as a function of concentration of three trivalent cations: spermidine, me8spermidine, and hexammine cobalt(III). Using McGhee's (1976) theory of DNA melting in the presence of ligands, we have estimated association constants Kh, Kc and binding site sizes nh, nc for binding to double-helical (h) and single-stranded (c) polynucleotide. The results are as follows: (table; see text) The binding parameters for spermidine and hexammine cobalt(III) to double helical molecules agree fairly well with direct equilibrium dialysis measurements, and are in reasonable accord with predictions of counterion condensation theory. However, despite their identical charges, the three ligands bind to single-stranded DNA with quite different affinities. Estimates of the charge spacing of single-stranded DNA suggest that poly[d(AT)] is less elongated in the presence of spermidine and hexammine cobalt(III) than it is when complexed with me8spermidine.     

Interaction of poly-5-bromouridylic acid. II. Thermodynamic analysis of its interaction with adenosine and 9-methyladenine

The interaction of poly-5-bromouridylic acid [poly(BU)] with adenosine and 9-methyladenine was studied by equilibrium dialysis, optical melting, and microcalorimetry. The stacking free energy, ω, was estimated as ?17.6 kJ/mol for adenosine·2poly(BU) and ?18.8 kJ/mol for 9-methyladenine·2poly(BU) from the binding isotherms constructed from equilibrium dialysis results. The binding isotherms constructed from a series of melting curves also gave ω values for adenosine·2poly(BU). The thermal stability of the complex depends on monomer concentration, and the partial molar enthalpies of the complex formation at the midpoint of the transition were evaluated from the T_m coefficients as a function of free monomer concentration. The values of ?92.0 and ?90.4 kJ/mol were obtained for adenosine·2poly(BU) and 9-methyladenine·2poly(BU) in 0.4M NaCl–0.02M Na-cacodylate–5 × 10^?4M EDTA (pH 7.0), respectively. Microcalorimetric measurements provided lower integral heats of reaction values for these complexes, i.e., ?73.2 kJ/mol for adenosine·2poly(BU) and ?71.5 kJ/mol for 9-methyladenine·2poly(BU). A comparison with a polyribouridylic acid system provided a quantitative understanding of a stabilization by bromination in terms of thermodynamic parameters.     

The physical and enzymatic properties of Escherichia coli recA protein display anion-specific inhibition.

The enzymatic activities of Escherichia coli recA protein are sensitive to ionic composition. Here we report that sodium glutamate (NaGlu) is much less inhibitory to the DNA strand exchange, DNA-dependent ATPase, and DNA binding activities of the recA protein than is NaCl. Both joint molecule formation and complete exchange of DNA strands occur (albeit at reduced rates) at NaGlu concentrations as high as 0.5 M whereas concentrations of NaCl greater than 0.2 M are sufficient for complete inhibition. The single-stranded DNA (ssDNA)-dependent ATPase activity is even less sensitive to inhibition by NaGlu; ATP hydrolysis stimulated by M13 ssDNA is unaffected by 0.5 M NaGlu and is further stimulated by E. coli ssDNA binding protein approximately 2-fold. Finally, NaGlu has essentially no effect on the stability of recA protein-epsilon M13 DNA complexes, with concentrations of NaGlu as high as 1.5 M failing to dissociate the complexes. Surprisingly, NaGlu also has little effect on the concentration of NaCl required to disrupt the recA protein-epsilon M13 DNA complex, demonstrating that destabilization is dependent on both the concentration and type of anionic rather than cationic species. Quantitative analysis of DNA binding isotherms establishes that the intrinsic binding affinity of recA protein is affected by the anionic species present and that the cooperativity parameter is relatively unaffected. Consequently, the sensitivity of recA protein-ssDNA complexes to disruption by NaCl does not result from the competitive effects associated with cation displacement from the ssDNA upon protein binding but rather results from anion displacement upon complex formation. The magnitude of this anion-specific effect on ssDNA binding is large relative to that of other nucleic acid binding proteins.     

Initiation of DNA replication in delta cya mutants of Escherichia coli K12

The purified DnaA protein has a high affinity for cyclic AMP (cAMP). Using equilibrium dialysis, we determined the K(A) value for cAMP as 0.819 muM(-1). The number of cAMP binding sites per DnaA protein molecule was calculated to be 1.04. This binding was quite specific for cAMP. ATP was also bound by DnaA protein and inhibited cAMP binding. This inhibition was non-competitive in nature with an inhibition constant (K(i)) of about 8.25 muM. However, in vivo we have found not only that the DnaA protein level is reduced in a cyclase deletion mutant strain, Delta++ cya, but also that DnaA protein is not degraded. The Delta cya mutants of E. coli are unable to continue DNA synthesis in the absence of de novo protein synthesis and the initiation of DNA replication in these mutants takes place from oriC.     

Biophysical studies of a ruthenium(II) polypyridyl complex binding to DNA and RNA prove that nucleic acid structure has significant effects on binding behaviors

The interactions of a metal complex [Ru(phen)(2)PMIP](2+) {Ru=ruthenium, phen=1,10-phenanthroline, PMIP=2-(4-methylphenyl)imidazo[4,5-f]1,10-phenanthroline} with yeast tRNA and calf thymus DNA (CT DNA) have been investigated comparatively by UV-vis spectroscopy, fluorescence spectroscopy, viscosity measurements, isothermal titration calorimetry (ITC), as well as equilibrium dialysis and circular dichroism (CD). Spectroscopic studies together with ITC and viscosity measurements indicate that both binding modes of the Ru(II) polypyridyl complex to yeast tRNA and CT DNA are intercalation and yeast tRNA binding of the complex is stronger than CT DNA binding. ITC experiments show that the interaction of the complex with yeast tRNA is driven by a moderately favorable enthalpy decrease in combination with a moderately favorable entropy increase, while the binding of the complex to CT DNA is driven by a large favorable enthalpy decrease with a less favorable entropy increase. The results from equilibrium dialysis and CD suggest that both interactions are enantioselective and the Delta enantiomer of the complex may bind more favorably to both yeast tRNA and CT DNA than the Lambda enantiomer does, and that the complex is a better candidate for an enantioselective binder to yeast tRNA than to CT DNA. Taken together, these results indicate that the structures of nucleic acids have significant effects on the binding behaviors of metal complexes.     

A nitrocellulose filter binding assay for ribonucleotide reductase

Protein B1, one of the two nonidentical subunits of Escherichia coli ribonucleotide reductase, contains two classes of binding sites for nucleoside triphosphates. One class (h-sites), with a high affinity for dATP (KD = 30 nM) regulates the substrate specificity, while the other (l-sites), with a lower affinity for dATP, regulates overall activity. These classes were defined from experiments involving equilibrium dialysis. Here we describe a sensitive alternative method to measure nucleotide binding to ribonucleotide reductases that gave the same results as equilibrium dialysis. The method involves the protein-specific binding of radioactive nucleotides to nitrocellulose filters. We believe that this method will be useful in binding studies with pure reductases from sources other than E. coli, for the characterization of mutants with changed allosteric properties, and as an assay during purification of reductases containing an h-site for dATP.     

Rapid competitive PCR using melting curve analysis for DNA quantification.

A rapid competitive PCR method was developed to quantify DNA on the LightCycler. It rests on the quantitative information contained in the melting curves obtained after amplification in the presence of SYBR Green I. Specific hybridization probes are not required. Heterologous internal standards sharing the same primer binding sites and having different melting temperatures to the natural PCR products were used as competitors. After a co-amplification of known amounts of the competitor with a DNA-containing sample, the target DNA can be quantified from the ratio of the melting peak areas of competitor and target products. The method was developed using 16S rDNA fragments from Streptococcus mutans and E. coli and tested against existing PCR-based DNA quantification procedures. While kinetic analysis of real-time PCR is well established for the quantification of pure nucleic acids, competitive PCR on the LightCycler based on an internal standardization was found to represent a rapid and sensitive alternative DNA quantification method for analysis of complex biological samples that may contain PCR inhibitors.