Specific and nonspecific interactions of integration host factor with oligo DNAs as revealed by circular dichroism spectroscopy and filter binding assay.

Binding specificity of integration host factor (IHF) to oligo DNAs has been studied by circular dichroism (CD) spectroscopy and filter binding experiment. CD difference spectra of IHF-DNA complexes demonstrated that a conformational change in DNA was induced by binding of IHF when DNA had a consensus sequence for the binding sites of IHF, but that such conformational change was not observed for consensus DNA 20 mer as well as nonconsensus DNA 45 mer. Dissociation constants for IHF-DNA complexes determined by filter binding assay showed that IHF has indeed stronger affinity to DNA with the consensus binding site than to nonconsensus DNA, but the difference in its affinity between consensus and nonconsensus DNAs was rather small, 3.4-fold. It was, therefore, concluded that the flanking regions of the consensus sequence are important for the specific binding of IHF and that its binding specificity is well characterized by the induced conformational change in DNA rather than by dissociation constants for IHF-DNA complexes.     

Determination of protein-DNA binding constants and specificities from statistical analyses of single molecules: MutS-DNA interactions

Atomic force microscopy (AFM) is a powerful technique for examining the conformations of protein–DNA complexes and determining the stoichiometries and affinities of protein–protein complexes. We extend the capabilities of AFM to the determination of protein–DNA binding constants and specificities. The distribution of positions of the protein on the DNA fragments provides a direct measure of specificity and requires no knowledge of the absolute binding constants. The fractional occupancies of the protein at a given position in conjunction with the protein and DNA concentrations permit the determination of the absolute binding constants. We present the theoretical basis for this analysis and demonstrate its utility by characterizing the interaction of MutS with DNA fragments containing either no mismatch or a single mismatch. We show that MutS has significantly higher specificities for mismatches than was previously suggested from bulk studies and that the apparent low specificities are the result of high affinity binding to DNA ends. These results resolve the puzzle of the apparent low binding specificity of MutS with the expected high repair specificities. In conclusion, from a single set of AFM experiments, it is possible to determine the binding affinity, specificity and stoichiometry, as well as the conformational properties of the protein–DNA complexes.     

Interaction between synthetic analogues of quinoxaline antibiotics and nucleic acids. Changes in mechanism and specificity related to structural alterations.

The interaction with DNA of six chemically synthesized derivatives of the quinoxaline antibiotics was investigated. Five of the compounds bound only weakly to DNA or not at all; for these substances spectrophotometric measurements, sedimentation studies with closed circular duplex bacteriophage-PM2 DNA and thermal-denaturation profiles were used to determine limits fot the binding constants. No interaction could be detected with two products of degradation of echinomycin (quinomycin A), one of which, echinomycinic acid dimethyl ester, had the lactone linkages opened, whereas the other retained an intact octapeptide ring but had a broken cross-bridge. The other compounds studied were des-N-tetramethyl-triostin A ('TANDEM') and its derivatives. A derivative of 'TANDEM' IN WHICH benzyloxycarbonyl moieties replace both quinoxaline chromophores had binding constants to nucelic acids in the range 10(2)--10(3)-1, whereas no interaction could be detected for a benzyloxycarbonyl derivative that, in addition, had the cross-bridge broken. The derivative of 'TANDEM' with L-serine in place of D-serine in both positions showed no detectable interaction with Clostridium perfringens DNA, whereas the binding constant to poly(dA-dT) was approx 2 X 10(3)M-1. 'TANDEM' itself bound strongly to DNA, and the bathochromic and hypochromic shifts in its u.v.-absorption spectrum in the presence of DNA were similar to those seen with echinomycin. From the effect on the sedimentation coefficient of closed circular duplex bacteriophage-PM2 DNA the mechanism of binding was shown to involve bifunctional intercalation, typical of the naturally occurring quinoxaline antibiotics. Solvent-partition analysis was used to determine binding constants for the interaction between 'TANDEM' and a variety of natural and synthetic DNA species. The pattern of specificity thus revealed differed markedly from that previously found with the naturally occurring quinoxaline antibiotics. Most striking was the evident large preference for (A + T)-rich DNA species, in complete contrast with echinomycin and triostin A. The highest binding constant was found for poly(dA-dT), the interaction with which appeared highly co-operative in character. The conformations adopted by those quinoxaline compounds that bind strongly to DNA were examined withe aid of molecular models on the basis of results derived from n.m.r. and computer studies. It appears that the observed patterns of base-sequence specificity are determined, at least in part, by the structure and conformation of the sulphur-containing cross-bridge.     

Analytic binding isotherms describing competitive interactions of a protein ligand with specific and nonspecific sites on the same DNA oligomer

Many studies of specific protein-nucleic acid binding use short oligonucleotides or restriction fragments, in part to minimize the potential for nonspecific binding of the protein. However, when the specificity ratio is low, multiple nonspecifically bound proteins may occupy the region of DNA corresponding to one specific site; this situation was encountered in our recent calorimetric study of binding of integration host factor (IHF) protein to its specific 34-bp H' DNA site. Here, beginning from the analytical McGhee and von Hippel infinite-lattice nonspecific binding isotherm, we derive a novel analytic isotherm for nonspecific binding of a ligand to a finite lattice. This isotherm is an excellent approximation to the exact factorial-based Epstein finite lattice isotherm even for short lattices and therefore is of great practical significance for analysis of experimental data and for analytic theory. Using this isotherm, we develop an analytic treatment of the competition between specific and nonspecific binding of a large ligand to the same finite lattice (i.e., DNA oligomer) containing one specific and multiple overlapping nonspecific binding sites. Analysis of calorimetric data for IHF-H' DNA binding using this treatment yields enthalpies and binding constants for both specific and nonspecific binding and the nonspecific site size. This novel analysis demonstrates the potential contribution of nonspecific binding to the observed thermodynamics of specific binding, even with very short DNA oligomers, and the need for reverse (constant protein) titrations or titrations with nonspecific DNA to resolve specific and nonspecific contributions. The competition treatment is useful in analyzing low-specificity systems, including those where specificity is weakened by mutations or the absence of specificity factors.     

Massive parallel analysis of DNA-Hoechst 33258 binding specificity with a generic oligodeoxyribonucleotide microchip.

A generic oligodeoxyribonucleotide microchip was used to determine the sequence specificity of Hoechst 33258 binding to double-stranded DNA. The generic microchip contained 4096 oxctadeoxynucleo-tides in which all possible 4(6)= 4096 hexadeoxy-nucleotide sequences are flanked on both the 3'- and 5'-ends with equimolar mixtures of four bases. The microchip was manufactured by chemical immobilization of presynthesized 8mers within polyacrylamide gel pads. A selected set of immobilized 8mers was converted to double-stranded form by hybridization with a mixture of fluorescently labeled complementary 8mers. Massive parallel measurements of melting curves were carried out for the majority of 2080 6mer duplexes, in both the absence and presence of the Hoechst dye. The sequence-specific affinity for Hoechst 33258 was calculated as the increase in melting temperature caused by ligand binding. The dye exhibited specificity for A:T but not G:C base pairs. The affinity is low for two A:T base pairs, increases significantly for three, and reaches a plateau for four A:T base pairs. The relative ligand affinity for all trinucleotide and tetranucleotide sequences (A/T)(3)and (A/T)(4)was estimated. The free energy of dye binding to several duplexes was calculated from the equilibrium melting curves of the duplexes formed on the oligonucleotide microchips. This method can be used as a general approach for massive screening of the sequence specificity of DNA-binding compounds.     

Repertoire selection of variant single-chain Cro: toward directed DNA-binding specificity of helix-turn-helix proteins

A single-chain derivative of the lambda Cro repressor (scCro) has been randomly mutated in amino acid residues critical for specific DNA recognition to create libraries of protein variants. Utilizing phage display-afforded affinity selection, scCro variants have been isolated for binding to synthetic DNA ligands. Isolated scCro variants were analyzed functionally, both in fusion with phage particles and after expression of the corresponding free proteins. The binding properties with regard to specificity and affinity in binding to different DNA ligands were investigated by inhibition studies and determination of equilibrium dissociation constants for formed complexes. Variant proteins with altered DNA-sequence specificity were identified, which favored binding of targeted synthetic DNA sequences over a consensus operator sequence, bound with high affinity by wild-type Cro. The specificities were relatively modest (2-3-fold, as calculated from K(D) values), which can be attributed to the inherent properties in the design of the selection system; one half-site of the synthetic DNA sequences maintains the consensus operator sequence, and one "subunit" of the variant single-chain Cro dimers was conserved as wild-type sequence. The anticipated interaction between the wild-type subunit and the consensus DNA half-site of target DNA ligands is, hence, expected to contribute to the overlap in sequence discrimination. The binding affinity for the synthetic DNA sequences, however, was improved 10-30-fold in selected variant proteins as compared to "wild-type" scCro.     

Equilibrium and kinetic aspects of protein-DNA recognition.

The specificity of regulatory protein binding to DNA is due to a complementarity between the sequence of reaction centres on the protein and the base pair sequence in the specific DNA site allowing the formation of a number of specific noncovalent bonds between the interacting entities. In the present communication the thermodynamic and kinetic aspects of these interactions are considered. The extent of binding specificity is shown to increase with an increase of the bond stability constants and with an increase in the number of ligand reaction centres. Kinetic analysis is carried out assuming that association process is very fast and that dissociation of nonspecific complexes is a rate-limiting step in the recognition of a specific binding site on DNA. The calculations show that a ligand can recognize its specific binding site on DNA within a reasonably limited time interval if the number of its reaction centres and the corresponding stability constants are strongly limited.     

Quantitative footprinting analysis using a DNA-cleaving metalloporphyrin complex

The results of quantitative footprinting studies involving the antiviral agent netropsin and a DNA-cleaving cationic metalloporphyrin complex are presented. An analysis of the footprinting autoradiographic spot intensities using a model previously applied to footprinting studies involving the enzyme DNase I [Ward, B., Rehfuss, R., Goodisman, J., & Dabrowiak, J. C. (1988) Biochemistry 27, 1198-1205] led to very low values for netropsin binding constants on a restriction fragment from pBR-322 DNA. In this work, we show that, because the porphyrin binds with high specificity to DNA, it does not report site loading information in the same manner as does DNase I. We elucidate a model involving binding equilibria for individual sites and include competitive binding of drug and porphyrin for the same site. The free porphyrin and free drug concentrations are determined by binding equilibria with the carrier (calf thymus DNA) which is present in excess and acts as a buffer for both. Given free porphyrin and free netropsin concentrations for each total drug concentration in a series of footprinting experiments, one can calculate autoradiographic spot intensities in terms of the binding constants of netropsin to the various sites on the 139 base pair restriction fragment. The best values of these binding constants are determined by minimizing the sum of the squared differences between calculated and experimental footprinting autoradiographic spot intensities. Although the determined netropsin binding constants are insensitive to the value assumed for the porphyrin binding constant toward its highest affinity sites, the best mean-square deviation between observed and calculated values, D, depends on the choice of (average) drug binding constant to carrier DNA, Kd.(ABSTRACT TRUNCATED AT 250 WORDS)     

Nucleotides flanking a conserved TAAT core dictate the DNA binding specificity of three murine homeodomain proteins.

Murine homeobox genes play a fundamental role in directing embryogenesis by controlling gene expression during development. The homeobox encodes a DNA binding domain (the homeodomain) which presumably mediates interactions of homeodomain proteins with specific DNA sites in the control regions of target genes. However, the bases for these selective DNA-protein interactions are not well defined. In this report, we have characterized the DNA binding specificities of three murine homeodomain proteins, Hox 7.1, Hox 1.5, and En-1. We have identified optimal DNA binding sites for each of these proteins by using a random oligonucleotide selection strategy. Comparison of the sequences of the selected binding sites predicted a common consensus site that contained the motif (C/G)TAATTG. The TAAT core was essential for DNA binding activity, and the nucleotides flanking this core directed binding specificity. Whereas variations in the nucleotides flanking the 5' side of the TAAT core produced modest alterations in binding activity for all three proteins, perturbations of the nucleotides directly 3' of the core distinguished the binding specificity of Hox 1.5 from those of Hox 7.1 and En-1. These differences in binding activity reflected differences in the dissociation rates rather than the equilibrium constants of the protein-DNA complexes. Differences in DNA binding specificities observed in vitro may contribute to selective interactions of homeodomain proteins with potential binding sites in the control regions of target genes.     

Divalent metal dependence of site-specific DNA binding by EcoRV endonuclease.

Measurements of binding equilibria of EcoRV endonuclease to DNA, for a series of base-analogue substrates, demonstrate that expression of sequence selectivity is strongly enhanced by the presence of Ca2+ ions. Binding constants were determined for short duplex oligodeoxynucleotides containing the cognate DNA site, three cleavable noncognate sites, and a fully nonspecific site. At pH 7.5 and 100 mM NaCl, the full range of specificity from the specific (tightest binding) to nonspecific (weakest binding) sites is 0.9 kcal/mol in the absence of metal ions and 5.8 kcal/mol in the presence of Ca2+. Precise determination of binding affinities in the presence of the active Mg2+ cofactor was found to be possible for substrates retaining up to 1.6% of wild-type activity, as determined by the rate of phosphoryl transfer. These measurements show that Ca2+ is a near-perfect analogue for Mg2+ in binding reactions of the wild-type enzyme with DNA base-analogue substrates, as it provides identical DeltaDeltaG degrees bind values among the cleavable noncognate sites. Equilibrium dissociation constants of wild-type and base-analogue sites were also measured for the weakly active EcoRV mutant K38A, in the presence of either Mg2+ or Ca2+. In this case, Ca2+ allows expression of a greater degree of specificity than does Mg2+. DeltaDeltaG degrees bind values of K38A toward specific versus nonspecific sites are 6.1 kcal/mol with Ca2+ and 3.9 kcal/mol with Mg2+, perhaps reflecting metal-specific conformational changes in the ground-state ternary complexes. The enhancement of binding specificity provided by divalent metal ions is likely to be general to many restriction endonucleases and other metal-dependent nucleic acid-modifying enzymes. These results strongly suggest that measurements of DNA binding affinities for EcoRV, and likely for many other restriction endonucleases, should be performed in the presence of divalent metal ions.     

Base- and sequence-dependent binding of aristololactam beta-D-glucoside to deoxyribonucleic acid

The dependence on base-pair composition and sequence specificity of the (aristololactam beta-D-glucoside)-DNA interaction was examined by spectrophotometric, spectrofluorometric, spectropolarimetric, thermal melting, thermodynamic, and viscometric studies. Binding of this alkaloid to various natural and synthetic DNAs was dependent upon the base composition and sequences of DNA. The binding parameters obtained from spectrophotometric analysis, according to an excluded-site model, indicated a relatively high affinity of the alkaloid binding to GC-rich DNA and alternating GC polymer. This affinity was further evidenced by the quenching of fluorescence intensity, decrease in quantum yield, and perturbations in circular dichroic spectrum. The alkaloid stabilized all DNAs against thermal denaturation. The temperature dependence of the binding constants was used to estimate the thermodynamic parameters involved in the complex formation of the alkaloid with various DNAs. The negative enthalpy and entropy change increased with increasing GC content of DNA and also compensated one another to produce a relatively small Gibbs free energy change. Viscometric studies showed that in the strong binding region the increase of contour length of DNA depended strongly on its base composition and sequence of bases, being larger for GC-rich DNA and alternating GC polymer. On the basis of these observations, it is concluded that the alkaloid binds to DNA by a mechanism of intercalation and exhibits considerable specificity toward alternating GC polymer.     

Influence of ionic strength on Hoechst 33258 binding with DNA

The binding of Hoechst 33258 with DNA at various ionic strengths of solution and different ligand concentrations has been investigated. Existence of more than one type of interactions of Hoechst 33258 with DNA has been revealed, which were very sensitive to the ionic strength. Hoechst 33258 doesn't show specificity to AT sequences of DNA at low ionic strength. High affinity binding mode becomes obvious at high ionic strength. The values of binding constants and binding site sizes for revealed strong and weak interactions have been determined.     

Thermodynamic and kinetic basis for the relaxed DNA sequence specificity of "promiscuous" mutant EcoRI endonucleases

Promiscuous mutant EcoRI endonucleases produce lethal to sublethal effects because they cleave Escherichia coli DNA despite the presence of the EcoRI methylase. Three promiscuous mutant forms, Ala138Thr, Glu192Lys and His114Tyr, have been characterized with respect to their binding affinities and first-order cleavage rate constants towards the three classes of DNA sites: specific, miscognate (EcoRI*) and non-specific. We have made the unanticipated and counterintuitive observations that the mutant restriction endonucleases that exhibit relaxed specificity in vivo nevertheless bind more tightly than the wild-type enzyme to the specific recognition sequence in vitro, and show even greater preference for binding to the cognate GAATTC site over miscognate sites. Binding preference for EcoRI* over non-specific DNA is also improved. The first-order cleavage rate constants of the mutant enzymes are normal for the cognate site GAATTC, but are greater than those of the wild-type enzyme at EcoRI* sites. Thus, the mutant enzymes use two mechanisms to partially bypass the multiple fail-safe mechanisms that protect against cleavage of genomic DNA in cells carrying the wild-type EcoRI restriction-modification system: (a) binding to EcoRI* sites is more probable than for wild-type enzyme because non-specific DNA is less effective as a competitive inhibitor; (b) the combination of increased affinity and elevated cleavage rate constants at EcoRI* sites makes double-strand cleavage of these sites a more probable outcome than it is for the wild-type enzyme. Semi-quantitative estimates of rates of EcoRI* site cleavage in vivo, predicted using the binding and cleavage constants measured in vitro, are in accord with the observed lethal phenotypes associated with the three mutations.     

Massive parallel analysis of the binding specificity of histone-like protein HU to single- and double-stranded DNA with generic oligodeoxyribonucleotide microchips

A generic hexadeoxyribonucleotide microchip has been applied to test the DNA-binding properties of HU histone-like bacterial protein, which is known to have a low sequence specificity. All 4096 hexamers flanked within 8mers by degenerate bases at both the 3′- and 5′-ends were immobilized within the 100 × 100 × 20 mm polyacrylamide gel pads of the microchip. Single-stranded immobilized oligonucleotides were converted in some experiments to the double-stranded form by hybridization with a specified mixture of 8mers. The DNA interaction with HU was characterized by three type of measurements: (i) binding of FITC-labeled HU to microchip oligonucleotides; (ii) melting curves of complexes of labeled HU with single-stranded microchip oligonucleotides; (iii) the effect of HU binding on melting curves of microchip double-stranded DNA labeled with another fluorescent dye, Texas Red. Large numbers of measurements of these parameters were carried out in parallel for all or many generic microchip elements in real time with a multi-wavelength fluorescence microscope. Statistical analysis of these data suggests some preference for HU binding to G/C-rich single-stranded oligonucleotides. HU complexes with double-stranded microchip 8mers can be divided into two groups in which HU binding either increased the melting temperature (T_m) of duplexes or decreased it. The stabilized duplexes showed some preference for presence of the sequence motifs AAG, AGA and AAGA. In the second type of complex, enriched with A/T base pairs, the destabilization effect was higher for longer stretches of A/T duplexes. Binding of HU to labeled duplexes in the second type of complex caused some decrease in fluorescence. This decrease also correlates with the higher A/T content and lower T_m. The results demonstrate that generic microchips could be an efficient approach in analysis of sequence specificity of proteins.     

Kinetics and binding of the thymine-DNA mismatch glycosylase,Mig-Mth,with mismatch-containing DNA substrates

We have examined the removal of thymine residues from T-G mismatches in DNA by the thymine-DNA mismatch glycosylase from Methanobacterium thermoautrophicum (Mig-Mth), within the context of the base excision repair (BER) pathway, to investigate why this glycosylase has such low activity in vitro. Using single-turnover kinetics and steady-state kinetics, we calculated the catalytic and product dissociation rate constants for Mig-Mth, and determined that Mig-Mth is inhibited by product apyrimidinic (AP) sites in DNA. Electrophoretic mobility shift assays (EMSA) provide evidence that the specificity of product binding is dependent upon the base opposite the AP site. The binding of Mig-Mth to DNA containing the non-cleavable substrate analogue difluorotoluene (F) was also analyzed to determine the effect of the opposite base on Mig-Mth binding specificity for substrate-like duplex DNA. The results of these experiments support the idea that opposite strand interactions play roles in determining substrate specificity. Endonuclease IV, which cleaves AP sites in the next step of the BER pathway, was used to analyze the effect of product removal on the overall rate of thymine hydrolysis by Mig-Mth. Our results support the hypothesis that endonuclease IV increases the apparent activity of Mig-Mth significantly under steady-state conditions by preventing reassociation of enzyme to product.     

Specific and non-specific interactions of integration host factor with DNA: thermodynamic evidence for disruption of multiple IHF surface salt-bridges coupled to DNA binding.

Site-specific DNA binding of architectural protein integration host factor (IHF) is involved in formation of functional multiprotein-DNA assemblies in Escherichia coli, while non-specific binding of IHF and other histone-like proteins serves to structure the nucleoid. Here, we report an isothermal titration calorimetry study of the thermodynamics of binding IHF to a 34 bp fragment composed entirely of the specific H' site from lambda-phage DNA. At low to moderate [K(+)] (60-100 mM), strong competition is observed between specific and non-specific binding as a result of a low specificity ratio (approximately 10(2)) and a very small non-specific site size. In this [K(+)] range, both specific and non-specific binding are enthalpy-driven, with large negative enthalpy, entropy and heat capacity changes and binding constants that are insensitive to [K(+)]. Above 100 mM K(+), only specific binding is observed, and both the binding constant and the magnitudes of enthalpy, entropy and heat capacity changes all decrease strongly with increasing [K(+)]. When interpreted in the context of the structure of the specific complex, the thermodynamics provide compelling evidence for a previously unrecognized design principle by which proteins that form extensive binding interfaces with nucleic acids control binding constants, binding site sizes and effects of temperature and ion concentrations on stability and specificity. We propose that up to 22 of the 23 IHF cationic side-chains that are located within 6 A of DNA phosphate oxygen atoms in the complex, are masked in the absence of DNA by pairing with anionic carboxylate groups in intramolecular salt-bridges (dehydrated ion-pairs). These salt-bridges increase in stability with increasing temperature and decreasing [K(+)]. To explain the unusual thermodynamics of IHF-DNA interactions, we propose that both specific and non-specific binding at low [K(+)] require disruption of salt-bridges (as many as 18 for specific binding) whereupon many of the unmasked charged groups hydrate and the cationic groups interact with DNA. From structural or thermodynamic parallels with IHF, we propose that large-scale coupling of disruption of protein salt-bridges to DNA binding is significant for other large-interface DNA wrapping proteins including the nucleosome, lac repressor core tetramer, RNA polymerase core protein, HU and SSB.     

Binding of platinum(II) intercalation reagents to deoxyribnonucleic acid. Dependence on base-pair composition, nature of the intercalator, and ionic strength.

The DNA binding of three platinum(II) intercalation reagents has been studied and found to depend upon base composition, the nature of the intercalator, and the ionic strength of the solvent medium. In 0.2 M NaCl, binding data for calf thymus DNA show the association constants to be approximately 10(4) M-1. The binding constants decrease in the order [(o-phen)Pt(en)]2+ greater than or equal to [(terpy)Pt(HET)]+ greater than [(bipy)Pt(en)]2+. The number of available intercalation sites for the doubly charged intercalators is only 70% of the number expected from the nearest-neighbor exclusion model. Binding of [(o-phen)Pt(en)]2+ and [(terpy)Pt(HET)]+ to various DNAs depends linearly on G.C content. Both reagents exhibit essentially the same degree of G.C specificity. Intercalative binding is a function of ionic strength. Increasing the salt concentration minimizes the importance of metallointercalator charge, and extrapolation to 1 M salt reveals the intercalative abilities, as reflected in binding constants, to be equivalent for [(terpy)Pt(HET)]+ and [o-phen)Pt(en)]2+ and about 1 order of magnitude less than that of ethidium.     

Bifunctional intercalation and sequence specificity in the binding of quinomycin and triostin antibiotics to deoxyribonucleic acid.

Quinomycin C, triostin A and triostin C are peptide antibiotics of the quinoxaline family, of which echinomycin (quinomycin A) is also a member. They all remove and reverse the supercoiling of closed circular duplex DNA from bacteriophage PM2 in the fashion characteristic of intercalating drugs, and the unwinding angle at I 0.01 is, in all cases, almost twice that of ethidium. Thus, as with echinomycin, they can be characterized as bifunctional intercalating agents. For the triostins this conclusion has been confirmed by measurements of changes in the viscosity of sonicated rod-like DNA fragments; the helix extension was found to be almost double that expected for a simple monofunctional intercalation process. For triostin A, further evidence for bifunctionality was derived from the cross-over point of binding isotherms to nicked circular and closed circular bacteriophage-PM2DNA. Binding curves for the interaction of quinomycin C and triostin A with a variety of synthetic and naturally occurring nucleic acids were determined by solvent-partition analysis, but triostin C was too insoluble in aqueous solution to make this method applicable. For quinomycin C the highest binding constant was found with Micrococcus lysodeikticus DNA, and its pattern of specificity among natural DNA species was broadly similar to that of echinomycin, although the binding constants were 2--6 times as large. For triostin A the highest binding constant was again found for M. lysodeikticus DNA, but the specificity pattern was quite different from that of the quinomycins. In particular, triostin A bound better to poly(dA-dT) than to the poly(dG-dC) whereas this order was reversed for quinomycin C. There was also evidence that the binding to poly(dA-dT) might be co-operative in nature. No significant interaction could be detected with poly(dA).poly(dT) or with RNA from Escherichia coli. Poly(dG).poly(dC) gave variable results, depending on the source of the polymer. The different patterns of specificity displayed by the quinomycins and triostins are tentatively ascribed to differences in their conformations in solution.