Interaction of echinomycin with An.Tn. and (AT)n regions flanking its CG binding site.

We have prepared DNA fragments containing the sequences A15CGT15, T15CGA15 and T(AT)8CG(AT)15 cloned within the SmaI site of the pUC19 polylinker. These have been used as substrates in footprinting experiments with DNase I and diethylpyrocarbonate probing the effects of echinomycin, binding to the central CG, on the structure of the surrounding sequences. No clear DNase I footprints are seen with T15CGA15 though alterations in the nuclease susceptibility of surrounding regions suggest that the ligand is binding, albeit weakly at this site. All the other fragments show the expected footprints around the CG site. Regions of An and Tn are rendered much more reactive to DNase I and adenines on the 3'-side of the CG become hyperreactive to diethylpyrocarbonate. Regions of alternating AT show unusual changes in the presence of the ligand. At low concentrations (5 microM) cleavage of TpA is enhanced, whereas at higher concentrations a cleavage pattern with a four base pair repeat is evident. A similar pattern is seen with micrococcal nuclease. Modification by diethylpyrocarbonate is strongest at alternate adenines which are staggered in the 5'-direction across the two strands. We interpret these changes by suggesting secondary drug binding within regions of alternating AT, possibly to the dinucleotide ApT. DNase I footprinting experiments performed at 4 degrees C revealed neither enhancements nor footprints for flanking regions of homopolymeric A and T suggesting that the conformational changes are necessary consequence of drug binding.     

Effects of the antitumor antibiotic mithramycin on the structure of repetitive DNA regions adjacent to its GC-rich binding site.

Regions of An.Tn, (GA)n.(TC)n, and (GT)n.(AC)n have been cloned into the SmaI (CCC/GGG) site of plasmid pUC19. HindIII-EcoRI restriction fragments containing these inserts have been used as substrates for footprinting experiments using DNase I, DNase II, and micrococcal nuclease as probes. These present good mithramycin binding sites (GGG) flanking repetitive regions to which the drug does not bind. In each case, mithramycin footprints are observed at the CCC/GGG sites, which are not affected by the nature of the surrounding sequences. Some weaker binding is detected at TCGA and ACCA sites and at regions of alternating GA. No binding is found to regions of alternating GT. An.Tn inserts (n = 23 or 69) are normally resistant to cleavage by all these probes; in the presence of mithramycin, a dramatic increase in DNase I cleavage is observed throughout the entire insert and is indicative of an alteration in DNA structure. Similar changes are seen with DNase II and micrococcal nuclease. These changes cannot be explained by invoking changes in the ratio of free substrate to cleavage agent. In contrast, cleavage of (GA)n.(CT)n and (GT)n.(AC)n inserts is not affected by drug binding. The results are consistent with a model in which mithramycin causes dramatic changes in the width of the DNA minor groove, generating a structure which has some properties of A-DNA, and suggest that this can be propagated into surrounding DNA regions in a sequence-dependent manner. The structural alterations with An.Tn are highly cooperative and can be transmitted over at least three turns of the DNA helix.     

Interaction of Hoechst 33258 and echinomycin with nucleosomal DNA fragments containing isolated ligand binding sites

We have examined the interaction of Hoechst 33258 and echinomycin with nucleosomal DNA fragments which contain isolated ligand binding sites. A 145 base pair fragment was prepared on the basis of the sequence of tyrT DNA, which contained no CpG or (A/T)(4) binding sites for these ligands. Isolated binding sites were introduced into this fragment at discrete locations where the minor groove is known to face toward or away from the protein core when reconstituted onto nucleosome core particles. The interaction of ligands with target sites on these nucleosomal DNA fragments was assessed by DNase I footprinting. We find that Hoechst 33258 can bind to single nucleosomal sites which face both toward and away from the protein core, without affecting the nucleosome structure. Hoechst binding is also observed on nucleosomal fragments which contain two or more drug binding sites, though in these cases the footprints are accompanied by the presence of new cleavage products in positions which suggest that the ligand has caused a proportion of the DNA molecules to adopt a new rotational positioning on the protein surface. Hoechst 33258 does not affect nucleosome reconstitution with any of these fragments. In contrast, the bifunctional intercalating antibiotic echinomycin is not able to bind to single nucleosomal CpG sites. Echinomycin footprints are observed on nucleosomal fragments containing two or more CpG sites, but there are no changes in the cleavage patterns in the remainder of the fragment. Echinomycin abolishes nucleosome reconstitution when included in the reconstitution mixture.     

Methidiumpropyl-EDTA.Fe(II) and DNase I footprinting report different small molecule binding site sizes on DNA.

DNase I and MPE.Fe (II) footprinting both employ partial cleavage of ligand-protected DNA restriction fragments and Maxam-Gilbert sequencing gel methods of analysis. One method utilizes the enzyme, DNase I, as the DNA cleaving agent while the other employs the synthetic molecule, methidium-propyl-EDTA (MPE). For actinomycin D, chromomycin A3 and distamycin A, DNase I footprinting reports larger binding site sizes than MPE.Fe (II). DNase I footprinting appears more sensitive for weakly bound sites. MPE.Fe (II) footprinting appears more accurate in determining the actual size and location of the binding sites for small molecules on DNA, especially in cases where several small molecules are closely spaced on the DNA. MPE.Fe (II) and DNase I report the same sequence and binding site size for lac repressor protein on operator DNA.     

Sequence specificity of the binding of 9-aminoacridine- and amsacrine-4-carboxamides to DNA studied by DNase I footprinting.

DNase I footprinting has been used to probe the sequence selectivity of binding of a series of intercalating amsacrine-4-carboxamides and a related 9-aminoacridine-4-carboxamide to three DNA restriction fragments. These ligands have good experimental antileukemic activity, and for those members of the series that gave evaluable footprints, our principal finding is that they bind preferentially to GC-rich regions in agreement with the conclusion of equilibrium and kinetic measurements. The highest affinity sites generally occur in clusters of GC base pairs with runs of AT pairs being excluded from binding. It is important to appreciate that the 9-aminoacridine- and amsacrine-4-carboxamides exhibit a very high degree of selectivity for GC sites which, to our knowledge, has not been previously matched by acridine derivatives in footprinting experiments. The principal determinant of specificity appears to be the 4-carboxamide group itself since neither variations in the terminal funtionality of the 4-carboxamide sidechain nor the presence of the 9-anilino substituent modifies sequence preferences. The molecular origins of selectivity may be discerned in terms of potential hydrogen bonding interactions between the 4-carboxamide moiety and carbonyl oxygen and amino groups of GC base pairs in the DNA minor groove at CG dinucleotide sites. The related therapeutic agent amsacrine failed to inhibit cleavage by DNase I, so no conclusion can be drawn concerning its binding selectivity, save to note that amsacrine does not possess the 4-carboxamide group which appears to be the crucial determinant of GC specificity. Whether selectivity for binding to GC-rich sequences is an important element in the antitumor activity of both the 9-aminoacridine- and amsacrine-4-carboxamides remains to be determined.     

Determinants of affinity and mode of DNA binding at the carboxy terminus of the bacteriophage SPO1-encoded type II DNA-binding protein, TF1.

The role of the carboxy-terminal amino acids of the bacteriophage SPO1-encoded type II DNA-binding protein, TF1, in DNA binding was analyzed. Chain-terminating mutations truncating the normally 99-amino-acid TF1 at amino acids 96, 97, and 98 were constructed, as were missense mutations substituting cysteine, arginine, and serine for phenylalanine at amino acid 97 and tryptophan for lysine at amino acid 99. The binding of the resulting proteins to a synthetic 44-bp binding site in 5-(hydroxymethyl)uracil DNA, to binding sites in larger SPO1 [5-(hydroxymethyl)uracil-containing] DNA fragments, and to thymine-containing homologous DNA was analyzed by gel retardation and also by DNase I and hydroxy radical footprinting. We conclude that the C tail up to and including phenylalanine at amino acid 97 is essential for DNA binding and that the two C-terminal amino acids, 98 and 99, are involved in protein-protein interactions between TF1 dimers bound to DNA.     

Visualising the kinetics of dissociation of actinomycin from individual sites in mixed sequence DNA by DNase I footprinting.

We have investigated the kinetics of dissociation of actinomycin D from DNA by a variation of the footprinting technique. Complexes of actinomycin with a radiolabelled DNA fragment (tyrT) were dissociated by addition of a large excess of unlabelled calf thymus DNA and the mixture subjected to DNase I footprinting at subsequent intervals. The rates at which the footprints disappeared varied between the different binding sites. The dissociation was temperature dependent with average time constants of 30 s, 10 mins and 2 hours at temperatures of 37 degrees C, 20 degrees C and 4 degrees C respectively. The dissociation from a DNA fragment containing the synthetic insert T9GCA9 was significantly faster, with a half-life of about 1 min at 20 degrees C. In contrast, the dissociation of distamycin was too fast to measure (< 5 s) even at 4 degrees C.     

Engineering of Substrate Selectivity for Tissue Factor·Factor VIIa Complex Signaling through Protease-activated Receptor 2

The complex of factor VIIa (FVIIa) with tissue factor (TF) triggers coagulation by recognizing its macromolecular substrate factors IX (FIX) and X (FX) predominantly through extended exosite interactions. In addition, TF mediates unique cell-signaling properties in cancer, angiogenesis, and inflammation that involve proteolytic cleavage of protease-activated receptor 2 (PAR2). PAR2 is cleaved by FVIIa in the binary TF·FVIIa complex and by FXa in the ternary TF·FVIIa·FXa complex, but physiological roles of these signaling complexes are incompletely understood. In a screen of FVIIa protease domain mutants, three variants (Q40A, Q143N, and T151S) activated macromolecular coagulation substrates and supported signaling of the ternary TF·FVIIa-Xa complex normally but were severely impaired in binary TF·FVIIa·PAR2 signaling. The residues identified were located in the model-predicted S2′ pocket of FVIIa, and complementary PAR2 P2′ Leu-38 replacements demonstrated that the P2′ side chain was indeed crucial for PAR2 cleavage by TF·FVIIa. In addition, PAR2 was activated more efficiently by FVIIa T99Y, consistent with further contributions from the S2 subsite. The P2 residue preference of FVIIa and FXa predicted additional PAR2 mutants that were efficiently activated by TF·FVIIa but resistant to cleavage by the alternative PAR2 activator FXa. Thus, contrary to the paradigm of exosite-assisted cleavage of PAR1 by thrombin, the cofactor-associated protease FVIIa recognizes PAR2 predominantly by catalytic cleft interactions. Furthermore, the delineated molecular details of this substrate interaction enabled protein engineering of protease-selective PAR2 receptors that will aid further studies to dissect the roles of TF signaling complexes in vivo.     

Nucleic acid fragmentation on the millisecond timescale using a conventional X-ray rotating anode source: application to protein–DNA footprinting

Nucleic acid fragmentation (footprinting) by ·OH radicals is used often as a tool to probe nucleic acid structure and nucleic acid–protein interactions. This method has proven valuable because it provides structural information with single base pair resolution. Recent developments in the field introduced the ‘synchrotron X-ray footprinting’ method, which uses a high-flux X-ray source to produce single base pair fragmentation of nucleic acid in tens of milliseconds. We developed a complementary method that utilizes X-rays generated from a conventional rotating anode machine in which nucleic acid footprints can be generated by X-ray exposures as short as 100–300 ms. Our theoretical and experimental studies indicate that efficient cleavage of nucleic acids by X-rays depends upon sample preparation, energy of the X-ray source and the beam intensity. In addition, using this experimental set up, we demonstrated the feasibility of conducting X-ray footprinting to produce protein–DNA protection portraits at sub-second timescales.