Heterogeneous DNA binding modes of berenil.

Isothermal titration calorimetry (ITC) profiles of berenil bound to different DNAs show that, despite the strong preference of berenil for AT-rich regions in DNA, it can bind to other DNA sequences significantly. The ITC results were used to quantify the binding of berenil, and the thermodynamic profiles were obtained using natural DNAs as well as synthetic polynucleotides. ITC binding isotherms cannot be simply described when a single set of identical binding sites is considered, except for poly[d(A-T)2]. Ultraviolet melting of DNA and differential scanning calorimetry were also used to quantify several aspects of the binding of berenil to salmon testes DNA. We present evidence for secondary binding sites for berenil in DNA, corresponding to G+C rich sites. Berenil binding to poly[d(G-C)2] is also observed. Circular dichroism experiments showed that binding to GC-rich sites involves drug intercalation. Using a molecular modeling approach we demonstrate that intercalation of berenil into CpG steps is sterically feasible.     

Bifunctional intercalator [N-MeCys3,N-MeCys7]TANDEM binds to the dinucleotide TpA.

The binding of [N-MeCys3,N-MeCys7]TANDEM has been examined by DNase I footprinting and diethyl pyrocarbonate modification of several synthetic DNA fragments containing AT-rich regions. DNase I footprinting reveals that at low concentrations the ligand binds preferentially to the center of (AT)n regions. A fragment containing the tetranucleotide AATT was unaffected by the ligand. Diethyl pyrocarbonate modification of several fragments containing blocks of (AT)n revealed a pattern in which alternate adenines were rendered more reactive in the presence of the ligand. These reactive adenines were staggered across the two DNA strands in the 3'-direction, consistent with ligand binding to the dinucleotide TpA. In sequences of the type (TAA)n.(TTA)n, binding of [N-MeCys3,N-MeCys7]TANDEM resulted in strong modification of the second adenine in the sequence TAA, i.e., the base on the 3'-side of the ligand binding site. Data for binding to (AT)n are best explained by suggesting that the adenines sandwiched between the quinoxaline chromophores are rendered most reactive to diethyl pyrocarbonate.     

The structure of the initiation complex at the replication origin, oriC, of Escherichia coli.

Two distinct regions in the replication origin, oriC, of Escherichia coli are separately distorted upon initiation complex formation by the initiator protein DnaA. The AT-rich region in the left part of oriC and the start site region in the right part of oriC. Chemical modification of single-stranded DNA was observed at both regions whereas endonuclease recognition of DNA mini-bulges specifically occurred in the start site region. We show that the helical phasing of binding sites for DnaA protein in oriC is important for origin function. An insertion or deletion of one helical turn between the two rightmost binding sites does not alter the efficiency of replication initiation, whereas all modifications of distance by less or more than one helical turn result in inactivation of oriC. DnaA binding and helical distortions in the AT-rich region as well as in the start site region are not affected in the distance mutants irrespective of their functionality in vivo. We propose a specific compact nucleoprotein structure for the initiation complex.     

New fluorescence reactions in DNA cytochemistry. 1. Microscopic and spectroscopic studies on nonrigid fluorochromes

Some nonrigid DNA-binding antibiotics and fluorochromes that recognize adenine-thymine (AT) sequences are widely applied in biomedical research, but the microscopic use, spectral characteristics and DNA binding modes of other similar compounds have been overlooked or scarcely explored. After treatment with thioflavine T, auramine O and G, curcumin, bis-aminophenyl-oxadiazol, berenil and distamycin A, a bright DNA-dependent fluorescence reaction was found in the chromatin of interphase nuclei, meiotic and polytene chromosomes, spermatozoa heads and kinetoplasts of Trypanosoma cruzi epimastigotes. Nucleoli and basophilic cytoplasm showed low or no fluorescence; the highest emission occurred in the AT-rich kinetoplast DNA. When bound to DNA or in the presence of alpha-cyclodextrin and viscous solvents or cosolutes, nonrigid compounds revealed a striking enhancement of fluorescence. The results indicate that these new or poorly known fluorochromes bind selectively to DNA-containing structures and that the minor groove from AT-rich DNA regions could represent the specific and highly fluorescent binding site.     

Interactions of DNA binding ligands with PNA-DNA hybrids.

The interactions of two representative mixed-sequence (one with an AT-stretch) PNA-DNA duplexes (10 or 15 base-pairs) and a PNA2/DNA triplex with the DNA binding reagents distamycin A, 4',6-diamidino-2-phenylindole (DAPI), ethidium bromide, 8-methoxy-psoralen and the delta and lambda enantiomers of Ru(phen)2-dppz2+ have been investigated using optical spectroscopic methods. The behaviour of these reagents versus two PNA-PNA duplexes has also been investigated. With triple helical poly(dA)/(H-T10-Lys-NH2)2 no significant intercalative binding was detected for any of the DNA intercalators, whereas DAPI, a DNA minor groove binder, was found to exhibit a circular dichroism with a positive sign and amplitude consistent with minor groove binding. Similarly, a PNA-DNA duplex containing a central AATA motif, a typical minor groove binding site for the DNA minor groove binders distamycin A and DAPI, showed binding for both of these drugs, though with strongly reduced affinity. No important interactions were found for any of the ligands with a PNA-DNA duplex consisting of a ten base-pair mixed purine-pyrimidine sequence with only two AT base-pairs in the centre. Nor did any of the ligands show any detectable binding to the PNA-PNA duplexes (one containing an AATT motif). Various PNA derivatives with extentions of the backbone, believed to increase the flexibility of the duplex to opening of an intercalation slot, were tested for intercalation of ethidium bromide or 8-methoxypsoralen into the mixed sequence PNA-DNA duplex, however, without any observation of improved binding. The importance of the ionic contribution of the deoxyribose phosphate backbone, versus interactions with the nucleobases, for drug binding to DNA is discussed in the light of these findings.     

DNA sequence preferences of several AT-selective minor groove binding ligands.

We have examined the interaction of distamycin, netropsin, Hoechst 33258 and berenil, which are AT-selective minor groove-binding ligands, with synthetic DNA fragments containing different arrangements of AT base pairs by DNase I footprinting. For fragments which contain multiple blocks of (A/T)4 quantitative DNase I footprinting reveals that AATT and AAAA are much better binding sites than TTAA and TATA. Hoechst 33258 shows that greatest discrimination between these sites with a 50-fold difference in affinity between AATT and TATA. Alone amongst these ligands, Hoechst 33258 binds to AATT better than AAAA. These differences in binding to the various AT-tracts are interpreted in terms of variations in DNA minor groove width and suggest that TpA steps within an AT-tract decrease the affinity of these ligands. The behaviour of each site also depends on the flanking sequences; adjacent pyrimidine-purine steps cause a decrease in affinity. The precise ranking order for the various binding sites is not the same for each ligand.     

Sequence-specific binding of echinomycin to DNA: evidence for conformational changes affecting flanking sequences.

The technique of DNAase I footprinting has been used to investigate preferred binding sites for echinomycin on a 160-base-pair DNA fragment from E. coli containing the tyr T promoter sequence. Six binding sites have been precisely located in the sequence; a seventh has been partially identified. The minimum site-size is six base pairs. All the binding sites contain the dinucleotide sequence CpG but no other regularities can be discerned. When the protected regions on each complementary strand are compared it is evident that they are staggered by 2-3 base-pairs towards the 3' end at each site. Footprinting with DNAase II reports a similar, though less precise, pattern of protection. Cutting by both enzymes is markedly enhanced at AT-rich regions flanking the antibiotic-binding sites. This increased susceptibility to nuclease attack can be attributed to an altered helix conformation in the vicinity of the bis-intercalated echinomycin molecule. It seems that certain sequences, mainly runs of A or runs of T, switch from a nuclease-resistant to a nuclease-sensitive form when echinomycin binds nearby.     

Induction of DNA bending by bifunctional intercalating agents of the 7H-pyridocarbazole family

The structures and binding energetics of selected complexes formed between the deoxynucleotides d(CpGpGpCpG).d(CpGpCpCpG), d(CpGpApTpCpG)2, d(GpCpGpCpCpG).d(CpGpGpCpGpC), and d(CpGpCpCpCpG)2 with the DNA bifunctional intercalating agent ditercalinium and three of its rigid linking chain derivatives have been investigated theoretically by means of a molecular mechanics approach that takes into account nucleic acid flexibility, ligand flexibility and solvent dielectric effects (R. Lavery, in: Unusual DNA structures, eds S. Harvey and R. Wells (Pergamon, New York, 1988) p. 189; R. Lavery, in: DNA bending and curvature, eds W.K. Olson et al. (Adenine Press, New York, 1988) p. 191). The piperidinium chains of the bis-intercalating ligands are always located in the major groove of DNA. For the energy-minimized complexes the ligand proceeds to bind following preferentially the 5'-pyrimidine-purine-3' alternating sequence, thus dictating the number of internal exclusion sites. The complexes with three exclusion sites will present (i) a bending of the structure towards the major groove, and (ii) a non-ideal distribution of unwinding angles; complexes with less than three exclusion sites will remain essentially linear. The absence of a bend does not preclude other types of local deformations of the base-pairs such as inclination, buckle and tip. The proposed structures of the d(CpGpApTpCpG)2 complexes are in agreement with NMR structural results. The possible relevance of these findings to a previously proposed mode of interaction for ditercalinium-like DNA ligands is discussed.     

Sequence-dependent flexibility in promoter sequences

The non-neighbor interactions between base-pairs were taken into account to calculate the angular parameters (Omega, rho and tau) describing the orientation of successive base-pair planes and the translation parameters (D(y)) along the long axis of base-pair steps for 36 independent tetramers. A statistical mechanical model was proposed to predict the DNA flexibility that is mainly related to the thermal fluctuations at individual base-pair steps. The DNA flexibility can be described by the root-mean-square deviation of the end-to-end distance of DNA helical structure. The present model was then used to investigate the extreme flexible pattern in prokaryotic and eukaryotic promoter sequences. The results demonstrated several extreme flexible regions related to functionally important elements exist both in prokaryotic promoters and in eukaryotic promoters, DNA flexibility and AT content are highly correlated. The probabilities finding flexibility pattern in promoter sequences were also estimated statistically. The biological implications were discussed briefly.     

A single-step competitive binding assay for mapping of single DNA molecules

Optical mapping of genomic DNA is of relevance for a plethora of applications such as scaffolding for sequencing and detection of structural variations as well as identification of pathogens like bacteria and viruses. For future clinical applications it is desirable to have a fast and robust mapping method based on as few steps as possible. We here demonstrate a single-step method to obtain a DNA barcode that is directly visualized using nanofluidic devices and fluorescence microscopy. Using a mixture of YOYO-1, a bright DNA dye, and netropsin, a natural antibiotic with very high AT specificity, we obtain a DNA map with a fluorescence intensity profile along the DNA that reflects the underlying sequence. The netropsin binds to AT-tetrads and blocks these binding sites from YOYO-1 binding which results in lower fluorescence intensity from AT-rich regions of the DNA. We thus obtain a DNA barcode that is dark in AT-rich regions and bright in GC-rich regions with kilobasepair resolution. We demonstrate the versatility of the method by obtaining a barcode on DNA from the phage T4 that captures its circular permutation and agrees well with its known sequence.     

Bent DNA is needed for recombinational enhancer activity in the site-specific recombination system Cin of bacteriophage P1. The role of FIS protein

A series of recombinational enhancer mutants was constructed by manipulating the ClaI site between the two FIS binding sites of the Hin enhancer. These mutants include insertions from two to 12 base-pairs and two deletions of one or two base-pairs. Recombinational enhancer activity was found only with four mutants carrying either a four base-pair substitution, ten base-pair insertions or a one base-pair deletion, respectively; two other ten base-pair insertion mutants, however, were inactive, although FIS protein binding was unaffected. So, besides binding of FIS protein to its specific sites within the enhancer sequence and the correct helical positioning of these sites on the DNA, another criterion for enhancer activity must be fulfilled. DNA bending assays identify this requirement as a change of the enhancer DNA conformation, which FIS protein is able to induce and to stabilize. This conformational change of the DNA can be blocked by mutations in the central segment between the two FIS binding sites of the Hin enhancer. This sequence has special functions for the recombinational enhancer activity.     

Assignment of DNA binding sites for 4',6-diamidine-2-phenylindole and bisbenzimide (Hoechst 33258). A comparative footprinting study

DNA binding sites for the minor groove-binding ligands DAPI (4',6-diamidine-2-phenylindole) and Hoechst 33258 (bisbenzimide) have been analysed using DNAase I and micrococcal nuclease footprinting techniques. Both drugs appear to bind to AT-rich regions containing at least four such basepairs. Hoechst 33258 seems to bind relatively poorly to nucleotide sequences containing the alternating step TpA. However, in contrast to DAPI, it can more readily accommodate the presence of guanosine residues at the end of the binding site. We compare the DNA binding sites for DAPI and Hoechst 33258 with those determined for the related minor groove-binding ligands, berenil, netropsin and distamycin A, under comparable conditions, and discuss the importance of using different footprinting probes when analysing drug-DNA interactions.     

Nitrosamine-induced cancer: O4-alkylthymine produces sites of DNA hyperflexibility.

The carcinogenic properties of N-nitroso compounds are associated with their ability to alkylate DNA, in particular to form O6-alkylguanine and O4-alkylthymine. DNA duplexes containing either O6-alkylguanine or O4-alkylthymine were synthesized, and each duplex was ligated to form a set of DNAs of increasing length with the alkylated base out of phase (16 base-pairs apart) or in phase (21 base-pairs apart) with the helical repeat of the DNA. The DNA contained the sequence 5' CAA 3', which is the 61st codon of the K-ras gene, because this codon is a preferred site of mutation for a number of carcinogens including the methylating carcinogen 4-(methylnitrosamino)-1-(3-pyridyl)-1- butanone (NNK). O4-Methylthymine or O4-ethylthymine replaced thymine in either of the two A.T base-pairs of this codon (normally CAA), and O6-methylguanine replaced the guanine in the G.C pair. All the sequences containing O4-alkylthymine exhibited anomalous, slow, gel migration and ligated to form circles of unusually small diameter. In general, the effect was seen when the alkylated base-pair was out of phase with the helical repeat as well as when it was in phase, suggesting that the alkylated base-pair confers flexibility which is largely isotropic, i.e., has no preferred direction, rather than anisotropic flexibility or bending. However, at pH 8.3 the 21-base-pair set containing O4-alkylT.A had significantly greater anomalous migration than the 16-base-pair set, suggesting that the flexibility produced by this base-pair has a significant anisotropic component and thus resembles true bending.(ABSTRACT TRUNCATED AT 250 WORDS)     

Propeller-Twisting of Base-pairs and the Conformational Mobility of Dinucleotide Steps in DNA

When DNA is bent around a protein, it must distort. The distortion occurs by changes in the conformation of successive dinucleotide steps. Bending does not necessarily occur uniformly: some steps might remain particularly rigid, i.e. they might deform relatively little, while others might take more than their proportional share of deformation. We investigate here the deformational capacity of specific dinucleotide steps by examining a database of crystallized oligomers. Dividing the steps into ten types by sequence (AA(=TT), AC(=GT), AG(=CT), AT, CA(=TG), CG, GA(=TC), GC, GG(=CC) and TA), we find that some step types are practically rigid, while others have considerable internal mobility or conformational flexibility. Now in general base-pairs are not planar, but have Propeller-Twist. We find a clear empirical correlation between the level of Propeller-Twist in the base-pairs and the flexibility of the dinucleotide step which they constitute. Propeller-Twist in the base-pairs makes stacking into a dinucleotide step more awkward than in plane base-pairs. In particular, it provides a stereochemical “locking” effect which can make steps with highly Propeller-Twisted base-pairs rigid. Although the origins of Propeller-Twist are not yet clearly understood, this result provides a key to understanding the flexibility of DNA in bending around proteins.     

Crystal structure of a berenil-d(CGCAAATTTGCG) complex. An example of drug-DNA recognition based on sequence-dependent structural features.

The AT-selective drug berenil has been co-crystallized with the dodecanucleotide sequence d(CGCAAATTTGCG)2. The crystal structure has been solved to a resolution of 2.0 A and an R factor of 18.3%, with the location of 65 water molecules. The drug is symmetrically bound in the 5'-AATT region of the minor groove, with its amidinium groups hydrogen-bonding to O-2 atoms of the thymine base at each end of the binding site. This arrangement is distinct from that previously found for berenil with the sequence d(CGCGAATTCGCG)2, which has the drug bound to the sequencing 5'-ATT via hydrogen bonds to adenine N-3 atoms with the involvement of a bridging water molecule at one end of the binding site. The reasons for these differences are discussed in terms of changes in helical parameters; in particular propeller twist and base-pair roll are considered to be important. The conformational and base-pair geometry of the dodecanucleotide in the structure reported here, is closely similar to that for the native structure, suggesting that the 5'-AAATTT sequence does not significantly alter during drug binding, either because of its inflexibility or because its geometry is nearly ideal for berenil binding.     

Netropsin, distamycin and berenil interact differentially with a high-affinity binding site for the high mobility group protein HMG-I

Netropsin, distamycin, berenil and the chromosomal protein HMG-I share the ability to bind preferentially to AT-rich regions of DNA. We studied the binding behaviour of the chemical agents towards a high-affinity binding site for HMG-I by DNase I and MPE footprinting and analyzed their ability to challenge HMG-I-DNA complexes by competition experiments. Significant differences in the binding affinities and in the efficiencies to abolish HMG-I-DNA complexes were observed for the three drugs. Netropsin proved to be the most avidly binding compound and the most efficient competitor raising the interesting possibility that netropsin affects cell growth by interfering with HMG-I-DNA interaction.     

Contribution of opening and bending dynamics to specific recognition of DNA damage

Guanine-uracil (G.U) wobble base-pairs are a detrimental lesion in DNA. Previous investigations have shown that such wobble base-pairs are more prone to base-opening than the normal G.C base-pairs. To investigate the sequence-dependence of base-pair opening we have performed 5ns molecular dynamics simulations on G.U wobble base-pairs in two different sequence contexts, TGT/AUA and CGC/GUG. Furthermore, we have investigated the effect of replacing the guanine base in each sequence with a fluorescent guanine analogue, 6-methylisoxanthopterin (6MI). Our results indicate that each sequence opens spontaneously towards the major groove in the course of the simulations. The TGT/AUA sequence has a greater proportion of structures in the open state than the CGC/GUG sequence. Incorporation of 6MI yields wobble base-pairs that open more readily than their guanine counterparts. In order of increasing open population, the sequences are ordered as CGC相似文献   

Herpes simplex virus: selection of origins of DNA replication.

A selection procedure was devised to study the role of cis -acting sequences at origins of DNA replication. Two regions in Herpes simplex virus oriS were examined: an AT-rich spacer sequence and a putative binding site, box III, for the origin binding protein. Plasmid libraries were generated using oligonucleotides with locally random sequences. The library, amplified in Escherichia coli , was used to transfect BHK cells followed by superinfection with HSV-1. Replicated plasmids resistant to Dpn I cleavage were amplified in E. coli. The selection scheme was repeated. Plasmids were isolated at different stages of the procedure and their replication efficiency was determined. Efficiently replicating plasmids had a high AT content in the spacer sequence as well as a low helical stability of this region. In contrast, this was not seen using the box III library. We also noted that the wild type sequence invariably dominated the library after five rounds of selection. These plasmids arose from recombination between plasmids and viral DNA. Our results imply that a large group of sequences can mechanistically serve as origins of DNA replication. In a viral system, however, where the initiation process might be rate-limiting, this potentially large group of sequences would always converge towards the most efficient replicator.