Effects of sequence selective drugs on the gel mobility of a bent DNA fragment

Targeting Transcription Factors for Cancer Treatment

Transcription factors are involved in a large number of human diseases such as cancers for which they account for about 20% of all oncogenes identified so far. For long time, with the exception of ligand-inducible nuclear receptors, transcription factors were considered as “undruggable” targets. Advances knowledge of these transcription factors, in terms of structure, function (expression, degradation, interaction with co-factors and other proteins) and the dynamics of their mode of binding to DNA has changed this postulate and paved the way for new therapies targeted against transcription factors. Here, we discuss various ways to target transcription factors in cancer models: by modulating their expression or degradation, by blocking protein/protein interactions, by targeting the transcription factor itself to prevent its DNA binding either through a binding pocket or at the DNA-interacting site, some of these inhibitors being currently used or evaluated for cancer treatment. Such different targeting of transcription factors by small molecules is facilitated by modern chemistry developing a wide variety of original molecules designed to specifically abort transcription factor and by an increased knowledge of their pathological implication through the use of new technologies in order to make it possible to improve therapeutic control of transcription factor oncogenic functions.

Molecular basis for sequence-dependent induced DNA bending

With a growing understanding of the microstructural variations of DNA, it has become apparent that subtle conformational features are essential for specific DNA molecular recognition and function. DNA containing an A-tract has a narrow minor groove and a globally bent conformation but the structural features of alternating AT DNA are less well understood. Several studies indicate that alternating AT sequences are polymorphic with different global and local properties from A-tracts. The mobility of alternating AT DNA in gel electrophoresis is extensively reduced upon binding with minor-groove binding agents such as netropsin. Although this suggests that such complexes are bent, similarly to A-tract DNA, direct evidence and structural information on AT DNA and the induced conformational change is lacking. We have used NMR spectroscopy and residual dipolar coupling together with restrained molecular-dynamics simulations to determine the solution structures of an alternating AT DNA segment, with and without netropsin, in order to evaluate the molecular basis of the binding-induced effects. Complex formation causes a significant narrowing of the minor groove and a pronounced change in bending, from a slight bend towards the major groove for the free DNA to a pronounced bend towards the minor groove in the complex. This observation demonstrates that conformational features and the inherent malleability of AT sequences are essential for specific molecular recognition and function. These results take the field of DNA structures into new areas while opening up avenues to target novel DNA sequences.

Induced topological changes in DNA complexes: influence of DNA sequences and small molecule structures

Heterocyclic diamidines are compounds with antiparasitic properties that target the minor groove of kinetoplast DNA. The mechanism of action of these compounds is unknown, but topological changes to DNA structures are likely to be involved. In this study, we have developed a polyacrylamide gel electrophoresis-based screening method to determine topological effects of heterocyclic diamidines on four minor groove target sequences: AAAAA, TTTAA, AAATT and ATATA. The AAAAA and AAATT sequences have the largest intrinsic bend, whereas the TTTAA and ATATA sequences are relatively straight. The changes caused by binding of the compounds are sequence dependent, but generally the topological effects on AAAAA and AAATT are similar as are the effects on TTTAA and ATATA. A total of 13 compounds with a variety of structural differences were evaluated for topological changes to DNA. All compounds decrease the mobility of the ATATA sequence that is consistent with decreased minor groove width and bending of the relatively straight DNA into the minor groove. Similar, but generally smaller, effects are seen with TTTAA. The intrinsically bent AAAAA and AAATT sequences, which have more narrow minor grooves, have smaller mobility changes on binding that are consistent with increased or decreased bending depending on compound structure.

Large, sequence-dependent effects on DNA conformation by minor groove binding compounds

To determine what topological changes antiparasitic heterocyclic dications can have on kinetoplast DNA, we have constructed ligation ladders, with phased A5 and ATATA sequences in the same flanking sequence context, as models. Bending by the A5 tract is observed, as expected, while the ATATA sequence bends DNA very little. Complexes of these DNAs with three diamidines containing either furan, thiophene or selenophene groups flanked by phenylamidines were investigated along with netropsin. With the bent A5 ladder the compounds caused either a slight increase or decrease in the bending angle. Surprisingly, however, with ATATA all of the compounds caused significant bending, to values close to or even greater than the A5 bend angle. Results with a mixed cis sequence, which has one A5 and one ATATA, show that the compounds bend ATATA in the same direction as a reference A5 tract, that is, into the minor groove. These results are interpreted in terms of a groove structure for A5 which is largely pre-organized for a fit to the heterocyclic amidines. With ATATA the groove is intrinsically wider and must close to bind the compounds tightly. The conformational change at the binding site then leads to significant bending of the alternating DNA sequence.

Two-dimensional conformation-dependent electrophoresis (2D-CDE) to separate DNA fragments containing unmatched bulge from complex DNA samples

DNA fragments containing mispaired and modified bases, bulges, lesions and specific sequences have altered conformation. Methods for separating complex samples of DNA fragments based on conformation but independent of length have many applications, including (i) separation of mismatched or unmatched DNA fragments from those perfectly matched; (ii) simultaneous, diagnostic, mismatch scanning of multiple fragments; (iii) isolation of damaged DNA fragments from undamaged fragments; and (iv) estimation of reannealing efficiency of complex DNA samples. We developed a two-dimensional conformation-dependent electrophoresis (2D-CDE) method for separating DNA fragments based on length and conformation in the first dimension and only on length in the second dimension. Differences in migration velocity due to conformation were minimized during second dimension electrophoresis by introducing an intercalator. To test the method, we constructed 298 bp DNA fragments containing cytosine bulges ranging from 1 to 5 nt. Bulge-containing DNA fragments had reduced migration velocity in the first dimension due to altered conformation. After 2D-CDE, bulge-containing DNA fragments had migrated in front of an arc comprising heterogeneous fragments with regular conformation. This simple and robust method could be used in both analytical and preparative applications involving complex DNA samples.

Inhibition of human papilloma virus E2 DNA binding protein by covalently linked polyamides

Polyamides are a class of heterocyclic small molecules with the potential of controlling gene expression by binding to the minor groove of DNA in a sequence-specific manner. To evaluate the feasibility of this class of compounds as antiviral therapeutics, molecules were designed to essential sequence elements occurring numerous times in the HPV genome. This sequence element is bound by a virus-encoded transcription and replication factor E2, which binds to a 12 bp recognition site as a homodimeric protein. Here, we take advantage of polyamide:DNA and E2:DNA co-crystal structural information and advances in polyamide synthetic chemistry to design tandem hairpin polyamides that are capable of displacing the major groove-binding E2 homodimer from its DNA binding site. The binding of tandem hairpin polyamides and the E2 DNA binding protein to the DNA site is mutually exclusive even though the two ligands occupy opposite faces of the DNA double helix. We show with circular permutation studies that the tandem hairpin polyamide prevents the intrinsic bending of the E2 DNA site important for binding of the protein. Taken together, these results illustrate the feasibility of inhibiting the binding of homodimeric, major groove-binding transcription factors by altering the local DNA geometry using minor groove-binding tandem hairpin polyamides.

The pleiotropic response regulator DegU functions as a priming protein in competence development in Bacillus subtilis

The response regulator DegU is involved in various late-growth developmental processes in Bacillus subtilis, including the production of degradative enzymes and the development of genetic competence. DegU is essential for the expression of the competence transcription factor, encoded by comK. ComK is required for the transcription of genes encoding the DNA uptake and integration machinery, as well as for the transcription of its own gene. We have purified DegU to study its role in the expression of comK, and we demonstrate here that DegU binds specifically to the comK promoter. The binding of the response regulator DegU to a promoter target had not been reported previously. DNase I protection analyses show that the DegU binding site overlaps with the ComK binding site, and gel retardation experiments indicate that DegU strongly stimulates the binding of ComK to the comK promoter. We propose that DegU functions at the initiation of competence development, when ComK concentrations are insufficient to support comK transcription, by facilitating ComK binding to the comK promoter. DegU therefore acts as a priming protein that primes the autostimulatory transcription of comK. Such priming activity adds a function to the class of response regulator proteins.

Circular structures in retroviral and cellular genomes

A computer program for predicting DNA bending from nucleotide sequence was used to identify circular structures in retroviral and cellular genomes. An 830-base pair circular structure was located in a control region near the center of the genome of the human immunodeficiency virus type I (HIV-I). This unusual structure displayed relatively smooth planar bending throughout its length. The structure is conserved in diverse isolates of HIV-I, HIV-II, and simian immunodeficiency viruses, which implies that it is under selective constraints. A search of all sequences in the GenBank data base was carried out in order to identify similar circular structures in cellular DNA. The results revealed that the structures are associated with a wide range of sequences that undergo recombination, including most known examples of DNA inversion and subtelomeric translocation systems. Circular structures were also associated with replication and transposition systems where DNA looping has been implicated in the generation of large protein-DNA complexes. Experimental evidence for the structures was provided by studies which demonstrated that two sequences detected as circular by computer preferentially formed covalently closed circles during ligation reactions in vitro when compared to nonbent fragments, bent fragments with noncircular shapes, and total genomic DNA. In addition, a single T-->C substitution in one of these sequences rendered it less planar as seen by computer analysis and significantly reduced its rate of ligase-catalyzed cyclization. These results permit us to speculate that intrinsically circular structures facilitate DNA looping during formation of the large protein-DNA complexes that are involved in site- and region-specific recombination and in other genomic processes.

Interaction of bleomycin with a bent DNA fragment

The interaction of bleomycin with a kinetoplast DNA fragment has been examined using various footprinting techniques. This DNA adopts a bent structure and displays an unusually low gel mobility on account of its phased runs of adenines. The bleomycin-cobalt complex increases the mobility of this DNA fragment, in contrast with other DNAs which show a decreased rate of gel migration, suggesting that the antibiotic removes DNA bending, possibly via an unwinding mechanism. Removal of the bending is confirmed by hydroxy-radical footprinting which produces a more even ladder of bands in the presence of the ligand. Cleavage by bleomycin is at the sequence G-pyrimidine, though not all such sites are affected to the same extent and some cutting is found at GA and GG. DNase I footprinting confirms the antibiotic-binding sites but reveals that some strong cleavage sites do not yield footprints. Bleomycin renders adenines on the 3' side of its cleavage sites (GT, GC and GA) hyper-reactive to diethyl pyrocarbonate.