Electrophoretic analysis of protein-induced DNA bending and twist changes

Recognition of Local DNA Structures by p53 Protein

p53 plays critical roles in regulating cell cycle, apoptosis, senescence and metabolism and is commonly mutated in human cancer. These roles are achieved by interaction with other proteins, but particularly by interaction with DNA. As a transcription factor, p53 is well known to bind consensus target sequences in linear B-DNA. Recent findings indicate that p53 binds with higher affinity to target sequences that form cruciform DNA structure. Moreover, p53 binds very tightly to non-B DNA structures and local DNA structures are increasingly recognized to influence the activity of wild-type and mutant p53. Apart from cruciform structures, p53 binds to quadruplex DNA, triplex DNA, DNA loops, bulged DNA and hemicatenane DNA. In this review, we describe local DNA structures and summarize information about interactions of p53 with these structural DNA motifs. These recent data provide important insights into the complexity of the p53 pathway and the functional consequences of wild-type and mutant p53 activation in normal and tumor cells.

p53-induced DNA bending and twisting: p53 tetramer binds on the outer side of a DNA loop and increases DNA twisting

DNA binding activity of p53 is crucial for its tumor suppressor function. Our recent studies have shown that four molecules of the DNA binding domain of human p53 (p53DBD) bind the response elements with high cooperativity and bend the DNA. By using A-tract phasing experiments, we find significant differences between the bending and twisting of DNA by p53DBD and by full-length human wild-type (wt) p53. Our data show that four subunits of p53DBD bend the DNA by 32-36 degrees, whereas wt p53 bends it by 51-57 degrees. The directionality of bending is consistent with major groove bends at the two pentamer junctions in the consensus DNA response element. More sophisticated phasing analyses also demonstrate that p53DBD and wt p53 overtwist the DNA response element by approximately 35 degrees and approximately 70 degrees, respectively. These results are in accord with molecular modeling studies of the tetrameric complex. Within the constraints imposed by the protein subunits, the DNA can assume a range of conformations resulting from correlated changes in bend and twist angles such that the p53-DNA tetrameric complex is stabilized by DNA overtwisting and bending toward the major groove at the CATG tetramers. This bending is consistent with the inherent sequence-dependent anisotropy of the duplex. Overall, the four p53 moieties are placed laterally in a staggered array on the external side of the DNA loop and have numerous interprotein interactions that increase the stability and cooperativity of binding. The novel architecture of the p53 tetrameric complex has important functional implications including possible p53 interactions with chromatin.

A possible tertiary structure change induced by acrylamide in the DNA-binding domain of the Tn10-encoded Tet repressor. A fluorescence study

A thorough investigation of the acrylamide fluorescence quenching of F75TetR, a mutant of the Tn10-encoded TetR repressor containing a single Trp residue at position 43, was carried out. The Trp-43 residue is located in a helix alpha-turn-helix alpha (H-t-H) motif involved in the specific binding of F75TetR to the operator site in specific DNA. Distinct Ranges of acrylamide concentration have been assumed. At acrylamide concentrations below 0.15-0.2 M (a usual range of values in fluorescence quenching studies) the observed limited tertiary structure change induced by acrylamide is consistent with a noncooperative local unfolding of the DNA-binding domain. It is suggested that penetration of the neutral quencher could cause the deletion of a hydrophobic tertiary structure contact, partly involving TrP-43, responsible for the anchoring of the H-t-H motif inside the three-helix protein bundle, characterizing the N-terminal part. Correspondingly, the affinity of the mutant repressor for the operator was shown to decrease substantially (about five orders of magnitude), seemingly losing its specificity. A subsequent phase, up to 0.8 M acrylamide, was observed in which the involved intermediate protein structure is not further perturbed, nor is DNA binding.

Sequence-specific DNA binding by a rhodium complex: recognition based on sequence-dependent twistability

The chemical construction of small molecules targeted to DNA depends upon the sequence-dependent structure of the double helix. Here we describe a new structural element to be considered in the sequence-specific recognition of DNA, sequence-dependent DNA twistability. The importance of sequence-dependent DNA twistability is demonstrated in the DNA recognition properties of a novel synthetic rhodium intercalator, lambda-1-Rh(MGP)2phi5+. This metallointercalator, containing pendant guanidinium groups, binds in the major groove of DNA at subnanomolar concentrations to the 6 base pair sequence 5'-CATATG-3' with enantiospecificity. An essential feature of this recognition is the sequence-specific unwinding of the DNA helix, which permits direct contacts between guanidinium functionalities on the metal complex and guanine residues. Through an assay developed to test for sequence-specific DNA unwinding, a 70 +/- 10 degrees unwinding of the sequence 5'-CATATG-3' is established with specific binding by the metal complex. This sequence-dependent twistability may be an essential feature of the recognition of sequences by DNA-binding proteins and may be exploited in future design.

Oligo[d(C).(G)] runs exhibit a helical repeat of 11.1 bp in solution and cause slight DNA curvature when properly phased

We have inserted d(C)10 in a set of DNA fragments with bent segments on both ends, which are rotated with respect to each other by base pair wise increasing insertions. The electrophoretic mobilities on polyacrylamide gels of these DNA fragments were used to identify insertion sizes with cis conformations of the bent ends. These experiments revealed a helical repeat in solution of d(C).d(G) tracts of 11.1 +/- 0.08 bp. The electrophoretic mobilities of ligation ladders with properly phased d(C)5 and d(C)16 runs demonstrate a small but clearly detectable curvature of these fragments.