Iodine-125 radioprobing of E. coli RNA polymerase transcription elongation complexes

Radioprobing the conformation of DNA in a p53-DNA complex

PURPOSE

The frequency of DNA strand breaks produced by the decay of Auger electron-emitting radionuclides is inversely proportional to the distance of DNA nucleotides from the decay site; and thus is very sensitive to changes in the local conformation of the DNA. Analysis of the frequency of DNA breaks, or radioprobing, gives valuable information about the local DNA structure. More than 10 years ago, we demonstrated the feasibility of radioprobing using a DNA-repressor complex with a known structure. Herein, we used radioprobing to study the conformation of DNA in complex with the tumor suppressor protein 53 (p53). Several structures of p53-DNA complexes have been solved by X-ray crystallography. These structures, obtained with the p53 DNA binding domain, a truncated form, laid the groundwork for understanding p53-DNA interactions and their relation to p53 functions. However, whether all observed stereochemical details are relevant to the native p53-DNA complex remains unclear. A common theme of the crystallographic structures is the lack of significant bending in the central part of the DNA response element. In contrast, gel electrophoresis and electron microscopy data showed strong DNA bending and overtwisting upon binding to the native p53 tetramer.

METHODS

To analyze DNA in complex with p53, we incorporated (125)I-dCTP in two different positions of synthetic duplexes containing the consensus p53-binding site.

RESULTS

The most significant changes in the break frequency distributions were detected close to the center of the binding site, which is consistent with an increase in DNA twisting in this region and local DNA bending and sliding.

CONCLUSIONS

Our data confirm the main results of the studies made in solution and lay a foundation for systematic examination of interactions between DNA and native p53 using (125)I radioprobing.

Assessing DNA structures with 125I radioprobing

Iodine-125 radioprobing is based on incorporation of radioiodine into a defined position in a nucleic acid molecule. Decay of (125)I results in the emission of multiple, low-energy Auger electrons that, along with positively charged residual daughter nuclide, produce DNA strand breaks. The probability of such strand breaks at a given nucleotide is in inverse proportion to the distance from the (125)I atom to the sugar of that nucleotide. Therefore, conclusions can be drawn about the conformation or folding of a DNA or RNA molecule based on the distribution of (125)I decay-induced strand breaks. Here we describe in detail the application (125)I radioprobing for studying the conformation of quadruplex structures, and discuss the advantages and limitations of the method.

Antibodies with infinite affinity: origins and applications

Antibodies with infinite affinity were developed with the aim of improving targeted delivery of metal complexes to sites of disease. This is part of a series of chemical technology developments for biomedical imaging and therapy. Using a combination of genetics and chemical synthesis, it addresses challenges in developing proteins that specifically bind synthetic molecules and do not release them. The result is a set of reagents that promise to capture any of a large variety of metallic elements under physiological conditions and hold them for long periods of time.

The potential for gene-targeted radiation therapy of cancers

Targeted cancer therapy is the mantra now chanted by oncologists of all types. Everyone hopes that the rapid expansion in the knowledge of cancer cell genetics, signaling, regulatory factors and other changes that underlie malignant transformation and metastasis will lead to innovative approaches for the treatment of cancers. To date, successful targeted therapies have been derived from pharmaceutical chemistry - designing chemical compounds intended to disrupt a crucial pathway for malignant cells to survive, grow and metastasize. Radiotherapy also has a goal of more-selective targeting of therapeutic radiation effects to only tumor cells. In this review, we describe our efforts to create a form of gene-targeted radiation therapy by using the unique radiation effects of radionuclides that decay by the Auger process attached to oligonucleotide carrier-molecules that are capable of forming triplex DNA structures with target sequences in the genome of the human cancer cell.

Intramolecular quadruplex conformation of human telomeric DNA assessed with 125I-radioprobing

A repeated non-coding DNA sequence d(TTAGGG)n is present in the telomeric ends of all human chromosomes. These repeats can adopt multiple inter and intramolecular non-B-DNA conformations that may play an important role in biological processes. Two intramolecular structures of the telomeric oligonucleotide dAGGG(TTAGGG)3, antiparallel and parallel, have been solved by NMR and X-ray crystallography. In both structures, the telomeric sequence adopts an intramolecular quadruplex structure that is stabilized by G-4 quartets, but the ways in which the sequence folds into the quadruplex are different. The folds of the human telomeric DNA were described as an anti-parallel basket-type and a parallel propeller-type. We applied 125I-radioprobing to determine the conformation of the telomeric quadruplex in solution, in the presence of either Na+ or K+ ions. The probability of DNA breaks caused by decay of 125I is inversely related to the distance between the radionuclide and the sugar unit of the DNA backbone; hence, the conformation of the DNA backbone can be deduced from the distribution of breaks. The probability of breaks measured in the presence of Na+ and K+ were compared with the distances in basket-type and propeller-type quadruplexes obtained from the NMR and crystal structures. Our radioprobing data demonstrate that the antiparallel conformation was present in solution in the presence of both K+ and Na+. The preferable conformation in the Na+-containing solution was the basket-type antiparallel quadruplex whereas the presence of K+ favored the chair-type antiparallel quadruplex. Thus, we believe that the two antiparallel and the parallel conformations may coexist in solution, and that their relative proportion is determined by the type and concentration of ions.