An RNA aptamer with high affinity and high specificity for the 5S RNA binding zinc finger proteins TFIIIA and p43.

The Xenopus zinc finger proteins TFIIIA and p43 bind to 5S RNA in immature oocytes to form 7S and 42S ribonucleoprotein storage particles. To probe the similarities and differences in the RNA binding domains of these two proteins, a library of random RNA molecules was enriched using TFIIIA as the bait protein. One of the abundant aptamers isolated, RNA22, bound to both TFIIIA and p43 derived zinc finger peptides with high affinity and specificity even though the predicted secondary structure of the RNA was unrelated to that of 5S RNA. The interactions of TFIIIA and p43 peptides with RNA22 were compared to their interactions with 5S RNA by characterizing the effects of assay conditions, mutations in RNA22, and mutations in the zinc finger proteins. The similarities and differences in the mechanisms by which these two zinc finger proteins interact with 5S RNA compared to RNA22 suggest they share a common platform for RNA binding with enough flexibility to form specific interactions with both RNAs.

Characterization of the DNA binding activity of the ZFY zinc finger domain.

The ZFY protein is a member of one of the most interesting classes of polydactyl zinc finger proteins. It has a domain of 13 tandem zinc fingers that is organized with an internal repeat of odd-even finger pairs. It has been proposed that each finger pair interacts with six base pairs within a turn of the double helix, the downstream linker crossing the minor groove to place the next finger pair on the following turn of the DNA. Yet putative binding sites for the full-length ZFY protein appear to consist of a six-base AGGCCY consensus sequence that is present in one or two copies. In this study the equilibrium binding of two ZFY-derived zinc finger peptides to 4R DNA with tandem copies of the consensus sequence was investigated. The ZFY5 peptide contains fingers 5-13, including four odd-even finger pairs, and the ZFY11 peptide contains fingers 11-13 and has one odd-even finger pair. Both peptides bound to 4R DNA with equal affinities, forming a bimolecular complex that is mediated by the downstream AGGCCY motif. The additional odd-even finger pairs in ZFY5 made no measurable difference in the mechanism of DNA binding compared to ZFY11. The effects on the DNA-protein interaction of mutations in the 4R DNA and in the key alpha-helical residues of fingers 11-13 indicate that the binding of ZFY to DNA is mediated by the interaction of the GGCC core base pairs with fingers 12 and 13. These results demonstrate that the even-odd repeats in the ZFY zinc finger domain do not make significant contributions to DNA binding.

An RNA aptamer with high affinity and broad specificity for zinc finger proteins.

A class of RNA aptamers that demonstrates a high affinity for a large variety of C(2)H(2) zinc finger proteins was isolated from a library of random RNA sequences by the zinc finger protein TFIIIA. These aptamers have one or more copies of the consensus sequence GGGUGGG, which is part of a putative hairpin loop in the proposed structure of the most abundant aptamer, RNA1. Binding of zinc finger proteins to RNA1 relies upon zinc-dependent folding of the protein, the affinity of an individual protein for RNA1 being determined by the number of tandem zinc finger motifs. The properties of RNA1 were compared to the properties of two other aptamers from the same selection experiment: RNA21, which binds to some but not all zinc finger proteins tested, and RNA22, which binds only to the 5S rRNA binding zinc finger proteins TFIIIA and p43. The binding of three different zinc finger proteins to RNA1 was compared, and the results indicate that the RNA1-protein interaction occurs by several distinct mechanisms. Mutagenesis of RNA1 confirmed that the GGGUGGG consensus sequence presented in a hairpin conformation is required for high-affinity binding of zinc finger proteins.

Contribution of individual amino acids to the RNA binding activity of the Wilms' tumor suppressor protein WT1.

In addition to binding to DNA, the zinc finger protein WT1 can also bind specifically to RNA. To determine the role of individual zinc fingers of the protein in this RNA binding activity, deletion and substitution mutants of the WT1 zinc finger domain were constructed. The effects of the various mutations on the binding of WT1 to the RNA aptamers RNA22 and RNA38 were determined using a quantitative equilibrium binding assay. The results indicate that zinc fingers 2 and 3 of WT1 are essential for the binding of the protein to the RNA aptamers. For both of these fingers, the arginine residue immediately preceding the alpha-helix makes a significant contribution to RNA binding. For zinc finger 2, a second arginine residue within the alpha-helix is also critical for RNA binding, while several alpha-helical residues in zinc finger 3 contribute to the overall affinity of WT1 for RNA. Investigating the effects of the same point mutations on DNA binding indicates that there are similarities and differences in the contributions of zinc fingers 2 and 3 to the DNA and RNA binding activities of WT1.

Contribution of individual amino acids to the 5S RNA binding activity of the Xenopus zinc finger protein p43.

Xenopus zinc finger protein p43 binds to 5S RNA in immature oocytes to form a 42S ribonucleoprotein storage particle. To determine the role of individual zinc fingers of the protein in this RNA binding activity, a series of deletion and substitution mutants of p43 were constructed. The effects of the various mutations on the RNA binding activity of p43 were determined using a quantitative equilibrium binding assay. The results indicate that zinc fingers 1 and 4 of p43 are essential for the binding of the protein to 5S RNA. In the case of finger 1, four amino acids key to RNA binding are found on the same face of the alpha-helix, while in the case of finger 4, two key residues are clustered at the start of the alpha-helix. The similarities and differences in the mechanisms by which fingers 1 and 4 of p43 interact with 5S RNA are compared to the interaction of the zinc fingers of Xenopus transcription factor IIIA with 5S RNA.

Measuring Equilibrium Binding Constants for the WT1-DNA Interaction Using a Filter Binding Assay.

Equilibrium binding of WT1 to specific sites in DNA and potentially RNA molecules is central in mediating the regulatory roles of this protein. In order to understand the functional effects of mutations in the nucleic acid-binding domain of WT1 proteins and/or mutations in the DNA- or RNA-binding sites, it is necessary to measure the equilibrium constant for formation of the protein-nucleic acid complex. This chapter describes the use of a filter binding assay to make accurate measurements of the binding of the WT1 zinc finger domain to the consensus WT1-binding site in DNA. The method described is readily adapted to the measurement of the effects of mutations in either the WT1 zinc finger domain or the putative binding sites within a promoter element or cellular RNA.

Cross priming amplification: mechanism and optimization for isothermal DNA amplification.

CPA is a class of isothermal amplification reactions that is carried out by a strand displacement DNA polymerase and does not require an initial denaturation step or the addition of a nicking enzyme. At the assay temperature of 63°C, the formation of a primer-template hybrid at transient, spontaneous denaturation bubbles in the DNA template is favored over re-annealing of the template strands by the high concentration of primer relative to template DNA. Strand displacement is encouraged by the annealing of cross primers with 5' ends that are not complementary to the template strand and the binding of a displacement primer upstream of the crossing primer. The resulting exponential amplification of target DNA is highly specific and highly sensitive, producing amplicons from as few as four bacterial cells. Here we report on the basic CPA mechanism - single crossing CPA - and provide details on alternative mechanisms.

The ratio of +/-KTS splice variants of the Wilms' tumour suppressor protein WT1 mRNA is determined by an intronic enhancer.

Alternative splicing of the primary transcript of the Wilms' tumour suppressor gene WT1 involving 2 overlapping 5' splice sites at the end of exon 9 results in the insertion of 2 amino acids (KTS) between zinc fingers 3 and 4 of the protein. The presence or absence of these 3 amino acids has consequences for DNA binding affinity, protein-protein interactions, and subnuclear localization. Disruption of the characteristic +KTS to -KTS ratio of mRNA isoforms as a result of mutations in the +KTS splice site results in Frasier syndrome. Mutational analysis of a WT1 minigene construct was carried out to search for sequences that regulate the +/-KTS alternative splicing event. A strong pyrimidine-rich intronic enhancer that increases the use of the +KTS splice site was identified. Cross-linking experiments with nuclear extracts demonstrated that this enhancer specifically binds a protein with a molecular mass of 42+/-2 kDa. One candidate for this trans-factor is the splicing regulator TIA-1, which binds to the pyrimidine-rich enhancer in the primary transcript from the minigene construct and increases the +/-KTS splicing ratio. The observation that TIA-1 and WT1 are both involved in apoptosis supports our proposal for a functional link between these proteins.