Mutations in 5S DNA and 5S RNA have different effects on the binding of Xenopus transcription factor IIIA

The effects on TFIIIA binding affinity of a series of substitution mutations in the Xenopus laevis oocyte 5S RNA gene were quantified. These data indicate that TFIIIA binds specifically to 5S DNA by forming sequence-specific contacts with three discrete sites located within the classical A and C boxes and the intermediate element of the internal control region. Substitution of the nucleotide sequence at any of the three sites significantly reduces TFIIIA binding affinity, with a 100-fold reduction observed for substitutions in the box C subregion. These results are consistent with a direct interaction of TFIIIA with specific base pairs within the major groove of the DNA. A comparison of the TFIIIA binding data for the same mutations expressed in 5S RNA indicates that the protein does not make any strong sequence-specific contacts with the RNA. Although the protein footprinting sites on the 5S DNA and 5S RNA are coincident, nucleotide substitutions in 5S RNA which moderately reduce TFIIIA binding affinity do not correspond at all to the three specific TFIIIA interaction sites within the gene. The implications of these results for models which attempt to reconcile the DNA and RNA binding activities of TFIIIA by proposing a common structural motif for the two nucleic acids are discussed.     

T7 RNA polymerase interacts with its promoter from one side of the DNA helix

The interactions of T7 RNA polymerase with its promoter DNA have been previously probed in footprinting experiments with either DNase I or (methidiumpropyl-EDTA)-Fe(II) to cleave unprotected DNA [Basu, S., & Maitra, U. (1986) J. Mol. Biol. 190, 425-437. Ikeda, R. A., & Richardson, C. C. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 3614-3618]. Both of these reagents have drawbacks; DNase I is a bulky reagent and so provides low resolution, and (methidiumpropyl-EDTA)-Fe(II) intercalates into DNA and is therefore biased toward cleavage of double-stranded DNA. In this study, the interaction between the polymerase and the promoter has been probed with Fe(II)-EDTA. This reagent generates reactive hydroxyl radicals free in solution, which produces a more detailed picture of the polymerase-promoter complex. Two protected regions are observed on each of the two promoter DNA strands: from position -17 to position -13 and from position -7 to position -1 on the coding strand and from position -14 to position -9 and from position -3 to position +2 on the noncoding strand. From this pattern it is clear that if recognition occurs via double-stranded B-form DNA, then the protected regions lie on one face of the DNA helix, and therefore the enzyme must interact predominantly from one side of the DNA helix. Digestion of the DNA in a polymerase-promoter complex with a single-strand-specific endonuclease shows that a small region of the noncoding strand near position -5 is susceptible to cleavage.(ABSTRACT TRUNCATED AT 250 WORDS)     

Triplex mediated delivery of a platinum complex to a specific DNA target site

Tethering an ethylene diamine linker to the 5' terminus of an oligothymidine sequence provides a site for complexation with K(2)PtCl(4). Due to the low reactivity of dT toward a platinum source, we chose dT(8) and dT(15) as our initial synthetic targets for platination. Post-synthetic reaction of the platinum reagent with the diamino oligothymidine generates the diamino dichloro platinum-DNA conjugate that can be used for DNA duplex targeting by oligodeoxyncleotide-mediated triplex formation. The dT(8) sequence is not sufficiently long to facilitate triplex formation and Pt-cross-linking, whereas with a dT(15) sequence cross-linking between the third strand and the duplex occurs exclusively with the duplex target strand directly involved in triplex formation. No examples of cross-linking to the complementary target strand, or of cross-linking to both target strands are observed. Most efficient cross-linking occurs when the dinucleotide d(GpG) is present in the target strand and no cross-linking occurs with the corresponding 7-deazaG dinucleotide target. Cross-linking is also observed when dC or dA residues are present in the target strand, or even with a single dG residue, but it is not observed in any cases to dT residues. Triplex formation provides the ability to target specific sequences of double-stranded DNA and the orientational control arising from triplex formation is sufficient to alter the binding preferences of platinum. Conjugates of the type described here offer the potential of delivering a platinum complex to a specific DNA site.     

Efficient RNA 5'-adenylation by T4 DNA ligase to facilitate practical applications

We describe a simple procedure for RNA 5'-adenylation using T4 DNA ligase. The 5'-monophosphorylated terminus of an RNA substrate is annealed to a complementary DNA strand that has a 3'-overhang of 10 nucleotides. Then, T4 DNA ligase and ATP are used to synthesize 5'-adenylated RNA (5'-AppRNA), which should find use in a variety of practical applications. In the absence of an acceptor nucleic acid strand, the two-step T4 DNA ligase mechanism is successfully interrupted after the adenylation step, providing 40%-80% yield of 5'-AppRNA after PAGE purification with few side products (the yield varies with RNA sequence). Optimized reaction conditions are described for 5'-adenylating RNA substrates of essentially any length including long and structured RNAs, without need for sequestration of the RNA 3'-terminus to avoid circularization. The new procedure is applicable on the preparative nanomole scale. This 5'-adenylation strategy using T4 DNA ligase is a substantial improvement over our recently reported adenylation method that uses T4 RNA ligase, which often leads to substantial amounts of side products and requires careful optimization for each RNA substrate. Efficient synthetic access to 5'-adenylated RNA will facilitate a range of applications by providing substrates for in vitro selection; by establishing a new protocol for RNA 5'-capping; and by providing an alternative approach for labeling RNA with (32)P or biophysical probes at the 5'-terminus.