DNA unwinding ability of Xenopus transcription factor A

Simultaneous determination of helical unwinding angles and intrinsic association constants in ligand-DNA complexes: the interaction between DNA and calichearubicin B

We present a helical unwinding assay for reversibly binding DNA ligands that uses closed circular DNA, topoisomerase I (Topo I), and two-dimensional agarose gel electrophoresis. Serially diluted Topo I relaxation reactions at constant DNA/ligand ratio are performed, and the resulting apparent unwinding of the closed circular DNA is used to calculate both ligand unwinding angle (phi) and intrinsic association constant (Ka). Mathematical treatment of apparent unwinding is formally analogous to that of apparent extinction coefficient data for optical binding titrations. Extrapolation to infinite DNA concentration yields the true unwinding angle of a given ligand and its association constant under Topo I relaxation conditions. Thus this assay delivers simultaneous structural and thermodynamic information describing the ligand-DNA complex. The utility of this assay has been demonstrated by using calichearubicin B (CRB), a synthetic hybrid molecule containing the anthraquinone chromophore of (DA) and the carbohydrate domain of calicheamicin gamma1I. The unwinding angle for CRB calculated by this method is -5. 3 +/- 0.5 degrees. Its Ka value is 0.20 x 10(6) M-1. For comparison, the unwinding angles of ethidium bromide and DA have been independently calculated, and the results are in agreement with canonical values for these compounds. Although a stronger binder to selected sites, CRB is a less potent unwinder than its parent compound DA. The assay requires only small amounts of ligand and offers an attractive option for analysis of DNA binding by synthetic and natural compounds.

Strand displacement synthesis capability of Moloney murine leukemia virus reverse transcriptase

The accepted model of retroviral reverse transcription includes a circular DNA intermediate which requires strand displacement synthesis for linearization and creation of an integration-competent, long terminal repeat-flanked DNA product. We have used an in vitro model of this last step of reverse transcription to examine the role of the viral enzyme, reverse transcriptase (RT), in displacement synthesis. We show that Moloney murine leukemia virus RT possesses an activity which allows for displacement synthesis through a minimum of 1,334 bp of duplex DNA--an extent much greater than that required during in vivo reverse transcription and over 25-fold greater than has been previously demonstrated for a viral RT. RT does not function as a helicase in the classical sense but appears to closely couple duplex DNA melting with synthesis-driven translocation of the enzyme. In the absence of synthesis, the unwound region created by a primer-positioned RT appears to be no greater than 2 bp and does not advance along the template. Additionally, RT does not utilize ATP or any deoxynucleoside triphosphate not directly encoded by the template strand to catalyze processive duplex unwinding at a nick; nor does binding of the enzyme unwind duplex DNA in the absence of a 3' terminus. The approximate maximum chain elongation rate during strand displacement synthesis by Moloney murine leukemia virus RT falls between 0.73 and 1.5 nucleotides per s at 37 degrees C. The RNase H activity of RT does not appear to play a role in displacement synthesis; however, a 181-amino-acid C-terminal truncation of RT displays a dramatically reduced ability to catalyze synthesis through duplex DNA.

Estrogen receptor alters the topology of plasmid DNA containing estrogen responsive elements

We have recently used DNA containing estrogen responsive element (ERE) sequences for affinity purification to prepare calf uterine estrogen receptor (ER) at near homogeneity. The capacity of this purified ER to alter DNA topology upon binding was examined. Although the ER is not a topoisomerase, the presence of ER changes the distribution of topoisomers generated by incubation of plasmid DNA with excess wheat germ topoisomerase I. This effect is larger in plasmids containing a consensus ERE sequence. Two dimensional gel electrophoretic analysis suggested that interaction of ER and ERE causes negative supercoiling in regions of the plasmid accessible to topoisomerase I, resulting from overwinding of DNA contacting the ER. The extent of topological alteration was dependent on ER concentration. We suggest that the observed conformational changes in the DNA could have a role in regulation of transcription.

Xenopus transcription factor IIIA (XTFIIIA): after a decade of research

Xenopus transcription factor IIIA (XTFIIIA) is the first eukaryotic transcription factor purified to homogeneity and is specifically required for the 5S RNA gene transcription. It contains two structural domains and nine zinc finger motifs through which it recognizes the promoter region of the 5S RNA gene. It also binds to 5S RNA and serves to store 5S RNA in the form of 7S ribonucleoprotein particles in oocytes. Additionally, it forms a metastable complex with 5S DNA and promotes the formation of stable and competent transcription complexes. Its expression is developmentally controlled at the level of transcription and translation. Moreover, it participates in the assembly of active chromatin templates and at least, in part, is responsible for the developmental regulation of two kinds of 5S RNA genes in Xenopus.

Protein-induced unwinding of DNA: measurement by gel electrophoresis of complexes with DNA minicircles. Application to restriction endonuclease EcoRI, catabolite gene activator protein and lac repressor

An electrophoretic procedure for the measurement of the helix unwinding induced by a sequence-specific protein is described. The method, which was applied here to EcoR I, CAP and lac repressor, involved the migration of the complexes with positively and negatively supercoiled DNA minicircles carrying a single protein binding site. Mobility shifts of complexes relative to naked DNAs appeared to be a result of i) the unwinding; of ii) an increase in the molecular frictional coefficient, which led to a retardation; of iii) bending, in the particular case of CAP, which induced an acceleration; and of iv) looping, in the case of lac repressor, which also resulted in an acceleration. Under conditions where the migration of the naked topoisomers was V-like (topoisomer mobility showed the same linear increase with both negative and positive supercoilings; Zivanovic et al. (1986) J. Mol. Biol., 192, 645-660), the protein unwinding contribution to mobility was assumed to be identical to that experimentally observed in the case of a thermal unwinding: all negatively supercoiled topoisomers were retarded and all positively supercoiled topoisomers were accelerated to the same extent. In contrast, the mobility contribution of the frictional term, as well as those of bending and looping, appeared to vary strongly with the magnitude of the supercoiling, but only weakly with its polarity. As a consequence, these latter contributions may approximately cancel when one is measuring the difference between the shifts observed for two comigrating, negatively and positively supercoiled, topoisomers, allowing the unwinding to be calculated. While estimates obtained for EcoR I, 23 +/- 3 degrees, and CAP, about 29 degrees, were in good agreement with previous measurements using topoisomerase I, the value found for lac repressor, 13 to 16 degrees, was significantly smaller.

Bovine seminalplasmin [corrected] is a DNA unwinding protein

The duplex DNA unwinding ability of seminalplasmin [corrected] from bovine semen was examined by treatment of plasmid-protein complexes with calf thymus topoisomerase I and resolution of the topoisomer distributions by agarose gel electrophoresis. Binding of seminalplasmin [corrected] results in a moderate degree of unwinding of supercoiled plasmid. The elongation of the RNA chain by E. coli RNA polymerase over promoter containing template is not inhibited by seminalplasmin [corrected]. However, the reinitiation of transcription is blocked in such cases indicating that seminalplasmin [corrected] inhibits transcription by binding to the initiation site of RNA polymerase.

A model for the interaction of nucleic acids with transcription factor IIIA

Based on published biochemical evidence which examines the interaction of Xenopus transcription factor IIIA (TFIIIA) with 5 S RNA genes and 5 S RNA, this paper proposes that the formation of a 5 S RNA type stem-loop structure in the DNA occurs during the binding of TFIIIA to 5 S genes.

Mapping of the sites of protection on a 5 S RNA gene by the Xenopus transcription factor IIIA. A model for the interaction

The contact points of transcription factor IIIA with the internal control region of the 5 S RNA gene of Xenopus have been investigated by probing the accessibility of the DNA in the protein-DNA complex to dimethylsulphate and to micrococcal nuclease. The results of quantitative measurements, combined with those from earlier DNase I and DNase II protection studies, are consistent with a series of multiple contacts about five base-pairs apart, or half a double-helical turn, along the whole length of the internal control region. The nine patches of contact we have mapped could correspond to nine DNA-binding fingers in the protein. A model for the overall geometry of the interaction is presented in which the protein lies on one face of the DNA double helix.

Analysis of the RNA structural elements involved in the binding of the transcription factor III A from Xenopus laevis

Xenopus laevis 5S rRNA isolated from 7S particles or transcribed in vitro is found to adopt two alternative conformations. These two conformers contain different structural elements within the major TF III A binding domain, which, when isolated as RNA fragments, still interact with the transcription factor. Chemical modification of easily accessible adenines in their N-1 position does not have any measurable effect on the binding of 5S rRNA to TF III A. These observations are in support of the idea that only a small amount of conserved sequence information is required for the binding of the transcription factor, whereas specific secondary structure features seem to be essential.

Identification of the binding site on 5S rRNA for the transcription factor IIIA: proposed structure of a common binding site on 5S rRNA and on the gene

Transcription factor IIIA interacts specifically with an internal control region of Xenopus 5S ribosomal RNA genes and is also a component, along with 5S rRNA, of a 7S ribonucleoprotein particle present in previtellogenic oocytes. We have determined the region of the 5S rRNA in the 7S ribonucleoprotein complex that is protected by the transcription factor from digestion with the ribonuclease alpha-sarcin. The binding site for factor IIIA extends from nucleotide 64 through nucleotide 116; the protected region includes two CCUGG helices separated by 11 nucleotides. The same helices occur in the factor IIIA binding site in the 5S rRNA gene and may constitute a common structural feature recognized by the protein in the gene and in the gene product.

5S RNA gene specific transcription factor (TFIIIA) changes the linking number of the DNA

The purified 5S gene specific transcription factor A (TFIIIA), when incubated with the relaxed 5S gene in the presence of topoisomerase I alters the conformation of the DNA, resulting in a change in the linking number. This interaction introduces a change of one bp per TFIIIA binding site at a low concentration of DNA to protein (1:2) which increases to an extent of 0.9 turns (9 bp) per TFIIIA binding site at a higher protein concentration (1:12). These analyses support the notion that the binding of TFIIIA to the 5S DNA introduces a minimal change in the topology of circular DNA molecules.

Characterization of the RNA binding properties of transcription factor IIIA of Xenopus laevis oocytes

A nitrocellulose filter binding assay has been developed to study the interaction of Xenopus transcription factor IIIA with 5S RNA. The protein binds Xenopus oocyte 5S RNA with an association constant of 1.4 X 10(9) M-1 at 0.1 M salt, pH 7.5 at 20 degrees C. TF IIIA binds wheat germ 5S RNA with a two-fold higher affinity, E. coli 5S RNA with a four-fold weaker affinity, and has a barely detectable interaction with yeast tRNAphe. The preference for binding eukaryotic 5S RNA is enhanced in competition assays. The homologous reconstituted complex contains one molecule each of protein and 5S RNA and is indistinguishable from native 7S RNP in mobility on non-denaturing polyacrylamide gels. The conformation of the RNA in reconstituted particles is identical to the conformation of RNA in native 7S RNP. Further analysis of the homologous interaction reveals that complex formation is a favoured both by enthalpy and entropy. The 5S RNA binding activity has a broad pH optimum spanning pH 6.0 to pH 8.0. Determination of the salt dependence of Ka reveals that as many as 5 lysine-phosphate type ionic bonds may be formed in the homologous complex. Approximately 68% of the free energy of complex formation is contributed by non-electrostatic interactions between TF IIIA and Xenopus 5S RNA.

Eukaryotic RNA polymerases

This review will attempt to cover the present information on the multiple forms of eukaryotic DNA-dependent RNA polymerases, both at the structural and functional level. Nuclear RNA polymerases constitute a group of three large multimeric enzymes, each with a different and complex subunit structure and distinct specificity. The review will include a detailed description of their molecular structure. The current approaches to elucidate subunit function via chemical modification, phosphorylation, enzyme reconstitution, immunological studies, and mutant analysis will be described. In vitro reconstituted systems are available for the accurate transcription of cloned genes coding for rRNA, tRNA, 5 SRNA, and mRNA. These systems will be described with special attention to the cellular factors required for specific transcription. A section on future prospects will address questions concerning the significance of the complex subunit structure of the nuclear enzymes; the organization and regulation of the gene coding for RNA polymerase subunits; the obtention of mutants affected at the level of factors, or RNA polymerases; the mechanism of template recognition by factors and RNA polymerase.

Structural requirements for the interaction of 5S rRNA with the eukaryotic transcription factor IIIA

In order to study the binding of the eukaryotic transcription factor IIIA to heterologous 5S rRNAs with a low degree of overall sequence conservation (less than 20%) we have utilized a transcription competition assay involving eubacterial, archaebacterial and eukaryotic 5S rRNAs. All the molecules inhibit Xenopus 5S rRNA transcription specifically, which suggests that only a small amount of specific conserved RNA sequences, if indeed any, are essential for the interaction of the transcription factor with the 5S rRNA molecule, whereas universal 5S rRNA secondary structure elements seem to be required. A fragment of Xenopus laevis oocyte 5S rRNA (nucleotides 41-120), which partially maintains the original 5S rRNA structure, also competes for TF III A. In vitro transcription of a naturally occurring mutant of the Xenopus laevis oocyte 5S rRNA gene, the pseudogene, which carries several point mutations within the TF III A binding domain is equally inhibited by exogenous Xenopus 5S rRNA.