Electron microscopy reveals that transcription factor TFIIIA bends 5S DNA

Structural basis of TFIIIC-dependent RNA Polymerase III transcription initiation

RNA Polymerase III (Pol III) is responsible for transcribing 5S ribosomal RNA (5S rRNA), tRNAs, and other short non-coding RNAs. Its recruitment to the 5S rRNA promoter requires transcription factors TFIIIA, TFIIIC, and TFIIIB. Here we use cryo-electron microscopy to visualize the S. cerevisiae complex of TFIIIA and TFIIIC bound to the promoter. Brf1-TBP binding further stabilizes the DNA, resulting in the full-length 5S rRNA gene wrapping around the complex. Our smFRET study reveals that the DNA undergoes both sharp bending and partial dissociation on a slow timescale, consistent with the model predicted from our cryo-EM results. Our findings provide new insights into the mechanism of how the transcription initiation complex assembles on the 5S rRNA promoter, a crucial step in Pol III transcription regulation.

DNA looping in the RNA polymerase I enhancesome is the result of non-cooperative in-phase bending by two UBF molecules

The so-called upstream binding factor (UBF) is required for the initial step in formation of an RNA polymerase I initiation complex. This function of UBF correlates with its ability to induce the ribosomal enhancesome, a structure which resembles in its mass and DNA content the nucleosome of chromatin. DNA looping in the enhancesome is probably the result of six in-phase bends induced by the HMG boxes of a UBF dimer. Here we show that insertion/deletion mutations in the basic peptide linker lying between the N-terminal dimerisation domain and the first HMG box of Xenopus UBF prevent the DNA looping characteristic of the enhancesome. Using these mutants we demonstrate that (i) the enhancesome structure does not depend on tethering of the entering and exiting DNA duplexes, (ii) UBF monomers induce hemi-enhancesomes, bending the DNA by 175 +/- 24 degrees and (iii) two hemi-enhancesomes are precisely phased by UBF dimerisation. We use this and previous data to refine the existing enhancesome model and show that HMG boxes 1 and 2 of UBF lie head-to-head along the DNA.

The DNA supercoiling architecture induced by the transcription factor xUBF requires three of its five HMG-boxes

The formation of a near complete loop of DNA is a striking property of the architectural HMG-box factor xUBF. Here we show that DNA looping only requires a dimer of Nbox13, a C-terminal truncation mutant of xUBF containing just HMG-boxes 1-3. This segment of xUBF corresponds to that minimally required for activation of polymerase I transcription and is sufficient to generate the major characteristics of the footprint given by intact xUBF. Stepwise reduction in the number of HMG-boxes to less than three significantly diminishes DNA bending and provides an estimate of bend angle for each HMG-box. Together the data indicate that a 350 +/- 16 degree loop in 142 +/- 30 bp of DNA can be induced by binding of the six HMG-boxes in an Nbox13 dimer and that DNA looping is probably achieved by six in-phase bends. The positioning of each HMG-box on the DNA does not predominantly involve DNA sequence recognition and is thus an intrinsic property of xUBF.

Examination of the phosphate in conjugative F-like pili by use of electron spectroscopic imaging

F-like pili specified by conjugative plasmids have been reported to contain phosphate which may be noncovalently incorporated into the pilus. Electron spectroscopic imaging was able to detect phosphate in the filamentous, single-stranded DNA phage f1, used as positive control, but could not detect phosphate in F-like pili. Thus, the phosphate in purified pili which has been reported is probably derived from contaminating cell envelope material.

TFIIIA induced DNA bending: effect of low ionic strength electrophoresis buffer conditions

We have used a circular permutation gel shift assay to show that the 5S gene transcription factor, TFIIIA, induces a bend at the internal promoter of the Xenopus oocyte-type 5S gene. The degree of bending is comparable to what we have previously observed for TFIIIA induced bending of the Xenopus somatic-type gene [Schroth, G.P. et al. (1989) Nature 340, 487-488]. In addition, we show that TFIIIA induced DNA bending is dramatically affected by the ionic conditions used during gel electrophoresis. By modifying the conditions of the electrophoresis, we can detect two distinct conformations for the TFIIIA/DNA complex. In very low ionic strength buffers, the degree of DNA bending in the complex is estimated to be about 25 to 30 degrees, whereas in higher ionic strength buffers it is about 60 to 65 degrees. These data explain the apparent discrepancy between our results and the results of another study in which it was claimed that TFIIIA did not 'substantially' bend DNA [Zweib, C. and Brown, R.S. (1990) Nucleic Acid Res. 18, 583-587]. These results also demonstrate that the TFIIIA/DNA complex has a large degree of conformational flexibility. Both DNA bending and conformational flexibility are structural features which may provide a key insight into the function of TFIIIA as a positive transcription factor.

Ultrastructure of transcriptionally competent chromatin

We have examined a salt-soluble, transcriptionally competent gene-enriched fraction of chicken erythrocyte chromatin and compared it to bulk chromatin using the unique microanalytical capabilities of Electron Spectroscopic Imaging (ESI). The salt-soluble fraction is enriched 48 fold in beta-globin gene sequences and is also enriched in histones that are post-synthetically modified, including acetylation and ubiquitination. Differences between the two fractions are also apparent in the distribution of the two major forms of nucleoprotein structures, including (1) particles which present a circular profile and possess protein and DNA content nearly identical to that of the canonical nucleosome and account for 89% of particles in the bulk fraction but account for only 66% of the particles in the competent fraction, and (2) u-shaped particles which possess about 20% less protein mass than particles of circular profile and are about 10x more prevalent in the transcriptionally competent fraction than in the bulk. Additionally, elongated particles with protein and DNA content similar to the u-shaped objects are also seen in the competent fraction.

Histone hyperacetylation can induce unfolding of the nucleosome core particle

A direct correlation exists between the level of histone H4 hyperacetylation induced by sodium butyrate and the extent to which nucleosomes lose their compact shape and become elongated (62.0% of the particles have a length/width ratio over 1.6; overall mean in the length/width ratio = 1.83 +/- 0.48) when bound to electron microscope specimen grids at low ionic strength (1mM EDTA, 10mM Tris, pH 8.0). A marked proportion of elongated core particles is also observed in the naturally occurring hyperacetylated chicken testis chromatin undergoing spermatogenesis when analyzed at low ionic strength (36.8% of the particles have a length/width ratio over 1.6). Core particles of elongated shape (length/width ratio over 1.6) generated under low ionic strength conditions are absent in the hypoacetylated chicken erythrocyte chromatin and represent only 2.3% of the untreated Hela S3 cell core particles containing a low proportion of hyperacetylated histones. The marked differences between control and hyperacetylated core particles are absent if the particles are bound to the carbon support film in the presence of 0.2 M NaCl, 6mM MgCl2 and 10mM Tris pH 8.0, conditions known to stabilize nucleosomes. A survey of the published work on histone hyperacetylation together with the present results indicate that histone hyperacetylation does not produce any marked disruption of the core particle 'per se', but that it decreases intranucleosomal stabilizing forces as judged by the lowered stability of the hyperacetylated core particle under conditions of shearing stress such as cationic competition by the carbon support film of the EM grid for DNA binding.

Absence of substantial bending in Xenopus laevis transcription factor IIIA-DNA complexes

The extent and location of DNA-bending induced in the Xenopus laevis transcription factor IIIA-oocyte 5S RNA gene complex was determined by the gel retardation method. The electrophoretic mobilities of TFIIIA complexed with restriction fragments of 160, 177, 282 and 300 bp that contain the sequence of the major oocyte 5S RNA gene were compared. In these fragments the 120-bp gene is positioned either in the middle or at the end. Minor differences in the mobility of the complexes indicate that the degree of DNA bending is only slight. To determine the bending angle more precisely, a bending vector system, pBend3, was used to examine the complex of TFIIIA with the internal control region (ICR) of the 5S RNA gene. A 61-bp synthetic duplex corresponding to the ICR sequence was cloned into pBend3. Duplicated circular permuted restriction sites allow several 186-bp fragments to be generated in which the position of the ICR can be varied. Gel retardation of TFIIIA-DNA complexes with the ICR sequence contained in pBend3 indicates a bending angle of only 30 degrees and shows that interaction in the ICR could account for all of the bending found in the complete oocyte 5S RNA gene.