The core subunit structure in RNA polymerase holoenzyme determined by neutron small-angle scattering

Tetrahydrocortisol-apolipoprotein A-I complex specifically interacts with eukaryotic DNA and GCC elements of genes

Tetrahydrocortisol stimulates DNA and protein biosynthesis in hepatocytes only when it enters the complex with apolipoprotein A-I. Tetrahydrocortisol-apolipoprotein A-I (THC-apoA-I) complex specifically interacts with eukaryotic DNA isolated from rat liver. In the process of interaction, rupture of hydrogen bonds between the pairs of nitrous bases occurs with the formation of single-stranded DNA structures. In such state DNA forms complexes with DNA-dependent RNA-polymerase. The most probable site of binding the tetrahydrocortisol-apolipoprotein A-I complex with DNA is the sequence of CC(GCC)(n) type entering the structure of many genes, among them the structure of human apolipoprotein A-I gene. Oligonucleotide of this type has been synthesized. Association constant (K(ass)) of it with tetrahydrocortisol-apolipoprotein A-I complex was shown to be 1.66 x 10(6)M(-1). Substitution of tetrahydrocortisol for cortisol in the complex results in a considerable decrease of K(ass). It was assumed that in the GC-pairs of the given sequence tetrahydrocortisol itself participates in the formation of hydrogen bonds with cytosine, favoring their rupture with complementary base-guanine.

In situ shape and distance measurements in neutron scattering and diffraction

Neutron scattering combined with selective isotopic labeling and contrast matching is useful for obtaining in situ structural information about a selected particle, or particles, in a macromolecular complex. The observed intensities, however, may be distorted by inter-complex interference and by scattering-length-density fluctuations of the (otherwise) contrast-matched portions. Methods have been proposed to cancel out such distortions (Hoppe's method, the Statistical Labeling Method, and the Triple Isotopic Substitution Method). With these methods as well as related unmixed-sample methods, structural information about the selected particle(s) can be obtained without these distortions. We have generalized these methods so that, in addition to globular particles in solution, they can be applied to in situ structures of systems having underlying symmetry and/or net orientation as well. The information obtainable from such experiments is discussed.

Electrodeposition procedure of E. coli RNA polymerase onto gold and deposition of E. coli RNA polymerase onto mica for observation with scanning force microscopy

Molecules of the transcriptional enzyme E. coli RNA polymerase (RNAP) have been deposited using three different deposition methods: (1) passive adsorption onto gold, (2) electrochemical adsorption onto gold and (3) adsorption onto mica. In all cases SFM imaging was straightforward and reliable, and surface coverage by the protein varied with deposition conditions as expected. To determine the nature of the electrochemical treatment on the gold substrate, cyclic voltammetry was performed with various chemical solutions. Finally, a comparison is made between the SFM images of RNAP obtained with these methods and STM images obtained earlier. Both STM and SFM show strikingly similar results; however, heights and widths of individual molecules differ.

Immunoelectron microscopy of enzymes, multienzyme complexes, and selected other oligomeric proteins

The collective term "immunoelectron microscopy" subsumes a number of techniques in which the biological material is decorated with specific antibodies, prior to being visualized in the electron microscope. In this article, we have reviewed literature on immunoelectron microscopy that focusses on the analysis of the molecular architecture of proteins, in particular of enzymes and of multienzyme complexes. Molecular immunoelectron microscopy has been remarkably successful with multi-subunit enzymes of complex quaternary structures, and in many cases the data have been the basis for the eventual development of detailed three-dimensional molecular models. The elucidation of subunit composition and juxtaposition of a given enzyme, an important accomplishment in itself, has in turn stimulated and guided discussions on the catalytic mechanism; illustrative examples include F1 ATPase and citrate lyase, among others. Here we have chosen a variety of enzymes, multienzyme complexes, and non-enzymatic proteins to demonstrate the versatility of immunoelectron microscopy, to illustrate methodological prerequisites and limitations, and to discuss significance and implications of individual immunoelectron microscopy studies.

Spatial arrangement of sigma-factor and core enzyme of Escherichia coli RNA polymerase. A neutron solution scattering study

By means of neutron solution scattering we determined the position and orientation of core enzyme and sigma-factor within the Escherichia coli RNA polymerase holoenzyme with the aim of improving existing models. The individual components, core enzyme (E) and sigma-factor (sigma), were highlighted by deuterium labeling and their center-to-center distances determined in the monomeric and the dimeric holoenzyme. The following distance parameters were obtained: dE1-sigma 1 = 8.6(+/- 1) nm, dE1-E2 = 11.5(+/- 1) nm, d sigma 1-sigma 2 = 12.0(+/- 0.7) nm, dE1-sigma 2 = 9(+/- 3) nm. Using a triangulation procedure the position of the sigma-factors, sigma 1 and sigma 2, were determined with respect to the mass center of the core enzyme molecules, E1 and E2, assuming a symmetrical arrangement of the holoenzyme molecules in the dimer (C2 symmetry). In addition, the orientation of the sigma-factor with respect to core enzyme was estimated by means of model calculations. The obtained model of holoenzyme depicts the sigma-factor as buried in a groove of core enzyme, probably between the large subunits beta' and beta.

Low-resolution structure of the tetrameric phenylalanyl-tRNA synthetase from Escherichia coli. A neutron small-angle scattering study of hybrids composed of protonated and deuterated protomers

Escherichia coli phenylalanyl-tRNA synthetase is a tetrameric protein composed of two types of protomers. In order to resolve the subunit organization, neutron small-angle scattering experiments have been performed in different contrasts with all types of isotope hybrids that could be obtained by reconstituting the alpha 2 beta 2 enzyme from the protonated and deuterated forms of the alpha and beta subunits. Experiments have been also made with the isolated alpha promoter. A model for the alpha 2 beta 2 tetramer is deduced where the two alpha promoters are elongated ellipsoids (45 x 45 x 160 A3) lying side by side with an angle of about 40 degrees between their long axes and where the two beta subunits are also elongated ellipsoids (31 x 31 x 130 A3) with an angle of 30 degrees between their axes. This model was obtained by assuming that the two pairs of subunits are in contact in an orthogonal manner and by taking advantage of the measured distance between the centers of mass of the alpha 2 and beta 2 pairs (d = 23 +/- 2 A).

Monoclonal antibodies as probes of the topological arrangement of the alpha subunits of Escherichia coli RNA polymerase

Three monoclonal anti-alpha antibodies were used to study the properties of the alpha subunit of Escherichia coli RNA polymerase. None of the monoclonal antibodies inhibited the d(A-T)n-directed synthesis of r(A-U)n. Reassembly of the RNA polymerase core was blocked by mAb 129C4 or mAb 126C6 while no effect was observed with mAb 124D1. The conversion of premature to mature core was partially inhibited by mAb 129C4 and almost totally inhibited by mAb 126C6. The data suggest that during the course of core assembly at least one of the alpha subunits undergoes conformational changes. The increase in affinity of mAb 126C6 for assembled alpha compared with free alpha also implies that alpha undergoes conformational changes during RNA polymerase assembly. Double antibody binding studies showed that the epitopes for mAb 124D1 and mAb 129C4 are available on only one of the alpha subunits in RNA polymerase. It would appear that the relevant domain on one of the alpha subunits in RNA polymerase is well exposed whereas this domain on the second alpha subunit is shielded by interaction with regions of the large beta and beta' subunits. The alpha domain in which the epitope for mAb 126C6 resides is not impeded by subunit interactions in the RNA polymerase. The data obtained also suggest that in the holoenzyme the sigma subunit may be positioned close to one of the alpha subunits, probably to the more exposed alpha. The alpha beta complex is the minimal stable subassembly since one of the alpha subunits dissociates from the alpha 2 beta complex following binding of any of the monoclonal antibodies studied.(ABSTRACT TRUNCATED AT 250 WORDS)

Structural studies of proteins by high-flux X-ray and neutron solution scattering

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Spatial arrangement of DNA-dependent RNA polymerase of Escherichia coli and DNA in the specific complex. A neutron small angle scattering study

In this paper we demonstrate that neutron small angle scattering is a suitable method to study the spatial arrangement of large specific protein-DNA complexes. We studied the complex of DNA-dependent RNA polymerase of Escherichia coli and a 130 base-pair DNA fragment containing the strong promoter A1 of bacteriophage T7. Contrast variation of the complex with deuterium allowed us to "visualize" either RNA polymerase, or DNA, or both components in situ. From the corresponding scattering curves information was derived about: (1) Conformational changes of RNA polymerase and DNA by complex formation: comparison of the scattering profiles of the isolated and complexed components showed that by specific complex formation the cross-section of RNA polymerase decreases, while the DNA fragment does not undergo a gross conformational change. (2) The spatial arrangement of RNA polymerase and DNA in the specific complex from the cross-sectional radii of gyration of the complex the normal distance dn between the centre of gravity of the RNA polymerase and the axis of the DNA fragment was derived as 5.0 (+/- 0.3) nm. On the basis of these and footprinting data a low resolution model of the RNA polymerase-promoter complex is proposed. The main feature of this model is the positioning of RNA polymerase to only one side of the DNA.

Structure and evolution of prokaryotic and eukaryotic RNA polymerases: a model

A comparative overview of the subunit taxonomy and sequences of eukaryotic and prokaryotic RNA polymerases indicates the presence of a core structure conserved between both sets of enzymes. The differentiation between prokaryotic and eukaryotic polymerases is ascribed to domains and subunits peripheral to the largely conserved central structure. Possible subunit and domain functions are outlined. The core's flexible shape is largely determined by the elongated architecture of the two largest subunits, which can be oriented along the DNA axis with their bulkier amino-terminal head regions looking towards the 3' end of the gene to be transcribed and their more slender carboxyl-terminal domains at the tail end of the enzyme. The two largest prokaryotic subunits appear originally derived from a single gene.

The quaternary structure of Escherichia coli RNA polymerase studied with (scanning) transmission (immuno)electron microscopy

A model for the quaternary structure of Escherichia coli RNA polymerase (nucleosidetriphosphate:RNA nucleotidyltransferase, EC 2.7.7.6) is presented. It is based on results from classification of profiles of enzyme molecules, and from application of immuno electron microscopy. Classification of molecules, prepared with the single carbon layer technique, was first achieved for images recorded in dark field with the scanning transmission electron microscope and later on for images recorded in bright-field transmission electron microscopy. It results in five approximately equally sized groups, containing about 80% of the core enzyme profiles. Holoenzyme profiles can be grouped into the same classes, and have approximately the same dimensions (9 nm X 16 nm). Based on the shapes and sizes of the classified profiles, a tentative model for core enzyme has been constructed. Correlation of shadow projections of this model, with the distributions of attachment sites of antibodies against alpha, beta, beta' and sigma over the profiles, has led to models for core and holoenzyme in which the subunits are localized. The model is compared with literature data on the quaternary structure of RNA polymerase.

Topography of transcription: path of the leading end of nascent RNA through the Escherichia coli transcription complex

A cleavable dinucleotide photoaffinity reagent was prepared and used to map the path of the leading end of the RNA transcript across the surface of Escherichia coli RNA polymerase/T7 DNA transcription complexes. By using 5'-(4-azidophenacylthio)phosphoryladenylyl(3'-5')uridine, transcription was specifically initiated at the A1 promoter of bacteriophage T7 D111 or D123 DNA. Transcription complexes containing radiolabeled RNA chains of various lengths (4-116 nucleotides) were prepared, and the 5' end of the RNA transcript was then covalently attached to the nearby polymerase subunits or DNA by irradiation with UV light. The photoaffinity-labeled enzyme subunits and DNA were separated, the radiolabeled RNAs were cleaved from each, and the lengths and sequences of RNA attached to each component were determined. The leading end of RNA chains up to 12 bases long was found to label the DNA and the beta and beta' subunits of RNA polymerase, with more than 90% of the label going to the DNA. When the RNA transcript reached 12 bases in length, the 5' end diverged from the DNA and only the beta and beta' enzyme subunits were labeled thereafter. These two subunits were heavily labeled by RNA chains 12 to as many as 94 bases long. No significant labeling of the alpha subunit occurred. The sigma subunit was not labeled by RNAs longer than the trinucleotide.

The subunit positions within RNA polymerase holoenzyme determined by triangulation of centre-to-centre distances

The complete 'centre-of-subunit structure' of the multisubunit enzyme DNA-dependent RNA polymerase was determined by triangulation of the subunit positions using the intersubunit distances calculated from scattering difference measurements and from the corresponding radii of gyration R. In addition to the centre-to-centre distances d between the core subunits alpha 2, beta and beta' presented in the preceding paper, the values of d between initiation factor sigma and alpha 2 (8.4 +/- 1.6 nm), beta (4.4 +/- 2.2 nm) and beta' (10.7 +/- 1.5 nm) were derived from R of sigma (4.1 +/- 0.3 nm) in situ and of the pairs alpha 2--sigma (6.1 +/- 0.4 nm), beta--sigma (5.6 +/- 0.3 nm) and beta'--sigma (7.5 +/- 0.4 nm) within the holoenzyme (alpha 2 beta beta' sigma). The structural parameters of the subunits within their molecular complex are accessible for neutron small-angle scattering measurements using labelling of the different subunits (deuteration), total reconstitution of isotopic hybrids, scattering length density matching of 'hydrogenated' molecular parts and extended exposure times because of weak scattering effects. The overall shape of sigma bound to core enzyme (alpha 2 beta beta') proved to be identical (within experimental resolution) with sigma in the isolated state measured recently by X-ray small-angle scattering. The refined shape of isolated sigma was reduced to an ellipsoid which was orientated with respect to the core structure (alpha 2--beta--beta') in a 'space-filling' way around the position of the sigma centre obtained by triangulation. The complete subunit arrangement of holoenzyme is shown in a three-dimensional model.