UNIPROT:P06889 - FACTA Search

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Transcription in eukaryotic cells occurs in the context of chromatin. Binding of sequence-specific regulatory factors must contend with the presence of nucleosomes for establishment of a committed preinitiation complex. Here we demonstrate that the high-affinity binding site for heat shock transcription factor (HSF) is occupied independently of other cis-regulatory elements and is critically required for preventing nucleosomal assembly over the yeast HSC82 core promoter under both noninducing (basal) and inducing conditions. Chromosomal mutation of this sequence, termed HSE1, erases the HSF footprint and abolishes both transcription and in vivo occupancy of the TATA box. Moreover, it dramatically reduces promoter chromatin accessibility to DNase I and TaqI, as the nuclease-hypersensitive region is replaced by a localized nucleosome. By comparison, in situ mutagenesis of two other promoter elements engaged in stable protein-DNA interactions in vivo, the GRF2/REB1 site and the TATA box, despite reducing transcription three- to fivefold, does not compromise the nucleosome-free state of the promoter. The GRF2-binding factor appears to facilitate the binding of proteins to both HSE1 and TATA, as these sequences, while still occupied, are less protected from in vivo dimethyl sulfate methylation in a deltaGRF2 strain. Finally, deletion of a consensus upstream repressor sequence (URS1), positioned immediately upstream of the GRF2-HSE1 region and only weakly occupied in chromatin, has no expression phenotype, even under meiotic conditions. However, deletion of URS1, like mutation of GRF2, shifts the translational setting of an upstream nucleosomal array flanking the promoter region. Taken together, our results argue that HSF, independent of and dominant among sequence-specific factors binding to the HSC82 upstream region, antagonizes nucleosomal repression and creates an accessible chromatin structure conducive to preinitiation complex assembly and transcriptional activation.
Mol Cell Biol 1996 Dec
PMID:Heat shock factor gains access to the yeast HSC82 promoter independently of other sequence-specific factors and antagonizes nucleosomal repression of basal and induced transcription. 894 56

We have analyzed the structure of 18 S rRNA in native 40 S subunits using chemical modification followed by primer extension. The native subunits were modified using the single-stranded specific reagents dimethyl sulfate and 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide metho-p-toluenesulfonate. The modification pattern of the 18 S rRNA was compared to that obtained from derived 40 S subunits prepared by dissociation of unprogrammed 80 S ribosomes. Eighteen nucleotides showed different accessibility to the chemical probes in derived and native subunits. Half of these nucleotides were found in the central domain of the rRNA between the 1060 loop and the central pseudoknot. The remaining nucleotides were located in two clusters in the 5'- and 3'-domains of the 18 S rRNA. Derived 40 S subunits are free from non-ribosomal proteins. In contrast, native subunits are intermediates in protein synthesis initiation and contain stoichiometric amounts of initiation factor 3 (Sundkvist, I. C., and Staehelin, T. (1975) J. Mol. Biol. 99, 401-418). The possible role of this factor in altering the structure of 18 S rRNA in the native 40 S subunits is discussed.
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PMID:Structure of 18 S ribosomal RNA in native 40 S ribosomal subunits. 901 62

To identify the functional regulatory elements of the promoter of the cytoplasmic actin A3 gene in Bombyx mori, transient expression of A3-LacZ mutants was assayed in cultured Lepidoptera cells. This led to the recognition of two proximal and contiguous domains exerting strong negative and positive effects, respectively on promoter activity. The negative region contains a ten-base-pair sequence that binds Bombyx silk gland cell nuclear proteins in vitro. The positive regulatory element was identified as a serum response element (SRE) by its sequence, and its in vitro binding properties. Moreover, structural analysis of posterior and median silk gland cell chromatin by dimethyl sulfate-aided LMPCR revealed that SRE is bound to its cognate factor in situ, in most, if not all, the approximately 100,000 A3 copies of the polyploid DNA stock. The regulation of the A3 promoter in the silk gland would thus result from the combined action of these two antagonist factors.
J Mol Biol 1997 Jan 24
PMID:A strong inhibitory element down-regulates SRE-stimulated transcription of the A3 cytoplasmic actin gene of Bombyx mori. 901 41

The export of pre-mRNAs coding for the structural genes of the human immunodeficiency virus type I depends on the interaction of the Rev protein with a highly structured viral RNA sequence, the Rev-responsive element (RRE). To gain information about the structure of the RRE and the determinants of the in vivo RRE-Rev interaction, we have analyzed the structure of the 351 nt RRE RNA within living yeast (Saccharomyces cerevisiae) by dimethyl sulfate probing with or without Rev. The in vivo structure in the absence of Rev is generally similar to the previously established solution structure. In addition, we observe a single hypermethylated guanine residue (G128), located within the Rev high-affinity binding site, in vitro as well as in vivo. The important homopurine interaction between residues 129 and 106 is required for the hyperreactivity, confirming its biological relevance. Expression of wild-type Rev leads to a protection of this region and to modifications of the RRE structure: the high-affinity site becomes further structured, and Stem IIA is destabilized. High-level expression of the oligomerization-defective mutant M4 protein leads to the same protections without destabilization of Stem IIA. Taken together with other observations, the data suggest that Rev captures the unusual conformation of the high-affinity site, followed by additional changes in the structure of the RRE.
J Mol Biol 1997 Mar 14
PMID:A dynamic in vivo view of the HIV-I Rev-RRE interaction. 908 73

Nitrite reductase (NiR) is the second enzyme in the nitrate assimilatory pathway reducing nitrite to ammonium. The expression of the NiR gene is induced upon the addition of nitrate. In an earlier study, a 130 bp upstream region of the spinach NiR gene promoter, located between -330 to - 200, was shown to be necessary for nitrate induction of beta-glucuronidase (GUS) expression in tissue-specific manner in transgenic tobacco plant [28]. To further delineate the cis-acting elements involved in nitrate regulation of NiR gene expression, transgenic tobacco plants were generated with 5' deletions in the -330 to -200 region of the spinach NiR gene promoter fused to the GUS gene. Plants with the NiR promoter deleted to -230 showed a considerable increase in GUS activity in the presence of nitrate, indicating that the 30 bp region between -230 to -200 is crucial for nitrate-regulated expression of NiR. In vivo DMS footprinting of the -300 to -130 region of the NiR promoter in leaf tissues from two independent transgenic lines revealed several nitrate-inducible footprints. Footprinting within the -230 to -181 region revealed factor binding to two adjacent GATA elements separated by 24 bp. This arrangement of GATA elements is analogous to cis-regulatory sequences found in the promoters of nitrate-inducible genes of Neurospora crassa, regulated by the NIT2 Zn-finger protein. The -240 to -110 fragment of the NiR promoter, which contains two NIT2 consensus core elements, bound in vitro to a fusion protein comprising the zinc finger domain of the N. crassa NIT2 protein. The data presented here show that nitrate-inducible expression of the NiR gene is mediated by nitrate-specific binding of trans-acting factors to sequences preserved between fungi and higher plants.
Plant Mol Biol 1997 Jun
PMID:Footprinting of the spinach nitrite reductase gene promoter reveals the preservation of nitrate regulatory elements between fungi and higher plants. 922 57

The structure and accessibility of the S. cerevisiae U3A snoRNA was studied in semi-purified U3A snoRNPs using both chemical and enzymatic probes and in vivo using DMS as the probe. The results obtained show that S. cerevisiae U3A snoRNA is composed of a short 5' domain with two stem-loop structures containing the phylogenetically conserved boxes A' and A and a large cruciform 3' domain containing boxes B, C, C' and D. A precise identification of RNA-protein contacts is provided. Protection by proteins in the snoRNP and in vivo are nearly identical and were exclusively found in the 3' domain. There are two distinct protein anchoring sites: (i), box C' and its surrounding region, this site probably includes box D, (ii) the boxes B and C pair and the bases of stem-loop 2 and 4. Box C' is wrapped by the proteins. RNA-protein interactions are more loose at the level of boxes C and D and a box C and D interaction is preserved in the snoRNP. In accord with this location of the protein binding sites, an in vivo mutational analysis showed that box C' is important for U3A snoRNA accumulation, whereas mutations in the 5' domain have little effect on RNA stability. Our in vivo probing experiments strongly suggest that, in exponentially growing cells, most of the U3A snoRNA molecules are involved in the 10-bp interaction with the 5'-ETS region and in two of the interactions recently proposed with 18S rRNA sequences. Our experimental study leads to a slightly revised version of the model of interaction proposed by J. Hughes. Single-stranded segments linking the heterologous helices are highly sensitive to DMS in vivo and their functional importance was tested by a mutational analysis.
J Mol Biol 1997 Oct 31
PMID:An in vivo and in vitro structure-function analysis of the Saccharomyces cerevisiae U3A snoRNP: protein-RNA contacts and base-pair interaction with the pre-ribosomal RNA. 935 46

Streptomycin, an error-inducing aminoglycoside antibiotic, binds to a single site on the small ribosomal subunit of bacteria, but this site has not yet been defined precisely. Here, we demonstrate that streptomycin binds to E. coli 16 S rRNA in the absence of ribosomal proteins, and protects a set of bases in the decoding region against dimethyl sulfate attack. The binding studies were performed in a high ionic strength buffer containing 20 mM Mg2+. The pattern of protection in the decoding region was similar to that observed when streptomycin binds to the 30 S subunit. However, streptomycin also protects the 915 region of 16 S rRNA within the 30 S subunit, whereas it did not protect the 915 region of the naked 16 S rRNA. The interaction of streptomycin with 16 S rRNA was further defined by using two fragments that correspond to the 3' minor domain of 16 S rRNA and to the decoding analog, a portion of this domain encompassing the decoding center. In the presence of streptomycin, the pattern of protection against dimethyl sulfate attack for the two fragments was similar to that seen with the full-length 16 S rRNA. This indicates that the 3' minor domain as well as the decoding analog contain the recognition signals for the binding of streptomycin. However, streptomycin could not bind to the decoding analog in the absence of Mg2+. This contrasts with neomycin, another error-inducing aminoglycoside antibiotic, that binds to the decoding analog in the absence of Mg2+, but not at 20 mM Mg2+. Our results suggest that both neomycin and streptomycin interact with the decoding center, but recognize alternative conformations of this region.
J Mol Biol 1997 Oct 31
PMID:Streptomycin binds to the decoding center of 16 S ribosomal RNA. 935 48

The Escherichia coli RecBCD enzyme unwinds DNA from a free double-stranded DNA end to produce single-stranded DNA intermediates of homologous recombination. In the absence of ATP RecBCD binds to a free DNA end to form an initiation complex for DNA unwinding. We studied the structure of these complexes formed with blunt-ended, 5'-extended, and 3'-extended DNA. Reactivity to the single-stranded DNA-specific reagents KMnO4 and dimethyl sulfate indicated that RecBCD opened, in a Mg(2+)-dependent manner, the terminal five or six base-pairs in each substrate. Thymine residues located four to six nucleotides from the 5' end were only partially reactive to KMnO4, suggesting that part of the 5'-terminated strand was partially shielded by the enzyme. DNase I footprinting indicated that the enzyme positions itself relative to the end of the longer of the two strands, although an exception was noted. These results imply flexibility in the ability of RecBCD to open the DNA and position itself for unwinding on DNA with different types of ends. They also imply conformational differences of RecBCD enzyme bound to different types of ends; these conformational differences may be related to those occurring during the unwinding cycle.
J Mol Biol 1997 Oct 10
PMID:The RecBCD enzyme initiation complex for DNA unwinding: enzyme positioning and DNA opening. 936 52

A simple homopolymeric purine:purine.pyrimidine, d(GA)n:d(GA)n.d(TC)n, triplex DNA was generated in the presence of magnesium ion at neutral pH. Hydrogen bonding of the N7 positions of guanines and adenines was investigated by 7-deaza base substitutions and protection from chemical modification by dimethyl sulfate (DMS). Chemical modification of this triplex with DMS revealed an unexpected triplex specific hypermodification in the N3 positions of the adenines in addition to the protection in the N7 positions of the guanines. The significance of this increase in the chemical accessibility of the N3 positions of adenines in the minor groove and possible relevance of dehydration to the mechanism of triplex formation and stability is discussed.
Mol Cells 1997 Oct 31
PMID:An alteration in the structure of the minor groove of duplex DNA induced by the formation of an intermolecular d(GA)n:d(GA)n.d(TC)n triplex. 938 52

We have studied the interaction between recombination signal sequences (RSSs) and protein products of the truncated forms of recombination-activating genes (RAG) by gel mobility shift, DNase I footprinting, and methylation interference assays. Methylation interference with dimethyl sulfate demonstrated that binding was blocked by methylation in the nonamer at the second-position G residue in the bottom strand and at the sixth- and seventh-position A residues in the top strand. DNase I footprinting experiments demonstrated that RAG1 alone, or even a RAG1 homeodomain peptide, gave footprint patterns very similar to those obtained with the RAG1-RAG2 complex. In the heptamer, partial methylation interference was observed at the sixth-position A residue in the bottom strand. In DNase I footprinting, the heptamer region was weakly protected in the bottom strand by RAG1. The effects of RSS mutations on RAG binding were evaluated by DNA footprinting. Comparison of the RAG-RSS footprint data with the published Hin model confirmed the notion that sequence-specific RSS-RAG interaction takes place primarily between the Hin domain of the RAG1 protein and adjacent major and minor grooves of the nonamer DNA.
Mol Cell Biol 1998 Jan
PMID:Footprint analysis of the RAG protein recombination signal sequence complex for V(D)J type recombination. 941 11

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