EC:3.1.21.1 - FACTA Search

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Query: EC:3.1.21.1 (DNase)
7,655 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have used an Eppendorf centrifuge for isolation of transcription complexes assembled on VARNA genes and other related genes with NTP-depleted cell-free extracts. Similar to the 5 S rRNA gene, sedimentable, stable transcription preinitiation complexes could be assembled from two VARNA genes, two EB virus-specific EBER genes, four human tRNA genes, and one human Alu-family RNA gene, suggesting that the 5 S rRNA-specific transcription factor, TFIIIA, was not required for formation of these sedimentable, stable preinitiation complexes. Parameters affecting assembly of these complexes were sequences in circular DNA templates, sizes and sequences of linear DNA templates, temperature and incubation time. These complexes were stable at from 4 to 37 degrees C, and somewhat stable to salt wash. From results of effects of various mutations on assembly of these sedimentable complexes, we concluded that they were transcription machineries. Addition of the supernatant and partially purified factors to salt-washed complexes stimulated their transcription, we concluded that these sedimentable complexes were minimal transcription machineries containing suboptimal quantities of loosely bound transcription factors, TFIIIB, and RNA polymerase III. DNase 1 footprints of these sedimentable preinitiation complexes showed that two regions were protected, from +34 to +80 including the B block promoter element, and from +98 to +105. Similar DNase 1 footprints were also obtained from salt-washed complexes and stable preinitiation complexes isolated by molecular sieve column chromatography.
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PMID:Formation of large, sedimentable transcription complexes with VARNA genes and other related genes. 272 76

Yeast transcription factor tau forms a stable complex with tRNA genes. Using this property, the factor could be highly purified on a specific tDNA column. The purified factor was found by DNA footprinting to protect the whole yeast tRNA3Glu gene from position -8 to +81. A DNase-sensitive site was retained in the middle of the gene on both strands. The 3' border of the complex was mapped by exonuclease digestion at +88, just downstream of the termination signal. The 5' limit of the complex was found at position -11. However, upon prolonged incubation with exonuclease, the -11 blockage disappeared and the DNA molecules were digested to position +30 to 38 in the middle of the gene. Contact points at guanine residues were identified by dimethyl sulphate protection experiments. Reduced methylation of G residues in the presence of factor was found solely within the A block and in the B block region. All six invariant GC pairs (i.e., G10, G18, G19 and G53, C56 and C61) were found to have strong contacts with the factor. These results show that tau factor interacts with both the 5' and 3' half of the tRNA3Glu gene, with the B block region being the predominant binding site. The presence of this dual binding site suggests a model in which the factor would bind alternately at the A and B block regions to allow transcription of the internal promoter by RNA polymerase C.
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PMID:A split binding site for transcription factor tau on the tRNA3Glu gene. 286 29

We determined the complete nucleotide sequence of the gypsy element present at the forked locus of Drosophila melanogaster in the f1 allele. The gypsy element shares more homology with vertebrate retroviruses than with the copia element of D. melanogaster or the Ty element of Saccharomyces cerevisiae, both in overall organization and at the DNA sequence level. This transposable element is 7,469 base pairs long and encodes three putative protein products. The long terminal repeats are 482 nucleotides long and contain transcription initiation and termination signals; sequences homologous to the polypurine tract and tRNA primer binding site of retroviruses are located adjacent to the long terminal repeats. The central region of the element contains three different open reading frames. The second one encodes a putative protein which shows extensive amino acid homology to retroviral proteins, including gag-specific protease, reverse transcriptase, and DNA endonuclease.
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PMID:The Drosophila melanogaster gypsy transposable element encodes putative gene products homologous to retroviral proteins. 302 71

The effects of NaCl, EDTA and tRNA on methylation and enzymatic properties of deoxyribonuclease I (DNase I) were investigated. The methylation was carried out by S-methylmethionine (vitamin U) in the phosphate-citric buffer pH 4.0. It was found that 0.5 M NaCl decreases by about 30% the incorporation of CH3-groups into the DNase, whereas 1.5 M NaCl-by 47%. A similar, although a less pronounced effect, was exerted by tRNA within the concentration range of 1.36-34.7 microM. On the contrast, EDTA (0.01-0.05 M) stimulated the incorporation of CH3-groups by 15 and 30%, respectively. The functional properties of methylated DNase I in the presence of EDTA remained unaffected. The enzyme methylation in the presence of NaCl or tRNA caused deceleration of the 3H-DNA hydrolysis (by 15-30%) only within the first 20 min of the reaction.
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PMID:[Effect of various factors on the methylation of DNAse I]. 313 Aug 97

Zinc is an important cofactor for many enzymes involved in nucleic acid metabolism such as DNA and RNA polymerases, reverse transcriptase and tRNA synthetases. We have developed an inducible in vitro transcription system using metal-depleted nuclear extracts to reveal the presence and functional relevance of heavy metal ions in transcription factors. Using protein-DNA binding assays (band shift and DNAase I footprint) we show that Sp1, a promoter-specific vertebrate transcription factor that binds to the "GC box" (Sequence in text), is reversibly inactivated by metal-depletion. Zinc is required for specific DNA binding in vitro and is also essential for Sp1 factor-directed transcription. In contrast, another factor from HeLa cells, the so-called octamer transcription factor (OTF) that binds to the sequence 5'-ATGCAAATNA, is not affected by metal-depletion and thus seems not to be a zinc metalloprotein.
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PMID:Heavy metal ions in transcription factors from HeLa cells: Sp1, but not octamer transcription factor requires zinc for DNA binding and for activator function. 313 32

In small oocytes of Xenopus species, two sets of 5S RNA genes, oocyte-type and somatic-type, are fully activated. The 5S RNA transcripts are temporarily stored, half in association with TFIIIA to form a 7S particle, the other half in association with tRNA and two proteins (p48 and p43) to form a 42S particle. It has been established previously that TFIIIA binds to the internal control region of 5S RNA genes and promotes their transcription. Here we show that protein can be translocated from the 42S particles to 5S RNA genes, but only after treatment of the particles with ribonuclease. Nevertheless, once transferred, stable protein-DNA complexes are formed and DNase-protection experiments show that binding is specific to the gene promoter, covering exactly the same sequence as TFIIIA. The DNA-binding protein is identified as p48 which, after isolation by ion-exchange chromatography, will bind to 5S RNA genes in the absence of ribonuclease.
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PMID:An alternative protein factor which binds the internal promoter of Xenopus 5S ribosomal RNA genes. 368 70

Rat liver mitochondria isolated in sucrose-N-tris(hydroxymethyl)methyl-2-aminoethane-sulphonic acid (TES) incorporated [(3)H]UTP into RNA for 1h. Incorporation was inhibited 50% by 1mug of actinomycin D/ml, 1mug of acriflavine/ml and 0.5mug of ethidium bromide/ml but was insensitive to rifampicin, rifamycin SV, streptovarcin and deoxyribonuclease. After the first 10min of incubation, the synthesis was insensitive to ribonuclease. RNA synthesis by mitochondria isolated in sucrose-EDTA was insensitive to actinomycin D and sensitive to ribonuclease during the first 10min of the incubation but thereafter the sensitivities were the same as for mitochondria isolated in sucrose-TES. In a hypo-osmotic medium the relative extent of incorporation of the four ribonucleoside triphosphates into RNA was CTP>UTP=ATP>>GTP. In an iso-osmotic medium the incorporation of CTP and GTP decreased. All four nucleotides were incorporated into RNA in a DNA-dependent process, as indicated by the inhibition by actinomycin D. In addition, CTP and ATP were incorporated into the CCA end of mitochondrial tRNA. ATP was also incorporated into an unidentified acid-insoluble compound, which hydrolysed in alkali to a product that was not ATP, ADP or 5'- or 2(3')-AMP. Atractyloside inhibited the incorporation of ATP into RNA with 50% inhibition at 2-3nmol/mg of protein. The [(3)H]UTP-labelled RNA had peaks of 16S and 13S characteristic of mitochondrial rRNA. In addition a peak at 20-21S was observed as well as heterogeneous RNA sedimenting throughout the gradient. The synthesis of all these species was inhibited by actinomycin D, indicating that rat liver mitochondrial DNA codes for mitochondrial rRNA as well as other as yet unidentified species.
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PMID:Synthesis of ribonucleic acid by isolated rat liver mitochondria. 440 94

Escherichia coli spheroplasts lysed by Brij 58 and deoxycholate were separated into supernatant (S) and membrane fractions by low-speed centrifugation. The membrane fraction was further divided into that which was releasable by deoxyribonuclease (fraction D) and that which was not (M). In the presence of 10(-2)m Mg(2+), the S, D, and M fractions contained, respectively, 60, 20, and 20% of the total cellular ribonucleic acid (RNA). Ribosomal and transfer RNA (rRNA, tRNA) were found in each fraction. The M + D fraction RNA was labeled more by a pulse label. Incorporation of uracil into the D fraction continued only as long as the uptake of exogenous uracil, suggesting that this was a major primary site of RNA synthesis. From pulse-labeled cells, each fraction contained precursor rRNA, and there was a 10S RNA in the M fraction. Ninety per cent of the ribosomal subunits and the ribosomal precursor particles, 26 and 43S, were in the S fraction. Precursor RNA (17S) was found in the 26S precursor particles. The D fraction contained 38% of the polysomes (this does not consider polysomes, if any, of the M fraction) which were labeled four times as much as the supernatant polysomes by a 1-min pulse of uracil. These results are interpreted to mean that new RNA is associated with a cytoplasmic membrane-RNA polymerase-DNA complex.
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PMID:"Compartmentalization" of Escherichia coli ribosomes and ribonucleic acid. 455 51

Cell-free peptide synthesis by extracts from vegetative cells and spores of Bacillus subtilis was analyzed and compared. The initial rate of phenylalanine incorporation in a polyuridylate-directed system was found to be in a similar range for the two extracts. However, spore extracts frequently incorporated less total phenylalanine as did the vegetative cell system. Optimal conditions for amino acid incorporation by spore extracts were found to be similar to those of vegetative cell extracts. Polyphenylalanine synthesis was stimulated by preincubation of both extracts prior to the addition of polyuridylic acid (poly U) and labeled phenylalanine. Both systems showed a dependence on an energy-generating system and were inhibited by chloramphenicol and puromycin. Ribonuclease, but not deoxyribonuclease, inhibited the reaction significantly. The presence of methionine transfer ribonucleic acid (tRNA(F)) and methionyl-tRNA(F) transformylase was demonstrated in spore extracts. An analysis of several aminoacyl-tRNAs in spores revealed that the relative amounts of these tRNAs were similar to those found in vegetative cells. Only lysine tRNA was found to be present in relatively greater amounts in spores. These results indicate that dormant spores of B. subtilis contain the machinery for the translation of genetic information.
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PMID:Peptide synthesis by extracts from Bacillus subtilis spores. 498 76

The rate of in vivo transcription from the E. coli tRNA and rRNA promoters depends on both cellular growth rate and aminoacid availability. To investigate the molecular mechanisms involved we determined the extent of interaction of RNA polymerase with the promoter of the tyrT stable RNA gene. We show that the enzyme can protect from DNAase I digestion a region of at least 85 bp of the wild-type tyrT promoter and only approximately 62 bp of the lacUV5 mRNA promoter, the protected region extending on the antisense strand to approximately 65 and 42 bp respectively upstream of the transcription startpoint. A mutant tyrT promoter, tyrTp27, is protected more extensively, RNA polymerase interactions extending to at least approximately -130. We propose that these upstream interactions of RNA polymerase perform two functions; activating initiation by polymerase bound at the primary binding site and increasing the concentration of polymerase in the vicinity of the tyrT promoter, thus allowing a high rate of maximal expression and enabling the promoter to be regulated over a wide range of activity.
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PMID:RNA polymerase interactions with the upstream region of the E. coli tyrT promoter. 619

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