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Query: EC:3.1.30.1 (
S1 nuclease
)
3,660
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The late genes of bacteriophage P2 are clustered into four transcription units. We have reported the transcription initiation sites for two of the late messenger RNAs, encoding genes QP and ONMLKRS. We have now located the 5' ends of the two remaining late mRNAs. The first gene in the VJHG transcription unit has been located by DNA sequence determination of the single nucleotide change in a V amber mutant. Location of the first gene in the FETUD transcription unit has been inferred from the DNA sequence. The 5' ends of the mRNAs for these two transcription units were located by protection of end-labeled restriction fragments in RNA-DNA hybrids from digestion with
nuclease S1
. Similar protection of hybrids using RNA that had been 5' end-labeled with [alpha-32P]
GTP
and guanylyl transferase confirmed that these 5' termini resulted from initiation of transcription. The DNA sequences preceding the P2 late transcription starts are different from the Escherichia coli promoter consensus sequences at -10 and -35, consistent with the apparent requirement for phage-encoded proteins in the regulation of P2 late gene expression. The four P2 late promoters do share sequence homologies in the -10 and -35 regions, however, and several additional homologies further upstream. P2 late gene expression also appears to involve negative regulation by a product of the ONMLKRS gene cluster. When cells are infected with P2 polar O amber mutants, a marked increase in the levels of proteins encoded by the other three gene clusters is observed. This increase is reflected in the amounts of late mRNAs, suggesting that RNA synthesis is normally repressed or that late mRNAs are more labile in the presence of a gene product from the ONMLKRS transcription unit. Satellite phage P4 induced P2 late gene expression without the usual requirement for P2 DNA replication. The 5' ends of the P2 late mRNAs are the same during P4 transactivation as during normal P2 late gene expression. Thus, the regulation of P2 late gene expression by P4 does not involve altered promoter selection.
...
PMID:Bacteriophage P2 late promoters. II. Comparison of the four late promoter sequences. 398 40
The DNA sequences encoding the large subunit of the mRNA-capping enzyme of vaccinia virus were located on the viral genome. The formation of an enzyme-guanylate covalent intermediate labeled with [alpha-32P]
GTP
allowed the identification of the large subunit of the capping enzyme and was used to monitor the appearance of the enzyme during the infectious cycle. This assay confirmed that after vaccinia infection, a novel 84,000-molecular-weight polypeptide corresponding to the large subunit was rapidly synthesized before viral DNA replication. Hybrid-selected cell-free translation of early viral mRNA established that vaccinia virus encoded a polypeptide identical in molecular weight with the 32P-labeled 84,000-molecular-weight polypeptide found in vaccinia virions. Like the authentic capping enzyme, this virus-encoded cell-free translation product bound specifically to DNA-cellulose. A comparison of the partial proteolytic digestion fragments generated by V8 protease, chymotrypsin, and trypsin demonstrated that the 32P-labeled large subunit and the [35S]methionine-labeled cell-free translation product were identical. The mRNA encoding the large subunit of the capping enzyme was located 3.1 kilobase pairs to the left of the HindIII D restriction fragment of the vaccinia genome. Furthermore, the mRNA was determined to be 3.0 kilobases in size, and its 5' and 3' termini were precisely located by
S1 nuclease
analysis.
...
PMID:Identification of the DNA sequences encoding the large subunit of the mRNA-capping enzyme of vaccinia virus. 609 Jun 98
The initiation sites for heavy (H) and light (L) strand transcription in HeLa cell mitochondrial DNA have been investigated by mapping experiments utilizing in vitro "capped" mitochondrial RNA molecules or nascent RNA chains. Mitochondrial poly(A)-containing RNA molecules were labeled at their 5' ends with [alpha-32P]
GTP
and guanylyltransferase ("capping" enzyme) and mapped on the mitochondrial genome by DNA transfer hybridization and
S1 nuclease
protection experiments. A mapping site for the capped 5' ends was found on the H strand very near to the 5' terminus of the 12S rRNA gene, and another site was found on the L strand very near to the 5' terminus of the 7S RNA coding sequence. In parallel experiments, the 5' ends of the nascent chains isolated from mitochondrial DNA transcription complexes were similarly mapped very near to the 5' termini of the 12S rRNA gene and of the 7S RNA coding sequence. The in vitro capped RNA molecules and the nascent chains thus presumably identify the same transcriptional initiation sites on the H strand and the L strand. The occurrence of a second possible initiation site for H-strand transcription 90-110 nucleotides upstream of that described above--i.e., 20-40 nucleotides upstream of the tRNAPhe gene--had been previously indicated by a mapping analysis of the nascent RNA chains and has been confirmed in the present work. The presence of two initiation sites for H-strand transcription can be correlated with other types of evidence that point to two different transcription events leading to the synthesis of a polycistronic molecule corresponding to the almost entire H strand and to the synthesis of the rRNA species.
...
PMID:Identification of initiation sites for heavy-strand and light-strand transcription in human mitochondrial DNA. 618 47
We have determined transcriptional initiation sites for the ATPase subunit 9 gene on the yeast mitochondrial genome. Using
S1 nuclease
mapping, in vitro capping of primary transcripts with
GTP
and guanylyl transferase, and in vitro transcription analysis with purified mitochondrial RNA polymerase, we find the major site of transcriptional initiation to be at a point 630 nucleotides upstream of the coding region for the gene. In addition, we find much lower levels of initiation at a second site 78 nucleotides downstream of the first. Both initiation sites occur at the same position within a nonanucleotide sequence which we have previously found associated with initiation of rRNA synthesis. This work further supports the notion that this nonanucleotide sequence is an integral component of mitochondrial promoters and indicates that the same RNA polymerase is used for transcription of both mRNA and rRNA in yeast mitochondria.
...
PMID:Initiation of transcription of the yeast mitochondrial gene coding for ATPase subunit 9. 623 27
We have used two methods to detect specific transcription of the chicken alpha 2 (type I) collagen gene in cell-free extracts derived from Rous sarcoma virus-transformed chicken embryo fibroblasts. The first method is a modification of the
S1 nuclease
mapping procedure which utilizes a DNA probe labeled with 32P at the 5' end of the HindIII linker originally used to clone the collagen promoter region into PBR322. The probe distinguishes newly made, specific RNA from endogenous RNA and nonspecific transcripts. Using this procedure we have found that chicken whole cell extracts support accurate initiation of transcription of the chicken alpha 2 (type I) collagen DNA template. Addition of either creatine phosphate,
GTP
, or UTP to concentrations of approximately 3 to 5 mM was found to stimulate RNA polymerase II transcription by 5- to 10-fold. The second method employs an avian myeloblastosis virus reverse transcriptase-catalyzed primary extension procedure, rendered in vitro-specific by use of a pBR322 fragment as primer. These two techniques should be useful for analyzing specific transcription in other types of cell-free extracts.
...
PMID:Transcription of the chicken alpha 2 (Type I) collagen gene by homologous cell-free extracts. 628 36
We have examined the initiation of transcription of the mitochondrial genes for ribosomal RNA (rRNA) in the yeast Kluyveromyces lactis and show that these are transcribed independently from individual promoters. The mature large rRNA contains a 5' di- or triphosphate end which can be labelled in vitro with [alpha-32P]
GTP
using guanylyltransferase and this enabled us to determine the nucleotide sequence of its 5' terminus. For the small rRNA, a minor in vitro capped RNA species hybridizes in the region where--as judged from
S1 nuclease
protection experiments--the precursor of this RNA starts. We have determined the DNA sequence around the beginning of both rRNA genes and this reveals the existence of an identical nonanucleotide sequence (5' -ATATAAGTA- 3') just preceding the positions where the rRNAs start. This sequence is identical to the one preceding the rRNA genes in the mtDNA of the distantly related yeast Saccharomyces cerevisiae (Osinga, K.A. and Tabak, H.F. (1982) Nucl.Acids Res. 10, 3617-3626) and supports our proposal that this sequence motif is part of a yeast mitochondrial promoter. We have noticed that the same sequence is located in the putative origin of replication present in hypersuppressive petite mutants of S. cerevisiae and consider the possibility that this sequence is involved in RNA priming of DNA replication.
...
PMID:A nonanucleotide sequence involved in promotion of ribosomal RNA synthesis and RNA priming of DNA replication in yeast mitochondria. 629 5
Divergent transcription of two of the bacteriophage P2 late mRNAs, encoding genes QP and ONMLKRS, is initiated from opposite strands of the DNA in a region near the left end of the P2 genome. The first gene in each of these transcription units (P and O) has been located in the nucleotide sequence by amino-terminal sequence analysis of the P gene product and by DNA sequence determination of the single nucleotide changes in two O amber mutants. The 5' ends of the P and O gene mRNAs are separated by 109 nucleotide pairs in the DNA template. The locations of these 5' termini were determined by protection of end-labeled restriction fragments in RNA-DNA hybrids from digestion with
nuclease S1
. Sequence analysis of mRNA that had been labeled at the 5' end with [alpha-32P]
GTP
and guanylyl transferase confirmed that these termini resulted from initiation of transcription. The DNA sequences preceding the O and P transcription starts have poor homologies to the bacterial promoter consensus sequences at -10 and -35, consistent with the apparent requirement for phage-encoded proteins in the regulation of P2 late gene expression. The O and P promoter regions also have no detectable homology to each other in the -10 or -35 regions, and are unusually G + C-rich. There are, however, blocks of sequence homology within the transcribed region of each of these two late operons near the 5' end. Satellite phage P4 induces P2 late gene expression without the usual requirement for P2 DNA replication. The 5' ends of the P2 P and O gene transcripts are the same during P4 "transactivation" as during normal P2 late gene expression. Thus the regulation of P2 late gene expression by P4 does not involve a change in the site for initiation of transcription.
...
PMID:Bacteriophage P2 late promoters. Transcription initiation sites for two late mRNAs. 630 67
We characterize a 1.95 kb transcription product of the Euglena gracilis chloroplast DNA fragment Eco-N + Q by
S1 nuclease
analysis and DNA sequencing and show that it is the product of three splicing events. Exon 1 (0.45 kb), exon 2 (0.74 kb) and 175 nucleotides of exon 3 (0.53 kb) code for the chloroplast elongation factor protein (EF-Tu). The remaining part of exon 3 and exon 4 (0.23 kb) have unidentified open reading frames. The chloroplast EF-Tu protein has 408 aminoacids and is to 70% homologous with the E. coli EF-Tu protein. The active site for aminoacyl-tRNA binding is highly conserved, while the active site for
GTP
/GDP binding lacks the cysteine present in the E. coli EF-Tu protein. The two introns separating exons 1, 2 and 3 are, respectively, 103 and 110 nucleotides long. The size of the third intron is not yet determined. The splicing rules for eukaryote mRNA are not followed.
...
PMID:Nucleotide sequence of a Euglena gracilis chloroplast genome region coding for the elongation factor Tu; evidence for a spliced mRNA. 631 May 19
A discrete primary transcript of HeLa mitochondrial DNA containing 12 S rRNA, tRNAPhe, and 19 +/- 2 nucleotides upstream has been identified. The 5' ends of heavy strand encoded RNAs adjacent to the D-loop region of mitochondrial DNA were mapped by primer extension and
S1 nuclease
protection to a site 19 +/- 2 nucleotides upstream from the start of tRNAPhe. Hybridization of a tRNAPhe-specific probe to a blot of mitochondrial RNA detected a discrete species with a molecular weight consistent with an RNA containing 12 S rRNA, tRNAPhe, and a short upstream leader sequence. The di- or triphosphate nature of the 5' end of this polycistronic RNA was demonstrated by in vitro capping with [alpha-32P]
GTP
and guanylyltransferase.
S1 nuclease
protection of the purified in vitro capped RNA established that the 5' end, 19 +/- 2 nucleotides upstream from tRNAPhe, is an initiation site for heavy strand transcription.
...
PMID:Identification and in vitro capping of a primary transcript of human mitochondrial DNA. 632 46
We have studied the initiation of human ribosomal RNA synthesis in vitro using a cell-free polymerase I transcription system derived from HeLa cells and cloned human ribosomal DNA containing the site of initiation for ribosomal RNA synthesis. Mapping of the RNA products by run-off assays and high-resolution
S1 nuclease
analysis indicated that transcription in vitro initiates at a unique site and that the RNA has the same 5' terminus as in vivo precursor ribosomal RNA isolated from nuclei of HeLa cells. To provide additional evidence for the initiation site of ribosomal RNA transcription, dinucleoside monophosphates complementary to a sequence on the template have been used as primers for ribosomal RNA synthesis. When the concentrations of the four nucleoside triphosphates in the transcription reaction were reduced to 10 microM, [alpha-32 P]
GTP
was no longer incorporated into the run-off transcript. Under these conditions, we then tested a variety of dinucleotides for their ability to initiate promoter-specific RNA synthesis, and found that GpC exhibited maximum stimulation. We have also determined that the human cell-free system exhibits a significant degree of template specificity and is able to transcribe ribosomal DNA derived from human and rhesus monkey cells but not from mouse cells.
...
PMID:In vitro transcription of human ribosomal RNA genes by RNA polymerase I. 715 90
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