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Query: EC:3.1.30.2 (
endonuclease
)
18,621
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
DNA sequence analysis of wild-type and mutant ADH2 loci suggested that two unusual features 5' of the promoter, a 22-base-pair perfect dyad sequence and a (dA)20 tract, were important for regulation of this gene (D. W. Russell, M. Smith, D. Cox, V. M. Williamson, and E. T. Young, Nature [London] 304:652-654, 1983). Oligonucleotide-directed mutagenesis was used to construct ADH2 genes lacking the 22-base-pair dyad or the (dA)20 tract (V.-L. Chan and M. Smith, Nucleic Acids Res. 12:2407-2419, 1984). These mutant genes and other ADH2 deletions constructed by
BAL
31
endonuclease
digestion were studied after replacing the wild-type chromosomal locus with the altered alleles by the technique of gene transplacement (T. L. Orr-Weaver, J. W. Szostak, and R. S. Rothstein, Proc. Natl. Acad. Sci. USA 78:6354-6358, 1981), using canavanine resistance as the selectable marker. Deletions lacking the dyad failed to derepress normally and did not respond to mutations at the ADR1 locus, which encodes a protein necessary to activate ADH2. Deletions of the (dA)20 tract did not have a detectable phenotype. A small deletion located just 3' to the (dA)20 tract (between positions -164 and -146) had a low amount of ADR1-dependent transcription during repressed growth conditions, indicating that the regulatory protein encoded by ADR1 is present in a potentially active form during repression and that alterations of a DNA sequence in the promoter region can unmask its latent activity.
...
PMID:ADR1-mediated regulation of ADH2 requires an inverted repeat sequence. 353 11
We describe a system to generate cDNA or genomic libraries from DNA segments that have blunt termini. Background and rearrangement levels are low, but efficiencies are high and the procedural times very short. T4 ligase in the presence of polyethylene glycol produces high Mr oligomers of vector and insert. These concatemers are reduced to vector-insert monomers at a high frequency by subsequent cleavage with a restriction
endonuclease
, which recognises the insert rarely, if at all, and the vector once. The monomers are recircularised under standard ligation conditions prior to transformation. Thus insertion conditions are optimised independently of those for recircularisation. All reading frames for expression libraries are generated by short
BAL
31 cleavage followed by the blunt-end cloning procedure. Similarly, genomic expression libraries can be made by
BAL
31 or mung-bean nuclease treatment after cleavage with DNase I is the presence of Mn2+. The technique is suitable for any DNA segment that is blunt-ended or can be made so. When the vector is treated with alkaline phosphatase, recombinants are generated at a frequency greater than 90% and have single inserts. Yields are 3-5 X 10(6) colony-forming units per micrograms of insert.
...
PMID:Rapid and efficient method for cloning of blunt-ended DNA fragments. 359 40
Based on the rationale that Escherichia coli cells harboring plasmids containing the pnt gene would contain elevated levels of enzyme, we have isolated three clones bearing the transhydrogenase gene from the Clarke and Carbon colony bank. The three plasmids were subjected to restriction
endonuclease
analysis. A 10.4-kilobase restriction fragment which overlapped all three plasmids was cloned into the PstI site of plasmid pUC13. Examination of several deletion derivatives of the resulting plasmid and subsequent treatment with exonuclease
BAL
31 revealed that enhanced transhydrogenase expression was localized within a 3.05-kilobase segment. This segment was located at 35.4 min in the E. coli genome. Plasmid pDC21 conferred on its host 70-fold overproduction of transhydrogenase. The protein products of plasmids carrying the pnt gene were examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of membranes from cells containing the plasmids. Two polypeptides of molecular weights 50,000 and 47,000 were coded by the 3.05-kilobase fragment of pDC11. Both polypeptides were required for expression of transhydrogenase activity.
...
PMID:Cloning and expression of the transhydrogenase gene of Escherichia coli. 388 96
Using a combination of restriction
endonuclease
digestion, nuclease
BAL
31 treatment, and standard ligation procedures, a 4.4-kb DNA segment that carried the yeast LEU4 gene [encoding alpha-isopropylmalate synthase (IPMS) I] and adjoining sequences was excised from an appropriate plasmid and replaced with the yeast HIS3 gene. The new plasmid was digested to obtain a linear HIS3-carrying fragment flanked by remnants of the LEU4 region. Integrative transformation of a LEU4fbr LEU5+ his3- strain with this fragment resulted in the deletion of the LEU4 gene from the genome of some recipients, as demonstrated by transformant phenotype, genetic analysis and the absence of RNA capable of hybridizing to a LEU4 probe. The leu4 deletion strains remained Leu+. The extract of one such strain contained about 18% of the IPMS activity of wild-type cells. It is concluded that the residual activity is that of a second IPMS (IPMS II) that depends on an intact LEU5 locus. IPMS II was inhibited by leucine, but its sensitivity was about an order of magnitude lower than that of IPMS I. Deletion of the LEU4 region by the method utilized here resulted in an amino acid auxotrophy that could be satisfied by methionine, homocysteine, or cysteine. Complementation tests and genetic analysis demonstrated that the affected gene was MET4. Linkage to MET4 would place the LEU4 gene on the left arm of chromosome XIV.
...
PMID:Total deletion of yeast LEU4: further evidence for a second alpha-isopropylmalate synthase and evidence for tight LEU4-MET4 linkage. 389 12
Deletions in the cloned thymidine kinase (TK) gene of herpes simplex virus type 1 (HSV-1), strain 17 syn+, were produced by two methods. Removal of a 506 base pair fragment from between the unique SstI and Bg/II restriction
endonuclease
sites of pTK1 (HSV-1 BamHI p cloned in pAT153) and subsequent transformation of Escherichia coli resulted in the isolation of 50 deleted plasmids. Sequential digestion of pTK1 with Bg/II and nuclease
BAL
31 followed by ligation and recleavage with Bg/II resulted in the isolation of 31 deleted plasmids. Three clones, pTK2, pTK3 and pTK4, obtained following Bg/II and SstI treatment of pTK1 were recombined with wild-type (wt) HSV-1 (17) syn+ DNA in baby hamster kidney (BHK) cells to produce TK- deletion mutants HSV-1 (17) TK 1301, HSV-1 (17) TK 1302 and HSV-1 (17) TK 1303 respectively. 5-Bromo-2'-deoxyuridine, 5-bromo-2'-deoxycytidine and 9-(2-hydroxyethoxymethyl)guanine were used to reduce the background of TK+ virus in heterogeneous recombinant stocks analysed for the presence of TK- recombinants. All recombinant clones isolated produced a small syncytial plaque morphology in BHK cells. The mutants HSV-1 (17) TK 1301 and HSV-1 (17) TK 1302 were TK-, failed to produce polypeptides of molecular weights 43000 and 19000 found in wt-infected cells and demonstrated one-step growth curves different from wt virus and the TK- mutant HSV-1 (17) dPyk-7. Superinfection studies with HSV-1 (17) TK 1301, HSV-1 (17) TK 1302, HSV-1 (MDK) and HSV-1 (17) dPyk-7 indicated that all TK- mutants except dPyK-7 produce a trans-acting gene product which can switch on the transforming HSV-1 TK gene.
...
PMID:Thymidine kinase deletion mutants of herpes simplex virus type 1. 629 78
DNA fragments from Pseudomonas aeruginosa carrying the PaeR7 restriction/modification genes have been cloned in the plasmid vector pBR322 and propagated in Escherichia coli. A subclone (pPAORM3.8) has been constructed that contains the complete restriction/modification system on a 3.8-kilobase DNA fragment. Digestion of the pPAORM3.8 plasmid with nuclease
BAL
-31 has yielded two types of clones. One type contains an active methylase gene but no active
endonuclease
gene; such clones will modify the DNA but not restrict the growth of incoming phage in vivo. The second type contains an active
endonuclease
gene but no active methylase gene, as judged both by in vivo tests and by the activity of the cell extracts in vitro. Although extracts of cells containing these plasmids display restriction
endonuclease
activity, these bacteria are unable to restrict the growth of incoming phage. Furthermore, chromosomal and phage DNA isolated from these host cells are not protected against cleavage by PaeR7 in vitro. The properties of PaeR7
endonuclease
and methylase enzymes have also been examined. The PaeR7 restriction
endonuclease
recognizes and cleaves the sequence C decreased T-C-G-A-G, as does Xho I. However, there exists a canonical Xho I site at 26.5% on the adenovirus 2 genome which is totally refractory to PaeR7 cleavage but is cut by Xho I. Under conditions of low salt, high glycerol, and high enzyme concentrations, a "PaeR7" activity is found that is similar to that observed for EcoRI. Finally, evidence is presented that the PaeR7 methylase modifies the adenine residue within the recognition sequence.
...
PMID:Cloned restriction/modification system from Pseudomonas aeruginosa. 630 Aug 41
We describe a rapid "nonrandom" DNA sequence analysis procedure that facilitates the nucleotide sequence determination of large contiguous regions of DNA. The method consists of cloning a restriction
endonuclease
fragment of interest into bacteriophage M13 followed by construction of a series of nuclease
BAL
-31 deletion mutants originating from a single site in M13 that is close to the DNA insert. Determination of the size of the deletion mutant is accomplished by hybridization to a complementary single-stranded probe derived from M13 containing that total insert followed by nuclease S1 treatment. Single-stranded M13-insert DNAs of progressively smaller sizes are isolated and analyzed by using a site-specific M13 DNA primer and the dideoxy chain-termination method. In this way, analysis of the DNA sequence proceeds from one end of the total insert to the other in a nonrandom fashion due to generation of a controlled overlapping set of deletion mutants.
...
PMID:"Nonrandom" DNA sequence analysis in bacteriophage M13 by the dideoxy chain-termination method. 695 59
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