Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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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)

We have conducted studies to obtain practical knowledge regarding the stability, digestion, and analytical determination of the content of 8-hydroxy-2-deoxy-guanosine (8-OHdG) in oxidatively damaged DNA. Utilizing H2O2 plus uv light to form oxidatively damaged DNA, we found that storage of the DNA at -20 degrees C at alkaline pH caused a significant loss of 8-OHdG, whereas storage at -20 degrees C at neutral or acidic pH prevented loss of 8-OHdG. The 8-OHdG within DNA is stable at 100 degrees C for at least 15 min. Formation of 8-OHdG within DNA using uv light and H2O2 as a hydroxyl free radical-generating system yields the highest amounts when low levels of phosphate buffer are used; but the use of Tris or citrate buffers causes a lower yield of 8-OHdG because these buffers act as scavengers for the hydroxyl free radicals. Independent assessment of hydroxyl free radical flux by the use of salicylate trapping allows assessment of competitive radical reactions. Ethanol washing of plastic microfuge tubes prior to DNA enzymatic digestion improved the yield of 8-OHdG and reduced the variability between samples. Digestion of the oxidatively damaged DNA by the use of a method involving DNase I, endonuclease, phosphodiesterase, and alkaline phosphatase produced the highest yield of 8-OHdG.
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PMID:Conditions influencing yield and analysis of 8-hydroxy-2'-deoxyguanosine in oxidatively damaged DNA. 222 56

The cation-dependent solubilization of rat thymocyte chromatin has been compared with decondensation of the nuclei as a function of sodium phosphate-mediated changes in the concentration of Mg2+ and Na+. After digestion of the nuclei with DNase I or Micrococcus nuclease for a time just sufficient to permit extraction of a maximal amount of chromatin (minimum digestion), solubilization of most of the chromatin was found to occur with the same cation dependency as decondensation of untreated nuclei, while further digestion changed the ionic requirements for solubilization. The cation-dependency of the chromatin solubility and of the nuclear decondensation also exhibited the same variations with temperature. The chromatin in the nuclei became up to 4-times more sensitive to DNase I by decondensation, which also induced a shift in the DNase I cleavage mode from a 200 bp to a 100 bp repeat pattern. In contrast, the sensitivity to Micrococcus nuclease appeared to be nearly unchanged. These results suggest that solubilization of chromatin prepared by a mild endonuclease treatment occurs as a direct consequence of structural changes in the chromatin which take place during decondensation of the nuclei.
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PMID:Cation-dependent solubilization of rat thymocyte chromatin is closely related to decondensation of the nuclei. 222 79

Mature DNA from phage T3 or T7 is a linear duplex DNA with direct repeats at its ends known as "terminally redundant sequences." The DNA of these phages is synthesized as concatemers in which unit length molecules are joined together in a head-to-tail fashion through the terminally redundant sequences and processed to form mature DNA with coupling to DNA packaging. When linearized plasmid DNA carrying a concatemer joint, a terminally redundant sequence and its flanking sequences from the concatemer, was incubated in a defined in vitro system for packaging T3 DNA, composed of purified proheads and packaging proteins (gp 18 and gp 19), DNA was cleaved at the left end of the terminally redundant sequence. The cleavage reaction required all factors necessary for DNA packaging. The DNA fragment with the left end was preferentially protected from DNase I digestion, indicating that the cleavage reaction occurs at the left end of the terminally redundant sequence in the concatemer when DNA is packaged leftward, corresponding to the direction from the right to the left end of the T3 genome. The cleavage reaction was stimulated by high concentrations of NaCl and ATP, a condition in which DNA translocation into the head is slowed down. The cleavage reaction was not specific between T3 and T7. The right end of the concatemer joint was not required for cleavage at the left end. In the absence of ATP, DNA was extensively degraded by gp 19. gp 19 by itself had nonspecific endonuclease activity, making double-stranded breaks. The activity was inhibited by either ATP or gp 18.
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PMID:In vitro cleavage of the concatemer joint of bacteriophage T3 DNA. 229 41

The transcription of the mouse alpha-fetoprotein gene in the fetal liver, gut, and yolk sac is under the control of at least four regulatory sequences, three 5' distal enhancers, and a proximal promoter region. In transgenic mice, the three enhancers exhibited distinct tissue preferences, with all three active in the visceral endoderm of the yolk sac, two in the fetal liver, and one in the fetal gut. To ask whether the enhancers are differentially utilized by the endogenous gene in the three tissues in vivo, we examined their differential sensitivity to the endonuclease DNase I. The experiments indicated that two of the three enhancers exhibited sensitivity to DNase I in all three fetal tissues, as well as in the adult liver, where the gene is transcriptionally repressed. The third enhancer, which exhibited the weakest activity in transgenic mice, was the least sensitive to DNase I in fetal liver and yolk sac and insensitive in the fetal gut. The major changes in the chromatin structure of the gene during postnatal development occurred within the proximal promoter region. The major DNase I cleavage site shifted from a position at 120 nucleotides upstream of the transcriptional start site to the start site itself. Two new sites, at 300 nucleotides upstream of the start site and 1.5 kb within the structural gene, were observed. These results suggest that the distal regulatory regions have the capability to retain biological activity throughout development, and that the primary repression of transcription of the gene proceeds through elements proximal to the promoter of the gene.
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PMID:Configuration of the alpha-fetoprotein regulatory domain during development. 245 88

Oligodeoxynucleotides with different arrangements of methylphosphonate linkages were examined for nuclease sensitivity in vitro, stability in tissue culture, and ability to form RNase H-sensitive substrates with complementary RNA. After nuclease treatment, resistance was demonstrated by the ability to alter the electrophoretic mobility of a labeled complementary phosphodiester oligodeoxynucleotide. Both 5'- and 3'-exonuclease activities were retarded by methylphosphonate linkages. Methylphosphonate-containing oligodeoxynucleotides with 1-5 adjacent phosphodiester linkages were tested as substrates for the endonucleases DNase I and DNase II. The results indicated that a span of three or fewer contiguous internal phosphodiester linkages led to the greatest resistance to endonuclease. However, in serum-supplemented culture medium half-lives of these oligodeoxynucleotides were independent of the number of contiguous phosphodiester linkages. Methylphosphonate-containing oligodeoxynucleotides were hybridized to RNA runoff transcripts and tested as substrates for RNase H. The results indicated that a span of three internal phosphodiester linkages in the oligodeoxynucleotide was necessary and sufficient to direct cleavage of the RNA in the duplex.
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PMID:Number and distribution of methylphosphonate linkages in oligodeoxynucleotides affect exo- and endonuclease sensitivity and ability to form RNase H substrates. 247 96

Binding mechanisms of ADPR-transferase to restricted double-stranded DNA fragments of SV40 and pBR322 DNA were determined by nuclease protection techniques. Top and bottom strands of double-stranded DNA were identified by specific labeling with 32P. Protection against specific exonucleases identified binding of ADPR-transferase to DNA termini, whereas binding to internal regions of linear DNAs was probed by protection against endonucleases. ADPR-transferase protein protected against exonucleolytic attack from lambda exo and exoIII in all DNA fragments tested, demonstrating that the enzyme protein binds indiscriminately to all DNA termini. Extending earlier results [Sastry, S.S., & Kun, E. (1988) J. Biol. Chem. 263, 1505-1512], the modifying effect of the binding of ADPR-transferase to DNA induced changes in DNA conformation, as evident from altered pause sites that appeared following digestion of DNA fragments by lambda exonuclease in the presence of ADPR-transferase. In contrast to the nonselective binding of ADPR-transferase to DNA termini, ADPR-transferase conferred protection endonuclease attack (DNase I and micrococcal nuclease) only to the 209-bp EcoRI-PstI SV40 DNA fragment. These results indicate that binding of ADPR-transferase to relatively rare internal regions of restricted DNA fragments exhibits some degree of specificity. Specificity of binding appears to be related to the coincidental relative A+T-rich regions in DNA, and to DNA bending, both identified in the 209-bp SV40 DNA fragment. Synthetic polydeoxyribonucleotides containing dA-dT bind ADPR-transferase stronger than polydeoxyribonucleotides containing dG-dC. It was deduced from endonuclease protection patterns that binding of the enzyme protein leaves no defined footprints on the 209-bp SV40 DNA fragment, but there is significant modification of DNA structure following binding of the enzyme protein. Methylation protection assays and the prevention of the binding of ADPR-transferase to T4 DNA by its glucosylation indicate that the enzyme binds in the major groove of DNA. The 36-kDa A peptide fragment of ADPR-transferase [Buki, K. G., & Kun, E. (1988) Biochemistry 27, 5990-5995] exhibits the same protection against endonucleolytic enzymes as the intact ADPR-transferase molecule.
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PMID:Binding of adenosine diphosphoribosyltransferase to the termini and internal regions of linear DNAs. 250 40

Endonuclease protection or "footprinting" analysis is a powerful technique for identifying the nucleotides involved in a protein-DNA interaction. DNase I is the most often employed endonucleolytic agent; however, this endonuclease does not exhibit the true nonsequence-specific cleavage desired for this type of analysis. Methidiumpropyl-EDTA (MPE) is a synthetic DNA intercalator that cleaves DNA in the presence of ferrous ion and oxygen. Cleavage by MPE exhibits no sequence specificity, a characteristic that makes this reagent better suited for protection analysis. Here we report a generally applicable technique for MPE protection (or "footprinting") analysis of specific DNA-protein complexes from a crude nuclear extract. We have used this method to identify the nucleotides of the immunoglobulin (Ig) heavy chain promoter region that are involved in complex formation with a protein that binds the octameric sequence ATGCAAAT, and we compare our results to those obtained previously using DNase I.
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PMID:Protection analysis (or "footprinting") of specific protein-DNA complexes in crude nuclear extracts using methidiumpropyl-EDTA-iron (II). 251 95

Integrated adenovirus type 12 (Ad12) genes in Ad12-transformed cell lines were investigated for chromatin structure, expression levels and states of DNA methylation. The E3 region in the Ad12-transformed cell line HA12/7 is hypermethylated and not expressed. The same region in the Ad12-transformed hamster cell lines T637 and A2497-3 is transcribed and undermethylated (Kruczek, I. and Doerfler, W. (1982) EMBO J. 1, 409-414). There was no significant difference in the DNase I sensitivity of the E3 region when nuclei of the aforementioned cell lines were incubated with this nuclease. In contrast, incubation of these nuclei with the restriction endonuclease PstI and subsequent cleavage of the DNA with BamHI generated an additional 0.9 kbp fragment in T637 and A2497-3 DNA which was not observed after treating HA12/7 nuclei and DNA in the same way. This finding was interpreted as indicative of differences in the chromatin structure of the E3 region depending on its state of transcriptional activity and its level of methylation. The E1 and major late promoter regions, which were transcriptionally active and inactive, respectively, in all three cell lines investigated, did not exhibit differences in sensitivity towards DNase I or PstI treatment of nuclei. More refined technology will be required to compare the chromatin structure of active versus inactive genes.
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PMID:Chromatin structure and levels of expression and DNA methylation in the E3 region of chromosomally integrated adenovirus type 12 DNA. 252 12

The chromatin structure and protein-DNA interactions of a cell cycle regulated human H3 histone gene have been examined at different levels of resolution. Using traditional Southern blot analysis we have investigated the accessibility of the H3 coding region and its flanking sequences to DNase I, S1 nuclease and restriction endonuclease digestion. Using the native genomic blotting method recently developed in our laboratory, two sites of protein-DNA interaction in the proximal 240 bp of the promoter region of this H3 gene were established. Further in vivo analysis of protein-DNA binding sites in intact cells by genomic sequencing revealed, with single nucleotide resolution, the guanine contacts and footprints of the proteins bound to the promoter. The relative locations of protein-DNA interactions in this H3 gene are similar to those identified in vivo and in vitro in a cell cycle dependent human H4 histone gene. The proteins complexed with the H3 histone gene promoter can be dissociated between 0.16 and 0.28 M NaCl. The protein-DNA contacts persist throughout the cell cycle and thus may have a functional relationship with the basal level of transcription of this H3 gene that occurs during and outside of S phase.
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PMID:In vivo protein binding sites and nuclease hypersensitivity in the promoter region of a cell cycle regulated human H3 histone gene. 253 85

The interactions of T7 RNA polymerase with its promoter DNA have been previously probed in footprinting experiments with either DNase I or (methidiumpropyl-EDTA)-Fe(II) to cleave unprotected DNA [Basu, S., & Maitra, U. (1986) J. Mol. Biol. 190, 425-437. Ikeda, R. A., & Richardson, C. C. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 3614-3618]. Both of these reagents have drawbacks; DNase I is a bulky reagent and so provides low resolution, and (methidiumpropyl-EDTA)-Fe(II) intercalates into DNA and is therefore biased toward cleavage of double-stranded DNA. In this study, the interaction between the polymerase and the promoter has been probed with Fe(II)-EDTA. This reagent generates reactive hydroxyl radicals free in solution, which produces a more detailed picture of the polymerase-promoter complex. Two protected regions are observed on each of the two promoter DNA strands: from position -17 to position -13 and from position -7 to position -1 on the coding strand and from position -14 to position -9 and from position -3 to position +2 on the noncoding strand. From this pattern it is clear that if recognition occurs via double-stranded B-form DNA, then the protected regions lie on one face of the DNA helix, and therefore the enzyme must interact predominantly from one side of the DNA helix. Digestion of the DNA in a polymerase-promoter complex with a single-strand-specific endonuclease shows that a small region of the noncoding strand near position -5 is susceptible to cleavage.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:T7 RNA polymerase interacts with its promoter from one side of the DNA helix. 254 54


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