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Enzyme
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Query: EC:5.99.1.2 (
topoisomerase
)
9,166
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Renaturation of two complementary single-stranded circles should be limited by topological constraints against the rewinding of the DNA helix. If a mixture of complementary single-stranded rings is annealed and then treated with the DNA
untwisting enzyme
, the DNA circles completely renature as judged by (i) the presence of interlocked rings that sediment at 53 S in alkali, (ii) the buoyant density of the renatured DNA in CsCl gradients containing ethidium bromide, and (iii) the resistance of the product to the single-strand-specific
S1 nuclease
. Therefore, the DNA
untwisting enzyme
is able to provide a transient single-strand break that is sufficient to allow the two strands to completely rewind. The possibility that the
untwisting enzyme
might facilitate the initiation of the process of genetic recombination is discussed.
...
PMID:Renaturation of complementary single-stranded DNA circles: complete rewinding facilitated by the DNA untwisting enzyme. 20 51
Topoisomerase II displays higher affinity for supercoiled DNA compared to the same relaxed DNA. Moreover, cruciform structures are formed in topologically constrained DNA. Here we report that, using
S1 nuclease
experiments on supercoiled DNA, hairpin structures are located close to numerous
topoisomerase
II cleavage sites on the BPV I genome. Therefore, DNA secondary structure may play a role in the recognition mechanism of DNA by
topoisomerase
II.
...
PMID:Does cruciform DNA provide a recognition signal for DNA-topoisomerase II? 133 57
We have determined the nucleotide sequence of the Drosophila DNA topoisomerase II gene. Data from primer extension and
S1 nuclease
protection experiments were combined with comparisons of genomic and cDNA sequences to determine the structure of the mature messenger RNA. This message has a large open reading frame of 4341 nucleotides. The length of the predicted protein is 1447 amino acids with a molecular weight of 164,424. Topoisomerase II can be divided into three domains: (1) an N-terminal region with homology to the B (ATPase) subunit of the bacterial type II
topoisomerase
, DNA gyrase; (2) a central region with homology to the A (breaking and rejoining) subunit of DNA gyrase; (3) a C-terminal region characterized by alternating stretches of positively and negatively charged amino acids. DNA topoisomerase II from the fruit fly shares significant sequence homology with those from divergent sources, including bacteria, bacteriophage T4 and yeasts. The location and distribution of homologous stretches in these sequences are analyzed.
...
PMID:Structure of the Drosophila DNA topoisomerase II gene. Nucleotide sequence and homology among topoisomerases II. 253 21
In the absence of DNA aggregation, spermidine inhibited the relaxation of negatively supercoiled DNA by Escherichia coli topoisomerase I at concentrations of the polyamine normally found intracellularly. Spermidine also curtailed the cleavage of negatively supercoiled ColE1 DNA by the enzyme in the absence of Mg2+. On the contrary, knotting of M13 single-stranded DNA circles catalyzed by topoisomerase I was stimulated by the polyamine. Relaxation of supercoiled DNA by eukaryotic type 1 topoisomerases, such as calf thymus topoisomerase I and wheat germ
topoisomerase
, was significantly stimulated by spermidine in the same range of concentrations that inhibited the prokaryotic enzyme. In reactions catalyzed by
S1 nuclease
, the polyamine enhanced the digestion of single-stranded DNA and inhibited the nicking of negatively supercoiled DNA. These results suggest that spermidine modifies the supercoiled duplex substrate in these reactions by modulating the degree of single strandedness.
...
PMID:Differential modulation by spermidine of reactions catalyzed by type 1 prokaryotic and eukaryotic topoisomerases. 300 Apr 18
Sundin and Varshavsky (J. Mol. Biol. 132:535-546, 1979) found that nearly two-thirds of simian virus 40 (SV40) minichromosomes obtained from nuclei of SV40-infected cells become singly nicked or cleaved across both strands after digestion with staphylococcal nuclease at 0 degrees C. The same treatment of SV40 DNA causes complete digestion rather than the limited cleavages produced in minichromosomal DNA. We have explored this novel behavior of the minichromosome and found that the nuclease sensitivity is dependent upon the topology of the DNA. Thus, if minichromosomes are pretreated with wheat germ DNA topoisomerase I, the minichromosomal DNA is completely resistant to subsequent digestion with staphylococcal nuclease at 0 degrees C. If the minichromosome-associated
topoisomerase
is removed, virtually all of the minichromosomes are cleaved to nicked or linear structures by the nuclease treatment. The cleavage sites are nonrandomly located; instead they occur at discrete loci throughout the SV40 genome. SV40 minichromosomal DNA is also cleaved to nicked circles and full-length linear fragments after treatment with the single strand-specific
endonuclease S1
; this cleavage is also inhibited by pretreatment with topoisomerase I. Thus, it may be that the nuclease sensitivity of minichromosomes is due to the transient or permanent unwinding of discrete regions of their DNA. Direct comparisons of the extent of negative supercoiling of native and
topoisomerase
-treated SV40 minichromosomes revealed that approximately two superhelical turns were removed by the
topoisomerase
treatment. The loss of these extra negative supercoils from the DNA probably accounts for the resistance of the
topoisomerase
-treated minichromosomes to the staphylococcal and S1 nucleases. These findings suggest that the DNA in SV40 intranuclear minichromosomes is torsionally strained. The functional significance of this finding is discussed.
...
PMID:Simian virus 40 minichromosomes contain torsionally strained DNA molecules. 301 97
Negatively superhelical pNS1 DNA with a molecular weight of 2.55 MDa (4 kbp) was found to contain 13 specific, unbasepaired sites that are sensitive to a single-strand-specific
S1 nuclease
cleavage. The S1-cleavage occurred once at these sites. In the absence of added Mg2+, the topoisomerase I purified from Haemophilus gallinarum formed a complex with the superhelical pNS1 DNA which has a hidden strand cleavage. Extensive proteinase K digestion of the complex led to cleavage of the DNA chain. Then the proteinase K-cleaved product was digested with S1, which can cut the opposite strand at the preexisting strand cleavage to generate unit-length linear DNA. Restriction endonuclease analysis of the linear DNA shows that the
topoisomerase
-induced cleavage occurred once at ten specific sites on the DNA. The
topoisomerase
caused mainly single-strand cleavage at these sites, but infrequently also caused double-strand cleavage at the same sites. Of interest is the fact that these sites considerably coincide with the S1-cleavable, unbasepaired sites.
...
PMID:Correlation of enzyme-induced cleavage sites on negatively superhelical DNA between prokaryotic topoisomerase I and S1 nuclease. 630 25
The gene TOP2 encoding yeast
topoisomerase
II has been cloned by immunological screening of a yeast genomic library constructed in the phage lambda expression vector, lambda gt11. The ends of the message encoded by the cloned DNA fragment were delimited by the Berk and Sharp procedure (
S1 nuclease
mapping) for the 5' end and mapping of the polyA tail portion of a cDNA fragment for the 3' end. The predicted size of the message agrees with the length of the message as determined by Northern blot hybridization analysis. The identity of the gene was confirmed by expressing the gene in E. coli from the E. coli promoter lac UV5 to give catalytically active yeast DNA topoisomerase II. Disruption of one copy of the gene in a diploid yeast creates a recessive lethal mutation, indicating that the single DNA topoisomerase II gene of yeast has an essential function.
...
PMID:Yeast DNA topoisomerase II is encoded by a single-copy, essential gene. 632 17
DNA end-labeling procedures were used to analyze both the frequency and distribution of DNA strand breaks in mammalian cells exposed or not to different types of DNA-damaging agents. The 3' ends were labeled by T4 DNA polymerase-catalyzed nucleotide exchange carried out in the absence or presence of Escherichia coli endonuclease IV to cleave abasic sites and remove 3' blocking groups. Using this sensitive assay, we show that DNA isolated from human cells or mouse tissues contains variable basal levels of DNA strand interruptions which are associated with normal bioprocesses, including DNA replication and repair. On the other hand, distinct dose-dependent patterns of DNA damage were assessed quantitatively in cultured human cells exposed briefly to menadione, methylmethane sulfonate,
topoisomerase
II inhibitors, or gamma rays. In vivo induction of single-strand breaks and abasic sites by methylmethane sulfonate was also measured in several mouse tissues. The genomic distribution of these lesions was investigated by DNA cleavage with the single-strand-specific
S1 nuclease
. Strikingly similar cleavage patterns were obtained with all DNA-damaging agents tested, indicating that the majority of S1-hypersensitive sites detected were not randomly distributed over the genome but apparently were clustered in damage-sensitive regions. The parallel disappearance of 3' ends and loss of S1-hypersensitive sites during post-gamma-irradiation repair periods indicates that these sites were rapidly repaired single-strand breaks or gaps (2- to 3-min half-life). Comparison of S1 cleavage patterns obtained with gamma-irradiated DNA and gamma-irradiated cells shows that chromatin structure was the primary determinant of the distribution of the DNA damage detected.
...
PMID:Clusters of S1 nuclease-hypersensitive sites induced in vivo by DNA damage. 927 20
A 52 base pair alternating purine-pyrimidine (RY) repeat sequence lies in the 5' upstream region of the human beta-globin gene. The structural transition of a plasmid containing this repeat was analyzed by two-dimensional gel electrophoresis. These conformational studies indicate that the 52 bp RY repeat undergoes local transition from the right-handed B-DNA into a cruciform DNA under torsional stress and the transition initiates at a threshold level of negative supercoiling (-sigma = 0.042). The superhelicity-dependent
S1 nuclease
cleavage sites were mapped only within the RY repeat and no nicking was observed outside of the repeat. In view of the fact that DNA topoisomerase II is highly reactive towards RY repeat which can adopt unusual DNA conformation, we have investigated the effects of the superhelicity-dependent conformational transition of the 52 bp RY repeat on
topoisomerase
II cleavages. Cleavage reactions were performed on the pRYG plasmid with varying levels of negative superhelical densities ranging from 0 to -0.074. Under the low torsional stress,
topoisomerase
II cleavage activity at the RY repeat gradually increased with the increasing levels of negative superhelical densities. However, over a threshold level of negative supercoiling for cruciform conformation, the intensities of enzyme cleavage sites at the RY repeat were essentially identical. These results suggest that
topoisomerase
II can bind and cleave the cruciform structure in a dynamic process identical to duplex B-DNA.
...
PMID:Topoisomerase II-mediated DNA cleavage on the cruciform structure formed within the 5'upstream region of the human beta-globin gene. 974 29
Phenomena involving the disassembly of chromosomes to approximately 50 kbp double-stranded fragments upon protein denaturing treatments of normal and apoptotic mammalian nuclei as well as yeast protoplasts may be an indication of special, hypersensitive regions positioned regularly at loop-size intervals in the eukaryotic chromatin. Here we show evidence in yeast cell systems that loop-size fragmentation can occur in any phase of the cell cycle and that the plating efficiency of these cells is approximately 100%. The possibility of sequence specificity was investigated within the breakpoint cluster region (bcr) of the human MLL gene, frequently rearranged in certain leukemias. Our data suggest that DNA isolated from yeast cultures or mammalian cell lines carry nicks or secondary structures predisposing DNA for a specific nicking activity, at non-random positions. Furthermore, exposure of MLL bcr-carrying plasmid DNA to
S1 nuclease
or nuclear extracts or purified
topoisomerase
II elicited cleavages at the nucleotide positions of nick formation on human genomic DNA. These data support the possibility that certain sequence elements are preferentially involved in the cleavage processes responsible for the en masse disassembly of chromatin to loop-size fragments upon isolation of DNA from live eukaryotic cells.
...
PMID:Nick-forming sequences may be involved in the organization of eukaryotic chromatin into approximately 50 kbp loops. 1619 88
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