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
Query: EC:3.1.30.1 (
S1 nuclease
)
3,660
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Fixed and unfixed human chromosomes, as well as fixed rye chromosomes were treated with
S1 nuclease
, which specifically cleaves single stranded DNA. Subsequent staining with either acridine orange, ethidium
bromide
or Giemsa revealed that, contrary to what has previously been reported, S1 digestion extensively altered chromosomal morphology and staining intensity, although the alteration was more pronounced in fixed as compared to unfixed metaphases. A number of mechanisms, which may account for our findings, have been invoked: a) the presence in metaphase chromatin of B-DNA/Z-DNA transitional junctions, b) the induction, by alcohol: acid fixation procedure, of nicks within regular B-DNA conformation and c) the induction of sites available to S1 by torsional stress due to metaphase high condensation degree.
...
PMID:S1 nuclease removes DNA from eukaryotic metaphase chromosomes: cytological evidence. 299 24
This paper evaluates methods to measure crosslinkage due to psoralen plus light in total DNA and in specific sequences. DNA exposed in cells or in vitro to a bifunctional psoralen and near ultraviolet light accumulates interstrand crosslinks. Crosslinkage is the DNA mass fraction that is attached in both strands to a crosslink. We show here biochemical methods to measure psoralen photocrosslinkage accurately in total DNA. We also describe methods to measure photocrosslinkage indirectly, in specific sequences, by nucleic acid hybridization. We show that a single 4,5',8-trimethylpsoralen (TMP) crosslink causes at least 50 kbp of alkali-denatured DNA contiguous in both strands with it to snap back into the duplex form when the denatured preparation is returned to neutral pH. This process was so efficient that the DNA was not nicked by the single-strand
nuclease S1
at 100-fold excess after snapping back. Uncrosslinked DNA was digested to acid-soluble material by the enzyme. Crosslinkage therefore equals the fraction of S1-resistant nucleotide in this kind of experiment. We alkali-denatured DNA samples crosslinked to varying degrees by varying TMP concentration at constant light exposure. We then measured crosslinkage by ethidium
bromide
(EtBr) fluorometry at pH 11.8; by EtBr fluorometry at neutral pH of S1 digests of the DNA; and by the fraction of radioactivity remaining acid insoluble in S1-digests of DNA labeled uniformly with [3H]deoxythymidine. These assays measure distinct physical properties of crosslinked DNA. Numerical agreement is expected only when all three measurements are accurate. Under optimum conditions, the three methods yielded identical results over the range of measurement. Using alkaline EtBr fluorescence in crude cell lysates, we detected crosslinks at frequencies in the range of 1.6 X 10(-7) per base pair. These levels were compatible with cell survival, attesting to the sensitivity of the measurement system. Crosslinkage affected hybridization as well. One crosslink prevented all alkali-denatured DNA contiguous in both strands with it from hybridizing to complementary DNA either on solid supports or in solution. Strand-length effects on crosslinkage and on reassociation caused solution hybridization levels to exceed those predicted by simple theory. In a quantitative, dot-blotting assay hybridization was linear up to membrane saturation by denatured, uncrosslinked DNA of any strand length.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Accurate measurement of psoralen-crosslinked DNA: direct biochemical measurements and indirect measurement by hybridization. 314 59
The interaction of ethidium
bromide
(EtBr) with double-stranded (ds), and acridine orange (AO) with single-stranded (ss) fragments of 16S rRNA Escherichia coli in a wide range of ionic strength, at various pH, Zn2+ ion concentrations and partial hydrolysis by
nuclease S1
was investigated. It was shown that about 90% of the RNA molecule is accessible to both dyes, when the ionic strength is near of 0.01 (pH 7). Approximately half of the RNA becomes inaccessible to dyes, when the ionic strength was increased up to 0.08-0.24 (pH 4.7-7), independent on the presence of Zn2+ ions (10(-3) M). About a half of the ds-, and a quarter of the ss-segments of the RNA, deduced from the secondary structure model were protected from the interaction with EtBr and AO. The hydrolysis of about a half of ss-segments upon addition of the Zn2+ (10(-3) M) ions did not affect the RNA tertiary structure. The experimental data obtained confirm the idea of the existence of some "nucleus" (or "nuclei") within the 16S rRNA molecule. The "nucleus" seems to be inaccessible to the dyes and is very stable to heat denaturation. It was supposed that this structure is organized by means of interaction of some of the parallelly oriented ds-segments, as it was suggested earlier for the phage MS2 RNA structure.
...
PMID:[Comparison of the conformation of RNA from phage MS2 and 16S rRNA. Interaction with dyes specific for the secondary structure of native RNA and RNA subjected to hydrolysis by nuclease S1]. 329 45
<< Previous
1
2
