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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 frequency of occurrence of particular repetitive sequence families has been estimated in the DNA of the three sea urchin species
Strongylocentrotus purpuratus
. Strongylocentrotus franciscanus and Lytechinus pictus using individual cloned S. purpuratus repetitive sequence elements. Cloned repetitive sequence elements as described by Scheller et al. (1977a) were prepared by reassociation of S. purpuratus DNA fragments to repetitive Cot, digestion with single-strand-specific
nuclease S1
and ligation of synthetic restriction sites to their ends. The sequences were cloned by insertion at the Eco RI site of plasmid RSF2124, labeled, strand-separated and reassociated with 800--900 nucleotide long unlabeled DNA. Both kinetic (genomic DNA excess) and saturation (cloned DNA excess) estimates of frequencies were made. For nine cloned fragments, the ratio of the repetition frequency in S. purpuratus DNA to that in S. franciscanus DNA ranges from about 20 to about 1. In the four cases examined, only a few copies were detected in the DNA of L. pictus. Estimates have also been made of frequency changes in many repetitive families by measuring the reassociation of labeled repetitive DNA fractions of each species with total DNA from other species. In each reciprocal comparison, the labeled repetitive sequences reassociate more slowly with DNA of other species than with DNA of the species from which they were prepared. Thus it appears that the dominant repetitive sequence families in the DNA of each species are present at lower frequencies in the DNA of closely related species. Measurements of thermal stability have been made of S. purpuratus cloned repetitive sequences reassociated with S. franciscanus DNA or S. purpuratus DNA. Most families have changed both in frequency and sequence, although some have changed little in sequence but show great changes in frequency.
...
PMID:Evolutionary change in the repetition frequency of sea urchin DNA sequences. 71 56
The single-copy DNA sequence difference between individual sea urchins of the species
Strongylocentrotus purpuratus
has been estimated by comparing the thermal stability of reassociated DNA duplexes from two individuals with that for DNA from an individual. Thermal stability was measured by hydroxyapatite thermal chromatography,
S1 nuclease
resistance after heating in a solvent which neutralizes the effect of DNA base composition, and spectrophotometric melting. One pair of individuals appear to differ from each other in about 4% of the nucleotide pairs of their single-copy DNA sequence. The differences in DNA sequence among individuals in local populations are not distinguishably smaller than those among populations as far apart as 2000 kilometers along the Pacific coast of North America.
...
PMID:The single-copy DNA sequence polymorphism of the sea urchin Strongylocentrotus purpuratus. 72 97
The sequence organization of the DNA of the mollusc Aplysia californica has been examined by a combination of techniques. Close-spaced interspersion of repetitive and single copy sequences occurs throughout the majority of the genome. Detailed examination of the DNA of this protostome reveals great similarities to the pattern observed in the two deuterostome organisms previously examined in detail in this laboratory, Xenopus laevis and
Strongylocentrotus purpuratus
. Labeled and unlabeled Aplysia DNA were prepared from developing embryos and sheared to a fragment length of 400 nucleotides. The kinetics of reassociation were studied by means of hydroxyapatite chromatography, single-strand-specific
S1 nuclease
, and optical methods of assay. Aplysia DNA of this fragment length contains at least five resolvable kinetic fractions. One classification of these fractions, listed with their reassociation rate constants (l M-1 sec-1) is: single copy (0.00057), slow (0.047), fast (2.58), very fast (4000), and foldback (greater than 10(5)). Sequence arrangement was deduced from: the kinetics of reassociation of DNA fragments of length 400 or 2000 nucleotides; the hyperchromicity of reassociated fragments containing duplex regions; the size of duplex regions resistant to
S1 nuclease
; and the reassociation of labeled fragments of various lengths with short driver fragments. More than 80% of the single copy DNA sequences are interspersed with repetitive sequences. The maximum spacing of the repeats is about 2000 nucleotides, and the average less than 1000. The very fast fraction does not show interspersion with single copy sequences or with other kinetic fractions. The foldback fraction sequences are fairly widely interspersed. The slow fraction sequences are interspersed with the fast fraction, and possibly also with the single copy DNA. The fast fraction is the dominant interspersed repetitive fraction. Its sequences are adjacent to the great majority of the single copy sequences and have an average length of about 300 nucleotides.
...
PMID:DNA sequence organization in the mollusc Aplysia californica. 116 33
A Urechis caupo histone gene tandem repeat has been isolated from a 5.0-kilobase EcoRI genomic library in lambda gtWES.lambda B. Genomic reconstruction experiments indicate that the cloned sequence is repeated approximately 100 times per haploid genome. Unique restriction fragments from the cloned sequence hybridize with individual core histone genes from a histone gene tandem repeat of the sea urchin,
Strongylocentrotus purpuratus
. No hybridization is detected when restriction digests are probed with a sea urchin H1 histone gene. Hybrid selection and in vitro translation of embryo mRNAs demonstrate that the clone contains sequences complementary to all four core histones; however, no H1 histone is detected among the translation products. Based on a restriction site map of the clone and the subcloned sequences which hybridize to the histone mRNAs, the order of the core histone genes in the clone is shown to be H3 H2A H2B H4.
S1 nuclease
hybrid protection mapping is used to locate the coding regions and to determine the transcript lengths of the core histone mRNAs. The transcript lengths of H2A, H2B, H3, and H4 mRNAs are approximately 464, 438, 494, and 397 bases, respectively. The
S1 nuclease
mapping also demonstrates that H2A and H4 are transcribed from one DNA strand while H2B and H3 are transcribed from the other strand. In the tandem repeat, the genes are organized so that transcription of the H2A-H2B and H3-H4 gene pairs is divergent.
...
PMID:Cloning and characterization of a core histone gene tandem repeat in Urechis caupo. 284 32
New methods have been applied to the determination of single copy DNA sequence differences between the sea urchin species
Strongylocentrotus purpuratus
, S. franciscanus, S. drobachiensis, and Lytechinus pictus. The thermal stability of interspecies DNA duplexes was measured in a solvent (2.4 M tetraethylammonium chloride) that suppresses the effect of base composition on melting temperature. The lengths of duplexes were measured after digestion with
S1 nuclease
and correction made for the effect of length on thermal stability. The degree of base substitution that has occurred in the single copy DNA during sea urchin evolution is significantly larger than indicated by earlier measurements. We estimate that 19% of the nucleotides of the single copy DNA are different in the genomes of the two sea urchin congeners, S. purpuratus, and S. franciscanus, which apparently diverged only 15 to 20 million years ago.
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PMID:Evolution of sea urchin non-repetitive DNA. 746 91
Long-term labeled sea urchin embryo (
Strongylocentrotus purpuratus
) DNAs were examined for size of recovered pieces, single-strandedness, and length of continuous double-stranded regions. Sizing on neutral sucrose gradients indicates that morula stage DNA sediments predominantly at 31 S, blastula stage DNA at 27 S, and gastrula stage DNA as a broad range of sizes of greater than 29 S. Treatment of [3H]thymidine-labeled DNA with
Aspergillus oryzae S1 nuclease
removes 19% of the 3H from morula stage DNA, 4% of the 3H from blastula stage DNA, and less than 0.1% of the 3H from gastrula stage DNA. Sedimentation of
S1 nuclease
treated [3H]DNAs on alkaline sucrose gradients indicates that in native morula stage DNA there is a nick or gap in one strand approximately every 9700 base pairs, in native blastula stage DNA about every 3300 base pairs, and very few nicks or gaps in native gastrula stage DNA.
...
PMID:Single-stranded regions in DNA isolated from different developmental stages of the sea urchin. 1140 Apr 27
