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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)
The site-specific restriction endonucleases isolated from Hemophilus influenzae strains Rc (HincII) and Rd (HindII + III), and Hemophilus parainfluenzae (HpaI) were used to digest bacteriophage lambda DNA into 34, 40, and 15 specific fragments, respectively. The sites cleaved by each of these enzymes were localized on the lambda physical map and the fragments resulting from these cleavages were electrophoretically identified on gels by (1) analysis of the digestion profiles of deletion and transducing derivatives of lambda; and (2) digesting individual fragments produced by one restriction
endonuclease
with another restriction
endonuclease
. This paper presents the HindII, HindIII, and HpaI restriction fragment maps for the entire lambda genome, and the data used to derive these maps for the region of the lambda genome between the attachment site (at 57.3% lambda) and the right vegetative end (100% lambda). The data for mapping the left arm of lambda may be found in the accompanying paper (
Robinson
and Landy, 1977).
...
PMID:HindII, HindIII, and HpaI restriction fragment maps of bacteriophage lambda DNA. 59 4
The sites on the left arm of bacteriophage lambda DNA cleaved by the restriction endonucleases isolated from Hemophilus influenzae strain Rc (HincII) and Rd (HindII + III), and Hemophilus parainfluenzae (HpaI) were localized on the lambda physical map, and the fragments resulting from these cleavages were identified by gel electrophoresis. The restriction sites within the b2 region of lambda were mapped by analysis of the digestion profiles of deletion and substitution derivatives of lambda, as well as by digesting individual fragments produced by one restriction
endonuclease
with another restriction
endonuclease
. The restriction sites of the lambda genome between the left vegetative end and the b2 region were mapped entirely by succesive digestion experiments. The restriction fragment map for the right arm of lambda may be found in the accompanying paper (
Robinson
and Landy, 1977).
...
PMID:HindII, HindIII, and HpaI restriction fragment maps of the left arm of bacteriophage lambda DNA. 59 5
The complexity and structural organization of defective-interfering (DI) particle DNA of equine herpesvirus type 1 (EHV-1) have been elucidated by using restriction enzyme and Southern blot hybridization analyses. DI particles were generated by serial high-multiplicity passage of EHV-1 in L-M cells, and total viral DNA was extracted from virus purified from supernatants of these serial passages. EHV-1 DI particle DNA was quantitatively separated from standard (STD) DNA by several cycles of CsCl isopycnic banding in a vertical rotor. Restriction
endonuclease
digestion profiles of pure DI DNA were completely different from the mapped patterns observed for EHV-1 STD DNA. Digestion of pure defective DNA with restriction enzymes (Bg/II, EcoRI, and XbaI), for which there are few or no cleavage sites within the S (short) region of the EHV-1 STD genome, yielded high-molecular-weight supermolar DNA bands, suggesting that a large subgenomic repeat unit was present in defective DNA. DNA blot hybridization analysis with the Bg/II supermolar fragment of defective DNA, intact DI particle genomic DNA, and EHV-1 STD DNA restriction enzyme fragments as 32P-labeled probes indicated that the EHV-1 DI particle genome originates predominately from the STD DNA S region (0.77 to 1.00 map units) and to a lesser extent from the left terminus of the unique long (UL) region (0.00 to 0.05 map units). None of the EHV-1 DNA sequences associated to date with EHV-1 oncogenesis (0.32 to 0.38 map units; O'Callaghan et al. in B. Roizman [ed.], Herpesviruses, in press;
Robinson
et al., Cell 32:204-219, 1983, and Proc. Natl. Acad. Sci., U.S.A., 78:6684-6688, 1981) were detected in the DI particle DNA. The importance of these data with regard to DNA replication of DI particles and the role of DI particles in one model system of EHV-1 oncogenic transformation are discussed.
...
PMID:Structure and genetic complexity of the genomes of herpesvirus defective-interfering particles associated with oncogenic transformation and persistent infection. 632 84
Restriction
endonuclease
mapping studies were performed to determine the molecular structure of the genome of equine herpesvirus type 3 (EHV-3). Purified EHV-3 DNA, either unlabeled or 32P-labeled, was analyzed using the restriction enzymes BamHI, BclI, BglII, EcoRI, and HindIII. The findings that four 0.5 M (molar) fragments were present, that two of these were terminal fragments, and that all 0.5 M fragments contained homologous DNA sequences as judged by DNA hybridization analyses indicated that DNA sequences located at one terminus are repeated within the molecule and that two populations of molecules exist with regard to the arrangement of this pair of shared sequences. Mapping of BamHI, BclI, BglII, EcoRI, and HindIII fragments by double digestion of intact EHV-3 DNA, reciprocal digestion of isolated restriction enzyme fragments, and blot hybridization experiments revealed that the EHV-3 genome is a linear, double-stranded DNA molecule with a molecular size of 96.2 +/- 0.48 MDa and is comprised of two covalently linked segments, designated L (long) and S (short). The S region is approximately 22.9 MDa in size and consists of a unique segment (Us) of approximately 5.8 MDa bracketed by 8.5 MDa inverted repeat sequences that allow the S region to invert relative to the fixed L region which is approximately 73.3 MDa in size and consists only of unique sequences. Thus, these data confirm that EHV-3 DNA exists in two isomeric forms and has a molecular structure similar to that of the genomes of EHV-1 (B. E. Henry, S. A.
Robinson
, S. A. Dauenhauer, S. S. Atherton, G. S. Hayward, and D. J. O'Callaghan, Virology 115, 97-114, 1981; D. J. O'Callaghan, G. A. Gentry, and C. C. Randall, "The Herpesvirus," Vol. 2, pp. 215-318, Plenum, New York, 1983; D. J. O'Callaghan, B. E. Henry, J. H. Wharton, S. A. Dauenhauer, R. B. Vance, J. Staczek, and R. A.
Robinson
, "Developments in Molecular Virology," Vol. 1, pp. 387-418, Nijhoff, The Hague, 1981; W. T. Ruyechan, S. A. Dauenhauer, and D. J. O'Callaghan, J. Virol., 42, 297-300, 1982), pseudorabies virus (W. Stevely, J. Virol., 22, 232-234, 1977; T. Ben-Porat, F. J. Rixon, and M. L. Blankenship, Virology, 95, 285-294, 1979), varicella-zoster virus (A. M. Dumas, J. L. Geelen, M. W. Weststrate, P. Wertheim, and J. Van Der Noordaa, J. Virol., 39, 390-400, 1981; S. E. Straus, H. S. Aulakh, W. T. Ruyechan, J. Hay, T. A. Casey, G. F. Vande Woude, J. Owens, and H. A. Smith, J. Virol., 40, 516-525, 1981.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Structure of the genome of equine herpesvirus type 3. 632 18
C2-Methylhypoxanthine (m2I) is a synthetic analog of guanine with the N2-amino group replaced by a methyl group. We have studied the structural consequence of the m2I incorporation in DNA by a combination of X-ray crystallographic, NMR, and enzymatic analyses. The crystal structure of d(CGC[m2I]AATTCGCG) has been solved and refined to an R factor of 20.7% at 2.25-A resolution. In the DNA duplex, the two independent m2I:C base pairs maintain the Watson-Crick scheme. While the C2-methyl group of m2I is in van der Waals contact with the O2 of the base-paired cytosine, it only causes the base pair to have slightly higher propeller twist and buckle angles. Its solution structure was analyzed by the NMR refinement procedure SPEDREF [
Robinson
, H., & Wang, A. H.-J. (1992) Biochemistry 31, 3524-3533] using 2D nuclear Overhauser effect data. Two starting models, a relaxed fiber model and an X-ray model, were subjected to the NOE-constrained refinement using 1518 NOE cross-peak integrals to arrive at the final models with (NOE) R factors of 13.8% and 14.3%, respectively. The RMSD between the two refined models (all atoms included) is 1.23 A, which presently seems to be near the limit of convergence of NOE-based refinement. The local structures of the two models are in better agreement as measured by the RMSD of the dinucleotide steps, falling in the range 0.54-0.98 A. Both refined solution structures confirm that the m2I dodecamer structure is of the B-DNA type with a narrow minor groove at the AT region, as observed in the crystal. However, significant differences exist between the crystal and solution structures in parameters such as pseudorotation angles, propeller twist angles, etc. The solution structure tends to have a more uniform backbone conformation, an observation consistent with that concluded from the laser Raman study of d(CGCAAATTTGCG) [Benevides, J. M., Wang, A. H.-J., van der Marel, G. A., van Boom, J. H., & Thomas, G. J., J. (1988) Biochemistry 27, 931-938]. Three related dodecamers, d(CGCGAATTCGCG), d(CGC[m2I]AATTCGCG), and d(CGC[e6G]AATTCGCG), were tested as substrates for the restriction
endonuclease
EcoRI. The m2I dodecamer was active, but the e6G dodecamer was not. Our results illustrate the complementarity in terms of the structural information provided by the two methods, X-ray diffraction and NMR.
...
PMID:Structural effects of the C2-methylhypoxanthine:cytosine base pair in B-DNA: A combined NMR and X-ray diffraction study of d(CGC[m2I]AATTCGCG). 835 9
In this report, the effects of osmotic pressure on BamHI cognate binding and catalysis were investigated and compared with a previous study on EcoRI (
Robinson
, C. R. and Sligar, S. G. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 2186-2191). Our observation of the dependence of binding and catalytic parameters on osmotic pressure has allowed for the comparison of hydration changes associated with site-specific DNA recognition for both endonucleases. Over a large range of osmotic pressures (pi), the dependence of BamHI on osmotic stress during cognate binding and catalysis was very different from that of the related
endonuclease
EcoRI. The binding of EcoRI to cognate DNA was dominated by a dehydration of the
endonuclease
-DNA complex, whereas binding by BamHI to its cognate sequence was accompanied by a solvent release corresponding to some 125 fewer waters. Catalytic analysis at elevated osmotic pressures indicated that both endonucleases had undergone a net hydration of the complex with BamHI displaying a much greater dependence on osmotic stress than EcoRI. Although the enzymes shared core structural motifs, comparisons of high resolution x-ray structures revealed many different secondary structural features of the complexed endonucleases. The large difference in hydration changes by both BamHI and EcoRI could be attributed to these dissimilar secondary structural features, as well as the functional differences of the two endonucleases during site-specific DNA recognition.
...
PMID:Macromolecular hydration changes associated with BamHI binding and catalysis. 1087
