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:3.1.25.1 (
deoxyribonuclease
)
1,471
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A method for isolating extensively purified cell walls from higher plants is described; the preparations contain no detectable chloroplast or nuclear material and the protein content (2-5% of the dry wt. of walls) indicates that there is little contamination with cytoplasm. Incubation of purified cell walls with 0.3n-potassium
hydroxide
for 17hr. at 37 degrees liberates ribonucleotides, which can be purified by adsorption on charcoal and by ion-exchange chromatography. Ribonucleotides are also liberated by incubating the walls with ribonuclease, but not with
deoxyribonuclease
. The RNA content varies from 0.5 to 6mg./g. dry wt. of walls, depending on the nature and age of the tissue, and at 3mg./g. dry wt. of walls accounts for about 7% of the total RNA of the tissue. Less than 0.2% of the RNA of the walls is due to the presence of bacteria in the preparation. The base composition of the cell-wall RNA is identical with that of ribosomal RNA.
...
PMID:The presence of ribonucleic acid in the cell walls of higher plants. 565 50
A strategy was developed to assemble nucleosomes specifically damaged at only one site and one structural orientation. The most prevalent UV photoproduct, a cis-syn cyclobutane thymine dimer (cs CTD), was chemically synthesized and incorporated into a 30 base oligonucleotide harboring the glucocorticoid hormone response element. This oligonucleotide was assembled into a 165 base pair double stranded DNA molecule with nucleosome positioning elements on each side of the cs CTD-containing insert. Proton NMR verified that the synthetic photoproduct is the cis-syn stereoisomer of the CTD. Moreover, two different pyrimidine dimer-specific endonucleases cut approximately 90% of the dsDNA molecules. This cleavage is completely reversed by photoreactivation with E. coli UV photolyase, further demonstrating the correct stereochemistry of the photoproduct. Nucleosomes were reconstituted by histone octamer exchange from chicken erythocyte core particles, and contained a unique translational and rotational setting of the insert on the histone surface.
Hydroxyl radical
footprinting demonstrates that the minor groove at the cs CTD is positioned away from the histone surface about 5 bases from the nucleosome dyad. Competitive gel-shift analysis indicates there is a small increase in histone binding energy required for the damaged fragment (DeltaDeltaG approximately 0.15 kcal/mol), which does not prevent complete nucleosome loading under our conditions. Finally, folding of the synthetic DNA into nucleosomes dramatically inhibits cleavage at the cs CTD by
T4 endonuclease V
and photoreversal by UV photolyase. Thus, specifically damaged nucleosomes can be experimentally designed for in vitro DNA repair studies.
...
PMID:Synthesis and nucleosome structure of DNA containing a UV photoproduct at a specific site. 1041 26
A common feature of DNA repair enzymes is their ability to recognize the damage independently of sequence in which they are found. The presence of a flipped out base inserted into the protein in several DNA-enzyme complexes suggests a contribution to enzyme specificity. Molecular simulations of damaged DNA indicate that the damage produces changes in DNA structure and changes the dynamics of DNA bending. The reduced bending force constant can be used by the enzyme to induce DNA bending and facilitate base flipping. We show that a thymine dimer (TD) containing DNA requires less energy to bend, lowering the barrier for base flipping. On the other hand, bending in DNA with U-G mismatch is affected only by a small amount and flipping is not enhanced significantly.
T4 endonuclease V
(endoV), which recognizes TD, utilizes the reduced barrier for flipping as a specific recognition element. In uracil DNA glycosylase (UDG), which recognizes U-G mismatches, base flipping is not enhanced and recognition is encoded in a highly specific binding pocket for the flipped base. Simulations of UDG and endoV in complex with damaged DNA provide insight into the essential elements of the catalytic mechanism. Calculations of pKas of active site residues in endoV and endoV-DNA complex show that the pKa, of the N-terminus is reduced from 8.01 to 6.52 while that of Glu-23 increases from 1.52 to 7.82. Thus, the key catalytic residues are in their neutral form. The simulations also show that Glu-23 is also H-bonded to O4' of the 5'-TD enhancing the nucleophilic attack on Cl and that Arg-26 enhances the hydrolysis by electrostatic stabilization but does not participate in proton transfer. In the enzyme-substrate complex of UDG, the role of electrostatic stabilization is played by His-268, whose pKa increases to 7.1 from 4.9 in the free enzyme. The pKa of Asp-145, the other important catalytic residue, remains around 4.2 in the free enzyme and in the complex. Thus, it can not act as a proton acceptor. In the complex the 3'-phosphate of uracil is stabilized next to Asp-145 by two bridging water molecules. Such a configuration activates one water molecule to act as a proton acceptor to produce a stabilizing hydronium ion and the other as a proton donor to produce the nucleophilic
hydroxide
. It appears that DNA glycosylases share commonalties in recognition of damage but differ in their catalytic mechanisms.
...
PMID:Specificity of damage recognition and catalysis of DNA repair. 1081 3
