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:6.5.1.2 (
DNA ligase
)
2,749
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The capacity of eukaryotic cells to modulate the activities of DNA repair enzymes during cell proliferation was examined. Using regenerating rat liver as a model system, the specific activities of the DNA repair enzymes uracil DNA glycosylase and
3-methyladenine DNA glycosylase
were determined at specific intervals after partial hepatectomy. The induction of DNA replication and the stimulation of DNA polymerase were also measured in order to relate changes in the potential for DNA repair to those observed for DNA replication. As measured in nuclear extracts, the specific activities of both the uracil DNA glycosylase and the
3-methyladenine DNA glycosylase
were increased in regenerating rat liver reaching maximal levels 18--24 h after partial hepatectomy. The specific activity of each
DNA repair enzyme
returned to basal levels by 48 h after the hepatectomy. No increase in either enzyme activity was observed in sham operated controls. The products of the reactions were identified as 3-methyladenine or as uracil by high pressure liquid chromatography or by gel filtration on Sephadex G-10. The 2--3 fold increases in the specific activity observed for each nuclear
DNA repair enzyme
was comparable to the 2.7 fold increase observed for DNA polymerase activity. The stimulation of DNA repair enzymes in regenerating rat liver is a further suggestion that eukaryotic cells actively regulate excision repair pathways in the defined pattern of gene expression observed during the eukaryotic cell cycle.
...
PMID:Induction of the DNA repair enzymes uracil DNA glycosylase and 3-methyladenine DNA glycosylase in regenerating rat liver. 727 38
Mutagenesis of protein-encoding sequences occurs ubiquitously; it enables evolution, accumulates during aging, and is associated with disease. Many biotechnological methods exploit random mutations to evolve novel proteins. To quantitate protein tolerance to random change, it is vital to understand the probability that a random amino acid replacement will lead to a protein's functional inactivation. We define this probability as the "x factor." Here, we develop a broadly applicable approach to calculate x factors and demonstrate this method using the human
DNA repair enzyme
3-methyladenine DNA glycosylase
(AAG). Three gene-wide mutagenesis libraries were created, each with 10(5) diversity and averaging 2.2, 4.6, and 6.2 random amino acid changes per mutant. After determining the percentage of functional mutants in each library using high-stringency selection (>19,000-fold), the x factor was found to be 34% +/- 6%. Remarkably, reanalysis of data from studies of diverse proteins reveals similar inactivation probabilities. To delineate the nature of tolerated amino acid substitutions, we sequenced 244 surviving AAG mutants. The 920 tolerated substitutions were characterized by substitutability index and mapped onto the AAG primary, secondary, and known tertiary structures. Evolutionarily conserved residues show low substitutability indices. In AAG, beta strands are on average less substitutable than alpha helices; and surface loops that are not involved in DNA binding are the most substitutable. Our results are relevant to such diverse topics as applied molecular evolution, the rate of introduction of deleterious alleles into genomes in evolutionary history, and organisms' tolerance of mutational burden.
...
PMID:Protein tolerance to random amino acid change. 1519 60
