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INITIATION OF BASE EXCISION REPAIR: Glycosylase Mechanisms and Structures (1999)

McCullough, Amanda K. ; Dodson, M. L. ; Lloyd, R. Stephen

Palo Alto, Calif. : Annual Reviews

Annual Review of Biochemistry 68 (1999), S. 255-285

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ISSN: 0066-4154

Source: Annual Reviews Electronic Back Volume Collection 1932-2001ff

Topics: Chemistry and Pharmacology , Biology

Notes: Abstract The base excision repair pathway is an organism's primary defense against mutations induced by oxidative, alkylating, and other DNA-damaging agents. This pathway is initiated by DNA glycosylases that excise the damaged base by cleavage of the glycosidic bond between the base and the DNA sugar-phosphate backbone. A subset of glycosylases has an associated apurinic/apyrimidinic (AP) lyase activity that further processes the AP site to generate cleavage of the DNA phosphate backbone. Chemical mechanisms that are supported by biochemical and structural data have been proposed for several glycosylases and glycosylase/AP lyases. This review focuses on the chemical mechanisms of catalysis in the context of recent structural information, with emphasis on the catalytic residues and the active site conformations of several cocrystal structures of glycosylases with their substrate DNAs. Common structural motifs for DNA binding and damage specificity as well as conservation of acidic residues and amino groups for catalysis are discussed.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1146/annurev.biochem.68.1.255

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Intron Conservation in a UV-Specific DNA Repair Gene Encoded by Chlorella Viruses (2000)

Sun, Liangwu ; Li, Yu ; McCullough, Amanda K. ; [et al.]

Springer

Journal of molecular evolution 50 (2000), S. 82-92

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ISSN: 1432-1432

Keywords: Key words: Pyrimidine dimer-specific glycosylase — DNA repair — Intron — dsDNA virus — Chlorella viruses — Phycodnaviridae

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract. Large dsDNA-containing chlorella viruses encode a pyrimidine dimer-specific glycosylase (PDG) that initiates repair of UV-induced pyrimidine dimers. The PDG enzyme is a homologue of the bacteriophage T4-encoded endonuclease V. The pdg gene was cloned and sequenced from 42 chlorella viruses isolated over a 12-year period from diverse geographic regions. Surprisingly, the pdg gene from 15 of these 42 viruses contain a 98-nucleotide intron that is 100% conserved among the viruses and another 4 viruses contain an 81-nucleotide intron, in the same position, that is nearly 100% identical (one virus differed by one base). In contrast, the nucleotides in the pdg coding regions (exons) from the intron-containing viruses are 84 to 100% identical. The introns in the pdg gene have 5′-AG/GTATGT and 3′-TTGCAG/AA splice site sequences which are characteristic of nuclear-located, spliceosomal processed pre-mRNA introns. The 100% identity of the 98-nucleotide intron sequence in the 15 viruses and the near-perfect identity of an 81-nucleotide intron sequence in another 4 viruses imply strong selective pressure to maintain the DNA sequence of the intron when it is in the pdg gene. However, the ability of intron-plus and intron-minus viruses to repair UV-damaged DNA in the dark was nearly identical. These findings contradict the widely accepted dogma that intron sequences are more variable than exon sequences.