Unnatural substrates reveal the importance of 8-oxoguanine for in vivo mismatch repair by MutY

Livingston, Alison L.; O’Shea, Valerie L.; Kim, Taewoo; Kool, Eric T.; David, Sheila S.

doi:10.1038/nchembio.2007.40

Cited by 35 publications

(91 citation statements)

References 41 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Q and Z1 are more easily cleaved than would be predicted by the acidities in Figure 14, but both have one feature in common: a nitrogen at N3, which has been proposed to be important for MutY excision. 14,16,25,26 …”

Section: Discussionmentioning

confidence: 99%

Gas-Phase Studies of Substrates for the DNA Mismatch Repair Enzyme MutY

et al. 2012

View full text Add to dashboard Cite

The gas phase thermochemical properties (tautomeric energies, acidity, and proton affinity) have been measured and calculated for adenine and six adenine analogs that were designed to test features of the catalytic mechanism used by the adenine glycosylase MutY. The gas phase intrinsic properties are correlated to possible excision mechanisms and MutY excision rates to gain insight into the the MutY mechanism. The data support a mechanism involving protonation at N7 and hydrogen bonding to N3 of adenine. We also explored the acid-catalyzed (non-enzymatic) depurination of these substrates, which appears to follow a different mechanism than that employed by MutY, which we elucidate using calculations.

show abstract

Section: Discussionmentioning

confidence: 99%

Gas-Phase Studies of Substrates for the DNA Mismatch Repair Enzyme MutY

et al. 2012

View full text Add to dashboard Cite

show abstract

“…3D, not shown in Fig. 5A), but we ruled out this second water as the catalytic nucleophile, both because of its poor positioning but also because E. coli MutY efficiently processes the substrate analog 3-deazaadenine (40). The involvement of Glu-43 in protonating the substrate adenine and Asp-144 in deprotonating the catalytic water had been proposed earlier by Tainer and colleagues on the basis of the structure of a mutant E. coli MutY bound to adenine (corresponding residues Glu-37 and Asp-138) (12).…”

Section: General Features Of the Muty Flrcmentioning

confidence: 99%

Atomic substitution reveals the structural basis for substrate adenine recognition and removal by adenine DNA glycosylase

Lee

Verdine

2009

Proc. Natl. Acad. Sci. U.S.A.

174

View full text Add to dashboard Cite

Adenine DNA glycosylase catalyzes the glycolytic removal of adenine from the promutagenic A⅐oxoG base pair in DNA. The general features of DNA recognition by an adenine DNA glycosylase, Bacillus stearothermophilus MutY, have previously been revealed via the X-ray structure of a catalytically inactive mutant protein bound to an A:oxoG-containing DNA duplex. Although the structure revealed the substrate adenine to be, as expected, extruded from the DNA helix and inserted into an extrahelical active site pocket on the enzyme, the substrate adenine engaged in no direct contacts with active site residues. This feature was paradoxical, because other glycosylases have been observed to engage their substrates primarily through direct contacts. The lack of direct contacts in the case of MutY suggested that either MutY uses a distinctive logic for substrate recognition or that the X-ray structure had captured a noncatalytically competent state in lesion recognition. To gain further insight into this issue, we crystallized wild-type MutY bound to DNA containing a catalytically inactive analog of 2-deoxyadenosine in which a single 2-H atom was replaced by fluorine. The structure of this fluorinated lesionrecognition complex (FLRC) reveals the substrate adenine buried more deeply into the active site pocket than in the prior structure and now engaged in multiple direct hydrogen bonding and hydrophobic interactions. This structure appears to capture the catalytically competent state of adenine DNA glycosylases, and it suggests a catalytic mechanism for this class of enzymes, one in which general acid-catalyzed protonation of the nucleobase promotes glycosidic bond cleavage.base-excision repair ͉ general acid catalysis ͉ substrate recognition T he genotoxic DNA lesion 8-oxoguanine (oxoG) arises chronically in cells through the attack of endogenous electrophilic oxidants on guanine residues (Fig. 1A). Left unrepaired, these oxoG lesions mispair with A during DNA replication, thereby giving rise to G⅐C to T⅐A transversion mutations. Most organisms possess a repair system dedicated to countering the deleterious effects of oxoG. The so-called GO system in eubacteria (1, 2) (Fig. 1B), for example, consists of proteins that directly sanitize the nucleotide precursor pool (MutT) and DNA (MutM or Fpg) of oxoG residues. Proteins that serve functions equivalent to those of MutT and MutM are found in all eukaryotic organisms (3). Failure of this first round of defense results in replicative production of oxoG:A pairs (4), which are particularly troublesome to repair, with neither nucleobase providing faithful information with which to direct correction of the other: oxoG does not belong in DNA at all, and although A is a canonical nucleobase, it is contextually aberrant in the oxoG:A pair because it replaces what should be a C. The multistep repair of oxoG:A is initiated by the highly evolutionarily conserved enzyme adenine DNA glycosylase (MutY in bacteria, hMYH in humans), which catalyzes hydrolysis of the glycosidic linkage between th...

show abstract

“…Location of damaged bases in the genome is likely the rate-limiting step in BER within the cell (6). Current models for genome scanning to detect lesions involve protein sliding along the DNA, squeezing the backbone, slipping bases out to allow for interrogation, or finding transiently opened sites (7,8).…”

mentioning

confidence: 99%

Redox signaling between DNA repair proteins for efficient lesion detection

Boal

Genereux

Sontz

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

120

294

View full text Add to dashboard Cite

Base excision repair (BER) enzymes maintain the integrity of the genome, and in humans, BER mutations are associated with cancer. Given the remarkable sensitivity of DNA-mediated charge transport (CT) to mismatched and damaged base pairs, we have proposed that DNA repair glycosylases (EndoIII and MutY) containing a redox-active [4Fe4S] cluster could use DNA CT in signaling one another to search cooperatively for damage in the genome. Here, we examine this model, where we estimate that electron transfers over a few hundred base pairs are sufficient for rapid interrogation of the full genome. Using atomic force microscopy, we found a redistribution of repair proteins onto DNA strands containing a single base mismatch, consistent with our model for CT scanning. We also demonstrated in Escherichia coli a cooperativity between EndoIII and MutY that is predicted by the CT scanning model. This relationship does not require the enzymatic activity of the glycosylase. Y82A EndoIII, a mutation that renders the protein deficient in DNA-mediated CT, however, inhibits cooperativity between MutY and EndoIII. These results illustrate how repair proteins might efficiently locate DNA lesions and point to a biological role for DNA-mediated CT within the cell.DNA charge transport ͉ DNA damage ͉ iron-sulfur proteins ͉ oxidative stress

show abstract

Unnatural substrates reveal the importance of 8-oxoguanine for in vivo mismatch repair by MutY

Cited by 35 publications

References 41 publications

Gas-Phase Studies of Substrates for the DNA Mismatch Repair Enzyme MutY

Gas-Phase Studies of Substrates for the DNA Mismatch Repair Enzyme MutY

Atomic substitution reveals the structural basis for substrate adenine recognition and removal by adenine DNA glycosylase

Redox signaling between DNA repair proteins for efficient lesion detection

Contact Info

Product

Resources

About