Structure of Escherichia coli AlkA in Complex with Undamaged DNA

Abstract: Because DNA damage is so rare, DNA glycosylases interact for the most part with undamaged DNA. Whereas the structural basis for recognition of DNA lesions by glycosylases has been studied extensively, less is known about the nature of the interaction between these proteins and undamaged DNA. Here we report the crystal structures of the DNA glycosylase AlkA in complex with undamaged DNA. The structures revealed a recognition mode in which the DNA is nearly straight, with no amino acid side chains inserted into … Show more

“…The two structures reported in this work show that MutY uses the signature HhH DNA-binding motif common to all HhH superfamily proteins to initiate DNA interactions, indicating that this could be a mechanism employed by all proteins of this superfamily. Such nonspecific DNA contacts by the HhH motif has also been observed in the AlkA undamaged DNA structure (23,33), further suggesting the existence of a common lesion-scanning mechanism for the HhH DNA glycosylases. It is therefore reasonable to assume that the structurally related HhH proteins share a similar mode of interaction all along the base extrusion pathway.…”

“…The fact that the HhH motif accounts for most of the phosphate contacts in the N-LSC suggests that MutY uses it to first engage the DNA in a nonspecific fashion without causing DNA bending or base extrusion. Crystal structure of other HhH-GPD superfamily DNA glycosylases such as AlkA (23,24) and hOGG1, 3 in complex with undamaged DNA also showed a similar mode of interaction, where the HhH motif of the glycosylase interacts with the two phosphate groups that are 3Ј to the target base on the lesion-containing strand.…”

“…Because of the lack of a crystal structure of full-length MutY bound to undamaged DNA, we turned to size exclusion chromatography (SEC)-SAXS to generate a conformational model of the LSC. Previous structures of hOGG1 in complex with undamaged DNA (23,24) 3 have shown that cross-linking the protein to the DNA at particular positions facilitates the extrusion of an undamaged base. To ensure that the target A in the T:A base pair remains fully intrahelical during the course of sample preparation and data collection, we turned to in vitro cleavage assays on disulfide cross-linked MutY complexes having either an oxoG or a T that base pairs with the A at the target site (Fig.…”

“…Crystallization was therefore facilitated by introducing an intermolecular disulfide cross-linker at a site that is 4 base pairs away from the target base pair (12,13,22). The relatively low affinity MutY exhibits toward undamaged DNA (20,23), and the anticipated fleeting nature of such binding led us to introduce a similar cross-linking strategy to obtain a stable and homogenous protein-DNA complex suitable for crystallization. We first set out to crystallize the full-length MutY with undamaged DNA using the same cross-linking site that was used in the LRC (13, 23).…”

Structural Basis for the Lesion-scanning Mechanism of the MutY DNA Glycosylase

“…The two structures reported in this work show that MutY uses the signature HhH DNA-binding motif common to all HhH superfamily proteins to initiate DNA interactions, indicating that this could be a mechanism employed by all proteins of this superfamily. Such nonspecific DNA contacts by the HhH motif has also been observed in the AlkA undamaged DNA structure (23,33), further suggesting the existence of a common lesion-scanning mechanism for the HhH DNA glycosylases. It is therefore reasonable to assume that the structurally related HhH proteins share a similar mode of interaction all along the base extrusion pathway.…”

“…The fact that the HhH motif accounts for most of the phosphate contacts in the N-LSC suggests that MutY uses it to first engage the DNA in a nonspecific fashion without causing DNA bending or base extrusion. Crystal structure of other HhH-GPD superfamily DNA glycosylases such as AlkA (23,24) and hOGG1, 3 in complex with undamaged DNA also showed a similar mode of interaction, where the HhH motif of the glycosylase interacts with the two phosphate groups that are 3Ј to the target base on the lesion-containing strand.…”

“…Because of the lack of a crystal structure of full-length MutY bound to undamaged DNA, we turned to size exclusion chromatography (SEC)-SAXS to generate a conformational model of the LSC. Previous structures of hOGG1 in complex with undamaged DNA (23,24) 3 have shown that cross-linking the protein to the DNA at particular positions facilitates the extrusion of an undamaged base. To ensure that the target A in the T:A base pair remains fully intrahelical during the course of sample preparation and data collection, we turned to in vitro cleavage assays on disulfide cross-linked MutY complexes having either an oxoG or a T that base pairs with the A at the target site (Fig.…”

“…Crystallization was therefore facilitated by introducing an intermolecular disulfide cross-linker at a site that is 4 base pairs away from the target base pair (12,13,22). The relatively low affinity MutY exhibits toward undamaged DNA (20,23), and the anticipated fleeting nature of such binding led us to introduce a similar cross-linking strategy to obtain a stable and homogenous protein-DNA complex suitable for crystallization. We first set out to crystallize the full-length MutY with undamaged DNA using the same cross-linking site that was used in the LRC (13, 23).…”

Structural Basis for the Lesion-scanning Mechanism of the MutY DNA Glycosylase

“…We have overcome this problem by developing a straightforward means by which to drastically limit the region a protein can explore while diffusing along DNA, through the introduction of an intermolecular disulfide cross-link (DXL) between protein and DNA. This modification has enabled the crystallization and structure determination of multiple protein-DNA complexes (33)(34)(35)(36)(37)(38)(39)(40)(41)(42)(43)(44).…”

Enforced Presentation of an Extrahelical Guanine to the Lesion Recognition Pocket of Human 8-Oxoguanine Glycosylase, hOGG1

Recent advances in the structural mechanisms of DNA glycosylases