Abstract
The human XPG endonuclease cuts on the 3' side of a DNA lesion during nucleotide excision repair. Mutations in XPG can lead to the disorders xeroderma pigmentosum (XP) and Cockayne syndrome. XPG shares sequence similarities in two regions with a family of structure-specific nucleases and exonucleases. To begin defining its catalytic mechanism, we changed highly conserved residues and determined the effects on the endonuclease activity of isolated XPG, its function in open complex formation and dual incision reconstituted with purified proteins, and its ability to restore cellular resistance to UV light. The substitution A792V present in two XP complementation group G (XP-G) individuals reduced but did not abolish endonuclease activity, explaining their mild clinical phenotype. Isolated XPG proteins with Asp-77 or Glu-791 substitutions did not cleave DNA. In the reconstituted repair system, alanine substitutions at these positions permitted open complex formation but were inactive for 3' cleavage, whereas D77E and E791D proteins retained considerable activity. The function of each mutant protein in the reconstituted system was mirrored by its ability to restore UV resistance to XP-G cell lines. Hydrodynamic measurements indicated that XPG exists as a monomer in high salt conditions, but immunoprecipitation of intact and truncated XPG proteins showed that XPG polypeptides can interact with each other, suggesting dimerization as an element of XPG function. The mutation results define critical residues in the catalytic center of XPG and strongly suggest that key features of the strand cleavage mechanism and active site structure are shared by members of the nuclease family.
Highlights
The XPG protein is a DNA endonuclease with remarkable structure-specific properties, cleaving near the junctions between duplex and single-stranded DNA with a defined polarity
Conserved Catalytic Residues in the XPG Family—The results presented here provide insight into human XPG function
The metal coordinating side chains in the active sites are all clustered at the top of the -sheets and are highly conserved both in sequence (Fig. 1) and in position
Summary
5Ј-CCCATGGAAGCAGCCGCGCAGTGCGCC-3Ј 5Ј-CCCATGGAAGCAGATGCGCAGTGCGCC-3Ј 5Ј-GCAGAGGCGCAGGCCGCCATCCTGGAC-3Ј 5Ј-GCAGAGGCGCAGAGCGCCATCCTGGAC-3Ј a The altered nucleotides are underlined. ERCC1-XPF (and its S. cerevisiae counterpart Rad10-Rad1) cuts on the strand that leads off from the junction in the 5Ј 3 3Ј direction [21], whereas XPG (and its S. cerevisiae homolog Rad2) makes endonucleolytic incision close to the 3Ј junction, where single-stranded DNA meets duplex DNA [6, 7]. A combination of biochemical and cellular tests was used to measure the function of the mutated proteins. Their intrinsic endonuclease activity was measured on a model bubble substrate, and their repair function was assayed by their ability to form an open preincision complex and to complete dual incision of DNA containing a single cisplatin adduct in the presence of purified NER components. We discuss the implications of the results for the XPG incision mechanism and XP-G clinical phenotypes
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