Abstract
Ataxia-oculomotor apraxia syndrome 1 is an early onset cerebellar ataxia that results from loss of function mutations in the APTX gene, encoding Aprataxin, which contains three conserved domains. The forkhead-associated domain of Aprataxin mediates protein-protein interactions with molecules that respond to DNA damage, but the cellular phenotype of the disease does not appear to be consistent with a major loss in DNA damage responses. Disease-associated mutations in Aprataxin target a histidine triad domain that is similar to Hint, a universally conserved AMP-lysine hydrolase, or truncate the protein NH2-terminal to a zinc finger. With novel fluorigenic substrates, we demonstrate that Aprataxin possesses an active-site-dependent AMP-lysine and GMP-lysine hydrolase activity that depends additionally on the zinc finger for protein stability and on the forkhead associated domain for enzymatic activity. Alleles carrying any of eight recessive mutations associated with ataxia and oculomotor apraxia encode proteins with huge losses in protein stability and enzymatic activity, consistent with a null phenotype. The mild presentation allele, APTX-K197Q, associated with ataxia but not oculomotor apraxia, encodes a protein with a mild defect in stability and activity, while enzyme encoded by the atypical presentation allele, APTX-R199H, retained substantial function, consistent with altered and not loss of activity. The data suggest that the essential function of Aprataxin is reversal of nucleotidylylated protein modifications, that all three domains contribute to formation of a stable enzyme, and that the in vitro behavior of cloned APTX alleles can score disease-associated mutations.
Highlights
Ataxia-oculomotor apraxia (AOA)[1] has been characterized as a unique disorder since 1988 (1)
Ataxia-oculomotor apraxia syndrome 1 is an early onset cerebellar ataxia that results from loss of function mutations in the APTX gene, encoding Aprataxin, which contains three conserved domains
Aprataxin Exhibits AMP- and GMP-Lysine Hydrolase Activity—The 342-amino acid APTX cDNA was fused to an aminoterminal His-tag, and the resulting protein was purified to homogeneity by metal chelate affinity chromatography
Summary
Because intact, purified Aprataxin was reported to be devoid of diadenosine polyphosphate hydrolase activity (16), and there is no known connection between diadenosine polyphosphate hydrolysis and DNA repair, this model appears to be unlikely. According to the second model, Aprataxin stabilizes Xrcc[1] by a physical association between phosphorylated Xrcc[1] and the FHA domain of Aprataxin (25). This model appears to be undermined by the lack of x-ray sensitivity of aptx fibroblasts (11) and the fact that disease-associated mutations in APTX do not alter the ability of Aprataxin to associate with Xrcc[1] (25). Biochemical analysis indicated that eight reported disease-associated alleles are null or nearly null for the Hint active site, while a reported mild presentation allele and an atypical presentation allele can be functionally diagnosed by in vitro stability and activity
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