Expression of Caytaxin protein in Cayman Ataxia mouse models correlates with phenotype severity.

Caytaxin is a highly-conserved protein, which is encoded by the Atcay/ATCAY gene. Mutations in Atcay/ATCAY have been identified as causative of cerebellar disorders such as the rare hereditary disease Cayman ataxia in humans, generalized dystonia in the dystonic (dt) rat, and marked motor defects in three ataxic mouse lines. While several lines of evidence suggest that Caytaxin plays a critical role in maintaining nervous system processes, the physiological function of Caytaxin has not been fully characterized. In the study presented here, we generated novel specific monoclonal antibodies against full-length Caytaxin to examine endogenous Caytaxin expression in wild type and Atcay mutant mouse lines. Caytaxin protein is absent from brain tissues in the two severely ataxic Atcay(jit) (jittery) and Atcay(swd) (sidewinder) mutant lines, and markedly decreased in the mildly ataxic/dystonic Atcay(ji-hes) (hesitant) line, indicating a correlation between Caytaxin expression and disease severity. As the expression of wild type human Caytaxin in mutant sidewinder and jittery mice rescues the ataxic phenotype, Caytaxin's physiological function appears to be conserved between the human and mouse orthologs. Across multiple species and in several neuronal cell lines Caytaxin is expressed as several protein isoforms, the two largest of which are caused by the usage of conserved methionine translation start sites. The work described in this manuscript presents an initial characterization of the Caytaxin protein and its expression in wild type and several mutant mouse models. Utilizing these animal models of human Cayman Ataxia will now allow an in-depth analysis to elucidate Caytaxin's role in maintaining normal neuronal function.

Phenylalanine hydroxylase gene mutations in phenylketonuria patients from India: identification of novel mutations that affect PAH RNA.

Analysis of seven Indian phenylketonuria families has revealed four novel mutations in the phenylalanine hydroxylase gene; two affected consensus splice sequence and the 3' UTR, respectively, while the other two were single base insertion and deletion mutations, respectively. A novel 3' splice site mutation c.168-2A>G resulted in the activation of a cryptic 3' splice site that generated a premature termination codon leading to very low levels of the mutant transcript, probably due to activation of the nonsense-mediated decay (NMD) pathway. This is probably the first report of PKU caused by the activation of NMD.

Genetic and phenotypic analysis of the mouse mutant mh2J, an Ap3d allele caused by IAP element insertion.

Mocha (mh), a mouse model for Hermansky-Pudlak syndrome (HPS), is characterized by platelet storage pool deficiency, pigment dilution, and deafness as well as neurological abnormalities. The trans-Golgi/endosome adaptor-related complex AP-3 is missing in mh mice owing to a deletion in the gene encoding the delta subunit. Mice mutant for a second allele, mh(2J), are as hyperactive as mh, and display both spike wave absence and generalized tonic clonic seizures, but have less coat color dilution, no hearing loss, and no hypersynchronized EEG. Here we show that the mh(2J) mutation is due to an IAP element insertion in the Ap3d gene leading to a C-terminally truncated protein. Despite correct assembly of the AP-3 complex and localization to the trans-Golgi network and endosomes, AP-3 function in neurons remains impaired. While mh mice show a severe reduction of vesicular zinc (TIMM staining) owing to mislocalization and degradation of the Zinc transporter ZnT-3, the TIMM and ZnT-3 staining patterns in mh(2J) varies, with normal expression in hippocampal mossy fibers, but abnormal patterns in neocortex. These results indicate that the N-terminal portion of the delta subunit is sufficient for AP-3 complex assembly and subcellular localization to the TGN/endosomes, while subsequent function is regulated in part by cell-specific interactions with the C-terminal portion.