DNA methylation in the pathophysiology of hyperphenylalaninemia in the PAH(enu2) mouse model of phenylketonuria.

Phenylalanine hydroxylase deficient phenylketonuria (PKU) is the paradigm for a treatable inborn error of metabolism where maintaining plasma phenylalanine (Phe) in the therapeutic range relates to improved clinical outcomes. While Phe is the presumed intoxicating analyte causal in neurologic damage, the mechanism(s) of Phe toxicity has remained elusive. Altered DNA methylation is a recognized response associated with exposure to numerous small molecule toxic agents. Paralleling this effect, we hypothesized that chronic Phe over-exposure in the brain would lead to aberrant DNA methylation with secondary influence upon gene regulation that would ultimately contribute to PKU neuropathology. The PAH(enu2) mouse models human PKU with intrinsic hyperphenylalaninemia, abnormal response to Phe challenge, and neurologic deficit. To examine this hypothesis, we assessed DNA methylation patterns in brain tissues using methylated DNA immunoprecipitation and paired end sequencing in adult PAH(enu2) animals maintained under either continuous dietary Phe restriction or chronic hyperphenylalaninemia. Heterozygous PAH(enu2/WT) litter mates served as controls for normal Phe exposure. Extensive repatterning of DNA methylation was observed in brain tissue of hyperphenylalaninemic animals while Phe restricted animals displayed an attenuated pattern of aberrant DNA methylation. Affected gene coding regions displayed aberrant hypermethylation and hypomethylation. Gene body methylation of noncoding RNA genes was observed and among these microRNA genes were prominent. Of particular note, observed only in hyperphenylalaninemic animals, was hypomethylation of miRNA genes within the imprinted Dlk1-Dio3 locus on chromosome 12. Aberrant methylation of microRNA genes influenced their expression which has secondary effects upon the expression of targeted protein coding genes. Differential hypermethylation of gene promoters was exclusive to hyperphenylalaninemic PAH(enu2) animals. Genes with synaptic involvement were targets of promoter hypermethylation that resulted in down-regulation of their expression. Gene dysregulation secondary to abnormal DNA methylation may be contributing to PKU neuropathology. These results suggest drugs that prevent or correct aberrant DNA methylation may offer a novel therapeutic option to management of neurological symptoms in PKU patients.

Methylome repatterning in a mouse model of Maternal PKU Syndrome.

Maternal PKU Syndrome (MPKU) is an embryopathy resulting from in utero phenylalanine (PHE) toxicity secondary to maternal phenylalanine hydroxylase deficient phenylketonuria (PKU). Clinical phenotypes in MPKU include mental retardation, microcephaly, in utero growth restriction, and congenital heart defects. Numerous in utero toxic exposures alter DNA methylation in the fetus. The PAH(enu2) mouse is a model of classical PKU while offspring born of hyperphenylalaninemic dams model MPKU. We investigated offspring of PAH(enu2) dams to determine if altered patterns of DNA methylation occurred in response to in utero PHE exposure. As neurologic deficit is the most prominent MPKU phenotype, methylome patterns were assessed in brain tissue using methylated DNA immunoprecipitation and paired-end sequencing. Brain tissues were assessed in E18.5-19 fetuses of PHE unrestricted PAH(enu2) dams, PHE restricted PAH(enu2) dams, and heterozygous(wt/enu2) control dams. Extensive methylome repatterning was observed in offspring of hyperphenylalaninemic dams while the offspring of PHE restricted dams displayed attenuated methylome repatterning. Methylation within coding regions was dominated by noncoding RNA genes. Differential methylation of promoters targeted protein coding genes. To assess the impact of methylome repatterning on gene expression, brain tissue in experimental and control animals were queried with microarrays assessing expression of microRNAs and protein coding genes. Altered expression of methylome-modified microRNAs and protein coding genes was extensive in offspring of hyperphenylalaninemic dams while minimal changes were observed in offspring of PHE restricted dams. Several genes displaying significantly reduced expression have roles in neurological function or genetic disease with neurological phenotypes. These data indicate in utero PHE toxicity alters DNA methylation in the brain which has downstream impact upon gene expression. Altered gene expression may contribute to pathophysiology of neurologic presentation in MPKU.

The beta(3)-adrenergic receptor TRP64ARG polymorphism and obesity in Alaskan Eskimos.

OBJECTIVE: A polymorphism in the beta 3-adrenergic receptor (beta 3-AR) has been described and consists of an amino acid substitution at position 64 where tryptophan is replaced by arginine (Arg allele). This polymorphism appears to be a modest contributor to obesity and non-insulin dependent diabetes mellitus (NIDDM), and may be dependent on gender, gene dosage, ethnic background and environmental factors. We have investigated whether the Trp64Arg polymorphism of the beta 3-AR was associated with body mass index (BMI), blood pressure or the presence of NIDDM in Alaskan Eskimos. SUBJECTS: Two hundred and fifty four Alaskan Eskimos from two distinct villages (Inupiaq and Yupik). MEASUREMENTS: beta 3-AR genotypes were determined by polymerase chain reaction followed by enzymatic digestion. RESULTS: The frequency of the Arg allele in Alaskan Eskimos was 0.38 and represents the highest Arg allele frequency in any population reported to date. 13.8% of the population were homozygous for the Arg allele, 47.6% heterozygous, and 38.6% lacked the Arg allele. However, the Arg allele was not associated with BMI, blood pressure or the presence of NIDDM in Alaskan Eskimos. CONCLUSION: These data do not support a significant role for the beta-AR Arg allele as a marker for obesity (as measured by BMI) or the presence of NIDDM in Alaskan Eskimos. It is possible that other phenotypic variables, not yet available for analysis in this population, may be associated with the presence of the Arg allele