Cortical morphology in children and adolescents with different apolipoprotein E gene polymorphisms: an observational study.

BACKGROUND: Alleles of the apolipoprotein E (APOE) gene modulate risk for Alzheimer's disease, with carriers of the epsilon4 allele being at increased risk and carriers of the epsilon2 allele possibly at decreased risk compared with non-carriers. Our aim was to determine whether possession of an epsilon4 allele would confer children with a neural substrate that might render them at risk for Alzheimer's disease, and whether carriers of the epsilon2 allele might have a so-called protective cortical morphology. METHODS: 239 healthy children and adolescents were genotyped and had repeated neuroanatomic MRI (total 530 scans). Mixed model regression was used to determine whether the developmental trajectory of the cortex differed by genotype. FINDINGS: Cortical thickness of the left entorhinal region was significantly thinner in epsilon4 carriers than it was in non-epsilon4 carriers (3.79 [SE 0.06] mm, range 1.54-5.24 vs 3.94 [0.03] mm, 2.37-6.11; p=0.03). There was a significant stepwise increase in cortical thickness in the left entorhinal regions, with epsilon4 carriers having the thinnest cortex and epsilon2 carriers the thickest, with epsilon3 homozygotes occupying an intermediate position (left beta 0.11 [SE 0.05], p=0.02). Neuroanatomic effects seemed fixed and non-progressive, with no evidence of accelerated cortical loss in young healthy epsilon4 carriers. INTERPRETATION: Alleles of the apolipoprotein E gene have distinct neuroanatomic signatures, identifiable in childhood. The thinner entorhinal cortex in individuals with the epsilon4 allele might contribute to risk of Alzheimer's disease.

Effects of hormones and sex chromosomes on stress-influenced regions of the developing pediatric brain.

Recently discovered sexual dimorphism within developing brain structures such as the amygdala and hippocampus suggests that biological factors may account for many of the sex differences in stress reactivity. In this study, we have relied on studies of naturally occurring anomalous processes, such as congenital adrenal hyperplasia (CAH) and Klinefelter's syndrome (XXY), to observe the effects of hormones and sex chromosomes on brain structures thought to influence an individual's vulnerability to stress. Brain magnetic resonance imaging (MRI) scans were obtained both from 16 boys with classic CAH and 34 age- and sex-matched controls and from 20 XXY children and 40 age-matched controls. Smaller amygdala volumes were observed in boys with CAH than in matched controls, and in XXY patients than in matched controls. XXY patients were also found to have smaller hippocampus volumes when compared with matched controls. Acknowledging that hormone and sex chromosome effects upon the developing human brain are widespread and complex, it is difficult to conclude, with any certainty, the etiology of the differences found in this study. Future studies that examine longitudinal data and/or other diagnostic groups, however, may help to better elucidate specific hormone and sex chromosome effects upon stress-related structures in the brain.