ABSTRACT
PURPOSE: Previous research has indicated that children with autism exhibit accelerated head growth (HG) in infancy, although the timing of acceleration varies between studies. We examined infant HG trajectory as a candidate autism endophenotype by studying sibling pairs. METHODS: We retrospectively obtained serial head orbitofrontal circumference measurements of: a) 48 sibling pairs in which one (n=28) or both (n=20) sibs were affected by an autism spectrum disorder (ASD); and b) 85 control male sibling pairs. RESULTS: Rate of HG of ASD subjects was slightly accelerated compared to controls, but the magnitude of difference was below the limit of reliability of standard measurement methods. Sibling intra class correlation for rate of HG was highly statistically significant; the magnitude was significantly stronger among autism-affected families (ICC=.63) than among controls (ICC=.26), p<.01. CONCLUSION: Infant HG trajectory appears familial-possibly endophenotypic-but was not a reliable marker of autism risk among siblings of ASD probands in this sample.
ABSTRACT
Carbamyl phosphate synthetase I (CPSI) determines the rate-limiting entry of free ammonia into the urea cycle. Disruption of CPSI affects the liver's ability to remove waste nitrogen and produce arginine, citrulline, and urea. Arginine is the necessary precursor for the critical biomolecule, nitric oxide (NO). We have studied the classic model of CPSI deficiency, which results in severe hyperammonemia, and identified a large number of molecular defects. A number of CPSI polymorphisms have been found that appear to result in functional consequences. We have examined the association of these polymorphisms with various environmental stress conditions and found that certain CPSI alleles are associated with clinical outcome. We refer to these associations as environmentally determined genetic expression (EDGE) affects. In addition to studies of classic CPSI deficiency, we have developed data for the EDGE concept in post-cardiac surgery-related pulmonary hypertension, hepatic veno-occlusive disease after bone marrow transplantation, and persistent pulmonary hypertension of the newborn. We have linked these outcomes and genotypes to the availability of the urea cycle intermediates, citrulline and arginine, and their role in NO synthesis. We hypothesize that these polymorphisms affect the functional efficiency of CPSI and thus the entire urea cycle and as such, the availability of the NO substrates. By piecing together the various functional aspects of the urea cycle changes we have seen, we can better understand the clinical vulnerabilities of patients in environmentally stressful situations. This knowledge should allow us to design intervention strategies to either predict or modify the associated adverse outcomes.
