Mutations in MEF2A have been implicated in an autosomal dominant form of coronary artery disease (adCAD1). In this study we sought to determine whether severe mutations in MEF2A might also explain sporadic cases of coronary artery disease (CAD). To do this, we resequenced the coding sequence and splice sites of MEF2A in ~;300 patients with premature CAD and failed to find causative mutations in the CAD cohort. However, we did identify the 21 base pair (bp) MEF2A coding sequence deletion originally implicated in adCAD1 in one of 300 elderly control subjects without CAD. Further screening of an additional ~;1,500 non-CAD patients revealed two more subjects with the MEF2A 21 bp deletion. Genotyping of 19 family members of the three probands with the 21 bp deletion in MEF2A revealed that the mutation did not co-segregate with early CAD. These studies demonstrate that MEF2A mutations are not a common cause of CAD and cast serious doubt on the role of the MEF2A 21 bp deletion in adCAD1.

Members of the pancreatic polypeptide family and their receptors have been implicated in the control of food intake in rodents and humans. To investigate whether nucleotide changes in these candidate genes result in abnormal weight in humans, we sequenced the coding exons and splice sites of seven family members (NPY, PYY, PPY, NPY1R, NPY2R, NPY4R, and NPY5R) in a large cohort of extremely obese (n=379) and lean (n=378) individuals. In total we found eleven rare non-synonymous variants, four of which exhibited familial segregation, NPY1R L53P and PPY P63L with leanness and NPY2R D42G and PYY Q62P with obesity. Functional analysis of the obese variants revealed NPY2R D42G to have reduced cell surface expression, while previous cell culture based studies indicated variant PYY Q62P to have altered receptor binding selectivity and we show that it fails to reduce food intake through mouse peptide injection experiments. These results support that rare non-synonymous variants within these genes can alter susceptibility to human body mass index extremes.

Body weight is a quantitative trait with significant heritability in humans. To identify potential genetic contributors to this phenotype, we resequenced the coding exons and splice junctions of 58 genes in 379 obese and 378 lean individuals. Our 96Mb survey included 21 genes associated with monogenic forms of obesity in humans or mice, as well as 37 genes that function in body weight-related pathways. We found that the monogenic obesity-associated gene group was enriched for rare nonsynonymous variants unique to the obese (n=46) versus lean (n=26) populations. Computational analysis further predicted a significantly greater fraction of deleterious variants within the obese cohort. Consistent with the complex inheritance of body weight, we did not observe obvious familial segregation in the majority of the 28 available kindreds. Taken together, these data suggest that multiple rare alleles with variable penetrance contribute to obesity in the population and provide a deep medical sequencing based approach to detect them.