A novel mutation in medium chain acyl-CoA dehydrogenase causes sudden neonatal death.

Medium chain acyl-CoA dehydrogenase (MCAD) deficiency is the most common known genetic disorder of fatty acid oxidation. Most (approximately 80%) cases are homozygous for a single mutation: A to G replacement at nucleotide 985 (A985G). MCAD deficiency typically presents in the second year of life as hypoketotic hypoglycemia associated with fasting and may progress to liver failure, coma, and death. Prompt diagnosis and management may prevent long-term sequelae. MCAD deficiency was verified by analysis of urinary acylglycine and serum acylcarnitine species from two neonates referred for diagnosis. Full-length cDNA and MCAD exon 7 and 11 genomic clones were prepared for sequence analysis. Normal and mutant cDNAs were expressed in bacteria, and enzymatic activity was assayed by the ferricenium hexaflurophosphate method. Four compound heterozygote individuals from two unrelated families with A985G on one allele and a novel G to A mutation at nucleotide 583 (G583A) as the second mutant allele presented with MCAD deficiency in the first week of life. The expressed G583A mutant protein lacks enzymatic activity. This novel mutation, G583A, is associated with severe MCAD deficiency causing hypoglycemia or sudden, unexpected neonatal death. This previously unrecognized phenotype of MCAD deficiency may contribute significantly to preventable infant deaths.

Contribution of the repeating domains of membrane cofactor protein (CD46) of the complement system to ligand binding and cofactor activity.

Membrane cofactor protein (MCP) (CD46) of the C system binds to C3b and C4b, functions as a cofactor for their cleavage, and protects autologous cells from C-mediated injury. The predominant structural motif of MCP is the short consensus repeat (SCR), a repeating domain involved in ligand binding of other related C regulatory proteins. SCR deletion mutants were constructed to determine which of the four SCR of MCP contribute to ligand binding and cofactor activity. ELISA were developed to evaluate binding efficiency of mutants to ligand. Analysis of the deletion mutants indicated that the third and fourth SCR were important for both ligand binding and cofactor activity of C3b (iC3) and C4b. In addition, the same SCR were required for efficient binding of an mAb known to inhibit MCP function. The mutant deleted of SCR-2 bound but lacked cofactor activity for iC3. It did not bind or possess cofactor activity for C4b. Deletion of the first (amino-terminal) SCR had a minimal effect on iC3 binding and cofactor activity but reduced the efficiency of C4b binding. The results identify the SCR of MCP that contribute to ligand binding and cofactor activity. The data also suggest the presence of distinguishable iC3 and C4b binding sites and provide evidence that iC3 binding is not always sufficient for cofactor activity.