Mutations in CYP1B1 cause primary congenital glaucoma by reduction of either activity or abundance of the enzyme.

Primary congenital glaucoma (PCG) is an autosomal recessive disorder caused predominantly by mutations in the CYP1B1 gene. A total of five frequent single nucleotide polymorphisms (SNPs) have been identified in the coding sequence of CYP1B1: rs10012C>G (p.R48G), rs1056827G>T (p.A119S), rs1056836C>G (p.V432L), rs1056837C>T (p.D449D), and rs1800440A>G (p.N453S). We performed a functional characterization of four common CYP1B1 variants presenting different coding SNP haplotypes (RAVDN, GSLDN, RALDS, and RALDN) and five CYP1B1 mutations reported for PCG patients: c.182G>A (p.G61E), c.608A>G (p.N203S), c.1033_1035del (p.L343del), c.241 T>A (p.Y81N), and c.685G>A (p.E229 K). Each mutation was embedded in its corresponding background SNP haplotype. The common variants revealed variation in enzymatic activity; among them, RAVDN showed the highest activity. Mutants p.G61E, p.N203S, and p.L343del each revealed a residual activity (<10%) of their respective haplotype. The microsomal CYP1B1 abundance relative to total protein also showed variation in common variants and a significant reduction in p.L343del, p.Y81N, and p.E229 K. The free energy of folding (DeltaDeltaG) values suggest that the lower stability of the mutants is one key property leading to the experimentally observed lower protein abundance. Our new measure of relative enzymatic activity (U/mg total protein), which combines activity and abundance values, was significantly lower for all five mutations compared to the corresponding background haplotype. We classified p.Y81N and p.E229 K not as mutations but as hypomorphic alleles, since their relative activity values are intermediate between bona fide mutations and the common variant with the lowest activity (RALDS). We propose that CYP1B1 mutations can act by either reducing enzymatic activity (p.G61E and p.N203S), reducing the abundance of the enzyme (p.Y81N and p.E229 K), or both (p.L343del).