Mutations in human CPO gene predict clinical expression of either hepatic hereditary coproporphyria or erythropoietic harderoporphyria.

Hereditary coproporphyria (HCP), an autosomal dominant acute hepatic porphyria, results from mutations in the gene that encodes coproporphyrinogen III oxidase (CPO). HCP (heterozygous or rarely homozygous) patients present with an acute neurovisceral crisis, sometimes associated with skin lesions. Four patients (two families) have been reported with a clinically distinct variant form of HCP. In such patients, the presence of a specific mutation (K404E) on both alleles or associated with a null allele, produces a unifying syndrome in which hematological disorders predominate: 'harderoporphyria'. Here, we report the fifth case (from a third family) with harderoporphyria. In addition, we show that harderoporphyric patients exhibit iron overload secondary to dyserythropoiesis. To investigate the molecular basis of this peculiar phenotype, we first studied the secondary structure of the human CPO by a predictive method, the hydrophobic cluster analysis (HCA) which allowed us to focus on a region of the enzyme. We then expressed mutant enzymes for each amino acid of the region of interest, as well as all missense mutations reported so far in HCP patients and evaluated the amount of harderoporphyrin in each mutant. Our results strongly suggest that only a few missense mutations, restricted to five amino acids encoded by exon 6, may accumulate significant amounts of harderoporphyrin: D400-K404. Moreover, all other type of mutations or missense mutations mapped elsewhere throughout the CPO gene, lead to coproporphyrin accumulation and subsequently typical HCP. Our findings, reinforced by recent crystallographic results of yeast CPO, shed new light on the genetic predisposition to HCP. It represents a first monogenic metabolic disorder where clinical expression of overt disease is dependent upon the location and type of mutation, resulting either in acute hepatic or in erythropoietic porphyria.

Hemochromatosis (HFE) and transferrin receptor-1 (TFRC1) genes in sporadic porphyria cutanea tarda (sPCT).

Porphyria cutanea tarda (PCT), a disorder characterized by a photosensitive dermatosis and hepatic siderosis, is caused by a decreased activity of the hepatic enzyme uroporphyrinogen decarboxylase (UROD). Two forms of PCT have been described: a familial one (fPCT) with an inherited decrease of UROD activity in all tissues and a sporadic one (sPCT) with a decreased UROD activity restricted to the liver. Iron overload and acquired factors including hepatic viral infections, alcohol, drugs contribute to the expression of PCT. In 65 French sPCT patients and 108 controls we have evaluated the respective role of iron and HCV status, the hemochromatosis (HFE) gene mutations frequencies (H63D. S65C, C282Y), and in a case control study we searched for an association between sPCT and the human transferrin receptor-1 (TFRC1) gene whose product is thought to be in functional association with the HFE protein: three single nucleotide polymorphisms (SNPs) previously characterized and 2 novel ones were studied. The iron-related parameters and transaminases were higher in sPCT patients than those of non-porphyric controls. Of the sPCT patients studied, 28% were HCV positive. In the HFE gene, 17% of sPCT patients carried C282Y mutation compared to 4% in controls, no significant differences were found with H63D and S65C variants. Compound heterozygous genotypes, C282Y/H63D or C282Y/S65C, were not significantly different in sPCT and control groups. Independently from HFE gene mutations, an association was found between the IVS4+198 T allele in the TFRC1 gene and sPCT patients. Analysis of HFE genotypes indicated that C282Y (but not H63D nor S65C) is a susceptibility factor for the development of sPCT in West European continental patients. However, analysis of TFRC1 genotypes suggest that sPCT should be considered as a multifactorial disorder in which other intracellular iron metabolism genes could be involved.