Hepatoerythropoietic Porphyria Caused by a Novel Homoallelic Mutation in Uroporphyrinogen Decarboxylase Gene in Egyptian Patients.

Porphyrias are metabolic disorders resulting from mutations in haem biosynthetic pathway genes. Hepatoerythropoietic porphyria (HEP) is a rare type of porphyria caused by the deficiency of the fifth enzyme (uroporphyrinogen decarboxylase, UROD) in this pathway. The defect in the enzymatic activity is due to biallelic mutations in the UROD gene. Currently, 109 UROD mutations are known. The human disease has an early onset, manifesting in infancy or early childhood with red urine, skin photosensitivity in sun-exposed areas, and hypertrichosis. Similar defects and links to photosensitivity and hepatopathy exist in several animal models, including zebrafish and mice. In the present study, we report a new mutation in the UROD gene in Egyptian patients with HEP. We show that the homozygous c.T163A missense mutation leads to a substitution of a conserved phenylalanine (amino acid 55) for isoleucine in the enzyme active site, causing a dramatic decrease in the enzyme activity (19 % of activity of wild-type enzyme). Inspection of the UROD crystal structure shows that Phe-55 contacts the substrate and is located in the loop that connects helices 2 and 3. Phe-55 is strictly conserved in both prokaryotic and eukaryotic UROD. The F55I substitution likely interferes with the enzyme-substrate interaction.

A zebrafish model for hepatoerythropoietic porphyria.

Defects in the enzymes involved in the haem biosynthetic pathway can lead to a group of human diseases known as the porphyrias. yquem (yqe(tp61)) is a zebrafish mutant with a photosensitive porphyria syndrome. Here we show that the porphyric phenotype is due to an inherited homozygous mutation in the gene encoding uroporphyrinogen decarboxylase (UROD); a homozygous deficiency of this enzyme causes hepatoerythropoietic porphyria (HEP) in humans. The zebrafish mutant represents the first genetically 'accurate' animal model of HEP, and should be useful for studying the pathogenesis of UROD deficiency and evaluating gene therapy vectors. We rescued the mutant phenotype by transient and germline expression of the wild-type allele.

Molecular characterization of a novel defect occurring de novo associated with erythropoietic protoporphyria.

A ferrochelatase (FC) mRNA lacking exon 4 was detected in a patient with erythropoietic protoporphyria (EPP). The mutation responsible for the exon skipping was a novel one: a G-->C transition at the -1 position of the exon 4 donor site (nucleotide 463). The efficiency of missplicing was not 100%. The same mutation could alternatively result in exon 4 skipping or act as a missense mutation (G463-->C, predicting an Ala155-->Pro substitution), that inactivates the FC activity almost completely. Both parents were negative for the mutation and DNA fingerprinting indicated that both of them are the biological parents with 99.58% certainty. This is the first report of a de novo mutation in EPP.

Mutations in familial porphyria cutanea tarda: two novel and two previously described for hepatoerythropoietic porphyria.

Uroporphyrinogen decarboxylase (URO-D) deficiency is responsible for two forms of genetic cutaneous porphyria: familial porphyria cutanea tarda (f-PCT) and hepatoerythropoietic porphyria (HEP). The f-PCT transmitted as an autosomal dominant trait, is characterized by photosensitive cutaneous lesions frequently associated to hepatic dysfunction and is precipitated by various ecogenic factors. The HEP, transmitted as a recessive trait, is more severe than f-PCT and would be considered as the homozygous form of f-PCT. For the mutational analysis of f-PCT patients, the entire URO-D gene was amplified and each exon, intron-exon boundaries and the promoter region were cycle sequenced. Five mutations were found in 6 unrelated families studied, of these, two were new: a nonsense mutation in exon 6 (W159X) and a splice defect in intron 9 (IVS9(-1)G-->C). The other two missense mutations, P62L and A80G, had been previously reported in the homozygous state in HEP families. The g10insA, reported in our laboratory, was again identified in other two unrelated families. In addition 3 novel URO-D polymorphisms in non-coding regions were found. The reverse transcription-PCR and sequencing of the splice mutation carrier's RNA did not reveal the presence of an abnormal mRNA, suggesting that no stable transcript from the mutated allele is synthesized. These results increase to 39 the number of mutations identified in the URO-D gene; 4 of them causing both HEP and f-PCT.

Molecular defects of uroporphyrinogen decarboxylase in a patient with mild hepatoerythropoietic porphyria.

The molecular defect of uroporphyrinogen decarboxylase (UROD) was examined in a patient with mild hepatoerythropoietic porphyria. To elucidate the UROD defect, we cloned UROD cDNAs from EBV-transformed lymphoblastoid cells of the proband using reverse transcriptase-polymerase chain reaction. Nucleotide sequence analysis of the cloned UROD cDNAs revealed two separate missense mutations, each occurring in a separate allele. One mutation was a Val134-->Gln transition, and was due to three sequential point mutations (T417G418T419-->CCA); the other mutation was a His220-->Pro transition (A677-->C). UROD phenotype studies demonstrated that the TGT-->CCA mutation was inherited from the father, and the A-->C mutation was inherited from the mother. In contrast to the null activity previously described for a mutant UROD from a patient with familial porphyria cutanea tarda, these mutant URODs had subnormal but substantial enzyme activities, when expressed in Chinese hamster ovary cells. This is the first demonstration of a mutation caused by three sequential base substitutions.

Amelioration of the metabolic defect in erythropoietic protoporphyria by expression of human ferrochelatase in cultured cells.

The cDNA for human ferrochelatase, the enzyme that is defective in the rare genetic disease erythropoietic protoporphyria (EPP), was tested for its ability to allow the expression of ferrochelatase in mammalian cells. The cDNA was ligated to the plasmid expression vectors pCD and pED6 and transfected into COS-1 and CHO-DUKX cells, respectively. In each case, ferrochelatase activity increased. The cDNA was also ligated into the retroviral vector pLXSN, and virus-packaging cells were produced. Supernatants from these cells were used to infect fibroblasts in vitro from a patient with EPP. We found that the infected cells containing the ferrochelatase cDNA had enzyme levels in the range of normal fibroblasts and that they did not accumulate protoporphyrin when grown in the presence of delta-aminolevulinic acid. We conclude that introducing the cDNA for normal ferrochelatase into fibroblasts from an EPP patient restores ferrochelatase enzyme activity to the normal range. These experiments suggest potential for genetic therapy in EPP.

Mutations in the ferrochelatase gene of four Spanish patients with erythropoietic protoporphyria.

Erythropoietic protoporphyria is a hereditary disorder of porphyrin metabolism caused by mutations in the ferrochelatase gene. Ferrochelatase catalyzes the chelation of ferrous iron into protoporphyrin IX to form heme. Mutation analysis was performed in four Spanish erythropoietic protoporphyria families resulting in the identification of four different mutations in the ferrochelatase gene. Two of them were novel mutations, a missense mutation (1157 A-->C, H386P) and a frameshift mutation (843delC) found in two Spanish families, respectively. The third and the forth Spanish patients carried already published ferrochelatase gene mutations, a nonsense mutation (343C-->T, R115X) and a missense mutation (557T-->C, I186T), respectively. The newly described frameshift mutation (843delC) predicted formation of an abrupt mRNA. The deleterious effect of His386 to Pro substitution as a result of mutation 1157 A-->C on the ferrochelatase activity was investigated by expressing the mutant ferrochelatase in Escherichia coli. The mutant ferrochelatase exhibited only 0.8% of the wild-type ferrochelatase activity. Prediction of the secondary structure of ferrochelatase suggested that the H386P mutation disrupted the original alpha-helical structure by way of introducing a turn, a rather drastic structural change of the enzyme sufficient to cause activity loss.

Haplotype analysis of families with erythropoietic protoporphyria and novel mutations of the ferrochelatase gene.

Ferrochelatase, the enzyme that catalyzes the terminal step in the heme biosynthetic pathway, is the site of the defect in the human inherited disease erythropoietic protoporphyria. Molecular genetic studies have shown that the majority of erythropoietic protoporphyria cases are transmitted in dominant fashion and that mutations underlying erythropoietic protoporphyria are heterogeneous. We performed haplotype analysis of American families that shared recurrent ferrochelatase gene mutations yet had forbearers from several European countries. This was to gain insight into whether these mutations represent mutational hotspots at the ferrochelatase gene, or propagation of ancestral alleles bearing the mutations. Two recurrent mutations were found to occur on distinctive chromosome 18 haplotypes, consistent with being hotspot mutations. On the other hand, we found three sets of two unrelated families that shared the same haplotypes bearing these mutations, which could reflect geographic dispersion of ancestral mutant alleles. In addition, we report novel mutations associated with erythropoietic protoporphyria: g(+ 1)-->t transversion of the exon 4 donor site, g(+ 1)-->a transition of the exon 6 donor site, and t(+ 2)-->a substitution at the exon 9 donor site; these mutations are predicted to cause splicing defects of the associated exons. We also identified a g(+ 5)-->a transition of the exon 1 donor site in four unrelated families with erythropoietic protoporphyria, and a G(- 1)-->A substitution at the exon 9 donor site in an additional family. The probability that these sequence changes are normal polymorphisms was virtually excluded (p < 0.0001) by their absence in 120 ferrochelatase alleles from 30 normal subjects and 30 individuals with manifested erythropoietic protoporphyria with or without a known mutation.

Ferrochelatase.

Ferrochelatase, the terminal enzyme of the heme biosynthetic pathway, catalyzes the insertion of ferrous iron into protoporphyrin IX. It is encoded by a single gene, and mutations in the human gene are associated with the inherited disorder, erythropoietic protoporphyria. With the development of heterologous overexpression systems and the ready availability of recombinant ferrochelatase, new structural elements have been identified and new aspects of the ferrochelatase-catalyzed reaction mechanism have been unraveled. Namely, a [2Fe-2S] cluster is a prosthetic group in mammalian ferrochelatase, a conserved and essential histidine residue appears to be involved in the binding of the metal substrate and a conserved glutamate residue has been proposed to have a catalytic role. The three-dimensional structure for Bacillus subtilis ferrochelatase, the only known 'water-soluble' ferrochelatase, revealed that the protein contains two similar domains, each of which has a four-stranded beta-sheet flanked by alpha-helices; the active site was modeled to be in a cleft defined by the two domains. The definition of the structure and catalytic mechanism of ferrochelatase should help in the interpretation of the impact caused by erythropoietic porphyria mutations.

Alteration of mRNA levels of delta-aminolevulinic acid synthase, ferrochelatase and heme oxygenase-1 in griseofulvin induced protoporphyria mice.

Human erythropoietic protoporphyria (EPP) is an inherited disorder of porphyrin metabolism and its experimental murine model can be produced by treatment with griseofulvin (GF). We investigated the alteration of mRNA expression in ferrochelatase (FeC), delta-aminolevulinic acid synthase (ALAS) and heme oxygenase-1 (HO-1) in liver, skin and peripheral blood cells of GF-treated mice. In liver, ALAS mRNA was enhanced dramatically by GF administration, in accord with thesis that the expression of ALAS is regulated by feedback mechanism. The expression of HO-1 mRNA increased most rapidly and drastically in liver, however its mechanism of regulation may be different from that of ALAS mRNA. The level of FeC mRNA in liver was less affected with GF treatment. Our results indicate that the inhibition of FeC by GF administration might occur primarily at post-transcriptional level. Similar effects were observed in the ALAS and HO-1 mRNA expression in peripheral blood cells, 2-fold increase in the ALAS mRNA and increase from undetectable level to detectable level in the HO-1 mRNA. In skin of GF-treated mice, average increases of 1.3-fold in the ALAS mRNA and 1.6-fold in the HO-1 mRNA were statistically insignificant. The FeC mRNA level was not altered in peripheral blood or in skin of GF-treated mice. The present study indicates that the molecular analysis is practicable in skin and peripheral blood. In further study, this model could contribute to investigate the pathogenesis of clinical manifestation including possibly cutaneous changes in EPP.

Autosomal recessive erythropoietic protoporphyria: a syndrome of severe photosensitivity and liver failure.

Erythropoietic protoporphyria is caused by inherited deficiency of the haem synthetic enzyme ferrochelatase, and is characterized by lifelong photosensitivity. About 5% of patients also develop rapidly progressive liver failure. Inheritance is considered to be autosomal dominant, with transmission of a single ferrochelatase defect from one parent. We describe a family in which two siblings with protoporphyria suffered from severe photosensitivity and developed hepatic failure requiring liver transplantation. Their asymptomatic parents were heterozygous for distinct ferrochelatase gene mutations (exon 10 donor site a(+3)-->g and 1088T-->G). Both mutations disrupt splicing of the transcript and cause partial deficiency of ferrochelatase. The affected offspring were compound heterozygotes for these mutations. These patients suffered from an autosomal recessive form of protoporphyria characterized by severe photosensitivity and cholestatic liver disease in adolescence. We postulate that hepatic failure in erythropoietic protoporphyria may in some cases represent an autosomal recessive type of ferrochelatase deficiency distinct from the purely dermatological disorder. Studies of disease inheritance in families affected by protoporphyria may help identify those predisposed to develop severe liver complications, a distinction not currently possible.

Hematologic aspects of the porphyrias.

The porphyrias are disorders that can be inherited and acquired, in which the activities of the enzymes of the heme biosynthetic pathway are partially or almost totally deficient. There are 8 enzymes involved in the synthesis of heme, and, with the exception of the first enzyme, an enzymatic defect at every step leads to tissue accumulation and excessive excretion of porphyrins and/or their precursors, such as delta-aminolevulinic acid and porphobilinogen. Whereas heme, the final product of the biosynthetic pathway, is biologically important, porphyrins and their precursors are not only useless but also toxic. Porphyrias can be classified as either photosensitive or neurologic, depending on the type of symptoms, but some porphyrias cause both photosensitive and neurologic symptoms. Alternatively, they can be classified either hepatic or erythropoietic, depending on the principal site of expression of the specific enzymatic defect. The tissue-specific expression of porphyrias is largely due to the tissue-specific control of heme pathway gene expression, particularly at the level of delta-aminolevulinate synthase, the first and the rate-limiting enzyme of heme biosynthesis. In this chapter, hematologic aspects of the erythropoietic porphyrias will be described. The 3 major erythropoietic porphyrias are congenital erythropoietic porphyria (CEP), hepatoerythropoietic porphyria (HEP) and erythropoietic protoporphyria (EPP).

Erythropoietic protoporphyria: identification of novel mutations in the ferrochelatase gene and comparison of biochemical markers versus molecular analysis as diagnostic strategies.

BACKGROUND: Erythropoietic protoporphyria (EPP) results from an inherited deficiency of the last enzyme of the heme biosynthetic pathway, ferrochelatase (FC). EPP is usually inherited in an autosomal dominant fashion, and the mutations in the FC gene on chromosome 18q21.3 detected in EPP patients are heterogeneous. METHODS: In this study, we screened the FC gene for mutations in 12 patients from 10 unrelated families with EPP and their family members using heteroduplex analysis, automated sequencing, and restriction enzyme digestion. RESULTS: We detected 8 different mutations in these patients, including 1 missense mutation, 5 frameshift mutations, and 2 splice site mutations, 6 of which are previously undescribed. CONCLUSIONS: We have established the molecular basis of EPP in 10 unrelated families, thereby providing further evidence for the heterogeneity in this disorder. Importantly, molecular diagnosis allowed revisions in the status of several clinically unaffected silent mutation carriers within the families. We compare the value of genetic research strategies with the combination of biochemical data and clinical phenotype as diagnostic tools to confirm a putative diagnosis in EPP.

Molecular genetics of erythropoietic protoporphyria.

Erythropoietic protoporphyria (EPP) is caused by decreased activity of the enzyme ferrochelatase and is characterized by burning photosensitivity commencing in childhood. From 1-10% of patients develop potentially fatal protoporphyric hepatic failure. The gene for ferrochelatase has been cloned, sequenced and mapped to the long arm of chromosome 18. EPP is genetically very heterogeneous and 24 different mutations in 27 unrelated patients have been published. In the majority of families co-inheritance of a mutant ferrochelatase allele from one parent and a low-output "normal" ferrochelatase allele from the other parent is required for disease expression. The molecular basis, if any, of protoporphyric hepatic failure has not yet been resolved. Gene therapy experiments have been completed in vitro and are in progress in an animal model of EPP. In conclusion, molecular genetic investigation of EPP has increased our understanding of its pathogenesis and inheritance. Why some EPP patients develop hepatic failure is still unanswered. Gene therapy of EPP patients may become possible in the future.

Human protoporphyria: genetic heterogeneity at the ferrochelatase locus.

Inherited deficiency of ferrochelatase results in erythropoietic protoporphyria (EPP). Genetic heterogeneity at the locus for human ferrochelatase was investigated. Analysis of genomic DNA of patients with EPP and of control subjects by restriction endonuclease techniques using ten different enzymes detected polymorphisms only at sites recognized by EcoRI, HincII, PstI and TaqI. None of these polymorphisms alone was specific for expression of the disease since each was observed in control subjects as well. Three of these polymorphisms (at EcoRI, HincII and PstI sites) were always associated, indicating linkage. These and other studies demonstrate that the ferrochelatase gene is markedly heterogeneous. It is not yet clear whether some of the mutations associated with these polymorphisms contribute to expression of EPP.

[Enzymatic and molecular studies in a case of hepato-erythropoietic porphyria. Homozygote form of type familial cutaneous porphyria]. / Etudes enzymatique et moléculaire d'un cas de porphyrie hépato-érythrocytaire. Forme homozygote de la porphyrie cutanée de type familial.

BACKGROUND: Porphyrias are either hepatic or erythroid, depending on the principal site of the specific enzymatic defect. Homozygous uroporphyrinogen decarboxylase deficiency, known as hepato-erythropoietic porphyria (HEP), can involve several mutations. CASE REPORT: A young man, aged 20 years, had gradually developed photosensitivity since the age of 1 year, leading to hypertrichosis and sclerodermoid changes in sun-exposed areas of skin. He displayed high urinary uroporphyrin and 7-carboxylic porphyrins, and elevated fecal and red blood cell iso-coproporphyrin and coproporphyrin. Erythrocyte uroporphyrinogen decarboxylase activity of the patient was reduced to 18% of normal control values, while those of his grandmother and his half-brother were 62-65% of normal. MOLECULAR BIOLOGY: Amplification of the genomic DNA by PCR and hybridization with allele-specific oligonucleotides (ASOs) demonstrated the presence of a Gly 281-->Glu mutation in the patient and in his grandmother and half-brother. CONCLUSION: Enzymatic studies and details of the familial lineage are important for precisely classifying this type of porphyria. Molecular biology studies are necessary before considering any future gene therapy.

Erythropoietic protoporphyria (EPP) at 40. Where are we now?

Since Professor Magnus first defined erythropoietic protoporphyria (EPP) in 1961, there has been considerable progress in the understanding this disease. The past decade has been a period of spectacular progress in understanding the genetics and pathogenesis of the disease by molecular investigation. However, progress in therapy for EPP has been slower, and has been dogged by difficulty in assessing treatment efficacy in patients. We are now entering an era in which advances in molecular genetics are directly affecting patient management. This review summarises laboratory and clinical progress in EPP in the past 40 years, and assesses the potential impact of molecular biology on clinical practice.

Five new mutations in the uroporphyrinogen decarboxylase gene identified in families with cutaneous porphyria.

We describe five new mutations in the uroporphyrinogen decarboxylase (UROD) gene. All mutations were observed in conjunction with decreased erythrocyte UROD and clinical familial porphyria cutanea tarda (fPCT), (four families) or hepatoerythropoietic porphyria (HEP), (one family). The fPCT mutations included three point mutations that resulted in amino acid substitutions: a lysine to glutamine at amino acid position 253 (exon 7); a glycine to arginine at position 318 (exon 10); an isoleucine to threonine at position 334 (exon 10). The lysine to glutamine at amino acid position 253 was found in conjunction with a single C nucleotide deletion in exon 8 on the same allele of the UROD gene in the same family. This deletion resulted in a shift in the reading frame and the introduction of a premature stop codon 8 amino acids downstream. In the fourth family, a 31-bp deletion (nucleotides 828-858: exon 8) of the coding region, resulted in a frameshift and the introduction of a stop codon 19 amino acids downstream. A point mutation was observed in an individual diagnosed with HEP, resulting in an alanine to glycine change at amino acid position 80 and was present on both alleles. All mutations were confirmed in at least one other family member. The impact of these mutations on the function of the UROD protein was examined using in vitro protein expression and with activity assessed using pentacarboxylic acid porphyrinogen I as a substrate for UROD. Although three mutations reduced UROD activity to < 15% of normal, one resulted in a UROD protein with 50% functional activity and the other had near normal activity. These results indicate that many different genetic lesions of the UROD gene are associated with fPCT.