Identification of the first variegate porphyria mutation in an indigenous black South African and further evidence for heterogeneity in variegate porphyria

Quantitative structural insight into human variegate porphyria disease

Defects in the human protoporphyrinogen oxidase (hPPO) gene, resulting in ~50% decreased activity of hPPO, is responsible for the dominantly inherited disorder variegate porphyria (VP). To understand the molecular mechanism of VP, we employed the site-directed mutagenesis, biochemical assays, structural biology, and molecular dynamics simulation studies to investigate VP-causing hPPO mutants. We report here the crystal structures of R59Q and R59G mutants in complex with acifluorfen at a resolution of 2.6 and 2.8 Å. The r.m.s.d. of the Cα atoms of the active site structure of R59G and R59Q with respect to the wild-type was 0.20 and 0.15 Å, respectively. However, these highly similar static crystal structures of mutants with the wild-type could not quantitatively explain the observed large differences in their enzymatic activity. To understand how the hPPO mutations affect their catalytic activities, we combined molecular dynamics simulation and statistical analysis to quantitatively understand the molecular mechanism of VP-causing mutants. We have found that the probability of the privileged conformations of hPPO can be correlated very well with the k(cat)/K(m) of PPO (correlation coefficient, R(2) > 0.9), and the catalytic activity of 44 clinically reported VP-causing mutants can be accurately predicted. These results indicated that the VP-causing mutation affect the catalytic activity of hPPO by affecting the ability of hPPO to sample the privileged conformations. The current work, together with our previous crystal structure study on the wild-type hPPO, provided the quantitative structural insight into human variegate porphyria disease.

Hepatoerythropoietic porphyria due to a novel mutation in the uroporphyrinogen decarboxylase gene

BACKGROUND

Hepatoerythropoietic porphyria (HEP) is a rare form of porphyria that results from a deficiency of uroporphyrinogen decarboxylase (UROD). The disease is caused by homoallelism or heteroallelism for mutations in the UROD gene.

OBJECTIVE

To study a 19-year-old woman from Equatorial Guinea, one of the few cases of HEP of African descent and to characterize a new mutation causing HEP.

METHODS

Excretion of porphyrins and residual UROD activity in erythrocytes were measured and compared with those of other patients with HEP. The UROD gene of the proband was sequenced and a new mutation identified. The recombinant UROD protein was purified and assayed for enzymatic activity. The change of amino acid mapped to the UROD protein and the functional consequences were predicted.

RESULTS

The patient presented a novel homozygous G170D missense mutation. Porphyrin excretion showed an atypical pattern in stool with a high pentaporphyrin III to isocoproporphyrin ratio. Erythrocyte UROD activity was 42% of normal and higher than the activity found in patients with HEP with a G281E mutation. The recombinant UROD protein showed a relative activity of 17% and 60% of wild-type to uroporphyrinogen I and III respectively. Molecular modelling showed that glycine 170 is located on the dimer interface of UROD, in a loop containing residues 167-172 that are critical for optimal enzymatic activity and that the carboxyl side chain from aspartic acid is predicted to cause negative interactions between the protein and the substrate.

CONCLUSIONS

The results emphasize the complex relationship between the genetic defects and the biochemical phenotype in homozygous porphyria.

Kinetic and physical characterisation of recombinant wild-type and mutant human protoporphyrinogen oxidases

The effects of various protoporphyrinogen oxidase (PPOX) mutations responsible for variegate porphyria (VP), the roles of the arginine-59 residue and the glycines in the conserved flavin binding site, in catalysis and/or cofactor binding, were examined. Wild-type recombinant human PPOX and a selection of mutants were generated, expressed, purified and partially characterised. All mutants had reduced PPOX activity to varying degrees. However, the activity data did not correlate with the ability/inability to bind flavin. The positive charge at arginine-59 appears to be directly involved in catalysis and not in flavin-cofactor binding alone. The K(m)s for the arginine-59 mutants suggested a substrate-binding problem. T(1/2) indicated that arginine-59 is required for the integrity of the active site. The dominant alpha-helical content was decreased in the mutants. The degree of alpha-helix did not correlate linearly with T(1/2) nor T(m) values, supporting the suggestion that arginine-59 is important for catalysis at the active site. Examination of the conserved dinucleotide-binding sequence showed that substitution of glycine in codon 14 was less disruptive than substitutions in codons 9 and 11. Ultraviolet melting curves generally showed a two-state transition suggesting formation of a multi-domain structure. All mutants studied were more resistant to thermal denaturation compared to wild type, except for R168C.

Nine novel mutations in the protoporphyrinogen oxidase gene in Swedish families with variegate porphyria

Variegate porphyria (VP) is an autosomal-dominant disorder that is caused by inheritance of a partial deficiency of the enzyme protoporphyrinogen oxidase (EC 1.3.3.4). It is characterized by cutaneous photosensitivity and/or various neurological manifestations. Protoporphyrinogen oxidase catalyses the penultimate step of haem biosynthesis, and mutations in the PPOX gene have been coupled to VP. In the present study, sequencing analysis revealed 10 different mutations in the PPOX gene in 14 out of 17 apparently unrelated Swedish VP families. Six of the identified mutations, 3G > A (exon 2), 454C > T (exon 5), 472G > C (exon 6), 614C > T (exon 6), 988G > C (exon 10) and IVS12 + 2T > G (intron 12), are single nucleotide substitutions, while 604delC (exon 6), 916-17delCT (exon 9) and 1330-31delCT (exon 13) are small deletions, and IVS12 + 2-3insT (intron 12) is a small insertion. Only one of these 10 mutations has been reported previously. Three of the mutations were each identified in two or more families, while the remaining mutations were specific for an individual family. In addition to the 10 mutations, one previously unreported single nucleotide polymorphism was identified. Mutation analysis of family members revealed two adults and four children who were silent carriers of the VP trait. Genetic analysis can now be added to the conventional biochemical analyses and used in investigation of putative carriers of a VP trait in these families.

Clinical and biochemical characteristics and genotype-phenotype correlation in Finnish variegate porphyria patients

Variegate porphyria (VP) is an inherited metabolic disease resulting from the partial deficiency of protoporphyrinogen oxidase, the penultimate enzyme in the heme biosynthetic pathway. We have evaluated the clinical and biochemical outcome of 103 Finnish VP patients diagnosed between 1966 and 2001. Fifty-two per cent of patients had experienced clinical symptoms: 40% had photosensitivity, 27% acute attacks and 14% both manifestations. The proportion of patients with acute attacks has decreased dramatically from 38 to 14% in patients diagnosed before and after 1980, whereas the prevalence of skin symptoms had decreased only subtly from 45 to 34%. We have studied the correlation between PPOX genotype and clinical outcome of 90 patients with the three most common Finnish mutations I12T, R152C and 338G-->C. The patients with the I12T mutation experienced no photosensitivity and acute attacks were rare (8%). Therefore, the occurrence of photosensitivity was lower in the I12T group compared to the R152C group (P=0.001), whereas no significant differences between the R152C and 338G-->C groups could be observed. Biochemical abnormalities were significantly milder suggesting a milder form of the disease in patients with the I12T mutation. In all VP patients, normal excretion of protoporphyrin in faeces in adulthood predicted freedom from both skin symptoms and acute attacks. The most valuable test predicting an increased risk of symptoms was urinary coproporphyrin, but only a substantially increased excretion exceeding 1,000 nmol/day was associated with an increased risk of both skin symptoms and acute attacks. All patients with an excretion of more than 1,000 nmol/day experienced either skin symptoms, acute attacks, or both.