Rat hepatic uroporphyrinogen III co-synthase. Purification and evidence for a bound folate coenzyme participating in the biosynthesis of uroporphyrinogen III.

Rat hepatic uroporphyrinogen III co-synthase was isolated and purified 73-fold with a 13% yield by (NH4)2SO4 fractionation and sequential chromatography on DEAE-Sephacel, Sephadex G-100 (superfine grade) and folate-AH-Sepharose 4B. The purified co-synthase has an Mr of approx. 42 000, and is resolved into two bands, each possessing co-synthase activity, by polyacrylamide-gel electrophoresis. A factor was dissociated from the purified co-synthase. Results of both microbiological and competitive protein-binding assays suggest that it is a pteroylpolyglutamate. The isolated pteroylpolyglutamate factor was co-eluted with authentic N5-methyltetrahydropteroylheptaglutamate on DEAE-Sephacel. Uroporphyrinogen III is formed by cosynthase-free preparations of uroporphyrinogen I synthase in the presence of tetrahydropteroylglutamate. Tetrahydropeteroylheptaglutamate is also able to direct the formation of equivalent amounts of uroporphyrinogen III at a concentration approximately one-hundredth that of tetrahydropteroylmonoglutamate. These results suggest that a reduced pteroylpolyglutamate factor is associated with rat hepatic uroporphyrinogen III co-synthase, and that this may function as a coenzyme for the biosynthesis of uroporphyrinogen III.     

Random decarboxylation of uroporphyrinogen III by human hepatic uroporphyrinogen decarboxylase

The type III heptacarboxylic porphyrinogens derived from enzymic decarboxylation of an acetic acid substituent on uroporphyrinogen III to a methyl group by human hepatic uroporphyrinogen decarboxylase has been analysed by reversed-phase high-performance liquid chromatography with electrochemical detection. The results showed that all four possible heptacarboxylic acid porphyrinogen isomers, with the methyl group attached to rings A, B, C and D of the tetrapyrrole macrocycle, respectively, were formed in almost equal proportions. It was concluded that the normal pathway of uroporphyrinogen III decarboxylation in human liver follows a random mechanism.     

Uroporphyrinogen decarboxylase

Uroporphyrinogen decarboxylase (EC 4.1.1.37) catalyzes the decarboxylation of uroporphyrinogen III to coproporphyrinogen III. The amino acid sequences, kinetic properties, and physicochemical characteristics of enzymes from different sources (mammals, yeast, bacteria) are similar, but little is known about the structure/function relationships of uroporphyrinogen decarboxylases. Halogenated and other aromatic hydrocarbons cause hepatic uroporphyria by decreasing hepatic uroporphyrinogen decarboxylase activity. Two related human porphyrias, porphyria cutanea tarda and hepatoerythropoietic porphyria, also result from deficiency of this enzyme. The roles of inherited and acquired factors, including iron, in the pathogenesis of human and experimental uroporphyrias are reviewed.     

Rat hepatic uroporphyrinogen III cosynthase: Purification,properties, and inhibition by metal ions

Rat hepatic uroporphyrinogen III cosynthase has been isolated and purified 50-fold with a 36% yield by ammonium sulfate fractionation and sequential chromatography on DEAE-Sephacel and Sephadex G-100SF. Inhibition of uroporphyrinogen III formation with increasing porphobilinogen concentration was observed. Cosynthase was shown to be thermolabile, and a time-dependent loss of enzyme activity during reaction with uroporphyrinogen I synthase and porphobilinogen was observed. The pH optimum for the complete system (synthase and cosynthase) was pH 7.8 in 50 mm Tris-HCl or 50 mm sodium phosphate buffer. Various metals (KCl, NaCl, MgCl₂, CaCl₂) increased formation of Uroporphyrinogen III. Heavy metals including ZnCl₂, CdCl₂, and CuCl₂ were shown to selectively inhibit cosynthase activity, whereas other metals (HgCl₂, PbCl₂) were less selective and inhibited both synthase and cosynthase at similar concentrations.     

In vitro studies of the mechanism of inhibition of rat liver uroporphyrinogen decarboxylase activity by ferrous iron under anaerobic conditions

Human porphyria cutanea tarda (PCT) is an unusual consequence of common hepatic disorders such as alcoholic liver disease and iron overload, where hepatic iron plays a key role in the expression of the metabolic lesion, i.e., defective hepatic decarboxylation of porphyrinogens. In this investigation, kinetic studies on a partially purified rat liver uroporphyrinogen decarboxylase have been conducted under controlled conditions to determine how iron perturbs porphyrinogen decarboxylation in vitro. The enzyme, assayed strictly under anaerobic conditions in the dark, was inhibited progressively by ferrous iron. Approximately 0.45 mM ferrous ammonium sulfate was required to observe about 50% inhibition of enzyme activity measured with uroporphyrinogen I as substrate. We showed that (a) all the steps of enzymatic decarboxylation (octa-, hepta-, hexa-, and pentacarboxylic porphyrinogen of isomer I series) were inhibited by ferrous iron. The inhibition was competitive with respect to uroporphyrinogen I and III substrates; (b) the cations, e.g., Fe3+ and Mg2+, had no effect, whereas sulfhydryl group specific cations and compounds such as Hg2+, Zn2+, p-mercuribenzoate, and 5,5'-dithiobis(2-nitrobenzoate) all inhibited the enzyme; (c) the enzyme could be protected from inhibition by Fe2+ and p-mercuribenzoate by preincubation with pentacarboxylic porphyrinogen, a natural substrate and competitive inhibitor. These data suggest for the first time a direct interaction of ferrous iron with cysteinyl residue(s) located at the active site(s) of the enzyme.     

Oxidation of uroporphyrinogen by methylcholanthrene-induced cytochrome P-450. Essential role of cytochrome P-450d.

We have previously shown that uroporphyrinogen is oxidized to uroporphyrin by microsomes (microsomal fractions) from 3-methylcholanthrene-pretreated chick embryo liver [Sinclair, Lambrecht & Sinclair (1987) Biochem. Biophys. Res. Commun. 146, 1324-1329]. We report here that a specific antibody to chick liver methylcholanthrene-induced cytochrome P-450 (P-450) inhibited both uroporphyrinogen oxidation and ethoxyresorufin O-de-ethylation in chick-embryo liver microsomes. 3-Methylcholanthrene-pretreatment of rats and mice markedly increased uroporphyrinogen oxidation in hepatic microsomes as well as P-450-mediated ethoxyresorufin de-ethylation. In rodent microsomes, uroporphyrinogen oxidation required the addition of NADPH, whereas chick liver microsomes required both NADPH and 3,3',4,4'-tetrachlorobiphenyl. Treatment of rats with methylcholanthrene, hexachlorobenzene and o-aminoazotoluene increased uroporphyrinogen oxidation and P-450d, whereas phenobarbital did not increase either. The contribution of hepatic P-450c and P-450d to uroporphyrinogen oxidation and ethoxyresorufin O-de-ethylation in methylcholanthrene-induced microsomes was assessed by using specific antibodies to P-450c and P-450d. Uroporphyrinogen oxidation by methylcholanthrene-induced rat liver microsomes was inhibited up to 75% by specific antibodies to P-450d, but not by specific antibodies to P-450c. In contrast, ethoxyresorufin de-ethylation was inhibited only 20% by anti-P450d but 70% by anti-P450c. Methylcholanthrene-induced kidney microsomes which contain P-450c but non P-450d did not oxidize uroporphyrinogen. These data indicate that hepatic P-450d catalyses uroporphyrinogen oxidation. We suggest that the P-450d-catalysed oxidation of uroporphyrinogen has a role in the uroporphyria caused by hexachlorobenzene and other compounds.     

Inhibition of the biosynthesis of uroporphyrinogen and heme in rat liver during obstructive jaundice produced by bile duct ligation

Altered hepatic microsomal drug metabolism has been reported to occur in afflicted with hyperbilirubinemia. Similarities of the chemical structures of hydroxymethylbilane, an intermediate in the biosynthesis of uroporphyrinogen, to bilirubin prompted investigations of the effect of bilirubin on the activity of uroporphyrinogen I synthase (porphobilinogen deaminase, EC 4.3.1.8) and the biosynthesis of heme. Bilirubin was found to be a reversible, noncompetitive inhibitor of uroporphyrinogen I synthase. The inhibition constant (Ki) for bilirubin was 1.5 microM. Bile acids had no effect on rat hepatic uroporphyrinogen I synthase activity. Hyperbilirubinemia was achieved in rats by biliary ligation in order to investigate whether elevated levels of bilirubin impair the biosynthesis of hepatic heme in vivo. The relative rate of heme biosynthesis, as measured by the rate of incorporation of delta-[4-14C]aminolevulinic acid into heme, was decreased 59% 24 h after biliary obstruction. The levels of hepatic microsomal heme and cytochrome P-450 were decreased by 43 and 40%, respectively, 72 h after biliary obstruction. The activities of hepatic delta-aminolevulinic acid synthase and uroporphyrinogen I synthase were increased by 39 and 46%, respectively, 72 h after biliary obstruction. During the 48- to 72-h period following biliary obstruction, the urinary excretion of porphobilinogen and uroporphyrin was increased 3.0- and 3.5-fold, respectively, whereas, the urinary excretion of delta-aminolevulinic acid was not altered. During this 48-to 72-h time interval following biliary obstruction, 100% of the uroporphyrin was excreted as isomer I. These results indicate that bilirubin is capable of depressing the biosynthesis of rat hepatic heme and thus cytochrome P-450-mediated drug metabolism by inhibition of the formation of uroporphyrinogen. These findings are a plausible mechanism for reports of impaired clearance of various drugs in patients afflicted with hyperbilirubinemic disease states.     

Biosynthesis of uroporphyrinogens. Interaction among 2-aminomethyltripyrranes and the enzymatic system

Many hypotheses on uroporphyrinogen biosynthesis advanced the possibility that 2-aminomethyltripyrranes formed by porphobilinogen deaminase are further substrates or uroporphyrinogen III co-synthase in the presence of porphobilinogen. These proposals were put to test by employing synthetic 2-aminomethyltripyrranes formally derived from porphobilinogen. None of them was found to be by itself a substrate of deaminase or of co-synthase in the presence of porphobilinogen. The tripyrranes chemically formed uroporphyrinogens by dimerization reactions, and the latter had to be deducted in control runs during the enzymatic studies. Two of the tripyrranes examined, the 2-aminomethyltripyrrane 7 and the 2-aminomethyltripyrrane 8, were found to be incorporated into enzymatically formed uroporphyrinogen III in the presence of porphobilinogen and of the deaminase-co-synthase system. While the former gave only a slight incorporation, the latter was incorporated in about 16%. No incorporation of 8 into uroporphyrinogen I was detected. On the basis of these results, and of the previous results obtained with 2-aminomethyldipyrrylmethanes, an outline of the most likely pathway of uroporphyrinogen III biosynthesis from porphobilinogen is given.     

Free radical mechanism of oxidation of uroporphyrinogen in the presence of ferrous iron

Human porphyria cutanea tarda is an unusual consequence of common hepatic disorders such as alcoholic liver disease. Hepatic iron plays a key role in the expression of the metabolic lesions, i.e., defective hepatic decarboxylation of porphyrinogens, catalyzed by uroporphyrinogen decarboxylase. This prompted the present study to determine the in vitro effects of iron on the uroporphyrinogen substrate in the absence and presence of atmospheric oxygen. We observed that (i) unless oxygen is the limiting reactant, autoxidation of ferrous iron and iron-catalyzed oxidation of uroporphyrinogen occurred soon after initiating the reaction at pH 7.4 and 30 degrees C in buffers which are non- or poor chelators of iron; (ii) the rates of uroporphyrinogen oxidation were proportional to the initial concentration of ferrous ion; (iii) about 70% of the oxidations of uroporphyrinogen were accountable due to a free-radical chain reaction pathway involving superoxide radical and hence inhibitable by superoxide dismutase; (iv) uroporphyrinogen could be further oxidized to completion by the hydroxyl radical since the reaction was partially inhibited by both mannitol and catalase which prevent hydroxyl radical production; (v) the oxidizing effects of ferric ion on uroporphyrinogen were none or negligible as compared to those of ferrous ion. Ferric was reduced to ferrous ion in the presence of dithiothreitol. When the ferrous ion thus formed was reoxidized in the presence of atmospheric oxygen, minor but definite oxidations of both uroporphyrinogen and dithiothreitol were observed. The oxidations of Fe2+ and uroporphyrinogen could be blocked by 1,10-phenanthroline, a ferrous iron chelator. The data suggest that ferrous is the reactive form of iron that may contribute to pathogenic development of the disease by irreversibly oxidizing the porphyrinogen substrates to nonmetabolizable porphyrins, which accumulate in porphyric liver.     

Uroporphyrinogen decarboxylase. Purification, properties, and inhibition by polychlorinated biphenyl isomers

Uroporphyrinogen decarboxylase (EC 4.1.1.37) which converts uroporphyrinogen I or III into coproporphyrinogen I or III, respectively, was purified about 5,500-fold from chicken erythrocytes. Purification was accomplished by chromatography on DEAE-cellulose, ammonium sulfate fractionation, chromatography on Sephadex G-100, and chromatofocusing. The most purified preparation was homogeneous on polyacrylamide gel electrophoresis and had a specific activity of 1,420 units/mg of protein, the highest value so far reported. The molecular weight, as determined by Sephadex G-150 gel chromatography, is 79,000. The subunit molecular weight, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, is 39,700, suggesting that uroporphyrinogen decarboxylase is dimeric in form. The purified enzyme had an isoelectric point of 6.2 and a pH optimum of 6.8. The SH reagents inhibited the enzyme activity, but neither metal ions nor cofactor requirements could be demonstrated. A new and simple method for the separation of free uroporphyrin, hepta-, hexa-, and pentacarboxylic porphyrins and coproporphyrin was developed using a high pressure liquid chromatograph equipped with a spectrofluorometric detector. Kinetic studies of the sequential decarboxylation of uroporphyrinogen with purified enzyme were performed. 3,4,3',4'-Tetrachlorobiphenyl and 3,4,5,3',4'5'-hexachlorobiphenyl which specifically induce delta-aminolevulinic acid synthetase also strongly inhibit uroporphyrinogen decarboxylase directly at two steps, i.e. first in the formation of hexacarboxylic porphyrinogen III from heptacarboxylic porphyrinogen III and second in the formation of heptacarboxylic porphyrinogen III from uroporphyrinogen III.     

Purification and characterization of S-adenosyl-L-methionine: uroporphyrinogen III methyltransferase from Pseudomonas denitrificans.

S-Adenosyl-L-methionine:uroporphyrinogen III methyltransferase (SUMT), the enzyme of the cobalamin biosynthetic pathway which catalyzes C methylation of uroporphyrinogen III, was purified about 150-fold to homogeneity from extracts of a recombinant strain of Pseudomonas denitrificans derived from a cobalamin-overproducing strain by ammonium sulfate fractionation, anion-exchange chromatography, and hydroxyapatite chromatography. The purified protein has an isoelectric point of 6.4 and molecular weights of 56,500 as estimated by gel filtration and 30,000 as estimated by gel electrophoresis under denaturing conditions, suggesting that the active enzyme is a homodimer. It does not contain a chromophoric prosthetic group and does not seem to require metal ions or cofactors for activity. SUMT catalyzes the two successive C-2 and C-7 methylation reactions involved in the conversion of uroporphyrinogen III to precorrin-2 via the intermediate formation of precorrin-1. In vitro studies suggest that the intermediate monomethylated product (precorrin-1) is released from the protein and then added back to the enzyme for the second C-methylation reaction. The pH optimum was 7.7, the Km values for S-adenosyl-L-methionine and uroporphyrinogen III were 6.3 and 1.0 microM, respectively, and the turnover number was 38 h-1. The enzyme activity was shown to be completely insensitive to feedback inhibition by cobalamin and corrinoid intermediates tested at physiological concentration. At uroporphyrinogen III concentrations above 2 microM, SUMT exhibited a substrate inhibition phenomenon. It is suggested that this property might play a regulatory role in cobalamin biosynthesis in the cobalamin-overproducing strain studied.     

Biosynthesis of uroporphyrinogens from porphobilinogen: mechanism and the nature of the process.

The enzymic self-polymerization of prophobilinogen gives rise to the cyclic tetrapyrroles uroporphyrinogen III and uroporphyrinogen I. The former is the precursor of all the natural porphyrins and chlorins. The formation of uroporphyrinogen III is catalysed by a dual enzymic system, porphobilinogen deaminase and uroporphyrinogen III cosynthase. Deaminase polymerizes four porphobilinogen units on the enzymic surface, without liberation of free intermediates into the reaction medium, and forms uroporphyrinogen I. Cosynthase enters into association with the deaminase, and acts as a 'specifier protein' of the latter, changing the mode of porphobilinogen condensation on the enzymic surface. The association is independent of the presence of substrate. While deaminase catalyses the head-to-tail condensation of the porphobilinogen units, the association deaminase-cosynthase catalyses the head-to-head condensation of the same units. As a result different enzyme-bound dipyrrylmethanes are formed form the beginning of the process, and this can be demonstrated by using synthetic dipyrrylmethanes and tripyrranes.     

Purification and characterization of bovine hepatic uroporphyrinogen decarboxylase

Uroporphyrinogen decarboxylase (EC 4.1.1.37) has been purified to homogeneity from bovine liver by using isoelectric and salt precipitations, followed by chromatography on DEAE-cellulose, phenyl-Sepharose, hydroxylapatite, and Sephacryl S-200. The purified enzyme is a monomer with an Mr approximately 57 000 and an isoelectric point at pH 4.6. Enzyme activity is optimal in buffers having an ionic strength of approximately 0.1 M and a pH of 6.8. The purified enzyme has a specific activity (expressed as the disappearance of uroporphyrinogen I) of 936 nmol X h-1 X (mg of protein)-1. The purified enzyme catalyzes all four decarboxylation reactions in the conversion of uroporphyrinogen I or III to the corresponding coproporphyrinogen. The rate-limiting step in the physiologically significant conversion of uroporphyrinogen III to coproporphyrinogen III is the decarboxylation of heptacarboxylate III. Kinetic data suggest that the enzyme has at least two noninteracting active sites. At least one sulfhydryl group is required for catalytic activity. The enzyme is inhibited by sulfhydryl-specific reagents and by divalent metal ions including Fe2+, Co2+, Cu2+, Zn2+, and Pb2+. The pattern of accumulation of intermediate (hepta-, hexa-, and pentacarboxylate porphyrinogens) and final (coproporphyrinogen) decarboxylation products is affected by the ratio of substrate (uroporphyrinogen I or III) concentration to enzyme concentration. Under physiologic conditions where the uroporphyrinogen to enzyme ratio is low, the substrate is nearly quantitatively decarboxylated, and the major product is coproporphyrinogen. If the ratio of uroporphyrinogen to enzyme is high, intermediates accumulate, and heptacarboxylate porphyrinogen becomes the major decarboxylation product.(ABSTRACT TRUNCATED AT 250 WORDS)     

On uroporphyrinogen formation: Studies with 1-aminomethyl-3, 8, 13, 18-tetra(2-carboxyethyl)-2, 7, 12, 17-tetracarboxymethylbilinogen (author's transl)]

The preparation of the aminomethyl-bilinogen which results from formal "head to tail" condensation of porphobilinogen is described. The chemical cyclocondensation of this compound at pH 7.4 yields uroporphyrinogen I. Enzymatic studies with enzyme preparations from Propionibacterium shermanii, which synthesize uroporphyrinogens from porphobilinogen, show that the rate of cyclisation is increased by these enzymes and indicate that the bilinogen also might be used for uroporphyrinogen III formation. This is also suggested by studies on the formation of cobyrinic acid from [4-14C]5-aminolevulinate via uroporphyrinogen III in the presence of the aminomethylbilinogen by cell-free extracts from Clostridium tetanomorphum.     

Decarboxylation of porphyrinogens by rat liver uroporphyrinogen decarboxylase.

The decarboxylations of uroporphyrinogens I and III and of heptacarboxylic, hexacarboxylic and pentacarboxylic porphyrinogens III by rat liver uroporphyrinogen decarboxylase were compared, and the results suggest that the removal of the first carboxy group from uroporphyrinogen III is a more rapid step than that from isomer I or the other substrates investigated.     

Purification, characterization, and molecular cloning of S-adenosyl-L-methionine: uroporphyrinogen III methyltransferase from Methanobacterium ivanovii.

An S-adenosyl-L-methionine:uroporphyrinogen III methyltransferase (SUMT) activity has been identified in Methanobacterium ivanovii and was purified 4,500-fold to homogeneity with a 38% yield. The enzyme had an apparent molecular weight of 58,200 by gel filtration and consisted of two identical subunits of Mr 29,000, as estimated by gel electrophoresis under denaturing conditions. The Km value for uroporphyrinogen III was 52 nM. The enzyme catalyzed the two C-2 and C-7 methylation reactions converting uroporphyrinogen III into precorrin-2. Unlike Pseudomonas denitrificans SUMT, the only SUMT characterized to date (F. Blanche, L. Debussche, D. Thibaut, J. Crouzet and B. Cameron, J. Bacteriol. 171:4222-4231, 1989), M. ivanovii SUMT did not show substrate inhibition at uroporphyrinogen III concentrations of up to 20 microM. Oligonucleotide probes from limited peptide sequence information were used to clone the corresponding gene. The encoded polypeptide showed more than 40% strict homology with P. denitrificans SUMT. The M. ivanovii SUMT structural gene is likely to be, as is P. denitrificans cobA, involved in corrinoid synthesis.     

Investigations of rat liver uroporphyrinogen decarboxylase. Comparisons of porphyrinogens I and III as substrates and the inhibition by porphyrins.

1. The decarboxylations of uroporphyrinogens, hepta-, hexa- and penta-carboxyporphyrinogens I and III by porphyrinogen carboxy-lyase (EC 4.1.1.37) in rat liver supernatant have been compared as functions of substrate concentrations. Although Km and Vmax. (for total porphyrinogens formed) were estimated, prophyrinogens and CO2 produced at 1 microM were considered to be a better indication of real relative rates, owing to substrate/product inhibitions. Uroporphyrinogen III was the best substrate by the criteria of Km/Vmax. and decarboxylation at 1 microM and was converted into coproporphyrinogen more quickly than its series-I isomer. 2. The difference between uroporphyrinogens I and III as substrates was confirmed by using a mixture of [14C8]uroporphyrinogens, the discrimination occurring principally in the first decarboxylation. 3. Porphyrins, especially oxidation products of the substrates, inhibited the enzyme. Heptacarboxyporphyrin III was the most effective inhibitor of both uroporphyrinogen III and heptacarboxyporphyrinogen III conversion into coproporphyrinogen. 4. Rapid analysis of the livers from rats made porphyric with hexachlorobenzene demonstrated that substantial quantities of the tetrapyrroles were present in vivo as the porphyrinogens (21-42%). 5. Enzymic decarboxylation of uroporphyrinogen III in 2H2O-containing buffer gave [2H4]coproporphyrinogen. 6. Rats treated with cycloheximide for 10h showed no decrease in uroporphyrinogen decarboxylase activity/mg of protein, suggesting a relatively slow turnover of the enzyme.     

Biosynthesis of porphyrins. II

A mechanism for the biosynthesis of uroporphyrinogen III, consistent with recent experimental results is proposed as follows: Four porphobilinogen (PBG) units form a chain by a succession of rearrangements of a methylene group derived from the unit which ultimately becomes ring D. Three PBG units (rings A, B, C) are incorporated intact. The methylene group is anchored to the enzyme during three condensations and rearrangements until cyclization of the tetrapyrrole chain produces uroporphyrinogen III.     

Structural diversity in metal ion chelation and the structure of uroporphyrinogen III synthase

All tetrapyrroles are synthesized through a branched pathway, and although each tetrapyrrole receives unique modifications around the ring periphery, they all share the unifying feature of a central metal ion. Each pathway maintains a unique metal ion chelatase, and several tertiary structures have been determined, including those of the protoporphyrin ferrochelatase from both human and Bacillus subtilus, and the cobalt chelatase CbiK. These enzymes exhibit strong structural similarity and appear to function by a similar mechanism. Met8p, from Saccharomyces cerevisiae, catalyses ferrochelation during the synthesis of sirohaem, and the structure reveals a novel chelatase architecture whereby both ferrochelation and NAD(+)-dependent dehydrogenation take place in a single bifunctional active site. Asp-141 appears to participate in both catalytic reactions. The final common biosynthetic step in tetrapyrrole biosynthesis is the generation of uroporphyrinogen by uroporphyrinogen III synthase, whereby the D ring of hydroxymethylbilane is flipped during ring closure to generate the asymmetrical structure of uroporphyrinogen III. The recently derived structure of uroporphyrinogen III synthase reveals a bi-lobed structure in which the active site lies between the domains.     

Porphobilinogen deaminase and uroporphyrinogen III synthase: Structure,molecular biology,and mechanism

Porphobilinogen deaminase (hydroxymethylbilane synthase) and uroporphyrinogen III synthase (uroporphyrinogen III cosynthase) catalyze the transformation of four molecules of porphobilinogen, via the 1-hydroxymethylbilane, preuroporphyrinogen, into uroporphyrinogen III. A combination of studies involving protein chemistry, molecular biology, site-directed mutagenesis, and the use of chemically synthesized substrate analogs and inhibitors is helping to unravel the complex mechanisms by which the two enzymes function. The determination of the X-ray structure ofE. coli porphobilinogen deaminase at 1.76 Å resolution has provided the springboard for the design of further experiments to elucidate the precise mechanism for the assembly of both the dipyrromethane cofactor and the tetrapyrrole chain. The human deaminase structure has been modeled from theE. coli structure and has led to a molecular explanation for the disease acute intermittent porphyria. Molecular modeling has also been employed to simulate the spiro-mechanism of uroporphyrinogen III synthase.