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.     

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.     

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.     

The common origins of the pigments of life—early steps of chlorophyll biosynthesis

The complex pathway of tetrapyrrole biosynthesis can be dissected into five sections: the pathways that produce 5-aminolevulinate (the C-4 and the C-5 pathways), the steps that transform ALA to uroporphyrinogen III, which are ubiquitous in the biosynthesis of all tetrapyrroles, and the three branches producing specialized end products. These end products include corrins and siroheme, chlorophylls and hemes and linear tetrapyrroles. These branches have been subjects of recent reviews. This review concentrates on the early steps leading up to uroporphyrinogen III formation which have been investigated intensively in recent years in animals, in plants, and in a wide range of bacteria.Abbreviations ALA 5-aminolevulinic acid - ALAS 5-aminolevulinic acid synthase - GR glutamyl-tRNA reductase - GSA glutamate-1-semialdehyde - GSAT glutamate-1-semialdehyde aminotransferase - HMB hydroxymethylbilane - PBG porphobilinogen - PBGD porphobilinogen deaminase - PBGS porphobilinogen synthase - URO uroporphyrin - URO'gen uroporphyrinogen - US uroporphyrinogen III synthase     

Involvement of free and enzyme-bound intermediates in the reaction mechanism catalyzed by the bovine liver immobilized porphobilinogen deaminase. Proof that they are substrates for cosynthetase in uroporphyrinogen III biosynthesis

The detection and accumulation of tetrapyrrole intermediates synthesized by the action of bovine liver porphobilinogen deaminase immobilized to Sepharose 4B is reported. Employing Sepharose-deaminase preparations, two phases in uroporphyrinogen I synthesis as a function of time were observed, suggesting the accumulation of free and enzyme-bound intermediates, the concentration and distribution of which were time dependent. The deaminase-bound intermediate behaves as a substrate in uroporphyrinogen I synthesis whereas the free intermediates produce enzyme inhibition. The tetrapyrrole intermediate bound to the Sepharose-enzyme is removed from the protein by the binding of porphobilinogen. Free as well as enzyme-bound intermediates are shown to be substrates for cosynthetase with formation of 80% uroporphyrinogen III.     

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.     

Chemistry of porphyrin biosynthesis: Results and applications

• 1.1. Pairs of suitable mono-, di-, and tripyrroles, differently labeled with ¹⁴C and ³H, were submitted to in vivo incorporation into heme in competition experiments. It turned out that the di- and tripyrroles, in striking contrast to porphobilinogen and uroporphyrinogen III compete little with the intermediates bound to the enzyme. Some inspecifity of the enzyme system is indicated by similarity of the low but significant incorporation of different di- and tripyrroles.
• 2.2. Systematic investigation of the in vitro condensation of porphobilinogen derivatives under conditions of kinetic control revealed that the ratio of uroporphyrinogen I in the reaction mixture dropped steadily in favour of the III/IV isomers with increasing acidity. A mechanistic explanation is given, by which the formation of the biologically essential uroporphyrinogen III appears less cryptic than assumed before.
• 3.3. Derivatives of nor- and homoporphobilinogen with equal side chains, provided by convenient syntheses, gave porphyrins by biomimetic condensation in high yields. Among these porphyrins are useful model compounds, as well as novel nonplanar porphyrins and porphyrinogens with remarkable properties.

     

Mapping the uroporphyrinogen III cosynthase locus in Bacillus subtilis.

Summary The gene hemD taking part in the formation of uroporphyrinogen III from porphobilinogen was mapped by two-and three-factor transduction crosses in Bacillus subtilis. This gene codes uroporphyrinogen III cosynthase. The gene hemD is linked to the hemA locus and is located between the hemA and pheA loci.     

Biosynthesis of glycoproteins in Candida albicans: Processing of a Man6-GlcNAc2-Asn oligosaccharide by membrane fractions

Abstract Bacillus subtilis can synthesise cytochromes containing a -, b -, c - and d -type heme. The biosynthetic pathways of these heme prosthetic groups were investigated by using strains blocked in uroporphyrinogen III synthesis from porphobilinogen or in heme b (protoheme IX) synthesis from uroporphyrinogen III. The results strongly suggest that heme a and heme d are both synthesised from heme b (protoheme IX). They also indicate that B. subtilis contains a novel ferrochelatase involved in the synthesis of siroheme.     

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.     

Biosynthesis of porphyrins and corrins. 1. 1H and 13C NMR spectra of (hydroxymethyl)bilane and uroporphyrinogens I and III

High-field NMR spectroscopic methods have been applied to study the reactions catalyzed by porphobilinogen (PBG) deaminase and uroporphyrinogen III (uro'gen III) cosynthase, which are the enzymes responsible for the formation of the porphyrin macrocycle. The action of these enzymes in the conversion of PBG, [2,11-13C]PBG, and [3,5-13C]PBG to uro'gens I and III has been followed by 1H and 13C NMR, and assignments are presented. The principal intermediate that accumulated was the correspondingly labeled (hydroxymethyl)bilane (HMB), the assignments for which are also presented.     

Unique properties of Plasmodium falciparum porphobilinogen deaminase

The hybrid pathway for heme biosynthesis in the malarial parasite proposes the involvement of parasite genome-coded enzymes of the pathway localized in different compartments such as apicoplast, mitochondria, and cytosol. However, knowledge on the functionality and localization of many of these enzymes is not available. In this study, we demonstrate that porphobilinogen deaminase encoded by the Plasmodium falciparum genome (PfPBGD) has several unique biochemical properties. Studies carried out with PfPBGD partially purified from parasite membrane fraction, as well as recombinant PfPBGD lacking N-terminal 64 amino acids expressed and purified from Escherichia coli cells (DeltaPfPBGD), indicate that both the proteins are catalytically active. Surprisingly, PfPBGD catalyzes the conversion of porphobilinogen to uroporphyrinogen III (UROGEN III), indicating that it also possesses uroporphyrinogen III synthase (UROS) activity, catalyzing the next step. This obviates the necessity to have a separate gene for UROS that has not been so far annotated in the parasite genome. Interestingly, DeltaPfP-BGD gives rise to UROGEN III even after heat treatment, although UROS from other sources is known to be heat-sensitive. Based on the analysis of active site residues, a DeltaPfPBGDL116K mutant enzyme was created and the specific activity of this recombinant mutant enzyme is 5-fold higher than DeltaPfPBGD. More interestingly, DeltaPfPBGDL116K catalyzes the formation of uroporphyrinogen I (UROGEN I) in addition to UROGEN III, indicating that with increased PBGD activity the UROS activity of PBGD may perhaps become rate-limiting, thus leading to non-enzymatic cyclization of preuroporphyrinogen to UROGEN I. PfPBGD is localized to the apicoplast and is catalytically very inefficient compared with the host red cell enzyme.     

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.     

Labeling of porphobilinogen deaminase by radioactive 5-aminolevulinic acid in isolated developing pea chloroplasts

A protein had been previously described, which was labeled by radioactive 5-aminolevulinic acid in isolated developing chloroplasts. In the present study we have shown that this protein (Mr approximately equal to 43,000) probably exists as a monomer in the chloroplast stroma. The labeling is blocked if known inhibitors of 5-aminolevulinic acid dehydratase are added to the incubation mixture, and is markedly decreased in intensity if nonradioactive 5-aminolevulinate or porphobilinogen are added to the incubation mixture; other intermediates in the porphyrin biosynthetic pathway, uroporphyrinogen III, uroporphyrin III, and protoporphyrin IX, do not decrease the labeling of the 43-kDa protein appreciably. Nondenaturing gels of the proteins isolated from the incubation with radioactive 5-aminolevulinic acid were stained for porphobilinogen deaminase activity. A series of red fluorescent bands was obtained which coincided with the radioactive bands visualized by autoradiography. It is concluded that the soluble chloroplast protein that is labeled in organello by radioactive 5-aminolevulinic acid is porphobilinogen deaminase.     

The Escherichia coli cysG gene encodes S-adenosylmethionine-dependent uroporphyrinogen III methylase.

The Escherichia coli cysG gene was successfully subcloned and over-expressed to produce a 52 kDa protein that was purified to homogeneity. This protein was shown to catalyse the S-adenosylmethionine-dependent methylation of uroporphyrinogen III to give a product identified as sirohydrochlorin on the basis of its absorption spectra, incorporation of 14C label from S-adenosyl[Me-14C]methionine and mass and 1H-n.m.r. spectra of its octamethyl ester. Further confirmation of the structure was obtained from a 14C-n.m.r. spectrum of the methyl ester produced by incubation of the methylase with uroporphyrinogen III, derived from [4.6-13C2]porphobilinogen, and S-adenosyl[Me-13C]methionine.     

Tissue-specific expression of porphobilinogen deaminase. Two isoenzymes from a single gene

Porphobilinogen deaminase (hydroxymethylbilane synthase; EC 4.3.1.8), the third enzyme of the heme biosynthetic pathway, catalyzes the stepwise condensation of four porphobilinogen units to yield hydroxymethylbilane, which is in turn converted to uroporphyrinogen III by cosynthetase. We compared the apparent molecular mass of porphobilinogen deaminase from erythropoietic and from non-erythropoietic cells by sodium dodecyl sulfate/polyacrylamide gel electrophoresis and immune-blotting. The results indicate that two isoforms of porphobilinogen deaminase can be distinguished and differ by 2000 Da. Analysis of cell-free translation products directed by mRNAs from human erythropoietic spleen and from human liver demonstrates that the two isoforms of porphobilinogen deaminase are encoded by distinct messenger RNAs. We cloned and sequenced cDNAs complementary to the non-erythropoietic form of porphobilinogen deaminase encoding RNA. Comparison of these sequences to that of human erythropoietic mRNA [Raich et al. (1986) Nucleic Acids Res. 14, 5955-5968] revealed that the two mRNA species differ by their 5' extremity. From the mRNA sequences we could deduce that an additional peptide of 17 amino acid residues at the NH2 terminus of the non-erythropoietic isoform of porphobilinogen deaminase accounts for its higher molecular mass. RNase mapping experiments demonstrate that the two porphobilinogen deaminase mRNAs are distributed according to a strict tissue-specificity, the erythropoietic form being restricted to erythropoietic cells. We propose that a single porphobilinogen deaminase gene is transcribed from two different promoters, yielding the two forms of porphobilinogen deaminase mRNAs. Our present finding may have some relevance for further understanding the porphobilinogen deaminase deficiency in certain cases of acute intermittent porphyria with an enzymatic defect restricted in non-erythropoietic cells.     

Biosynthesis of porphyrins and corrins.

Haem, chlorophyll and vitamin B12 are all derived ultimately from four molecules of the pyrrole porphobilinogen (PBG) and the initial enzyme catalysed condensation of PBG leads to the unsymmetrical type III isomer of uroporphyrinogen. On the basis of straightforward chemical considerations the type I isomer should be formed and so the porphyrinogen-forming enzymes of all living systems must catalyse a highly specific rearrangement process. The nature and chemical mechanism of this rearrangement poses one of the most fascinating problems in the porphyrin field and so it is not surprising that over 20 hypothetical schemes have been proposed to account for it. Analysis of the problem suggested that the incorporation of doubly 13C-labelled precursors into the rearranged macrocyclic rings would give valuable new information on the nature of the rearrangement process. In this approach the meso=bridge atoms are of crucial importance, and several unambiguous syntheses of 13C-labelled pyrroles and porphyrins were developed to allow rigorous n.m.r. assignments to be made, and also to provide substrates for enzymic experiments. Studies carried out with enzymes from both avian blood and from Euglena gracilis have revealed the precise nature of the assembly of four PBG molecules into the type-III macrocycle: it is the same in both systems despite their vastly different evolutionary development. Complementary studies are in progress in order to determine the intermediates involved in the conversion of PBG into uroporphyrinogen III. The synthesis of amino methyl pyrromethanes and their interaction in the presence of PBG with the appropriate enzyme systems are described. It is important for the work to be able to separate not only isomeric pyrromethanes but also the four isomeric coproporphyrins. Powerful methods are described which make use of high pressure liquid chromatography for both types of separation process. Once uroporhyrinogen III has been built enzymically, there is a stepwise enzymic decarboxylation of the four acetic acid residues. A heptacarboxylic porphyrin shown to be a type-III porphyrin is isolated from the action of avian blood enzymes on porphobilinogen. Spectroscopic studies with 13C-labelling limit the possible structures to two and total synthesis of these substances shows that the natural product carries its methyl group on ring D. An isomeric heptacarboxylic porphyrin having its methyl group on ring C is of particular interest in relation to the biosynthesis of vitamin B12. This substance is synthesized together with uroporphyrin III, 14C-labelled specifically in ring C. This latter product is used to settle one of the key questions concerning nature's route to vitamin B12 - that is, does the corrin macrocycle arise from uroporphyrinogen III? Incorporation studies and specific degradations prove specific incorporation of uroporphyrinogen III into cobyrinic acid, which is the known precursor of vitamin B12.     

The Bacillus subtilis hemAXCDBL gene cluster, which encodes enzymes of the biosynthetic pathway from glutamate to uroporphyrinogen III.

We have recently reported (M. Petricek, L. Rutberg, I. Schr?der, and L. Hederstedt, J. Bacteriol. 172: 2250-2258, 1990) the cloning and sequence of a Bacillus subtilis chromosomal DNA fragment containing hemA proposed to encode the NAD(P)H-dependent glutamyl-tRNA reductase of the C5 pathway for 5-aminolevulinic acid (ALA) synthesis, hemX encoding a hydrophobic protein of unknown function, and hemC encoding hydroxymethylbilane synthase. In the present communication, we report the sequences and identities of three additional hem genes located immediately downstreatm of hemC, namely, hemD encoding uroporphyrinogen III synthase, hemB encoding porphobilinogen synthase, and hemL encoding glutamate-1-semialdehyde 2,1-aminotransferase. The six genes are proposed to constitute a hem operon encoding enzymes required for the synthesis of uroporphyrinogen III from glutamyl-tRNA. hemA, hemB, hemC, and hemD have all been shown to be essential for heme synthesis. However, deletion of an internal 427-bp fragment of hemL did not create a growth requirement for ALA or heme, indicating that formation of ALA from glutamate-1-semialdehyde can occur spontaneously in vivo or that this reaction may also be catalyzed by other enzymes. An analysis of B. subtilis carrying integrated plasmids or deletions-substitutions in or downstream of hemL indicates that no further genes in heme synthesis are part of the proposed hem operon.     

Uroporphyrin-accumulating mutant of Escherichia coli K-12.

An uroporphyrin III-accumulating mutant of Escherichia coli K-12 was isolated by neomycin. The mutant, designated SASQ85, was catalase deficient and formed dwarf colonies on usual media. Comparative extraction by cyclohexanone and ethyl acetate showed the superiority of the former for the extraction of the uroporphyrin accumulated by the mutant. Cell-free extracts of SASQ85 were able to convert 5-aminolevulinic acid and porphobilinogen to uroporphyrinogen, but not to copro- or protoporphyrinogen. Under the same conditions cell-free extracts of the parent strain converted 5-aminolevulinic to uroporphyringen, coproporphyrinogen, and protoporphyrinogen. The conversion of porphobilinogen to uroporphyrinogen by cell-free extracts of the mutant was inhibited 98 and 95%, respectively, by p-chloromercuribenzoate and p-chloromercuriphenyl-sulfonate, indicating the presence of uroporphyrinogen synthetase activity in the extracts. Spontaneous transformation of porphobilinogen to uroporphyrin was not detectable under the experimental conditions used [4 h at 37 C in tris(hydroxymethyl)aminomethane-potassium phosphate buffer, pH 8.2]. The results indicate a deficient uroporphyrinogen decarboxylase activity of SASQ85 which is thus the first uroporphyrinogen decarboxylase-deficient mutant isolated in E. coli K-12. Mapping of the corresponding locus by P1-mediated transduction revealed the frequent joint transduction of hemE and thiA markers (frequency of co-transduction, 41 to 44%). The results of the genetic analysis suggest the gene order rif, hemE, thiA, metA; however, they do not totally exclude the gene order rif, thiA, hemE, metA.     

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.