Synthetic and biosynthetic studies of porphyrins

Normal and abnormal heme biosynthesis. Part 7. Synthesis and metabolism of coproporphyrinogen-III analogues with acetate or butyrate side chains on rings C and D. Development of a modified model for the active site of coproporphyrinogen oxidase

Analogues of coproporphyrinogen-III have been prepared with acetate or butyrate groups attached to the C and D pyrrolic subunits. The corresponding porphyrin methyl esters were synthesized by first generating a,c-biladienes by reacting a dipyrrylmethane with pyrrole aldehydes in the presence of HBr. Cyclization with copper(II) chloride in DMF, followed by demetalation with 15% H(2)SO(4)-TFA and reesterification, gave the required porphyrins in excellent yields. Hydrolysis with 25% hydrochloric acid and reduction with sodium-amalgam gave novel diacetate and dibutyrate porphyrinogens 9. Diacetate 9a was incubated with chicken red cell hemolysates (CRH), but gave complex results due to the combined action of two of the enzymes present in these preparations. Separation of uroporphyrinogen decarboxylase (URO-D) from coproporphyrinogen oxidase (CPO) allowed the effects of both enzymes on the diacetate substrate to be assessed. Porphyrinogen 9a proved to be a relatively poor substrate for CPO compared to the natural substrate coproporphyrinogen-III, and only the A ring propionate moiety was processed to a significant extent. Similar results were obtained for incubations of 9a with purified human recombinant CPO. Diacetate 9a was also a substrate for URO-D and a porphyrinogen monoacetate was the major product in this case; however, some conversion of a second acetate unit was also evident. The dibutyrate porphyrinogen 9b was only recognized by the enzyme CPO, but proved to be a modest substrate for incubations with CRH. However, 9b was an excellent substrate for purified human recombinant CPO. The major product for these incubations was a monovinylporphyrinogen, but some divinyl product was also generated in incubations using purified recombinant human CPO. The incubation products were converted into the corresponding porphyrin methyl esters, and these were characterized by proton NMR spectroscopy and mass spectrometry. The results extend our understanding of substrate recognition and catalysis for this intriguing enzyme and have allowed us to extend the active site model for CPO. In addition, the competitive action of both URO-D and CPO on the same diacetate porphyrinogen substrate provides additional perspectives on the potential existence of abnormal pathways for heme biosynthesis.

Hexachlorobenzene treatment on hepatic mitochondrial function parameters and intracellular coproporphyrinogen oxidase location

These studies try to elucidate why isocoproporphyrin appears in hexachlorobenzene-poisoned rats' feces. Chronic exposure of hexachlorobenzene to rats produces an experimental model for human porphyria cutanea tarda. After 8 weeks of treatment, rats showed high porphyrin excreta and 50% inhibition of liver uroporphyrinogen decarboxylase activity. Uroporphyrin plus heptacarboxylic porphyrin exceeded coproporphyrin in urine, whereas in feces, isocoproporphyrin, from abnormal pentacarboxylic porphyrinogen III oxidative decarboxylation by liver coproporphyrinogen oxidase, became the main porphyrin. Trypsin-treated mitochondria showed that the outer and inner membrane permeability barrier was highly conserved after hexachlorobenzene intoxication. In digitonin-treated hexachlorobenzene mitochondria, coproporphyrinogen oxidase was free in the mitochondrial intermembrane space, whereas in normal mitochondria, 30% to 50% remained anchored to the inner membrane. Hexachlorobenzene led to a decrease in respiratory control and ADP/O ratios (uncoupled mitochondria). Albumin restored oxidative phosphorylation, indicating no irreversible inner membrane damage. Normal and hexachlorobenzene mitochondria oscillatory studies exhibited similar damping factor values, showing that hexachlorobenzene had no significant effect on membrane fluidity and elasticity. Mitochondrial uncoupling could explain the free state of the enzyme within the intermembrane space. The free state of the enzyme makes it more flexible and would allow pentacarboxylic porphyrinogen III, whose levels are increased, to compete with coproporphyrinogen III and being transformed into dehydroisocoproporphyrinogen, the liver forerunner of fecal isocoproporphyrin.

The modification of acetate and propionate side chains during the biosynthesis of haem and chlorophylls: mechanistic and stereochemical studies

In the conversion of uroporphyrinogen III into protoporphyrin IX and thence into chlorophylls, all eight carboxylic side chains, as well as the four meso positions, are modified, and four enzymes are involved. In the uroporphyrinogen decarboxylase-catalysed reaction all four acetate side chains are converted into methyl groups by the same mechanism, to produce coproporphyrinogen III. Both methylene hydrogen atoms remain undisturbed and the reaction occurs with the retention of stereochemistry. Several questions regarding the enzymology of the decarboxylase are posed. Do all the decarboxylations occur at the same active site and, if so, are the four acetate chains handled in a particular sequence? Is the decarboxylation reaction aided by the transient formation of an electron-withdrawing functionality in the pyrrole ring? Coproporphyrinogen oxidase converts the two propionate side chains of rings A and B into vinyl groups, with an overall anti-periplanar removal of the carboxyl group and the Hsi from the neighbouring position. Evidence is examined to evaluate whether a hydroxylated compound acts as an intermediate in the oxidative decarboxylation reaction. Protoporphyrinogen oxidase then converts the methylene-interrupted macrocycle of protoporphyrinogen IX into a conjugated system. The conversion has been suggested to involve three consecutive dehydrogenation reactions followed by an isomerization step. The face of the macrocycle from which the three meso hydrogen atoms are removed in the dehydrogenation reaction is thought to be opposite to that from which the fourth meso hydrogen is lost during the prototropic rearrangement. In an investigation of the in vivo mechanism for the esterification of the ring D propionic acid group with a C20 isoprenyl group 5-aminolaevulinic acid was labelled with 13C and 18O at C-1 and incorporated into bacteriochlorophyll a. The 18O-induced shift of the 13C resonance in the NMR spectrum showed that both oxygen atoms of the carboxyl group are retained in the ester bond. This and other results suggest that the reaction occurs by the nucleophilic attack of the ring D carboxylate anion on the activated form of an isoprenyl alcohol.

Dihydroxy-, Hydroxyspirolactone-, and Dihydroxyspirolactone-urochlorins Induced by 2,3,7,8-Tetrachlorodibenzo-p-dioxin in the Liver of Mice

Previous work has shown that 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) causes porphyria, enhanced by iron, in C57BL/6J mice with marked accumulation in the liver of uroporphyrin I and III isomers and heptacarboxylic acid III and is one model of human porphyria cutanea tarda. Preliminary examination by HPLC also indicated the presence of some oxygenated side chain uroporphyrin derivatives. Here, the porphyrin constituents of TCDD-induced porphyric liver have been examined by HPLC/electrospray ionization quadrupole time-of-flight mass spectrometry (HPLC/ESI-Q-TOFMS) to characterize the major and minor porphyrins present in hepatic tissue. As well as the major constituents uroporphyrins I and III, we identified the isomers of heptacarboxylic, hexacarboxylic, and pentacarboxylic acid porphyrins arising from intermediates in the stepwise decarboxylation of uroporphyrinogen I and III to coproporphyrinogens. In addition, monohydroxy analogues of uroporphyrin isomers were detected hydroxylated in the acetic acid and beta-positions of propionic acid side chains and in the meso ring position. Of particular note, for the first time for human and experimental porphyrias, we found chlorins (dihydroxy-, hydroxyspirolactone- ,and dihydroxyspirolactone-urochlorins) consistent with those derived from an epoxyurochlorin structure, formed by oxidation of the double bond of a pyrrole ring of uroporphyrinogen I and III isomers. The findings demonstrate that oxygen insertion into the pyrrole rings of uroporphyrinogens occurs under pathological circumstances in vivo and support the evidence for an oxidative cellular environment present in TCDD-treated porphyric tissue.

Metabolism of pentacarboxylate porphyrinogens by highly purified human coproporphyrinogen oxidase: Further evidence for the existence of an abnormal pathway for heme biosynthesis

An abnormal series of porphyrin tetracarboxylic acids known as the isocoproporphyrins, are commonly excreted by patients suffering from the disease porphyria cutanea tarda (PCT). These porphyrins appear to arise by bacterial degradation of dehydroisocoproporphyrinogen that is generated by the premature metabolism of the normal pentacarboxylate intermediate (5dab) by coproporphyrinogen oxidase (copro'gen oxidase). This porphyrinogen can be further metabolized by uroporphyrinogen decarboxylase to give harderoporphyrinogen, one of the usual intermediates in heme biosynthesis. Therefore, it is possible that some of the heme formed under abnormal conditions may originate from the 'isocopro-type' porphyrinogen intermediate. In order to investigate the feasibility of alternative pathways for heme biosynthesis, the four type III pentacarboxylate isomeric porphyrinogens were incubated with purified, cloned human copro'gen oxidase at 37 degrees C with various substrate concentrations under initial velocity conditions. Of the four isomers, only 5dab was a substrate for copro'gen oxidase and this gave dehydroisocoproporphyrin. The structure of the related porphyrin tetramethyl ester was confirmed by proton NMR spectroscopy and mass spectrometry. The K(m) value for proto'gen-IX formation from copro'gen, an indicator of molecular recognition, was similar to the K(m) value for monovinyl product formation with 5dab, although copro'gen-III has an approximately twofold higher K(cat) value. Although 5dab is a slightly poorer substrate than copro'gen-III, these results support the hypothesis that an abnormal route for heme biosynthesis is possible in humans suffering from PCT or related syndromes such as hexachlorobenzene poisoning.

Uroporphyrinogen decarboxylase in Saccharomyces cerevisiae. HEM12 gene sequence and evidence for two conserved glycines essential for enzymatic activity

The HEM12 gene from Saccharomyces cerevisiae encodes uroporphyrinogen decarboxylase which catalyzes the sequential decarboxylation of the four acetyl side chains of uroporphyrinogen to yield coproporphyrinogen, an intermediate in protoheme biosynthesis. The gene was isolated by functional complementation of a hem12 mutant. Sequencing revealed that the HEM12 gene encodes a protein of 362 amino acids with a calculated molecular mass of 41,348 Da. The amino acid sequence shares 50% identity with human and rat uroporphyrinogen decarboxylase and shows 40% identity with the N-terminus of an open reading frame described in Synechococcus sp. We determined the sequence of two hem12 mutations which lead to a totally inactive enzyme. They correspond to the amino acid changes Gly33----Asp and Gly300----Asp, located in two evolutionarily conserved regions. Each of these substitutions impairs binding of substrates without affecting the overall conformation of the protein. These results argue that a single active center exists in uroporphyrinogen decarboxylase.

Assay of mouse liver uroporphyrinogen decarboxylase by reverse-phase high-performance liquid chromatography

A method for the estimation of hepatic uroporphyrinogen decarboxylase activity employing reverse-phase HPLC is described. Mouse liver homogenate in 0.25 M sucrose was pretreated with a suspension of cellulose phosphate and then centrifuged to remove hemoglobin and debris. The supernatant was used as the enzyme source. Incubations were acidified, oxidized, and centrifuged only before analysis of the porphyrins formed, using a Spherisorb ODS column and a gradient solvent system constructed from methanol/lithium citrate mixtures. Coproporphyrinogen formation by BALB/c mouse liver supernatant was estimated as about 5.0 and 9.1 pmol/min/mg protein from uroporphyrinogens I and III, respectively, at 10 microM substrate concentration and pH 6.8. Decarboxylation of pentacarboxyporphyrinogens (the last step in coproporphyrinogen formation) proved to be easily measured. Coproporphyrinogen formation from pentacarboxyporphyrinogen III abd (20 microM) at pH 6.8 was about 109 pmol/min/mg protein. Pentacarboxyporphyrinogen I was not as good a substrate as III abd but was decarboxylated faster at pH 5.4 than at 6.8, and at the lower pH and at 10 microM concentration of substrate 42 pmol of coproporphyrinogen was formed/min/mg protein. These results compared favorably with those obtained by previously published procedures involving time-consuming extraction and esterification steps.