Signal transduction pathways and haem oxygenase induction in soybean leaves subjected to salt stress.

We have previously demonstrated that the induction of haem oxygenase-1 (EC 1.14.99.3) plays a protective role for soybean plants against cadmium and UV-B stress. Here, we have investigated the possible signal transduction pathways involved in haem oxygenase-1 induction in leaves of soybean plants subjected to salt stress. Treatment with 100 mM NaCl during 48 h increased thiobarbituric acid reactive substances by 30%, whereas GSH decreased by 50%, with respect to controls. These effects were prevented by pre-incubation with diphenyleneiodonium (DPI; an NADPH oxidase inhibitor), [1,2,4]oxadiazolo-[4,3-a]quinoxalin-1-one (ODQ; a guanylate cyclase inhibitor) or LaCl3 (calcium channel blocker). NaCl at 100 mM produced in situ accumulation of H2O2 and O2*-, which were also prevented by DPI, ODQ or LaCl3. Moreover, salt-induced haem oxygenase-1 activity was also totally abolished by pretreatment with the different inhibitors. These results clearly demonstrated that the signal transduction pathways involved in oxidative stress triggered by salt stress were similar to those implicated in haem oxygenase-1 induction, and provide additional information suggesting that haem oxygenase might play a key role in the antioxidative protection machinery of higher plants.

Polyamine metabolism in sunflower plants under long-term cadmium or copper stress.

The effect of different doses of cadmium and copper was studied in relation to growth and polyamine (Pas) metabolism in shoots of sunflower plants. Cadmium accumulated to higher levels than copper and shoot length was reduced by 0.5 and 1 mM Cd, but only by 1 mM Cu. At 1 mM of Cd or Cu, Put content increased 270% and 160% with Cd2+ and Cu2+, respectively. Spermidine (Spd) was modified only by 1 mM Cd, while spermine (Spm) declined after seeds germinated, increasing thereafter but only with 1 mM Cd or Cu (273% over the controls for Cd and 230% for Cu at day 16). Both ADC and ODC activities were increased by 1 mM Cd, whereas 1 mM Cu enhanced ADC activity, but reduced ODC activity at every concentration used. The role of Pas as markers of Cd or Cu toxicity is discussed.

Role of heme oxygenase/carbon monoxide pathway on the vascular response to noradrenaline in portal hypertensive rats.

1. Portal hypertension (PH), a major syndrome in cirrhosis, producing hyperdynamic splanchnic circulation and hyperaemia. In order to elucidate the contribution of heme oxygenase to the vascular hyporeactivity, we assessed the activity of heme oxygenase-1 (HO-1), measured the in vivo pressure response to noradrenaline (NA) and investigated the effects of blocking the carbon monoxide (CO) and nitric oxide (NO) pathways in a prehepatic model of PH in rats. 2. Portal hypertension was induced by partial portal vein ligation (PPVL). Noradrenaline was injected intravenously. Liver, spleen and mesentery homogenates were prepared for measurement of HO-1 activity and expression. Four groups of rats were used: (i) a sham group; (ii) a PPVL group; (iii) a sham group pretreated with Zn-protoporphyrin IX (ZnPPIX); and (iv) a PPVL group pretreated with ZnPPIX. Each group was studied before and after treatment with the NO synthase inhibitor N(G)-nitro-L-arginine methyl ester (L-NAME). 3. For basal pressures and the pressure response to NA, inhibition of CO and NO pathways by ZnPPIX and L-NAME, respectively, produced an increase in mean arterial pressure (MAP) in sham-operated and in PH rats. Similarly, when both inhibitors were used together in either sham or PPVL rats, a greater increase in MAP was observed. 4. These results, together with the increased HO-1 activity and expression only in the PH group, have led us to suggest that the heme oxygenase/CO pathway is involved in the vascular response to NA in PH rats.

Bilirubin and ferritin as protectors against hemin-induced oxidative stress in rat liver.

The in vivo effect of hemin on both hepatic oxidative stress and heme oxygenase induction was studied. A marked increase in lipid peroxidation was observed 1 hr after hemin administration. Heme oxygenase-1 activity and expression appeared 6 hr after treatment, reaching a maximum between 12 and 15 hr after hemin administration. Such induction was preceded by a decrease in the soluble and enzymatic defenses, both effects taking place some hours before induction of heme oxygenase. Ferritin content began to increase 6 hr after heme oxygenase induction, and these increases were significantly higher 15 hr after treatment and remained high for at least 24 hr after hemin injection. Co-administration of tin protoporphyrin IX, a potent inhibitor of heme oxygenase, completely prevented the enzyme induction and the increase in ferritin levels, increasing the appearance of oxidative stress parameters. Administration of bilirubin, prevented the heme oxygenase induction as well as the decrease in hepatic GSH and the increase of lipid peroxidation when it was administered 2 hr before hemin treatment. These results indicate that the induction of heme oxygenase by hemin may be a general response to oxidant stress, by increasing bilirubin and ferritin levels and could therefore provide a major cellular defense mechanism against oxidative damage.

Occurrence of cadaverine in hairy roots of Brugmansia candida.

The polyamine, cadaverine, was detected in transformed root cultures of Brugmansia candida (syn. Datura candida), a Solanaceae which produces the tropane alkaloids scopolamine and hyoscyamine. To the best of our knowledge, this is the first time that the existence of this uncommon polyamine has been detected in a Datura species. Cadaverine, however, could not be found in the whole plant. The occurrence of cadaverine in hairy roots could be a consequence of either the transformation or a response to stress. Also, cadaverine could be participating in other secondary pathways rather than to the tropane alkaloids. The common polyamines, putrescine, spermidine and spermine were also observed.

Heme oxygenase induction by menadione bisulfite adduct-generated oxidative stress in rat liver.

The in vivo effect of menadione bisulfite adduct on both hepatic oxidative stress and heme oxygenase induction was studied. A marked increase in lipid peroxidation was observed 1 h after menadione bisulfite adduct administration. To evaluate liver antioxidant enzymatic defenses, superoxide dismutase, catalase and glutathione peroxidase activities were determined. Antioxidant enzymes significantly decreased 3 h after menadione bisulfite adduct injection. Heme oxygenase activity appeared 6 h after treatment, peaking 9 h after menadione bisulfite adduct administration. Such induction was preceded by a decrease in the intrahepatic GSH pool and an increase in hydrogen peroxide steady-state concentration, both effects taking place some hours before induction of heme oxygenase. Iron ferritin levels and ferritin content began to increase 6 h after heme oxygenase induction, and these increases were significantly higher 15 h after treatment and remained high for at least 24 h after menadione bisulfite adduct injection. Administration of bilirubin entirely prevented heme oxygenase induction as well as the decrease in hepatic GSH and the increase in lipid peroxidation when administered 2 h before menadione bisulfite adduct treatment. These results indicate that the induction of heme oxygenase by menadione bisulfite adduct may be a general response to oxidant stress, by increasing bilirubin and ferritin levels and could therefore provide a major cellular defense mechanism against oxidative damage.

Effect of acetaminophen on heme metabolism in rat liver.

BACKGROUND AND AIMS: Acetaminophen (APAP) or paracetamol is a hepatotoxic drug through mechanisms involving oxidative stress. To know whether mammalian cells possess inducible pathways for antioxidant defense, we have to study the relationship between heme metabolism and oxidative stress. METHODS: fasted female Wistar rats received a single injection of APAP (3.3 mmol kg(-1) body weight) and then were killed at different times. Heme oxygenase-1 (HO), delta-aminolevulinic acid (ALA) synthase, ALA dehydratase, and porphobilinogenase activities, lipid peroxidation, GSH, catalase and glutathione peroxidase, were measured in liver homogenates. The antioxidant properties of bilirubin and S-adenosyl-L-methionine were also evaluated. RESULTS: APAP increased lipid peroxidation (115% +/- 6; S.E.M., n=12 over control values) 1 h after treatment. GSH reached a minimum at 3 h (38% +/- 5) increasing thereafter. At the same time antioxidant enzymes reached minimum values (catalase, 5. 6 +/- 0.4 pmol mg(-1) protein, glutathione peroxidase, 0.101 +/- 0.006 U mg(-1) protein). HO induction was observed 6 h after treatment reaching a maximum value of 2.56 +/- 0.12 U mg(-1) protein 15 after injection. ALA synthase (ALA-S) induction occurred after enhancement of HO, reaching a maximum at 18 h (three-fold the control). ALA dehydratase activity was first inhibited (31 +/- 3%) showing a profile similar to that of GSH, while porphobilinogenase activity was not modified along the whole period of the assay. Administration of bilirubin (5 micromol kg(-1) body weight) or S-adenosyl L-methionine (46 micromol kg(-1) body weight) 2 h before APAP treatment entirely prevented the increase in malondialdehyde (MDA) content, the decrease in GSH levels as well as HO and ALA-S induction. CONCLUSION: This study shows that oxidative stress produced by APAP leads to increase in ALA-S and HO activities, indicating that toxic doses of APAP affect both heme biosynthesis and degradation.

Cadmium inhibition of a structural wheat peroxidase.

The major peroxidase from 15-day-old wheat plants was purified to homogeneity by FPLC ion exchange and molecular exclusion chromatography. It consists of a single polypeptide of M(r) 37,500 according to gel filtration and SDS-PAGE and has a pI of 7.0. Kinetics of pyrogallol peroxidation showed that the enzyme follows the accepted mechanism for peroxidase, with kinetic constants k(1) =4.4x10(6) M(-1) s(-1) and k(3) =8.6x10(5) M(-1) s(-1). The effect of different metal ions was assayed on peroxidase activity. None of the ions used had any effect on enzyme activity, except for Cd(II), which was an inhibitor. This was an unexpected and novel finding for a peroxidase. The kinetics of pyrogallol peroxidation at different concentrations of Cd(II) have been studied and a mechanism for Cd(II) inhibition proposed. The results obtained could explain, in part, cadmium-induced oxidative stress.

Heme oxygenase induction by UVA radiation. A response to oxidative stress in rat liver.

Heme oxygenase is a key enzyme for heme catabolism and catalyzes the oxidative degradation of heme to form biliverdin IX alpha, an immediate precursor of bilirubin. In order to shed light on the mechanism by which UVA radiation causes oxidative damage, the relationship between heme oxygenase induction and oxidative stress was studied. HO-1 activity, lipid peroxidation and generation of active oxygen species (H2O2) were measured in rat liver exposed to UVA radiation. Besides, soluble and enzymatic antioxidant defenses (GSH, SOD, CAT and GSH-Px) were determined, while bilirubin antioxidant capacity was also evaluated. UVA radiation markedly increased both lipid peroxidation (180% +/- 7; S.E.M., n = 9 over control value of 0.1 +/- 0.01 nmol MDA/min per mg prot.) and steady state concentration of hydrogen peroxide (4 +/- 0.03 microM; S.E.M., n = 9) 3 h after treatment. At the same time, GSH content decreased to 3.6 +/- 0.2 mumol/g liver (S.E.M., n = 9) increasing thereafter. Antioxidant enzymes reached minimum values 6 h after UVA treatment (SOD: 7.2 +/- 0.2 U/mg protein, CAT: 7.8 +/- 0.2 pmol/mg protein, GSH-Px: 0.088 +/- 0.004 U/mg protein; S.E.M., n = 9), starting to increase 12 h after irradiation. HO-1 induction was observed 6 h after UVA irradiation, reaching a maximum value of 2.5 +/- 0.03 U/mg protein (S.E.M., n = 9) 12 h after treatment, and then declined until it reached control levels 24 h after exposure. Administration of bilirubin 2 h before UVA irradiation, entirely prevented HO-1 induction, the increase in MDA content and the decrease in GSH levels. This study shows that UVA irradiation leads to oxidative stress as evidenced by increased MDA content and H2O2 steady state levels, and depletion of GSH, SOD, CAT and GSH-Px. All these changes produced HO-1 induction. It is concluded that the induction of this enzyme could be a response to oxidative stress, since bilirubin can act as a physiological antioxidant.

Relationship between oxidative stress and heme oxygenase induction by copper sulfate.

The effect of copper sulfate (CuSO4) on both hepatic oxidative stress and heme oxygenase induction was studied. A strong increase in in vivo rat liver chemiluminescence was observed 1 h after Cu(II) administration. To evaluate liver antioxidant enzymatic defenses, superoxide dismutase, catalase, and glutathione peroxidase activities were determined. Catalase and glutathione peroxidase were found to be significantly decreased 5 h after CuSO4 injection. In contrast, superoxide dismutase activity was increased. Heme oxygenase activity appeared 5 h after treatment, reaching a maximum value 18 h after CuSO4 administration. This induction was preceded by a decrease in the intrahepatic GSH pool and an increase in the generation of thiobarbituric acid reactive substances, both effects taking place a number of hours before induction of heme oxygenase. Administration of bilirubin, the end product of heme catabolism in mammals, and alpha-tocopherol, a widely employed antioxidant, completely prevented heme oxygenase induction as well as the decrease in hepatic GSH and the increase in chemiluminescence when administered 2 h before CuSO4 treatment. Under the same experimental conditions, beta-carotene showed a moderate preventive effect on both heme oxygenase induction and oxidative stress parameters. These data obtained with Cu(II) treatment are in agreement with our previous reports suggesting a correlation between heme oxygenase induction and oxidative stress.

Heme oxygenase induction by cadmium chloride: evidence for oxidative stress involvement.

Cadmium chloride (CdCl2), a well-known inducer of heme oxygenase, produced a strong increase in 'in vivo' rat liver chemiluminescence (QLV) 3 h after administration. Heme oxygenase activity increased 5 h after treatment, reaching a maximum value around 12-15 h after CdCl2 administration. Such induction was preceded by a decrease in the intrahepatic GSH pool and an increase in hydrogen peroxide steady-state concentration, both effects taking place several hours before induction of heme oxygenase. The activity of antioxidant enzymes, superoxide dismutase (SOD), catalase (CAT) and glutathione peroxidase (GSH-Px) was found to be significantly decreased 5 h after CdCl2 injection. Administration of bilirubin, the end product of heme catabolism in mammals, and alpha-tocopherol, a widely employed antioxidant, prevented heme oxygenase induction as well as the decrease in hepatic GSH and the increase in chemiluminescence when administered 2 h before CdCl2 treatment. These results obtained with CdCl2 treatment support our recent reports correlating heme oxygenase induction with oxidative stress.

Heme oxygenase and oxidative stress. Evidence of involvement of bilirubin as physiological protector against oxidative damage.

Cobalt chloride (CoCl2), a well-known inducer of heme oxygenase, produced a strong increase of in vivo rat liver chemiluminescence (QLV) 6 h after its administration. The activity of antioxidant enzymes, superoxide dismutase (SOD), catalase (CAT) and glutathione peroxidase (GSH-Px) was found to be significantly decreased 9 h after CoCl2 injection. Heme oxygenase activity increased 9 h after treatment, reaching a maximum value around 18 to 24 h after CoCl2 administration. This induction was preceded by a decrease in the intrahepatic GSH pool and an increase in hydrogen peroxide steady state concentration, both effects taking place several hours before induction of the heme-oxygenase. Co-administration of Sn-protoporphyrin IX, a potent inhibitor of heme oxygenase, completely prevented the enzyme induction, increasing the QLV levels. Administration of bilirubin, the end product of heme catabolism in mammals, prevented the heme oxygenase induction as well as the decrease in hepatic GSH and the increase of chemiluminescence when it was administered 2 h before CoCl2 treatment. These results support the proposal that the induction of heme oxygenase by cobalt chloride may be a general response to oxidant stress and, by increasing bilirubin levels, could constitute an important cellular defense mechanism against oxidative damage.

Heme oxygenase induction by CoCl2, Co-protoporphyrin IX, phenylhydrazine, and diamide: evidence for oxidative stress involvement.

The induction of heme oxygenase in rat liver by cobaltous chloride (CoCl2) and Co-protoporphyrin IX is entirely prevented by the administration of alpha-tocopherol and allopurinol. CoCl2 was converted in the liver into Co-protoporphyrin IX before it induced heme oxygenase activity. Actinomycin and cycloheximide affected to a similar degree the induction of heme oxygenase by both CoCl2 and Co-protoporphyrin IX. Administration of either CoCl2 or Co-protoporphyrin strongly decreased the intrahepatic GSH pool, a decrease which was completely prevented by the administration of either alpha-tocopherol or allopurinol. The latter compounds prevented heme oxygenase induction as well as the decrease in hepatic GSH when administered 2 h before, together with, or 2 h after CoCl2. However, when given 5 h after administration of CoCl2, alpha-tocopherol and allopurinol showed no preventive effect. Similar results were obtained when Co-protoporphyrin IX was used, with the difference that when alpha-tocopherol and allopurinol were given 2 h after administration of the inducer, they showed no protective effect. Phenylhydrazine and diamide also induced heme oxygenase activity in rat liver. This inductive effect was preceded by a decrease in the intrahepatic GSH pool, which took place several hours before induction of the oxygenase. Administration of alpha-tocopherol and allopurinol prevented induction of the oxygenase but had no effect on the decrease in GSH levels. These results suggest that the induction of heme oxygenase by phenylhydrazine and the diamide is preceded by an oxidative stress which very likely originates in the depletion of GSH. The induction of heme oxygenase by hemin was not prevented by administration of alpha-tocopherol or allopurinol. Coprotoporphyrin IX did not affect the pattern of the molecular forms of hepatic biliverdin reductase, at variance with CoCl2, which is known to convert molecular form 1 of the enzyme into molecular form 3.

An analysis of the topography of molecular forms 1 and 3 of rat liver biliverdin reductase using polyclonal antibodies.

Rat liver biliverdin reductase exists in two molecular forms. The major one (molecular form 1) is transformed, under conditions of oxidative stress into another molecular form (molecular form 3) which is an S-S bridged dimer of form 1. The chemical modifications of the thiol, arginine and lysine residues of molecular form 1 which resulted in an inhibition of its catalytic activity did not affect the activity of molecular form 3. Rabbit polyclonal antibodies raised against form 1 did not recognize form 3. This lack of recognition persisted even when the dimer (form 3) was denatured with SDS or urea under non-reductive conditions. Reduction of form 3 with reduced thioredoxin gave the monomeric form 1, which was fully recognized by the antibodies. The latter recognized the biliverdin reductases from rat spleen and kidney to the same extent as they did with form 1. Molecular form 1 was completely inhibited by the addition of the antibodies. This inhibition was prevented by preincubation of the enzyme with either the substrate (biliverdin) or the cosubstrate (NADPH). Preincubation with the latter or with NADP+ (but not with bilirubin) strongly impaired the recognition of form 1 by the antibodies. Modification of the lysine or arginine residues of form 1 which were involved in substrate binding, impaired the interaction of the enzyme with the antibodies. The antisera blocked the enzymatic conversion of form 1 to form 3, but alkylation of the thiol residue involved in this dimerization had no effect on the interaction of form 1 with the antibodies. The lack of recognition of form 3 by the antibodies suggest that the antigenic site of the former becomes buried upon dimerization.

The enzymatic and chemical reduction of extended biliverdins.

The substrate specificity of rat liver biliverdin reductase was probed using helical and extended biliverdins. The former were the ZZZ-all-syn biliverdins IX alpha and IX gamma, and the latter were the 5Z-syn, 10Z-syn, 15Z-anti; 5Z-anti, 10E-anti, 15E-anti biliverdins. It was found that the reduction rates of the biliverdins increased with the progressive stretching of their conformations. The most extended biliverdin was reduced at a higher rate than biliverdin IX alpha. The chemical reduction rates to bilirubins followed a similar pattern. Nucleophilic addition of 2-mercaptoethanol to the C10 methine was also favored in the extended biliverdins.

Identification of the amino acid residues essential for the activity and the interconversion of the molecular forms of biliverdin reductase.

Biliverdin reductase (molecular form 1, EC 1.3.1.24, bilirubin:NAD(P)+ oxidoreductase) carries three thiol residues. Only one of them could be alkylated when a ratio N-ethylmaleimide (NEM)/mol enzyme's SH = 90 was used. The alkylation of this thiol group inhibited the conversion of molecular form 1 to its dimer, molecular form 3; however, it did not inhibit the enzymatic activity. At a ratio of NEM/enzyme's SH = 300, two thiol residues were alkylated and the activity of the enzyme was totally inhibited. The third thiol group could not be alkylated either by NEM or by iodoacetamide. Biliverdin as well as the co-substrate NADPH protected the thiol residue essential for the enzymatic activity from alkylation. Spectroscopic evidence was obtained that this thiol group binds covalently to the C-10 of biliverdin to form a rubinoid adduct. The presence of a lysine residue, which is also essential for the enzymatic activity, could be inferred from the fact that by reduction of the Schiff base formed by the enzyme with pyridoxal phosphate the catalytic activity was irreversibly abolished. The location of a lysine residue in the vicinity of the thiol group involved in the catalytic activity was evident when the enzyme was treated with o-phthalaldehyde. The inactivation of the enzymatic activity was coincident with the formation of the fluorescent isoindole derivative which originates when the thiol and epsilon-NH2 groups are located about 3 A apart. The presence of a positively charged ammonium ion in the vicinity of the NADPH binding site was inferred from the shifts in the UVmax of NADPH from 340 nm to 327 nm and of 3-acetyl NADPH from 360 nm to 348 nm when the pyridine nucleotides bind to the reductase. The involvement of arginine residues in the enzymatic activity was established by inhibition of the latter after reaction with butanedione. This inhibition was totally protected by NADPH but not by biliverdin. The similarity of the structural features of biliverdin reductase with those of several dehydrogenases is discussed.

The in vivo and in vitro oxidation of molecular form 1 of biliverdin reductase to molecular form 3 by diamide.

Administration of phenylhydrazine to rats converted molecular form 1 of the liver biliverdin reductase into its disulfide bridged dimer (molecular form 3). This oxidative dimerization was shown not to be mediated by the NAD(+)-dependent dehydrogenase [(1984) Biochem. Biophys. Res. Commun. 121, 249-254]. Administration of diamide produced the same conversion. Although hepatic levels of GSH also decreased, no mixed disulfides of the reductase and GSH could be detected. Administration of the antioxidants allopurinol and alpha-tocopherol together with the diamide did not affect this conversion of molecular forms produced by the latter. The diamide also oxidized molecular form 1 of biliverdin reductase in vitro and molecular form 3 was formed. The chemical oxidation took place at a high rate and was partially inhibited by GSH but not by cysteine.

Molecular differences between rat-liver and rat-kidney biliverdin reductase. Implications for their in vivo regulation.

Rat-liver biliverdin reductase exists in two molecular forms. The major form 1 has a molecular mass of 34 kDa, while the minor form 2 has a molecular mass of 56 kDa. Form 1 was converted into a second major form (form 3) with a molecular mass of 68 kDa by a NAD+-dependent peroxisomal dehydrogenase which was induced under conditions of oxidative stress [Frydman, R. B., Tomaro, M. L., Awruch, J. & Frydman, B. (1984) Biochem. Biophys. Res. Commun. 121, 249]. Molecular form 1 from rat kidney was not affected by the dehydrogenase, and a structural explanation for this difference was therefore sought. Both form 1 biliverdin reductases, isolated from rat liver and kidney, were purified to homogeneity using affinity chromatography, FPLC and HPLC techniques. The homogeneous enzymes were found to be identical when compared by their HPLC retention times, amino acid compositions and electrophoretic behaviour on polyacrylamide gels under non-denaturing conditions and on SDS/polyacrylamide gels. On HPLC analysis the peptides resulting from the CNBr cleavage were found to be the same for both enzymes, when either the native enzymes or their thioethylpyridine derivatives were compared. When the HPLC fingerprints of the tryptic digests were compared, they were found to be very similar, except for a peptide eluting at 31.60 min in the liver digest and at 23.60 min in the kidney digest. When the enzyme from both origins was alkylated with 4-dimethylaminoazobenzene-4'-iodoacetamide and then digested with trypsin, the HPLC fingerprints of the alkylated cysteine-carrying peptides were almost identical, except for a peptide with a retention time of 19.03 min in the liver digest and of 18.19 min in the kidney digest. The liver reductase was not amenable to Edman degradation suggesting a block at the NH2-terminus; in the kidney enzyme, however, it was free and an NH2-terminal sequence of 12 amino acids could be determined. The liver enzyme was found to be more sensitive toward p-hydroxymercuriphenyl sulfonate than the kidney enzyme.

Biliverdin reductase: substrate specificity and kinetics.

The substrate specificity of the different forms of rat liver biliverdin reductase was examined using synthetic biliverdins. Biliverdins carrying methyl, ethyl and one propionate residue in their structure were not substrates of biliverdin reductase. Biliverdins with one propionate and one acetate residue or with two acetate residues were not reduced by the enzyme either. The presence of two propionates in the biliverdin structure gave a biliverdin with substrate activity. Increasing the number of propionates to four, as in coprobiliverdins, did not affect substrate activity, while the octaacid urobiliverdins were also good substrates of the enzymes. The beta isomer of urobiliverdin III and coprobiliverdin III were reduced at much higher rates by molecular form 3 of the enzyme as compared to molecular form 1, a fact which had already been observed with the beta isomer of biliverdins IX, XIII and hematobiliverdin. All the biliverdins mentioned above were readily reduced to bilirubins by sodium borohydride. The purified molecular forms 1 and 3 displayed sigmoidal kinetics with most of the biliverdins tested. The data were analyzed by nonlinear regression in a microcomputer and it was found that they fitted a model of a moderate cooperative dimer where both ES and ES2 are catalytically active. The Vm, Ks and the Hill numbers, nH, for biliverdin IX alpha and beta, hematobiliverdin IX alpha and beta, and several synthetic biliverdin isomers are given. Molecular form 2 showed classical Michaelian kinetics.

The regulation of porphobilinogen oxygenase and porphobilinogen deaminase activities in rat bone marrow under conditions of erythropoietic stress.

Porphorbilinogen oxygenase (EC 4.2.1.24) was associated with the microsomal fraction of bone marrow in normal rats and in rats submitted to erythropoietic stress, while porphobilinogen deaminase (EC 4.3.1.8) of the same origin was present in the cytosol. An NADPH-dependent electron-donor system for the oxygenase was also present in the microsomes of the bone marrow. Under conditions of erythropoietic stress caused by hypoxia, the activities of both enzymes were found to be inversely correlated. While the oxygenase showed minimum activity between the 4th and 8th day of hypoxia, porphobilinogen deaminase reached its maximum activity during this period. After the 8th day of hypoxia, oxygenase activity increased while deaminase activity decreased. The NADPH-dependent electron-transport system necessary for the microsomal oxygenase activity was largely inactivated after the 10th day of hypoxia, while oxygenase activity was not affected. The particulate porphobilinogen oxygenase could be solubilized from the bone marrow microsomes with 1% deoxycholate or 0.5 M KCl. In addition, the oxygenase was also released by freezing and thawing the microsomes isolated from bone marrow of rats which had been submitted to an erythropoietic stress (hypoxia or phenylhydrazine). The enzyme solubilized with deoxycholate or KCl showed a high molecular weight form and a low molecular weight form (Mr 25 000). The former could be transformed into the latter either by treatment with 2 M KCl or by succinylation. When the oxygenase was solubilized by freezing and thawing a third molecular weight form (Mr 50 000) also appeared. The solubilized enzyme could be succinylated without loss of its catalytic activity, while the membrane-bound enzyme could not be succinylated.