Cytochrome P-450 and NADPH cytochrome c reductase in rat brain: formation of catechols and reactive catechol metabolites.

Microsomes isolated from whole rat brain were found to contain cytochreme P-450 (0.025 to 0.051 nmoles/mg) and NADPH cytochrome $\text{c}$ reductase activity (26.0 to 55.0 nmoles/mg/min). The oxidation of estradiol to a reactive metabolite that became covalently bound to rat brain microsomal protein was inhibited 63% by an atmosphere of CO:O₂ (9:1), indicating the involvement of a cytochrome P-450 oxygenase. In contrast, this atmosphere had no effect on the binding of either the catechol estrogen, 2-hydroxyestradiol, or several catecholamines to rat brain microsomes. An antibody prepared against NADPH cytochrome $\text{c}$ reductase was found to decrease significantly both the formation of 2-hydroxyestradiol from estradiol by rat brain microsomes and the covalent binding of the catechol estrogen and catecholamines to rat brain microsomal protein.     

The enzyme "aldehyde oxidase" is an iminium oxidase. Reaction with nicotine delta 1'(5') iminium ion.

The second of the two reaction steps involved in the metabolic transformation of (?)-nicotine to (?)-cotinine $\text{(}\text{3}\text{) (}\text{i.}\text{e.}$, the oxidation of the intermediate $\text{2}\text{)}$ is mediated mainly, if not solely, by the enzyme aldehyde oxidase (EC 1.2.3.1). Of the molecular species that constitute $\text{2}$, nicotine Δ^1′(5′) iminium ion $\text{(}\text{2a}\text{)}$ appears to serve as the substrate. The enzyme has a strong affinity for $\text{2a}$, as shown in a study on the inhibition of the oxidation of 3-(aminocarbonyl)-1-methylpyridinium chloride. This study gave a value of K_i = 6 μM; K_m = 2 μM (pH 7.4). Mainly in view of this finding, “iminium oxidase” seems to be a more adequate name than “aldehyde oxidase” for this enzyme.     

The effect of diphenols upon the autoxiation of oxyhemoglobin and oxymyoglobin.

P-Hydroquinone and catechol catalytically promote the oxidation of oxyhemoglobin and Oxymyoglobin to the ferriform. Kinetic data for oxyhemoglobin oxidation indicates a first-order dependence upon the hemeprotein concentration and half-order dependence upon diphenol; however at high catalyst concentration, saturation is observed with similar V values for both diphenols despite the difference in reactivity.It is proposed that initially formed quinone oxidizes the hemeprotein with oxygen release; in turn, the semiquinone oxidizes a second molecule of hemeprotein and regenerates the quinone, with the bound oxygen acquiring two electrons. Except for the more reactive oxymyoglobin, the reduced form of the catalyst must be present to oppose semiquinone disappearance by dismutation.Since the expected release of O₂ for water formation is observed, the system may be considered a model for terminal oxidase, the couple $\text{Q}\text{S}$ replacing a $\text{Fe}{}^{\mathrm{2+}}\text{Fe}{}^{\mathrm{2+}}$ or a $\text{Cu}{}^{\mathrm{+}}\text{Cu}{}^{\mathrm{2+}}$ system.It is tentatively inferred that oxyhemoglobin has the structure HbFe²⁺---O₂ and that the rate of the catalyzed oxidation is limited by the rate of generation of the true reacting form, the superoxide ferri structure, HbFe³⁺---O₂^?.     

Energy-coupling mechanisms under aerobic and anaerobic conditions in autotrophically grown Pseudomonas saccharophila

The cell-free preparations from autotrophieally grown Pseudomonas saccharophila catalyzed the process of electron transport from H₂ or various other organic electron donors to either O₂ or NO₃^? with concomitant ATP generation. The respective $\text{P}\text{O}$ ratios with H₂ and NADH were 0.63 and 0.73, the respective $\text{P}\text{NO}{}_3{}^{\mathrm{?}}$ ratios were 0.57 and 0.54. In contrast, the $\text{P}\text{O}$ and $\text{P}\text{NO}{}_3{}^{\mathrm{?}}$ ratios with succinate were 0.18 and 0.11, respectively. ATP formation coupled to the oxidation of ascorbate, in the absence or presence of added N,N,N′,N′-tetramethyl-p-phenylenediamine or cytochrome c, could not be detected. Various uncouplers inhibited phosphorylation with either O₂ or NO₃^? as terminal electron acceptors without affecting the oxidation of H₂ or other substrates. The NADH oxidation at the expense of O₂ or NO₃^? reduction as well as the associated phosphorylation were inhibited by rotenone and amytal. The aerobic and anaerobic H₂ oxidation and coupled ATP synthesis, on the other hand, was unaffected by the flavoprotein inhibitors as well as by the NADH trapping system. The NADH, H₂, and succinate-linked electron transport to O₂ or NO₃^? and the associated phosphorylations were sensitive, however, to antimycin A or 2-n-nonyl-4-hydroxyquino-line-N-oxide, and cyanide or azide. The data indicated that although the phosphorylation sites 1 and II were associated with NADH oxidation by O₂ or NO₃^?, the energy conservation coupled to H₂ oxidation under aerobic or anaerobic conditions appeared to involve site II only.     

Two high affinity estrogen binding proteins of different specificity in the immature rat uterus cytosol

The presence of two high affinity estrogen binding proteins in the uterine cytosol of the immature rat has been observed.Besides the 8 S cytosol estrogen $\text{receptor}$, there is a 4–5 S fraction binding estradiol and estrone with a large capacity. In fact, the two binding systems have a different affinity for estradiol and estrone, the receptor binding more the former and the 4–5 S fraction more the latter. Exposure of the cytosol to specific anti-α₁-Fetoprotein antibodies suppresses a large part of the 4–5 S binder, if not the totality. Moreover the estrogen binding 4–5 S fraction decreases with increasing age until puberty, while the $\text{receptor}$ increases. These results suggest therefore that the estradiol-estrone binding 4–5 S peak of the uterine cytosol is mainly made up of Estradiol Binding Plasma Protein-α₁-Fetoprotein (EBP-AFP). Also they confirm that “cytosol” should be taken as an operational fraction which may include extracellular components.During the course of these experiments, it has been observed that the increase of the estradiol $\text{receptor}$ is more rapid than the other uterine cytosol proteins until the 8th day, and that there is a second period of growth when it follows the development of the uterus and of the animal, as if it had reached a constant number of binding sites per cell.     

The effects of estrogen on cortisol metabolism in female baboons

We examined Cortisol (F) dynamics in female baboons $\text{(Papio anubis)}$ treated with diethylstilbestrol (DES) or estradiol (E₂) and compared values with those previously measured in nonpregnant and pregnant animals. Five regularly menstruating baboons (12–18 kg, BW) were administered 5 mg DES daily via fruit or 0.5 mg E₂/0.1ml oil sc for 30 days. Blood samples, obtained before and after treatment, were assayed for serum F concentrations and serum Cortisol binding capacity (CBC). The metabolic clearance (MCR) and production rate (PR) of F and the catabolism of i.v. administered [³H] F were examined 25 and 30 days after initiation of estrogen treatment. Compared with values in nonpregnant baboons, F metabolism in estrogen treated animals is significantly altered and is characterized by increased formation of unconjugated metabolites, decreased glucuronylation, increased excretion of unconjugated F, cortisone, and highly polar metabolites, and increased CBC. These changes induced by estrogen are similar to those observed in intact pregnant baboons and permit the suggestion that the pattern of F metabolism and the level of CBC in baboon pregnancy are the result of elevated estrogen production.However, estrogen also caused a significant decrease in the MCR and PR of F, parameters which, by contrast, are similar in intact pregnant and nonpregnant baboons. These findings indicate that while estrogen also influences the rate of F clearance and F production, these effects of estrogen are not apparent during pregnancy. Collectively, these findings allow the suggestion that estrogen is a major factor which alters F metabolism and increases serum CBC in baboon gestation. However, additional factors are operative in primate pregnancy which maintain PR and MCR of F at levels similar to those of nonpregnant baboons.     

Steric factors involved in the action of glycosidases and galactose oxidase

α-(1→2)-$\text{L}\text{=}$-Fucosidase, β-$\text{D}\text{=}$-galactosidase and galactose oxidase are sterically hindered by certain types of branching in the oligosaccharide chains. 1) β-$\text{D}\text{=}$-Galactosidase will not cleave galactose when the penultimate sugar carries a sialic acid residue as in I. 2) Galactose Oxidase will not oxidize the galactose residue in trisaccharide I but will in II. Moreover, neither galactose nor $\text{N}$-acetylgalactosamine, glycosidically bound as in III, is susceptible to oxidation with galactose oxidase until the α-(1→2) linkage between them is cleaved by $\text{α-}\text{N}\text{-acetylgalactosaminidase}$. 3) α-(1→2)-$\text{L}\text{=}$-Fucosidase action is inhibited by $\text{α-(1→3)-}\text{N}\text{-acetylgalactosaminyl}$ or galactosyl residue, as in III and IV. Removal of the terminal sugars makes the fucosyl residue susceptible to fucosidase action.

     

Compensation for measuring error produced by finite response time in determination of rates of oxygen consumption with a Clark-type polarographic electrode

In the determination of the rates of oxygen consumption with a Clark-type oxygen electrode, and experimental error is caused by finite response time of the oxygen electrode for a rapid oxidation reaction. A theoretical equation between the observed pseudo first-order rate constant (k_obs) and the true rate constant (k)

$\text{1}\text{k}{}_{\mathrm{obs}}\text{=}\text{1}\text{k}\text{+T}$

where T is a time constant for a first-order response of the oxygen electrode, was derived and found to hold up to k = 23 min^?1 in oxidation of hydroquinone at pH 7.60–8.63.     

Progesterone-induced inactivation of nuclear estrogen receptor in the hamster uterus is mediated by acid phosphatase

Inactivation of hamster uterine estrogen receptor was assayed in nuclear KCl extracts (30 min, 37°C, pH 7.5) after progesterone treatment $\text{in}\text{vivo}$ for 2h. At very low concentrations ($\text{>}$0.05 mM), molybdate and vanadate blocked the progesterone-induced increase in receptor inactivation. In contrast, only high concentrations ($\text{>}$10 mM) of the inhibitors blocked receptor inactivation in extracts from untreated hamsters. Gel electrophoresis and inhibition curves for phosphatases in nuclear extract demonstrated that acid, rather than alkaline, phosphatase activity is most likely responsible for these effects. These data suggest that progesterone antagonizes estrogen action in the hamster uterus by promoting estrogen receptor dephosphorylation leading to inactivation.     

The estrogenic activity of DDT: Invivo and invitro induction of a specific estrogen inducible uterine protein by o,p'-DDT

The pesticide o,p'-DDT stimulates the production of a specific uterine protein, the so-called induced protein or IP, normally associated with an estrogenic response of the uterus. $\text{In}$$\text{vivo}$ stimulation of IP production is observed 1 hour after the administration of 250 mg/kg of o,p'-DDT to immature rats. $\text{In}$$\text{vitro}$ stimulation of IP production is observed after a 1 hour incubation of uteri with 100 μM o,p'-DDT. This $\text{in}$$\text{vitro}$ response is blocked by Actinomycin D. In contrast to o,p'-DDT, which binds to the cytoplasmic estrogen receptor and stimulates IP production, p,p'-DDT which does not bind well to the estrogen receptor does not stimulate IP production $\text{in}$$\text{vitro}$. These findings represent the first report of an estrogenic effect of o,p'-DDT in a completely $\text{in}$$\text{vitro}$ system.     

Acyl phosphate and cyclic AMP inhibition of reactions of d-glyceraldehyde-3-phosphate dehydrogenase with aldehyde and acyl phosphate substrates: Multiple inhibition analysis

The effects of the inhibitors trimethylacetyl phosphate and cAMP have been determined in reactions catalyzed by d-glyceraldehyde-3-phosphate dehydrogenase. These inhibitors must influence the oxidation of aldehydes through substrate dependent co-operative conformational changes. Both trimethylacetyl phosphate and cAMP give sigmoidal $\text{1}\text{V}$ vs (I) plots in oxidation of glyceraldehyde 3-phosphate, but exert linear competitive effects on the acyl phosphatase site in acylation reactions of β-(2-furyl) acryloyl phosphate. The linear inhibition in the latter reactions indicates that one inhibitor molecule is bound per active site. Hydride transfer to NAD⁺ is the ratedetermining step in oxidation of benzaldehyde to an acylenzyme, as shown by the threefold decrease in V_max without change in K_m when 1-deuterobenzaldehyde is the substrate; it is very likely this step that is affected by acyl phosphate inhibitors. Plots of $\text{1}\text{V}$ vs cAMP concentration for oxidation of benzaldehyde at a series of trimethylacetyl phosphate concentrations are parallel at concentrations of acyl phosphate less than 0.00625 m, which demonstrates that binding of the inhibitors is mutually exclusive. However, at higher concentrations of trimethylacetyl phosphate, the slopes are affected, which shows that both inhibitors are then binding. Thus, the binding of high concentrations of acyl phosphate must result in a conformational change of the enzyme that permits binding of both inhibitors. A number of conformations with different kinetic properties are formed with the various substrate and inhibitor combinations. In reactions of muscle d-glyceraldehyde-3-phosphate dehydrogenase, binding of these inhibitors is best explained in terms of induced fit and a sequential model of conformational changes.     

Inhibition of p-nitroanisole O-demethylation in perfused rat liver by potassium cyanide

The effect of potassium cyanide on p-nitroanisole O-demethylation in perfused rat livers has been examined. Cyanide (2 mm), an inhibitor of cytochrome oxidase, diminished p-nitroanisole O-demethylation by 50–75% in perfused livers from normal and phenobarbital-treated rats, but had much less effect on hepatic microsomal p-nitroanisole O-demethylation. The inhibition was also observed in livers where the activity of the pentose phosphate shunt was abolished by pretreatment with 6-aminonicotinamide. Cyanide infusion decreased hepatic $\text{ATP}\text{ADP}$ ratios and cellular concentrations of glutamate, α-ketoglutarate, and isocitrate, but caused an increase in the $\text{NADPV}{}^{\mathrm{+}}\text{NADPH}$ ratio. Rates of NADPH generation via the pentose phosphate shunt were unchanged by cyanide, and hepatic concentrations of glucose 6-phosphate were markedly increased by cyanide. Thus, inhibition of p-nitroanisole metabolism could not be explained solely by a direct interaction of cyanide with mixed-function oxidases or diminished NADPH generation via the pentose cycle. These data indicate that cyanide inhibits mixed-function oxidation in intact cells by diminishing the generation of NADPH from sources other than the pentose cycle. Further, these data are consistent with the hypothesis that some NADPH for mixed-function oxidation arises from cyanidesensitive mitochondrial sources.     

Bromine oxidation of 1,2-O-isopropylidene-α-d-Glucofuranose and sucrose

Sucrose and $\text{1,2-O-}\text{isopropylidene-α-}\text{d}\text{-glucofuranose}$ (1) were oxidised with bromine in aqueous solution at pH 7 and room temperature. The resulting keto derivatives were converted into their more-stable O-methyloximes, which were characterised by spectroscopic and chromatographic methods. Oxidation of 1 occurred at C-3 and C-5, with a preference for C-5. In the sucrose derivatives isolated after oxidation, those having a keto group in the glucopyranosyl moiety preponderated. The axial fructofuranosyl aglycon protects position 3 in the glucopyranosyl group and oxidation occurs only at C-2 and C-4. Small amounts of sucrose oxidised at C-3 in the fructofuranosyl moiety were also found.     

Kinetic and thermodynamic properties of membrane-bound cytochromes of aerobically and photosynthetically grown Rhodopseudomonas spheroides

A green mutant of Rhodopseudomonas spheroides was isolated in which spectroscopic measurements of the α-band region of cytochromes could be made. It was grown either aerobically or photosynthetically, and the membrane fractions prepared from cells of each type. Anaerobic potentiometric titration at 560 nm minus 542 nm showed the same three redox components, tentatively identified as b-type cytochromes, in membrane fractions from either type of cell. The mid-point potentials were approximately +185, +41 and ?104 mV. In membranes from photosynthetically grown cells the major cytochrome form absorbing at 560 nm had a mid-point potential of +42 mV; in aerobically grown cells the major form had a potential of +185 mV. In both types of cell only one c-type cytochrome was found, with a mid-point potential of +295 mV. An a-type cytochrome was present only in aerobically-grown cells.Substrate-reduced particles from these cells were mixed with air-saturated buffer in a stopped-flow spectrophotometer and the kinetics of oxidation of b- and c-type cytochromes were measured. The same two b-type components, reacting with pseudo first order kinetics, were detected in particles from both aerobically and photosynthetically grown cells ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ for oxidation 1.3 s and 0.13 s). The c-type cytochrome of particles from aerobically grown cells was oxidised with $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ of 0.97 s; the c-type cytochrome of photosynthetic cells was oxidised faster, with $\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ of 0.27 s.These observations have implications on the adaptive formation of electron transport systems that are discussed.     

New experimental approach to the estimation of rate of electron transfer from the primary to secondary acceptors in the photosynthetic electron transport chain of purple bacteria

A method for calculating the rate constant ($\text{K}{}_{\mathrm{<mtext>A</mtext><mtext>1</mtext><mtext>A</mtext><mtext>2</mtext>}}$) for the oxidation of the primary electron acceptor (A₁) by the secondary one (A₂) in the photosynthetic electron transport chain of purple bacteria is proposed.The method is based on the analysis of the dark recovery kinetics of reaction centre bacteriochlorophyll (P) following its oxidation by a short single laser pulse at a high oxidation-reduction potential of the medium. It is shown that in Ectothiorhodospira shaposhnikovii there is little difference in the value of $\text{K}{}_{\mathrm{<mtext>A</mtext><mtext>1</mtext><mtext>A</mtext><mtext>2</mtext>}}$ obtained by this method from that measured by the method of Parson ((1969) Biochim. Biophys. Acta 189, 384–396), namely: $\text{(4.5±1.4) · 10}{}^3\text{s}{}^{\mathrm{?1}}$ and $\text{(6.9±1.2) · 10}{}^3\text{s}{}^{\mathrm{?1}}$, respectively.The proposed method has also been used for the estimation of the $\text{K}{}_{\mathrm{<mtext>A</mtext><mtext>1</mtext><mtext>A</mtext><mtext>2</mtext>}}$ value in chromatophores of Rhodospirillum rubrum deprived of constitutive electron donors which are capable of reducing P⁺ at a rate exceeding this for the transfer of electron from A₁ to A₂. The method of Parson cannot be used in this case. The value of $\text{K}{}_{\mathrm{<mtext>A</mtext><mtext>1</mtext><mtext>A</mtext><mtext>2</mtext>}}$ has been found to be $\text{(2.7±0.8) · 10}{}^3\text{s}{}^{\mathrm{?1}}$.The activation energies for the A₁ to A₂ electron transfer have also been determined. They are 12.4 kcal/mol and 9.9 kcal/mol for E. shaposhnikovii and R. rubrum, respectively.     

Covalent modification of chloroplast Photosystem II polypeptides by p-nitrothiophenol

Illumination of the chlorophyll $\text{a}\text{b}$ light-harvesting complex in the presence of $\text{p-}\text{nitrothio}\text{[}{}^{14}\text{C]phenol}$ caused quenching of fluorescence emission at 685 nm (77 K) relative to 695 nm and covalent modification of light-harvesting complex polypeptides. Fluorescence quenching saturated with one p-nitrothiophenol bound per light-harvesting complex polypeptide (10–13 chlorophylls); $\text{1}\text{2}$ maximal quenching occurred with one p-nitrothiophenol bound per light-harvesting complex polypeptides (190–247 chlorophylls). This result provides direct evidence for excitation energy transfer between light-harvesting complex subunits which contain 4–6 polypeptides plus 40–78 chlorophylls per complex.Illumination of chloroplasts or Photosystem II (PS II) particles in the presence of $\text{p-}\text{nitrothio}\text{[}{}^{14}\text{C]phenol}$ caused inhibition of PS II activity and labeling of several polypeptides including those of 42–48 kilodaltons previously identified as PS II reaction center polypeptides. In chloroplasts, inhibition of oxygen evolution accelerated p-nitrothiophenol modification reactions; DCMU or donors to PS II decreased p-nitrothiophenol modification. These results are consistent with the hypothesis that accumulation of oxidizing equivalents on the donor side of PS II creates a ‘reactive state’ in which polypeptides of PS II are susceptible to p-nitrothiophenol modification.     

Alkali-labile oligosaccharides from bovine milk fat globule membrane clycoprotein

Phenol extraction of bovine milk fat globule membrane gave a glycoprotein fraction which, in sodium dodecyl sulphate electrophoresis, showed three major bands, all staining for both protein and carbohydrate. Alkaline borohydride treatment and desialylation of the glycoprotein fraction released the reduced disaccharide β-d-galactosyl(1 → 3)-$\text{N-}\text{acetyl-}\text{d}\text{-galactosamine}$ (T-antigen), which was identified by gas chromatography using a standard. All of the disaccharide units in the native glycoprotein were shown to be substituted by sialic acid, and a tetrasaccharide containing the disaccharide plus two molecules of sialic acid was isolated following alkaline borohydride treatment of the glycoprotein and gel filtration. Periodate oxidation of native and desialylated glycoprotein, together with paper chromatography of alkali degraded oligosaccharide fragments, indicated that the major alkali-labile oligosaccharide of the glycoprotein fraction is a tetrasaccharide containing $\text{β-}\text{d}\text{-galactosyl(1 → 3)}\text{-N-}\text{acetyl-}\text{d}\text{-galactosamine}$ substituted by sialic acid at position C3 of the galactosyl and position C6 of the $\text{N-}\text{acetyl-}\text{d}\text{-galactosamine}$ residue. Evidence was also obtained for the presence of small amounts of unsubstituted alkali-labile $\text{N-}\text{acetyl-}\text{d}\text{-galactosamine}$ linked directly to protein in the native glycoprotein.Serological evidence using agglutinins from Vicia graminea, Arachis hypogoea and human anti-T serum confirmed the presence in the native glycoprotein of a sialic acid substituted T-antigen. Similar evidence using agglutinins from Helix pomatia and Cepaea hortensis also confirmed the presence of terminal alkali-labile $\text{N-}\text{acetyl-}\text{d}\text{-galactosamine}$ in the native glycoprotein.     

Oxidation of anionic nitroalkanes by flavoenzymes,and participation of superoxide anion in the catalysis

The reactivities of anionic nitroalkanes with 2-nitropropane dioxygenase of Hansenula mrakii, glucose oxidase of Aspergillus niger, and mammalian d-amino acid oxidase have been compared kinetically. 2-Nitropropane dioxygenase is 1200 and 4800 times more active with anionic 2-nitropropane than d-amino acid oxidase and glucose oxidase, respectively. The apparent K_m values for anionic 2-nitropropane are as follows: 2-nitropropane dioxygenase, 1.61 mm; glucose oxidase, 16.7 mm; and d-amino acid oxidase, 11.1 mm. Anionic 2-nitropropane undergoes an oxygenase reaction with 2-nitropropane dioxygenase and glucose oxidase, and an oxidase reaction with d-amino acid oxidase. In contrast, anionic nitroethane is oxidized through an oxygenase reaction by 2-nitropropane dioxygenase, and through an oxidase reaction by glucose oxidase. All nitroalkane oxidations by these three flavoenzymes are inhibited by Cu and Zn-superoxide dismutase of bovine blood, Mn-superoxide dismutases of bacilli, Fe-superoxide dismutase of Serratia marcescens, and other $\text{O}{}_2{}^{\mathrm{?}}$ scavengers such as cytochrome c and NADH, but are not affected by hydroxyl radical scavengers such as mannitol. None of the $\text{O}{}_2{}^{\mathrm{?}}$ scavengers tested affected the inherent substrate oxidation by glucose oxidase and d-amino acid oxidase. Furthermore, the generation of $\text{O}{}_2{}^{\mathrm{?}}$ in the oxidation of anionic 2-nitropropane by 2-nitropropane dioxygenase was revealed by ESR spectroscoy. The ESR spectrum of anionic 2-nitropropane plus 2-nitropropane dioxygenase shows signals at g₁ = 2.007 and g₁₁ = 2.051, which are characteristic of $\text{O}{}_2{}^{\mathrm{?}}$. The $\text{O}{}_2{}^{\mathrm{?}}$ generated is a catalytically essential intermediate in the oxidation of anionic nitroalkanes by the enzymes.