Cytochrome P-450-dependent oxidation of lanosterol in cholesterol biosynthesis. Microsomal electron transport and C-32 demethylation

Electron transfer to rat liver microsomal cytochrome P-450 of 14 alpha-methyl group demethylation of 24,25-dihydrolanosterol (C30-sterol) has been studied with a new radio-high-performance liquid chromatography assay. The monooxygenase is dependent upon NADPH plus oxygen, insensitive to CN-, and sensitive to CO. Microsomal oxidation is also sensitive to trypsin digestion, and reactivation is dependent upon the addition of purified, detergent-solubilized cytochrome P-450 reductase. Electron transport of C-32 sterol demethylation can be fully supported by very low concentrations of NADPH (approximately 10 microM) only in the presence of saturating concentrations of NADH (approximately 200 microM) suggesting involvement of cytochrome b5-dependent electron transfer in addition to the NADPH-supported pathway. The cytochrome P-450 of 14 alpha-demethylation has been solubilized with detergents, resolved chromatographically from cytochrome P-450 reductase and cytochrome b5, and fully active C-32 demethylase reconstituted. Incubation of intact microsomes with NADH and very low concentrations of NADPH described above leads to interruption of demethylation without 14 alpha-methyl group elimination. Under these conditions, C-32 oxidation products of the C30-sterol substrate accumulate at the expense of formation of demethylated, C29-sterol products. This enzymic interruption of C-32 demethylation, accumulation of oxygenated C30-sterols, along with subsequent demethylation of the isolated C30-oxysterols under similar oxidative conditions supports the suggestion that 14 alpha-hydroxymethyl and aldehydic sterols are metabolic intermediates of sterol 14 alpha-demethylation. Only very modest inductions of the constitutive cytochrome P-450 isozyme of 14 alpha-methyl sterol oxidase can be obtained with just 2 out of 12 known, potent inducers of mammalian hepatic cytochrome P-450s. Alternatively, administration of complete adjuvant in mineral oil drastically reduces amounts of total microsomal cytochrome P-450 while activity of 14 alpha-methyl sterol oxidase is not affected dramatically. Thus, as much as 2.5-fold enhancement of C-32 oxidase specific activity is obtained when expressed per unit of cytochrome P-450.     

Microsomal electron transport. I. Reduced nicotinamide adenine dinucleotide phosphate-cytochrome c reductase and cytochrome P-450 as electron carriers in microsomal NADPH-peroxidase activity

An electron transport system that catalyzes the oxidation of NADPH by organic, hydroperoxides has been discovered in microsomal fractions. A tissue distribution study revealed that the microsomal fraction of rat liver was particularly effective in catalyzing the NADPH-peroxidase reaction whereas microsomes from adrenal cortex, lung, kidney, and testis were weakly active. The properties of the hepatic microsomal NADPH-peroxidase enzyme system were next examined in detail.The rate of NADPH oxidation by hydroperoxides was first-order with respect to microsomal protein concentration and a K_m value for NADPH of less than 3 μm was obtained. Examination of the hydroperoxide specificity revealed that cumene hydroperoxide and various steroid hydroperoxides were effective substrates for the enzyme system. Using cumene hydroperoxide as substrate, the reaction rate showed saturation kinetics with increasing concentrations of hydroperoxide and an apparent K_m of about 0.4 mm was obtained. The NADPH-peroxidase reaction was inhibited by potassium cyanide, half-maximal inhibition occurring at a cyanide concentration of 2.2 mm. NADH was able to support the NADPH-dependent peroxidase activity synergistically.Evidence compiled for the involvement of NADPH-cytochrome c reductase (NADPH-cytochrome c oxidoreductase, EC 1.6.2.3) in the NADPH-peroxidase reaction included: (1) an identical pH optimum for both activities; (2) stimulation of NADPH-peroxidase activity by increasing ionic strength; (3) inhibition by 0.05 mm, p-hydroxymercuribenzoate with partial protection by NADPH; (4) inhibition by NADP⁺; and (5) inactivation by antiserum to NADPH-cytochrome c reductase. In contrast, antibody to cytochrome b₅ did not inhibit the NADPH-peroxidase activity. Evidence for the participation of cytochrome P-450 in the NADPH-peroxidase reaction included inhibition by compounds forming type I, type II, and modified type II difference spectra with cytochrome P-450; inhibition by reagents converting cytochrome P-450 to cytochrome P-420; and marked stimulation by in vivo phenobarbital administration. The NADPH-reduced form of cytochrome P-450 was oxidized very rapidly by cumene hydroperoxide under a CO atmosphere.It was concluded that the NADPH-peroxidase enzyme system of liver microsomes is composed of the same electron transport components which function in substrate hydroxylation reactions.     

Chelator-sensitive in chloroplast electron transport

The effect of various chelators (orthophenanthroline, bathophen-anthroline, bathophenanthroline sulfonate and bathocuproine) on electron transport of spinach chloroplasts has been studied by means of various photosystem I and II reactions. It was found that photosystem II has at least 3 chelator-sensitive sites, photosystem I from 3–4. An uncoupler-affected site was found in each photosystem. In addition, photosystem I had a stimulator site and a soak site. The soak site was sensitive to chelators only after a period of incubation with the chelator.     

Regulation of photosynthetic electron transport

The photosynthetic electron transport chain consists of photosystem II, the cytochrome b(6)f complex, photosystem I, and the free electron carriers plastoquinone and plastocyanin. Light-driven charge separation events occur at the level of photosystem II and photosystem I, which are associated at one end of the chain with the oxidation of water followed by electron flow along the electron transport chain and concomitant pumping of protons into the thylakoid lumen, which is used by the ATP synthase to generate ATP. At the other end of the chain reducing power is generated, which together with ATP is used for CO(2) assimilation. A remarkable feature of the photosynthetic apparatus is its ability to adapt to changes in environmental conditions by sensing light quality and quantity, CO(2) levels, temperature, and nutrient availability. These acclimation responses involve a complex signaling network in the chloroplasts comprising the thylakoid protein kinases Stt7/STN7 and Stl1/STN7 and the phosphatase PPH1/TAP38, which play important roles in state transitions and in the regulation of electron flow as well as in thylakoid membrane folding. The activity of some of these enzymes is closely connected to the redox state of the plastoquinone pool, and they appear to be involved both in short-term and long-term acclimation. This article is part of a Special Issue entitled "Regulation of Electron Transport in Chloroplasts".     

Efficiency of electron transport processes

Efficiency of electron transport along the linear chain of molecules was investigated from a dynamic viewpoint. It was proposed that two kinds of efficiency are important for electron transport; one is energy efficiency, the other quantum efficiency. In this paper, these two efficiencies are defined for a linear chain system and the correlation between these quantities and the arrangement of various electron transfers is investigated. The optimization of energy and quantum efficiency is found to set different conditions on the arrangement of the rate constants of electron transfer, and there is strong correlation between neighboring electron transfers. In order to maximize both efficiencies, the rate constants of forward and backward transfers of electrons should be bounded by one another in a limited range. In particular, when there are some bypass reactions on the linear chain, as is the case for photosynthesis and respiration, the rate of the backward transfer should be the same order of magnitude as that of the next forward transfer. The present results are applied to some biological processes. In the early stage of photosynthetic electron transfer it seems that quantum efficiency is more important than energy efficiency. The quantum efficiency is close to unity, whereas a considerable part of the free energy is wasted as heat during the primary electron transfers. On the other hand, in the slower electron transfer processes in photosynthesis and respiration, which take place mostly near equilibrium, the energy efficiency seems to be more important than the quantum efficiency. The relation of these properties to biological function is discussed.     

Proton to electron stoichiometry in electron transport of spinach thylakoids

According to the concept of the Q-cycle, the H+/e- ratio of the electron transport chain of thylakoids can be raised from 2 to 3 by means of the rereduction of plastoquinone across the cytochrome b6f complex. In order to investigate the H+/e- ratio we compared stationary rates of electron transport and proton translocation in spinach thylakoids both in the presence of the artificial electron acceptor ferricyanide and in the presence of the natural acceptor system ferredoxin+NADP. The results may be summarised as follows: (1) a variability of the H+/e- ratio occurs with either acceptor. H+/e- ratios of 3 (or even higher in the case of the natural acceptor system, see below) are decreased towards 2 if strong light intensity and low membrane permeability are employed. Mechanistically this could be explained by proton channels connecting the plastoquinol binding site alternatively to the lumenal or stromal side of the cytochrome b6f complex, giving rise to a proton slip reaction at high transmembrane DeltapH. In this slip reaction protons are deposited on the stromal instead of the lumenal side. In addition to the pH effect there seems to be a contribution of the redox state of the plastoquinone pool to the control of proton translocation; switching over to stromal proton deposition is favoured when the reduced state of plastoquinone becomes dominant. (2) In the presence of NADP a competition of both NADP and oxygen for the electrons supplied by photosystem I takes place, inducing a general increase of the H+/e- ratios above the values obtained with ferricyanide. The implications with respect to the adjustment of a proper ATP/NADPH ratio for CO2 reduction are discussed.