Enzymatic oxidation of cadmium and lead metals photodeposited on cadmium sulfide.

Cadmium and lead metals deposited on CdS particles are shown to act as substrates--electron donors for enzymes, hydrogenase from Thiocapsa roseopersicina (HG), NAD-dependent hydrogenase from Alcaligenes eutrophus (NLH), and ferredoxin:NADP oxidoreductase (FNR) from Chlorella in the formation of hydrogen, NADH and NADPH, respectively. Adsorption of the enzyme on the surface of the metallized CdS particle is required for enzymatic oxidation of metal. The maximum rates for the formation of hydrogen and NADH catalyzed by hydrogenase and NAD-dependent hydrogenase with metals as electron donors are comparable with the rates obtained for these enzymes using soluble substrates. Kinetic analysis of the enzymatic oxidation of cadmium metal has revealed that the rate decreases mainly due to the formation of a solid product, which is supposed to be Cd(OH)2. The deceleration of lead oxidation catalyzed by hydrogenase proceeds at the expense of the inhibitory effect of the formed Pb2+. The enzymatic oxidation of electrochemically prepared cadmium metal is also shown. Based on these results, a new mechanism of action of the enzymes involved in anaerobic biocorrosion is proposed. By this mechanism, the enzyme accelerates the process of metal dissolution through a mediatorless catalysis of the reduction of the enzyme substrate.

Inorganic semiconductors as photosensitizers in biochemical redox reactions.

The results of studies of biochemical redox reactions photosensitized by inorganic semiconductor particles are reviewed. The mechanisms of hydrogen photoproduction, NAD+ or NADP+ photoreduction, CO2 photofixation and photosynthesis of organic and amino acids under the coupled action of TiO2, ZnO, CdS, ZnS and enzymes or bacterial cells are considered. Studies on the photocatalytic activity of ferritin, a protein containing microcrystals of hydrous ferric oxide, are described. The data on biosynthesis of cadmium sulfide by microorganisms and plants are analyzed. The possibility of the participation of inorganic semiconductors in photoprocesses in vivo is discussed.

Light induced redox reactions involving mammalian ferritin as photocatalyst.

Under excitation by visible light the iron storage protein ferritin catalyses the reduction of cytochrome c and viologens as well as the oxidation of carboxylic acids, thiol compounds, and sulfite. The photochemically active element of ferritin is its mineral ferrihydrite semiconductor core. Band-gap excitation of these microcrystals leads to generation of electron-hole pairs that are sufficiently long-lived and reactive to engage in redox reactions with components of the medium. Photoreduction of cytochrome c and viologens occurs due to electron transfer from the conduction band of the iron oxide cluster through the protein shell surrounding the ferritin core. Laser photolysis coupled with time-resolved kinetics spectroscopy showed the electron transfer to propylviologen sulfonate to proceed in the microsecond time range. In the absence of electron acceptor at pH < 7, light excitation results in photodissolution of the iron oxide cluster with concomitant formation of Fe(II). These novel findings concerning the photocatalytic activity of ferritin with its inherent biological implications are discussed.

Metal as a novel type of the enzyme substrate. Metallic cadmium photogenerated in the system CdS-formate as a substrate of the NAD-dependent hydrogenase.

The process of NAD+ photoreduction under the coupled action of CdS semiconductor and NAD-dependent hydrogenase from hydrogen-oxidizing bacterium Alcaligenes eutrophus may be divided into light and dark stages. At the first stage, illumination of the system leads to the photooxidation of the sacrificial electron donor and results in the reduction of the semiconductor surface. At the second dark stage NAD+ is reduced to NADH in the presence of hydrogenase. Atoms of metallic Cd(0) are shown to be the true substrate of the enzymatic reaction. The prerequisite for the electron transfer from Cd(0) to hydrogenase is enzyme adsorption on the semiconductor surface. The redox center of the hydrogenase reacting with Cd(0) atoms resides on the flavin-containing heterodimer of the protein. The activity of the hydrogenase immobilized on CdS in the reaction of NAD+ reduction by metallic Cd is close to the enzyme activity with the physiological substrates in solution. Thus, the first example of a metal being the substrate of the enzymatic process is presented.

Photogeneration of NADH under coupled action of CdS semiconductor and hydrogenase from Alcaligenes eutrophus without exogenous mediators.

Photoreduction of NAD has been accomplished by a system consisting of the NAD-dependent hydrogenase from Alcaligenes eutrophus immobilized on CdS particles with formate as artificial electron donor. Enzymatically active NADH is formed under illumination of this system by visible light. Accumulation of the coenzyme dimer (NAD)2 was not detected. NAD photoreduction is supposed to proceed via the direct electron transfer from the semiconductor to the enzyme electron transport chain. However, NADH formation as a result of hydrogenase interaction with anion-radicals (CO2.-) formed in the course of formate photooxidation cannot at present be excluded.

Efficiency of hydrogen photoproduction by chloroplast-bacterial hydrogenase systems.

A comparative study of H(2) photoproduction by chloroplasts and solubilized chlorophyll was performed in the presence of hydrogenase preparations of Clostridium butyricum. The photoproduction of H(2) by chloroplasts in the absence of exogenous electron donors, and with irreversibly oxidized dithiothreitol and cysteine, is thought to be limited by a cyclic transport of electrons wherein methylviologen short-circuits the electron transport in photosystem I. The efficiency of H(2) photoproduction by chloroplasts with ascorbate and NADPH is limited by a back reaction between light-reduced methylviologen and the oxidized electron donors. The use of a combination of electron donors (dithiothreitol and ascorbate), providing anaerobiosis without damage to chloroplasts, makes it possible to avoid consumption of reduced methylviologen for the reduction of oxidized electron donors and to exclude the short-circuiting of electron transfer. Under these conditions, photoproduction of H(2) was observed to occur with a rate of 350 to 400 micromoles H(2) per milligram chlorophyll per hour. In this case, the full electron-transferring capability of photosystem I (measured by irreversible photoreduction of methyl red or O(2)) is used to produce H(2).

[Conditions for effective hydrogen photoevolution by chloroplasts in the presence of bacterial hydrogenase]. / Issledovanie uslovii éffketivnogo fotovydeleniia vodoroda khloroplastami v prisutstvii bakterial'noi gidrogenazy.

The hydrogen photoevolution was studied to compare the efficiency of chloroplasts or solubilized chlorophyll in the presence of hydrogenase from Clostridium butyricum and methylviologen which links the electron transfer from photosystems to the exogenous enzyme. The hydrogen evolution by chloroplasts in the absence of exogeneous electron donors (or in the presence of irreversibly oxidized dithiotreitol or cysteine) is probably limited by cyclic electron flow shot-circuiting the photosystem 1. Efficiency of hydrogen photoproduction when ascorbate or NADP.H are used as electron donors is probably limited by reverse reaction of photoreduced methylviologen with the oxidized electron donor. The combination of both dithiotreitol and ascorbate prevents the shot-circuiting of photosystem 1 by methylviologen; in this case the maximum efficiency of hydrogen photoevolution was achieved up to 400 mumol H2 per 1 mg chlorophyll per hour.

[Methylviologen photoreduction by chloroplasts]. / Issledovanie uslovii fotovosstanovleniia metilviologena khloroplastami.

The condition of methylviologen photoreduction by chloroplasts was investigated. Argon bubbling through the suspension of chloroplasts or degasing in vacuum caused inhibition of methylviologen reduction probably due to the denaturation of chloroplast membranes at the water/air boundary. Adding glycerol or bovine serum albumine or removing oxygen from chloroplast suspension with the aid of the oxygen absorbing-systems preserved the activity of chloroplasts. Methylviologen photoreduction is inhibited by DCMU (10(-7) M) and Tris-buffer treatment and is activated by uncouples. The pH-dependence is similar to that of the Hill reaction. Triton X-100 (0.007%), ethyl ether (2%) and heating up to 42 degrees activated the Hill reaction but inhibited methylviologen reduction. Water molecule probably acts as an initial electron donor in this reaction. It is proposed that the steady level of methylviologen photoreduction is determined by a relationship between the rate of methylviologen electron acceptance and cyclic electron flow short-circuiting photosystem I.

[Light activation of NADH and NADPH]. / Svetovaia aktivatsiia NADH i NADPH.

Illumination of NADH and NADPH by UV-light in the absence of oxygen resulted in the reduction of ferredoxin or methyl-viologen to cation-radical and under prolonged illumination to dihydrodipyridyl. The reaction may by accompanied by triplet and singlet exitation of NADH. It was shown that hematoporphyrin in aqueous solution photosensitized the reaction of NADH oxidation by ferredoxin and methylviologen to the visible region of the spectrum. Under light excitation the redox potentials of NADH and NADPH were increased up to the level exceeding the potential of hydrogen electrode. Illumination of NADH and NADPH by UV-light in the presence of bacterial hydrogenase resulted in hydrogen evolution. The reaction of hydrogen evolution could be sensitised towards the visible region of the spectrum by chlorophyll or chloroplasts.

[Delayed chloroplast luminescence. Activation and suppression]. / Millisekundnoe poslesvechenie khloroplastov. Aktivatsiia i podavlenie.

Effect of diethyl ether, detergent triton X-100, glycerine, sucrose and preliminary heating on delayed luminescence (DL) of chloroplasts has been studied. Ether and triton X-100 in concentrations activating electron transport inhibit DL acting similarly to photophosphorylation uncouplers. Preliminary heating to 42-42C, glycerine and sucrose activate both the electron transport and DL of chloroplasts. Activation of electron transport under these agents is suggested to result not from photophosphorylation uncoupling, but from the changes in the conformation of chloroplast memebranes.

[Light-induced production and consumption of oxygen by chloroplasts: activation and inhibition]. / Vzaimosviaz' fotovydeleniia i fotopogloshcheniia kisloroda khloroplastami: Aktivatsiia i ingibirovanie.

Light-induced production and consumption of oxygen by pea chloroplasts are activated at certain concentrations of the solvents (diethyl ester, methyl alcohol, dimethylsulfoxide) and detergent Triton X-100. At higher concentrations of the compounds studied both reactions are inhibited. The uncouplers (methylamine and carbonyl cyanide-3-chlorophenylhydrazone) activate these processes. The agents studied have a similar effect on the processes of light-induced production and consumption of oxygen, which are limited by a common link bound to the phosphorylation site in photosystem I. The effects observed suggest that the inhibition may be due to inhibition of photosystem II, whereas the activation may be largely due to an action on photosystem I.