Methylobacterium rhodesianum MB 126 possesses two acetoacetyl-CoA reductases

Two constitutive acetoacetyl-CoA (AcAc-CoA) reductases were purified from Methylobacterium rhodesianum MB 126, an NADPH-linked d(-)--hydroxybutyryl-CoA forming reductase (enzyme A) and an NADH-and NADPH-linked l(+)--hydroxybutyryl-CoA forming reductase (enzyme B). Enzyme A and B give apparent K _m values of 15 M and 30 M for AcAc-CoA, 18 M for NADPH and 30 M for NADH, respectively. They are inhibited by AcAc-CoA at concentrations higher than 25 M and 50 M, respectively. The contribution of the two reductases to poly--hydroxybutyrate synthesis is discussed.     

Iron reductases from Pseudomonas aeruginosa

Cell-free extracts of Pseudomonas aeruginosa contain enzyme activities which reduce Fe(III) to Fe(II) when iron is provided in certain chelates, but not when the iron is uncomplexed. Iron reductase activities for two substrates, ferripyochelin and ferric citrate, appear to be separate enzymes because of differences in heat stabilities, in locations in fractions of cell-free extracts, in reductant specificity, and in apparent sizes during gel filtration chromatography. Ferric citrate iron reductase is an extremely labile activity found in the cytoplasmic fraction, and ferripyochelin iron reductase is a more stable activity found in the periplasmic as well as cytoplasmic fraction of extracts. A small amount of activity detectable in the membrane fraction seemed to be loosely associated with the membranes. Although both enzymes have highest activity reduced nicotinamide adenine dinucleotide, reduced glutathione also worked with ferripyochelin iron reductase. In addition, oxygen caused an irreversible loss of a percentage of the ferripyochelin iron reductase following sparge of reaction mixtures, whereas the reductase for ferric citrate was not appreciably affected by oxygen.     

Ferredoxin-NADP+ Reductase from Pseudomonas putida Functions as a Ferric Reductase

Pseudomonas putida harbors two ferredoxin-NADP⁺ reductases (Fprs) on its chromosome, and their functions remain largely unknown. Ferric reductase is structurally contained within the Fpr superfamily. Interestingly, ferric reductase is not annotated on the chromosome of P. putida. In an effort to elucidate the function of the Fpr as a ferric reductase, we used a variety of biochemical and physiological methods using the wild-type and mutant strains. In both the ferric reductase and flavin reductase assays, FprA and FprB preferentially used NADPH and NADH as electron donors, respectively. Two Fprs prefer a native ferric chelator to a synthetic ferric chelator and utilize free flavin mononucleotide (FMN) as an electron carrier. FprB has a higher k_cat/K_m value for reducing the ferric complex with free FMN. The growth rate of the fprB mutant was reduced more profoundly than that of the fprA mutant, the growth rate of which is also lower than the wild type in ferric iron-containing minimal media. Flavin reductase activity was diminished completely when the cell extracts of the fprB mutant plus NADH were utilized, but not the fprA mutant with NADPH. This indicates that other NADPH-dependent flavin reductases may exist. Interestingly, the structure of the NAD(P) region of FprB, but not of FprA, resembled the ferric reductase (Fre) of Escherichia coli in the homology modeling. This study demonstrates, for the first time, the functions of Fprs in P. putida as flavin and ferric reductases. Furthermore, our results indicated that FprB may perform a crucial role as a NADH-dependent ferric/flavin reductase under iron stress conditions.Commonly, Fprs are ubiquitous, monomeric, reversible flavin enzymes. Fprs evidence a profound preference for NADP(H) over NAD(H) (3). They harbor a prosthetic flavin cofactor (FAD) and catalyze the reversible electron exchange between NADPH and either ferredoxin (Fd) or flavodoxin (Fld) (4, 5). In oxygenic photosynthesis, the Fd is reduced by the photosystem and subsequently passes electrons on to NADP⁺ via the Fpr. This reaction provides the cellular NADPH pool required for CO₂ assimilation and other biosynthetic processes (4, 5). In heterotrophic organisms such as bacteria, reduced ferredoxin, owing to the reverse enzymatic activity of the Fpr, can donate an electron to several Fd-dependent enzymes, such as nitrite reductase, sulfite reductase, glutamate synthase, and Fd-thioredoxin reductase, allowing ferredoxin to function in a variety of systems, including oxidative stress (1, 4, 5).Iron is the fourth most abundant element in the natural environment and exists primarily as an oxidized form, Fe(III), which has very low solubility under neutral pH conditions (9, 34) and thus presents problems in terms of bioavailability. However, ferrous iron, of Fe(II), is soluble and available at neutral pH in bacterial cytosol (34). Most bacteria secrete siderophores, which are natural chelators of ferric iron. After they bind to ferric iron, that complex enters the bacteria and releases ferric iron into the cytosol in ferric or ferrous form (9). In the bacterial cytosol, ferric iron must be reduced to ferrous form, and thus ferric reductase is essential to bacterial iron utilization.Commonly, prokaryotic ferric reductases are divided into two groups—namely, the bacterial and archaeal types (34). The typical bacterial type ferric reductase is Escherichia coli Fre, which also functions as a flavin reductase. In other words, the ferric reductase can reduce free flavin as flavin reductase, rather than having the flavin cofactor as a prosthetic group in E. coli (38). The archaeal ferric reductase harbors a flavin cofactor in the enzyme and thus does not require a flavin carrier for ferric reduction (26, 34). E. coli Fre includes a Rosmann folding structure at the NAD(P) binding region, whereas the archaeal ferric reductase (FeR) of Archaeoglobus fulgidus does not evidence that folding structure (6, 34). Many bacterial ferric reductases utilize free flavins, such as flavin mononucleotide (FMN), flavin adenine dinucleotide (FAD) and riboflavin, as electron carrier and, NADH (NAD) or NADP as electron donors to ferric reductase (14, 34). However, reduced ferric iron by reduced free flavin gives rise to the Fenton reaction, which generates the hydroxyl radical within the cell (20, 38). The Fenton reaction is known to generate hydroxyl radicals from ferrous iron and hydrogen peroxide (20). The hydroxyl radical is the most reactive radical and can damage DNA, proteins, and membrane lipids (16, 20, 34, 38). Therefore, the fine-tuning of ferric reduction regulation is required for the survival of bacterial cells.Many Pseudomonas strains, including Pseudomonas putida, a gram-negative soil model bacteria, and Pseudomonas aeruginosa, a human pathogen bacteria, do not harbor annotated ferric reductase within their genome sequences. Commonly, the pathogens compete with the host for available iron, whichis crucial for their survival within the host. Thus, studies of P. aeruginosa regarding iron utilization, siderophores, and ferric reduction are considered to be essential for a better understanding of human infections (9, 19). Studying the physiology and ecology of P. putida also provides us with a new framework for elucidating the basis of the metabolic versatility and environmental stress response of soil microorganisms. Thus, the study of ferric reductase in strains of Pseudomonas at the molecular level is certainly required. From the structural perspective, ferric reductases are generally considered to be contained within the structurally diverse ferredoxin-NADP⁺ reductase (Fprs; EC 1.18.1.2) superfamily, which is frequently involved in the transfer of electrons between Fd/Fld and NADP(H) (2, 15, 34). Thus, we tested the role of the Fpr as a ferric reductase using free flavin (FMN or FAD), NADH, or NADPH as electron donors, and ferric-citrate or ferric-EDTA as terminal electron acceptors (37). We determined that FprA could efficiently utilize NADPH in ferric reduction. Rather, FprB could use NADH as an electron donor and may perform a crucial role as a NADH-dependent ferric reductase under iron stress conditions.     

Ferric chelate reduction by suspension culture cells and roots of soybean: A kinetic comparison

The abilities of suspension cultures and intact roots of soybean (Glycine max L. cv. Hawkeye) to reduce ferric chelate were compared. Ferric chelate was supplied as ferric hydroxyethylethylenediaminetriacetic acid (FeHEDTA) and reduction was measured spectrophotometrically using bathophenan-throlinedisulfonic acid (BPDS) as the ferrous scavenger. Ferric chelate reduction by cell suspension cultures showed typical saturation kinetics; however, no difference was observed between cells that had been continuously grown with Fe (+Fe) and those that had been grown for four days without added Fe (–Fe). Values for K_m and V_max, determined from a Lineweaver-Burk plot, were 57 M and nmoles mg^-1 dry weight for the +Fe cells and 50 M and 22 nmoles mg^-1 dry weight for the -Fe cells, respectively. Ferric chelate reduction by Fe-deficient roots also exhibited saturation kinetics, while roots grown with adequate Fe did not reduce ferric chelate. The K_m and V_max values for Fe-deficient roots were 45 M and 20 nmoles mg^-1 dry weight, respectively, and did not differ from values obtained for cells in culture. This study offers strong evidence that the mechanism responsible for the reduction of ferric chelate is the same for cultured cells and roots and that the process is controlled at the cellular level. We propose that suspension cultures can be used as an alternative to intact roots in the study of ferric chelate reduction.     

Chlorate Reducing Activity of Spinach Nitrate Reductase

The activities of 2-oxoaldehyde-metabolizing enzymes (glyoxalase I, glyoxalase II, methyl- glyoxal reductase, methylglyoxal dehydrogenase and lactaldehyde dehydrogenase) were found to be widely distributed among microorganisms. One of the enzymes, methylglyoxal reductase, which catalyzes the reductive conversion of methylglyoxal into lactaldehyde, was purified from Escherichia coli cells. The enzyme was judged to be homogeneous on polyacrylamide gel electrophoresis and was a monomer with a molecular weight of 43000. The enzyme was most active at pH 6.5 and 45°C. The enzyme utilized both NADPH and NADH for the reduction of 2- oxoaldehydes (glyoxal, methylglyoxal, phenylglyoxal and 4,5-dioxovalerate) and some aldehydes (glycolaldehyde, D,l-glyceraldehyde, propionaldehyde and acetaldehyde). The Km values of the enzyme for methylglyoxal, NADPH and NADH were 4.0 mm, 1.7 fiM and 2.8 /¿m, respectively. The product of methylglyoxal reduction was identified as lactaldehyde. The enzyme from E. coli cells was different from the yeast and goat liver enzymes in both molecular structure and substrate specificity.     

Ferrous iron dependent nitric oxide production in nitrate reducing cultures of Escherichia coli

l-Lactate-driven ferric and nitrate reduction was studied in Escherichia coli E4. Ferric iron reduction activity in E. coli E4 was found to be constitutive. Contrary to nitrate, ferric iron could not be used as electron acceptor for growth. Ferric iron reductase activity of 9 nmol Fe²⁺ mg^-1 protein min^-1 could not be inhibited by inhibitors for the respiratory chain, like Rotenone, quinacrine, Actinomycin A, or potassium cyanide. Active cells and l-lactate-driven nitrate respiration in E. coli E4 leading to the production of nitrite, was reduced to about 20% of its maximum activity with 5 mM ferric iron, or to about 50% in presence of 5 mM ferrous iron. The inhibition was caused by nitric oxide formed by a purely chemical reduction of nitrite by ferrous iron. Nitric oxide was further chemically reduced by ferrous iron to nitrous oxide. With electron paramagnetic resonance spectroscopy, the presence of a free [Fe²⁺-NO] complex was shown. In presence of ferrous or ferric iron and l-lactate, nitrate was anaerobically converted to nitric oxide and nitrous oxide by the combined action of E. coli E4 and chemical reduction reactions (chemodenitrification).     

A Novel Ferric Reductase Purified from <Emphasis Type="Italic">Magnetospirillum gryphiswaldense</Emphasis> MSR-1

A ferric reductase was purified into an electrophoretically homologous state from Magnetospirillum gryphiswaldense MSR-1 strain. The enzyme was found within the cytoplasm and associated with the cytoplasmic membrane. The molecular weight of the purified enzyme was calculated as 16.1 kDa using sodium dodecyl sulfate–polyacrylamide gel electrophoresis, and was almost identical to that calibrated using agarose gel filtration chromatography. It was NADH-dependent and required flavin mononucleotide as a cofactor. The optimal reaction temperature and pH values were 30°C and 6.5, respectively. The K _m and Vmax values for ferric citrate were 45.1 μM and 1.216 μM min⁻¹, respectively. Though ferric reductase activity could be inhibited by Co²⁺, Cu²⁺, Mn²⁺, and Zn²⁺, even high concentrations of Mg²⁺ ions have failed to accomplish such enzyme inhibition. Furthermore, the molecular weight, the N-terminal sequence, and the activity of ferric reductase from MSR-1 are not matching with the enzyme preparation obtained from an analogous strain M. magnetotacticum (MS-1). Therefore, it is concluded that the ferric reductase of M. grysphiwaldense and M. magnetotacticum strains are two different enzymes.     

Modeling of Alternative Pathways of Electron Transport to Photosystem I in Isolated Thylakoids

Kinetics of dark decay of absorbance changes at 830 nm (₈₃₀) was examined in thylakoids isolated from leaves of pea seedlings at various concentrations of exogenous NADPH or NADH. Absorbance changes were induced by far-red light to avoid electron donation from photosystem II. In the presence of either biological reductant, the kinetics of ₈₃₀ decay reflecting dark reduction of 700⁺, the primary electron donor of photosystem I, was fitted by a single exponential term. The rate of 700⁺ reduction increased with the rise in the concentration of both NADPH and NADH. The values of K _M and V _max for 700⁺ reduction estimated from concentration dependences were 105 ± 21 M and 0.32/s for NADPH or 21 ± 8 M and 0.12/s for NADH. The rate of P700⁺ reduction by either NADPH or NADH significantly increased in the presence of rotenone, a specific inhibitor of chloroplast reductase. The value of V _max was changed only in the presence of rotenone, whereas K _m was practically unaffected. Unlike the chloroplasts of intact leaves, the only enzyme mediating the input of reducing equivalents from NADPH or NADH to the electron transport chain was concluded to be present in thylakoids.     

NADH- and NAD(P)H-Nitrate Reductases in Rice Seedlings

By use of affinity chromatography on blue dextran-Sepharose, two nitrate reductases from rice (Oryza sativa L.) seedlings, specifically, NADH:nitrate oxidoreductase (EC 1.6.6.1) and NAD(P)-H:nitrate oxidoreductase (EC 1.6.6.2), have been partially separated. Nitrate-induced seedlings contained more NADH-nitrate reductase than NAD(P)H-nitrate reductase, whereas chloramphenicol-induced seedlings contained primarily NAD(P)H-nitrate reductase. NAD(P)H-nitrate reductase was shown to utilize NADPH directly as reductant. This enzyme has a preference for NADPH, but reacts about half as well with NADH.     

Metabolic regulation including anaerobic metabolism inParacoccus denitrificans

Under anaerobic circumstances in the presence of nitrateParacoccus denitrificans is able to denitrify. The properties of the reductases involved in nitrate reductase, nitrite reductase, nitric oxide reductase, and nitrous oxide reductase are described. For that purpose not only the properties of the enzymes ofP. denitrificans are considered but also those fromEscherichia coli, Pseudomonas aeruginosa, andPseudomonas stutzeri. Nitrate reductase consists of three subunits: the subunit contains the molybdenum cofactor, the subunit contains the iron sulfur clusters, and the subunit is a special cytochromeb. Nitrate is reduced at the cytoplasmic side of the membrane and evidence for the presence of a nitrate-nitrite antiporter is presented. Electron flow is from ubiquinol via the specific cytochromeb to the nitrate reductase. Nitrite reductase (which is identical to cytochromecd ₁) and nitrous oxide reductase are periplasmic proteins. Nitric oxide reductase is a membrane-bound enzyme. Thebc ₁ complex is involved in electron flow to these reductases and the whole reaction takes place at the periplasmic side of the membrane. It is now firmly established that NO is an obligatory intermediate between nitrite and nitrous oxide. Nitrous oxide reductase is a multi-copper protein. A large number of genes is involved in the acquisition of molybdenum and copper, the formation of the molybdenum cofactor, and the insertion of the metals. It is estimated that at least 40 genes are involved in the process of denitrification. The control of the expression of these genes inP. denitrificans is totally unknown. As an example of such complex regulatory systems the function of thefnr, narX, andnarL gene products in the expression of nitrate reductase inE. coli is described. The control of the effects of oxygen on the reduction of nitrate, nitrite, and nitrous oxide are discussed. Oxygen inhibits reduction of nitrate by prevention of nitrate uptake in the cell. In the case of nitrite and nitrous oxide a competition between reductases and oxidases for a limited supply of electrons from primary dehydrogenases seems to play an important role. Under some circumstances NO formed from nitrite may inhibit oxidases, resulting in a redistribution of electron flow from oxygen to nitrite.P. denitrificans contains three main oxidases: cytochromeaa ₃, cytochromeo, and cytochromeco. Cytochromeo is proton translocating and receives its electrons from ubiquinol. Some properties of cytochromeco, which receives its electrons from cytochromec, are reported. The control of the formation of these various oxidases is unknown, as well as the control of electron flow in the branched respiratory chain. Schemes for aerobic and anaerobic electron transport are given. Proton translocation and charge separation during electron transport from various electron donors and by various electron transfer pathways to oxygen and nitrogenous oxide are given. The extent of energy conservation during denitrification is about 70% of that during aerobic respiration. In sulfate-limited cultures (in which proton translocation in the NADH-ubiquinone segment of the respiratory chain is lost) the extent of energy conservation is about 60% of that under substrate-limited conditions. These conclusions are in accordance with measurements of molar growth yields.     

An NADP-linked acetoacetyl CoA reductase from Zoogloea ramigera

Zoogloea ramigera I-16-M was found to contain two stereospecific acetoacetyl CoA reductases; one was NADP⁺-linked and d(-)--hydroxybutyryl CoA specific and the other was NAD⁺-linked and l(+)-isomer specific. The NADP⁺-linked enzyme, purified approximately 150-fold, had a pH optimum for the reduction of acetoacetyl CoA at 8.1, but no definite pH optimum for the oxidation of -hydroxybutyryl CoA. The apparent Michaelis constants for acetoacetyl CoA and NADPH were 8.3 and 21 M, respectively. The enzyme was markedly inhibited by acetoacetyl CoA at concentrations higher than 10 M.The incorporation of [1-¹⁴C]acetyl CoA into poly--hydroxybutyrate (PHB) by bacterial crude extract (containing -ketothiolase, acetoacetyl CoA reductases, enoyl CoA hydratases and PHB synthases) or by a system reconstituted from purified preparations of -ketothiolase, acetoacetyl CoA reductase and PHB synthase, was observed only in the presence of NADPH, but not NADH. Among various enzymes involved in PHB metabolism, only the specific activity of glucose 6-phosphate dehydrogenase was elevated 5-fold within 2 h after the addition of glucose to the cells grown in the basal medium.These findings suggest that, in Z. ramigera I-16-M, acetoacetyl CoA is directly reduced to d(-)--hydroxybutyryl CoA by the NADP⁺-dependent reductase, and PHB synthesis is at least partially controled by NADPH availability through glucose 6-phosphate dehydrogenase.Non-Standard Abbreviation PHB poly--hydroxybutyrate     

Vectorial electron transport in Degulfovibrio vulgaris (Marburg) growing on hydrogen plus sulfate as sole energy source

Desulfovibrio vulgaris (Marburg) was grown on hydrogen plus sulfate as sole energy source in a medium containing excess iron. The topography of electron transport components was investigated. The bacterium contained per mg cells (dry weight) 30U hydrogenase (1U=1 mol/min), 35 g desulfoviridin (= bisulfite reductase), 0.6 U adenosine phosphosulfate reductase, 30 mU thiosulfate reductase, 0.3 nmol cytochrome c ₃ (M _r=13,000), 0.04 nmol cytochrome b, 0.85 nmol menaquinone, and 0.4 nmol ferredoxin. Hydrogenase (>95%) and cytochrome c ₃ (82%) were localized on the periplasmic side and desulfoviridin (95%), adenosine phosphosulfate reductase (87%), thiosulfate reductase (74%), and ferredoxin (71%) on the cytoplasmic side of the cytoplasmic membrane; menaquinone and cytochrome b were exlusively found in the membrane fraction. The location of the oxidoreductases indicate that in D. vulgaris (Marburg) H₂ oxidation and sulfate reduction take place on opposite sides of the cytoplasmic membrane rather than on the same side, as has recently been proposed.     

Further studies of the β-lactamases ofBacteroides species

The -lactamases of individual strains ofBacteroides fragilis, B. thetaiotaomicron, andB. melaninogenicus were examined to characterize their enzymatic activity and the relation between the periplasmic and cytoplasmic forms of the enzymes. K_m and V_max values indicate that all strains examined were very similar in terms of enzymatic activity with the antibiotics tested. Electrophoretic analysis and treatment with phospholipase D suggest the presence of a cytoplasmic form of the enzyme that is modified upon entry into the periplasmic space.     

Purification and characterization of ferredoxin-NADP<Superscript>+</Superscript> reductase encoded by <Emphasis Type="Italic">Bacillus subtilis yumC</Emphasis>

From Bacillus subtilis cell extracts, ferredoxin-NADP⁺ reductase (FNR) was purified to homogeneity and found to be the yumC gene product by N-terminal amino acid sequencing. YumC is a 94-kDa homodimeric protein with one molecule of non-covalently bound FAD per subunit. In a diaphorase assay with 2,6-dichlorophenol-indophenol as electron acceptor, the affinity for NADPH was much higher than that for NADH, with K_m values of 0.57 M vs >200 M. K_cat values of YumC with NADPH were 22.7 s^–1 and 35.4 s^–1 in diaphorase and in a ferredoxin-dependent NADPH-cytochrome c reduction assay, respectively. The cell extracts contained another diaphorase-active enzyme, the yfkO gene product, but its affinity for ferredoxin was very low. The deduced YumC amino acid sequence has high identity to that of the recently identified Chlorobium tepidum FNR. A genomic database search indicated that there are more than 20 genes encoding proteins that share a high level of amino acid sequence identity with YumC and which have been annotated variously as NADH oxidase, thioredoxin reductase, thioredoxin reductase-like protein, etc. These genes are found notably in gram-positive bacteria, except Clostridia, and less frequently in archaea and proteobacteria. We propose that YumC and C. tepidum FNR constitute a new group of FNR that should be added to the already established plant-type, bacteria-type, and mitochondria-type FNR groups.     

Amino acid metabolism in the thermophilic phototroph,Chloroflexus aurantiacus: properties and metabolic role of two l-threonine (l-serine) dehydratases

Two l-threonine (l-serine) dehydratases (EC 4.2.1.16) of the thermophilic phototrophic bacterium Chloroflexus aurantiacus Ok-70-fl were purified to electrophoretic homogeneity by procedures involving anion exchange and hydrophobic interaction chromatography. Only one of the two enzymes was sensitive to inhibition by l-isoleucine (K _i=2 M) and activation by l-valine. The isoleucine-insensitive dehydratase was active with l-threonine (K _m=20 mM) as well as with l-serine (K _m=10 mM) whereas the other enzyme, which displayed much higher affinity to l-threonine (K _m=1.3 mM), was inactivated when acting on l-serine. Both dehydratases contained pyridoxal-5-phosphate as cofactor. When assayed by gel filtration techniques at 20 to 25° C, the molecular weights of both enzymes were found to be 106,000±6,000. In sodium dodecylsulfate-polyacrylamide gel electrophoresis, the two dehydratases yielded only one type of subunit with a molecular weight of 55,000±3,000. The isoleucine-insensitive enzyme was subject to a glucose-mediated catabolite repression.Abbreviations A absorbance - ile isoleucine - PLP pyridoxal-5-phosphate - SDS sodium dodecyl sulfate - TDH threonine dehydratase - U unit     

Mucosal surface ferricyanide reductase activity in mouse duodenum

Mouse duodenum possesses mucosal surface ferricyanide reductase activity. The reducing activity, determined in vitro by measuring ferrocyanide production from ferricyanide, was found to be greater in duodenal fragments when compared with ileal fragments. Experiments with right-side out tied-off duodenal sacs show that reduction occurs mainly on the mucosal side and indicates that the reducing activity is associated with the brush border membrane. Experiments using mice with increased levels of iron absorption (hypoxic, iron-deficient) showed corresponding increases in reducing activity. The increase was present in duodenal but not ileal fragments. Inhibitor studies showed no effect of several compounds which inhibit other, more characterized, transplasma membrane reductases. In particular, doxorubicin (10 m) and quinacrine (1 mm) were without effect on duodenal mucosal transplasma membrane reducing activity. Depolarization of the membrane potential with high medium K ⁺ inhibited reducing activity. N-ethyl malemide (1 mm) was a potent inhibitor, but iodoacetate was found to be less inhibitory. Comparision with inhibitory effects on glyceraldehyde-3-phosphate dehydrogenase (GAPDH) demonstrated that the effect of N-ethyl malemide on reducing activity was not secondary to GAPDH. Collectively these results indicate that mouse duodenum possesses mucosal surface transplasma membrane ferricyanide reductase activity and that the activity is correlated with the process of intestinal iron absorption. Furthermore, the reducing activity appears to be distinct from other reported transplasma membrane reductases.     

Induction by nitrate of cytoplasmic and periplasmic proteins in the photodenitrifier Rhodobacter sphaeroides forma sp. denitrificans under anaerobic or aerobic condition

The synthesis of nitrate, nitrite, and nitrous oxide reductases is highly enhanced by the addition of nitrate during growth of Rhodobacter sphaeroides forma sp. denitrificans. Contrary to what is observed in many denitrifiers, the synthesis of these enzymes is not repressed by oxygen at concentrations as high as 37% air saturation. When oxygen concentration is increased up to 100% air saturation, the synthesis of nitrite and nitrous oxide reductases is repressed while the nitrate reductase is still synthesized. Two proteins, one periplasmic (35kDa) and the other cytoplasmic (32kDa), are also induced by nitrate, but not by trimethylamine-N-oxide or oxygen. Although their function is not yet known, these two proteins appear to be specifically linked to the denitrification pathway. The amino acid sequences of tryptic peptides and of the N-terminal ends of these proteins indicate no significant similarity with the sequences in the Swiss Prot Data Bank. However, a very good alignment is obtained between the amino acid sequences of the periplasmic nitrate reductase of Alcaligenes eutrophus H16 and those of various tryptic peptides of the nitrate reductase of R. sphaeroides forma sp. denitrificans.Abbreviations 2D Two-dimensional - DTT Dithiotreitol - PAGE Polyacrylamide gel electrophoresis - TMAO Trimethylamine-N-oxide - DMSO Dimethylsulfoxide - TMPD N,N,N,N tetramethyl-p-phenylenediamine     

Purification and properties of two 2,5-diketo-d-gluconate reductases from a mutant strain derived from Corynebacterium sp.

Two 2,5-diketo-d-gluconate reductases, I and II, were purified respectively 918-fold and 28-fold from a mutant strain derived from Corynebacterium sp. SHS 0007. The enzymes appeared to be homogeneous on polyacrylamide gel electrophoresis. Both reductases converted 2,5-diketo-d-gluconate to 2-keto-l-gulonate in the presence of NADPH and seemed to be active only for reduction. The molecular weights of reductases I and II were estimated to be 29,000 and 34,000, respectively; and both were monomeric. Their isoelectric points were respectively pH 4.3 and pH 4.1. The optimum pH was 6.0 to 7.0 for reductase I, and 6.0 to 7.5 for reductase II. The K_m values (pH 7.0, 30°C) of reductase I for 2,5-diketo-d-gluconate and for NADPH were 1.8 mM and 12 μM, respectively; and the corresponding values of reductase II were 13.5 mM and 13 μM. Both reductases converted 5-keto-d-fructose to l-sorbose in the presence of NADPH.     

Inheritance and expression of NAD(P)H nitrate reductase in barley

Summary NADH-specific and NAD(P)H bispecific nitrate reductases are present in barley (Hordeum vulgare L.). Wild-type leaves have only the NADH-specific enzyme while mutants with defects in the NADH nitrate reductase structural gene (nar1) have the NAD(P)H bispecific enzyme. A mutant deficient in the NAD(P)H nitrate reductase was isolated in a line (nar1a) deficient in the NADH nitrate reductase structural gene. The double mutant (nar1a;nar7w) lacks NAD(P)H nitrate reductase activity and has xanthine dehydrogenase and nitrite reductase activities similar to nar1a. NAD(P)H nitrate reductase activity in this mutant is controlled by a single codominant gene designated nar7. The nar7 locus appears to be the NAD(P)H nitrate reductase structural gene and is not closely linked to nar1. From segregating progeny of a cross between the wild type and nar1a;nar7w, a line was obtained which has the same NADH nitrate reductase activity as the wild type in both the roots and leaves but lacks NADPH nitrate reductase activity in the roots. This line is assumed to have the genotype Nar1Nar1nar7nar7. Roots of wild type seedlings have both nitrate reductases as shown by differential inactivation of the NADH and NAD(P)H nitrate reductases by a monospecific NADH-nitrate reductase antiserum. Thus, nar7 controls the NAD(P)H nitrate reductase in roots and in leaves of barley.Scientific Paper No. 7617, College of Agriculture Research Center and Home Economics, Washington State University, Pullman, WA, USA. Project Nos. 0233 and 0745     

Adherence of a virulent strain of Listeria monocytogenes to the surface of a hepatocarcinoma cell line via lectin-substrate interaction

Listeria monocytogenes was examined for the presence of surface carbohydrates to ascertain whether surface sugars, if present, would interact with eucaryotic surface carbohydrate receptors. We found that a virulent, but not two avirulent strains had a surface -d-galactose residue as determined by agglutination with Griffonia simplicifolia (GS-I) and other lectins. The virulent strain bound to a human hepatocarcinoma cell line (HepG2), which has a well characterized receptor for -d-galactose. This interaction could be blocked by pretreatment of the HepG2 cells with either -d-galactose or neuraminidase, the latter of which will render the galactose receptor functionally inactive. We propose that the attachment of the virulent Listeria to eucaryotic cells occurs as a result of the interaction of the microbial -d-galactose with that of the eucaryotic galactose receptor. This surface carbohydrate may provide an explanation for the mechanism of attachment and penetration of virulent Listeria into host cells during infection. As such, this may allow for amplication of pathogenesis through intracellular multiplication in nonprofessional phagocytes prior to macrophage involvement.Abbreviations ATCC 19113 and ATCC 4428 Listeria monocytogenes, avirulent strains - EDG Listeria monocytogenes, virulent strain - GS-I Griffonia simplicifolia lectin - GepG2 Human, hepatocarcinoma cells - MES buffer 2(N-Morpholino)-ethane sulfonic acid - PBS buffer phosphate buffered saline This work was carried out and submitted in part by JL to the 47th Annual Westinghouse Science Talent Search while a senior at Union High School, Tulsa, OklahomaRecipient of a National Merit Scholarship Award. Presently attending Southwest Missouri State University, Springfield, Missouri