Rapid Modulation of Spinach Leaf Nitrate Reductase Activity by Photosynthesis : I. Modulation in Vivo by CO(2) Availability

It has been shown recently that in spinach leaves (Spinacia oleracea) net photosynthesis and nitrate reduction are closely linked: when net photosynthesis was low because of stomatal closure, rates of nitrate reduction decreased (WM Kaiser, J Förster [1989] Plant Physiol 91: 970-974). Here we present evidence that photosynthesis regulates nitrate reduction by modulating nitrate reductase activity (NRA, EC 1.6.6.1). When spinach leaves were exposed to low CO₂ in the light, extractable NRA declined rapidly with a half-time of 15 minutes. The inhibition was rapidly reversed when leaves were brought back to air. NRA was also inhibited when leaves were wilted in air; this inhibition was due to decreased CO₂ supply as a consequence of stomatal closure. The modulation of NRA was stable in vitro. It was not reversed by gel filtration. In contrast, the in vitro inhibition of nitrate reductase (NR) by classical inhibitors such as cyanide, hydroxylamin, or NADH disappeared after removal of free inhibitors by gel filtration. The negative modulation of NRA in —CO₂-treated leaves became manifest as a decrease in total enzyme activity only in the presence of free Mg²⁺ or Ca²⁺. Mg²⁺ concentrations required for observing half-maximal inhibition were about 1 millimolar. In the presence of EDTA, the enzyme activity was always high and rather independent of the activation status of the enzyme. NRA was also independent of the pH in the range from pH 7 to pH 8, at saturating substrate and Mg²⁺ concentrations. The apparent substrate affinities of NR were hardly affected by the in vivo modulation of NR. Only V_max changed.     

Nitrate Reduction in Response to CO(2)-Limited Photosynthesis : Relationship to Carbohydrate Supply and Nitrate Reductase Activity in Maize Seedlings

The effects of CO₂-limited photosynthesis on ¹⁵NO₃⁻ uptake and reduction by maize (Zea mays, DeKalb XL-45) seedlings were examined in relation to concurrent effects of CO₂ stress on carbohydrate levels and in vitro nitrate reductase activities. During a 10-hour period in CO₂-depleted air (30 microliters of CO₂/ per liter), cumulative ¹⁵NO₃⁻ uptake and reduction were restricted 22 and 82%, respectively, relative to control seedlings exposed to ambient air containing 450 microliters of CO₂ per liter. The comparable values for roots of decapitated maize seedlings, the shoots of which had previously been subjected to CO₂ stress, were 30 and 42%. The results demonstrate that reduction of entering nitrate by roots as well as shoots was regulated by concurrent photosynthesis. Although in vitro nitrate reductase activity of both tissues declined by 60% during a 10-hour period of CO₂ stress, the remaining activity was greatly in excess of that required to catalyze the measured rate of ¹⁵NO₃⁻ reduction. Root respiration and soluble carbohydrate levels in root tissue were also decreased by CO₂ stress. Collectively, the results indicate that nitrate uptake and reduction were regulated by the supply of energy and carbon skeletons required to support these processes, rather than by the potential enzymatic capacity to catalyze nitrate reduction, as measured by in vitro nitrate reductase activity.     

Periplasmic Cytochrome c3 of Desulfovibrio vulgaris Is Directly Involved in H2-Mediated Metal but Not Sulfate Reduction

Kinetic parameters and the role of cytochrome c₃ in sulfate, Fe(III), and U(VI) reduction were investigated in Desulfovibrio vulgaris Hildenborough. While sulfate reduction followed Michaelis-Menten kinetics (K_m = 220 μM), loss of Fe(III) and U(VI) was first-order at all concentrations tested. Initial reduction rates of all electron acceptors were similar for cells grown with H₂ and sulfate, while cultures grown using lactate and sulfate had similar rates of metal loss but lower sulfate reduction activities. The similarities in metal, but not sulfate, reduction with H₂ and lactate suggest divergent pathways. Respiration assays and reduced minus oxidized spectra were carried out to determine c-type cytochrome involvement in electron acceptor reduction. c-type cytochrome oxidation was immediate with Fe(III) and U(VI) in the presence of H₂, lactate, or pyruvate. Sulfidogenesis occurred with all three electron donors and effectively oxidized the c-type cytochrome in lactate- or pyruvate-reduced, but not H₂-reduced cells. Correspondingly, electron acceptor competition assays with lactate or pyruvate as electron donors showed that Fe(III) inhibited U(VI) reduction, and U(VI) inhibited sulfate loss. However, sulfate reduction was slowed but not halted when H₂ was the electron donor in the presence of Fe(III) or U(VI). U(VI) loss was still impeded by Fe(III) when H₂ was used. Hence, we propose a modified pathway for the reduction of sulfate, Fe(III), and U(VI) which helps explain why these bacteria cannot grow using these metals. We further propose that cytochrome c₃ is an electron carrier involved in lactate and pyruvate oxidation and is the reductase for alternate electron acceptors with higher redox potentials than sulfate.     

A Short-Term Decrease in Nitrogenase Activity (C2H2 Reduction) Is Induced by Exposure of Soybean Shoots to Their CO2 Compensation Point

Photosynthesis and nitrogenase acetylene-reducing activity (ARA) were measured in soybeans (Glycine max [L.] Merr.) in which the shoots were exposed for 48 h to 60 [mu]L L-1 CO2, a value corresponding to their CO2 compensation point. Six hours after the beginning of the light period at low CO2, the ARA started to decrease, reaching a rate of 50% of the control rate in 14 to 24 h and 20% of the control rate in 34 to 38 h after the beginning of the CO2 treatment. At these times, there was no net photosynthesis, and the transpiration rate was 20% lower than that in the control plants. An increase in the partial pressure of O2 around the nodules alleviated this inhibition of ARA. The maximal ARA achieved at 40 kPaO2 was 3 times higher than that at 20 kPa O2 and similar to the maximal ARA of the control plants. It was argued that the decrease in ARA of soybean exposed to the CO2 compensation point was due to a decrease in the nodule's permeability to O2 diffusion.     

The Intracellular Component of Cellular 3-(4,5-Dimethylthiazol-2-yl)-2,5-Diphenyltetrazolium Bromide (MTT) Reduction Is Specifically Inhibited by β-Amyloid Peptides

Abstract: In vitro cell culture model systems for investigating the biochemical mechanisms involved in the neurodegenerative actions of β-amyloid peptide (β-AP) have been established. Using rat pheochromocytoma PC12 or human epitheloid HeLa cell lines, submicromolar concentrations of the β-AP fragments β1–40, β1–39, and β25–35, but not β1–28, were found to inhibit the reduction of the redox dye 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT). In both cell lines, the β-AP-sensitive component represented ∼70% of total cellular MTT reduction. When the reduction of a series of structurally related dyes was compared with that of MTT, the reduction of 3α-naphthyl-2-phenyl-5-(4-nitrophenyl)-2 H -tetrazolium chloride (NTV) was also found to be sensitive to β25–35, but that of seven other redox dyes was not. A property common to MTT and NTV is that they are both readily taken up into PC12 and HeLa cells and do not require an artificial electron coupling agent to be reduced. Microscopic analysis of MTT-formazan product formation in PC12 and HeLa cells following β25–35 treatment revealed that it was the intracellular component of the reduction of this dye that was abolished. These results support the hypothesis that the cellular reduction of MTT represents a specific indicator of the initial events underlying the mechanism of β-AP toxicity.     

Investigation of the Apparent Induction of Nitrate Uptake in Barley (Hordeum vulgare L.) Using NO3--Selective Microelectrodes (Modulation of Coarse Regulation of NO3- Uptake by Exogenous Application of Downstream Metabolites in the NO3- Assimilatory Pathway)

The influence of a 12-h pretreatment with either NO3-, NH4+, glutamine, or glutamate (300 [mu]M) on the apparent induction of NO3- uptake was investigated. Net fluxes of NO3- into roots of intact, 7-d-old barley (Hordeum vulgare L. cv Prato) seedlings in solution culture were estimated from ion activity gradients measured with NO3--selective microelectrodes in the unstirred layer of solution immediately external to the root surface. Control plants, pretreated with nitrogen-free nutrient solution, exhibited a sigmoidal increase in net NO3- uptake, reaching a maximum rate between 8 and 9 h after first exposure to NO3-. Plants pretreated with NH4+ or Glu exhibited a delay of several hours in the initiation of the induction process after they had been exposed to NO3-. In Gln-pretreated plants, however, responses ranged from no delay of the induction process to delays comparable to those observed following NH4+ or Glu pretreatments. Only treatment with NO3-resulted in the induction of NO3- uptake, whereas pretreatments with NH4+, Gln, or Glu tended to delay induction of NO3- uptake upon subsequent exposure to NO3-.     

The Full-Length, Cytoplasmic C-Terminus of the β2-Adrenergic Receptor Expressed in E. coli Acts as a Substrate for Phosphorylation by Protein Kinase A, Insulin Receptor Tyrosine Kinase, GRK2, but Not Protein Kinase C and Suppresses Desensitization when Expressed in Vivo

The ability of the cytoplasmic, full-length C-terminus of the β2-adrenergic receptor (BAC1) expressed in Escherichia coli to act as a functional domain and substrate for protein phosphorylation was tested. BAC1 was expressed at high-levels, purified, and examined in solution as a substrate for protein phosphorylation. The mobility of BAC1 on SDS–PAGE mimics that of the native receptor itself, displaying decreased mobility upon chemical reduction of disulfide bonds. Importantly, the C-terminal, cytoplasmic domain of the receptor expressed in E. coli was determined to be a substrate for phosphorylation by several candidate protein kinases known to regulate G-protein-linked receptors. Mapping was performed by proteolytic degradation and matrix-assisted laser desorption ionization, time-of-flight mass spectrometry. Purified BAC1 is phosphorylated readily by protein kinase A, the phosphorylation occurring within the predicted motif RRSSSK. The kinetic properties of the phosphorylation by protein kinase A displayed cooperative character. The activated insulin receptor tyrosine kinase, which phosphorylates the beta-adrenergic receptor in vivo, phosphorylates BAC1. The Y364 residue of BAC1 was predominantly phosphorylated by the insulin receptor kinase. GRK2 catalyzed modest phosphorylation of BAC1. Phosphorylation of the human analog of BAC1 in which Cys341 and Cys378 were mutated to minimize disulfide bonding constraints, displayed robust phosphorylation following thermal activation, suggesting under standard conditions that the population of BAC1 molecules capable of assuming the “activated” conformer required by GRKs is low. BAC1 was not a substrate for protein kinase C, suggesting that the canonical site in the second cytoplasmic loop of the intact receptor is preferred. The functional nature of BAC1 was tested additionally by expression of BAC1 protein in human epidermoid carcinoma A431 cells. BAC1 was found to act as a dominant-negative, blocking agonist-induced desensitization of the beta-adrenergic receptor when expressed in mammalian cells. Thus, the C-terminal, cytoplasmic tail of this G-protein-linked receptor expressed in E. coli acts as a functional domain, displaying fidelity with regard to protein kinase action in vivo and acting as a dominant-negative with respect to agonist-induced desensitization.