Chemical intermediates in α-methylnoradrenaline oxidation by tyrosinase—I. Spectral properties and stoichiometry

• 1.1. A pathway for a-methylnoradrenaline oxidation to α-methylnoradrenochrome, by tyrosinase, is proposed. Characterization of intermediates in this oxidative reaction and stoichiometry determination have both been performed.
• 2.2. It has been possible to detect spectrophotometrically o-quinone-H⁺ as the first intermediate in this pathway after oxidizing α-methylnoradrenaline with mushroom tyrosinase or sodium periodate in a pH range from 5 to 6.
• 3.3. The steps for α-methylnoradrenaline transformation into its aminochrome could be: α-methylnoradrenaline → o -α-methylnoradrenaline — H⁺ → o — α -methylnoradrenalinequinone → leuko — α — methylnora — drenochrome→α-methylnoradrenochrome.
• 4.4. No participation of oxygen was detected in the conversion of leuko-α-mehtylnoradrenochrome into α -methylnoradrenochrome.
• 5.5. Matrix analysis of the spectra obtained with a rapid scan spetrophotometer verified that o-quinone-H⁺ was transformed into aminochrome in a constant ratio.
• 6.6. The stoichiometry for this conversion followed the equation: 2 α-methylnoradrenalinequinone-H⁺ → α-methylnoradrenaline + α-methylnoradrenochrome.

     

Chemical intermediates in α-methylnoradrenaline oxidation by tyrosinase—II. Kinetic study of process

• 1.1. The pathway for α-methylnoradrenaline oxidation to α-methylnoradrenochrome by tyrosinase. has been studied as a system of various chemical reactions coupled to an enzymatic reaction.
• 2.2. A theoretical and experimental kinetic approach was proposed for such a system, we named this type of mechanism as a mechanism enzymatic-chemical-chemical (E₂CC).
• 3.3. Rate constants for the implied chemical steps at different temperature and pH values, were evaluated from measurement of the lag period, arising from the accumulation of aminochroine, that took place when α-methylnoradrenaline was oxidized at acid pH.
• 4.4. The thermodynamic activation parameters of the chemical steps, the deprotonation and the internal cyclization of o-quinone into leukoaminochrome, were also calculated.

     

Kinetic studies of the transphosphorylation reactions catalyzed by alkaline phosphatase from E. coli: Hydrolysis of p-nitrophenyl phosphate and o-carboxyphenyl phosphate in presence of tris

• 1.1. Transphosphorylation of p-nitrophenyl phosphate and o-carboxyphenyl phosphate to Tris, has been studied at alkaline and acid pH.
• 2.2. The rate of release for all reactions products was Tris-dependent for both substrates, with a slight maximum for phenol at alkaline pH. These dependences have been analyzed from a mechanistic standpoint.
• 3.3. Individual constants of rate of a simple transphosphorylation mechanism have been determined.
• 4.4. At high Tris concentrations (> 1.0 M) a slight competitive inhibition has been observed.
• 5.5. Inhibition in NH₄⁺-NH₃Cl buffer has been found at alkaline pH but not at acid pH. It would therefore seem that the non-protonated NH₂ group of Tris is responsible for inhibition.
• 6.6. The results suggest the formation of complexes between Tris and the enzyme. Other possible alternatives are also analyzed.

     

The regulation of glucose 6-phosphate dehydrogenase from Dicentrarchus labrax (bass) liver

• 1.1. Kinetic constant values of the reaction catalyzed by bass liver glucose 6-phosphate dehydrogenase show to be modified between 10 and 40°C.
• 2.2. The Arrhenius plot between 10 and 50°C shows two slopes with different activation energies.
• 3.3. These results suggest a regulation of this enzyme by environmental temperature.
• 4.4. Kinetics of ATP inhibition were examined between pH 6.2 and 7.8: patterns and K_i values obtained are affected by the pH variation.
• 5.5. NADH is an effective inhibitor of bass glucose 6-phosphate dehydrogenase but this enzyme does not show NAD-linked activity.
• 6.6. Kinetics of pyridoxal 5′-phosphate inhibition have indicated the presence of a lysine in the catalytic site for NADP⁺.

     

Potassium channels in growth cones of leech retzius cells

• 1.1. Potassium-selective channels were analysed in growth cones of cultured leech Retzius cells.
• 2.2. In the cell-attached mode and at physiological bath and pipette solution little channel activity was observed at resting membrane potential. The channel open probability (p_o) increased with cell depolarization, and the slope conductance of the single K⁺ channel current was about 60 pS.
• 3.3. With symmetrical high KCl solution on both sides of the excised membrane patch three K⁺ -selective channels could be discriminated. Two channels exhibited a linear current-voltage relation of about 18 pS and 106 pS, respectively.
• 4.4. The most frequently observed K⁺ channel showed a non-linear current-voltage relation and p_o increased with increasing free cytoplasmic Ca²⁺ and during cell hyperpolarization.

     

Characterisation of the electron transport chain of an obligate methylotroph,strain 4025

• 1.1. The obligate methanol-utilising bacterium strain 4025 contains cytochromes b and c. Cytochrome a is never present.
• 2.2. The soluble cytochrome c is similar to that from other methylotrophs in reacting (slowly) with carbon monoxide and it can be separated into two types, differing markedly in their isoelectric points.
• 3.3. Some of the cytochrome b reacts rapidly with carbon monoxide and is thus the likely cytochrome oxidase (cytochrome o).
• 4.4. The partially purified, NAD⁺-independent methanol dehydrogenase is similar to such enzymes from the other methanol-utilising bacteria in respect of its prosthetic group, dependence on ammonia or methylamine for activity and its wide substrate specificity.
• 5.5. The fluorescence seen in colonies of this organism is probably due to a flavin derivative.
• 6.6. This study of electron transport components does not shed any light on the unusually high copper requirement shown by this methylotroph.

     

Calcium-dependent potassium conductance in the photoresponse of a nudibranch mollusk

• 1.1. The response to light of Hermissenda photoreceptors when recorded intracellularly without interference from synaptic and action potentials consisted of three phases: an early depolarization (ED) followed by hyperpolarization (dip) and subsequent depolarization (tail).
• 2.2. The ED and the dip were associated with increased membrane conductance while decreased membrane conductance was involved with the tail.
• 3.3. The dip reversal potential was − 82.1 ± 5.3 mV and its amplitude varied inversely with the log of [K⁺].
• 4.4. Perfusing with agents which block K⁺ current like 4AP, Quinine, Quinidine or injection of TEA eliminated the dip and its associated increased membrane conductance, thus further supporting the role of K⁺ conductance in producing the dip.
• 5.5. The dip was enhanced by increased [Ca²⁺]_o, reduced by decreased [Ca²⁺]_o and abolished together with its associated increased membrane conductance when perfused with either D600, Cd²⁺, Mg²⁺, Mn²⁺, or Co²⁺, which block transmembrane Ca²⁺ current.
• 6.6. The dip and its associated increased membrane conductance were abolished by intracellular injection of EGTA and enhanced by perfusion with Ruthenium red.
• 7.7. Intracellular injection of Ca²⁺ mimicked the dip: membrane conductance was increased and the cell hyperpolarized.
• 8.8. These results indicate that the increase in intracellular [Ca²⁺] is primarily responsible for the light-induced increase of K⁺ conductance during the dip. The possible source of the Ca²⁺ is, at least in part, extracellular due to activation of an inward Ca²⁺ current.

     

Blood volume recovery in hemorrhaged japanese quail

• 1.1. Blood volume and plasma biochemical changes and feed and water consumption in response to a hemorrhage by phlebotomy of 30% of the calculated total blood volume with and without replacement of blood volume with physiological saline were determined in juvenile male Coturnix coturnix japonica.
• 2.2. Plasma protein and osmolality decreased rapidly posthemorrhage and did not recover by 72 hr posthemorrhage.
• 3.3. Plasma glucose, Na⁺ and K⁺ increased within Ihr postphlebotomy. Plasma Na⁺ returned to nonphlebotomized levels within 6 hr postphlebotomy.
• 4.4. Saline replacement of blood volume resulted in hypervolemia within 3–5 min postphlebotomy.
• 5.5. Phlebotomized quail receiving no saline recovered blood volume to 0 hr (nonphlebotomized) levels within l hr postphlebotomy.

     

Calcium uptake in the gorgonian Leptogorgia virgulata. The effects of atpase inhibitors

• 1.1. Longitudinally split or completely regenerated branch tips from Leplogorgia virgulata show no differences in calcium uptake between control and ouabain treatments. This indicates that there is no ouabain sensitive Na⁺, K⁺-ATPase involved in calcium uptake.
• 2.2. The tissue fractions of both regenerated and split branch tips show, at certain times, higher calcium uptake than control fractions. In the spicule fractions of these tips calcium uptake decreases in vandate treated specimens.
• 3.3. Pulse-chase experiments show an initial rapid release of calcium from the tips into surrounding seawater.
• 4.4. The results may suggest the presence of outwardly directed calcium pumps on the basal/lateral and apical plasma membranes of the epithelial cells. Outwardly directed calcium pumps may also be envisaged on the cell membranes of scleroblasts. In addition, pumps may move calcium into specific organelles of the scleroblasts en route to the spicule forming vacuoles.
• 5.5. These pumps are likely to be Ca²⁺-ATPase.

     

Ionic dependence and vanadate sensitivity of (Na+, K+)-ATPase isolated from branchial sac of ascidians

• 1.1. Ion dependence and vanadium-induced inhibition on branchial sac ATPase in five species of ascidian Phlebobranchiata (vanadium-accumulating) and Stolidobranchiata (iron-accumulating) were studied.
• 2.2. The ATPase was obtained from the microsomal fraction, which was prepared from each ascidian branchial sac.
• 3.3. The ATPase was dependent on Mg²⁺ and activated by exogenous Na⁺ + K⁺.
• 4.4. Ouabain inhibited the ATPase activity in vitro, 10 μM to 100 μM vanadate, in vitro, suppressed the (Na⁺, K⁺)-ATPase.

     

Modulation of active potassium transport by aldosterone

• 1.1. The role of aldosterone on active potassium transport across lizard colon under voltage-clamped conditions has been investigated.
• 2.2. Control colons exhibited no net potassium flux (J^k_net) despite of the existence of active opposite unidi ectional fluxes.
• 3.3. An important net secretory potassium flux was found in short-circuited aldosterone-stimulated colons.
• 4.4. Mucosal amiloride did not change (J^k_net) either in control or aldosterone-stimulated colons.
• 5.5. Luminal barium alters K ⁺ transport in a manner consistent with the presence of barium-sensitive conductances at the apical membrane of both control and aldosterone-treated colons.
• 6.6. The effects of ouabain and barium on control and aldosterone-induced potassium flows were consistent with a model involving basolateral uptake by an Na ⁺-K ⁺-ATPase and conductive exit across the apical membrane.
• 7.7. The stimulatory effect of aldosterone on potassium secretion is associated with parallel increases of both basolateral K ⁺ entry and the apical conductive pathway.

     

Nacl flux in the flounder (Pseudopleuronectes americanus) intestine: Effects of ph and transport inhibitors

• 1.1. The effects of extracellular pH on Na⁺ and Cl⁻ absorption were studied in vitro in the small intestine of the winter flounder, Pseudopleuronectes americanus.
• 2.2. Reductions in bathing solution pH inhibited J_ms^na (mucosal-to-serosal flux) and J_net^na (net flux) (r = 0.90) and J_net^Cl (r = 0.92) [due to an increase in J_sm^Cl, (serosal-to-mucosal)] and decreased short circuit current (Isc).
• 3.3. Luminal bumetanide (0.1 mM) and amiloride (1 mM) inhibited Na⁺ and Cl⁻ absorption by reducing J_ms.
• 4.4. Luminal barium (5mM) and luminal copper (100 μM) decreased J_ms^Cl and increased J_sm^Cl.
• 5.5. We conclude that reductions in extracellular pH inhibit a luminal membrane NaCl absorptive process (Na⁺-K⁺-2Cl⁻) and stimulate an electrogenic Cl⁻ secretory process.

     

Sodium and potassium balance of captive meadow voles (Microtus pennsylvanicus) fed laboratory chow and vegetation diets

• 1.1. Mineral balance was studied in meadow voles (Microtus pennsylvanicus) maintained in the laboratory.
• 2.2. Urine and fecal Na⁺ contents of voles on low-Na⁺ diets were comparable to those reported for other herbivore species, but urine and fecal K levels were higher.
• 3.3. Voles approached Na⁺ balance (input = output) on diets with Na⁺ content as low as 56 ppm.
• 4.4. There was not a clearcut hypertrophy of the adrenal-gland zona glomerulosa in voles maintained on low-Na⁺ diets.
• 5.5. Plasma K content and bone water content were higher in voles maintained on high-Na ⁺ vegetation diets, suggesting expansion of extracellular fluid volume.

     

Characterization of NaK ATPase from the gills of the freshwater prawn Macrobrachium rosenbergii (de Man)

• 1.1. The specific activity of Na-K ATPase was determined from the microsomal preparation of gills dissected from adult Macrobrachium rosenbergii.
• 2.2. Maximal ATPase activity was achieved at a substrate concentration of 0.5 mM ATP.
• 3.3. Optimal enzyme activity was obtained at pH of 7.5.
• 4.4. The Arrhenius plot of Na-K ATPase activity revealed a marked discontinuity at 30°C. “Mg” ATPase activity did not exhibit a marked discontinuity.
• 5.5. The E_a for Na-K ATPase and “Mg” ATPase was 14.6 kCal/mole and 9.31 kCal/mole respectively. Q₁₀ values for Na-K ATPase was 2.34 and for “Mg” ATPase 1.65.
• 6.6. ATPase activity and gill homogenate protein concentration exhibited a linear relationship up to 130 μg protein/ml.
• 7.7. Na-K ATPase activity was inhibited by 10⁻³ M ouabain. It was equally inhibited by the removal of K⁺ from the reaction medium.

     

Aluminium and calcium affect the perivitelline fluid in fish eggs

• 1.1. Microelectrodes have been used to measure K⁺ activities and electrical potential differences between the perivitelline fluid (pvf) of the eggs of pike (Esox lucius) and surrounding water in a range of pH, calcium and aluminium concentrations.
• 2.2. Potential differences between pvf and water are decreased by Ca²⁺ (10⁻³ M) while Al³⁺ (18 × 10⁻⁶ M) reverses the polarity of the potential difference.
• 3.3. K⁺ activities in the pvf of eggs in 10⁻⁴M KCl + 10⁻⁵M NaCl are decreased by Ca²⁺(10⁻³ M).
• 4.4. The results are discussed with reference to ion-exchange theory and chorion permeability.

     

Evidence for the presence of ion pumps in the photophores of two mesopelagic fishes: Argyropelecus and maurolicus

• 1.l. Adenosine triphosphatase (ATPase) activity has been measured on homogenates of photophores from the two mesopelagic fishes Argyropelecus and Maurolicus. This activity is equivalent for both fishes when reported to the protein content as is their O₂ consumption.
• 2.2. The activity is optimal at pH 6.8–7.5. It is not specific for ATP since GTP, ITP, UTP and CTP are also hydrolyzed to a significant extent. It is also not specific for Mg²⁺, the activity being equivalent (Argyropelecus) or higher (Maurolicus) with Ca²⁺ and high also with Co²⁺ and Mn²⁺
• 3.3. Twenty to 30 per cent of the activity measured at pH 7.4 is probably due to the mitochondrial ATPase as it is shown by oligomycin and venturicidin inhibition.
• 4.4. Activities of both fishes photophores are partly inhibited by N-N'-dicyclohexylcarbodiimide (DCCD), azide, LaCl₃, vanadate, diethylstilbestrol (DES) and N-ethylmaleimide (NEM) which are all inhibitors of ionic pumps.
• 5.5. Argyropelecus activity is sensitive to ouabaïn.
• 6.6. Our results show the presence of ionic pumps in Argyropelecus and Maurolicus photophores. If there is evidence for the absence or very low activity of a H⁺ pump, it is sure that Argyropelecus at least possess a Na⁺K⁺-ATPase.
• 7.7. The significance of a high protein content in Maurolicus photophores and of a large inorganic phosphate concentration in Argyropelecus is discussed.

     

S-Adenosyl-l-methionine decarboxylase activities in Mytilus edulis

• 1.1. The activities of S-adenosylmethionine decarboxylase (EC 4.1.1.50) were measured in cell extracts of mantle, hepatopancreas and foot from Mytilus edulis.
• 2.2. The apparent molecular weights of the enzymes estimated by gel filtration chromatography were 65,000 ± 10,000.
• 3.3. The enzymes do not require bivalent cations for catalysis and show optimum pH between 7.0–8.0 in phosphate buffer.
• 4.4. The hepatopancreas enzyme shows different behavior to the other two enzymes against temperature and its activity is strongly inhibited by NH₄⁺.
• 5.5. The apparent K_ms for S-adenosylmethionine were found to be 300, 200 and 250 μM for the hepatopancreas, mantle and foot enzymes, respectively.

     

Acid and alkaline phosphomonoesterase activities in snake venoms

• 1.1. Acid and alkaline phosphatase activities of eight different snake venoms were determined quantitatively by using synthetic substrates, o-carboxyphenylphosphate and p-nitrophenylphosphate respectively.
• 2.2. It was found that most of Elapidae venoms investigated had both acid and alkaline phosphatase activities.
• 3.3. Three Crotalidae venoms investigated did not show any alkaline phosphatase activity.
• 4.4. The strength of venom acid phosphatase activity is as follows: Agkistroden acutus > Naja haje > Naja naja samarensis > Naja naja atra > Naja melanoleuca.
• 5.5. The strength of venom alkaline phosphatase activity by using p-nitrophenylphosphate is in the order of Naja hannah > Naja haje > Naja naja samarensis > Naja naja atra > Naja melanoleuca.When o-carboxyphenylphosphate was used as a substrate, the order of enzyme activity is Naja hannah > Naja haje > Naja naja samarensis > Naja melanoleuca > Naja naja atra.
• 6.6. Acid phosphatase activity of all the Elapidae venoms was inhibited completely by fluoride. The alkaline phosphatase activity of Elapidae venoms was not inhibited by fluoride either using p-nitrophenylphosphate or o-carboxyphenylphosphate.
• 7.7. The acid phosphatase of all the Elapidae venoms was not inhibited by zinc ion. However, most of the venom alkaline phosphatases were inhibited by zinc ion.
• 8.8. Ethylenediaminetetraacetic acid (EDTA) had inhibitory action on venom phosphatase activity. However, tris-(hydroxymethyl)-aminoethane had a counter effect on the inhibitory action of EDTA.
• 9.9. Optimum pH studies of the snake venom phosphatases showed that the acid phosphatases of the snake venoms had their highest activity in the range of pH 4–5. The alkaline phosphatases of the snake venoms had their optimum pH at 9.
• 10.10. Comparable experiments were also conducted by using chicken intestine alkaline phosphatase and wheat germ acid phosphatase.

     

Na+-K+ ATPase and carbonic anhydrase activities in larvae,postlarvae and adults of the shrimp Penaeus japonicus (Decapoda,Penaeidea)

• 1.1. Activities of Na⁺-K⁺ ATPase and carbonic anhydrase were measured through the early post-embryonic development of Penaeusjaponicus. In adults, only the Na⁺-K⁺ ATPase activity was measured.
• 2.2. ATPase activity was variable in the successive development stages. From zero in nauplii, the activity slightly increased in zoeae, and rose sharply in mysis stages 2 and 3.
• 3.3. A further significant increase in activity was noted at the transition from late mysis to early postlarvae, concomitant with a change from the larval osmoconforming pattern of osmoregulation to the postlarval and adult hyper-hyporegulating pattern.
• 4.4. The activity of Na⁺-K⁺ ATPase, measured in isolated cephalothorax, increased from PL3 to PL4 to its maximum value in PL5; at this stage, osmoregulatory capacity was fully efficient.
• 5.5. In young stages of P. japonicus, the variations in Na⁺-K⁺ ATPase activity appear correlated with the development of osmoregulatory ultrastructures, and with osmoregulation and salinity tolerance.
• 6.6. These results are discussed with regard to their ecological and physiological implications.
• 7.7. In adults, the activity of Na⁺-K⁺ ATPase was high in gills and epipodites and no activity was detected in branchiostegites. These results are related to the ultrastructure of these organs.
• 8.8. The activity of carbonic anhydrase did not change significantly in larval and postlarval stages.
• 9.9. From these results, it is proposed that the effector sites of osmoregulation are located in branchiostegites, pleurae and epipodites in postlarvae, and in epipodites and mainly in gills in adults.

     

Identification of essential amino acids in the active center of thyroidal NAD+ glycohydrolase

• 1.1. Purified thyroidal NAD⁺ glycohydrolase has been subjected to the action of a number of group specific reagents in order to gain information concerning its mode of action.
• 2.2. Modification of histidyl residues with diethylpyrocarbonate strongly suppresses the NAD⁺ glycohydrolase activity. Inactivation with this reagent can be reversed to some extent by subsequent treatment with hydroxylamine.
• 3.3. NAD⁺ and ADP-ribose partially protect against inactivation with similar efficiencies.
• 4.4. The incomplete reactivation with hydroxylamine after diethylpyrocarbonate treatment and the selective inactivation by 2,4-pentanedione indicates that apart from one or more essential histidyl residue(s) also lysyl residues are important for activity. NAD⁺ and to a smaller extent ADP-ribose again protect against inactivation by 2,4-pentanedione.
• 5.5. The sensitivity of the enzyme towards N-ethyl-5-phenyl-isooxazolium-3'-sulfonate further points to the importance of carboxylate containing side chains.
• 6.6. The mechanistic implications of these results are discussed.