Seasonal changes in the structure and function of mitochondrial membranes of artichoke tubers: acyl Fatty Acid composition and the effect of growth conditions

Changes in the temperature response, fluidity, function and the acyl fatty acid composition, were determined for a mitochondria-rich membrane fraction from Jerusalem artichoke (Helianthus tuberosus L.) tubers during dormancy for a crop which matured in midsummer. The temperature of both the upper and lower limits of the membrane lipid transition decreased during dormancy from 26 C and 1 C to 4 C and −5 C, respectively. This was similar to the changes observed with crops maturing in late autumn. The order parameter of a spin label intercalated into the membrane lipids decreased from about 0.6 to 0.5 during dormancy and returned to the original value before sprouting, showing that membrane fluidity increased during dormancy. The activation energy of succinate oxidase of tuber mitochondria was generally high at middormancy when membrane lipids were more fluid and decreased as the membranes became more rigid at the end of dormancy. The fatty acid composition of the membrane lipids did not alter significantly during dormancy. The results indicate that neither decreasing day length nor low soil temperature during tuber maturation is essential for the initiation of the membrane changes necessary for tubers to avoid low temperature injury during dormancy. The increase in membrane fluidity during dormancy could not be accounted for by an increase in the proportion of unsaturated fatty acids in the membrane lipids.     

An Analysis of the Relationship between Respiration and the Transmembrane Potential in Corn Roots

The effects of cyanide, anoxia, and temperatures varying from 2 to 42 C on the cell membrane electropotential difference (PD) of washed and freshly excised corn roots have been determined. Respiration rates of freshly excised root segments in response to cyanide and to varying temperatures were also measured. The cell membrane PD of roots which had been washed for 12 to 15 hours was almost insensitive to cyanide and anoxia but sensitive to low temperature. In contrast, the cell membrane PD of freshly excised roots was reversibly depolarized by all three treatments, cyanide depolarized from −117 to −86 millivolts and the sequential imposition of anoxia further lowered the PD to −69 millivolts. Anoxia applied first depolarized maximally and the PD was not further lowered by sequential cyanide treatment. Arrhenius plot analysis of the temperature response of respiration showed an apparent transition at 13 C with an activation energy of 20.0 kilocalories per mole below and 8.8 kilocalories per mole above the transition temperatures. The energy of activation for repolarization of PD is much higher; 53.4 kilocalories per mole below 7 to 8 C and 25.4 kilocalories per mole above this apparent transition. The energy requirement for polarization of the cell membrane PD was calculated based on the temperature responses of the cell membrane PD and respiration. It was estimated that 3.5% of the energy output from respiration at 22 C is required for cell polarization. It is unlikely that ion transport is limited by energy availability below the 8 C transition in this chill sensitive species.     

USE OF ARRHENIUS PLOTS OF Na-K ATPase and ACETYLCHOLINESTERASE AS A TOOL FOR STUDYING CHANGES IN LIPID-PROTEIN INTERACTIONS IN NEURONAL MEMBRANES DURING BRAIN DEVELOPMENT

Abstract— The activities of Na-K ATPase and acetylcholinesterase in the rat brain cortex were measured at different postnatal ages as a function of temperature. It was found that compared to acetylcholinesterase, Na-K ATPase is more strongly affected by the rise in temperature and that this response is further enhanced with age. Arrhenius plots of the data were prepared and the apparent energies of activation were computed for each plot. It was observed that all plots were biphasic except that for Na-K ATPase of the immature (5-day-old) brain which showed no transition temperature, with an apparent energy of activation of 15.5 kcal/mol. The enzyme from the mature brain (25-day-old) showed an average transition temperature of 22.6°C, with average apparent energies of activation of 15.3 and 27.2 kcal/mol above and below the transition temperature respectively. The cortex of 1-day-old rat showed no Na-K ATPase activity. Arrhenius plots of acetylcholinesterase studied at ages 1, 5 and 25 days postnatally all showed transition temperatures which increased from an average of 16.1°C for 1-day-old to 17 and 21.5°C for 5- and 25-day-old animals respectively. The average apparent energies of activation for acetylcholinesterase below the transition temperature changed from 8.3 kcal/mole at day 1 to 8.7 and 7.2 kcal/mol at days 5 and 25, while above the transition temperature they were 4.3, 5.2 and 4.1 at days 1, 5 and 25 respectively. The results are discussed in terms of the differences and changes in the interactions of Na-K ATPase and acetylcholinesterase with membrane lipids during the postnatal phase of brain development.     

Temperature dependence and Arrhenius activation energy of F-actin velocity generated in vitro by skeletal myosin.

The effect of temperature on the velocity of rhodamine phalloidin-labelled F-actin moving in vitro on rabbit skeletal myosin has been studied. Translating actin filaments were visualized by epi-fluorescence in an inverted microscope, equipped with temperature control (+/- 0.2 K) of the stage and objective. Images were recorded in real time at magnifications of 400x or 160x by an intensified CCD camera on video tape. Motion of individual filaments was tracked by hand and velocities determined using frame times recorded simultaneously on the video tape. Velocity changed from 12 microns per second at 42 degrees C to 11 nm per second at 3 degrees C. The Arrhenius plot is non-linear, with the data following a cubic regression curve with no evident breaks or jumps. Data taken over the temperature range from single preparations followed the same curve for both heating and cooling; this indicates reversibility and absence of hysteresis. A hyperbolic model that smoothly translates with temperature between two asymptotic activation energies fits the data above 7 degrees C: these energies are 50(+/- 5) kJ per mole (Q10 = 1.9) at high temperatures and 289(+/- 29) kJ per mole (Q10 = 76.5) at low temperature with a transition temperature of 15.4(+/- 0.6) degrees C. These values are compared with other measurements made in vitro, in solution studies and on muscle fibres. An Arrhenius activation energy of 50 kJ per mole and a transition temperature of 15 degrees C are consistent with previous determinations but 289 kJ per mole is significantly greater than has been seen at low temperatures in other systems. This may indicate a different rate-limiting step in the kinetics of skeletal myosin driving actin filaments in vitro below 15 degrees C. Current determinations of the myosin "step-size" assume that the actin velocity is determined by the rate of ATP hydrolysis; the data confirm similar activation energies above 20 degrees C but they show that the temperature dependencies and activation energies are different at lower temperatures, implying uncoupling of the two processes.     

Wheat mitochondria: oxidative activity and membrane lipid structure as a function of temperature

Mitochondrial oxidative activity and membrane lipid structure of two wheat (Triticum aestivum L.) cultivars were measured as a function of temperature. The Arrhenius activation energy for the oxidation of both succinate and α-ketoglutarate was constant over the temperature range of 3 to 27 C. The activation energy for succinate-cytochrome c oxidoreductase activity was also constant over the same temperature range. The concentration of mitochondria in the reaction, the degree of initial inhibition of state 3 respiration, and the time after isolation of mitochondria were each shown to be capable of causing a disproportionate decrease in the rate of oxidation at low temperatures which resulted in an apparent increase in the activation energy of oxidative activity. Using three spin-labeling techniques, wheat membrane lipids were shown to undergo phase changes at about 0 C and 30 C. It is concluded that the membrane lipids of wheat, a chillingresistant plant, undergo a phase transition similar to the transition observed in the membrane lipids of chilling-sensitive plants. For wheat, however, the transition is initiated at a lower temperature and extends over a wider temperature range.     

In vitro stability of nitrate reductase from wheat leaves: I. Stability of highly purified enzyme and its component activities

NADH-nitrate reductase has been highly purified from leaves of 8-day-old wheat (Triticum aestivum L. cv. Olympic) seedlings by affinity chromatography, using blue dextran-Sepharose 4B. Purification was assessed by polyacrylamide gel electrophoresis. The enzyme was isolated with a specific activity of 23 micromoles nitrite produced per minute per milligram protein at 25 C. At pH 7.5, the optimum pH for stability of NADH-nitrate reductase, this enzyme, and a component enzyme reduced flavin adenine mononucleotide (FMNH₂)-nitrate reductase has a similar stability at both 10 and 25 C. Two other component enzymes—methylviologen-nitrate reductase and NADH-ferricyanide reductase—also have a similar but higher stability. At this pH the Arrhenius plot for decay of NADH-nitrate reductase and methylviologen-nitrate reductase indicates a transition temperature at approximately 30 C above which the energy of activation for denaturation increases. FMNH₂-nitrate reductase and NADH-ferricyanide reductase do now show this transition. The energy of activation for denaturation (approximately 9 kcal per mole) of each enzyme is similar between 15 and 30 C. The optimum pH for stability of the component enzymes was: NADH-ferricyanide reductase, 6.6; FMNH₂-nitrate reductase and methylviologen-nitrate reductase, 8.9. All of our studies indicate that the NADH-ferricyanide reductase was the most stable component of the purified nitrate reductase (at pH 6.6, t_½ [25 C] = 704 minutes). Data are presented which suggest that methylviologen and FMNH₂ do not donate electrons to the same site of the nitrate reductase protein.     

Isolation of NADH Oxidation System from the Plasmalemma of Corn Root Protoplasts

A plasmalemma-bound NADH oxidation system (Lin 1982 Proc Natl Acad Sci USA 79: 3773-3776) in corn root protoplasts was isolated by a mild treatment of intact protoplasts with trypsin. The majority of NADH stimulated O₂ consumption activity of the protoplasts could be recovered in the supernatant isolated from the intact protoplasts which have been treated with trypsin. The activation energy of NADH oxidation in the supernatant is similar to that of the intact protoplasts (8.7 versus 9.4 kilocalories per mole per degree). Unlike that of the intact protoplasts, an Arrhenius plot of the temperature response (from 5 to 25°C) of the activity in the supernatant shows no transition suggestive of a dissociation of the enzyme from the membrane. Trypsin treatment did not affect K⁺ uptake into cell volume of the protoplast. However, the NADH-stimulated K⁺ uptake and the increase of cell volume were greatly reduced. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of trichloroacetic acid-precipitated protein from the supernatant showed one extra peptide band with ~42 kilodalton molecular weight.     

Temperature-dependent kinetics of the activities of influenza virus

The temperature dependence of membrane interactions between PR8 influenza virus and virus receptor (GD1a)-containing liposomes was studied. For quantitation, the octadecylrhodamine B chloride (R18) membrane marker was incorporated into liposomes at quenched concentrations. Upon interaction with target membranes, the marker gets diluted, and dequenching can be measured in a fluorescence spectrophotometer. Rate constants were calculated from the dequenching curves under low pH conditions, which allow for fusion, and at neutral pH, where no specific fusion occurs. Activation energies were determined from Arrhenius plots. The results were compared with the temperature dependence of other viral activities like infectivity, hemolysis, and fusion with erythrocytes. For the slow reaction at pH 7.4, where only non-specific lipid transfer takes place, the activation energy was about 24 kcal/mole between 15 degrees C and 45 degrees C. For the fast, hemagglutinin (HA)-specific fusion reaction (pH 5.3), a very low activation energy (approximately 7 kcal/mole) was found between 25 degrees C and 37 degrees C, whereas below 25 degrees C it was much higher (approximately 34 kcal/mole). The temperature range with low activation energy coincides with the one for optimal infectivity, hemolysis, and fusion with erythrocytes. Furthermore, it is the same range in which the conformational change of HA takes place, which in the absence of a partner membrane leads to an irreversible inactivation of the fusion protein.     

Membrane phase transitions and succinate oxidase activity in an extremely thermophilic bacterium

ESR and succinate oxidase activity were used to investigate the membrane phase-transitions of an extreme thermophile, Thermus T351, over an 80°C temperature range in whole cells, membrane particles, and extracted lipid suspension. Three phase transitions were observed using both techniques. These occurred at about 19°C, 39°C and 66°C. The transition at 19°C is unusual in that the Arrhenius plot for succinate oxidase is concave upwards, implying an increase in activation energy (E_a) with increased temperature.     

Temperature dependence of solute transport and enzyme activities in hog renal brush border membrane vesicles

The temperature dependence of sodium-dependent and sodium-independent d-glucose and phosphate uptake by renal brush border membrane vesicles has been studied under tracer exchange conditions. For sodium-dependent d-glucose and phosphate uptake, discontinuities in the Arrhenius plot were observed. The apparent activation energy for both processes increased at least 4-fold with decreasing temperature. The most striking change in the slope of the Arrhenius plot occurred between 12 and 15°C. The sodium-independent uptake of d-glucose and phosphate showed a linear Arrhenius plot over the temperature range tested (35–5°C). The behavior of the transport processes was compared to the temperature dependence of typical brush border membrane enzymes. Alkaline phosphatase as intrinsic membrane protein showed a nonlinear Arrhenius plot with a transition temperature at 12.4°C. Aminopeptidase M, an extrinsic membrane protein exhibited a linear Arrhenius plot. These data indicate that the sodium-glucose and sodium-phosphate cotransport systems are intrinsic brush border membrane proteins, and that a change in membrane organization alters the activity of a variety of intrinsic membrane proteins simultaneously.     

Effect of reduced temperatures on protein synthesis in mouse L cells.

The rate of incorporation of leucine into protein, the rate of polypeptide elongation and termination, and the relative quantity and size of polysomes were analyzed in mouse L cells grown in suspension culture at various temperatures between 0 degrees C and 36 degrees C. Between 10 degrees C and 36 degrees C protein synthesis exhibited two different apparent activation energies (39 kcal/mole, 10-25 degrees C; 14 kcal/mole, 25-36 degrees C), whereas elongation and termination had only one (16 kcal/mole). Below 36 degrees C, the polysome level and size decreased, reaching a minimum of 30% of the control 36 degrees C values at 10 degrees C; below 10 degrees C the level increased again back to control values at 0 degrees C. The polysome decline was time dependent, requiring about 5 hr to reach the equilibrium value. This decline is completely reversible within 60 min, even in the presence of 4 mug/ml of actinomycin D, and even after 15 hr of incubation at the lower temperature. The results suggest that polypeptide initiation is rate limiting, particularly below 25 degrees C; whereas above this temperature, elongation or perhaps some other process may be limiting. These results are quite different from those obtained for E. coli and rabbit reticulocyte protein synthesis.     

The effect of temperature on the activity of the adenylate cyclase system of liver plasma membranes

The rat liver adenylate cyclase system shows a discontinuity in the Arrhenius plots at 20°C in the nonstimulated activity (basal) with activation energies of 16 and 28 Kcal/mole. The discontinuity disappears when the enzyme is stimulated either by glucagon, sodium fluoride, 5′ guanylyl-imidodiphosphate or glucagon plus 5′ guanylyl-imidodiphosphate and the energy of activation was the same with all the compounds tested. If the activator was initially in contact with the membranes at 0°C the energy of activation was similar to that observed below the break (26 Kcal/mole) but it changed to that above the break if the compound contacted the membranes at temperatures above the break (22–24°C). We discuss the possibility of two different conformations of the enzyme; both conformations can be “frozen” by any of the compounds tested, “isolating” the enzyme from any subsequent physical change of the membrane due to temperature.     

Effects of Oxygen and Respiratory Inhibitors on Induction and Release of Dormancy in Aerial Tubers of Begonia evansiana

Effects of O₂ and some respiratory inhibitors on the induction and release of bud dormancy were examined with the aerial tubers of different ages of Begonia evansiana Andr. Oxygen was needed not only for tuber sprouting but also during the chilling process at 2 to 5 C to break tuber dormancy. If the mature tubers were exposed to blue light during the chilling period, their dormancy was strikingly released even by the chilling given under an O₂ concentration as low as 3%. Blue light pretreatment promoted photo-sprouting of immature tubers only when given under lower O₂ concentrations. On the other hand, red light became effective in inducing dormancy in the immature tubers and in prolonging dormancy in the mature tubers as O₂ tension was increased. This was also the case with the induction of dormancy in the immature tubers by exposing them to a lower temperature (17 C) in the dark. The development of dormancy was suppressed by 2,4-dinitrophenol, p-nitrophenol, and sodium azide.     

Regulation of translation in rabbit reticulocytes and mouse L-cells; comparison of the effects of temperature.

Various parameters of protein synthesis were analyzed in rabbit reticulocytes exposed to various temperatures for up to five hours. Between 10 degrees C and 40 degrees C total protein synthesis exhibited two different apparent activation energies (36 kcal/mole, 10-24 degrees C; 22 kcal/mole, 24-40 degrees C), as did protein elongation and release (35 kcal/mole, 10-25 degrees C; 12 kcal/mole, 25-40 degrees C). However, the level of polysomes remained essentially unchanged between 0 degrees C and 42 degrees C which implies that the activation energy for polypeptide initiation is quite similar to that for elongation and is also biphasic. This situation is different from that in cultured mouse L-cells where the polysome level is dependent on temperatures. Nevertheless, reticulocytes and L-cells appear to be similar in their temperature dependence of initiation and in their rate of elongation (5-6 amino acids/second at 36 degrees C.     

Effect of cations on the temperature sensitivity of Ca2+ transport in rat-liver mitochondria and safranine uptake by liposomes

The activation energy of mitochondrial Ca²⁺ transport has been studied in various conditions by Arrhenius plots in the temperature range 6–20°C. In the presence of Mg²⁺ the activation energy is decreased to 18 kJ/mole from that of 40 kJ/mole found in a sucrose medium. In the presence of the polyamine spermine the activation energy is practically 0 kJ/mole. A lanthanide Eu³⁺, which is a potent inhibitor of Ca²⁺ transport, has no significant effect on the activation energy. In a KCl medium the activation energy is increased to 70 kJ/mole. When both K⁺ and Mg⁺ are present the activation energy is nonlinear between 11 and 18°C. In the presence of K⁺ and spermine it is about 0 kJ/mole between 6 and 13°C and at higher temperatures 68 kJ/mole. Neither Mg²⁺ nor spermine affect the slope of the Arrhenius plot for state 4 respiration. Spermine decreases slightly the activation energy of Ca²⁺-stimulated respiration. Spermine also decreases the activation energy of valinomycin- or gramicidin-induced safranine uptake by liposomes from 68 to almost 0 kJ/mole between 17 and 30°C. The results indicate that Ca²⁺ binding to the polar head groups of the phospholipids at the membrane surface is the rate-limiting step of mitochondrial Ca²⁺ transport, because agents that inhibit Ca²⁺ binding to these sites (Mg²⁺, spermine, K⁺) have the most marked effect, whereas Eu³⁺, which, because of the small concentration used, ought to interact mainly with the mitochondrial Ca²⁺ transport system, has no significant effect on the temperature sensitivity of mitochondrial Ca²⁺ transport.     

Regulation of translation in rabbit reticulocytes and mouse L-cells; comparison of the effects of temperature

Various parameters of protein synthesis were analyzed in rabbit reticulocytes exposed to various temperatures for up to five hours. Between 10°C and 40°C total protein synthesis exhibited two different apparent activation energies (36 kcal/mole, 10–24°C; 22 kcal/mole, 24–40°C), as did protein elongation and release (35 kcal/mole, 10–25°C; 12 kcal/mole, 25–40°C). However, the level of polysomes remained essentially unchanged between 0°C and 42°C which implies that the activation energy for polypeptide initiation is quite similar to that for elongation and is also biphasic. This situation is different from that in cultured mouse L-cells where the polysome level is dependent on temperatures. Nevertheless, reticulocytes and L-cells appear to be similar in their temperature dependence of initiation and in their rate of elongation (5–6 amino acids/second at 36°C).     

Effects of Temperature on Electron Transport in Arum maculatum Mitochondria

The effects of temperature upon the respiratory pathways of Arum maculatum mitochondria have been studied. The alternate oxidase sustained a greater proportion of the total respiration at low temperatures than at higher temperatures. Arrhenius plots of respiratory activities show two discontinuities, one at 14°C and one at 21°C. The lower temperature discontinuity was associated with electron transport from succinate dehydrogenase to the alternative oxidase, enzymes that face the inner side of the membrane while the higher temperature discontinuity was associated with electron transport from the external NADH dehydrogenase to cytochrome c oxidase, which face the outer side of the membrane. Both discontinuities resulted in a decrease in the activation energy for electron transport on one side of the membrane. Arrhenius plots of transmembrane electron transport showed discontinuities at both 14° and 21°C but the upper discontinuity resulted in an increase in the activation energy. Activation energies determined for the respiratory activities show that above 21°C the exogenous NADH-cytochrome pathway and the succinate-alternative oxidase pathway were lower than those for the NADH-alternative pathway or the succinate cytochrome pathway.     

Membrane lipids can modulate guanylate cyclase activity of rat intestinal microvillus membranes

Studies of the temperature dependence (10-40 degrees C) of guanylate cyclase in rat intestinal microbillus membranes reveal a change in energy of activation (slope of the Arrhenius plot) at 30 +/- 1 degree C. The break point temperature corresponds to the lipid thermotropic transition in these membranes previously characterized by differential scanning calorimetry (range: 23-39 degrees C; peak temperature, 31 degrees C). The break point temperature for guanylate cyclase also corresponds to that of a number of other microbillus membrane enzymes and of D-glucose transport. These activities are defined as "intrinsic" membrane activities by this operational criterion. Treatment with the nonionic detergent Lubrol WX increased the guanylate cyclase activity 4- to 8-fold and removed the discontinuity in the Arrhenius plot.     

Seasonal Changes in the Kinetic Parameters of a Photosynthetic Fructose-1,6-Bisphosphatase Isolated from Peltigera rufescens

The kinetic parameters of the photosynthetic fructose-1,6-bisphosphatase isolated from Peltigera rufescens (Weis) Mudd. were measured on a seasonal basis and during a laboratory-induced temperature acclimation. Both the substrate affinity and Ea changed on a seasonal basis. During the summer, the Ea decreased from 91.8 to 62.3 kilojoules per mole. The K_m fructose-1,6-bisphosphate measured at temperatures above 25°C was also found to decrease by 50%. This seasonal change in K_m can be induced by growing the lichen under appropriate conditions for 2 weeks, and is correlated to a change in the net photosynthetic rates. It is hypothesized that this change in fructose-1,6-bisphosphatase is related to the seasonal temperature acclimation process that has been previously reported in this species.     

Temperature dependence of the concentration kinetics of absorption of phosphate and potassium in corn roots

The effect of temperature on respiration and kinetics of H₂PO₄⁻ and K⁺ uptake in corn roots was determined in the range of 2 to 42 C. The response of uptake to temperature, determined from Q₁₀ and activation energy (Ea) data, for the anion and the cation differ significantly, especially in the range of uptake mechanism (Mech.) I. At 2.5 micromolar the Ea for K⁺ uptake below the 13 C transition is 29.3 kilocalories per mole. As the K⁺ concentration is increased, Ea declines and at 0.25 millimolar is 21.6 kilocalories per mole. Accompanying this change in Ea is a shifting of the apparent transition temperature from 13 to 17 C. Above the temperature transition the Ea's for K⁺ uptake in the Mech. I range are quite low (3.0) and this value is unchanged by increases of K⁺ concentration to 0.25 millimolar. In the range of Mech. II above 1 millimolar K⁺ the temperature transitions are not seen and plots become linear. The Ea's show an increasing trend from 4.7 at 1 millimolar to 6.1 at 50 millimolar. The uptake of H₂PO₄⁻ is much more temperature sensitive having a constant Ea at concentrations in the Mech. I range below the 13 C temperature transition. The Arrhenius plots reveal a second transition at 22 C and the Ea for this segment is 21.0. Above the second transition the Ea remains high (10.0) and is constant in the range of Mech. I. In the range of Mech. II there is a concentration dependent decline in Ea for H₂PO₄⁻ uptake (22.7 at 1.0 millimolar to 1.0 at 50 millimolar). There is no definable low temperature transition at these concentrations. Ion uptake is found to be much more sensitive to low temperature than respiration in this chill-sensitive species. The data suggest that the low temperature reduction of ion transport is more closely related to restriction of function of active transport systems than to either respiration or membrane permeability.