On the developmental dependence of leaf respiration: responses to short- and long-term changes in growth temperature

Using measurements of leaf respiratory O(2) uptake (R), we investigated whether immature and mature Arabidopsis thaliana (ecotype Columbia) leaves differed in their response to temperature. Confocal microscopy (using plants with mitochondrially targeted green fluorescent protein [GFP]) was used to determine whether ontogenetic changes in R are associated with concomitant changes in mitochondrial morphology/abundance. Comparisons were made of warm-grown (25/20°C) leaves, warm-grown leaves shifted to cold (5°C) for 10 days, and cold-developed leaves. Short-term Q(10) values and the ability to cold-acclimate were determined. In warm-grown plants, rates of R per mass were highest in immature leaves, decreasing as leaves developed. Moreover, although mitochondrial size (5.6-6.5 μm(3)) remained constant during development, mitochondrial number per μm(3) declined from 0.01 to 0.003 as leaves expanded (i.e., mitochondrial density decreased). Immature and mature leaves did not differ in Q(10) values but did differ in their ability to cold-acclimate. Whereas mature leaves had clear evidence of cold acclimation (e.g., when measured at 25°C, R was highest in cold-developed leaves), young leaves had none. Collectively, the results highlight the changes in rates of R, mitochondrial density, and biomass allocation associated with leaf development and that changes in respiratory flux associated with acclimation only take place within mature tissues.     

Contributions of photosynthetic and non‐photosynthetic cell types to leaf respiration in Vicia faba L. and their responses to growth temperature

In intact leaves, mitochondrial populations are highly heterogeneous among contrasting cell types; how such contrasting populations respond to sustained changes in the environment remains, however, unclear. Here, we examined respiratory rates, mitochondrial protein composition and response to growth temperature in photosynthetic (mesophyll) and non‐photosynthetic (epidermal) cells from fully expanded leaves of warm‐developed (WD) and cold‐developed (CD) broad bean (Vicia faba L.). Rates of respiration were significantly higher in mesophyll cell protoplasts (MCPs) than epidermal cell protoplasts (ECPs), with both protoplast types exhibiting capacity for cytochrome and alternative oxidase activity. Compared with ECPs, MCPs contained greater relative quantities of porin, suggesting higher mitochondrial surface area in mesophyll cells. Nevertheless, the relative quantities of respiratory proteins (normalized to porin) were similar in MCPs and ECPs, suggesting that ECPs have lower numbers of mitochondria yet similar protein complement to MCP mitochondria (albeit with lower abundance serine hydroxymethyltransferase). Several mitochondrial proteins (both non‐photorespiratory and photorespiratory) exhibited an increased abundance in response to cold in both protoplast types. Based on estimates of individual protoplast respiration rates, combined with leaf cell abundance data, epidermal cells make a small but significant (2%) contribution to overall leaf respiration which increases twofold in the cold. Taken together, our data highlight the heterogeneous nature of mitochondrial populations in leaves, both among contrasting cell types and in how those populations respond to growth temperature.     

Temporal heterogeneity of cold acclimation phenotypes in Arabidopsis leaves

To predict the effects of temperature changes on plant growth and performance, it is crucial to understand the impact of thermal history on leaf morphology, anatomy and physiology. Here, we document a comprehensive range of leaf phenotypes in 25/20 °C‐grown Arabidopsis thaliana plants that were shifted to 5 °C for up to 2 months. When warm‐grown, pre‐existing (PE) leaves were exposed to cold, leaf thickness increased due to an increase in mesophyll cell size. Leaves that were entirely cold‐developed (CD) were twice as thick (eight cell layers) as their warm‐developed (WD) counterparts (six layers), and also had higher epidermal and stomatal cell densities. After 4 d of cold, PE leaves accumulated high levels of total non‐structural carbohydrates (TNC). However, glucose and starch levels declined thereafter, and after 45 d in the cold, PE leaves exhibited similar TNC to CD leaves. A similar phenomenon was observed in δ¹³C and a range of photosynthetic parameters. In cold‐treated PE leaves, an increase in respiration (R_dark) with cold exposure time was evident when measured at 25 °C but not 5 °C. Cold acclimation was associated with a large increase in the ratio of leaf R_dark to photosynthesis. The data highlight the importance of understanding developmental thermal history in determining individual phenotypic traits.     

Effects of hibernation on mitochondrial regulation and metabolic capacities in myocardium of painted turtle (Chrysemys picta)

Painted turtles hibernating during winter may endure long-term exposure to low temperature and anoxia. These two conditions may affect the aerobic capacity of a tissue and might be of particular importance to the cardiac muscle normally highly reliant on aerobic energy production. The present study addressed how hibernation affects respiratory characteristics of mitochondria in situ and the metabolic pattern of turtle myocardium. Painted turtles were acclimated to control (25 degrees C), cold (5 degrees C) normoxic and cold anoxic conditions. In saponin-skinned myocardial fibres, cold acclimation increased mitochondrial respiratory capacity and decreased apparent ADP-affinity. Concomitant anoxia did not affect this. Creatine increased the apparent ADP-affinity to similar values in the three acclimation groups, suggesting a functional coupling of creatine kinase to mitochondrial respiration. As to the metabolic pattern, cold acclimation decreased glycolytic capacity in terms of pyruvate kinase activity and increased lactate dehydrogenase (LHD) activity. Concomitant anoxia counteracted the cold-induced decrease in pyruvate kinase activity and increased creatine kinase activity. In conclusion, cold acclimation seems to increase aerobic and decrease anaerobic energy production capacity in painted turtle myocardium. Importantly, anoxia does not affect the mitochondrial functional integrity but seems to increase the capacity for anaerobic energy production and energy buffering.     

Acclimation of photosynthesis and respiration is asynchronous in response to changes in temperature regardless of plant functional group

Gas exchange, fluorescence, western blot and chemical composition analyses were combined to assess if three functional groups (forbs, grasses and evergreen trees/shrubs) differed in acclimation of leaf respiration (R) and photosynthesis (A) to a range of growth temperatures (7, 14, 21 and 28 degrees C). When measured at a common temperature, acclimation was greater for R than for A and differed between leaves experiencing a 10-d change in growth temperature (PE) and leaves newly developed at each temperature (ND). As a result, the R : A ratio was temperature dependent, increasing in cold-acclimated plants. The balance was largely restored in ND leaves. Acclimation responses were similar among functional groups. Across the functional groups, cold acclimation was associated with increases in nonstructural carbohydrates and nitrogen. Cold acclimation of R was associated with an increase in abundance of alternative and/or cytochrome oxidases in a species-dependent manner. Cold acclimation of A was consistent with an initial decrease and subsequent recovery of thylakoid membrane proteins and increased abundance of proteins involved in the Calvin cycle. Overall, the results point to striking similarities in the extent and the biochemical underpinning of acclimation of R and A among contrasting functional groups differing in overall rates of metabolism, chemical composition and leaf structure.     

Assessing the relationship between respiratory acclimation to the cold and photosystem II redox poise in Arabidopsis thaliana

We examined the effect of manipulating photosystem II (PSII) redox poise on respiratory flux in leaves of Arabidopsis thaliana. Measurements were made on wild-type (WT) plants and npq4 mutant plants deficient in non-photochemical quenching (NPQ). Two experiments were carried out. In the first experiment, WT and mutant warm-grown plants were exposed to three different irradiance regimes [75, 150 and 300 micromol photosynthetically active radiation (PAR)], and leaf dark respiration was measured in conjunction with PSII redox poise. In the second experiment, WT and mutant warm-grown plants were shifted to 5 degrees C and 75, 150 or 300 micromol PAR, and dark respiration was measured alongside PSII redox poise in cold-treated and cold-developed leaves. Despite significant differences in PSII redox poise between genotypes and irradiance treatments, neither genotype nor growth irradiance had any effect upon the rate of respiration in warm-grown, cold-treated or cold-developed leaves. We conclude that changes in PSII redox poise, at least within the range experienced here, have no direct impacts on rates of leaf dark respiration, and that the respiratory cold acclimation response is unrelated to changes in chloroplast redox poise.     

Glycine betaine involvement in freezing tolerance and water stress in Arabidopsis thaliana

Levels of endogenous glycine betaine in the leaves were measured in response to cold acclimation, water stress and exogenous ABA application in Arabidopsis thaliana. The endogenous glycine betaine level in the leaves increased sharply during cold acclimation treatment as plants gained freezing tolerance. When glycine betaine (10 mM) was applied exogenously to the plants as a foliar spray, the freezing tolerance increased from -3.1 to -4.5 degrees C. In addition, when ABA (1 mM) was applied exogenously, the endogenous glycine betaine level and the freezing tolerance in the leaves increased. However, the increase in the leaf glycine betaine level induced by ABA was only about half of that by the cold acclimation treatment. Furthermore, when plants were subjected to water stress (leaf water potential of approximately -1.6 MPa), the endogenous leaf glycine betaine level increased by about 18-fold over that in the control plants. Water stress lead to significant increase in the freezing tolerance, which was slightly less than that induced by the cold acclimation treatment. The results suggest that glycine betaine is involved in the induction of freezing tolerance in response to cold acclimation, ABA, and water stress in Arabidopsis plants.     

Loose-coupled subsarcolemmal mitochondria from muscle Rhomboideus in cold-acclimated piglets

1. Intermyofibrillar (IM) and subsarcolemmal (SM) mitochondria were isolated from rhomboideus (RH) and longissimus dorsi (LD) muscles of cold-acclimated (12 degrees C for 3 weeks) and control (23 degrees C) 8-week-old piglets. 2. Together with measurements of yield of mitochondrial protein and enzyme activities (cytochrome oxydase-CO; creatine kinase--CK), the respiratory rate of isolated mitochondria was followed polarographically in order to determine the respiratory control ratio (RCR) and consequently the tightness of coupling in response to ADP. 3. In control and cold-acclimated piglets, there were more IM than SM (P less than 0.05) and more mitochondria in RH than LD muscle (P less than 0.05). In both muscles, the yield of mitochondria was slightly but not significantly higher after cold acclimation than in controls. 4. In both muscles, IM were tightly coupled and their RCR (congruent to 4.5) were similar in both groups of piglets. RCR values were increased in the presence of bovine serum albumin (BSA). 5. In controls, SM exhibited lower respiration rates than IM (P less than 0.05) and were slightly coupled (RCR congruent to 2). Cold acclimation increases the loose-coupling of SM (P less than 0.05), especially in RH muscle. No changes appeared in the mitochondrial coupling after the addition of BSA. 6. After cold acclimation, CO and CK activities were increased in IM (P less than 0.05) while only CO activity was increased in SM (P less than 0.05). These results support a coupling defect in SM and therefore confirm mitochondrial respiration results.     

Role of the Ca2+ cycle in uncoupling of oxidative phosphorylation in liver mitochondria of cold-acclimated rats

Cold acclimation of Wistar rats for 2-4 weeks at about 3 degrees C resulted in an increased respiration rate and a reduced ADP/O ratio in liver mitochondria. With increasing duration of acclimation up to 10-12 weeks, these parameters returned to a normal level. The increase in the respiration rate and the decline of the mitochondrial ADP/O ratio were associated with a significant activation of the electroneutral release of Ca2+. When the animals were acclimated for 10-12 weeks the rate of Ca2+ release reduced to control values. The addition of 1 microM ruthenium red resulted in a decrease in the rates of mitochondrial respiration in control and cold-acclimated rats to approximately equal values and in a partial restoration of the ADP/O ratio in liver mitochondria of rats kept in the cold for 2-4 weeks. The respiratory activity of mitochondria isolated in the presence of 1 mM EGTA unaffected by ruthenium red.     

Increased respiration in skeletal muscle mitochondria from cold-acclimated ducklings: uncoupling effects of free fatty acids

Intermyofibrillar mitochondria from skeletal muscle (m. gastrocnemius) and liver mitochondria were isolated from cold-acclimated (4 degrees C) or control (30 degrees C) 4-week old ducklings. The respiratory rate of isolated mitochondria, with Na-succinate as substrate, was followed polarographically at 25 degrees C in order to determine the basal respiratory rate, the rate of respiration in the presence of free fatty acids (FFA) (Na-palmitate), and the fully uncoupled rate, after addition of FCCP. The basal respiration (which in liver mitochondria was unaffected by acclimation to cold) was higher (+53%) in intermyofibrillar mitochondria from cold-acclimated ducklings than from controls, and the maximal FCCP-stimulated respiration was also increased (+98%) by acclimation to cold. FFA-stimulated respiration increased as a function of FFA concentration in both types of mitochondria. The increase in respiration due to FFA was about double in intermyofibrillar mitochondria from cold-acclimated ducklings than that of controls, but in liver mitochondria there was no increase due to cold. The membrane potential was estimated by the dye safranine in the absence or in the presence of FFA in the incubation medium. There were no significant differences in the basal membrane potential in the two groups and the addition of FFA led to the same depolarization in both groups. The significance of these alterations for acclimation to cold is discussed.     

Temperature acclimation in crucian carp, Carassius carassius L., morphometric analyses of muscle fibre ultrastructure

Carp show a partial compensation in metabolic rate and activity following temperature acclimation. In the present study crucian carp, Carassius carassius , were acclimated for eight weeks to either 2deg; C or 28deg; C. The effects of temperature acclimation on muscle fibre ultrastructure has been investigated. The fractional volume (%) of each fibre type occupied by mitochondria and myofibrils was determined using a point counting morphometric method. Mitochondrial density was found to be higher in the muscles of cold (red fibres 25%; pink fibres 20% and white fibres 4%) than in those of warm acclimated fish (red fibres 14%, pink fibres 11%, white fibres 1%). The proportion of subsarcolemmal to intra-myofibrillar mitochondria was significantly lower in the red fibres of cold acclimated fish. Metabolic compensation to low temperatures are therefore associated with an increase in the number of mitochondria per cell. In contrast, the fractional volume occupied by myofibrils actually decreased following cold acclimation. Evidence is reviewed that temperature compensation of contractile activity results from qualitative rather than quantitative changes in myofibrillar proteins.     

Variations in energization parameters and proton conductance induced by cold adaptation and essential fatty acid deficiency in mitochondria of brown adipose tissue in the rat

Male weanling Long-Evans rats were fed on a low-fat semipurified diet (control diet, 2% sunflower oil; essential fatty acid (EFA) deficient diet, 2% hydrogenated coconut oil) for 9 weeks. In order to modulate need for non-shivering thermogenesis, groups of rats on each diet were exposed at 28 degrees C (thermoneutrality) and at 5 degrees C (cold acclimation) for the last 5 weeks. In brown adipose tissue (BAT) mitochondria, several parameters of mitochondrial energization, protonmotive force (delta p) and its components delta pH and membrane potential, delta psi, were investigated. Simultaneous measurement of oxygen consumption and delta psi (the main component of delta p) was performed by varying alpha-glycerophosphate concentration and the force/flux relationship of the mitochondria was established by comparison of proton conductance, CmH+, over the whole range of protonmotive force. delta p. In the absence of GDP, at 28 degrees C, EFA deficiency induced a marked increase in CmH+. Cold acclimation led to comparable enhanced CmH+ in control and EFA-deficient mitochondria. In the presence of GDP which binds and inhibits the BAT 32 kDa uncoupling protein, CmH+ was the same in 28 degrees C and 5 degrees C control mitochondria, but EFA deficiency led to an enhanced GDP independent CmH+ at 28 degrees C and to a lesser extent at 5 degrees C. These results are discussed with reference to substantial changes in mitochondrial lipid composition induced by the deficiency.     

Mitochondrial function in seasonal acclimatization versus latitudinal adaptation to cold in the lugworm Arenicola marina (L.)

Previous studies in marine ectotherms from a latitudinal cline have led to the hypothesis that eurythermal adaptation to low mean annual temperatures is energetically costly. To obtain more information on the trade-offs and with that the constraints of thermal adaptation, mitochondrial functions were studied in subpolar lugworms (Arenicola marina L.) adapted to summer cold at the White Sea and were compared with those in boreal specimens from the North Sea, either acclimatized to summer temperatures or to winter cold. During summer, a comparison of mitochondria from subpolar and boreal worms revealed higher succinate oxidation rates and reduced Arrhenius activation energies (Ea) in state 3 respiration at low temperatures, as well as higher proton leakage rates in subpolar lugworms. These differences reflect a higher aerobic capacity in subpolar worms, which is required to maintain motor activity at low but variable environmental temperatures--however, at the expense of an elevated metabolic rate. The lower activity of citrate synthase (CS) found in subpolar worms may indicate a shift in metabolic control within mitochondria. In contrast, acclimatization of boreal lugworms to winter conditions elicited elevated mitochondrial CS activities in parallel with enhanced mitochondrial respiration rates. With falling acclimation temperatures, the significant Arrhenius break temperature in state 3 respiration (11 degrees C) became insignificant (5 degrees C) or even disappeared (0 degrees C) at lower levels of Arrhenius activation energies in the cold, similar to a phenomenon known from hibernating vertebrates. The efficiency of aerobic energy production in winter mitochondria rose as proton leakage in relation to state 3 decreased with cold acclimation, indicated by higher respiratory control ratio values and increased adenosine diphosphate/oxygen (ADP/O) ratios. These transitions indicate reduced metabolic flexibility, possibly paralleled by a loss in aerobic scope and metabolic depression during winter cold. Accordingly, these patterns contrast those found in summer-active, cold-adapted eurytherms at high latitudes.     

Increase in the adenine nucleotide translocase content of duckling subsarcolemmal mitochondria during cold acclimation

Intermyofibrillar and subsarcolemmal mitochondria were isolated from duckling gastrocnemius muscle. The adenine nucleotide translocase (ANT) content of subsarcolemmal mitochondria was found to be half of that present in intermyofibrillar mitochondria. In addition, cold acclimation resulted in a 1.7-fold increase in subsarcolemmal mitochondrial ANT content, with intermyofibrillar mitochondrial ANT remaining constant. This change in mitochondrial ANT content correlates with the previously reported cold-induced change in the sensitivity of mitochondria to palmitate-inhibited ATP synthesis [Roussel et al. (1998) FEBS Lett. 439, 258-262]. It is suggested that the mitochondrial ANT content enhances or reduces the fatty acid uncoupling activity in tissue, depending on the energetic state of mitochondria.     

青海湖盐碱湿地灰绿藜叶的形态解剖学研究

利用光学显微镜和透射电镜对生长于青海湖湖滨盐碱湿地的先锋植物灰绿藜（Chenopodium glaucum Linn.）及生长于甘肃兰州大学校园内中生环境对照灰绿藜叶片的显微、超微结构进行了比较观察研究。结果发现中生环境灰绿藜叶片较薄,有明显的栅栏与海绵组织分化;叶绿体呈椭圆形,基粒片层较发达且普遍含有淀粉粒。与对照相比,生长于高海拔湖滨盐碱湿地灰绿藜叶为等面叶,叶片厚,角质层厚,栅栏组织发达,气室明显,具表皮毛;线粒体较多,但嵴不发达,叶绿体呈扁船型沿着壁的边缘排列,叶绿体的基粒片层不发达且普遍含有脂质球,一些细胞中常出现大量的多层膜结构。研究结果表明2种生态型灰绿藜的形态结构已发生了深刻的变异,湖滨灰绿藜表现出适应区域的寒旱化的明显特征。     

Oxidation of Glycine via the Respiratory Chain in Mitochondria Prepared from Different Parts of Spinach

Mitochondria were prepared from roots, stalks, leaves, and leaf veins of spinach. The mitochondrial preparations were examined for their ability to oxidize glycine via the respiratory chain. It is shown that the glycine-oxidizing capacity is restricted to photosynthetically active tissue. The activity is present in mitochondria from the green parts of the leaves, but not in mitochondria from roots, stalks, or leaf veins.     

Sucrose metabolism in spring and winter wheat in response to high irradiance, cold stress and cold acclimation

Effects of low‐temperature stress, cold acclimation and growth at high irradiance in a spring (Triticum aestivum L. cv. Katepwa) and a winter wheat (Triticum aestivum L. cv. Monopol) were examined in leaves and crowns with respect to the sucrose utilisation and carbon allocation. Light‐saturated and carbon dioxide (CO₂)‐saturated rates of CO₂ assimilation were decreased by 50% in cold‐stressed spring and winter wheat cultivars. Cold‐ or high light‐acclimated Katepwa spring wheat maintained light‐saturated rates of CO₂ assimilation comparable to those of control spring wheat. In contrast, cold‐ or high light‐acclimated winter wheat maintained higher light and CO₂‐saturated rates of CO₂ assimilation than non‐acclimated controls. In leaves, during either cold stress, cold acclimation or acclimation to high irradiance, the sucrose/starch ratio increased by 5‐ to 10‐fold and neutral invertase activity increased by 2‐ to 2.5‐fold in both the spring and the winter wheat. In contrast, Monopol winter wheat, but not Katepwa spring wheat, exhibited a 3‐fold increase in leaf sucrose phosphate synthase (SPS) activity, a 4‐fold increase in sucrose:sucrose fructosyl transferase activity and a 6.6‐fold increase in acid invertase upon cold acclimation. Although leaves of cold‐stressed and high light‐grown spring and winter wheat showed 2.3‐ to 7‐fold higher sucrose levels than controls, these plants exhibited a limited capacity to adjust either sucrose phosphate synthase or sucrose synthase activity (SS[s]). In addition, the acclimation to high light resulted in a 23–31% lower starch abundance and no changes at the level of fructan accumulation in leaves of either winter or spring wheat when compared with controls. However, high light‐acclimated winter wheat exhibited a 1.8‐fold higher neutral invertase activity and high light‐acclimated spring wheat exhibited an induction of SS(d) activity when compared with controls. Crowns of Monopol showed higher fructan accumulation than Katepwa upon cold and high light acclimation. We suggest that the differential adjustment of CO₂‐saturated rates of CO₂ assimilation upon cold acclimation in Monopol winter wheat, as compared with Katepwa spring wheat, is associated with the increased capacity of Monopol for sucrose utilisation through the biosynthesis of fructans in the leaves and subsequent export to the crowns. In contrast, the differential adjustment of CO₂‐saturated rates of CO₂ assimilation upon high light acclimation of Monopol appears to be associated with both increased fructan and starch accumulation in the crowns.     

Thermal de‐acclimation: how permanent are leaf phenotypes when cold‐acclimated plants experience warming?

We quantified a broad range of Arabidopsis thaliana (Col‐0) leaf phenotypes for initially warm‐grown (25/20 °C day/night) plants that were exposed to cold (5 °C) for periods of a few hours to 45 d before being transferred back to the warm, where leaves were allowed to mature. This allowed us to address the following questions: (1) For how long do warm‐grown plants have to experience cold before developing leaves become irreversibly cold acclimated? (2) To what extent is the de‐acclimation process associated with changes in leaf anatomy and physiology? We show that leaves that experience cold for extended periods during early development exhibit little plasticity in either photosynthesis or respiration, and they do not revert to a warm‐associated carbohydrate profile. The eventual expansion rate in the warm was inversely related to the duration of previous cold treatment. Moreover, cold exposure of immature/developing leaves for as little as 5 d resulted in irreversible changes in the morphology of leaves that subsequently matured in the warm, with 15 d cold being sufficient for a permanent alteration of leaf anatomy. Collectively, these results highlight the impact of transitory cold during early leaf development in determining the eventual phenotype of leaves that mature in the warm.     

Developmental Regulation of Respiratory Activity in Pea Leaves

The developmental pattern of mitochondrial respiratory activity in pea (Pisum sativum) leaves has been investigated in an attempt to determine changes in mitochondrial function as plant cells mature. NADH and succinate dehydrogenase and cytochrome c oxidase activities remained relatively constant during cell maturation (from d 0 to d 14). Alternative oxidase and glycine decarboxylase activity, however, were low in young leaf tissue (d 0-6) but increased substantially as the tissue matured (d 7-14) and gained photorespiratory activity. Western blot analysis of the alternative oxidase protein revealed that it was primarily in an oxidized state in young leaves (d 0-6) but switched dramatically to the reduced form of the protein as the pea cells matured (d 7-14). The switch to the reduced form of the protein correlated with an increase in alternative oxidase activity. Results are discussed in terms of the changing function of plant mitochondria during leaf development.