The relationship between respiration and temperature in leaves of the arctic plant Saxifraga cernua

Abstract Saxifraga cernua, a perennial herb distributed throughout the arctic and subarctic regions, shows high levels of dark respiration. The amount of respiration exhibited by leaves and whole plants at any temperature is influenced by the pretreatment temperature. Plants grown at 10°C typically show higher dark respiration rates than plants grown at 20°C. The levels of alternative-pathway respiration (or cyanide-insensitive respiration) in leaves of S. cernua grown at high and low temperatures were assessed by treating leaf discs with 0.25 mol m^?3 salicylhydroxamic acid during measurements of oxygen consumption. Alternative pathway respiration accounted for up to 75% of the total respiration. Tissues from 20°C-grown plants yielded a Q₁₀ of 3.37 for normal respiration, and of 0.97 for alternative-pathway respiration. Tissues from 10°C-grown plants yielded a Q₁₀ of 2.55 for normal respiration, and of 0.79 for alternative-pathway respiration. The alternative pathway does not appear to be as temperature sensitive as the normal cytochrome pathway. A simple energy model was used to predict the temperature gain expected from these high rates of alternative-pathway respiration. The model shows that less than 0.02°C can be gained by leaves experiencing these high respiration rates.     

Dark respiration in the marine macroalga Chondrus crispus (Rhodophyceae)

Dark respiration in the red macroalga Chondrus crispus was studied under a variety of conditions. The components of respiration were examined using selective inhibitors in order to characterise pathways of respiration and examine regulation of respiration in marine macroalgae.In comparison to respiration rates generally reported for higher-plant leaves and roots, the steady-state rate of O₂ consumption by this alga, after 30 min dark pretreatment, was found to be quite low (three- to sixfold lower than in higher plants). The addition of uncoupler had only a slight effect on the basal respiration rate, indicating that in these conditions, substrate supply could be limiting respiration. The addition of KCN inhibited respiration by approx. 60%, indicating the presence of alternative oxidase activity. The coefficient of engagement of the alternative pathway (calculated from the data herein) showed that under normal conditions there was little participation of the alternative pathway in O₂ consumption. The response of respiration to O₂ tension was examined with and without inhibitors and the apparent K _m was 17 to 21 M. The addition of KCN plus salicylhydroxamic acid almost completely blocked respiration in C. crispus. The hypothesis that respiratory substrate limits respiration in this alga was investigated by measuring respiration rates immediately after periods of photosynthetic activity. It was found that the respiration rate was dependent on the duration of the light period and could increase up to twofold. This stimulated rate of respiration declined in a first-order fashion during the next 20 to 30 min, finally reaching the basal, zero-order rate measured before illumination. These results strongly indicate a change in the nature of the respiratory substrates during this period. No change in the contribution of the alternative pathway of respiration could be detected following light pretreatment.Abbreviations CCCP carbonyl cyanide m-chlorophenylhydrazone - SHAM salicyl hydroxamic acid     

Respiratory Shifts in Developing Petals of Saxifraga cernua

Changes in the oxygen uptake of petal slices by the cytochrome and alternative respiratory pathways were monitored during petal development in the arctic herb Saxifraga cernua. As the petals developed, rates of total respiration increased to a maximum rate during petal unfolding (day 4.5), and thereafter declined. Respiration in petals of all ages was at least partially resistant to cyanide, indicating the capacity for the alternative pathway. In all, except day 1 and senescing day 8 petals, respiration was inhibited by salicylhydroxamic acid, indicating engagement of the alternative pathway. In general, temporal changes in the respiratory activity along each pathway were similar and in parallel with changes in total respiration, although maximum rates along each pathway occurred at different times. Maximum cytochrome pathway activity occurred during petal expansion (day 4) whereas the alternative pathway peaked during petal unfolding at day 4.5. The control of respiration was also investigated. In the presence of salicylhydroxamic acid, the addition of the uncoupler carbonyl cyanide m-chlorophenylhydrazone was never stimulatory, suggesting that the cytochrome pathway was not restricted by adenylate levels. The addition of sucrose stimulated respiration only in day 1 petals, suggesting substrate limitation at this developmental stage. Since the rate of alternative pathway respiration peaked during petal unfolding, a time of high energy requirement, we suggest that the alternative pathway may have been used as an inefficient energy source during petal development.     

Light induction of alternative pathway capacity in leaf slices of Belgium endive

The effect of light on the development of the capacity for alternative pathway respiration was investigated in leaf slices of Belgium endive (Cichorum intybus L. cv. deliva). Dark-grown plants possessed little capacity for the cyanide-insensitive alternative pathway. In contrast, plants grown in continuous light had significant alternative pathway capacity. Light-grown plants also had substantially higher concentrations of ethanol-soluble carbohydrates in their leaves than plants grown in complete darkness. Despite these differences in leaf carbohydrate status and alternative pathway capacity of light- and dark-grown leaf tissue, no differences were found in the activity of the alternative pathway, which was negligible in both treatments. Dark-grown plants were adenylate restricted, as indicated by the increase in cytochrome pathway activity following uncoupling. Adenylates did not limit respiration in light-grown leaf tissue. Plants that had been grown for 8d in complete darkness were also transferred to continuous light. Respiration of dark controls steadily declined over 11d following the transfer of plants to the light, due primarily to a decrease in cytochrome pathway activity. No such decline was observed in the plants transferred to continuous light. Transfer to continuous light led to significant increases in alternative pathway capacity relative to the dark controls. Alternative pathway activity remained negligible in both the dark controls and in plants transferred to continuous light. The results of this study suggest then that light per se may be responsible for the induction of alternative pathway capacity in Belgium endive.     

Photorespiratory and respiratory decarboxylations in leaves of C3 plants under different CO2 concentrations and irradiances

We used an advanced radiogasometric method to study the effects of short-term changes in CO2 concentration ([CO2]) on the rates and substrates of photorespiratory and respiratory decarboxylations under steady-state photosynthesis and in the dark. Experiments were carried out on Plantago lanceolata, Poa trivialis, Secale cereale, Triticum aestivum, Helianthus annuus and Arabidopsis thaliana plants. Rates of photorespiration and respiration measured at a low [CO2] (40 micromol mol(-1)) were equal to those at normal [CO2] (360 micromol mol(-1)). Under low [CO2], the substrates of decarboxylation reactions were derived mainly from stored photosynthates, while under normal [CO2] primary photosynthates were preferentially consumed. An increase in [CO2] from 320 to 2300 micromol mol(-1) brought about a fourfold decrease in the rate of photorespiration with a concomitant 50% increase in the rate of respiration in the light. Respiration in the dark did not depend on [CO2] up to 30 mmol mol(-1). A positive correlation was found between the rate of respiration in the dark and the rate of photosynthesis during the preceding light period. The respiratory decarboxylation of stored photosynthates was suppressed by light. The extent of light inhibition decreased with increasing [CO2]; no inhibition was detected at 30 mmol mol(-1) CO2.     

The rate of development of water deficits affects Saxifraga cernua leaf respiration

We allowed plant water deficits to develop at two different rates following the cessation of watering in order to investigate the effects of water stress on cytochrome pathway and alternative pathway respiration in the leaves of the arctic herb Saxifraga cernua. Plants were pretreated by growth in either a commercial organic (CO) mixture or a vermiculite-perlite (VP) mixture, which allowed the complete development of water deficits in 19 and 8 days, respectively. The rate of water potential reduction was approximately 0.11 MPa day⁻¹ in the leaves of CO plants, compared to a reduction of 0.21 MPa day⁻¹ in leaves of VP plants. Osmotic adjustment occurred to a greater extent in leaves of CO plants and corresponded with an increase in ethanol-soluble sugars. In leaves of CO plants, cytochrome pathway activity gradually declined from that of control rates until day 11, and then declined more rapidly. In contrast, cytochrome pathway activity significantly increased in response to water deficits in leaves of VP plants. In leaves of both CO and VP plants, alternative pathway activity declined as water stress progressed. Relatively severe water deficits reduced alternative pathway capacity in leaves of both CO and VP plants. We also investigated the effect of previous exposure to water deficits on leaf respiration. In plants that had previously experienced three cycles of water stress, the increase in cytochrome pathway activity during the fourth water stress cycle was small compared to the increase observed in leaves of plants experiencing water stress for the first time. These results suggest that cytochrome pathway activity is differentially sensitive to the rate of development of plant water deficits and that respiratory responses to acute water stress are not necessarily similar to the responses to chronic water stress.     

Growth, photosynthesis and respiration in Plantago coronopus as affected by salinity

Plantago coronopus was grown in a non-saline culture solution and in a culture solution containing 50 m M NaCl. The rates of dry matter accumulation in both roots and shoots were not affected by 50 m M NaCl. Photosynthesis, expressed per shoot, was also the same in both environments. Neither the rate of shoot respiration nor that of root respiration was affected by salinity. In both environments the alternative respiratory pathway contributed to the same extent in root respiration. The activity of the alternative pathway decreased with increasing age. Since the respiratory activities were the same in plants grown under both saline and non-saline conditions and since the alternative respiratory pathway was also equally active in roots under both environmental conditions, it is concluded that respiratory costs involved in growth in 50 m M NaCl are negligible in terms of the plant's total energy costings.     

The flexible interrelation between AOX respiratory pathway and photosynthesis in rice leaves.

Alternative respiratory pathway was investigated in rice seedlings grown under total darkness, light/dark cycle, or continuous light. The capacity of the alternative pathway was relatively higher in leaves that had longer light exposure. An analysis of rice AOX1 multigene family revealed that AOX1c, but not AOX1a and AOX1b, had a light-independent expression. The alternative oxidase (AOX) inhibitor, salicylhydroxamic acid (SHAM, 1mM), inhibited nearly 68% of the capacity of the alternative pathway in leaves grown under different light conditions. The plants grown under different light periods were treated with SHAM and then were exposed to illumination for 4h. The transition from dark to 4h of light stimulated the capacity of alternative pathway in etiolated rice seedlings and in those grown under light/dark cycle, whereas the capacity of the alternative pathway was constant in seedlings grown under continuous light with additional 4h of illumination. Etiolated leaves did not show any CO(2) fixation after 4h of illumination, and the increase in chlorophyll content was delayed by the SHAM pretreatment. When seedlings grown under light/dark cycle were moved from dark and exposed to 4h of light, increases in chlorophyll content and CO(2) fixation rate were reduced by SHAM. Although these parameters were stable in plants grown under continuous light, SHAM decreased CO(2) fixation rate but not the chlorophyll content. These results indicate that the role and regulation of AOX in light are determined by the developmental stage of plant photosynthetic apparatus.     

Cytochrome and alternative pathway respiration in white spruce (Picea glauca) roots. Effects of growth and measurement temperature

Interactions between growth temperature and measurement temperature were examined for their effects on white spruce [ Picea glauca (Moench) Voss] root respiration. Total dark respiration rates increased with measurement temperature and were unaffected by growth temperature. Partitioning of respiratory electron flow between the cytochrome and alternative pathways was also unaffected by growth temperature. The proportion of respiration mediated by the alternative pathway was constant at measurement temperatures between 4°C and 18°C, but was increased at higher temperatures. Changes in alternative pathway activity were paralleled by changes in capacity, and the alternative pathway was almost fully engaged at all temperatures. Roots grown at low temperature displayed higher carbohydrate levels than roots grown at higher temperatures, but respiration rate was unaffected. Spruce root respiration did not appear to acclimate to growth temperature, and the alternative pathway was not preferentially engaged at low temperature.     

The electron partitioning between the cytochrome and alternative respiratory pathways during chilling recovery in two cultivars of maize differing in chilling sensitivity

Chilling effects on respiration during the recovery period were studied in two maize (Zea mays L.) cultivars differing in their tolerance to chilling: Penjalinan, a chilling-sensitive cultivar, and Z7, a chilling-tolerant cultivar. Both cultivars were exposed to 5 degrees C for 5 d, after which measurements were taken at 25 degrees C. Chlorophyll fluorescence analysis in dark-adapted leaves showed less damage in cv Z7 than in cv Penjalinan during recovery from the chilling treatment. Studies of the electron partitioning between the cytochrome and the alternative respiratory pathways during chilling recovery using the oxygen isotope fractionation technique showed that, although total leaf respiration was not affected by the chilling treatment in either of the two cultivars, electron partitioning to the alternative pathway was significantly increased in the more stressed chilling-sensitive cv Penjalinan, suggesting that increased activity of the alternative pathway is not related to the plant tolerance to chilling. These results suggest a possible role of the alternative pathway in plants under stress rather than specifically contributing to plant resistance to chilling.     

Short-term effects of two aphid species on plant growth and root respiration of three leguminous species

The short-term effects of cowpea aphids ( Aphis craccivora Koch) and pea aphids ( Acyrthosiphon pisum Harris), both Homoptera: Aphididae, on plant growth and respiration of excised, intact roots of cowpea [ Vigna unguiculata (L.) Walp. cv. Caloona], broadbean ( Vicia faba L. cv. Aquadulce) and garden pea ( Pisum sativum L. cv. Victory Freezer) seedlings were investigated, but not all plant-aphid combinations were used. Plant and root mean relative growth rates were significantly reduced within 10 days in the infested plants. Rates of total root respiration were was also significantly reduced in all infested plants within 10 days, presumably because of the reduced availability of translocate to the roots. The contribution of the cytochrome pathway to root respiration was significantly greater in control than in infested plants. The activity and engagement of the alternative respiratory pathway was also greater in control plants, and was absent in infested plants after 10 days infestation in all cases but one. These data indicate that the roots of aphid-infested plants were more efficient, in terms of energy conversion, than their respective controls.     

Starch Accumulation in Leaves of Potato (Solanum tuberosum L.) during the First 18 Days of Photoperiod Treatment

Potato (Solanum tuberosum L.) plants were grown under long days(LD) of 18 h before a subset of the plants was transferred to10-h photosynthetic periods with either a dark night (SD) oran 8-h dim photoperiod extension with incandescent lamps (DE).Temperature was constant at 21 °C. Leaves were sampled atthe beginning and end of the high density light period for starchanalyses. Potato leaves accumulated starch more rapidly underSD than under LD; and this difference continued after a secondmajor sink, the tuber, began to develop. Starch accumulationover 10 h in SD leaves was three times higher than in LD leaves,even after 17 d of treatment. By this time SD gave higher wholeplant relative growth rates than LD, and the tuber mass of SDplants exceeded 30% of their total plant biomass. The DE treatmentresulted in starch accumulation intermediate to the LD and SDtreatments. Genotypes likewise differed: the earlier genotype,more strongly induced to tuberize, had higher leaf starch accumulationthan the later genotype. The effects of photoperiod and genotypewere also present when potatoes were grown at 27 °C, a temperatureunfavourable for tuberization under LD. Thus the formation ofa strong tuber sink was consistently associated with more rapidleaf starch accumulation. Potato, Solanum tuberosum L., cv. Norchip, photoperiod, temperature, genotype, starch accumulation, partitionin     

Leaf respiration in Piper species native to a Mexican rainforest

We measured leaf respiration with a Clark-type oxygen-electrode in 6 species of the genus Piper (Piperaceae) growing naturally in wet evergreen rainforest, in microsites characterized by a broad range of light availabilities. Species normally found in large gaps and clearings ( Piper auritum and P. umbellatum ) had approximately twice the dark respiration per unit of leaf area or dry mass as species found predominantly in shaded understory sites ( P. aequale, P. lapathifolium and P. amalago ). within a species, dark respiration was lower in the individuals growing in low-light sites than in the individuals growing in high-light sites. Over all species, leaf respiration was positively correlated with the average daily photosynthetically active photon flux density (PFD) at each site, and negatively correlated with mean leaf longevity. Respiration was insensitive to leaf age in a shade species. ( P. lapathifolium ) and in a generalist ( P. hispidum ) but decreased with increasing leaf age in a gap specialist ( P. aurtium ).
In experiments on greenhouse-grown plants, we titrated respiration with potassium cyanide (KCN) and/or salicylhydroxamic acid (SHAM) to determine the cytochrome and alternative pathway components to respiration in 4 Piper species. All 4 species, representing gap, generalist and shade species, exhibited alternative pathway respiration. Engagement of the cytochrome pathway (ϱ_cyt) varied from 0.69 in P. auritum to 1.04 in P. lapathifolium and engagement of the alternative pathway (ϱ_alt varied from 0.41 to 1.02. Although the shade species had lower respiration rates than the gap species, the capacities for cytochrome and alternative pathway respiration made up similar or greater fractions of total respiration in shade species.     

Diurnal Functioning of the Legume Root Nodule

Diurnal changes in plant and nodule performance were studiedin 28–9 d plants of Pisum sativum L. in two environments,both with a 12 h (27 000 lx):12 h::light:dark cycle, but one(A) with a fluctuating temperature-humidity regime (photoperiod18 ?C, 60 per cent relative humidity:night 12 ?C, 85 per cent),the other (B) with constant temperature (18 ?C) and humidity(75 per cent). Fixation rate (C₂H₂ reduction), respiratory output of the nodulatedroot, and nodule sugar level increased throughout the photoperiod,whereas nodule soluble nitrogen level declined steadily. Reversalof these trends in the night period led, at its end, to minimain fixation rate, sugar level and respiration, but a maximumin soluble nitrogen. The A environment produced the greaterday:night fluctuations in transpiration and nodule soluble nitrogen,but B, with its higher night temperature, induced the more pronounceddecrease in fixation at night. Slightly less nitrogen was fixed during the photoperiod thanduring the night in the A environment, yet since some fixationproducts were retained in the nodules at night and not releaseduntil the next photoperiod, the day: night difference in nitrogenexport from nodules was 1.8:1. The photoperiod of A was alsoa time of higher nodule respiration and replenishment of nodulesugar and starch, so that the nodules' requirement for translocatedcarbohydrate was more than twice that at night. Humidity decrease in the photoperiod (of A) elicited higherrates of transpiration and a more rapid than normal emptyingof soluble nitrogen from the nodules: elevation of humidityhad the opposite effects. Shoot removal (A-grown plants) causednodule sugar levels to fall rapidly below those normally encounteredin intact plants.     

Comparative study of dark respiration in plants inhabiting arctic (Wrangel Island) and temperate climate zones

Comparative analysis of dark respiration was carried out for 18 plant species inhabiting arctic zone (Wrangel Island, lat. 71° N) and temperate zone (Leningrad oblast, lat. 59° N). For 15 pairs of species examined, the Stocker’s rule was proved valid; i.e., respiration rates of identical species were equal at average temperatures of their natural habitats. The concept of respiratory features in boreal and mountain plants is described in its historic development. The possible causes for controversial data are explained. It is concluded that gas exchange measurements in natural plant habitats are the only valid means for characterizing plant respiration. Only such measurements should provide the basis for the discussion of global climate changes.     

小麦幼苗叶片抗氰呼吸对轻度水分胁迫的响应

小麦幼苗经－０．５ＭＰa聚乙二醇（ＰＥＧ－６０００）溶液暗中渗透迫０、６、１２、１８、２４、３０、３６、４２、４８h,叶片的总呼吸速率（Ｖt)呈现先上升后降低的趋势,交替途径呼吸也表现出相同的变化模式。水分胁迫初期（０－１２h),交替途径容量（Ｖalt)、实际运行活性（ρValt)及运行系数（ρ值）均上升,此后（１８－４８h）逐渐下降,水分胁迫也影响了呼吸电子流在２条呼吸途径中的分配比例,胁迫初期的０－１２h内,流经交替途径的电子流增多,而流向细胞色素主路的电子流减少,但随着胁迫时间的延长,交替途径的贡献降低,而细胞色素主路的贡献增加,说明小麦叶片的抗氰呼吸在水分胁迫初期被诱导增加,而随着胁迫进行的延长又表现为下降。     

Reversible dark-induced senescence of soybean root nodules

Nodule senescence was induced in intact soybean [Glycine max. (L.) Merr., cv Woodworth] plants by an 8-day dark treatment. Dark-induced senescence resulted in the complete loss of acetylene reduction activity, a 67% loss of total soluble protein, and an almost complete loss in total leghemoglobin of nodule extracts. Isoelectric focusing gels demonstrated a preferential loss of certain proteins, which was correlated with an increase in endoprotease specific activity toward azocasein. Nodules were completely green after the 8-day dark treatment. If plants were returned to a normal photoperiod after 8 days in the dark, nodules recovered from the dark treatment in 12 to 16 days. Acetylene reduction activity returned to normal, and both total soluble protein and leghemoglobin were resynthesized while protease activity against azocasein decreased to the level of control nodules. The nodule population that had turned green after 8 days in the dark exhibited a progressive increase in red color starting nearest the exterior of the nodule, and after 16 days of recovery nodules were indistinguishable from control nodules maintained under a normal photoperiod.     

In vitro multiplication and plantlet establishment of avocado

Summary A procedure is described to regenerate shoots and plants from the embryonic axis of avocado seedlings with benzyladenine or thidiazuron. Explants were grown in the dark for 10 d and then transferred to an 18-h photoperiod to induce multiple shoots. Increased concentrations of benzyladenine or thidiazuron resulted in increased shoot production. Shoots were transferred to shoot promoting media where additional shoots were formed. Under the best conditions, six rooted shoots were produced per original explant. About 80% of the shoots with roots survived in the glasshouse and produced normal phenotypic plants.     

A new measurement technique reveals rapid post-illumination changes in the carbon isotope composition of leaf-respired CO2

We describe an open leaf gas exchange system coupled to a tunable diode laser (TDL) spectroscopy system enabling measurement of the leaf respiratory CO(2) flux and its associated carbon isotope composition (delta(13)C(Rl)) every 3 min. The precision of delta(13)C(Rl) measurement is comparable to that of traditional mass spectrometry techniques. delta(13)C(Rl) from castor bean (Ricinus communis L.) leaves tended to be positively related to the ratio of CO(2) produced to O(2) consumed [respiratory quotient (RQ)] after 24-48 h of prolonged darkness, in support of existing models. Further, the apparent fractionation between respiratory substrates and respired CO(2) within 1-8 h after the start of the dark period was similar to previous observations. In subsequent experiments, R. communis plants were grown under variable water availability to provide a range in delta(13)C of recently fixed carbohydrate. In leaves exposed to high light levels prior to the start of the dark period, CO(2) respired by leaves was up to 11 per thousand more enriched than phloem sap sugars within the first 10-15 min after plants had been moved from the light into the dark. The (13)C enrichment in respired CO(2) then decreased rapidly to within 3-7 per thousand of phloem sap after 30-60 min in the dark. This strong enrichment was not observed if light levels were low prior to the start of the dark period. Measurements of RQ confirmed that carbohydrates were the likely respiratory substrate for plants (RQ > 0.8) within the first 60 min after illumination. The strong (13)C enrichment that followed a high light-to-dark transition coincided with high respiration rates, suggesting that so-called light-enhanced dark respiration (LEDR) is fed by (13)C-enriched metabolites.     

Alterations in Growth, Photosynthesis, and Respiration in a Starchless Mutant of Arabidopsis thaliana (L.) Deficient in Chloroplast Phosphoglucomutase Activity

A mutant of Arabidopsis thaliana (L.) Heynh. which lacks leaf starch was isolated by screening for plants which did not stain with iodine. The starchless phenotype, confirmed by quantitative enzymic analysis, is caused by a single recessive nuclear mutation which results in a deficiency of the chloroplast isozyme of phosphoglucomutase. When grown in a 12-h photoperiod, leaves of the wild-type accumulated substantial amounts of starch but lower levels of soluble sugars. Under these conditions, the mutant accumulated relatively high levels of soluble sugars. Rates of growth and net photosynthesis of the mutant and wild-type were indistinguishable when the plants were grown in constant illumination. However, in a short photoperiod, the growth of the mutant was severely impaired, the rate of photosynthesis was depressed relative to the wild-type, and the rate of dark respiration, which was high following the onset of darkness, exhibited an uncharacteristic decay throughout the dark period. The altered control of respiration by the mutant, which may be related to the relatively high levels of soluble carbohydrate that accumulate in the leaf and stem tissue, is believed to be partially responsible for the low growth rate of the mutant in short days. The depressed photosynthetic capacity of the mutant may also reflect a metabolic adaptation to the accumulation of high levels of soluble carbohydrate which mimics the effects of alterations in source/sink ratio. The activities of sucrose phosphate synthase and acid invertase are significantly higher in the mutant than in the wild-type whereas ADP-glucose pyrophosphorylase activity is lower. This suggests that the activities of these enzymes may be modulated in response to metabolite concentrations or flux through the pathways.