Oxygen exchange associated with electron transport and photophosphorylation in spinach thylakoids

O₂ uptake in spinach thylakoids was composed of ferredoxin-dependent and -independent components. The ferredoxin-independent component was largely 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) insensitive (60%). Light-dependent O₂ uptake was stimulated 7-fold by 70 μM ferredoxin and both uptake and evolution (with O₂ as the only electron acceptor) responded almost linearly to ferredoxin up to 40 μM. NADP⁺ reduction, however, was saturated by less than 20 μM ferredoxin. The affinity of O₂ uptake for for O₂ was highly dependent on ferredoxin concentration, with $\text{K}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{(O}{}_2\text{)}$ of less than 20 μM at 2 μM ferredoxin but greater than 60 μM O₂ with 25 μM ferredoxin. O₂ uptake could be suppressed up to 80% with saturating NADP⁺ and it approximated a competitive inhibitor of O₂ uptake with a K_i of 8–15 μM. Electron transport in these thylakoids supported high rates of photophosphorylation with NADP⁺ (600 μmol ATP/mg Chl per h) or O₂ (280 μmol/mg Chl per h) as electron acceptors, with $\text{ATP}\text{2}\text{e}$ ratios of 1.15–1.55. Variation in $\text{ATP}\text{2}\text{e}$ ratios with ferredoxin concentration and effects of antimycin A indicate that cyclic electron flow may also be occurring in this thylakoid system. Results are discussed with regard to photoreduction of O₂ as a potential source of ATP in vivo.     

Fluxes of carbon dioxide and water vapour over an undisturbed tropical forest in south-west Amazonia

• 1 Carbon dioxide and water vapour fluxes were measured for 55 days by eddy covariance over an undisturbed tropical rain forest in Rondonia, Brazil. Profiles of CO₂ inside the canopy were also measured.
• 2 During the night, CO₂ concentration frequently built up to 500 ppm throughout the canopy as a result of low rates of exchange with the atmosphere. In the early morning hours, ventilation of the canopy occurred.
• 3 Ecosystem gas exchange was calculated from a knowledge of fluxes above the canopy and changes of CO₂ stored inside the canopy. Typically, uptake by the canopy was 15 μmol m^?2 s^?1 in bright sunlight and dark respiration was 6-7 μmol m^?2 s^?1 The quantum requirement at low irradiance was: 40 mol photons per mol of CO₂.
• 4 Bulk stomatal conductance of the ecosystem was maximal in the early morning (0.4-1.0 mol m^?2 s^?1) and declined over the course of the day as leaf-to-air vapour pressure difference increased.

     

A study of the impaired growth of roots of Zea mays seedlings at low oxygen concentrations

Abstract. Seedlings of Zea mays L. were grown in the dark at 27°C. Four-day-old seedlings were then exposed for 3 days to solutions equilibrated with gas mixtures to give O₂ concentrations between 0.02 and 0.25 mol m^?3. Root growth was impaired just as severely at 0.06 as 0.02 mol O₂ m^?3 while growth at 0.16 mol O₂ m^?3 was about the same as in solutions in equilibrium with air (0.25 mol O₂ m^?3). Growth of young seedlings at low O₂ concentrations was inhibited to the same extent in nutrient solution and 0.5 ml m^?3 CaCl₂, showing that the adverse effect of O₂ deficits on growth was not due to less uptake of inorganic nutrients. Furthermore, at low O₂ concentrations neither exposure of the shoots to a relative humidity of 100% (26.0 g H₂O m^?3) nor excision of the entire shoot enhanced root growth relative to that in plants with shoots at a relative humidity of 50% (13.0 g H₂O m^?3). Therefore, for these seedlings growing in the dark, impairment of root growth at low O₂ concentrations was not a consequence of water deficits in the shoot or of other shoot-root interactions. Total soluble sugars and amino acid concentrations were generally greater at low (0.02–0.06 mol O₂m^?3) than at high O₂ concentrations (0.16–0.25 mol O₂ m ^?3). This applied specifically to the root apices (0–2 mm) and expanding (2–15 mm) tissue except in some experiments where sugar concentrations in expanding tissue were slightly greater at high than at low O₂ concentrations. Critical O₂ pressures for respiration of excised root segments were approximately 0.117 and 0.065 mol O₂ m^?3 in the expanding and expanded zones of the roots, respectively. In contrast, the critical O₂ pressure exceeded 0.20 mol O₂ m^?3 in the apex, suggesting that O₂ supply for metabolic processes is most likely to be sub-optimal in this zone. Our results show clearly that the adverse effects of low O₂ concentrations are unlikely to be a consequence of substrate shortage for either respiration or synthesis of macromolecules; low rates of ATP regeneration in growing root tissues are the logical cause for impaired growth in young seedlings while they are being sustained by seed reserves.     

CO2 uptake and fluorescence responses for a shade-tolerant cactus Hylocereus undatus under current and doubled CO2 concentrations

Hylocereus undatus (Haworth) Britton and Rose growing in controlled environment chambers at 370 and 740 μmol CO₂ mol^?1 air showed a Crassulacean acid metabolism (CAM) pattern of CO₂ uptake, with 34% more total daily CO₂ uptake under the doubled CO₂ concentration and most of the increase occurring in the late afternoon. For both CO₂ concentrations, 90% of the maximal daily CO₂ uptake occurred at a total daily photosynthetic photon flux density (PPFD) of only 10 mol m^?2 day^?1 and the best day/night air temperatures were 25/15°C. Enhancement of the daily net CO₂ uptake by doubling the CO₂ concentration was greater under the highest PPFD (30 mol m^?2 day^?1) and extreme day/night air temperatures (15/5 and 45/35°C). After 24 days of drought, daily CO₂ uptake under 370 μmol CO₂ mol^?1 was 25% of that under 740 μmol CO₂ mol^?1. The ratio of variable to maximal chlorophyll fluorescence (F_y/F_m) decreased as the PPFD was raised above 5 mol m^?2 day^?1, at extreme day/night temperatures and during drought, suggesting that stress occurred under these conditions. F_v/F_m was higher under the doubled CO₂ concentration, indicating that the current CO₂ concentration was apparently limiting for photosynthesis. Thus net CO₂ uptake by the shade-tolerant H. undatus, the photosynthetic efficiency of which was greatest at low PPFDs. showed a positive response to doubling the CO₂ concentration, especially under stressful environmental conditions.     

Seasonal CO2 exchange patterns of developing peach (Prunus persica) fruits in response to temperature, light and CO2 concentration

CO₂ exchange rates per unit dry weight, measured in the field on attached fruits of the late-maturing Cal Red peach cultivar, at 1200 μmol photons m^?2S^?1 and in dark, and photosynthetic rates, calculated by the difference between the rates of CO₂ evolution in light and dark, declined over the growing season. Calculated photosynthetic rates per fruit increased over the season with increasing fruit dry matter, but declined in maturing fruits apparently coinciding with the loss of chlorophyll. Slight net fruit photosynthetic rates ranging from 0. 087 ± 0. 06 to 0. 003 ± 0. 05 nmol CO₂ (g dry weight)^?1 S^?1 were measured in midseason under optimal temperature (15 and 20°C) and light (1200 μmol photons m^?2 S^?1) conditions. Calculated fruit photosynthetic rates per unit dry weight increased with increasing temperatures and photon flux densities during fruit development. Dark respiration rates per unit dry weight doubled within a temperature interval of 10°C; the mean seasonal O₁₀ value was 2. 03 between 20 and 30°C. The highest photosynthetic rates were measured at 35°C throughout the growing season. Since dark respiration rates increased at high temperatures to a greater extent than CO₂ exchange rates in light, fruit photosynthesis was apparently stimulated by high internal CO₂ concentrations via CO₂ refixation. At 15°C, fruit photosynthetic rates tended to be saturated at about 600 μmol photons m^?2 S^?1. Young peach fruits responded to increasing ambient CO₂ concentrations with decreasing net CO₂ exchange rates in light, but more mature fruits did not respond to increases in ambient CO₂. Fruit CO₂ exchange rates in the dark remained fairly constant, apparently uninfluenced by ambient CO₂ concentrations during the entire growing season. Calculated fruit photosynthetic rates clearly revealed the difference in CO₂ response of young and mature peach fruits. Photosynthetic rates of younger peach fruits apparently approached saturation at 370 μl CO₂1^?2. In CO₂ free air, fruit photosynthesis was dependent on CO₂ refixation since CO₂ uptake by the fruits from the external atmosphere was not possible. The difference in photosynthetic rates between fruits in CO₂-free air and 370 μl CO₂ 1^?1 indicated that young peach fruits were apparently able to take up CO₂ from the external atmosphere. CO₂ uptake by peach fruits contributed between 28 and 16% to the fruit photosynthetic rate early in the season, whereas photosynthesis in maturing fruits was supplied entirely by CO₂ refixation.     

On the nature of the oxygen uptake in the light by Chondrus crispus. Effects of inhibitors,temperature and light intensity

The nature of the different processes of O₂ uptake involved in the light in the red macroalga Chondrus crispus Stackhouse (Rhodophyta, Gigartinales) was investigated. At limiting CO₂, INH (2.5 mM) did not alter the O₂ uptake rate. Glycolate was not excreted and did not accumulate within the cells. KCN reduced the rate of O₂ uptake in the light by 76% at limiting CO₂ and by 43% at saturating CO₂, but caused > 95% inhibition of O₂ evolution. DCMU (5 μM) totally blocked the photosynthetic electron transport chain, but allowed a residual O₂ uptake of 3.0±0.6 μmol O₂ .h^?1.g^?1 FW, irrespective of the CO₂ concentration. In saturating CO₂, a high light intensity pretreatment significantly stimulated the rate of O₂ uptake compared to net O₂ evolution, suggesting the persistence, in the light, of mitochondrial respiration. Irrespective of the CO₂ concentration, the optimum temperature for O₂ evolution was 17°C whereas dark O₂ uptake increased linearly with temperature. In contrast, O₂ uptake in the light showed an optimum at 17°C in limiting CO₂, and 21–25° C in saturating CO₂; its Q₁₀ was 2.4 at limiting CO₂, a value close to that of RuBP oxygenase, and 3.1 at saturating CO₂, a value close to that of dark respiration. It is concluded that: 1) mitochondrial respiration and Mehler reaction are both involved at all CO₂ concentrations, 2) RuBP oxygenase activity cannot account for more than 45%, and Mehler reaction for less than 20%, of the total O₂ uptake observed in the light at limiting CO₂.     

Changes in dormancy of Sisymbrium officinaleseeds do not depend on changes in respiratory activity

Effects of dark incubation at different temperatures were studied on dormancy and respiratory activity of seeds of Sisymbrium officinale (L.) Scop. Because germination of this species absolutely depends on the simultaneous action of light and nitrate, changes in dormancy could be studied in darkness without the interference of early germination events. Upon the start of incubation rates of O₂ uptake and CO₂ release rose. This was followed by a gradual decrease until stable levels of O₂ uptake and CO₂ release were achieved. Seeds kept for prolonged periods at 24^°C, showed neither a change in germination capacity nor in rates of O₂ uptake and CO₂ release. Respiratory quotients were 0.55–0.7. The initial rise in O₂ uptake correlated with the rate of water uptake and with breaking of primary dormancy. However, the subsequent decline in O₂ uptake was not generally linked to induction of secondary dormancy. An increased O₂ uptake was not required during breaking of secondary dormancy. It is concluded that changes in dormancy are not generally related to changes in respiratory activity. However, germination strongly depends on respiration. The increase in O₂ uptake started well before radicle protrusion. A far red irradiation only reversed this increase when it was given before germination escaped from its red light antagonising action. The contribution of different respiratory pathways was followed during prolonged incubation at 24^°C in darkness. KCN at 1.5 mM was needed to inhibit the cytochrome pathway (CP) and benzohydroxamic acid (BHAM) at 30 mM to inhibit the alternative pathway (AP). These concentrations did not exert any side effects. Electron flow was predominantly via the CP, maximally 10% was via the AP. Flow through the CP declined during the first 6 days and residual respiration remained constant. Therefore, the contribution of residual respiration became relatively more important with prolonged incubation. KCN at concentrations that almost completely inhibited flow through the CP, did not dramatically reduce germination. BHAM already inhibited germination at concentrations that do not inhibit oxygen uptake.     

Oxygen Uptake and Antioxidant Responses of the Free-Living Diplomonad Hexamita sp.

ABSTRACT. The free-living anaerobic flagellate Hexamita sp. was observed to actively consume O₂ with a K_m O₂ of 13 μM. Oxygen consumption increased lineraly with O₂ tension up to a threshold level of 100 μM, above which it was inhibited. Oxygen uptake was supported by a number of substrates but probably not coupled to energy conservation as cytochromes could not be detected spectro-photometrically. In addition, inhibitors specific for respiratory chain components did not significantly affect O₂ uptake. Respiration was however, partially inhibited by flavoprotein and iron-sulfur protein inhibitors. NAD(P)H supported O₂ consumption was measured in both particulate and soluble fractions; this activity was partially inhibited by quinacrine. A chemosensory response was observed in cells exposed to air, however no response was observed in the presence of superoxide dismutase plus catalase. Catalase and nonspecific peroxidase activity could not be detected, but superoxide dismutase activity was present. Superoxide dismutase was sensitive to NaN₃ and H₂O₂ but not KCN, suggesting a Fe prosthetic group. Flow cytometric analysis revealed that thiol levels in live cells were depleted in the presence of t-butyl H₂O₂. The observed NADPH-driven glutathione reductase activity is believed to recycle oxidized thiols in order to re-establish reduced thiol levels in the cell. The corresponding thiol cycling enzyme glutathione peroxidase could not be detected. The ability to withstand high O₂ tensions (100 μM) would enable Hexamita to spend short periods in a wider range of habitats. Prologed exposure to O₂ tensions higher than 100 μM leads to irreversible damage and cell death.     

Inhibition of Cyanide-Insensitive Respiration in <Emphasis Type="Italic">Klebsiella oxytoca</Emphasis> SYSU-011 by 8-Hydroxyquinolone

The inhibition of the cyanide (KCN)-insensitive respiration of Klebsiella oxytoca SYSU-011 by 8-hydroxyquinoline (8-HQ) was determined. Results showed that the profile of the rate of oxygen uptake of normal-grown and 8-HQ–grown K. oxytoca SYSU-011 was biphasic and similar, suggesting that 8-HQ did not inhibit the respiration of normal-grown K. oxytoca SYSU-011. A different biphasic KCN inhibition profile of respiration was observed for KCN-grown cells treated with and without 8-HQ. No decrease in respiration rate of KCN-grown cells and a 40% decrease in respiration rate of KCN-grown cells treated with 8-HQ were observed when KCN concentration was 10^–1 mM. Comparing differences of the profiles of oxygen uptake in KCN-grown cells with and without 8-HQ addition indicated that 8-HQ inhibited expression of the KCN-insensitive pathway carried out by nonheme oxidase. Greater inhibition of NADH oxidase activity by 2-n-heptyl-4-hydroxyquinoline-N-oxide from the cell membrane of the KCN-grown cells treated with 8-HQ, and more H₂O₂ production from these cells with than without 8-HQ, suggest that the function of the cyanide-insensitive pathway can stabilize the respiration of the cyanide-grown cells to prevent the production of H₂O₂.     

Promotion of elongation and acid invertase activity in Phaseolus vulgaris L. internode segments by phenylacetic acid

Phenylacetic acid (PAA) significantly stimulated the elongation of isolated Phaseolus vulgaris internodal segments and prevented the decline in acid invertase specific activity observed in segments incubated in the absence of growth substances. Unlike IAA, which stimulated both elongation and invertase activity over a very wide range of concentrations (<10^-4 - 1 mol.m^-3; optimum 10^-2 mol.m^-3), the response to PAA was restricted to a much narrower range of concentrations (3 × 10^-2 - 1 mol.m^-3; optimum ca. 1–2 × 10^-1mol.m^-3). At the optimum concentration of PAA, the stimulation of both responses was about 63–75% of that induced by the optimum concentration of IAA. The differences in the concentration range and magnitude of the responses to IAA and PAA were not due to differences in uptake of the two compounds. The stimulation of elongation by both compounds was prevented by 3.6 × 10^-2mol.m^-3 cycloheximide (CH), and acid invertase activites were greatly reduced compared with samples treated with growth substances alone. A saturating concentration of the specific auxin efflux carrier inhibitor N-1-naphthylphthalamic acid (NPA) slightly promoted the growth of control segments, probably by reducing the loss of residual endogenous auxin to the incubation medium. The elongation induced by PAA at its optimum concentration was considerably greater than the elongation induced by NPA, indicating that PAA did not cause growth by preventing the loss of endogenous auxin from the segments. Elongation responses to combinations of IAA and PAA suggested that the compounds were acting additively and that they were affecting growth by the same mechanism.     

UV-A Inhibition of Alternative Respiration in Pea Leaves and a Unicellular Green Alga Chlamydomonas reinhardtii

Total respiration (v_T) increased after exposure to UV, but a decrease in the capacity of SHAM-sensitive-alternative respiration (V_alt) was accompanied by an increase in residual respiration (v_res). The capacity for CN sensitive-cytochrome c respiration (V_cyt) was not inhibited by UV-A. After 4 h of irradiation of high-CO₂-grown cells of Chlamydomonas reinhardtii with UV-A (2 μW. CM^?2) in the presence of white light (300μE.m^?2.s^?1), the capacity of Vast was reduced from 10 to 4 μmol O₂. mg^?1Chl.h^?1, a 60 % reduction. After a similar exposure to UV-A, the capacity of V_alt in pea leaves was reduced from 13 to 5 μmol O₂.g^?1 fr wt.h^?1. Exposure to UV-C was not inhibitory, but UV-B caused up to 25% inhibition of the V^alt. Twenty to 48 h after exposure to UV-A radiation, the capacity of alternative respiration had recovered. UV-A inhibition of the alternative respiration was consistent with UV-A absorption by quinones, except that UV-A did not inhibit the cyt c pathway of electron transport that also involves the ubiquinones.     

A field study of the effects of elevated CO2 on carbon assimilation, stomatal conductance and leaf and branch growth of Pinus taeda trees

A study was conducted in 21-year-old loblolly pine (Pinus taeda L.) trees growing in plantation in north central Georgia, USA. The experiment used branch chambers to impose treatments of ambient, ambient +165 and ambient + 330 μmol mol^?1 CO₂. After one growing season there was no indication of acclimation to elevated CO₂. In August and September, carbon assimilation, measured by two different methods, was twice as high at ambient +330 μmol mol^?1 CO₂ than at ambient. Dark respiration was suppressed by 6% at ambient +165 and by 14% at ambient + 330 μmol mol^?1 CO₂. This suppression was immediate, and not an effect of exposure to elevated CO₂ during growth, since respiration was reduced by the same amount in all treatments when measured at a high CO₂ concentration. Elevated CO₂ increased the growth of foliage and woody tissue. It also increased instantaneous transpiration efficiency, but it had no effect on stomatal conductance. Since the soil at the study site had low to moderate fertility, these results suggest that the growth potential of forests on many sites may be enhanced by global increases in atmospheric CO₂, concentration.     

Land use and season affect fluxes of CO2, CH4, CO,N2O,H2 and isotopic source signatures in Panama: evidence from nocturnal boundary layer profiles

Conversion of tropical rainforests to pastures and plantations is associated with changes in soil properties and biogeochemical cycling, with implications for carbon cycling and trace gas fluxes. The stable isotopic composition of ecosystem respiration (δ¹³C_R and δ¹⁸O_R) is used in inversion models to quantify regional patterns of CO₂ sources and sinks, but models are limited by sparse measurements in tropical regions. We measured soil respiration rates, concentrations of CO₂, CH₄, CO, N₂O and H₂ and the isotopic composition of CO₂, CH₄ and H₂ at four heights in the nocturnal boundary layer (NBL) above three common land‐use types in central Panama, during dry and rainy seasons. Soil respiration rates were lowest in Plantation (average 3.4 μmol m^?2 s^?1), highest in Pasture (8.3 μmol m^?2 s^?1) and intermediate in Rainforest (5.2 μmol m^?2 s^?1). δ¹³C_R closely reflected land use and increased during the dry season where C₃ vegetation was present. δ¹⁸O_R did not differ by land use but was lower during the rainy than the dry season. CO₂ was correlated with other species in approximately half of the NBL profiles, allowing us to estimate trace gas fluxes that were generally within the range of literature values. The Rainforest soil was a sink for CH₄ but emissions were observed in Pasture and Plantation, especially during the wet season. N₂O emissions were higher in Pasture and Plantation than Rainforest, contrary to expectations. Soil H₂ uptake was highest in Rainforest and was not observable in Pasture and Plantation during the wet season. We observed soil CO uptake during the dry season and emissions during the wet season across land‐use types. This study demonstrated that strong impacts of land‐use change on soil–atmosphere trace gas exchange can be detected in the NBL, and provides useful observational constraints for top‐down and bottom‐up biogeochemistry models.     

Discrimination of nitrogen isotopes during absorption of ammonium and nitrate at different nitrogen concentrations by rice (Oryza sativa L.) plants

Studies of uptake of ionic sources of N by two hydroponically grown rice (Oryza sativa L.) cultivars (paddy‐field‐adapted Koshihikari and dryland‐adapted Kanto 168) showed that the magnitude of the nitrogen isotope fractionation (?) for uptake of NH₄⁺ depended on the concentrations of NH₄⁺ and cultivar (averaging –6·1‰ for Koshihikari and –12·0‰ for Kanto 168 at concentrations from 40 to 200 mmol m^?3 and, respectively, –13·4 and –28·9‰ for the two cultivars at concentrations from 0·5 to 4 mol m^?3). In contrast, the ? for uptake of NO₃^? in similar experiments was almost insensitive to the N concentration, falling within a much narrower range (+3·2‰ to –0·9‰ for Koshihikari and –0·9‰ to –5·1‰ for Kanto 168 over NO₃^? concentrations from 0·04 to 2 mol m^?3). From longer term experiments in which Norin 8 and its nitrate‐reductase deficient mutant M819 were grown with 2 or 8 mol m^?3 NO₃^? for 30 d, it was concluded that the small concentration‐independent isotopic fractionation during absorption of this ion was not related to nitrate reductase activity.     

Evidence for a significant contribution by peroxidase-mediated O2 uptake to root respiration of Brachypodium pinnatum

This study describes the O₂ uptake characteristics of intact roots of Brachypodium pinnatum. In the presence of 25 mM salicylhydroxamic acid (SHAM), concentrations of KCN below 3.5 νM had no effect on the rate of root respiration, whereas in the absence of 25 mM SHAM a significant inhibition of approx. 18% was observed. This indicates that an O₂-consuming reaction, not associated with the cytochrome pathway, the alternative pathway or the “residual component”, operates in the absence of any inhibitors in roots of B. pinnatum. We demonstrate here that this fourth O₂-consuming reaction is mediated by a peroxidase. A peroxidase which catalyzed O₂ reduction in the presence of NADH was readily washed from the roots of B. pinnatum. This peroxidase was stimulated by 5 mM SHAM, whereas ascorbic acid, catalase, catechol, gentisic acid, low concentrations potassium cyanide (3.5 μM), sodium azide, sodium sulfide, superoxide dismutase and high concentrations SHAM (25 mM) inhibited this reaction. Except for high concentrations of SHAM and concentrations of KCN higher than approx. 3.5 μM, these effectors could not be used to inhibit the peroxidase-mediated O₂ uptake in intact roots of B. pinnatum. Concentrations of SHAM below 10 mM stimulated O₂ uptake up to 15% of the control rate, depending on concentration, whereas 25 mM SHAM inhibited O₂ uptake by 35%. The stimulation at low concentrations resulted from a SHAM-stimulated peroxidase activity, whereas 25 mM SHAM completely inhibited both the peroxidase-mediated O₂ uptake and the activity of the alternative pathway. A method is presented for determining the relative contributions of each of the four O₂-consuming reactions, i.e. the cytochrome pathway, the alternative pathway, the “residual component” and the peroxidase-mediated O₂ uptake. The peroxidase-mediated O₂ uptake contributed 21% to the total rate of oxygen uptake in roots of B. pinnatum, the cytochrome pathway contributed 41%, the alternative pathway 14% and the “residual component” 24%.     

Hydrogen peroxide-mediated cell-wall stiffening in vitro in maize coleoptiles

It has recently been proposed that H₂O₂-dependent peroxidative formation of phenolic cross-links between cell-wall polymers serves as a mechanism for fixing the viscoelastically extended wall structure and thus confers irreversibility to wall extension during cell growth (M. Hohl et al. 1995, Physiol. Plant. 94: 491–498). In the present paper the isolated cell wall (operationally, frozen/thawed maize coleoptile segments) was used as an experimental system to investigate H₂O₂-dependent cell-wall stiffening in vitro. Hydrogen peroxide inhibited elongation growth (in vivo) and decreased cell-wall extensibility (in vitro) in the concentration range of 10–10000 mol·1^–1. In rheological measurements with a constant-load extensiometer the stiffening effect of H₂O₂ could be observed with both relaxed and stressed cell walls. In-vitro cell-wall stiffening was a time-dependent reaction that lasted about 60 min in the presence of saturating concentrations of H₂O₂. The presence of peroxidase in the growth-limiting outer epidermal wall of the coleoptile was shown by histochemical assays. Peroxidase inhibitors (azide, ascorbate) suppressed the wall-stiffening reaction by H₂O₂ in vitro. Hydrogen peroxide induced the accumulation of a fluorescent, insoluble material in the cell walls of living coleoptile segments. These results demonstrate that primary cell walls of a growing plant organ contain all ingredients for the mechanical fortification of the wall structure by H₂O₂-inducible phenolic cross-linking.Supported by Deutsche Forschungsgemeinschaft. I thank Ms. Bärbel Huvermann for expert technical assistance.     

Growth and maintenance respiration in leaves of northern red oak seedlings and mature trees after 3 years of ozone exposure

A two-component model of growth and maintenance respiration is used to study the response of northern red oak (Quercus rubra L.) seedlings and 32-year-old trees to sub-ambient (10 μmol h; cumulative dose based on 7 h daily mean), ambient (43 μmol h), and twice-ambient (85 μmolh) ozone. The relative growth rates (RGR) of leaves sampled from seedlings and trees were similar across treatments, as were specific leaf respiration rates (SRR). Growth coefficients estimated from the SRR versus RGR relationship averaged 25-3 mol CO2 kg^?1 leaf dry mass produced for seedlings and 21-5 mol kg^?1 for trees. Maintenance coefficients ranged from 0-89 to 1-07 mol CO₂ kg^?1 leaf dry mass d^?1 for seedlings and from 0-64 to 0-84 mol kg-1 d^?1 for trees. Neither coefficient was affected by ozone. Leaves sampled throughout the growing season also showed little response of respiration to ozone. This occurred despite a 30% reduction in net photosynthesis for trees grown at twice-ambient ozone. These results suggest that growth and maintenance respiration in young northern red oak leaves are not affected by ozone and that in older leaves injury can occur without a parallel increase in so-called ‘maintenance’ respiration.     

Effect of irradiance and temperature on the photosynthesis of a cultivated red alga,Pyropia tenera (= Porphyra tenera), at the southern limit of distribution in Japan

The effect of irradiance and temperature on the photosynthesis of the red alga, Pyropia tenera, was determined for maricultured gametophytes and sporophytes collected from a region that is known as one of the southern limits of its distribution in Japan. Macroscopic gametophytes were examined using both pulse‐amplitude modulated fluorometry and/or dissolved oxygen sensors. A model of the net photosynthesis–irradiance (P‐E) relationship of the gametophytes at 12°C revealed that the net photosynthetic rate quickly increased at irradiances below the estimated saturation irradiance of 46 μmol photons m^?2 s^?1, and the compensation irradiance was 9 μmol photons m^?2 s^?1. Gross photosynthesis and dark respiration for the gametophytes were also determined over a range of temperatures (8–34°C), revealing that the gross photosynthetic rates of 46.3 μmol O₂ mg_chl‐a^?1 min^?1 was highest at 9.3 (95% Bayesian credible interval (BCI): 2.3–14.5)°C, and the dark respiration rate increased at a rate of 0.93 μmol O₂ mg_chl‐a^?1 min^?1°C^?1. The measured dark respiration rates ranged from ?0.06 μmol O₂ mg_chl‐a^?1 min^?1 at 6°C to ?25.2 μmol O₂ mg_chl‐a^?1 min^?1 at 34°C. The highest value of the maximum quantum yield (Fv/Fm) for the gametophytes occurred at 22.4 (BCI: 21.5–23.3) °C and was 0.48 (BCI: 0.475–0.486), although those of the sporophyte occurred at 12.9 (BCI: 7.4–15.1) °C and was 0.52 (BCI: 0.506–0.544). This species may be considered well‐adapted to the current range of seawater temperatures in this region. However, since the gametophytes have such a low temperature requirement, they are most likely close to their tolerable temperatures in the natural environment.     

GROWTH,PHOTOSYNTHESIS AND MAINTENANCE METABOLIC COST IN THE DIATOM PHAEODACTYLUM TRICORNUTUM AT VERY LOW LIGHT LEVELS 1

The compensation point for growth of Phaeodactylum tricornutum Bohlin is less than 1 μmol. m^?2s^?1. Growth at low PFDs (<3.5 μmol. m^?2.s^?1) does not appear to reduce the maximum quantum efficiency of photosynthesis (ø_m) or to greatly inhibit the potential for light-saturated, carbon-specific photosynthesis (P_m^c). The value for ø_m in P. tricornutum is 0.10–0.12 mol O₂-mol photon^?1, independent of acclimation PFD between 0.75 and 200 μmol.m^?2.s^?1 in nutrient-sufficient cultures. P_m^c in cells of P. tricornutum acclimated to PFDs <3.5 μmol m^?2?s^?1 is approximately 50% of the highest value obtained in nutrient-sufficient cultures acclimated to growth-rate-saturating PFDs. In addition, growth at low PFDs does not severely restrict the ability of cells to respond to an increase in light level. Cultures acclimated to growth at lees than 1% of the light-saturated growth rate respond rapidly to a shift-up in PFD after a short initial lag period and achieve exponential growth rates of 1.0 d^?1 (65% of the light- and nutrient-saturated maximum growth rate) at both 40 and 200 μmol.m^?2.s^?1     

Balance between Cyanide-Sensitive and -Insensitive Respiration in Wheat Root Mitochondria, as Influenced by Salt Concentration in the Plant Growth Medium

Mitochondria were isolated from 7-day-old wheat roots (Triticum vulgare Vill. cv. Svenno Spring Wheat) grown in either a full-strength culture medium (100%) or in the same medium diluted 100 times (1%). Outer membrane integrity was assayed using the cytochrome c reduction assay. This indicated about 20% damage. Using an oxygen electrode the respiration of the mitochondria was measured with either malate or succinate as the substrate (both 40 mM). KCN (3 mM) and salicylhydroxamic acid (SHAM, 1 mM) were used as inhibitors. The properties of the isolated mitochondria (STATE 3 rate, ADP/O ratio, and KCN-sensitivity) depend upon the ionic concentration of the growth medium of the roots. In the mitochondria isolated from roots grown in the 1% medium (1% mitochondria) there is a synergistic effect of KCN and SHAM. This means that electrons can be shifted from one pathway to the other when only one of the inhibitors is added. This flexibility between the electron pathways is almost nil in the mitochondria isolated from roots grown in the 100% medium (100% mitochondria). The maximal capacity of the alternative electron pathway (= rate in the presence of KCN) is higher in 1% (40 nmol O₂ min^?1 (mg protein)^?1) than in 100% mitochondria (20 nmol O₂ min^?1 (mg protein)^?1. In 100% mitochondria the alternative pathway seems to be operating at maximal capacity in the absence of KCN with both substrates and in both STATES 3 and 4. In 1% mitochondria the alternative pathway functions at >50% of its capacity in the absence of KCN.