Does ear C sink strength contribute to overcoming photosynthetic acclimation of wheat plants exposed to elevated CO2?

Wheat plants (Triticum durum Desf., cv. Regallo) were grown in the field to study the effects of contrasting [CO(2)] conditions (700 versus 370 μmol mol(-1)) on growth, photosynthetic performance, and C management during the post-anthesis period. The aim was to test whether a restricted capacity of sink organs to utilize photosynthates drives a loss of photosynthetic capacity in elevated CO(2). The ambient (13)C/(12)C isotopic composition (δ(13)C) of air CO(2) was changed from -10.2‰ in ambient [CO(2)] to -23.6‰ under elevated [CO(2)] between the 7th and the 14th days after anthesis in order to study C assimilation and partitioning between leaves and ears. Elevated [CO(2)] had no significant effect on biomass production and grain filling, and caused an accumulation of C compounds in leaves. This was accompanied by up-regulation of phosphoglycerate mutase and ATP synthase protein content, together with down-regulation of adenosine diphosphate glucose pyrophosphatase protein. Growth in elevated [CO(2)] negatively affected Rubisco and Rubisco activase protein content and induced photosynthetic down-regulation. CO(2) enrichment caused a specific decrease in Rubisco content, together with decreases in the amino acid and total N content of leaves. The C labelling revealed that in flag leaves, part of the C fixed during grain filling was stored as starch and structural C compounds whereas the rest of the labelled C (mainly in the form of soluble sugars) was completely respired 48 h after the end of labelling. Although labelled C was not detected in the δ(13)C of ear total organic matter and respired CO(2), soluble sugar δ(13)C revealed that a small amount of labelled C reached the ear. The (12)CO(2) labelling suggests that during the beginning of post-anthesis the ear did not contribute towards overcoming flag leaf carbohydrate accumulation, and this had a consequent effect on protein expression and photosynthetic acclimation.     

Does GABA increase the efficiency of symbiotic N2 fixation in legumes?

The ability to regulate the rates of metabolic processes in response to changes in the internal and/or external environment is a fundamental feature which is inherent in all organisms. This adaptability is necessary for conserving the stability of the intercellular environment (homeostasis) which is essential for maintaining an efficient functional state in the organism. Symbiotic nitrogen fixation in legumes is an important process which establishes from the complex interaction between the host plant and microorganism. This process is widely believed to be regulated by the host plant nitrogen demand through a whole plant N feedback mechanism in particular under unfavorable conditions. This mechanism is probably triggered by the impact of shoot-borne, phloem-delivered substances. The precise mechanism of the potential signal is under debate, however, the whole phenomenon is probably related to a constant amino acid cycling within the plant, thereby signaling the shoot nitrogen status. Recent work indicating that there may be a flow of nitrogen to bacteroids is discussed in light of hypothesis that such a flow may be important to nodule function. Large amount of γ-aminobutyric acid (GABA) are cycled through the root nodules of the symbiotic plants. In this paper some recent evidence concerning the possible role of GABA in whole-plant-based upregulation of symbiotic nitrogen fixation will be reviewed.Key words: γ-aminobutyric acid, nitrogen fixation, nodule, symbiosis, translocation, signalingNitrogen (N) is major limiting nutrient for the growth of most plant species in different ecosystems. Acquisition and assimilation of N is second in importance only to photosynthesis for plant growth and development. Elemental N is a key constituent of protein, nucleic acids and other vital cellular components. Most plants acquire N from the soil solution either as nitrate or ammonium ions. In addition, some plants can utilize the atmospheric gaseous nitrogen pool through symbiotic associations with species of bacteria, cyanobacteria or actinomycetes that contain the N₂ fixing enzyme, nitrogenase. Clearly, the crucial role that symbiotic plants play in plant growth requires that physiologists understand the biochemical and molecular events that regulate fixation and subsequent metabolism of nitrogen.Symbiotic N₂ fixation is an important process for increasing the plant available N and thereby the growth capacity of legumes. This process results from the complex interaction between the host plant and microorganism.¹ The host plant provides the microorganism with carbon and a source of energy for growth and functions while the microorganism fixes atmospheric N₂ and provides the plant with a source of reduced nitrogen in the form of ammonium. An adequate supply of carbohydrates is an essential requirement of nodule functioning as N₂ fixation is expensive in terms both of energy and carbon for the synthesis of N-products. Sucrose synthesized in photosynthesis and exported to the nodules via the phloem, is the primary fuel for N₂ fixation.² Sucrose can be metabolized in the cytoplasm of infected, uninfected or interstitial cells with organic acids as the end products. Malate is strongly believed to be the major respiratory substrate for bacteroids.³ This dicarboxylic acid is the major energy source for the bacteroids and plant mitochondria, and is used for NH₄⁺ assimilation as carbon skeleton in the glutamine synthetase/glutamate synthase (GS/GOGAT) pathway.⁴ The products of symbiotic N₂ fixation are exported from the nodules to the rest of the host plant where they are incorporated into essential macro-molecules such as amino acids, proteins that drive plant growth, development and yields. According to the fixation products, root nodules are generally divided into two major groupings:¹ (1) indeterminate nodules that are elongate-cylindrical activity that transport fixed N as amides such as alfalfa, pea and clover; and (2) determinate nodules that are spherical with determinate internal meristematic activity that transport fixed N as ureides, such as soybean and common bean. The complex series of events leading to the formation and functioning of the fixation machinery required controlled coordinated expression of both bacterial and host plant genes.     

Does down‐regulation of photosynthetic capacity by elevated CO2 depend on N supply in Dactylis glomerata?

Dactylis glomerata was grown hydroponically in a controlled environment at ambient (360 μl l⁻¹) or elevated (680 μl l⁻¹) CO₂ and four concentrations of nitrogen (0.15, 0.6, 1.5 and 6.0 m M NO₃⁻), to test the hypothesis that reduction of photosynthetic capacity at elevated [CO₂] is dependent on N availability and mediated by a build-up of non-structural carbohydrates. Photosynthetic capacity of the youngest fully expanded leaf (leaf 5, 2 days after full expansion) was reduced in CO₂-enriched plants at low, but not high N supply and so the stimulation of net photosynthesis by CO₂ enhancement was less at low than at high N supply. CO₂ enrichment resulted in a decrease in ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) content on a leaf area basis at 0.6 and 1.5 m M NO₃⁻, but not at 0.15 and 6.0 m M NO₃⁻, and had no effect on the total N content of the leaf on an area basis. However, decreases in Rubisco content could be primarily accounted for by a decrease in total N content of leaves, independent of [CO₂]. A doubling of the Rubisco content by increasing the N supply beyond 0.6 m M had only a marginal effect on the maximum carboxylation velocity in vivo, suggesting that the fraction of inactive Rubisco increased with increasing N supply. Although CO₂-enriched plants accumulated more non-structural carbohydrates in the leaf, the reduction of photosynthetic capacity at low N supply was not mediated simply by a build-up of carbohydrates. In D . glomerata , the photosynthetic capacity was mainly determined by the total N content of the leaf.     

Extra-amniotic 15(S)-15 methyl PGF2α to induce abortion: A study of three administration schedules

Abortion was induced in 60 patients between 8 and 18 weeks gestation using 15(S)-15 methyl PGF₂α in one of three extra-amniotic administration schedules: 1.0 mg in viscous medium (Tylose), 1 mg in viscous medium (Hyskon) or 0.5 mg in non-viscous medium repeated at 12 hours. Eighty per cent of patients aborted within 24 hours in each group. The overall mean induction-abortion interval (± S.E.) was 17.6 ± 2.0: there was no significant difference between the three groups. Twenty patients treated with 1.0 mg in viscous medium had the catheter removed immediately following the prostaglandin injection and the success rate was not significantly altered.Gastro-intestinal side effects (vomiting in 50%, diarrhoea in 32.5%) were more frequent in the patients treated with the larger dose though the difference was not statistically significant. No significant haematological or biochemical changes were detected during the 24 hours following the start of treatment in 24 patients investigated. Thirty seven of the 60 patients (61.5%) aborted completely and did not require surgical evacuation, and none lost more than 500 ml of blood, nor required transfusion.It is concluded that abortion can be induced with a single extra-amniotic injection of 1 mg of 15(S)-15 methyl PGF₂α in viscous medium in a large percentage of patients but that the incidence of side effects is high.     

Does the growth response of woody plants to elevated CO2 increase with temperature? A model‐oriented meta‐analysis

The temperature dependence of the reaction kinetics of the Rubisco enzyme implies that, at the level of a chloroplast, the response of photosynthesis to rising atmospheric CO₂ concentration (C_a) will increase with increasing air temperature. Vegetation models incorporating this interaction predict that the response of net primary productivity (NPP) to elevated CO₂ (eC_a) will increase with rising temperature and will be substantially larger in warm tropical forests than in cold boreal forests. We tested these model predictions against evidence from eC_a experiments by carrying out two meta‐analyses. Firstly, we tested for an interaction effect on growth responses in factorial eC_a × temperature experiments. This analysis showed a positive, but nonsignificant interaction effect (95% CI for above‐ground biomass response = ?0.8, 18.0%) between eC_a and temperature. Secondly, we tested field‐based eC_a experiments on woody plants across the globe for a relationship between the eC_a effect on plant biomass and mean annual temperature (MAT). This second analysis showed a positive but nonsignificant correlation between the eC_a response and MAT. The magnitude of the interactions between CO₂ and temperature found in both meta‐analyses were consistent with model predictions, even though both analyses gave nonsignificant results. Thus, we conclude that it is not possible to distinguish between the competing hypotheses of no interaction vs. an interaction based on Rubisco kinetics from the available experimental database. Experiments in a wider range of temperature zones are required. Until such experimental data are available, model predictions should aim to incorporate uncertainty about this interaction.     

A study of prostaglandin F2α as the luteolysin in swine: I. Effect of prostaglandin F2α in hysterectomized gilts

Experiments were conducted to determine if prostaglandin F_2α (PGF_2α) is luteolytic in swine. In Experiment 1, four bilaterally hysterectomized gilts were injected with PGF_2α at 0800 (10mg) and 2000 hours (10mg) and four gilts received .9% saline at the same times on day 17 after onset of estrus. Treatments were reversed in the two groups of gilts 21 days later. All eight PGF_2α treated gilts exhibited estrus an average of 88.0 ± 13.5 hours after treatment and average duration of estrus was 66.0 ± 16.4 hours. Saline treated controls did not exhibit estrus. Two additional gilts were hysterectomized bilaterally and the saphenous artery catheterized on day 7 after onset of estrus. PGF_2α injected on day 17 resulted in a precipitous decline in plasma progestin concentration and onset of estrus by 110 and 90 hours in gilts 1 and 2, respectively. Another bilaterally hysterectomized gilt, with CL marked with India ink, received PGF_2α on day 17. Estrus occurred 92 hours later and, on day 4, regression of marked CL to corpora albicantia and presence of newly formed CL was confirmed at laparotomy.In Experiment 2, 12 bilaterally hysterectomized gilts were treated with PGF_2α at 0800 (10mg) and 2000 hours (10mg) on either day 8, 11, 14 or 17 after onset of estrus. None of the gilts treated on days 8 and 11 exhibited estrus. Two of three gilts treated on day 14 and all three gilts treated on day 17 exhibited estrus at an average of 116.0 ± 9.8 hours post-treatment. Average duration of estrus was 49.6 ± 8.8 hours.     

Does salt stress increase the ability of the exotic legume Acacia longifolia to compete with native legumes in sand dune ecosystems?

Sand dune ecosystems are one of the areas most affected by the introduction of invasive species which represents a threat for biodiversity conservation. Their invasion patterns and spread may depend on their salinity tolerance, besides other factors. To test this hypothesis, we investigated the effects of salt stress on seed germination and on the activity of antioxidant enzymes (catalase, CAT; ascorbate peroxidase, APX; peroxidase, POX; and glutathione reductase, GR) in two legume species, an invasive, Acacia longifolia (Andrews.) Willd., and a native, Ulex europaeus (L.), very common in the sand dunes of the coast of Portugal. Salt stress was induced by adding NaCl at different concentrations, 0, 50, 100 and 200 mM, for 15 days. Results showed that the highest germination percentages were obtained in distilled water (control) and that, with increasing salt concentration, seed germination was delayed and decreased in both species. Inhibition of germination was higher in the native species, only 3% of seeds germinated at 100 mM and no seeds germinated at 200 mM NaCl. In the invasive species, the reduction was higher at 200 mM NaCl (16%). Considering the coefficient of germination velocity, a decrease in both species with increasing NaCl concentration was observed. The CAT and GR activities decreased in A. longifolia with increasing salinity. In turn, APX activity significantly increased as NaCl concentration increased while the POX activities declined at the highest NaCl concentration. On the other hand, at 50 mM NaCl lower activity of CAT and APX and higher GR and POX were found in U. europaeus. In both species, protein content increased as NaCl concentration increased. In addition, it seems that APX activities play an essential role in the scavenging reactive oxygen species (ROS). These results suggest that the seeds of the invasive legume A. longifolia are more tolerant to salinity than the native legume U. europaeus, and seem better equipped to handle the physiological stress of high salinity, which may contribute to its invasive ability in sand dunes.     

Do plants of a semi-natural grassland community benefit from long-term CO2 enrichment?

Increasing atmospheric CO₂ concentration ([CO₂]) may alter plant community structure. The long-term responses of a semi-natural grassland community to elevated [CO₂] and different cutting regimes were investigated. During four years the grassland was exposed in situ to a mean [CO₂] of 660 ppm using Free-Air CO₂ Enrichment (FACE) and harvested once or twice per season. Under elevated [CO₂], annual community biomass production was stimulated significantly only in the fourth year of investigation. Functional plant groups responded differentially to CO₂ enrichment causing a clear shift in botanical composition from 1999 to 2002 towards a higher proportion of legumes under elevated [CO₂] and two harvests per year, respectively. Photosynthetic capacity was not affected by higher [CO₂] in the legume Lotus corniculatus but downregulated in the monocot Bromus erectus. Under elevated [CO₂] the nitrogen content was lower in all functional plant groups, though C/N ratio was enhanced significantly only in grasses and non-leguminous dicots. In this nutrient-poor grassland community, legumes exhibit a higher competitiveness under elevated [CO₂] due to their ability of symbiotic N₂-fixation.Steigende atmosphärische CO₂ Konzentrationen ([CO₂]) können das Artengefüge von Pflanzengemeinschaften verändern. In der vorliegenden Studie wurden die langfristigen Reaktionen eines naturnahen Kalkmagerrasens auf eine [CO₂] Erhöhung und verschiedene Schnittfrequenzen untersucht. Mittels eines FACE (F ree A ir CO₂E nrichment) Systems wurde das untersuchte Graslandökosystem 4 Jahre lang in-situ einer mittleren [CO₂] von 660 ppm ausgesetzt und ein- bzw. zweimal pro Jahr gemäht. Eine signifikante Steigerung der jährlichen Biomasseproduktion durch erhöhtes CO₂ wurde erst im vierten Untersuchungsjahr beobachtet. Die funktionellen Pflanzengruppen reagierten unterschiedlich auf die [CO₂] Erhöhung, wodurch sich von 1999 bis 2002 sowohl unter erhöhtem CO₂ als auch bei 2 Ernten pro Jahr die Zusammensetzung der Pflanzengemeinschaft zu einem höheren Anteil von Leguminosen verschob. Die Photosynthesekapazität der Leguminose Lotus corniculatus wurde durch erhöhtes CO₂ nicht beeinflusst, während sie bei der Monokotyle Bromus erectus herabgesetzt wurde. Die [CO₂] Erhöhung führte in allen funktionellen Pflanzengruppen zu einem geringeren Stickstoffgehalt, jedoch war das C/N Verhältnis nur bei Gräsern und nicht-leguminosen Dikotylen signifikant erhöht. Die Fähigkeit zur symbiontischen Stickstofffixierung stärkt die Konkurrenzkraft der Leguminosen in der untersuchten nährstoffarmen Pflanzengemeinschaft.     

How does the C4 grass Eragrostis pilosa respond to elevated carbon dioxide and infection with the parasitic angiosperm Striga hermonthica?

Eragrostis pilosa (Linn.) P Beauv., a C₄ grass native to east Africa, was grown at both ambient (350 μmol mol⁻¹ and elevated (700 μmol mol⁻¹) CO₂ in either the presence or absence of the obligate, root hemi-parasite Striga hermonthica (Del.) Benth. Biomass of infected grasses was only 50% that of uninfected grasses at both CO₂ concentrations, with stems and reproductive tissues of infected plants being most severely affected. By contrast, CO₂ concentration had no effect on growth of E. pilosa , although rates of photosynthesis were enhanced by 30–40% at elevated CO₂. Infection with S. hermonthica did not affect either rates of photosynthesis or leaf areas of E. pilosa , but did bring about an increase in root:shoot ratio, leaf nitrogen and phosphorus concentration and a decline in leaf starch concentration at both ambient and elevated CO₂. Striga hermonthica had higher rates of photosynthesis and shoot concentrations of soluble sugars at elevated CO₂, but there was no difference in biomass relative to ambient grown plants. Both infection and growth at elevated CO₂ resulted in an increase in the Δ¹³C value of leaf tissue of E. pilosa , with the CO₂ effect being greater. The proportion of host-derived carbon in parasite tissue, as determined from δ¹³C values, was 27% and 39% in ambient and elevated CO₂ grown plants, respectively. In conclusion, infection with S. hermonthica limited growth of E. pilosa , and this limitation was not removed or alleviated by growing the association at elevated CO₂.     

Photoconvertible protochlorophyll(ide) in vivo: A single species or two species in dynamic equilibrium?

The decreasing absorbances in vivo of protochlorophyll(ide) at 635 and 650 nm bear the same relationships to one another during photoconversion to chlorophyll(ide) a in the leaves of dark-grown barley seedlings, regardless of whether the actinic light is absorbed primarily at 630, 640 or 671 nm. Accordingly, the absorption bands at 635–637 and 650 nm of photoconvertible protochlorophyll(ide) are attributed to a single species of membrane-bound protochlorophyll(ide) molecule or, alternatively, to two species which are in dynamic equilibrium.     

Where to sleep in a rural landscape? A comparative study of resting sites pattern in two syntopic Martes species

The niche‐complementarity hypothesis predicts that two sympatric species must differ in their requirements for one of the three main ecological dimensions (i.e. habitat use, diet, and activity time) to coexist. European pine marten Martes martes and stone marten M. foina are syntopic medium‐sized mustelids with very similar morphology and ecology for which resting sites are a key resource. To better understand how these species coexist, we investigated whether key features of their resting site pattern (number of resting sites, area over which they are distributed, main habitat type used for resting) differed. We used diurnal telemetry to identify resident individuals (e.g. spatially stable individuals over time) and to locate them during resting periods in a fragmented forested area in France. Stone marten used fewer resting sites distributed over a smaller surface area than pine marten. Most stone marten resting sites were located in open habitat (83%) in the proximity of human habitations, whereas pine martens rested almost exclusively in forest (98%). Sex, age, and season explained some variability in both the number of resting sites and the probability of resting within forested habitat for stone marten but not pine marten. The area covered by resting sites was larger in males than in females, but age modulated this difference in an opposite way for the two species. Such a pattern was expected given the intra‐sexual territoriality and the reproductive phenology of these species. Overall, stone marten showed higher inter‐individual variability in resting site pattern than pine marten. The particular pattern observed in subadult male stone martens during summer (increase in resting site surface area and in the probability to rest in forest) may reflect an attempt to settle in forests, and we discuss these implications in the context of interspecific competition.     

Does estradiol stimulate in vivo production of 1,25-dihydroxyvitamin D3 in the rat?

Female rats were injected with estradiol benzoate (3 mg/kg daily) or corn oil for 8 days before receiving 325 picomoles of 25-[26,27³H]-hydroxyvitamin D₃ intravenously. Eighteen hours later lipids were extracted from plasma, gut mucosa and kidneys and vitamin D₃ metabolites were separated using Sephadex LH-20 and chloroform: hexanes (65:35) column chromatography. Estradiol treatment increased 1,25-[26,27-³H]-dihydroxyvitamin D₃ content in all three isssues.     

Does reproductive success increase with age or with size in species with indeterminate growth? A case study using sand lizards (Lacerta agilis)

Most data on determinants of reproductive success (RS) and reproductive tactics are correlational in nature, and hence cannot be used to infer causation. Consistent patterns-such as an increase in RS with age, as seen in many types of organisms-may result from diverse underlying mechanisms. Ontogenetic increases in RS in mammals and birds may be due largely to direct effects of age (via learning, etc.) but our analyses show that apparently analogous ontogenetic shifts in reproductive tactics and increases in RS in sand lizards (Lacerta agilis) are actually due to ontogenetic changes in body size. When size effects are removed, age exerts very little effect on either reproductive behaviour or RS in either sex. In many taxa, both age and body size may exert important effects on reproductive biology, and disentangling these effects should be a focus of further research.