Effects of Oxygen on Metabolism by the Glycollate Pathway in Leaves

Segments of wheat leaves were supplied in the light with ¹⁴C-labelledserine or glucose in atmospheres containing different concentrationsof O₂ and zero or 350 parts/10⁶ CO₂. Some O₂ was necessary forsucrose synthesis from either serine or glucose but sucrosesynthesis from glucose depended on reactions with a high affinityfor O₂ whereas sucrose synthesis from serine depended both onreactions with high and low affinities for O₂. In the presenceof CO₂ sucrose synthesis from serine was decreased when theO₂ concentration was increased from 20 to 80% by volume andCO₂ was liberated; sucrose synthesis from glucose was almostunaffected by the same change in conditions. Also, in an atmospherecontaining 80% O₂ and 350 parts/10⁶ CO₂, radioactivity from[¹⁴C]serine, was incorporated into glycine. This was not truefor glucose feeding. Hence glucose provides a substrate forsucrose synthesis but not for photorespiration whereas serineis used for both processes in the presence of CO₂; in the absenceof CO₂ glucose provides substrate for both sucrose synthesisand photorespiration and serine metabolism to sucrose is restricted.     

Glycolate Pathway and Serine Synthesis in Relation to CO2 Concentration in Tomato Leaves

Isotopic trapping of the carbon flowing through the glycolatepathway by exogenous glycolate, glycine and L-serine was investigatedduring ¹⁴CO₂ photosynthesis at different CO₂ concentrationsin tomato leaves. L-Serine markedly trapped the carbon flowingfrom ¹⁴CO₂. The amounts of ¹⁴C incorporated into serine decreasedat a high CO₂ concentration, but increased with an increasein the CO₂ concentration in the presence of exogenous serineduring 10-min photosynthesis in ¹⁴CO₂. When ¹⁴CO₂ was fed for5 to 40 sec at 1300 ppm CO₂ to tomato leaves which had beengiven L-serine, an increase in the accumulation of ¹⁴C-serinebegan after 20 sec, and the ¹⁴C-serine molecules formed at 20and 40 sec were labeled uniformly. In the presence of exogenousserine during 10-min photosynthesis in 1300 ppm CO₂, isonicotinicacid hydrazide increased the incorporation of ¹⁴CO₂ into glycinewith a corresponding decrease in the accumulation of ¹⁴C-serine,but it did not inhibit serine accumulation completely; an evidencefor that some serine was formed by a pathway other than theglycolate pathway. The effect of the CO₂ concentration on theglycolate pathway is discussed in terms of serine synthesisin the presence of exogenous serine. (Received June 1, 1981; Accepted September 30, 1981)     

Biosynthetic mechanism of glycolate in Chromatium IV. Glycolate-glycine transformation

The metabolic transformation of glycolate to glycine occurringin photosynthesizing cells of Chromatium was investigated bythe radioisotopic technique and by amino acid analysis. By analyzingthe distribution of radiocarbon upon feeding [1-¹⁴C] glycolate,[2-¹⁴C] glyoxylate and [1-¹⁴C] glycine to bacterial cells, itwas demonstrated that glycolate is converted to glycinc viaglyoxylate, and both glycolate and glycine are excreted extracellularly.Although the formation of serine was barely detected by theabove two techniques in both N₂ and O₂ atmospheres, it was foundthat ¹⁴CO₂ is evolved quite markedly from both [1-¹⁴C] glycolateand [1-¹⁴C] glycine fed to the Chromatium cells. Analyticalresults of transient changes in amino acid compositions underatmospheric changes of N₂O₂ and by the addition of exogenousglycolate in N₂ confirm the notion that glycolate is convertedto glycine. Acidic amino acids (glutamic acid and aspartic acid)appear to take part in glycine formation as amino donors. Theformation of glycine from glycolate in a N₂ atmosphere suggeststhat an unknown glycolate dehydrogenation reaction may operatein the overall process. ¹ This is paper XXXVII in the series ‘Structure and Functionof Chloroplast Proteins’. Paper XXXVI is ref. (5). Theresearch was supported in part by grants from the Ministry ofEducation of Japan (No. 111912), the Toray Science Foundation(Tokyo) and the Naito Science Foundation (Tokyo). (Received July 14, 1976; )     

Amino Acid-Sugar Linkages in Rice Coleoptile Cell Walls

The nature of amino acid-sugar linkages in cell walls was investigatedin a monocotyledonous tissue, rice coleoptiles. The molar ratiosof aspartic acid, threonine, and serine in cell walls were decreasedby hydrazinolysis in coleoptiles grown both on and under water.The molar ratios of threonine and serine were decreased alsoby a NaOHNaBH₄ treatment, while the alanine content was increased,and -aminobutyric acid was not formed. The cell walls were treated with NaOH in the presence of NaB³H₄,hydrolyzed, then divided into amino acid and sugar fractions.Two distinct radioactive peaks were detected in the thin-layerchromatography of the amino acid fractions. One was identifiedas alanine derived from glycosylated serine; the other was confirmedto be an oxidation product of glucosaminitol. There was justone ³H-labeled product in the sugar fractions, galactitol. Theseresults suggest the presence of serine-O-galactose and asparagine-N-N-acetylglucosamine linkages in rice coleoptile cell walls. The existence of glucosamine linked to amino acids was furthersupported by the incorporation of ¹⁴C-glucosamine into cellwalls. These linkages were also detected in the cell walls ofa dicotyledonous tissue, Vicia epicotyls. (Received April 2, 1981; Accepted June 24, 1981)     

Effects of Water Stress on the Respiratory and Nitrogen-fixing Activity of Soybean Root Nodules

Seventy-five per cent of the N₂-fixing activity (measured asthe reduction of C₂H₂ to C₂H₄) and 50 per cent of the respiratoryactivity of detached soybean root nodules was lost when thewater potential () of the nodules was lowered from approximately–1 ? 105 Pa (turgid nodules) to –9 ? 105 Pa (moderatelystressed nodules). Severely stressed nodules ( = –1.8? 10⁶ Pa) showed almost total loss of N₂-fixing activity andup to 80 per cent loss of respiratory activity. Increasing theoxygen partial pressure (PO₂) from 10⁴ to 10⁵ Pa completelyrestored both N₂-fixation and respiration in moderately stressednodules, but only partial recovery was possible in severelystressed nodules. The activity of the stressed nodules was verylow at low PO₂ (5 ? 10³ and 10⁴ Pa). The C₂H₂-reducing activityof nodule slices, nodule breis, and bacteroids from turgid andmoderately stressed nodules was almost identical but some activitywas lost in the breis and bacteroids from severely stressednodules. Calculations showed that at low PO₂ (10⁴ and 2 ? 10⁴Pa), the rate of O₂ diffusion into severely stressed noduleswas ten times lower than that for turgid nodules, but only fourtimes lower at a higher PO₂ (4 ? 10⁴ Pa). Carbon monoxide inhibitionof C₂H₂ reduction was slower in stressed nodules than in turgidnodules. The results are discussed in view of the possible developmentof a physical barrier to gaseous diffusion and/or the possiblealtered affinity of the nodule leghaemoglobin for O₂ in thewater-stressed nodules.     

Effects of Carbon Dioxide on Metabolism by the Glycollate Pathway in Leaves

When solutions of [¹⁴C]glycollate, glycine, serine, glycerate,or glucose were supplied to segments of wheat leaves throughtheir cut bases in the light, most of the ¹⁴C was incorporatedinto sucrose in air but in CO₂-free air less sucrose was made.The synthesis of sucrose was decreased because metabolism ofserine was partly blocked. Sucrose synthesis from glucose andglycerate in CO₂-free air was decreased but to a smaller extent;relatively more CO₂ was evolved and serine accumulated. Theeffects of DCMU and light of different wavelengths on metabolismby leaves of L-[U-¹⁴C]serine confirmed that simultaneous photosyntheticassimilation of carbon was necessary for the conversion of serineto sucrose. Of various products of photosynthesis fed exogenouslyto the leaves -keto acids were the most effective in promotingphotosynthesis of sucrose and release of ¹⁴CO₂ from ¹⁴C-labelledserine. This suggests that in CO₂-free air the metabolism ofserine may be limited by a shortage of -keto acid acceptorsfor the amino group. In CO₂-free air added glucose stimulatedproduction of CO₂ and sucrose from D-[U-¹⁴C]- glycerate andno competitive effects were evident even though glucose is convertedrapidly to sucrose under these conditions. In addition to asupply of keto acid, photosynthesis may also provide substratesthat can be degraded and provide energy in the cytoplasm forthe conversion of glycerate to sugar and phosphates and sucrose.     

Biochemical properties of 1-aminocyclopropane-1-carboxylate N-malonyltransferase activity from early growing embryonic axes of chick-pea (Cicer arietinum L.) seeds

In the present work, certain biochemical characteristics ofthe enzyme 1-aminocyclopropane-1-carboxylate N-malonyltransferase(ACC N-MTase) which is responsible for the malonylation of 1-aminocyclopropane-1-carboxylate(ACC) in chickpea (Cicer arietinum) are described. Phosphatebuffer was the most appropriate buffer with regard to enzymestability and, therefore, ACC N-MTase was extracted, assayedand purified in the presence of this buffer. ACC N-MTase waspartially purified approximately 900-fold from embryonic axesof chick-pea seeds using ammonium sulphate precipitation, hydrophobicinteraction and molecular filtration chromatography. By gelfiltration chromatography on Superose-12, the molecular massof the enzyme was estimated to be 54 4 kDa. ACC N-MTase hadan optimal pH and temperature of 7.5 and 40C, respectively,as well as a K_m for ACC and malonyl-CoA of 400 M and 90 M,respectively. D-Phenylalanine was a competitive inhibitor ofACC N-MTase with respect to ACC (K_i of 720 M), whereas co-enzymeA was a competitive product inhibitor with respect to malonyl-CoA(K_i of 300 M) and a non-competitive inhibitor with respectto ACC (K_i of 600 M). Under optimal assay conditions, ACC N-MTasewas strongly inhibited by (a)divalent [Zn²⁺>Mg²⁺>>Co²⁺>Co²⁺>(NH₄)²⁺>Fe²⁺]and monovalent metal cations (Li⁺>Na⁺>K⁺), without activitybeing detected in the presence of Hg²⁺, and (b) PCMB or mersalicacid, suggesting that sulphydryl group(s) are involved at theactive site of the enzyme. Key words: ACC-N-malonyltransferase, Cicer arietinum, embryonic axes, ethylene, germination, seeds     

Photosynthesis, Respiration, and Carbon Assimilation in Water-Stressed Maize at Two Oxygen Concentrations

Photosynthesis decreased with decreasing leaf water potentialas a consequence of stomatal closure and possibly non-stimataleffects of severe stress. Assimilation ceased at c. 16x 10⁵Pa. Photo-respiration, in 21% O₂, was small in relation to assimilationin unstressed leaves and decreased as leaf water potential fellbut it was much larger in proportion to photosynthesis at severestress. Decreasing the O₂ content to 1.5% increased photosynthesisslightly and decreased photo-respiration but did not changethe stress at which assimilation stoped. Dark respiration wasinsensitive to both O₂ and stress. Less ¹⁴C accumulated in stressedleaves but in 21% O₂ a greater proportion of it was in aminoacids, particularly glycine and serine. 1.5% O₂ decreased the¹⁴C in glycine to 10% and in serine to 50% of their levels in21% O₂. In both O₂ concentrations the proportion of ¹⁴C in serineincreased only at the most severe stress. Gas exchange measurementsand changes in the ¹⁴C flux to glycine are interpreted as theresult of glycolate pathway metabolism increasing as a proportionof assimilation in stressed leaves in high O₂. The small absoluterate of photorespiration in high O₂ and at low leaf water potentialmay be due to slow rates of glycine decarbodylation as wellas efficient fixation of any CO₂ produced. Serine is synthesizedby an O₂-sensitive pathway and an O₂-insensitive pathway, whichis most active at severe stress. Synthesis of alanine competeswith that of glycine and serine for a common precursor suppliedby the photo-synthetic carbon reduction cycle. The relativespecific radioactivities of aspartate and alanine suggest thatthey are derived from a common precursor pool, probably pyruvatefrom 3-PGA. The amounts of 3-PGA, aspartate, malate, alanine,and sucrose decreased with increasing water stress as a consequenceof slower assimilation and pool filling. Other amino acids,glycine, serine, glutamate, and proline, accumulated at lowwater potential possibly due to increased synthesis and slowerrates of consumption. Changes in pool sizes, carbon fludes,and specific activities of metabolites are related to the mechanismof C₄ photosynthesis and current concepts of glycolate pathwaymetabolism.     

The Flux of 14C-Labelled Photosynthate through Soyabean Root Nodules during N2 Fixation

Experiments are described which examine the flux of photosyntheticassimilates from leaves to nodules of soyabean during N₂ fixation.The first part, where the respiratory efflux of ¹⁴CO₂ by noduleswas used as a means of assessing the import of labelled photosynthatefrom leaves, shows that most ¹⁴CO₂ loss from nodulated rootsis due to the metabolic activity of nodules. Much less photosynthatewas imported by nodules if the metabolic activity associatedwith N₂ fixation was inhibited by low O₂ concentration. The second part describes the chemical fate of current photosynthateas it is utilized by nodules. Labelled material was detectedin nodules within c.15 min of supplying ¹⁴CO₂ to the leaf. Thisrose to a maximum at c.70 min before declining by 85% withinthe following 4 h. Most (80%) ¹⁴carbon imported by nodules waseither lost as respiratory ¹⁴CO₂ or re-exported as productsof N₂ fixation. Ten per cent of imported carbon was found asstructural material and 10% as starch. Of the ¹⁴C soluble in ethanol, most was found in the neutralfraction (80% declining to 50% as sucrose) with smaller amountsas amino acids, organic acids (each category rising from 10%to 20%) and phosphate esters (<5%). Comparison of the distribution of ¹⁴C among amino acids, amidesand ureides in the nodules with that of xylem exudates indicatedthat selected compounds were exported from nodules. The ¹⁴Cdata indicate that c.80% of the nitrogen exported from noduleswas in the form of ureides (mainly allantoic acid) and only10–12% as amides. Key words: Nodules, ¹⁴C-photosynthate, Respiration, Carbon flux     

Tritium labelling of amino sugars at C-2 by alkaline epimerization in tritiated water

N-Acetyl-D-[2-³H]glucosamine was synthesized from N-acetyl-D-mannosamineby alkaline 2-epimerization in pyridine containing ³H₂O andnickelous acetate. The reaction involves reversible formationof an enol intermediate and therefore also resulted in incorporationof tritium into N-acetylmannosamine. After completed reaction,the two N-acetylhexosamines were separated from other radioactiveproducts and Morgan-Elson chromogens by chromatography on acolumn of Sephadex G-10, which was eluted with 10% ethanol,and were then separated from each other by chromatography onSephadex G-15 in 0·27 M sodium borate (pH 7·8).The location of the incorporated tritium was established bytreatment of the N-acetylhexosamines with borate under the conditionsof the Morgan-Elson reaction, which converts the sugars to Kuhn'schromogen I with concomitant loss of the C-2 hydrogen. As expected,this treatment resulted in the formation of ³H₂O, indicatingthat the tritium was located at C-2. [2-³H]Glucosamine was preparedby acid hydrolysis of the labelled N-acetylglucosamine and wasconverted to [2-³H]glucosamine 6-phosphate by incubation withhexokinase and ATP. The sugar phosphate was used as a substratefor glucosamine 6-phosphate deaminase (isomerase, EC 5.3.1.10 [EC] )in a simple ³H₂O release assay. N-acetyl[2-³H]glucosamine N-acetyl[2-³H]mannosamine [2-³H]glucosamine glucosamine 6-phosphate deaminase [2-³H]mannosamine     

黔中地区不同植被类型土壤氧化亚氮的释放特征及影响因素

利用密闭箱-气相色谱法于2006—2007年对黔中地区退耕荒草地、灌丛、马尾松林和阔叶林土壤氧化亚氮的释放通量进行原位观测,初步研究了我国南方喀斯特地区不同植被类型土壤N₂O释放量的季节变化.结果表明:除个别月份土壤表现为大气N2O的吸收汇,各观测点均为N₂O的源,植被条件和土壤类型对土壤N₂O的释放具有明显影响.退耕荒草地、灌丛N₂O释放量具有明显的季节变化规律, 春夏季节高于秋冬季节,通量范围分别在-20.7～103.0 μg N·m^-2·h^-1和 -33.0～67.3 μg N·m^-2·h^-1.马尾松林、阔叶林春季土壤N₂O释放量最高,其他季节变化规律不明显,通量范围分别在-5.3～35.0 μg N·m^-2·h^-1和-14.4～152.8 μg N·m^-2·h^-1.相关性分析表明,土壤水分与N₂O释放通量显著负相关,是影响土壤N₂O释放通量季节变化的主要驱动因素.温度通过影响土壤水分而间接影响土壤N₂O的释放通量.     

PHOTOSYNTHESIS OF GLYCINE AND SERINE IN GREEN PLANTS

1. The effects of "carbonyl" reagents on the photosyntheticin-corporation of ¹⁴CO₂ into the assimilation products of tobaccoand spinach leaves were studied. The presence of "carbonyl"reagents causes an increase in the ratio of ¹⁴CO₂ incorporatedin glycine and a decrease in serine. The incorporation of ¹⁴Cfrom glycolate-1-¹⁴C and glycolaldehyde-2-¹⁴C into glycine andserine was also affected by "carbonyl" reagents, as in the caseof ¹⁴CO₂-experiment. 2. The feeding experiments of glycine-1-¹⁴C and serine-1-¹⁴Cin the presence and in the absence of "carbonyl" reagents revealedthat these reagents inhibit the conversion of glycine to serine. 3. The results obtained above, together with the effects ofthiols on ¹⁴CO₂ incorporation presented in this paper, supportthe assumption that glycine and serine are formed via glycolateand glyoxylate during photosynthesis in green plants. 4. Comparison of ¹⁴C incorporation in malate from ¹⁴CO₂, glycolate-1-¹⁴C,glycine-1-¹⁴C and serine-1-¹⁴C in the presence and in the absenceof "carbonyl" reagents suggested the occurrence of the pathwayof the malate formation via glycolate and glyoxylate, not passingthrough glycine and serine, during photosynthesis. ¹ A part of this paper was presented at the Symposium on "Nitrogenand Plant" by the Japanese Society of Plant Physiologists, inOctober, 1963 ² Present address: Radiation Center of Osaka Prefecture, Sakai,Osaka     

Symbiotic N2 fixation of Alnus incana ssp. rugosa in shrub wetlands of the Adirondack Mountains, New York, USA

Surface waters in forested watersheds in the Adirondack Mountains and northern New York State are susceptible to nitrogen (N) saturation. Atmospheric deposition of N to watersheds in this region has been measured but the extent of internal N inputs from symbiotic N₂ fixation in alder-dominated wetlands is not known. We estimated N₂ fixation by speckled alder in these wetlands by the ¹⁵N natural abundance method and by acetylene reduction using a flow-through system. Foliar N derived from fixation (%N_dfa) was estimated for five wetlands. The '¹⁵N of speckled alder foliage from four of the five sites did not differ significantly (PА.05) from that of nodulated speckled alders grown in N-free water culture (-1.2ǂ.1‰). Estimates from the ¹⁵N natural abundance method indicated that alders at these sites derive 85-100% of their foliar N from N₂ fixation. At one of the sites, we also measured biomass and N content and estimated that the alder foliage contained 43 kg N ha^-1 of fixed N in 1997. This estimate was based on a foliar N content of 55.4lj kg N ha^-1 (mean-SE), 86dž%N_dfa, and an assumption that 10% of foliar N was derived from reserves in woody tissues. At this site, we further estimated via acetylene reduction that 37ᆞ kg N ha^-1 was fixed by speckled alders in 1998. This estimate used the theoretical 4:1 C₂H₂ reduction to N₂ fixation ratio and assumed no night-time fixation late in the season. Nitrogen inputs in wet and dry deposition at this site are approximately 8 kg N ha^-1 year^-1. We conclude that speckled alder in wetlands of northern New York State relies heavily on N₂ fixation to meet N demands, and symbiotic N₂ fixation in speckled alders adds substantial amounts of N to alder-dominated wetlands in the Adirondack Mountains. These additions may be important for watershed N budgets, where alder-dominated wetlands occupy a large proportion of watershed area.     

Can the 15N Dilution Technique be used to Study N2 Fixation in Tropical Tree Symbioses as Affected by Water Deficit?

Three methods were used to study N₂ fixation and effects ofwater deficit on N₂ fixation: C₂H₂ reduction assay (ARA), ¹⁵Ndilution technique and accumulated N content. In addition, ¹⁵Ndilution was calculated both in a traditional way and in a modifiedway, which takes into consideration N and ¹⁵N content for theplants before the experiment started. The three methods wereapplied on the following Rhizobium-symbioses: Acacia albidaDel (Faidherbia albida (Del) A. Chev.) and Leucaena leucocephala(Lam) de Wit., and the Frankia-symbiosis Casuarina equisetifoliaL. The plants wereabout 4-months-old when they were harvested. Nitrogen derived from N₂ fixation in control plants of Acaciaalbida was 54·2 mg as measured with ARA, while it was28·5 mg as measured with the ¹⁵N dilution technique,compared to 30·7 mg calculated as accumulated N. In comparison,L. leucocephala fixed 41·6 mg N (ARA), 53·5 mgN(15N dilution technique) and 56·3 mg N (accumulatedN). The Frankia-symbiosis had fixed 27·4 mg N as measuredby ARA, 8·1 mg N as measured by ¹⁵N dilution techniqueand 12·3 mg N as accumulated N. There were no differencesbetween the estimates based ontraditional and modified waysof calculating ¹⁵N dilution. The immediate effect of water deficit treatment on N₂ fixationwas continuously measured inall species with ARA, which startedto decrease approximately 10 d after the initiation of the treatment,and declined to less than 5% of the initial level after 21–28d. The decrease in the amount of N derived from N₂ fixation wasstudied in L. leucocephala during the period of treatment. Therewas a 26% decrease in amount of N derived from N₂ fixation asresult of water deficit (as measured with ARA), while the decreasewas 23% when measured withboth the ¹⁵N dilution method and asaccumulated N. The three different methods for measuring N₂ fixation and effectsof water deficit on N₂ fixation are discussed. Key words: Acacia albida, ARA, Casuarina equisetifolia, Leucaena leucocephala, ¹⁵N dilution, N₂N fixation, water deficit     

Proton Translocation Associated with Denitrification in a Photodenitrifier, Rhodopseudomonas sphaeroides forma sp. denitrificans

H⁺ translocation driven by NO₃^–, NO₂^– and N₂O reductionswith endogenous substrates in cells of Rhodopseudomonas sphaeroidesforma sp. denitrificans was investigated by the oxidant pulsemethod. Upon injection of nitrogenous oxides to anaerobic cellsin darkness, an alkaline transient in the external medium wasobserved, followed by acidification. The alkaline transientwas enhanced by carbonyl cyanide m-chlorophenylhydrazone. When a viologen dye was used as an electron donor in the presenceof 1 mM Af-ethylmaleimide and 0.1 mM 2-n-heptyl-4-hydroxyquinoline-N-oxideto preclude respiration-linked H⁺ extrusion, addition of KNO₃,KNO₂ and N₂O caused only a rapid alkalinization. The H⁺ consumptionstoichiometries, H⁺/2e^– ratios for NO₃^– reductionto NO₂^–, NO₂^– reduction to 1/2 N₂O and N₂O reductionto N₂ were –1.90, –3.18 and –2.04, respectively.These values agreed well with the fact that all reductions ofnitrogenous oxides in denitrification occur on the periplasmicside of the cytoplasmic membrane. When corrected for H⁺ consumption in the periplasm, the H⁺ extrusionstoichiometries, H⁺/2e^– ratios with endogenous substratesin the presence of K⁺/valinomycin for NO₃^– reduction toNO₂^–, NO₂^– reduction to 1/2 N₂O and N₂O reductionto N₂ were 4.05, 4.95 and 6.01, respectively. (Received August 4, 1982; Accepted January 13, 1983)     

Photosynthetic Oxygen Production Facilitates Translocation of 11C-Labelled Photoassimilates from Tendrils and Leaflets of Pisum sativum L

The translocation profiles of ¹¹C-photoassimilates from eithertendrils or leaflets of the compound leaf of Pisum sativum weresimilar in shape, speed and susceptibility to blockage by chillingand heat girdling. When the feed leaf component was exposedto an anaerobic gas stream consisting of N₂ gas supplementedwith 40 Pa CO₂, the export of previously-fixed ¹¹C-photoassimilatesfrom both leaflets and tendrils continued in the light, butstopped in the dark. However, in the light, translocation of¹¹C-assimilates from the leaflet was rapidly blocked by a flowof pure N₂ (i.e. anoxia). Movement of ¹¹C-assimilates from theleaf of another C₃ plant, sunflower, was similar to that fromthe pea leaflet. In contrast to both laminar leaf components,export from the tendrils was stopped under pure N₂ only in thedark. Taken together the data suggest that photosynthetic O₂production facilitated the movement of ¹¹C-assimilates in theabsence of exogenous O₂. The differences observed between thetendrils and the leaflets exposed to pure N₂ could be attributedto the greater capacity of tendrils to produce and recycle CO₂to support photosynthetic O₂ production in the light. Key words: Pea, ¹¹C-translocation, anoxia, tendril, leaflet     

Photosynthetic Assimilation of 14CO2 by Waterstressed Sunflower Leaves at Two O2 Concentrations and the Specific Activity of Products

Attached leaves of sunflower (Helianthus annuus L. var. Mennonite)with water potentials of –5 to –18 ? 10⁵ Pa, wereexposed for different times to 300 vpm CO₂ containing ¹⁴CO₂and 21 or 1.5% O₂. ¹⁴C accumulated linearly with time in bothO₂ concentrations and at all stresses. 3-Phosphoglyceric acidwas saturated with ¹⁴C after 10 min in unstressed plants atboth O₂ concentrations but with increasing stress the rate ofaccumulation and the specific activity decreased. With decreasingleaf water potential there was accumulation of radioactivityin the glycolate pathway intermediates glycine and serine. Otheramino acids contained a slightly larger proportion of assimilatedcarbon as water potential decreased. The specific activitiesof all compounds were smaller with stress. In contrast to theamino acids less radioactivity accumulated in sugars, organicacids, and sugar phosphates and their specific activities decreasedwith stress. The radioactive labelling patterns and specificactivity measurements are interpreted as showing increased carbonflux in the glycolate pathway and inhibition of the metabolismof serine to sucrose. These changes are related to previousresults showing that with stress photo respiration increasesas a proportion of photosynthesis. Lowering the O₂ concentrationto 1.5% decreased the accumulation of radioactivity in glycineand stopped photorespiration. It increased the amount of radioactivityin serine and sucrose but did not greatly change specific activities.Oxygen effects were independent of water stress. Glycolate pathwaymetabolism is discussed in relation to photorespiration andthe effects of water stress.     

Diffusion of Oxyleghaemoglobin

The diffusion of oxyleghaemoglobin, prepared from soybean rootnodules, was measured at 24°C in agar and agarose gels ofvarious strengths, or in 1% agarose containing 0-18% (w/v) bovineserum albumin, to simulate the protein content of the cytoplasmof root nodule cells. Values of D_p, the diffusion coefficient,were unaffected (D_p = 11·8 x 10^-11 m² s^-1; s.e.m. 0·3x 10^-11) until the protein concentration exceeded 6%, abovewhich D_p declined sharply. With 18% bovine serum albumin, theconcentration of total soluble protein calculated to be presentin the cytoplasm of infected cells, where most of the leghaemoglobinis located in vivo, D_p was 5·9 x 10^-11 m² s^-1. Theseresults are discussed in relation to leghaemoglobin-facilitateddelivery of O₂ to the respiring N₂-fixing bacteroids in rootnodule cells.Copyright 1993, 1999 Academic Press Bacteroids, diffusion, Glycine max, N₂ fixation, oxyleghaemoglobin, soybean, root nodules     

Activity of Gibberellins A1 to A0 in the Avena First-leaf Bioassay, and Location after Chromatography

Activity curves are determined for gibberellins A₁ to A₀ bythe Avena first-leaf bioassay method. Gibberellins A¹, A₄ andA₅ can be detected at 10^-11 or 10^-10 g/ml and give optimum activityof approximately 230 per cent elongation (water controls = 100per cent). Gibberellins A²A³, and A⁹ can be detected at 10^-3g/mland give optimum activity of approximately 200 per cent. GibberellinsA₆ and A₇ can be detected at 10^-5g/ml; GA₇ gives optimum activityof around 190 per cent. All the gibberellins except GA₈ canbe detected by this bioassay method after chromatography inn-butanol: 1.5 N ammonia (3: 1) and benzene: acetic acid: water(4: 2: 1) when applied to the paper at concentrations from O.Ito µg. The sensitivity of the method is compared withthat of other gibberellin bioassay methods.     

The Biological Properties of Cyclopenin and Cyclopenol

Cyclopenin (C₁₇H₁₄O₃N₂) and cyclopenol (C₁₇H₁₄O₄N₂), isolatedfrom an abberent strain of Penicillium cyclopium (NRRL 6233),significantly inhibited the growth of etiolated wheat (Triticumaestivum) coleoptile segments. The former inhibited at 10^–3and 10^–4 M, the latter at 10^–3 M. Cyclopenin producedmalformation of the first set of trifoliate leaves in bean (Phaseolusvulgaris) at 10^–2 M and necrosis and stunting in corn(Zea mays) at 10^–2 M. Cyclopenol induced no apparent effectsin bean or corn plants. Neither compound changed the growthor morphology of tobacco (Nicotiana tabacum) plants. Cyclopenininduced intoxication, prostration and ataxia in day-old chicksat 500 mg/kg, but they recovered within 18 hours. Cyclopenolwas inactive against chicks when dosed at levels up to 500 mg/kg. (Received October 11, 1983; Accepted December 15, 1983)