Photosynthate metabolism in the source leaves of n(2)-fixing soybean plants

Soybean plants (Glycine max [L.] Merr. cv Williams), which were symbiotic with Bradyrhizobium japonicum, and which grew well upon reduced nitrogen supplied solely through N₂ fixation processes, often exhibited excess accumulation of starch and sucrose and diminished soluble protein in their source leaves. Nitrate and ammonia, when supplied to the nodulated roots of N₂-fixing plants, mediated a reduction of foliar starch accumulation and a corresponding increase in soluble protein in the source leaves. This provided an opportunity to examine the potential metabolic adjustments by which NO₃⁻ and NH₄⁺ (N) sufficiency or deficiency exerted an influence upon soybean leaf starch synthesis. When compared with soybean plants supplied with N, elevated starch accumulation was focused in leaf palisade parenchyma tissue of N₂-fixing plants. Foliar activities of starch synthesis pathway enzymes including fructose-1,6-bisphosphate phosphatase, phosphohexoisomerase, phosphoglucomutase (PGM), as well as adenosine diphosphate glucose pyrophosphorylase (in some leaves) exhibited highest activities in leaf extracts of N₂-fixing plants when expressed on a leaf protein basis. This was interpreted to mean that there was an adaptation of these enzyme activities in the leaves of N₂-fixing plants, and this contributed to an increase in starch accumulation. Another major causal factor associated with increased starch accumulation was the elevation in foliar levels of fructose-6-phosphate, glucose-6-phosphate, and glucose-1-phosphate (G1P), which had risen to chloroplast concentrations considerably in excess of the K_m values for their respective target enzymes associated with starch synthesis, e.g. elevated G1P with respect to adenosine diphosphate glucose pyrophosphorylase (ADPG-PPiase) binding sites. The cofactor glucose-1,6-bisphosphate (G1,6BP) was found to be obligate for maximal PGM activity in soybean leaf extracts of N₂-fixing as well as N-supplemented plants, and G1,6BP levels in N₂-fixing plant leaves was twice that of levels in N-supplied treatments. However the concentration of chloroplastic G1,6BP in illuminated leaves was computed to be saturating with respect to PGM in both N₂-fixing and N-supplemented plants. This suggested that the higher level of this cofactor in N₂-fixing plant leaves did not confer any higher PGM activation and was not a factor in higher starch synthesis rates. Relative to plants supplied with NO₃⁻ and NH₄⁺, the source leaf glycerate-3-phosphate (3-PGA) and orthophosphate (Pi) concentrations in leaves of N₂-fixing plants were two to four times higher. Although Pi is a physiological competitive inhibitor of leaf chloroplast ADPG-PPiase, and hence, starch synthesis, elevated chloroplast 3-PGA levels in N₂-fixing plant leaves apparently prevented interference of Pi with ADPG-PPiase catalysis and starch synthesis.     

A new alkaloid from south african Conium species

Recent screening of South African Conium species for alkaloids as part of taxonomic studies has yielded γ-coniceine, coniine, methylconiine, conhydrine and a new alkaloid N-methylpseudoconhydrine. The relative stereochemistry of N-methylpseudoconhydrine was ascertained by ¹H NMR decoupling experiments. This latter alkaloid was found in significant amounts in the leaf and stem of some plants investigated and was the major alkaloid along with conhydrine in the leaf and stem of one group of high altitude plants. These plants also contained significant amounts of volatile oil, the major monoterpene being myrcene.     

Epoxidation in vivo of hyoscyamine to scopolamine does not involve a dehydration step

Hyoscyamine is epoxidized to scopolamine via 6β-hydroxyhyoscyamine in several solanaceous plants. 6,7-Dehydrohyoscyamine has been proposed to be an intermediate in the conversion of 6β-hydroxyhyoscyamine to scopolamine on the basis of the observation that this unsaturated alkaloid is converted to scopolamine when fed to a Datura scion. To determine whether a dehydration step is involved in scopolamine biosynthesis, [6-¹⁸O]6β-hydroxyhyoscyamine was prepared from l-hyoscyamine and ¹⁸O₂ using hyoscyamine 6β-hydroxylase obtained from root cultures of Hyoscyamus niger L. When [6-¹⁸O]6β-hydroxyhyoscyamine was fed to shoot cultures of Duboisia myoporoides R. B_R., the labeled alkaloid was converted to scopolamine which retained ¹⁸O in the epoxide oxygen. It is concluded that 6β-hydroxyhyoscyamine is converted in vivo to scopolamine without a dehydration step.     

Radioimmunoassay for the determination of digoxin and related compounds in Digitalis lanata

A radioimmunoassay technique has been developed for the measurement of digoxigenin glycosides in crude extracts from both fresh and dried leaf material of Digitalis lanata, The antibody, obtained by immunizing rabbits against a conjugate of digoxin with human serum albumin, had a high affinity (K_a = 0.8 × 10¹⁰ l/mol) for digoxin and permitted detection of as little as 60 fmol digoxin (45 pg) per 0.1 ml of sample. The antiserum was highly specific for digoxigenin and its glycosides, with only diginatin showing a substantial cross reactivity (3?0%). The use of [³H]-labelled and [¹²⁵I]-labelled digoxin as tracer and of dextran-coated charcoal or ammonium sulfate for separation did not change the specificity of the assay nor the properties of the standard curve. This method has been found to correlate with the usual fluorimetric determination of digoxin, but is more sensitive by a factor of 10⁴. A correlation analysis of 8 and 30 different D. lanata plants (leaf discs and drugs analysed with both methods) gave correlation coefficients of r = 0.989 and r = 0.907 respectively. The analysis of a single leaf disc, 3 mm in diameter (obtained from a fresh leaf), gave an exact measure of the digoxin content found in the dried leaf drug (r = 0.973). With a semi-automated technique, about 2000 quantitative analyses per week can be performed by one person, thus providing the potential to screen plants for use in breeding or tissue culture work. The distribution of digoxigenin equivalents in single seeds, seedlings and plants of different ages has also been investigated.     

Biosynthesis of tropic acid: Feeding experiments with cinnamoyltropine and littorine

The administration of cinnamoyl-[2-¹⁴C]-tropine-[N-methyl-¹⁴C] to Datura stramonium plants resulted in the formation of labeled atropine and scopolamine. However the atropine was found to have almost all its radioactivity located on the N-methyl group of the alkaloid, indicating that the administered ester had undergone hydrolysis in the plant affording tropine and cinnamic acid, the latter not being utilized for the biosynthesis of tropic acid. Dual labeled RS-littorine (3β-(2-hydroxy-3-phenylpropionyloxy-[1-¹⁴C]-tropane-[3β-³H]) was also fed to D. stramonium and radioactive atropine was obtained. However the drastic change in the ³H:¹⁴C ratio found in the atropine indicated that the littorine was not converted directly to the alkaloid, and it is suggested that the littorine is hydrolysed _{in vivo} to tropine and phenyl-lactic acid, the latter undergoing rearrangement to tropic acid prior to esterification with tropine.     

Production of tropane alkaloids in diploid and tetraploid plants and in vitro hairy root cultures of Egyptian henbane (Hyoscyamus muticus L.)

In this study, the effects of ploidy level and culture medium were studied on the production of tropane alkaloids. We have successfully produced stable tetraploid hairy root lines of Hyoscyamus muticus and their ploidy stability was confirmed 30?months after transformation. Tetraploidy affected the growth rate and alkaloid accumulation in plants and transformed root cultures of Egyptian henbane. Although tetraploid plants could produce 200% higher scopolamine than their diploid counterparts, this result was not observed for corresponding induced hairy root cultures. Culture conditions did not only play an important role for biomass production, but also significantly affected tropane alkaloid accumulation in hairy root cultures. In spite of its lower biomass production, tetraploid clone could produce more scopolamine than the diploid counterpart under similar growth conditions. The highest yields of scopolamine (13.87?mg?l^?1) and hyoscyamine (107.7?mg 1^?1) were obtained when diploid clones were grown on medium consisting of either Murashige and Skoog with 60?g/l sucrose or Gamborg??s B5 with 40?g/l sucrose, respectively. Although the hyoscyamine is the main alkaloid in the H. muticus plants, manipulation of ploidy level and culture conditions successfully changed the scopolamine/hyoscyamine ratio towards scopolamine. The fact that hyoscyamine is converted to scopolamine is very important due to the higher market value of scopolamine.     

Carbonic anhydrase activity in leaves and its role in the first step of c(4) photosynthesis

In C₄ plants carbonic anhydrase catalyzes the critical first step of C₄ photosynthesis, the hydration of CO₂ to bicarbonate. The maximum activity of this enzyme in C₄ leaf extracts, measured by H⁺ production with saturating CO₂ and extrapolated to 25°C, was found to be 3,000 to 10,000 times the maximum photosynthesis rate for these leaves. Similar activities were found in C₃ leaf extracts. However, the calculated effective activity of this enzyme at in vivo CO₂ concentrations was apparently just sufficient to prevent the rate of conversion of CO₂ to HCO₃⁻ from limiting C₄ photosynthesis. This conclusion was supported by the mass spectrometric determination of leaf carbonic anhydrase activities.     

Rapid micropropagation system in vitro and antioxidant activity of Scabiosa tschiliensis Grunning

A rapid micropropagation system for Scabiosa tschiliensis Grunning, an ethnic medicinal plant, has been developed. Calluses were induced from leaf and petiole explants on Murashige and Skoog (MS) medium supplemented with 2.0 mg l^?1 thidiazuron and 0.5 mg l^?1 2,4-dicholorophenoxyacetic acid. In this medium, callus induction rate was about 94.05 %. Adventitious shoots developed from leaf (86.30 %) and petiole (83.33 %) calluses when cultured on MS medium containing 4.0 or 2.0 mg l^?1 N⁶-benzyladenine (BA), respectively. Up to 73.85 % of the regenerated shoots formed complete plantlets on MS medium supplemented with 2.0 mg l^?1 indole-3-butyric acid, with an average of 3.25 roots per shoot. Quantitative analysis of flavonoids showed that the phytochemical profiles of calluses and regenerated plants were similar to that of wild-type plants. The 2, 2-diphenyl-1-picrylhydrazyl assay revealed that the flavonoid extracts of calluses, adventitious shoots and wild-type plants had stronger antioxidant activities, the inhibitory concentrations being 23.944, 31.329 and 26.502 μg ml^?1, respectively, where 50 % of DPPH was scavenged (IC₅₀). Results showed that this perennial herb could be used as a potential source of new natural antioxidants.     

Evidence for Cytokinin Involvement in Rhizobium (IC3342)-Induced Leaf Curl Syndrome of Pigeonpea (Cajanus cajan Millsp.)

A uniquely abnormal shoot development (shoot tip-bending, leaf curling, release from apical dominance, and stunted growth) in pigeonpea (Cajanus cajan Millsp) induced by a nodulating Rhizobium strain, IC3342, is thought to be due to a hormonal imbalance. Amaranthus betacyanin bioassay indicated that xylem exudate and leaf extracts from pigeonpea plants with Rhizobium-induced leaf curl symptoms contained high concentrations of cytokinin relative to those in normal plants. Radioimmunoassay (RIA) of samples purified with high performance liquid chromatography revealed that zeatin riboside (ZR) and dihydrozeatin riboside (DZR) concentrations in xylem sap from plants with leaf curl symptoms were 7 to 9 times higher than those in the sap from symptomless, nodulated plants. The sap from symptomless plants nodulated by a Curl⁻ mutant had ZR and DZR concentrations comparable to those in the normal plant sap. RIA indicated that the respective concentrations of zeatin and N⁶-isopenteny-ladenine in culture filtrates of the curl-inducing strain IC3342 were 26 and 8 times higher than those in filtrates of a related normal nodulating strain (ANU240). Gas chromatographic-mass spectrometric analyses revealed similar differences. Gene-specific hybridization and sequence comparisons failed to detect any homology of IC3342 DNA to Agrobacterium tumefaciens or Pseudomonas savastanoi genetic loci encoding enzymes involved in cytokinin biosynthesis.     

Analysis of the Potential Use of Androgenic Datura innoxia for the Development of Cell Cultures Producing High Amounts of Tropane Alkaloids

Normal and androgenic diploid Datura innoxia plants were selfedand the progeny was analysed for its leaf alkaloid content.Since the androgenic lines had originally produced very differentamounts of the tropane alkaloids, scopolamine and hyoscyamine,we were interested in determining whether this trait is transmittedby self-fertilization. The alkaloid content of the progeny wasfound to correlate well with that of the parental plants. Also,calli were initiated from leaf discs derived from plants withdifferent capacities for alkaloid biosynthesis. These were furthersubcultured for 2 years. Again, the same correlations in hyoscyamineand scopolamine content were observed. This indicates that itis possible to initiate callus with a high alkaloid contentstarting from actively alkaloid-producing androgenic Daturainnoxia plants. Key words: Datura innoxia, tropane alkaloids, androgenic plants, callus culture     

Estimation of pyruvate,phosphate dikinase activity in maize leaf tissue by (phosphoenolpyruvate plus pyrophosphate)-dependent phosphorylation of AMP

Crude extracts of maize leaf tissue catalysed the phosphorylation of AMP by ³²PPi in the presence of phosphoenolpyruvate (PEP). The reaction was enhanced by F^? and NH₄⁺. The optimum concentrations of AMP, PEP and PPi were 0.3, 10 and 1 mM, respectively. Under these conditions, ca75% of the AMP phosphorylated by ³²PPi was present as ATP and ca25 % as ADP. The activity was reversibly cold labile. The specific activity of crude extracts in the presence of F^? was proportional to enzyme concentration only at protein concentrations < 25,μg/ml. Partially purified pyruvate, phosphate dikinase (PPD) from maize leaf quantitatively phosphorylated AMP to ATP in a (PEP plus PPi)-dependent reaction with the concomitant production of 0.9 mol of pyruvate per mol of AMP phosphorylated. It was concluded that (PEP plus PPi)-dependent phosphorylation of AMP provides a reliable method for estimating PPD activity in crude extracts of maize. Crude maize extracts also catalysed ³²Pi-ATP and ³²PPi-ATP exchange but these activities were not specific for PPD.     

Accumulation of Ergopeptide Alkaloids in Symbiotic Tall Fescue Grown under Deficits of Soil Water and Nitrogen Fertilizer

The fungus Acremonium coenophialum is endophytically associated with tall fescue (Festuca arundinacea Schreber). Within this symbiotum the fungus produces ergopeptide alkaloids, which are associated with livestock toxicoses. Environmental effects on the production of ergot alkaloids within the symbiotum are unknown. We conducted a greenhouse study of the effects of flooding, nitrogen rate during fertilization (11, 73, and 220 mg of N per pot weekly), nitrogen form (3.4 and 34 mg of N as NH₄⁺ or NO₃^- per pot), and drought stress (-0.03, -0.05, and -0.50 MPa) on ergopeptide alkaloid concentrations in one genotype of nonsymbiotic and symbiotic tall fescue grown in plastic pots. It was determined that the concentration of ergovaline, the major type of ergopeptide alkaloid, was increased but was not as high as that in nonflooded controls. Total ergopeptide and ergovaline concentrations in plants receiving high (220 mg of N per pot) and low (11 mg of N per pot) levels of NH₄NO₃ fertilization were not affected by flooding. The form of nitrogen was important since all concentrations of NO₃^--N increased ergopeptide alkaloid content, as opposed to the effects of NH₄⁺-N, which was effective only at high concentrations (34 mg of N per pot). Ergopeptide concentrations were highest in drought-stressed plants grown at -0.50 MPa and fertilized at the moderate or high N rate. The results suggest that within this genotype, ergopeptide alkaloid biosynthesis by the fungus is not appreciably affected by flooding but is greatly increased by high rates of N fertilization and moderate water deficit.     

Demonstration of ATP-Dependent, Ubiquitin-Conjugating Activities in Higher Plants

Ubiquitin is a highly conserved, 76-amino acid polypeptide with several important regulatory functions in both plants and animals that all arise from its covalent ligation to other cellular proteins. Here, we demonstrate that higher plants have the capacity to conjugate ubiquitin to other plant proteins in vitro. Using ¹²⁵I-labeled human ubiquitin as a substrate, conjugating activities were observed in crude etiolated tissue extracts from all species tested, including oats, rye, barley, corn, zucchini squash, pea, soybean, and sunflower. The reaction has a soluble distribution, is specific for ATP, and requires the protease inhibitor, leupeptin, to protect ubiquitin from inactivation during the assay. Conjugation is inhibited by N-ethylmaleimide and high concentrations of 2-mercaptoethanol suggesting that the mechanism of ubiquitin ligation in plants involves a similar thiolester intermediate to that found in the mammalian pathway. The conjugating activity in etiolated oat extracts is extremely labile with a half-life of about 20 minutes at 30°C. Detectable but low ATP-stimulated, conjugating activities were also observed in extracts from dry seeds and green leaves of oats. In addition to this conjugating activity, crude plant extracts have the capacity to degrade ubiquitin-protein conjugates formed in vitro. These results demonstrate that higher plants contain several of the enzymic activities necessary for ubiquitin's functions and provide a method for assaying ubiquitin conjugation in vitro.     

Sulfur assimilation in c(4) plants: intercellular compartmentation of adenosine 5'-triphosphate sulfurylase in crabgrass leaves

The activity of adenosine 5′ triphosphate sulfurylase was determined in crabgrass mesophyll cells, bundle sheath strands, and whole leaf extracts. The enzyme was assayed by following molybdate-dependent pyrophosphate release from ATP, ³⁵SO₄²⁻ incorporation into adenosine 5′ phosphosulfate, and ATP synthesis dependent upon adenosine 5′ phosphosulfate and inorganic pyrophosphate. With all assays, greater than 90% of the activity was found in extracts from bundle sheath strands. The activities in whole leaf extracts were consistently intermediate between the activities of mesophyll and bundle sheath extracts and extract-mixing experiments gave no indication of enzyme activation or inhibition in vitro. Whole leaf activities were several hundred-fold less than concurrent measurements of ribulose 1,5-bisphosphate and phosphoenolpyruvate carboxylase activities, which is interpreted as being consistent with the relative amounts of elemental carbon and sulfur found in higher plants. A hypothesis is presented for the intercellular compartmentation of sulfur assimilation in relationship to NO₃⁻ and CO₂ assimilation in leaves of C₄ plants.     

Conjugation of ubiquitin to proteins from green plant tissues

Conjugation of the polypeptide ubiquitin to endogenous proteins was studied in oat (Avena sativa L.) plants, and particularly in green tissues. Conjugating activity in leaf extracts was different from that in root extracts, and in both was less than in etiolated tissue. The conjugates were identified by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE), and their formation was both time- and ATP-dependent and had a pH optimum of about 8.2. The assay had a high affinity for ATP with a probable K_m of less than 50 micromolar. The ubiquitin conjugating system was also shown to be present in isolated chloroplasts, and ubiquitin could be conjugated to endogenous proteins of lyzed chloroplasts in which the ATP concentrations were reduced by preincubation or desalting. SDS-PAGE analysis led to the suggestion that the large and small subunits of ribulose-1,5-bisphosphate carboxylase (RuBPCase) may be able to be ubiquitinated, and we have shown that ubiquitin can stimulate the in vitro breakdown of ¹²⁵I-labeled RuBPCase. These results invite the speculation that ubiquitin may be involved in the regulation of protein turnover in green plants.     

Biosynthesis of alpinigenine by way of tetrahydroprotoberberine and protopine intermediates

In the biosynthesis of the benzazepine alkaloid alpinigenine a N-methylation step followed by hydroxylation α to nitrogen has now been shown more conclusively to be involved in the transformation of a N-heterocyclic ring system. After feeding Papaver bracteatum plants both the precursors (±)-tetrahydropalmatine-[8,13,14-³H] and (±)-tetrahydropalmatine methiodide-[8,13,14-³H;8-⁴C] an identical mode of abstraction of tritium was observed including a complete loss of the isotope from C-14. The next member in the biogenetic chain, muramine-[8-¹⁴C], was incorporated into alpinigenine very efficiently. Furthermore, using structurally different precursors not utilized for normal alkaloid formation, e.g. 2′-hydroxymethyl-laudanosine-[¹⁴CH₂OH], 13-hydroxymuramine-[8-¹⁴C], the specificity of alkaloid metabolism was examined in the whole plant. Tracer dilution technique was applied to confirm the occurrence in the plant of three established intermediates. Chemical syntheses of four of the alkaloids used during these investigations were developed.     

An efficient method for organic acetylation and use of dl-phosphinothricin as a negative selection agent in argE transgenic rice

We present an efficient method for the production of N-acetyl-l-phosphinothricin (N-AcPt) from commercial dl-phosphinothricin (DL-PPT) by organic acetylation for use as a negative selection agent (NSA) that induces cell death in argE transgenic rice. DL-PPT was efficiently converted into N-AcPt with tetrahydrofuran (THF) and acetic anhydride (Ac₂O). Chemical changes were confirmed using NMR and ATR-FTIR analyses. DL-PPT was toxic but N-AcPt did not show cytotoxic effects on leaf discs or seed germination of wild-type rice. Conversely, in argE–hpt transgenic rice, non-toxic N-AcPt showed the negative selection (NS) effect by inducing cell destruction in leaf discs and restricting seed germination. For inducing NS, ?0.1 mg ml⁻¹ and ?0.5 mg ml⁻¹ of N-AcPt were effective in leaf and seed assays, respectively. Further, the NS effect occurred faster in the leaf assay compared with the seed germination assay, again indicating the leaf assay was a more sensitive indicator of N-AcPt as an NSA to argE transgenic rice than the seed germination assay. This negative selection approach could be useful for the development of selectable marker free transgenic plants in the economically important monocot species and its commercialization for multiple gene transformation.     

The Glycine-Glomus-Rhizobium Symbiosis : VII. Photosynthetic Nutrient-Use Efficiency in Nodulated, Mycorrhizal Soybeans

Four consecutive trifoliate leaves of 56-day-old symbiotic or nonsymbiotic soybean plants were evaluated individually for CO₂ exchange rates (CER), leaf area and dry weight, and leaf N, P, and starch concentrations. Plants had been inoculated with the vesicular-arbuscular mycorrhizal (VAM) fungus Glomus mosseae and Rhizobium japonicum, with either of the endophytes alone, or with neither at time of planting. Plants lacking one or both endophytes received N and/or P fertilizers to produce plants of equal total leaf dry weight in all four treatments. Photosynthetic P-use efficiency (CER per unit leaf P) was higher in the leaves of VAM plants than in P-fertilized plants regardless of the N source (N₂ fixation or combined N). Photosynthetic N-use efficiency was also higher in VAM than in non-VAM plants, but it was affected by the N source, with higher CER in the nodulated plants. The greatest differences in CER, starch accumulation and leaf area were found between the nonsymbiotic plants and those with both endophytes. Statistical evaluations of leaf parameters for treatment or nutrient concentration (N and P) effects between the tri-partite and the nonsymbiotic treatments showed significant changes in concentration of P, but not N, with decreasing leaf age. Both endophytes apparently enhance CO₂ fixation at N and/or P concentrations lower than those of the nonsymbiotic plants. The effects of the endophytes on CO₂ fixation were additive.     

Leaf magnesium alters photosynthetic response to low water potentials in sunflower

We grew sunflower (Helianthus annuus L.) plants in nutrient solutions having nutritionally adequate but low or high Mg²⁺ concentrations and determined whether photosynthesis was effected as leaf water potentials (ψ_w) decreased. Leaf Mg contents were 3- to 4-fold higher in the plants grown in high Mg²⁺ concentrations (10 millimolar) than in those grown in low concentrations (0.25 millimolar). These contents were sufficient to support maximum growth, plant dry weight, and photosynthesis, and the plants appeared normal. As low ψ_w developed, photosynthesis was inhibited but moreso in high Mg leaves than in low Mg leaves. The effect was particularly apparent under conditions of light- and CO₂-saturation, indicating that the chloroplast capacity to fix CO₂ was altered. The differential inhibition observed in leaves of differing Mg contents was not observed in leaves having differing K contents, suggesting that the effect may have been specific for Mg. Because Mg²⁺ inhibits photophosphorylation and coupling factor activities at concentrations likely to occur as leaves dehydrate, Mg may play a role in the inhibition of chloroplast reactions at low ψ_w, especially in leaves such as sunflower that markedly decrease in water content as ψ_w decreases.     

Bacteria on leaves: a previously unrecognised source of N2O in grazed pastures

Nitrous oxide (N₂O) emissions from grazed pastures are a product of microbial transformations of nitrogen and the prevailing view is that these only occur in the soil. Here we show this is not the case. We have found ammonia-oxidising bacteria (AOB) are present on plant leaves where they produce N₂O just as in soil. AOB (Nitrosospira sp. predominantly) on the pasture grass Lolium perenne converted 0.02–0.42% (mean 0.12%) of the oxidised ammonia to N₂O. As we have found AOB to be ubiquitous on grasses sampled from urine patches, we propose a ‘plant'' source of N₂O may be a feature of grazed grassland.In terms of climate forcing, nitrous oxide (N₂O) is the third most important greenhouse gas (Blunden and Arndt, 2013). Agriculture is the largest source of anthropogenic N₂O (Reay et al., 2012) with about 20% of agricultural emissions coming from grassland grazed by animals (Oenema et al., 2005).Grazed grassland is a major source of N₂O because grazers harvest nitrogen (N) from plants across a wide area but recycle it back onto the pasture, largely as urine, in patches of very high N concentration. The N in urine patches is often in excess of what can be used by plants resulting in losses through leaching as nitrate, as N₂O and through volatilisation as ammonia (NH₃) creating a high NH₃ environment in the soil and plant canopy; an important point that we will return to later. The established wisdom is that N₂O is generated exclusively by soil-based microbes such as ammonia-oxidising bacteria (AOB). This soil biology is represented in models designed to simulate N₂O emissions and the soil is a target for mitigation strategies such as the use of nitrification inhibitors.We have previously shown that pasture plants can emit N₂O largely through acting as a conduit for emissions generated in the soil, which are themselves controlled to some degree by the plant (Bowatte et al., 2014). In this case the origin of the emission is still the soil microbes. However, AOB have been found on the leaves of plants, for example, Norway spruce (Papen et al., 2002; Teuber et al., 2007) and weeds in rice paddies (Bowatte et al., 2006), prompting us to ask whether AOB might be present on the leaves of pasture species and contribute to N₂O emissions as they do in soil.We looked for AOB on plants in situations where NH₃ concentrations were likely to be high, choosing plants from urine patches in grazed pastures and plants from pastures surrounding a urea fertiliser manufacturing plant. DNA was extracted from the leaves (including both the surface and apoplast) and the presence of AOB tested using PCR. AOB were present in all the species we examined—the grasses Lolium perenne, Dactylis glomerata, Anthoxanthum odoratum, Poa pratensis, Bromus wildenowii and legumes Trifolium repens and T. subterraneum.To measure whether leaf AOB produce N₂O, we used intact plants of ryegrass (L. perenne) lifted as cores from a paddock that had been recently grazed by adult sheep. The cores were installed in a chamber system designed to allow sampling of above- and belowground environments separately (Bowatte et al., 2014). N₂O emissions were measured from untreated (control) plants and from plants where NH₃ was added to the aboveground chamber and leaves were either untreated or sterilised by wiping twice with paper towels soaked in 1% hypoclorite (Sturz et al., 1997) and then with sterile water. We tested for the presence and abundance of AOB on the leaves by extracting DNA and using PCR and real-time PCR targeting the ammonia monoxygenase A (amoA) gene, which is characteristic of AOB. AOB identity was established using cloning and DNA sequencing. Further details of these experiments can be found in the Supplementary Information.The addition of NH₃ to untreated plants significantly stimulated N₂O emissions (P<0.001) compared with the controls; by contrast, the plants with sterilised leaves produced significantly less N₂O than controls (P<0.001) even with NH₃ added (Figure 1) providing strong evidence for emissions being associated with bacteria on the leaves. Control plants did emit N₂O suggesting there was either sufficient NH₃ available for bacterially generated emissions and/or other plant-based mechanisms were involved (Bowatte et al., 2014).Open in a separate windowFigure 1Effect of an elevated NH₃ atmosphere and surface sterilisation of leaves on leaf N₂O emissions measured over 1-h periods on three occasions during the day. Values are means (s.e.m.), where n=7.The major AOB species identified was Nitrosospira strain III7 that has been previously shown to produce N₂O (Jiang and Bakken, 1999). We measured 10⁹ AOB cells per m² ryegrass leaf, assuming a specific leaf area of 250 cm² g⁻¹ leaf.The rate of production of N₂O (0.1–0.17 mg N₂O-N per m² leaf area per hour) can be translated to a field situation using the leaf area index (LAI)—1 m² leaf per m² ground would be an LAI of 1. LAI in a pasture can vary from <1 to >6 depending on the management (for example, Orr et al., 1988). At LAI of 1, the AOB leaf emission rate would equate to a N₂O emission rate of about 0.1–0.3 mg N₂O-N per m² ground per hour. By comparison, the emission rates measured after dairy cattle urine (650 kg N ha⁻¹) was applied to freely and poorly drained soil were 0.024–1.55 and 0.048–3.33 mg N₂O-N per m² ground per hour, respectively (Li and Kelliher, 2005).The fraction of the NH₃ that was converted to N₂O by the leaf AOB was 0.02–0.42% (mean 0.12%). The mean value is close to that measured for Nitrosospira strains including strain III7 isolated from acidic, loamy and sandy soils where values ranged from 0.07 to 0.10% (Jiang and Bakken, 1999). This is good evidence that the AOB on leaves have the capacity to produce N₂O at the same rate as AOB in soils. We do not suggest that leaf AOB will produce as much N₂O as soil microbes; however, because leaf AOB have access to a source of substrate—volatilised NH₃—that is unavailable to soil microbes and may constitute 26% (Laubach et al., 2013) to 40% (Carran et al., 1982) of the N deposited in the urine, N₂O emissions from these aboveground AOB are additional to soil emissions. Further research is required to identify the situations in which leaf AOB contribute to total emissions and to quantify this contribution.