Metabolism of Inorganic Carbon Taken Up by Roots in Salix Plants

The metabolic products of inorganic carbon taken up throughthe roots from nutrient solution were studied in willow plants.Willow cuttings (Salix cv. Aquatica gigantea) were suppliedwith unlabelled or ¹⁴C-labelled NaHC0₃ for 1, 5, 10, and 24h in light or in darkness. After feeding, the plants were dividedinto six samples (upper and lower leaves and corresponding stems,cuttings and roots), which were frozen in liquid N₂. Freeze-driedground samples were extracted into water-soluble, chloroform-solubleand insoluble fractions. The water-soluble fraction was furtherseparated into basic, acidic, and neutral fractions by ion-exchangechromatography. In the light experiment pronase treatment wasused to separate the insoluble fraction into proteins and insolublecarbohydrates. After I h feeding time, most of the ¹⁴C was fixed into organicacids and amino acids both in light and in darkness in all partsof the plants. In the roots a large part of the ^l4C-carbon wasincorporated into the protein and insoluble fractions alreadyduring short feeding times, and the amounts incorporated increasedwith time. In the leaves, after 1 and 5 h the main labelledcompounds were the organic acids and amino acids, but after10 h about half of the total ¹⁴C was in protein and in the insolublefraction. A further analysis of amino acids and organic acidswith HPLC showed that C-4 acids were labelled initially andthat over time the proportion of different acids changed. These results indicate that the metabolism of carbon in rootsmight take place via ß-carboxylation of PEP. Partof the fixed ¹⁴C is transported from the roots, probably asamino acids and organic acids, to the shoot. In roots the C-4acids are metabolized further into structural compounds (proteinsand insoluble carbohydrates). Key words: DIC, Salix, roots, metabolism, HPLC     

Mobilization of Reserves and Synthesis of Sterols and Triterpenes in Seedlings of Two Canarian Euphorbia Species

Seedlings from Euphorbia canariensis and Euphorbia lambii weregrown in the dark at 25 °C. Protein and triglyceride contentas well as levels of sugars and amino acids in the endospermwere determined during endosperm depletion. In the endospermof Euphorbia canariensis, relatively low levels of amino acids(up to 1 µmol.endosperm^–1) were found of which glutamine/glutamateaccounted for 40% at the stage of radicle emergence. High levelsof amino acids (up to 4 µmol.endosperm^–1) comparedwith sugars (up to 2 µmol sucrose.endosperm^–1) weredetected in the endosperm of Euphorbia lambii. Arginine wasthe main component (28 µmol%) of the amino acids in thistissue. In both species amino acid composition changed graduallyduring endosperm depletion. Cotyledons retained their ability to absorb a variety of watersoluble substrates after removal of the endosperm. ¹⁴C from[U-¹⁴C]sucrose was effectively incorporated into the triterpenesof the laticifers and to a lesser extent into the sterols ofthe seedling. The highest incorporation values were found inyoung seedlings about 2 d after the emergence of the radicle.Seedlings of this age also showed high incorporation rates of¹⁴C from labelled alanine, serine, threonine, valine, leucineand isoleucine into both triterpenols and sterols, but no generalconclusions about metabolic channelling in lipid synthesis couldbe made. Endosperm, Euphorbia canariensis L. Euphorbia lambii Svent., sterols, triterpenols, amino acids, laticifer, biosynthesis     

Assimilation and transport of nitrogen in rice I. 15N-labelled ammonium nitrogen

The assimilation and transport of ¹⁵N-labelled ammonium nitrogenin rice plants (Oryza sativa L.) was studied. Plants assimilatedlarge amounts of nitrogen from labelled ammonium into theiramides and amino acids, particularly in the roots and stem,at the end of a 4-day ¹⁵N feeding and 10 days later in the upperleaves, especially in the blades. Although the incorporationof ¹⁵N into all the nitrogen fractions of the newly emergedpanicle was evident, it was particularly pronounced in the amidesand amino acids of the soluble fractions. The upper leaves hada greater ¹⁵N incorporation in their organic N-fractions thandid the lower ones. Amides and amino acids are considered tobe the main forms of nitrogen transported to the shoot fromthe ammonium assimilated in the roots. The transport of theorganic forms of nitrogen was possibly greater to the upperleaves than to the lower ones. The nitrite fraction had more ¹⁵N than did the nitrate fractionin all parts of the plant, particularly in the upper leaf blades.It appeared that some of the ammonia might have been oxidizedto nitrite, then to nitrate in some parts of the plant; probablyin the upper leaves. The synthesis of protein and nucleic acid occurred rapidly inthe upper leaves, especially in the blades, also in the rootsas evidenced by the considerable incorporation of ¹⁵N in theinsoluble fractions of these parts. The variation in ¹⁵N-distribution,during the 10 days, in the different plant parts suggests thatthe nitrogen incorporated during protein synthesis in the rootsand tillers was remobilized and transported to the upper partsof the shoot. A concept for the transport of organic nitrogenouscompounds from the roots to shoot through the phloem and xylemof the rice plant stem is discussed. (Received May 11, 1974; )     

Assimilation of gaseous ammonia and the transport of its products in barley and spinach leaves

The interactions between the assimilation and transport of nitrogenand carbon were investigated in barley and spinach leaves. Bothplants were fumigated with NH₃ (1 mg m^–3 and the contentof amino acids, sucrose and carbon intermediates of amino acidmetabolism were analysed in the leaves, apoplast and phloemsap. The following changes took place in the C- and N-metabolismof barley leaves during 5 h of fumigation with NH₃ (a) The contentsof amino acids, especially glutamine, largely increased andthe contents of sucrose, 2-oxoglutarate, phosphoenolpyruvate,and glycerate-3-phosphate declined. (b) A decrease in the phophoenolpyruvatecontent was accompanied by an increased activity of phosphoenolpyruvatecarboxylase. (c) The altered cytosolic concentrations of aminoacids and sucrose during NH₃ fumigation correlated with similarchanges in the apoplast and phloem sap. The altered percentageof each amino acid relative to the total amino acid concentrationin the cytosol, caused by NH₃ fumigation, is reflected in theapoplast and the phloem sap. The results indicate that the concentrations of amino acids in the cytosol determine their concentrationsin the phloem. Key words: Amino acids, ammonia fumigation, barley leaves, C: N partitioning, phosphoenolpyruvate carboxylase, phloem sap, spinach leaves     

Dynamics of Carbon Photosynthetically Assimilated in Nodulated Soya Bean Plants under Steady-state Conditions 2. The Incorporation of 13C into Carbohydrates, Organic Acids, Amino Acids and some Storage Compounds

Nodulated soya bean (Glycine max L.) plants at the early floweringstage were allowed to assimilate ¹³CO₂ under steady-state conditions,with a constant ¹³C abundance, for 8 h in the light. The plantswere either harvested immediately or 2 d after the end of the¹³CO₂ feeding, divided into young leaves (including flower buds),mature leaves, stems+petioles, roots and nodules; the ¹³C abundancein soluble carbohydrates, organic acids, amino acids, starchand poly-ß-hydroxybutyric acid was determined witha gas chromatography-mass spectrometry. The rapid turnover of ¹³C in the sucrose pools observed in allorgans of the plants showed that sucrose was the principal materialin the translocation stream of primary products of photosynthesis.At the end of the ¹³CO₂ exposure, sucrose in the mature leavesas the major source organs and in the stems+petioles was labelledwith currently assimilated carbon to about 75 per cent, whereasa much higher labelling of sucrose was found in the roots andin the nodules. This suggests the existence of two or more compartmentedpools of sucrose in mature leaves and also in stems+petioles. The relative labelling patterns of individual organic acidsand amino acids were similar in various plant organs. However,the rapid turnover of succinate and glycine was characteristicof nodules. Treatment with a high concentration of nitrate inthe nutrient media increased the turnover rate of amino acidcarbon in shoot organs and roots, while it markedly decreasedthe labelling of amino acids in nodules. The cyclitols, exceptfor D-pinitol, were significantly labelled with assimilated¹³C in mature leaves, but in nodules, the labelling was verymuch less. In the nodules, which were actively fixing atmospheric nitrogen,a large proportion (80–90 per cent) of currently assimilatedcarbon was found as sucrose and starch at the end of the ¹³CO₂feeding. This was also true of the roots. On the other hand,in young growing leaves, the distribution of currently assimilatedcarbon into sucrose, starch and other soluble compounds wasmuch less. This suggests that a large amount of carbon assimilatedby and translocated to young leaves was used to make up structuralmaterials, mainly protein and cell wall polymers synthesis,during the light period. Glycine max L., soya bean, ¹³CO₂ assimilation, carbon metabolism in nodules     

Protein synthesis in Xanthium leaf development

Young, expanding Xanthium leaves had many soluble proteins;older leaves had progressively fewer. The leaves that grew themost rapidly incorporated the most ¹⁴CO₂ into their proteins.The relative intensity of ¹⁴CO₂ incorporation into the differentsoluble proteins changed with leaf development. (Received November 17, 1969; )     

Comparison of carbon dioxide fixation and the fine structure in various assimilatory tissues of Amaranthus retroflexus L

The pattern for primary products of CO₂-fixation and the chloroplaststructure of Amaranthus retrqflexus L., a species which incorporatescarbon dioxide into C₄ dicarboxylic acids as the primary productof photosynthesis, were compared in various chlorophyll containingtissues,i.e., foliage leaves, stems, cotyledons and pale-greencallus induced from stem pith. Despite some morphological differencesin these assimilatory tissues, malate and aspartate were identifiedas the major compounds labelled during a 10 sec fixation of¹⁴CO₂ in all tissues. Whereas, aspartate was the major componentin C₄-dicarboxylic acids formed in foliage leaves, malate predominatedas the primary product in stems, cotyledons and the pale-greencallus. The percentage of ¹⁴C-radioactivity incorporated intoPGA and sugar-P esters increased and ¹⁴C-sucrose was detectedin the prolonged fixation of ¹⁴CO₂ in the light, not only infoliage leaves, but also in stems and cotyledons. ¹ This work was supported by a Grant for Scientific ResearchNo. 58813, from the Ministry of Education, Japan. ² Present address: Institute of Applied Microbiology, Universityof Tokyo, Tokyo, Japan. ³ Present address: Department of Biochemistry, University ofGeorgia, Athens 30601. Georgia, U. S. A. (Received July 10, 1971; )     

Interconversions of 14C-labelled Sugars in Apple Tree Tissues12

Tissue pieces excised from orchard-grown apple trees duringa growing season exhibited different and changing capabilitiesof transferring ¹⁴C-label from sucrose, fructose and sorbitolto other soluble carbohydrates. All tissues incorporated fructose¹⁴C into sucrose but only leaves incorporated significant amountsof label from sucrose into sorbitol. As seeds developed andmatured, their ability to incorporate ¹⁴C from sorbitol andfrom fructose into sucrose increased. Sorbitol and sucrose arethe major translocated photosynthetic products of apple leavesbut whereas sorbitol appears to be an end-product of synthesis,sucrose may be considered as a substrate involved more directlyin carbohydrate utilization. Key words: Malus domestica, Apple, Carbohydrate interconversions     

Amino acids stimulate phosphorylation of p70S6k and organization of rat adipocytes into multicellular clusters

In previousstudies we have shown that rat adipocytes suspended in Matrigel andplaced in primary culture migrate through the gel to form multicellularclusters over a 5- to 6-day period. In the present study,phosphorylation of the insulin-regulated 70-kDa ribosomal protein S6kinase (p70^S6k) was observedwithin 30 min of establishment of adipocytes in primary culture. Twoinhibitors of the p70^S6ksignaling pathway, rapamycin and LY-294002, greatly reducedphosphorylation of p70^S6k andorganization of adipocytes into multicellular clusters. Of all thecomponents of the cell culture medium, amino acids, and in particular asubset of neutral amino acids, were found to promote bothphosphorylation of p70^S6k andcluster formation. Lowering the concentrations of amino acids in themedium to levels approximating those in plasma of fasted rats decreasedboth phosphorylation of p70^S6kand cluster formation. Furthermore, stimulation ofp70^S6k phosphorylation by aminoacids was prevented by either rapamycin or LY-294002. These findingsdemonstrate that amino acids stimulate thep70^S6k signaling pathway inadipocytes and imply a role for this pathway in multicellularclustering.

     

The Effects of Leaf Age and Senescence on the Distribution of Carbon in Lolium temulentum

Assimilate distribution in leaves of Lolium temulentum was establishedby root absorption of [¹⁴C]sucrose and after exposure to ¹⁴CO₂.Age determined the amount of carbon assimilated, with more labelbeing incorporated during expansion than at maturity. Duringsenescence ¹⁴C assimilation was much lower. Ethanol-solubleextracts from various tissues of root-labelled plants containedmost of the radioactivity chiefly in basic and acidic compounds.The neutral fraction was composed predominantly of sucrose. Sucrose was comparably labelled in leaves from plants fed equalamounts of either [¹⁴C]sucrose, glucose, or fructose and onlytraces of labelled monosaccharides appeared in extracts. Radioactive sucrose was translocated rapidly from mature leaveswhereas, in the expanding leaf, carbon incorporation was directedtowards growth and the greater proportion of label present atligule formation was in ethanol-insoluble material. Induced senescence, of a mature leaf fed during expansion, produceda rapid loss from the pool of insoluble ¹⁴C. This was accompaniedby a reduction in the contents of chlorophyll and soluble proteinand an accumulation of amino acids. The onset of senescencecaused changes in leaf sugar levels which were correlated withincreased rates of respiration.     

Metabolism of Exogenous Malonate by Coffee Leaf Tissue

When [l-¹⁴C]-malonate was supplied to discs cut from matureleaves of Coffea arabica, ¹⁴CO₂ was released (approximately12% of the total CO₂ respired) and organic acids of the Krebscycle, uronic acids, sugars and amino acids became radioactive.There was no incorporation of MC into either lipids or phenoliccompounds. The formation of glucose from malonate has not beenobserved in other studies with plant tissues. The synthesisof labelled glucose together with an active pentose phosphatepathway that is stimulated by malonate explains the accumulationof radioactive phosphogluconate in the leaf discs. Tentativeproposals are made for pathways to account for the results obtained. Key words: Coffee leaves, Malonate metabolism, Pentose phosphate pathway     

Origin of Foliar Nitrogen and Changes in Free Amino-Acid Composition and Content of Leaves, Stubble, and Roots of Perennial Ryegrass During Re-growth after Defoliation

Nitrogen re-mobilization and changes in free amino acids werestudied as a function of time in leaves, stubble, and rootsduring ryegrass (Lolium perenne L.) re-growth. Experiments with¹⁵N labelling clearly showed that during the first days nearlyall the nitrogen in new leaves came from organic nitrogen re-mobilizedfrom roots and stubble. On the days of defoliation, stubblehad the highest content of free amino acids with 23 mg per gdry weight against 15 mg and 14 mg in leaves and roots, respectively.The major amino acids in leaves were asparagine (23% of totalcontent in free amino acids), aminobutyrate, serine, glutamine,and glutamate (between 7% and 15%) whereas in roots and stubblethe contribution of amides was high, especially asparagine (about50%). Re-growth after cutting was associated with a rapid increaseof the free amino acid content in leaves, with a progressivedecrease in roots while stubble content remained virtually unchanged.In leaves, asparagine increased from the first day of re-growth,while the aspartate level remained unchanged and glutamine increasedstrongly on the first day but decreased steadily during thenext few days of re-growth. Asparagine in stubble and rootschanged in opposite directions: in stubble it tended to increasewhereas in roots it clearly decreased. In contrast, stubbleand roots showed a similar decrease in glutamine. In these twoplant parts, as in leaves, aspartate remained at a low level.Results concerning free amino acids are discussed with referenceto nitrogen re-mobilization from source organs (stubble androots) to the sink organ (regrowing leaves). Key words: Lolium perenne L, re-growth, nitrogen, free amino acids, glutamine, asparagine     

Salinity Stress and the Content of Proline in Roots of Pisum sativum and Tamarix tetragyna

Amino acid composition of the free amino acid pool and the TCA-insolubleprotein fraction were investigated in root tips of pea and Tamarixtetragyna plants grown at various levels of NaCl salinity. Salinitystress induced an increase of proline content, mainly in thefree amino acid pool in both plants, and of proline or hydroxyprolinecontent in the protein. Externally-supplied proline was absorbedand incorporated into protein, by pea roots, more effectivelythan by Tamarix roots. Salinity stress, apparently, stimulatedthe metabolism of externally-supplied labelled proline. Pearoots have a very large pool of free glutamic acid; however,70 per cent of the ¹⁴C from externally-supplied ¹⁴C-U-glutamicacid was released as CO₂. Very small amounts of it were incorporatedinto protein. No measurable amount of radioactivity could bedetected in any one of the individual amino acids, either ofprotein hydrolysate or the free amino acid pool. Proline very effectively counteracted the inhibitory effectof NaCl on pea seed germination and root growth. A similar effectbut to a lesser degree was achieved with phenylalanine and asparticacid. The feasibility of proline being a cytoplasmic osmoticumis discussed.     

(Na+-K+)-stimulated ATPase in Leaves of C4 Plants: Possible Involvement in Active Transport of C4 Acids

Leaves of three C₄ plants, Setaria italica, Pennisetum typhoides,and Amaranthus paniculatus possessed five- to ten-fold higheractivities of a (Na⁺-K⁺)-dependent ATPase than those of twoC₃ plants, Oryza sativa and Rumex vesicarius. Na⁺-K⁺ ATPasefrom leaves of Amarathus exhibited an optimal pH of 7?5 andan optimal temperature of 35 ?C. It required 40 mM K⁺ and 80mM Na⁺ for maximal activity. Ouabain partially inhibited (Na⁺-K⁺)-dependentATPase activity in leaves of C₄ plants. Ouabain also blockedthe movement of label from initially formed C₄ acids into endproducts in leaves of only C₄ plants, Setaria and Amaranthusbut not in a C₃ plant, Rumex. We propose that Na⁺-K⁺ ATPasemay mediate transfer of energy during active transport of C₄acids from mesophyll into the bundle sheath.     

EFFECTS OF CHLORAMPHENICOL AND KINETIN ON UPTAKE AND INCORPORATION OF AMINO ACIDS BY TOBACCO LEAF DISKS

The effects of chloramphenicol and kinetin on uptake and incorporationof ³⁵S-methionine and some ₁₄C-amino acids have been investigatedin leaf-disks of Nicotiana rustica in light and dark. Chloramphenicolin a concentration of 1 mg per ml inhibits the uptake of aminoacids from 30 to 60 per cent compared with the water control.The incorporation of amino acids into bulk protein is stronglyinhibited in light (40 to 70 per cent), but only to a smalldegree in dark (10 to 20 per cent), as revealed also by ¹⁴CO₂-photosynthesisof the disks and following treatment with chloramphenicol indark. The stimulating effect of kinetin on uptake and incorporationof amino acids is dependent upon its concentration (10^–5to 10^–6 M ; but 10^–4 M solution inhibits stronglyboth uptake and incorporation). The stimulation seems to influencemore incorporation than uptake processes. Possible interactionsof chloramphenicol and kinetin in the protein metabolism oftobacco leaves have been discussed. (Received April 27, 1964; )     

14CO2 Fixation, Translocation, and Carbon Metabolism in Rapidly Expanding Leaves ofPopulus deltoides

To examine ¹⁴CO₂ fixation, potential translocation, and carbonflow among leaf chemical fractions of young developing leaves,the shoot tip of 24-leaf cottonwood (Populus deltoides Bartr.ex. Marsh) plants were cut off under water, placed in artificialxylem sap, and treated with ¹⁴CO₂ in continuous and pulse-chaseexperiments. Additional leaves on whole plants were spot treatedon the lamina tip to follow export from the tip only. The analysedleaves ranged in age from leaf plastochron index(LPI) –5to 3, the spot treated leaves from LPI 2 to 5. After 30 minfixation, the specific activity in the lamina tip increasedlinearly with leaf age from LPI –5 to 1 (0.5 to 4.5 kBqmg^–1). Specific activity in the lower lamina increasedslowly with leaf age and did not reach 500 kBq mg^–1 untilLPI –1. Total ¹⁴CO₂ fixed in the lower lamina exceededthat fixed in the tip by LPI –2 because of the large amountof tissue present in the lower lamina. Although the lamina tipfixed high levels of ¹⁴CO₂, pulse-chase studies coupled withautoradiography indicated no vein loading or translocation fromthe tip until about LPI 4 or 5. The ¹⁴C fixed in both tip andlower lamina was incorporated at the site of fixation and wasnot distributed to younger tissue or translocated from the lamina.Although the percentage distribution (¹⁴C in each chemical fractioncompared with the total in all fractions) of ¹⁴C among certainchemical fractions, e.g. sugars, amino acids and proteins, indicatedthat the mesophyll of the tip was more mature than the lowerlamina, physiologically both leaf sectors were immature basedon the expected ¹⁴C distribution in mature tissue. Informationfrom this and other studies indicates that the extreme tip ofa developing cottonwood leaf first begins to export photosynthateabout LPI 4 or 5 on a 24-leaf plant. The first photosynthatetranslocated may be incorporated into the vascular tissues andmesophyll directly below the tip. However, as the tip continuesto mature photosynthate is translocated past the immature lowerlamina into the petiole and out of the leaf. Populus deltoides Bartr. ex. Marsh, eastern cottonwood, translocation, leaf development, ¹⁴C fixation, carbon metabolism     

Amino Acid Content of Leaves in Mycorrhizal and Non-mycorrhizal Citrus Rootstocks

Nitrogen status was examined in leaves of sour orange and roughlemon citrus rootstocks grown in a low phosphorus sand inoculatedwith Glomus etunicatus, in sand amended with superphosphateat a rate of 2240 kg ha^–1, and in a sand control leftuntreated. Sour orange was 3.1- and 3.5-fold taller and roughlemon was 1.8- and 2.0-fold taller than the controls in theinoculated and phosphorus treatments, respectively. In the controls,leaf N was up to 2.5-fold higher than in the other treatments.Both total and free amino acids accumulated in leaves of bothrootstocks to higher levels in the control than in the othertreatments. Most total amino acids in the control were lowerthan in the treatments, with the exceptions of arginine (upto 12-fold increase), proline (up to 1.8-fold increase), lysine,and free ammonia. Twenty-two free amino acids, urea, and ammoniawere detected. Both rootstocks grown in control sand had significantincreases in citrulline, ornithine, lysine, histidine, arginineand ammonia. Levels of total and most free amino acids in theinoculated and phosphorus treatments were similar to one another.It is suggested that mineral deficiency caused by the absenceof G. etunicatus causes a reorganization of N-metabolism witha shift to a greater synthesis of ornithine cycle intermediates. Citrus aurantium L., Citrus limon (L.) Burm, amino acid content, citrus rootstocks, mycorrhiza, nitrogen metabolism     

Methionine as a Dominant Precursor of Phytosiderophores in Graminaceae Plants

Nine ¹⁴C-labeled amino acids and ¹⁴C-acetic acid from root tipsof Fe-deficient Graminaceae plants (Hordeum vulgare, Oryzaesativa and Avena saliva) were surveyed to determine the precursoramino acid of phytosiderophores. The dominant precursor wasmethionine, which was incorporated into avenic acid deoxymugineicacid mugineic acid epihydroxymugineic acid and/or hydroxymugineicacid in this order. Methionine sulfoxide or methionine sulfonemay be important intermediates in going from methionine to avenicacid. (Received May 6, 1987; Accepted June 12, 1987)     

Assimilation of Nitrogen in Mutants Lacking Enzymes of the Glutamate Synthase Cycle

¹⁵N labelling was used to investigate the pathway of nitrogenassimilation in photorespiratory mutants of barley (Hordeumvulgare cv. Maris Mink), in which the leaves have low levelsof glutamine synthetase (GS) or glutamate synthase, key enzymesof ammonia assimilation. These plants grew normally when maintainedin high CO₂, but the deletions were lethal when photorespirationwas initiated by transfer to air. Enzyme levels in roots weremuch less affected, compared to leaves, and assimilation oflabelled nitrate into amino acids of the root showed very littledifference between wild type and mutants. Organic nitrogen wasexported from roots in the xylem sap mainly as glutamine, levelsof which were somewhat reduced in the GS-deficient mutant andenhanced in the glutamate synthase deficient mutant. In theleaf, the major effect was seen in the glutamatesynthase mutant,which had an extremely limited capacity to utilize the importedglutamine and amino acid synthesis was greatlyrestricted. Thiswas confirmed by the supply of [¹⁵N]-glutamine directly to leaves.Leaves of the GS-deficient mutant assimilatedammonia at about75% the rate found for the wild type, and this was almost completelyeliminated by addition of the inhibitormethionine sulphoximine.Root enzymes, together with residual levels of the deleted enzymesin the leaves, have sufficient capacityfor ammonia assimilation,through the glutamate synthase cycle, to provide adequate inputof nitrogen for normal growth of themutants, if photorespiratoryammonia production is suppressed. Key words: Hordeum vulgare, ¹⁵N, glutamine synthetase, glutamate synthase, ammonia assimilation