Stamenless, a tomato mutant with homeotic conversions in petals and stamens

A tomato (Lycopersicon esculentum Mill.) monogenic semidominant mutation, stamenless (sl), which results in homeotic conversions in two adjacent floral whorls, was studied. When grown at standard temperature, flowers of sl/sl plants showed sepaloid petals in the second whorl and strong transformation of stamens to carpels in whorl three. These transformed carpels were fused with each other and with the genuine carpels in the fourth whorl to form a unique gynoecium. The mutation is semidominant since heterozygous plants showed a phenotype intermediate between that of the wild type (WT) and that of homozygous mutant plants, with nearly WT petals but with feminized stamens bearing naked ovules on the base of their adaxial face. The initiation and position of organ primordia in sl/sl flowers were not altered when compared with WT primordia although development of organ primordia in the second and third whorls deviated from WT at an early stage as observed by scanning electron microscopy. The mutant phenotype is temperature sensitive and when sl/sl plants were cultured at low temperature, the morphology of some flowers resembled that of the WT. This reversion of the mutant phenotype is also induced by treatment of young sl/sl plants with gibberellic acid, providing evidence that gibberellin synthesis or sensitivity could mediate the effect of low temperature on the mutant phenotype. Southern blot analyses using a Deficiens-homologous gene from Solanum tuberosum as a probe showed a restriction-fragment-length polymorphism (RFLP) linked to the sl mutation. This result indicates that the mutation affects a Deficiens-like gene that controls the identity of petals and stamens. Received: 10 December 1998 / Accepted: 29 March 1999     

MORPHOGENESIS OF THE STAMENLESS-2 MUTANT IN TOMATO. I. COMPARATIVE DESCRIPTION OF THE FLOWERS AND ONTOGENY OF STAMENS IN THE NORMAL AND MUTANT PLANTS

The single gene recessive mutant stamenless-2 (sl₂/sl₂) differs phenotypically from the normal (+/+) only in the stamen structure. Stamens of the mutant plants were laterally free, twisted, shorter, paler in color, possessed abnormal pollen, and bore naked external ovules (E.O.) on the adaxial surface near the junction of anther and filament. Mutant plants grown in the field during summer produced flowers in which a number of carpel-like organs (‘carpelloid stamens‘) with few or no E.O. replaced the stamens. On the other hand, plants grown in the greenhouse during winter possessed flowers with greater number of yellow and pubescent stamens and many E.O. Study of stamen ontogeny revealed that at initiation (up to 100 μ in length) stamen primordia of normal and mutant plants resembled each other. Thereafter the development of stamens in the two genotypes could be distinguished.     

Quantum Yields of Photosystem II and Photosynthesis in an Aurea Mutant of Tobacco (C3) and an Oil Yellow Mutant of Maize (C4) Which Have High Capacities for Photosynthesis Despite Low Chlorophyll Contents

The quantum yields of O₂ evolution (_o2), CO₂ fixation (_co2)and of photosystem II measured by fluorescence analysis (_PSII),were determined in a mutant of tobacco (C₃) and a mutant ofmaize (C₄) having large deficiencies in light harvesting chlorophyll,but having similar capacities for photosynthesis on a leaf areabasis as the wild-type plants. The heterozygous dominant mutantof tobacco (aurea, Su/+) having 30% chlorophyll content of thewild-type, and of maize (oil yellow, Oy/+) having 60% chlorophyllcontent of the wild-type, maintain high leaf absorptances. Themaximum _o2 on an absorptance basis, measured under limitingred light and saturating CO₂ were the same in the mutant versuswild-type plants. _PSII and _co2 decreased in a similar mannerwith increasing light intensity, while the ratio of _PSII/_co2under varying light remained reasonably constant, in mutantversus wild-type seedlings. The results indicate that theseC₃ and C₄ mutants which have high capacities for photosynthesisdespite large deficiencies in chlorophyll content, maintaina high leaf absorptance, and a balanced utilization of absorbedquanta in photochemistry. ¹Present address: Botany Dept., University of California, Davis,CA, 95616, U.S.A.     

A bentazon and sulfonylurea sensitive mutant: breeding,genetics and potential application in seed production of hybrid rice

The use of a thermosensitive genic male sterility (TGMS) system in two-line hybrid rice breeding is affected greatly by the sterility instability of TGMS lines caused by temperature fluctuation beyond their critical temperatures for fertility reversion. To prevent seed production from self contamination, we have developed a system to secure seed purity using a herbicide-sensitive TGMS mutant, M8077S, obtained by radiation. Genetic analysis, using the F₁, F₂ and F₃ populations derived from this mutant and other normal varieties, revealed that bentazon lethality/sensitivity was controlled by a single recessive gene, which was named bel. The mutant can be killed at the seedling stage by bentazon at 300 mg/l or higher, a dosage that is safe for its F₁ hybrids and all other normal varieties. This mutant is also sensitive to all the tested sulfonylurea herbicides. Response of segregating plants to these two types of herbicide indicated that sulfonylurea sensitivity was also controlled by bel. By crossing this mutant with Pei-Ai 64S, an F₂ population was developed for genetic mapping. Surveying the two DNA pools from sensitive and non-sensitive F₂ plants identified four markers that were polymorphic between the pools. The putative linked markers were then confirmed with the F₂ population. The bel locus was located on chromosome 3, 7.1 cM from the closest microsatellite marker RM168. Phenotypic analysis indicated that the bel gene had no negative effect on agronomic traits in either a homozygous or heterozygous status. The mutant M8077S is valuable in the development of a TGMS breeding system for preventing impurity resulting from temperature fluctuation of the TGMS. Several two-line hybrid rice crosses using this system are under development.     

Regulation of Leaf Shape in the Solanifolia Mutant of Tomato (Lycopersicon esculentum) by Plant Growth Substances

The solanifolia mutant (sf/sf) of tomato (Lycopersicon esculentum)produces leaves consisting of leaflets with entire margins,unlike the lobed leaflets of normal plants. Normal plants treatedwith gibberellic acid (GA₃) produced leaves with entire marginswhereas mutant plants exposed to 2-chloroethyl-trimethyl ammoniumchloride (CCC)—an inhibitor of gibberellin biosynthesis—producedlobing of leaflets. The leaf area of the mutant was significantlygreater than that of the normal, but was not significantly differentfrom GA₃-treated normal leaves. Similarly, in CCC-treated mutantleaves the leaf area was not different from that of normal untreatedleaves. These observations suggest that the sf/sf mutation affectsthe leaf shape through its effect on endogenous gibberellinsand/or inhibitory substances. Leaf shape, Lycopersicon esculentum, plant growth substances, tomato     

Inheritance of a Mutation which Suppresses Flowering in Red Clover

A spontaneous mutation isolated from stocks of red clover (cultivarS123) prevents flower initiation unless plants are suppliedexogenously with gibberellin. Mutant plants are also more uprightand densely tillering in their growth habit. Inheritance ofthe non-flowering character was analysed in a series of crossesbetween wild-type S123 and mutant plants. Hybridity followingintercrossing was confirmed using electrophoretic variants ofcytoplasmic phosphoglucose isomerase coded by a- and b-allelesof the nuclear gene Pgi-2. All F₁ plants flowered normally andwere heterozygous at the Pgi-2 locus. However, F₂ segregationsdid not provide the expected ratios, with flowering plants exceedingpredicted levels. One back-cross involving an F₁ plant and themutant parent gave flowering:non flowering and ab:aa Pgi-2 ratiosof 2:1 rather than the expected 1:1. The results are consistentwith the existence of a zygotic lethal factor, originally presentin heterozygous (non-lethal) form in the mutant (non-flowering)parent and tightly linked to the mutated gene. Segregants whichwere non-flowering always displayed the characteristic mutantgrowth form and seeds borne on these plants were lighter incolour than those borne on normal plants. Thus, there existsin red clover a gene designated ‘dig’ (developmentinfluencing gibberellin) which has several pleiotropic effectsincluding suppressing the initiation of flowering in normallyflorally-inductive environments. There are at least two allelicforms of the gene, F (flowering) and f (non-flowering).     

Common Bean (Phaseolus vulgaris L.) Mutants Defective in Root Nodule Formation: II GENETIC ANALYSIS

Genetic analysis of crosses between two induced, ineffectivelynodulating mutants of common bean, NOD238 and NOD109, revealedthat their mutated nodulation phenotype is under the controlof the same locus in both mutants. The two mutants also resultedallelic for poor pod fertility, the other trait common to themutants. F₁ plants from crosses with their wild types nodulatedeffectively and had wild type pod fertility. Ineffective nodulationand poor pod fertility traits co-segregated in the F₂generationin which plants with the mutant nodulation and pod fertilityphenotypes represented 12.5% of the total population. Analysisin F₃confirmed that these plants were homozygous for both mutatedcharacters. The results indicated both mutant traits studiedare determined by a single recessive allele, named sym-2, whoseinheritance is negatively affected by its pleiotropic effecton pod fertility determining a deficit of ineffectively nodulatingcombinations. In an allelism test with the non-nodulating mutantof common bean NOD125 it was found that ineffective nodulationis controlled at a different locus and that the two loci arenot linked. Key words: Phaseolus valgaris, nitrogen fixation, nodulation mutants, genetics     

Identification of Genetically Induced Lesions and the Sites of Action of Inhibitors Affecting Photorespiration by Simple Tests on Leaf Discs

Turner, J. C. and Hall, N. P. 1988. Identification of geneticallyinduced lesions and sites of action of inhibitors affectingphotorespiration by simple tests on leaf discs.—J. exp,Bot. 39: 345-351. Six photorespiratory mutants of barley deficient in catalaseand two mutants lacking phospho-glycollate phosphatase wereidentified by a novel screening method using leaf discs. Leaf discs were punched directly into an appropriate bufferedreagent in which the enzymes diffused from the cut edges ofthe discs causing a change in the colour reagents. The reactionswere observed from 15 min onwards depending on which enzymeactivity was being followed. Hundreds of plants can be screenedrapidly for major differences in enzyme activity. The methods depend on the formation of a red product in thereaction of hydrogen peroxide (H₂O₂) with 4-aminoantipyrenein the presence of peroxidase. To detect P-glycollatc phosphataseand glycollate oxidase, the product of the linked reactions,H₂O₂, was measured. For catalase, the disappearance of addedH₂O₂ is followed. By omitting peroxidase from the colour reagentmixture, peroxidase activity in leaf discs can be measured. The method was evaluated by applying it to existing enzyme deficientmutants of barley lacking P-glycollate phosphatase and catalase.Further mutant plants were detected by this method. The techniquecould also be used to screen for inhibitors of the glycollatepathway for use as herbicides. Key words: Phosphoglycollate phosphatase, glycollate oxidase, catalase, peroxidase, hydrogen peroxide     

Temperature-induced modifications in the surface features of stamens of a tomato mutant: An SEM study

Summary Stamenless-2 (sl₂/sl₂) is a temperature-sensitive mutant of tomato (Lycopersicon esculentum) which exhibits altered stamen development under different temperatures (Sawhney 1983). By using scanning electron microscopy, this study was conducted to investigate the differentiation of surface features of mutant and normal stamens grown under different temperatures, with the view to further determine the role of temperature in gene expression in stamen development. Mutant stamens grown under intermediate temperatures (23 °C day/18 °C night) differed from the normal in hair production, the shape of epidermal cells and in the pattern of cuticular thickenings. Under low temperatures (18 °C day/15 °C night), all surface features of mutant stamens closely resembled the normal, whereas under high temperatures (28 °C day/23 °C night), the patterns and types of hairs, epidermal cells, stomata, and cuticular thickenings on mutant stamens were similar to that of a gynoecium. The staminal features of normal stamens were not affected by different temperatures. This study shows that the expression of the sl₂/sl₂ allele is influenced by temperature conditions to the extent that the pattern of cellular differentiation characteristic of either the stamens or the carpels can be induced in mutant stamens.     

Ion Imbalance in Capsicum annum scarbrous diminutive a Wilty Mutant of pepper: II.RUBIDIUM FLUX

Root tips of the wilty pepper mutant scarbrous diminutive accumulateless rubidium than those of the normal genotype. This phenomenonwas evident in root tips excised from plants maintained for2 d in CaSO₄ solution (low salt plants), especially in the lowerexternal concentration range (0.1– 1.0 mM) of RbCl. Theefflux rate of Rb⁺ from mutant root tips was twice as high asin normal root tips. These results indicate that the ability of the mutant rootsto absorb and accumulate Rb⁺ and K⁺ is impaired. This defectcould be a consequence of either an impaired Na⁺/K⁺ carriersystem, or increased leakiness of mutant membranes, or both. The fact that the normal roots can accumulate Rb⁺ much fasterthan mutant roots supports the first alternative, i.e. thatthe high affinity carrier system was impaired in the mutantroots. However, the higher efflux rate of Rb⁺ from the mutantroots suggests that membrane leakiness was also affected.     

The effects of temperature and the Rht3 dwarfing gene on growth, cell extension, and gibberellin content and responsiveness in the wheat leaf

The effects of low temperature and the Rht3 dwarfing gene onthe dynamics of cell extension in leaf 2 of wheat were examinedin relation to gibberellin (GA) content and GA-responsivenessof the extension zone. Leaf 2 of wild-type (rht3) wheat closelyresembled that of the Rht3 dwarf mutant when seedlings weregrown at 10C. The maximum relative elemental growth rate (REGR)within the extension zone in both genotypes was lower at 10Cthan at 20C, but the position with respect to the leaf basewas unaffected by temperature. The size of the extension zoneand epidermal cell lengths were similar in both genotypes at10C. Growth at 20C, instead of 10C, increased the lengthof the extension zone beyond the point of maximum REGR in thewild type, but not in the Rht3 mutant. Increasing temperatureresulted in longer epidermal cells in the wild type. Treatingwild-type plants at 10C with gibberellic acid (GA₃) also increasedthe length of the extension zone, but the Rht3 mutant was GA-non-responsive.However, the concentrations of endogenous GA₁ and GA₃ remainedsimilar across the extension zone of wild-type plants grownat both temperatures, despite large differences in leaf growthrates. The period of accelerating REGR as cells enter the extensionzone, and the maximum REGR attained, are apparently not affectedby GA. It is proposed that GA functions as a stimulus for continuedcell extension by preventing cell maturation in the region beyondmaximum REGR and that low temperature increases the sensitivitythreshold for GA action. Key words: Cell extension, gibberellin, Rht3 dwarfing gene, temperature, wheat leaf     

2-Trans-Abscisic Acid Biosynthesis and Metabolism of ABA-Aldehyde and Xanthoxin in Wild Type and the aba Mutant of Arabidopsis thaliana

Abscisic acid (ABA) and 2-trans-ABA (t-ABA) biosynthesis werestudied in wild type Landsberg erecta and the three allelicaba mutants of Arabidopsis thaliana (L.) Heynh., which are impairedin epoxy-carotenoid biosynthesis. Labelling experiments with¹⁸O₂and mass spectrometric analysis of [¹⁸O]ABA and its catabolitesABA-glucose ester (ABA-GE) and phaseic acid (PA), and t- ABAand t-ABA-GE, showed that t-ABA biosynthesis was less affectedthan ABA biosynthesis by mutations at the ABA locus. The aba-4allele caused the most severe impairment of ABA biosynthesiscompared with the other two mutant alleles aba-1 and aba-3,yet aba-4 plants synthesized as much t-ABA as wild type Landsbergerecta plants. Feeding experiments with RS- [²H₆]ABA-aldehydeisomers and unlabelled xanthoxin isomers suggest that t-xanthoxinand t-ABA-aldehyde are precursors to ABA and t-ABA in Arabidopsis Key words: ABA-alcohol, ABA-aldehyde, ABA-glucose ester, ¹⁸O₂ labelling, phaseic acid     

Simultaneous CO2- and 16O2/18O2-gas exchange and fluorescence measurements indicate differences in light energy dissipation between the wild type and the phytochrome-deficient aurea mutant of tomato during water stress

The CO₂-, H₂O- and ¹⁶O₂/¹⁸O₂ isotopic-gas exchange and the fluorescencequenching by attached leaves of the wild-type and of the phytochrome-deficienttomato aurea mutant was compared in relation to water stressand the photon fluence rate. The chlorophyll content of aurealeaves was reduced and the ultra-structure of the chloroplastswas altered. Nevertheless, the maximum rate of net CO₂ uptakein air by the yellow-green leaves of the aurea mutant was similarto that by the dark-green wild-type leaves. However, less O₂was produced by the leaves of the aurea mutant than by leavesof the wild-type. This result indicates a reduced rate of photosyntheticelectron flux in aurea mutant leaves. No difference in bothphotochemical and non-photochemical fluorescence quenching wasfound between wild-type and aurea mutant leaves. Water stresswas correlated with a reversible decrease in the rates of bothnet CO₂ uptake and transpiration by wild-type and aurea mutantleaves. The rate of gross ¹⁶O₂ evolution by both wild-type andaurea mutant leaves was fairly unaffected by water stress. Thisresult shows that in both wild-type and aurea leaves, the photochemicalprocesses are highly resistant to water stress. The rate ofgross ¹⁸O₂ uptake by wild-type leaves increased during waterstress when the photon fluence rate was high. Under the sameconditions, the rate of gross ¹⁸O₂ uptake by ^aurea mutant leavesremained unchanged. The physiological significane of this differencewith respect to the (presumed) importance of oxygen reductionin photoprotection is discussed. Key words: Water stress, gas exchange, fluorescence quenching, Lycopersicon esculentum, mutant (tomato, aurea), energy dissipation     

Synchronization of Phosphorylation of a Chloroplast Protein with the Cell Division Cycle in Heterosigma akashiwo

Fumigation of plants of five species with NO₂ in darkness causedvisible injuries to leaves, with the most severe injuries inkidney bean plants and the least severe in spinach plants. Fumigationof these plants in the light caused virtually no visible injuries.NO₂-fumigated leaves accumulated nitrite in the darkness butnot in the light. The level of accumulated NO₂^– was decreasedby light much more rapidly in spinach leaves than in those ofkidney bean, with much less injury to spinach leaves than tothose of kidney bean. A larger amount of NO₂^– accumulatedin the trifoliate leaves of kidney bean plants cultivated withNO₃^– as a main source of nitrogen than in those of plantscultivated with NH₄⁺, and the former plants were more susceptibleto injury from NO₂ than the latter. Administration of NO₂^–to leaves of spinach and kidney bean plants induced the destructionof Chi in the light. The extent of the destruction of Chi wassmaller in spinach than in kidney bean, consistent with theirrespective responses to NO₂. The NO₂^–-induced destructionof Chi was inhibited to some extent by scavengers of free radicals.Activities of superoxide dismutase (SOD) were higher in leavesof spinach than in those of kidney bean. These results indicatethat NO₂^– is the toxic species generated by fumigationwith NO₂ and that spinach has a greater tolerance for NO₂ thankidney bean, probably as a result both of a higher capacityfor reduction of NO₂^– and a higher level of activity ofSOD. (Received October 4, 1991; Accepted January 31, 1992)     

Differences between Spinach and Kidney Bean Plants in Terms of Sensitivity to Fumigation with NO2

Fumigation of plants of five species with NO₂ in darkness causedvisible injuries to leaves, with the most severe injuries inkidney bean plants and the least severe in spinach plants. Fumigationof these plants in the light caused virtually no visible injuries.NO₂-fumigated leaves accumulated nitrite in the darkness butnot in the light. The level of accumulated NO₂^– was decreasedby light much more rapidly in spinach leaves than in those ofkidney bean, with much less injury to spinach leaves than tothose of kidney bean. A larger amount of NO₂^– accumulatedin the trifoliate leaves of kidney bean plants cultivated withNO₃^– as a main source of nitrogen than in those of plantscultivated with NH₄⁺, and the former plants were more susceptibleto injury from NO₂ than the latter. Administration of NO₂^–to leaves of spinach and kidney bean plants induced the destructionof Chi in the light. The extent of the destruction of Chi wassmaller in spinach than in kidney bean, consistent with theirrespective responses to NO₂. The NO₂^–-induced destructionof Chi was inhibited to some extent by scavengers of free radicals.Activities of superoxide dismutase (SOD) were higher in leavesof spinach than in those of kidney bean. These results indicatethat NO₂^– is the toxic species generated by fumigationwith NO₂ and that spinach has a greater tolerance for NO₂ thankidney bean, probably as a result both of a higher capacityfor reduction of NO₂^– and a higher level of activity ofSOD. (Received June 5, 1991; Accepted January 27, 1992)     

Effect of CO2 Concentration During Growth on a CO2 Concentrating Mechanism in White Clover as Predicted from Differential 14CO2/12CO2Uptake

Lehnherr, B. M?chler, F. and N?sberger, J. 1985. Effect of CO₂concentration during growth on a CO₂ concentrating mechanismin white clover as predicted from differential ¹⁴CO₂/¹²CO² uptake.-J. exp. Bot. 36: 1835-1841. White clover was grown at 20 and100 Pa p(CO₂). The CO₂ response of net photosynthesis and differentialuptake of ¹⁴CO₂ and ¹²CO₂ by leaves were measured at varioustemperatures and at various O₂ and CO₂ partial pressures andcompared with predictions from ribulose bisphosphate carboxylase/oxygenasekinetics. Discrepancies between the observed gas exchange characteristicsfor the leaves and those predicted from the enzyme kineticswere interpreted as being due to a CO₂ concentrating mechanism.Plants grown at 20 Pa p(CO₂) showed a higher affinity for CO₂than plants grown at 100 Pa p(CO₂) when measured at 10 ?C. Nodifference in affinity was found at 30 ?C. The postulated CO₂concentrating effect was greater in plants grown at low CO₂than in plants grown at high CO₂ concentration and occurredonly at low temperature and low CO₂ partial pressure. It issuggested that plants grown at the lower CO₂ partial pressurehave a higher affinity for CO₂ due to a more efficient CO₂ concentratingsystem than plants grown at the higher CO₂ partial pressure. Key words: Photosynthesis, CO₂, concentration, RuBP carboxylase/oxygenase     

Rhizobium meliloti Mutants Defective in Symbiotic Nitrogen Fixation Affect the Oxygen Gradient in Alfalfa (Medicago sativa) Root Nodules

Rhizobium meliloti bacteroids carrying mutations in either fdxNor fixX isolated from alfalfa root nodules were shown to containthe nitrogenase proteins NifH, NifD and NifK. In contrast toan in vitro system of N₂-fixation based on R. meliloti wild-typebacteroids, nitrogenase activity could not be restored in crudeextracts of these mutant bacteroids by the addition of an artificialelectron donor, indicating that the nitrogenase proteins werepresent but not functional. ESR-studies revealed that both mutantslacked the FeMo-cofactor of nitrogenase. To analyse the roleof free O₂ on the damage of the nitrogenase components and theFeMo-cofactor in these mutant bacteroids, microelectrode studiesof O₂ concentrations and gradients within alfalfa root noduleswere carried out. R. meliloti mutants defective in other genesnecessary for symbiotic N₂-fixation were also included in thisstudy. Four distinct types of O₂ gradients were defined by theapparent presence or absence of an O₂ diffusion barrier andby the minimum internal O₂ concentration. These data clearlydemonstrated the influence of the microsymbiont on the O₂ gradientswithin the nodules. Nodules induced by Rm0540, an R. melilotimutant with altered exopolysaccharide production, which is notable to infect plant cells, did not contain an O₂ diffusionbarrier. In contrast, nodules containing a mutant defectivein dicarboxylate transport (dctA-), produced an O₂ gradientsimilar to the wild-type. Microelectrode measurements revealedH₂ concentrations in alfalfa wild-type nodules comparable tosoyabean, whereas no hydrogen could be detected in nodules harbouringthe dctA mutant or any other mutant strain. Key words: Nitrogen fixation, Rhizobium meliloti bacteroids, ferredoxin-like proteins, microelectrode studies     

Effect of Oxygen and Carbon Dioxide on Photorespiratory Flux Determined from Glycine Accumulation in a Mutant of Arabidopsis thaliana

Exposure to atmospheric conditions which promote photorespirationstrongly inhibits photosynthesis in a mutant of Arabidopsislacking mitochondrial serine transhydroxymethylase activity,and glycine accumulates as a stable end-product of photorespiratorycarbon and nitrogen flow. By providing exogenous serine andammonia to leaves of the mutant, wild-type photosynthesis ratescan be temporarily maintained in the absence of photorespiratoryCO₂ evolution. In these circumstances, the rate of glycine accumulationprovides a direct measure of photorespiratory flux which isnot complicated by the efflux and refixation of photorespiredCO₂, the dilution of radioactive label by endogenous metabolicpools, or non-specific effects of metabolic inhibitors. At thestandard atmospheric concentration of CO₂, the rate of glycineaccumulation in the mutant was proportional to the oxygen concentration,amounting to 53% of the rate of gross CO₂-fixation at 21% O₂.At normal levels of O₂, glycine accumulation was maximal atabout 475 µl CO₂1^–1 and was reduced at higher orlower CO₂ concentrations, being almost abolished at 3000µ1CO₂1^–1. These observations are discussed in the contextof a model of photorespiration based on the properties of ribulose1, 5-bisphosphate carboxylase/oxygenase, and in relation tothe results of previous attempts to measure photorespiration.Preliminary evidence from ¹⁴CO₂-labelling experiments whichsuggests a non-photorespiratory pathway of serine synthesisis also presented. Key words: Arabidopsis mutant, Photorespiration, Serine transhydroxymethylase     

The influence of elevated C02 on growth and age-related changes in leaf gas exchange

Rumex obtusifolius plants were grown for several months in daylitenvironment chambers (Solardomes) force-ventilated with aircontaining 350 or 600 µ;mol mol^–1 C0₂. ElevatedCO₂ was found to accelerate the natural ontogenic decline inphotosynthesis, but did not reduce leaf duration. In both CO₂treatments photosynthetic rates declined progressively withincreasing leaf age, the decline being greater for plants grownin elevated C0₂ such that rates became lower than in ambientCO₂. The degree of CO₂-induced photosynthetic down-regulationas determined by A/C₁ analysis was found to be dependent onleaf age. The major contribution to the decline in photosynthesiswas likely to be a reduction in Rubisco activity as changesin stomataland mesophyll limitations were small. Instantaneouswater use efficiency (WUE₁) was greater for plants in elevatedCO₂, but these values declined rapidly with leaf age, whereasin ambient CO₂ values were always lower, but were maintainedfor longer. Growth analysis indicated an increased root:-shootratio for plants grown in elevated CO₂, this occurring almostentirely as a result of increased root growth. Greater rootproliferation and increased WUE₁, are characteristics whichshould give this persistent and troublesome weed an increasedcompetitive advantage under projected conditions of climatechange Key words: tusifoliu, elevated CO₂, gas exchange, leaf age, senescence