Oxidation of C1-compounds in Pseudomonas C

Extracts of Pseudomonas C grown on methanol as sole carbon and energy source contain a methanol dehydrogenase activity which can be coupled to phenazine methosulfate. This enzyme catalyzes two reactions namely the conversion of methanol to formaldehyde (phenazine methosulfate coupled) and the oxidation of formaldehyde to formate (2,6-dichloroindophenol-coupled). Activities of glutathione-dependent formaldehyde dehydrogenase (NAD⁺) and formate dehydrogenase (NAD⁺) were also detected in the extracts.The addition of d-ribulose 5-phosphate to the reaction mixtures caused a marked increase in the formaldehyde-dependent reduction of NAD⁺ or NADP⁺. In addition, the oxidation of [¹⁴C]formaldehyde to CO₂, by extracts of Pseudomonas C, increased when d-ribulose 5-phosphate was present in the assay mixtures.The amount of radioactivity found in CO₂, was 6.8-times higher when extracts of methanol-grown Pseudomona C were incubated for a short period of time with [1-¹⁴C]glucose 6-phosphate than with [U-¹⁴C]glucose 6-phosphate.These data, and the presence of high specific activities of hexulose phosphate synthase, phosphoglucoisomerase, glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase indicate that in methanol-grown Pseudomonas C, formaldehyde carbon is oxidized to CO₂ both via a cyclic pathway which includes the enzymes mentioned and via formate as an oxidation intermediate, with the former predominant.     

Leaf gas exchange and nitrogen dynamics of N2-fixing, field-grown Alnus glutinosa under elevated atmospheric CO2

Few studies have investigated the effects of elevated CO₂ on the physiology of symbiotic N₂-fixing trees. Tree species grown in low N soils at elevated CO₂ generally show a decline in photosynthetic capacity over time relative to ambient CO₂ controls. This negative adjustment may be due to a reallocation of leaf N away from the photosynthetic apparatus, allowing for more efficient use of limiting N. We investigated the effect of twice ambient CO₂ on net CO₂ assimilation (A), photosynthetic capacity, leaf dark respiration, and leaf N content of N2-fixing Alnus glutinosa (black alder) grown in field open top chambers in a low N soil for 160 d. At growth CO₂, A was always greater in elevated compared to ambient CO₂ plants. Late season A vs. internal leaf p(CO₂) response curves indicated no negative adjustment of photosynthesis in elevated CO₂ plants. Rather, elevated CO₂ plants had 16% greater maximum rate of CO₂ fixation by Rubisco. Leaf dark respiration was greater at elevated CO₂ on an area basis, but unaffected by CO₂ on a mass or N basis. In elevated CO₂ plants, leaf N content (μg N cm^?2) increased 50% between Julian Date 208 and 264. Leaf N content showed little seasonal change in ambient CO₂ plants. A single point acetylene reduction assay of detached, nodulated root segments indicated a 46% increase in specific nitrogenase activity in elevated compared to ambient CO₂ plants. Our results suggest that N₂-fixing trees will be able to maintain high A with minimal negative adjustment of photosynthetic capacity following prolonged exposure to elevated CO₂ on N-poor soils.     

A new method for measuring 13carbon abundance in tracer experiments

Abstract. A new technique for the precise measurement of ¹³C-abundance and concentration is described. It is based on the differences in infra-red spectra between ¹²CO₂ and ¹³CO₂ and can be applied to gas mixtures or organic materials which have been oxidized to CO₂. The gas mixture is first dried and then passed through two infra-red gas analysers (IRGAs) connected in parallel. The two IRGAs are fitted with different optical filters so they differ in their relative sensitivities to ¹²CO₂ and ¹³CO₂. Once these sensitivities are known then simple algebra allows the concentrations of ¹²CO₂ and ¹³CO₂ to be calculated from the two readings. Two variants of this basic system have been tested. In both, one IRGA was a normal commercial instrument with a narrow band pass interference filter making it highly specific for ¹²CO₂; the second instrument was fitted with either a wide-band pass filter covering both the ¹²CO₂ and ¹³CO₂ absorption bands, or a narrow band pass filter specific for ¹³CO₂. These variations convey different advantages in operation. The wide-band system can be easily calibrated using a single natural abundance ¹²CO₂ standard but is only moderately precise at low abundances. It is particularly valuable for continuous monitoring of the relatively high abundance sources used in plant photosynthesis experiments. The narrow-band system gives high precision but requires a more complex standardization procedure. It is recommended for measurements on low-abundance samples resulting from tracer experiments. Here, its high sensitivity permits measurements on samples as small as 3 μmole C, thus enabling plant fractions and individual metabolites to be investigated. While the wide-band system can be manually operated under field conditions, it is necessary for highest precision to use computerized data collection and linearization. These processes are described, as are novel techniques for standardization, the preparation of small quantities of CO₂ of known abundance, and the transfer of gas samples from oxidizer to analyser. Determinations by the wide band system of % abundance in standard gas mixtures gave a standard error of ±0.03% but this increased to over ±0.1% for abundances below 20%. Corresponding values for the narrow-band system were ±0.01% over the whole abundance range an accuracy almost identical to that observed with an organic mass spectrometer. Two pulse-chase experiment with ¹³CO₂ are described in which the technique was used for studies on growth and metabolism of Lemna minor. The first demonstrated that ¹³C-accumulation within the plants matched closely the predictions from the net assimilation rate and measurements of ¹³C-abundance in the gas phase. The second revealed the rapid changes in the ¹³C-labelling of some plant components during pulse and chase phases. These examples demonstrate the potential of the method for studies in plant physiology and biochemistry. In view of its relative cheapness, ease of maintenance and operation, accuracy, and sensitivity, it is suggested that this new method may encourage a wider use of the safe stable ¹³C for biological and medical applications.     

The aerobic metabolism of 14C-sugars and 14CO2 by the daughter sporocysts of Microphallus similis (JÄG) and Macrophallus pygmaeus (Levinsen) (Digenea: Microphallidae)

The sporocysts of Microphallus similis and M. pygmaeus can aerobically utilise radiosugars and ¹⁴ CO₂in vitro. Both have an EMP pathway, TCA cycle, pentose-phosphate shunt, are able to undergo transamination reactions and can synthesise some essential amino acids. Carbon dioxide fixation involves the carboxylation of phosphoenolpyruvate to form oxaloacetate.     

Elevated CO2 stimulates associative N2 fixation in a C3 plant of the Chesapeake Bay wetland

In this study, the response of N₂ fixation to elevated CO₂ was measured in Scirpus olneyi, a C₃ sedge, and Spartina patens, a C₄ grass, using acetylene reduction assay and ¹⁵N₂ gas feeding. Field plants grown in PVC tubes (25 cm long, 10 cm internal diameter) were used. Exposure to elevated CO₂ significantly (P < 0·05) caused a 35% increase in nitrogenase activity and 73% increase in ¹⁵N incorporated by Scirpus olneyi. In Spartina patens, elevated CO₂ (660 ± 1 μ mol mol ^{− 1}) increased nitrogenase activity and ¹⁵N incorporation by 13 and 23%, respectively. Estimates showed that the rate of N₂ fixation in Scirpus olneyi under elevated CO₂ was 611 ± 75 ng ¹⁵N fixed plant ^{− 1} h ^{− 1} compared with 367 ± 46 ng ¹⁵N fixed plant ^{− 1} h ^{− 1} in ambient CO₂ plants. In Spartina patens, however, the rate of N₂ fixation was 12·5 ± 1·1 versus 9·8 ± 1·3 ng ¹⁵N fixed plant ^{− 1} h ^{− 1} for elevated and ambient CO₂, respectively. Heterotrophic non-symbiotic N₂ fixation in plant-free marsh sediment also increased significantly (P < 0·05) with elevated CO₂. The proportional increase in ¹⁵N₂ fixation correlated with the relative stimulation of photosynthesis, in that N₂ fixation was high in the C₃ plant in which photosynthesis was also high, and lower in the C₄ plant in which photosynthesis was relatively less stimulated by growth in elevated CO₂. These results are consistent with the hypothesis that carbon fixation in C₃ species, stimulated by rising CO₂, is likely to provide additional carbon to endophytic and below-ground microbial processes.     

Manganese application alleviates the water deficit-induced decline of N2 fixation

Water deficit is a very serious constraint on N₂ fixation rates and grain yield of soybean (Glycine max Merr.). Ureides are transported from the nodules and they accumulate in the leaves during soil drying. This accumulation appears responsible for a feedback mechanism on nitrogen fixation, and it is hypothesized to result from a decreased ureide degradation in the leaf. One enzyme involved in the ureide degradation, allantoate amidohydrolase, is manganese (Mn) dependent. As Mn deficiency can occur in soils where soybean is grown, this deficiency may aggravate soybean sensitivity to water deficit. In situ ureide breakdown was measured by incubating soybean leaves in a 5 mol m ^{? 3} allantoic acid solution for 9 h before sampling leaf discs in which remnant ureide was measured over time. In situ ureide breakdown was dramatically decreased in leaves from plants grown without Mn. At the plant level, allantoic acid application in the nutrient solution of hydroponically grown soybean resulted in a higher accumulation of ureide in leaves and lower acetylene reduction activity (ARA) by plants grown with 0 mol m ^{? 3} Mn than those grown with 6·6 mol m ^{? 3} Mn. Those plants grown with 6·6 mol m ^{? 3} Mn in comparison with those grown with 52·8 mol m ^{? 3} Mn had, in turn, higher accumulated ureide and lower ARA. To determine if Mn level also influenced N₂ fixation sensitivity to water deficit, a dry‐down experiment was carried out by slowly dehydrating plants that were grown in soil under four different Mn nutritions. Plants receiving no Mn had the lowest leaf Mn concentration, 11·9 mg kg ^{? 1}, and had N₂ fixation more sensitive to water deficit than plants treated with Mn in which leaf Mn concentration was in the range of 21–33 mg kg ^{? 1}. The highest Mn treatments increased leaf Mn concentration to 37·5 mg kg ^{? 1} and above but did not delay the decline of ARA with soil drying, although these plants showed a significant increase in ARA under well‐watered conditions.     

Modelling O2 and O2 unidirectional fluxes in plants. III: Fitting of experimental data by a simple model

Photosynthetic assimilation of CO₂ in plants results in the balance between the photochemical energy developed by light in chloroplasts, and the consumption of that energy by the oxygenation processes, mainly the photorespiration in C₃ plants. The analysis of classical biological models shows the difficulties to bring to fore the oxygenation rate due to the photorespiration pathway. As for other parameters, the most important key point is the estimation of the electron transport rate (ETR or J), i.e. the flux of biochemical energy, which is shared between the reductive and oxidative cycles of carbon. The only reliable method to quantify the linear electron flux responsible for the production of reductive energy is to directly measure the O₂ evolution by ¹⁸O₂ labelling and mass spectrometry. The hypothesis that the respective rates of reductive and oxidative cycles of carbon are only determined by the kinetic parameters of Rubisco, the respective concentrations of CO₂ and O₂ at the Rubisco site and the available electron transport rate, ultimately leads to propose new expressions of biochemical model equations. The modelling of ¹⁸O₂ and ¹⁶O₂ unidirectional fluxes in plants shows that a simple model can fit the photosynthetic and photorespiration exchanges for a wide range of environmental conditions. Its originality is to express the carboxylation and the oxygenation as a function of external gas concentrations, by the definition of a plant specificity factor Sp that mimics the internal reactions of Rubisco in plants. The difference between the specificity factors of plant (Sp) and of Rubisco (Sr) is directly related to the conductance values to CO₂ transfer between the atmosphere and the Rubisco site. This clearly illustrates that the values and the variation of conductance are much more important, in higher C₃ plants, than the small variations of the Rubisco specificity factor. The simple model systematically expresses the reciprocal variations of carboxylation and oxygenation exchanges illustrated by a “mirror effect”. It explains the protective sink effect of photorespiration, e.g. during water stress. The importance of the CO₂ compensation point, in classical models, is reduced at the benefit of the crossing points Cx and Ox, concentration values where carboxylation and oxygenation are equal or where the gross O₂ uptake is half of the gross O₂ evolution. This concept is useful to illustrate the feedback effects of photorespiration in the atmosphere regulation. The constancy of Sp and of Cx for a great variation of P under several irradiance levels shows that the regulation of the conductance maintains constant the internal CO₂ and the ratio of photorespiration to photosynthesis (PR/P). The maintenance of the ratio PR/P, in conditions of which PR could be reduced and the carboxylation increased, reinforces the hypothesis of a positive role of photorespiration and its involvement in the plant-atmosphere co-evolution.     

Photosynthesis and the influence of CO2-enrichment on δ13C values in a C3 halophyte

Abstract Shifts in ?¹³C of the graminaceous C₃ halophyte Puccinellia nuttalliana (Schultes) Hitch. can be induced by salinization. To investigate this phenomenon, three approaches were taken: assay of carboxylases, CO₂-enrichment studies, and gas exchange analysis. Although ribulose-1,5-bisphosphate carboxylase activity decreased with salinity, phosphoenolpyruvate carboxylase activity did not increase and its levels were not atypical of C₃ plants. When plants were grown at four NaCl concentrations under atmospheres of 310 and 1300 cm³ m^?3 CO₂, the CO₂-enrichment enhanced the effects of salinity on ?¹³C. This is consistent with a biophysical explanation for salt-induced shifts in ?¹³C, whereby there is a steepening of the CO₂ diffusion gradient into the leaf. Gas exchange analysis indicated that intercellular CO₂ concentrations were depressed in the leaves of salt-affected plants. This resulted from a greatly decreased stomatal conductance coupled with only small effects on intrinsic photosynthetic capacity. Water-use efficiency was enhanced.     

Growth responses of the perennial legume Sesbania sesban to NH4 and NO3 nutrition and effects on root nodulation

Preference for NH₄⁺ or NO₃⁻ nutrition by the perennial legume Sesbania sesban (L.) Merr. was assessed by supplying plants with NH₄⁺ and NO₃⁻ alone or mixed at equal concentrations (0.5 mM) in hydroponic culture. In addition, growth responses of S. sesban to NH₄⁺ and NO₃⁻ nutrition and the effects on root nodulation and nutrient and mineral composition of the plant tissues were evaluated in a hydroponic setup at a range of external concentration of NH₄⁺ and NO₃⁻ (0, 0.1, 0.2, 0.5, 2 and 5 mM). Seedlings of S. sesban grew equally well when supplied with either NH₄⁺ or NO₃⁻ alone or mixed and had high relative growth rates (RGRs) ranging between 0.19 and 0.21 d⁻¹. When larger plants of S. sesban were supplied with NH₄⁺ or NO₃⁻ alone, the RGRs and shoot elongation rates were not affected by the external concentration of inorganic N. At external N concentrations up to 0.5 mM nodulation occurred and contributed to the N nutrition through fixation of gaseous N₂ from the atmosphere. For both NH₄⁺ and NO₃⁻-fed plants the N concentration in the plant tissues, particularly water-extractable NO₃⁻, increased at high supply concentrations, and concentrations of mineral cations generally decreased. It is concluded that S. sesban can grow without an external inorganic N supply by fixing atmospheric N₂ gas via root nodules. Also, S. sesban grows well on both NH₄⁺ and NO₃⁻ as the external N source and the plant can tolerate relatively high concentrations of NH₄⁺. This wide ecological amplitude concerning N nutrition makes S. sesban very useful as a N₂-fixing fallow crop in N deficient areas and also a candidate species for use in constructed wetland systems for the treatment of NH₄⁺ rich waters.     

Kinetics of aggregation of αs1 -casein/ca2+ mixtures: charge and temperature effects

Time-dependent light-scattering studies have been made on mixtures of α_s1 -casein and Ca²⁺ at fixed temperature over a range of [Ca²⁺] and [α_s1 -casein], and also as functions of temperature- Measurements were also made of the extent of precipitate formation in the casein/Ca²⁺ mixtures, using centrifugation. The results are analysed in terms of a monomeroctamer equilibrium between calcium caseinate particles followed by a Smoluchowski aggregation in which only the octamers can participate. The equilibrium constant is dependent upon the charge on the protein/Ca²⁺ particles, and hence can be related to the extent of binding of Ca²⁺ to the α_s1 -casein. The Smoluchowski constant is likewise shown to be charge-dependent. The variation of the reaction rate with temperature can be ascribed solely to the changing charge of the α_s1 -casein/Ca²⁺ complex caused by changed binding of Ca²⁺ at different temperatures.     

Different Tolerance to Light Stress in NO3−- and NH4+-Grown Phaseolus vulgaris L.

Abstract: NH₄⁺‐grown plants are more sensitive to light stress than NO₃^?‐grown plants, as indicated by reduced growth and intervenal chlorosis of French bean (Phaseolus vulgaris L.). Measuring the time course of F_v/F_m ratios under photoinhibitory light regimes did not reveal any difference in PS II damage between NO₃^?‐ and NH₄⁺‐grown plants, in spite of some indications of higher energy quenching in NO₃^?‐grown plants. Also, a direct action of NH₄⁺ as an uncoupler at the thylakoid membrane could be excluded. Instead, biochemical analysis revealed enhanced lipid peroxidation and higher activity of scavenging enzymes in NH₄⁺‐grown plants indicating that these plants make use of metabolic pathways with stronger radical formation. Evidence for higher rates of photorespiration in NH₄⁺‐grown plants came from experiments showing that electron flux and O₂ evolution were decreased by SHAM in NH₄⁺‐grown plants, and by antimycin A in NO₃^?‐grown plants. Further, the comparison of electron flux and of photoacoustic measurements of O₂ evolution suggested that in NH₄⁺‐grown plants the Mehler reaction was also increased, at least in the induction phase. However, the major cause of N form‐dependent stress sensitivity is assumed to be in the coupling between photosynthesis and respiration, i.e., NO₃^?‐grown plants can utilize the TCA cycle for the generation of C skeletons for amino acid synthesis, thus improving the ATP: reductant balance, whereas NH₄⁺‐grown plants have enhanced rates of photorespiration.     

Somatic variations on a yellow mutant in Nicotiana tabacum L. (a1+/a1a2+/a2) I. Non-reciprocal genetic events occurring in leaf cells

A greenish-yellow mutant was obtained after treatment of seeds of Nicotiana tabacum L. var. Xanthi n.c. with ethyl methanesulfonate (EMS). Two genetically independent mutations (a₁ and a₂) were isolated. The first mutation (a₁) antagonizes the function of its partially dominant a₁⁺ allele. The second mutation (a₂) is amorphous but strongly interacts with a₁.Among the nine possible genotypes at the two loci, five varied in somatic cells. The heterozygous state a₁⁺/a₁ strongly increased the frequency of both spontaneous and induced variations. However, two homozygotes also showed variations.Variants were isolated from induced and spontaneous non-reciprocal and reciprocal variations within paliside tissues by bud induction in vitro. They were genetically tested. In this first paper, only non-reciprocal variations are reported.Green variants from the greenish-yellow (J¹) dihybrid a₁⁺/a₁a₂⁺/a₂ clone had two genotypes: the first was due to true reversions of a₁ to a₁⁺, whereas the second was due to amorphous a₁⁰ mutations from a₁. These a₁⁰ mutations may well be deletions.The lightest yellow variants from J¹ were due to mutations either from a₁⁺ into a₁ or from a₂⁺ into a₂.Deletions at the a₁⁺?a₁ locus led to either yellow variations when a₁⁺ was lost, or to false reversions when the antagonistic allele a₁ was lost.Amorphous alleles at the a₁⁺?a₁ locus were also isolated from tissues other than J⁺. They gave zygotic lethality (s) that probably varied with the size of the deletions. Thus, true reversions and deletions at the a₁⁺?a₁ locus could be distinguished from one another by progeny tests.Other variants showed higher frequencies of spontaneous variations (instability). Somatic changes observed in these unstable systems were due to modifications at the marker loci. The genetic nature of this instability is not yet known.There is strong evidence that the genetic events involved in these non-reciprocal variations were deletions, conversions and point mutations. True reversions from a₁ into a₁⁺ and new mutations from a₁⁺ into a₁ were obtained only from a₁⁺/a₁. It was therefore supposed that the changes observed took place only in heterozygotes, and the conversion hypothesis was made. Attempts are being made to prove that conversions do exist in higher plants, and to find out if this process, as deletions, is induced by radiation.     

Oxygen limitation of N2 fixation in stem-girdled and nitrate-treated soybean

The effects of increasing rhizosphere pO₂on nitrogenase activity and nodule resistance to O₂diffusion were investigated in soybean plants [Glycine max (L.) Merr. cv. Harosoy 63] in which nitrogenase (EC 1.7.99.2) activities were inhibited by (a) removal of the phloem tissue at the base of the stem (stem girdling), (b) exposure of roots to 10 mM NO₃over 5 days (NO₃-treated), or (c) partial inactivation of nitrogenase activity by an exposure of nodulated roots to 100 kPa O₂(O₂-inhibitcd). In control plants and in plants which had been treated with 100 kPa O₂, increasing rhizosphere O₂concentrations in 10 kPa increments from 20 to 70 kPa did not alter the steady-state nitrogenase activity. In contrast, in plants in which nitrogenase activities were depressed by stem girdling or by exposure to NO₃, increasing rhizosphere pO₂resulted in a recovery of 57 or 67%, respectively, of the initial, depressed rates of nitrogenase activity. This suggests that the nitrogenase activity of stem-girdled and NO₃-treated soybeans was O₂-limited. For each treatment, theoretical resistance values for O₂diffusion into nodules were estimated from measured rates of CO₂exchange, assuming a respiratory quotient of 1.1 and 0 kPa of O₂in the infected cells. At an external partial pressure of 20 kPa O₂, the stem-girdled and NO₃^--treated plants displayed resistance values which were 4 to 8.6 times higher than those in the nodules of the control plants. In control and O₂-inhibited plants, increases in pO₂from 20 to 70 kPa in 10 kPa increments resulted in a 2.5- to 3.9-fold increase in diffusion resistance to O₂, and had little effect on either respiration or nitrogenase activity. In contrast, in stem-girdled and NO₃^--treated plants, increases in external pO₂had little effect on diffusion resistance to O₂, but resulted in a 2.3- to 3.2-fold increase in nodule respiration and nitrogenase activity. These results are consistent with stem-girdling and NO₃^--inhibition treatments limiting phloem supply to nodules causing an increase in diffusion resistance to O₂at 20 kPa and an apparent insensitivity of diffusion resistance to increases in external pO₂.     

RuBPCO kinetics and the mechanism of CO2 entry in C3 plants

Abstract. The CO₂ partial pressure in the chloroplasts of intact photosynthetic C₃ leaves is thought to be less than the intercellular CO₂ partial pressure. The intercellular CO₂ partial pressure can be calculated from CO₂ and H₂O gas exchange measurements, whereas the CO₂ partial pressure in the chloroplasts is unknown. The conductance of CO₂ from the intercellular space to the chloroplast stroma and the CO₂ partial pressure in the chloroplast stroma can be calculated if the properties of photosynthetic gas exchange are compared with the kinetics of the enzyme ribulose 1,5-bisphosphate carboxylase/oxygenase (RuBPCO). A discrepancy between gas exchange and RuBPCO kinetics can be attributed to a deviation of CO₂ partial pressure in the chloroplast stroma from that calculated in the intercellular space. This paper is concerned with the following: estimation of the kinetic constants of RuBPCO and their comparison with the CO₂ compensation concentration; their comparison with differential uptake of ¹⁴CO₂ and ¹²CO₂; and their comparison with O₂ dependence of net CO₂ uptake of photosynthetic leaves. Discrepancy between RuBPCO kinetics and gas exchange was found at a temperature of 12.5 °C, a photosynthetic photon flux density (PPFD) of 550 μmol quanta m^?2 s^?1, and an ambient CO₂ partial pressure of 40 Pa. Consistency between RuBPCO kinetics and gas exchange was found if CO₂ partial pressure was decreased, temperature incresed and PPFD decreased. The results suggest that a discrepancy between RuBPCO kinetics and gas exchange is due to a diffusion resistance for CO₂ across the chloroplast envelope which decreases with increasing temperature. At low CO₂ partial pressure, the diffusion resistance appears to be counterbalanced by active CO₂ (or HCO₃) transport with high affinity and low maximum velocity. At low PPFD, CO₂ partial pressure in the chloroplast stroma appears to be in equilibrium with that in the intercellular space due to low CO₂ flux.     

Emission of nitrous oxide (N2O) from transgenic tobacco expressing antisense NiR mRNA

The emission of N₂ and N₂O from intact transgenic tobacco (clone 271) expressing antisense nitrite reductase (NiR) mRNA, and wild-type plants grown aseptically, on NO₃^–, NO₂^– or NH₄⁺ -containing medium was investigated. ¹⁵N contents of gas sampled from gas-sealed pots, in which the plants were grown on ¹⁵N-containing medium, were analyzed by gas chromato- graphy and mass spectrometry (GC–MS). No emission of N₂ was detected in either of the gas samples from plant clone 271 or the wild-type grown on NO₃^–-containing medium. N₂O emission from clone 271 grown on NO₃^–-containing medium was detected, but not from the wild-type plants. The N₂O emission rate of clone 271 was 106 ng N₂O mg^–1 incorporated N week^–1 and the N₂O emission was inhibited by tungstate (a nitrate reductase inhibitor). No emission of N₂O was found from clone 271 or wild-type plants grown on medium containing NH₄⁺. Emission of N₂O also was detected from clone 271 grown on NO₂^–-containing medium and its emission rate increased with increasing NO₂^– levels in plants. We speculate that NO₃^– is reduced to NO₂^– and that a part of NO₂^– is metabolized to N₂O in clone 271.     

4种金色叶树木对SO2胁迫的生理响应

近年来SO2污染比较严重,它对植物有着多方面的影响。因此,越来越多的学者开始关注这方面的问题。彩叶植物在丰富园林景观及降低环境污染方面占用重要的地位,它们也被认为是净化城市空气最有效的途径之一。旨在阐明4种彩叶树种耐SO2污染机制,对丰富植物耐SO2研究的理论、科学评价植物抗SO2污染能力以及指导园林绿化科学选择树种等具有重要理论和现实意义。研究采用人工模拟熏气的方法对金叶女贞、金叶莸、金叶风箱果和金叶红瑞木4种金色叶树种的2年生苗木进行不同浓度的SO2胁迫,研究了参试树种的外观受害症状及膜脂过氧化、渗透调节物质、保护酶活性等生理指标对SO2的反应,并采用模糊数学隶属函数法和灰色关联度法对其抗SO2能力进行了综合评价。结果表明:4种金色叶植物对SO2均具有一定的净化能力,表现为随着SO2浓度的增加膜透性增大,丙二醛、脯氨酸、可溶性糖和硫含量增加,超氧化物歧化酶、过氧化物酶以及过氧化氢酶活性上升,叶绿素含量先增后降,叶液pH值下降。但4种金色叶树木对SO2的净化能力有差别,其中金叶红瑞木的净化能力强最大,金叶女贞和金叶风箱果的净化能力为中等,而金叶莸的净化能力最差。这与其含硫量的顺序一致,却与其对SO2的抗性大小即金叶女贞>金叶莸>金叶红瑞木>金叶风箱果完全不同,说明这四种植物对SO2的吸收能力与其对该气体的抗性不完全一致。但这不能表明抗性差的树种在兰州地区不能应用,因为,兰州市空气中的SO2实际污染程度与研究所设置的最低浓度相比仍属安全浓度。在所选的10个指标中,丙二醛含量、细胞膜透性、超氧化物歧化酶活性、过氧化氢酶活性、脯氨酸、过氧化物酶活性、叶绿素和可溶性糖等指标均可作为金色叶植物对SO2抗性的重要鉴定指标,而S含量和叶液pH值在评价植物对SO2抗性能力时并不具有重要性。4种植物的受害程度与其SO2抗性相反,说明受害症状可以作为判断其对SO2抗性大小依据。     

Responses of Gmelina arborea, a tropical deciduous tree species, to elevated atmospheric CO2: Growth, biomass productivity and carbon sequestration efficacy

The photosynthetic response of trees to rising CO₂ concentrations largely depends on source-sink relations, in addition to differences in responsiveness by species, genotype, and functional group. Previous studies on elevated CO₂ responses in trees have either doubled the gas concentration (>700 μmol mol⁻¹) or used single large addition of CO₂ (500-600 μmol mol⁻¹). In this study, Gmelina arborea, a fast growing tropical deciduous tree species, was selected to determine the photosynthetic efficiency, growth response and overall source-sink relations under near elevated atmospheric CO₂ concentration (460 μmol mol⁻¹). Net photosynthetic rate of Gmelina was ∼30% higher in plants grown in elevated CO₂ compared with ambient CO₂-grown plants. The elevated CO₂ concentration also had significant effect on photochemical and biochemical capacities evidenced by changes in F_V/F_M, ABS/CSm, ET₀/CSm and RuBPcase activity. The study also revealed that elevated CO₂ conditions significantly increased absolute growth rate, above ground biomass and carbon sequestration potential in Gmelina which sequestered ∼2100 g tree⁻¹ carbon after 120 days of treatment when compared to ambient CO₂-grown plants. Our data indicate that young Gmelina could accumulate significant biomass and escape acclimatory down-regulation of photosynthesis due to high source-sink capacity even with an increase of 100 μmol mol⁻¹ CO₂.     

Photosynthesis of submersed macrophytes in acidified lakes II. Carbon limitation and utilization of benthic CO2 sources

Photosynthetic characteristics of carbon-dioxide limitations were analyzed for leaf tissue in a Cartesian-diver system, in which irradiance could be stringently controlled, and with whole plants in electrode macrosystems for submerged macrophytes (Juncus bulbosus L., Sphagnum auriculatum Schimp. var. inundatum (Russow) M. O. Hill) and other benthic moss and algae (Drepanocladus, Batrachospermum, and an algal mat) from acidified lakes. Light compensation points were extremely low for Juncus (1.5–6 μE m^?2 s^?1) and Sphagnum (3–10), and higher for shallow-inhabiting Batrachospermum (22–33). Leaf tissue, whole plants, and algal populations were rapidly limited by CO₂ availability under closed submersed, acidified conditions (pH 4–6).Controlled and in situ experiments were performed, in which the rooting tissue of Juncus bulbosus was partitioned from the leaves and the rates of photosynthetic carbon fixation of the foliage, utilizing dissolved inorganic ¹⁴C-carbon from the water, were analyzed under different conditions of CO₂ enhancement in the rhizosphere of the sediments. Results demonstrated that: (a) from 25 to 40% of the carbon fixed in the leaves can originate from the rhizosphere, diffuse to the leaves via internal gas lacunae, and be fixed photosynthetically; (b) photosynthetic utilization of CO₂ from the water surrounding the leaves is reduced markedly when the CO₂ concentration of the rhizosphere was increased by direct additions of CO₂, bacteria, or organic compounds (glucose, acetate) that stimulate bacterial growth. Shifts to predominance of submersed benthic primary producers with low light compensation points and adapted to acidified lakes are related in part to circumvention of carbon limitation in the water by utilization of enhanced CO₂ availability in the rhizosphere and at the sediment—water interface from bacterial degradation of organic matter, and in part to physiological mechanisms that conserve and recycle CO₂ of respiration and photorespiration.     

14CO2 dark fixation in the halophytic species mesembryanthemum crystallinum

The time course of ¹⁴CO₂ dark fixation was studied in leaves of the facultatively halophytic plant species Mesembryanthemum crystallinum cultivated with and without 400 mM NaCl in the nutrient medium. It is generally known from the literature that plants grown under saline conditions incorporate ¹⁴C predominately into amino acids. By contrast in leaves of M. crystallinum grown on NaCl and exposed to ¹⁴CO₂ in the dark, relatively more radioactivity is incorporated in the organic acids (especially malate) than in amino acids. The data obtained are discussed in relation to the NaCl induced Crassulacean acid metabolism in M. crystallinum reported earlier.