The role of phosphorus in nitrogen fixation by young pea plants (Pisum sativum)

The influence of P on N₂ fixation and dry matter production of young pea ( Pisum sativum L. cv. Bodil) plants grown in a soil-sand mixture was investigated in growth cabinet experiments. Nodule dry weight, specific C₂H₂ reduction and P concentration in shoots responded to P addition before any growth response could be observed. The P concentration in nodules responded only slightly to P addition. A supply of P to P-deficient plants increased both the nodule dry weight, specific C₂H₂ reduction and P concentration in shoots relatively faster than it increased shoot dry weight and P concentration in nodules. Combined N applied to plants when N₂ fixation had commenced, increased shoot dry weight only at the highest P levels. This indicates that the smaller plant growth at the low P levels did not result from N deficiency. The reduced nodulation and N₂ fixation in P-deficient plants seem to be caused by impaired shoot metabolism and not by a direct effect of P deficiency of the nodules.     

Chloroplasts in envelopes: CO2 fixation by fully functional intact chloroplasts

Dan Arnon, Bob Whatley, Mary Belle Allen, and their colleagues, were the first to obtain evidence for `complete photosynthesis by isolated chloroplasts' albeit at rates which were 1% or less of those displayed by the intact leaf. By the 1960s, partly in the hope of confirming full functionality, there was a perceived need to raise these rates to the same order of magnitude as those displayed by the parent tissue. A nominal figure of 100 μmol/mgċchlorophyll/h (CO₂ assimilated or O₂ evolved) became a target much sought after. This article describes the contributions that Dick Jensen and Al Bassham [(1966) Proc Natl Acad Sci USA 56: 1095–1101], and my colleagues and I, made to the achievement of this goal and the way in which it led to a better understanding of the role of inorganic phosphate in its relation to the movement of metabolites across chloroplast envelopes. This revised version was published online in August 2006 with corrections to the Cover Date.     

Inhibition of CO2 fixation in intact spinach chloroplasts by 3-phosphoglyceric acid

Glycerate-3-P inhibits CO₂ fixation of isolated spinach chloroplats at concentrations higher than 1 mM but does not inhibit O₂ evolution. Glycerate-3-P inhibition of photosynthesis is not overcome by higher bicarbonate concentrations.     

Disruption of male meiosis in the pea Pisum sativum L., caused by ms3 mutation

Analysis of morphological phenotype of meimutation ms3 in Pisum sativum was made at the light microscopic level with vizualization of MT cytoskeletal structures. This mutation disrupts simultaneously the chromosome cycle, nuclear envelope breakdown, and MT cytoskeleton cycle during meiosis in pollen mother cells.     

Free air CO2 enrichment (FACE) improves water use efficiency and moderates drought effect on N2 fixation of Pisum sativum L.

Plant and Soil - Soil water deficits have presented challenges to vegetation restoration in rocky desertification areas. In the field, small volumes of soil resources are present only in...     

Characterization of abscisic acid in chloroplasts of Pisum sativum L. cv. Alaska by combined gas-chromatography-mass spectrometry

Summary Abscisic acid was characterized from extracts of isolated pea chloroplasts by combined gas-chromatography-mass spectrometry. By single ion monitoring of the base peak (m/e 190) in the mass spectrum, 8.6 g ABA were detected in chloroplasts isolated from 1 kg fresh weight of pea shoots.GC-MS combined gas chromatography-mass spectrometry     

Atmospheric CO(2) and mycorrhiza effects on biomass allocation and nutrient uptake of nodulated pea (Pisum sativum L.) plants

The effect of ambient and elevated atmospheric CO(2) on biomass partitioning and nutrient uptake of mycorrhizal and non-mycorrhizal pea plants grown in pots in a controlled environment was studied. The hypothesis tested was that mycorrhizae would increase C assimilation by increasing photosynthetic rates and reduce below-ground biomass allocation by improving nutrient uptake. This effect was expected to be more pronounced at elevated CO(2) where plant C supply and nutrient demand would be increased. The results showed that mycorrhizae did not interact with atmospheric CO(2) concentration in the variables measured. Mycorrhizae did not affect photosynthetic rates, had no effect on root weight or root length density and almost no effect on nutrient uptake, but still significantly increased shoot weight and reduced root/shoot ratio at harvest. Elevated CO(2) increased photosynthetic rates with no evidence for down-regulation, increased shoot weight and nutrient uptake, had no effect on root weight, and actually reduced root/shoot ratio at harvest. Non-mycorrhizal plants growing at both CO(2) concentrations had lower shoot weight than mycorrhizal plants with similar nutritional status and photosynthetic rates. It is suggested that the positive effect of mycorrhizal inoculation was caused by an enhanced C supply and C use in mycorrhizal plants than in non-mycorrhizal plants. The results indicate that plant growth was not limited by mineral nutrients, but partially source and sink limited for carbon. Mycorrhizal inoculation and elevated CO(2) might have removed such limitations and their effects on above-ground biomass were independent, positive and additive.     

Requirements for the light-stimulated degradation of stromal proteins in isolated pea (Pisum sativum L.) chloroplasts

Chloroplasts from 17-d-old pea leaves (Pisum sativum L.) wereisolated to elucidate the requirements for the light-induceddegradation of stromal proteins. The influence of electron transportthrough the thylakoids and the influence of ATP on protein degradationwere investigated. When chloroplasts were incubated in the light(45 µmol m^–2s^–1), glutamine synthetase, thelarge subunit of ribulose-1,5-bisphosphate carboxylase and glutamatesynthase were degraded, whereas phosphoribulokinase, ferredoxin-NADP⁺reductase and the 33 kDa protein of photosystem II remainedmore stable. Major protein degradation was not observed over240 mm in darkness. The electron transport inhibitor dichlorophenyldimethylureareduced protein degradation in the light over several hours,whereas dibromothymoquinone was less effective. Inhibiting theproduction of ATP with tentoxin or by destroying the     

Promotion of stem elongation by indole-3-butyric acid in intact plants of Pisum sativum L.

While indole-3-butyric acid (IBA) has been confirmed to be an endogenous form of auxin in peas, and may occur in the shoot tip in a level higher than that of indole-3-acetic acid (IAA), the physiological significance of IBA in plants remains unclear. Recent evidence suggests that endogenous IAA may play an important role in controlling stem elongation in peas. To analyze the potential contribution of IBA to stem growth we determined the effectiveness of exogenous IBA in stimulating stem elongation in intact light-grown pea seedlings. Aqueous IBA, directly applied to the growing internodes via a cotton wick, was found to be nearly as effective as IAA in inducing stem elongation, even though the action of IBA appeared to be slower than that of IAA. Apically applied IBA was able to stimulate elongation of the subtending internodes, indicating that IBA is transported downwards in the stem tissue. The profiles of growth kinetics and distribution suggest that the basipetal transport of IBA in the intact plant stem is slower than that of IAA. Following withdrawal of an application, the residual effect of IBA in growth stimulation was markedly stronger than that of IAA, which may support the notion that IBA conjugates can be a better source of free auxin through hydrolysis than IAA conjugates. It is suggested that IBA may serve as a physiologically active form of auxin in contributing to stem elongation in intact plants.     

Plant Lectins Induce the Production of a Phytoalexin in Pisum sativum

The effects of several plant lectins on the production of apea phytoalexin, pisatin, were examined. Con A, PHA, PNA andPSA each induced the production of pisatin in pea epicotyl tissues,demonstrating that plant lectins can act as elicitors. The productionof pisatin in response to PHA, PNA or PSA was not affected bythe simultaneous presence of the respective hapten sugars, whereashaptens specific for Con A, such as -D-mannose and methyl--D-mannoside,abolished the induction of pisatin by Con A. These results indicatethat the elicitor effect of Con A is attributable to its abilityto bind to specific carbohydrates in pea cells. Induction ofthe production of pisatin by Con A was markedly inhibited bythe suppressor derived from a pea pathogen, Mycosphaerella pinodes,and by several inhibitors related to signal-transduction pathways.It is suggested, therefore, that the Con A-induced productionof pisatin in pea tissues might be associated with activationof a signal-transduction pathway. An additive effect on theaccumulation of pisatin was observed when Con A was presentwith a polysaccharide elicitor from M. pinodes, suggesting thatexogenous Con A does not compete with the recognition site(s)for the fungal elicitor in pea cells. The present data alsoindicate that Con A may be useful for characterization of thesignal-transduction system that leads to the synthesis of phytoalexinin pea epicotyl tissues. (Received November 16, 1994; Accepted April 20, 1995)     

CO2 reduction by intact chloroplasts under a diminished proton gradient.

9-Aminoacridine has been used to monitor the intrathylakoid pH of photosynthetically competent intact chloroplasts. Values obtained from 9-aminoacridine accumulation in the chloroplasts must be corrected for light-dependent binding of 9-aminoacridine to the thylakoid membranes. During nitrite reduction by intact chloroplasts, the intrathylakoid proton concentration increased. It decreased somewhat during CO2 reduction. However, low concentrations of uncoupling amines such as NH3 or cyclohexylamine, which rapidly penetrated the chloroplast envelope and decreased the intrathylakoid proton concentration, failed to reduce, and actually stimulated, rates of CO2-dependent oxygen evolution even under rate-limiting light. In contrast, low concentrations of carbonyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP) OR NIGERICIN, WHICH INHIBITED CO2 reduction, even appeared to increase the intrathylakoid proton concentration. As indicated by measurements of the 515 nm signal of the chloroplasts, the light-induced membrane potential was not much affected by low concentrations of the uncoupling amines, but was decreased by FCCP and by high concentrations of the amines. Even in the presence of high concentrations of NH4C1, ATP/ADP ratios of illuminated chloroplasts remained far above the ratios observed in the dark. In contrast, low concentrations of FCCP were sufficient to reduce ATP/ADP ratios to the dark value even under high intensity illumination. The observations are difficult to explain within the framework of the chemiosmotic hypothesis as presently discussed.