Photosynthesis in the Higher Plant, Vicia faba: III. Serine, a Precursor of the Tricarboxylic Acid Cycle

Evidence is presented to support the hypothesis that serine, rather than 3-phosphoglycerate of the Calvin cycle, is a precursor of the tricarboxylic acid cycle during photosynthesis by the higher plant, Vicia faba. Identification of the serine intermediate is based upon a unique C₁ > C₂ > C₃ isotope distribution for that metabolite following the fixation of ¹⁴CO₂. This labeling pattern, while incompatible with an origin either in the Calvin cycle or the glycolate pathway, satisfies a critical criterion for the 3-carbon precursor of the anomalously labeled organic acids. The predominant carboxyl carbon atom labeling of serine reflects either a mixing of two pools of that metabolite, ie., C₁ = C₂ > C₃ and C₁ > C₂ = C₃, or a higher order of complexity in its synthesis. An anomalous C₁ = C₂ > C₃ < C₄ distribution for aspartate, however, suggests an origin by the carboxylation of a 3-carbon intermediate related to serine which has a C₁ = C₂ > C₃ distribution. The latter distribution has been proposed for the serine intermediate of the postulated formate pathway. This pathway is described by the generalized metabolic sequence: CO₂ → formate → serine → organic acids. Corresponding carbon atom distributions for citrate (C₁ > C₂), aspartate (C₂ > C₃), and serine (C₂ > C₃) belie a precursor-product relationship with alanine (C₂ = C₃), which is a molecular parameter of the Calvin cycle product, 3-phosphoglycerate.     

Photosynthesis in Rhodospirillum rubrum. III. Metabolic Control of Reductive Pentose Phosphate and Tricarboxylic Acid Cycle Enzymes

Enzymes of the reductive pentose phosphate cycle including ribulose-diphosphate carboxylase, ribulose-5-phosphate kinase, ribose-5-phosphate isomerase, aldolase, glyceraldehyde-3-phosphate dehydrogenase and alkaline fructose-1,6-diphos-phatase were shown to be present in autotrophically grown Rhodospirillum rubrum. Enzyme levels were measured in this organism grown photo- and dark heterotrophically as well. Several, but not all, of these enzymes appeared to be under metabolic control, mediated by exogenous carbon and nitrogen compounds. Light had no effect on the presence or levels of any of these enzymes in this photosynthetic bacterium.

The enzymes of the tricarboxylic acid cycle and enolase were shown to be present in R. rubrum cultured aerobically, autotrophically, or photoheterotrophically, both in cultures evolving hydrogen and under conditions where hydrogen evolution is not observed. Light had no clearly demonstrable effect on the presence or levels of any of these enzymes.

     

Effects of Light and Inhibitors on Glutamate Metabolism in Leaf Discs of Vicia faba L: Sources of ATP for Glutamine Synthesis and Photoregulation of Tricarboxylic Acid Cycle Metabolism

Metabolism of [¹⁴C]glutamate was studied in leaf discs of Vicia faba L. in light and in darkness. In white light glutamine was the main labeled product. In the dark label was principally in compounds closely associated with tricarboxylic acid cycle metabolism, predominantly aspartate. Entry of label from glutamate into tricarboxylic acid metabolism appeared to be at least partially by decarboxylation of glutamate to γ-amino butyric acid, followed by conversion to succinate. 3-(3,4-dichlorophenyl)-1, 1-Dimethylurea inhibited light-enhanced synthesis of glutamine and caused reversion toward the dark pattern of metabolism. Methionine sulfoximine severely inhibited glutamine synthesis and caused accumulation of labeled malate.     

On the Metabolic Relationship between the Calvin Cycle and the Tricarboxylic Acid Cycle: IV. A Plant Survey for Anomalous Acetyl Coenzyme A

Leaves of 10 randomly selected plants representing eight dicotyledonous families were exposed to ¹⁴CO₂ for a 10-minute period in the light. Citrate and alanine were isolated, purified isotopically, and degraded to obtain the ¹⁴C-isotope distribution of corresponding carbon atoms, i.e. citrate (C-1,2) and alanine (C-2,3). The cited carbon atoms of alanine were equally labeled as is typical of a 3-carbon intermediate derived from photosynthetic 3-phosphoglycerate. The carbon atoms of citrate, equivalent to acetyl-CoA, were unequally labeled. The citrate (C-1,2) isotope ratio ranged from 1.20 to 1.78 for the various plants compared to a ratio of unity in the uniformly labeled control. The results infer that 3-phosphoglycerate produced in the chloroplast is not the singular precursor of mitochondrial citrate.     

Para-nitrophenyl Phosphate as a Substrate for Some Acid Phosphatases in Roots of Vicia faba

A cytochemical and biochemical study of acid phosphatases inroots of Vicia faba using p-nitrophenylphosphate(p-NPP) as substratehas shown the lack of specificity of the substrate which canbe acted upon by a K⁺-activated acyl phosphatase, nucleotidepyrophosphatase, glucox-6-phosphatase, 5' (3')-ribonucleotidephosphohydrolase, nucleotide phosph-transferase and those acidphosphatases demonstrable with ß-glycerophosphate.It is suggested that care should be taken in the interpretationof both biochemical and cytochemical studies employing sucha non-specific substrate as P-NPP. Vicia faba, broad bean, root, acid phosphatases     

Biosynthesis of Glutamic Acid in Saccharomyces: Accumulation of Tricarboxylic Acid Cycle Intermediates in a Glutamate Auxotroph

Aconitaseless glutamic acid auxotroph MO-1-9B of Saccharomyces grew in glutamic acid-supplemented minimal medium, but failed to grow when glutamic acid was substituted by proline, arginine, ornithine, or glutamine. This mutant was also unable to utilize lactate or glycerol as a carbon source. Under a glutamic acid-limiting condition, by using acetate-1-(14)C as tracer, the mutant accumulated rather large amounts of (14)C-citric acid and (14)C-succinic acid when compared with the wild-type strain. Under excess glutamic acid supplementation, accumulation of citric acid and succinic acid was considerably reduced. When (14)C-glutamic acid-(U) was used as tracer, (14)C-alpha-ketoglutaric acid, (14)C-citric acid, and (14)C-succinic acid were accumulated in the mutant. The citric acid peak was the largest, followed by alpha-ketoglutaric acid and succinic acid. In the wild-type strain under similar conditions, only small amounts of (14)C-citric acid and (14)C-succinic acid and no (14)C-alpha-ketoglutaric acid were accumulated.     

Plant age and the inducibility of extrafloral nectaries in Vicia faba

Insect herbivory imposes a strong selection pressure on plants. As a result, plants have evolved a wide array of defences, including resistance traits that help them reduce the negative impact of herbivores. Along one axis of variation, these traits can be divided into direct resistance (physical and chemical defences) and indirect resistance (the recruitment of natural enemies of the herbivore via extrafloral nectar and other incentives). Along a second axis of variation, resistance can be split into constitutive resistance, which is always present, and induced resistance, which is expressed more strongly following damage to plant tissues. Interestingly, the strength and efficacy of all of constitutive-direct, constitutive-indirect, induced-direct, and induced-indirect resistance can vary with plant age and ontological stage. Here, we examine the effect of plant age on an induced-indirect resistance trait, the deployment of extrafloral nectaries (EFNs) to attract pugnacious ants, in a short-lived annual, broad bean (Vicia faba L.). We demonstrate that in severely damaged plants, the induction of EFNs is greater in older plants (5?C6?weeks) than in younger plants (2?C4?weeks); however, in more moderately damaged plants, the induction of EFNs is unaffected by plant age. This suggests the hypothesis that a plant??s ability to induce extrafloral nectar, and therefore recruit more ant ??bodyguards,?? may be related to the interaction of plant age and severity of damage.     

Changes in the Duration of the Mitotic Cycle Induced by Colchicine and Indol-3yl-acetic Acid in Vicia faba Roots

Cells of root meristems of Vicia faba were labelled with tritiatedthymidine and treated with colchicine or IAA or both. The effectsof these compounds on the duration of the mitotic cycle andits constituent phases have been determined using the labelledmitoses wave method of Quastler and Sherman. Colchicine shortensthe mitotic cycle of the cells in interphase at the time oftreatment; it appears to stimulate cells in G1 or early S tocomplete interphase faster than untreated cells. The affectedcells arrive at mitosis 9–12 h after the beginning oftreatment and contribute to the increase in mitotic index seenafter treatment with colchicine. Treatment with IAA did notaffect cells in G2 but it delayed cells in S; this results ina temporary fall in M.I. The effect of IAA in prolonging interphasewas also seen in roots treated with colchicine and IAA; thetetraploid cells induced by colchicine take longer to reachmetaphase than cells treated only with colchicine. The resultssuggest that colchicine and IAA affect different phases of thecell cycle.     

Sporulation of Bacillus thuringiensis Without Concurrent Derepression of the Tricarboxylic Acid Cycle

Bacillus thuringiensis sporulates in a glucose-glutamate medium without concurrent derepression of the tricarboxylic acid cycle. Glutamate appears to regulate tricarboxylic acid cycle activity as well as to influence spore heat resistance and production of dipicolinic acid.     

Role of Potassium in Stomatal Opening in the Leaf of Vicia faba

With isolated epidermal strips of Vicia faba, the intensity of potassium-staining in the guard cells of stomata was calibrated against the uptake of radioactively labeled potassium. By using this calibration, the quantity of potassium that had accumulated in the guard cells, as stomata of leaves of Vicia open in the light, was estimated. Results support the hypothesis that in leaves, as well as in isolated epidermal strips, potassium and an accompanying anion comprise the major, osmotically active solutes in the guard cells of open stomata.     

The Effect of Anaerobiosis on Acids of the Tricarboxylic Acid Cycle in Peas

Maturing seeds of the pea (Pisum sativum) were subjected to24 hours' anaerobiosis and then returned to air. Carbon-dioxideevolution was estimated. At intervals samples were analysedfor their content of organic acids by silica gel and paper chromatographyand for bound carbon dioxide. During the anaerobic period there was a large accumulation oflactate, an initial increase of succinate, and a slow, continuingdecrease of malate and citrate. On return to air the main changes were a fall in the concentrationof lactate and succinate, a rise in malate and acetate, anda rapid rise followed by a fall of pyruvate and -oxo-glutarate. Comparison of these changes with each other and with the rateof production of carbon dioxide shows that they do not fit apattern based on the tricarboxylic acid cycle. The possibilitythat this was the result of a system of ‘pools’of these acids is considered.     

Anaplerotic Accumulation of Tricarboxylic Acid Cycle Intermediates as Well as Changes in Other Key Metabolites During Heterotopic Ossification

Heterotopic ossification (HO) is the de novo formation of bone that occurs in soft tissue, through recruitment, expansion, and differentiation of multiple cells types including transient brown adipocytes, osteoblasts, chondrocytes, mast cells, and platelets to name a few. Much evidence is accumulating that suggests changes in metabolism may be required to accomplish this bone formation. Recent work using a mouse model of heterotopic bone formation reliant on delivery of adenovirus‐transduced cells expressing low levels of BMP2 showed the immediate expansion of a unique brown adipocyte‐like cell. These cells are undergoing robust uncoupled oxidative phosphorylation to a level such that oxygen in the microenvironment is dramatically lowered creating areas of hypoxia. It is unclear how these oxygen changes ultimately affect metabolism and bone formation. To identify the processes and changes occurring over the course of bone formation, HO was established in the mice, and tissues isolated at early and late times were subjected to a global metabolomic screen. Results show that there are significant changes in both glucose levels, as well as TCA cycle intermediates. Additionally, metabolites necessary for oxidation of stored lipids were also found to be significantly elevated. The complete results of this screen are presented here, and provide a unique picture of the metabolic changes occurring during heterotopic bone formation. J. Cell. Biochem. 117: 1044–1053, 2016. © 2015 The Authors. Journal of Cellular Biochemistry Published by Wiley Periodicals, Inc.     

Nonfunctional Tricarboxylic Acid Cycle and the Mechanism of Glutamate Biosynthesis in Acetobacter suboxydans

Acetobacter suboxydans does not contain an active tricarboxylic acid cycle, yet two pathways have been suggested for glutamate synthesis from acetate catalyzed by cell extracts: a partial tricarboxylic acid cycle following an initial condensation of oxalacetate and acetyl coenzyme A. and the citramalate-mesaconate pathway following an initial condensation of pyruvate and acetyl coenzyme A. To determine which pathway functions in growing cells, acetate-1-(14)C was added to a culture growing in minimal medium. After growth had ceased, cells were recovered and fractionated. Radioactive glutamate was isolated from the cellular protein fraction, and the position of the radioactive label was determined. Decarboxylation of the C5 carbon removed 100% of the radioactivity found in the purified glutamate fraction. These experiments establish that growing cells synthesize glutamate via a partial tricarboxylic acid cycle. Aspartate isolated from these hydrolysates was not radioactive, thus providing further evidence for the lack of a complete tricarboxylic acid cycle. When cell extracts were analyzed, activity of all tricarboxylic acid cycle enzymes, except succinate dehydrogenase, was demonstrated.     

Isolate 761M: a New Type I Methanotroph That Possesses a Complete Tricarboxylic Acid Cycle

A methanotrophic bacterium, isolate 761M, grows slowly with methane as the sole carbon and energy source. Growth was stimulated by peptone, casein hydrolysate, glucose, and acetate plus malate. Sugars other than glucose did not stimulate growth. Growth yields, based on the amount of methane consumed, increased when other carbon sources were present, and less methane carbon was assimilated under these conditions. Methane was obligately required for growth of isolate 761M. This bacterium does not grow on rich media. Isolate 761M was found to possess hexulose phosphate synthase and intracytoplasmic membranes characteristic of other type I methanotrophs. Unlike other type I methanotrophs, this bacterium possessed alpha-ketoglutarate dehydrogenase and oxidized [2-¹⁴C]acetate to carbon dioxide.     

Photosynthesis by Guard Cell Chloroplasts of Vicia faba L.: Effects of Factors Associated with Stomatal Movement

The properties of photosynthetic O₂ evolution by mesophyll cellchloroplasts (MCC) and guard cell chloroplasts (GCC) isolatedfrom protoplasts of Vicia faba L. have been studied and effectson O₂ evolution of factors known to regulate stomatal movementshave been compared. The O₂ evolution of GCC was CO₂-dependent.The saturating light intensity for O₂ evolution was between150 and 200 µmol m^–2s^–1 for MCC and was between400 and 1,000µmol m^–2s^–1 for GCC. Light quality(red vs. blue) had no significant effect on O₂ evolution byeither MCC or GCC. The O₂ evolution rate of MCC was stronglydependent on external K⁺ concentration, but GCC did not respondsignificantly to variations in external K⁺ concentration between0 and 250 mM. The optimal external pH for O₂ evolution by MCCwas approximately 7.5, and either higher or lower external pHsignificantly inhibited O₂ evolution. However, O₂ evolutionby GCC was only slightly enhanced when external pH was increasedfrom 6.0 to 8.0. Our observation of differential sensitivityof MCC and GCC to light intensity and to variations of cytoplasmicK⁺ and pH may indicate differential regulation of photosynthesisin MCC and GCC. ¹Current address: Biology Department, Pennsylvania State University,208 Mueller Laboratory, University Park, PA 16802, U.S.A.     

Plant and soil resistance to water flow in faba bean (Vicia faba L. major Harz.)

An experiment was conducted to determine soil and plant resistance to water flow in faba bean under field conditions during the growing season. During each sampling period transpiration flux and leaf water potential measured hourly were used with daily measurements of root and soil water potential to calculate total resistance using Ohm's law analogy. Plant growth, root density and soil water content distributions with depth were measured. Leaf area and root length per plant reached their maximum value during flowering and pod setting (0.31 m² and 2200 m, respectively), then decreasing until the end of the growing period. Root distribution decreased with depth ranging, on average, between 34.2% (in the 0–0.25 m soil layer) and 18.1% (in the 0.75–1.0 m soil layer). Mean root diameter was 0.6 mm but most of the roots were less than 0.7 mm in diameter. Changes in plant and soil water potentials reflected plant growth characteristics and climatic patterns. The overall relationship between the difference in water potential between soil and leaf and transpiration was linear, with the slope equal to average plant resistance (0.0165 MPa/(cm³ m^-1 h^-1 10^-3). Different regression parameters were obtained for the various measurement days. The water potential difference was inversely related to transpiration at high leaf stomatal resistance and at high values of VPD. Total resistance decreased with transpiration flux in a linear relationship (r=−0.68). Different slope values were obtained for the different measurement days. Estimated soil resistance was much lower than the observed total resistance to water flow. The change from vegetative growth to pod filling was accompanied by an increase in plant resistance. The experimental results support previous findings that resistance to water flow through plants is not constant but is influenced by plant age, growth stage and environmental conditions. A more complex model than Ohm's law analogy may be necessary for describing the dynamic flow system under field conditions. This revised version was published online in June 2006 with corrections to the Cover Date.     

Disruption of Microtubules by Abscisic Acid in Guard Cells of Vicia faba L.

ABA disrupted cortical microtubules in guard cells, but notin epidermal cells, with concomitant closure of stomata. Otherplant growth regulators did not disrupt the microtubles in guardcells. Thus disrution of microtubules seems to be a specificeffect of ABA in guard cells but its physiological significanceremains obscure. (Received September 11, 1995; Accepted April 26, 1996)