Photoassimilation of Glycolate, Glycine and Serine by Euglena gracilis

SYNOPSIS. Glycolate was readily utilized for growth by Euglena gracilis , strain Z, in the light at pH 3.8 under a variety of atmospheric conditions, including CO₂-free air and nitrogen. Glycolate did not support growth in the dark as sole carbon source; no significant uptake of glycolate was observed under these conditions. However, cells grown in the light with glycolate as sole carbon source were still capable of glycolate uptake for up to 3 hr after transfer to darkness, and glycolate was taken up by cells utilizing glucose in the dark. The energy requirement for glycolate utilization could thus be met either by light, or by the aerobic metabolism of glucose in the dark. DCMU, an inhibitor of photosystem II, inhibited photoassimilation of glycolate. In the light, but again not in the dark, glycine and serine also served as sole source of carbon under CO₂-free air, but not under nitrogen. Net release of ammonia to the medium accompanied the photoassimilation of glycine and serine. Of the several metabolicallyrelated compounds tested, only glycolate was utilized as sole carbon source in the light under "anaerobic" conditions. A lag in net chlorophyll synthesis occurred during the photoassimilation of glycolate glycine or serine. Determination of rates of photosynthetic ¹⁴CO₂ fixation confirmed that some inhibition of photosynthetic capacity had occurred in response to utilization of glycolate and related compounds.     

植物中草酸积累与光呼吸乙醇酸代谢的关系

对几种C3 和C4 植物中草酸含量及相应的乙醇酸氧化酶活性测定结果表明 :叶片光呼吸强度及其关键酶活性大小与草酸积累量没有相关性 ;植物根中均能积累草酸 ,但未测出乙醇酸氧化酶活性。烟草根、叶中的草酸含量在不同生长时期差异明显 ,且二者呈极显著正相关 (y =2 .5 6 5lnx 2 .137,r =0 .749,P <0 .0 0 1) ,说明根中草酸可能来自叶片。氧化乙醇酸的酶的活性与氧化乙醛酸的酶的活性呈极显著线性正相关 (y =0 .2 41x 0 .0 0 6 ,r=0 .96 7,P <0 .0 0 0 1) ,进一步证实是乙醇酸氧化酶催化了两种底物的反应。烟草在不同生长期叶片中草酸总含量变化与相应的乙醇酸氧化酶活性变化亦没有相关性 ;低磷胁迫可显著诱导烟草根叶中的草酸形成和分泌 ,但并未影响乙醇酸氧化酶活性 ,进一步证明草酸积累与该酶活性大小无关     

Irreversible Plastid Loss in Euglena gracilis under Physiological Conditions

Irreversible loss of the ability to develop chloroplasts in Euglena gracilis may develop following transfer from organic medium to defined medium. Requirements for the loss include the absence of light and a temperature of 30 C (the optimal temperature for multiplication) although neither darkness alone nor this temperature alone serves as the bleaching agent. The extent of bleaching of a population can approach 100% but depends heavily on the following conditions: the pH of the defined medium and its phosphate content, the age of the parent culture at transfer, and the length of time spent in the defined medium before cell divisions are permitted. Bleaching is not due to loss of nonreplicating proplastids through “dilution out” as cells divide but appears to be a more direct inactivation of chloroplast differentiation from proplastids.     

Glycolate Metabolism and Excretion by Chlamydomonas reinhardtii

The flux of glycolate through the C₂ pathway in Chlamydomonas reinhardtii was estimated after inhibition of the pathway with aminooxyacetate (AOA) or aminoacetonitrile (AAN) by measurement of the accumulation of glycolate and glycine. Cells grown photoautotrophically in air excreted little glycolate except in the presence of 2 mm AOA when they excreted 5 micromoles glycolate per hour per milligram clorophyll. Cells grown on high CO₂ (1-5%) when transferred to air produced three times as much glycolate, with half of the glycolate metabolized and half excreted. The lower amount of glycolate produced by the air-grown cells reflects the presence of a CO₂ concentrating mechanism which raises the internal CO₂ level and decreases the ribulose-1,5-bisP oxygenase reaction for glycolate production. Despite the presence of the CO₂ concentrating mechanism, there was still a significant amount of glycolate produced and metabolized by air-grown Chlamydomonas. The capacity of these cells to metabolize between 5 and 10 micromoles of glycolate per hour per milligram chlorophyll was confirmed by measuring the biphasic uptake of added labeled glycolate. The initial rapid (<10 seconds) phase represented uptake of glycolate; the slow phase represented the metabolism of glycolate. The rates of glycolate metabolism were in agreement with those determined using the C₂-cycle inhibitors during CO₂ fixation.     

Evidence of Reentrance of Glycolate Carbon into the Photosynthetic Carbon Reduction Cycle in Photosynthesizing Euglena gracilis Z

Aminooxyacetate induced excretion of glycolate from air-grown cells of Euglena gracilis in both air and 1% CO₂ atmospheres. The rate of the excretion reached 70% of the photosynthetic rate in the air on a carbon basis, and was 10% in 1% CO₂. The compulsory loss of photosynthetically fixed carbon as glycolate at the high rate in air in the presence of aminooxyacetate caused a decrease of the rate of synthesis of paramylon, the reserve polysaccharide. Analyses of the steady levels of photosynthetic intermediates showed that a decrease of the 3-phosphoglycerate level was the cause of the slow rate of paramylon synthesis under these conditions.     

Guanine Metabolism in Carbon-Limited Euglena gracilis

SYNOPSIS. Guanine-8-³H is not a specific label for nucleic acids in Euglena gracilis (strain SM-L1, streptomycin-bleached), but is incorporated into all biochemical fractions. Autoradiographic results show that guanine is metabolized in, both the nucleus and the cytoplasm of these Eugelna , but nuclear metabolism of guanine occurs only at a very low level in carbon-limited cells. Further, carbon-limited Euglena incorporate less total guanine than do control Euglena in a comparable time period. However, the majority of label incorporated into the nucleic acid fraction of the carbon-limited cells is incorporated into RNA.     

Photosynthesis of Euglena gracilis under Cobalamin-Sufficient and -Limited Growing Conditions

Cobalamin is essential for growth of Euglena gracilis and photosynthesis. Methylcobalamin in Euglena chloroplasts (Y Isegawa, Y Nakano, S Kitaoka, 1984 Plant Physiol 76: 814-818) functions as a coenzyme of methionine synthetase. The requirement of cobalamin for photosynthesis appeared remarkably high in Euglena grown under the dark-precultured condition. The required amount of cobalamin for normal photosynthetic activity was 7.4 × 10⁻¹¹ molar, while 7.4 × 10⁻¹⁰ molar cobalamin was required for normal growth. The lowered photosynthetic activity in cobalamin-limited cells was restored 20 hours after feeding cyanocobalamin or methionine to cobalamin-limited cells. Lowering of photosynthetic activity was due to loss of photosystem I activity. This photosynthetic activity was recovered after supplementation by methionine or cobalamin. The results suggest that methionine serves for the stabilization of photosystem I. This paper is the first report of the physiological function of cobalamin in chloroplasts of photosynthetic eukaryotes.     

Mechanism of Glyoxylate Decarboxylation in the Glycolate Pathway in Euglena gracilis Z : Participation of Mn-Dependent NADPH Oxidase in Chloroplasts

The mechanism for decarboxylating the carboxyl carbon of glycolate was studied in Euglena gracilis Z, which liberates more than 70% of the carboxyl carbon as CO₂ during glycolate metabolism.     

Regulation der Synthese von Plastidenproteinen in Euglena gracilis,Stamm Z

Summary The multiplication of chloroplasts in synchronized Euglena gracilis, strain Z, requires the existence of a regulating system which coordinates both the synthesis of plastid proteins coded in the plastom and the synthesis of plastid proteins coded in the genom. At 27°C this system can not be influenced by external factors, such as chloramphenicol and cycloheximide. At 35°C, however, the inhibition of the synthesis of plastom-coded proteins by chloramphenicol increases the synthesis of certain plastid proteins coded in the genom. The inhibitor cycloheximide acts vice versa. These results are in favour of the hypothesis that the synthesis of plastid proteins is coordinated by regulator proteins.

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Abkürzungen CAP Chloramphenicol - CHM Cycloheximid     

Accumulation of Trehalose as a Compatible Solute under Osmotic Stress in Euglena gracilis Z

ABSTRACT. The photosynthetic protozoon Euglena gracilis, accumulated a large amount of trehalose in the cells under salt or osmotic stresses. Radioactivity of [14C] paramylon, a β-1,3-polyglucan which was stored in the cells of E. gracilis. was degraded rapidly and this radioactivity was almost stoichiometrically incorporated into trehalose. The interconversion of trehalose from paramylon by salt or osmotic stresses was dependent on the concentrations or osmotic pressures, suggesting that E. gracilis accumulate trehalose as an osmoprotectant. After the removal of salt or osmotic stresses, trehalose was gradually degraded, however, it was not converted into paramylon.     

Studies on uroporphyrinogen decarboxylase of etiolated Euglena gracilis Z

1. A 423-fold purified fraction of uroporphyrinogen decarboxylase (EC 4.1.1.37) showing a specific activity of 770 units/mg protein has been employed in order to study some properties in etiolated Euglena gracilis Z. 2. Uroporphyrinogen decarboxylase has a relative molecular mass of 54,000, an optimum pH of 7.2 and exhibits Michaelis-Menten kinetics, employing both uroporphyrinogen I and uroporphyrinogen III as substrates. 3. Anaerobic conditions seem not to be necessary for uroporphyrinogen decarboxylase activity. Neither EDTA nor cysteine affected enzyme activity, whereas dithiothreitol produced a remarkable activation of coproporphyrinogen formation. 4. Kinetic data employing both substrates showed an accumulation of porphyrinogen (i.e. hexa- and hepta-porphyrin) containing six or seven COOH groups, depending on the uroporphyrinogen concentration used. 5. An unusual elution profile of the intermediates on Sephacryl S-200 was found.     

Mono-ADP-Ribosylation of Arginine Residue of Euglena gracilis Z in Synchronous Culture

ABSTRACT. In Euglena gracilis Z, a considerably high activity of mono-ADP-ribosyltransferase occurred and change of it was accompanied by a cell cycle induced by a light-dark cycle. The enzyme activity was strongly inhibited by L-arginine and supported in the presence of poly-L-arginine as a substrate, indicating that ADP-ribosylated amino acid is an arginine residue. Arginine: mono-ADP-ribosyltransferase activity was found in the chloroplasts, mitochondria, microsomes and cytosol as judged from marker enzyme activities and the activity in each organelle fluctuated with the cell cycle.     

Purification and Some Properties of Extracellular Protease of Euglena gracilis Z

The extracellular protease of Euglena gracilis z was purified to a single protein. It was an endopeptidase as found by the Nunokawa’s method, and showed optimum pH for the proteinase, esterase and amidase activities at 7.3, 7.0 and 6.3, respectively. It had a molecular weight of 41,000 and isoelectric point of 8.3. The bleached mutant of E. gracilis produced higher activity of extracellular protease than the wild strain, and supplementation of peptone to the growth medium augmented the enzyme production in both green and bleached cells. The Euglena extracellular protease was markedly inhibited by diisopropylfluorophosphate and Streptomyces subtilicin inhibitor, and to lesser extents by EDTA and p-chloromercuribenzoate. The enzyme was potentiated by some sulfhydryl compounds, activated greatly by Fe²⁺ and stabilized by Ca²⁺ and K⁺.