Glycollate Formation during the Photorespiration of Acetate by Chlorella

WhenChlorella pyrenoidosa photoassimilates ³H-¹⁴C-acetate theglycollic acid formed shows a high ³H/¹⁴C ratio, the only othercompounds showing similar ratios being glycerate and serine.The ³H/¹⁴C ratio of glycollate was unaffected by the TCA cycleinhibitors MFA, diethylmalonate and arsenite showing that ³Hin glycollate does not result from the oxidation of acetatevia the TCA cycle, the resulting NADP³H₂ or NAD³H₂ being usedfor the reduction of the glycollate precursor. Although DCMUdecreased the ³H/¹⁴C ratio, complete inhibition of glycollatelabelling was not observed with 10^–6 M DCMU, at whichconcentration complete inhibition of the Hill reaction is achieved.Although the ³H/¹⁴C ratio was unaltered, total dpm of both ¹⁴Cand ³H in glycollate were increased by INH. The ³H/¹⁴C ratiosof glycerate and serine were decreased by INH, as were the totaldpm of ³H and ¹⁴C incorporated into these compounds. Thus, INHinhibits the further metabolism of glycollate to glycerate andserine. The effect of INH on incorporation of ¹⁴C-I-acetateinto various cell fractions was investigated. The incorporationof ¹⁴C into polysaccharide and lipid was decreased, while theincorporation of ¹⁴C into the water-soluble fraction of cellsand therelease of ¹⁴CO₂ were little affected. Although glycollicacid was an early product of acetate photoassimilation in Chlorellapyrenoidosa, glycollate excretion does not take place undera wide range of environmental conditions shown to favour glycollateexcretion by other algae. However, small amounts of labelledglycollate were detected in the supernatant from the cells duringthe photoassimilation of ³H-¹⁴C-acetate, but this glycollatedid not show the high ³H/¹⁴C ratio of glycollate present withinthe cell. The failure of Chlorella pyrenoidosa to excrete appreciableamounts of glycollate when photoassimilating acetate or carbondioxide was considered to result from the presence of glycollateoxidase (EC 1.1.3.1 [EC] ) which allowed the further metabolism ofglycollate. Besides glycollate oxidase, glyoxylate reductasewas also demonstrated in Chlorella pyrenoidosa so that glycollatecould function in hydrogen transfer during the photoassimilationof acetate.     

Glycollate formation during the photoassimilation of acetate by Chlorella

Summary When ³H-¹⁴C-acetate was supplied to Chlorella pyrenoidosa in the light, glycollic acid became rapidly labelled with tritium and ¹⁴C. The ratio of glycollate was 10, whilst the ratio was 4 in the acetate added. Both ³H and ¹⁴C from acetate were present in glycollate before they were present in Calvin cycle intermediates, so that glycollate was not formed as a C₂-fragment from the Calvin cycle.     

The pathway of glycollate utilization in Chlorella pyrenoidosa

1. Exogenous glycollate was rapidly metabolized in both the light and the dark by photoautotrophically grown Chlorella pyrenoidosa. 2. The incorporation of (14)C from [1-(14)C]glycollate by these cells was inhibited by the tricarboxylic acid-cycle inhibitors monofluoroacetate, diethylmalonate and arsenite, and also by alpha-hydroxypyrid-2-ylmethanesulphonate and isonicotinylhydrazine. 3. Short-term kinetic experiments showed over 80% of the total (14)C present in the soluble fraction from the cells to be in glycine and serine after 10s. This percentage decreased with time whereas the percentage radioactivity in glycerate increased for up to 30s then remained steady. The percentage of the total radioactivity present in citrate increased over the experimental period. Malate was the only other tricarboxylic acid-cycle intermediate to become labelled. 4. The kinetic and inhibitor experiments supported the following pathway of glycollate incorporation: glycollate --> glyoxylate --> glycine --> serine --> hydroxypyruvate --> glycerate --> 3-phosphoglycerate --> 2-phosphoglycerate --> phosphoenolpyruvate --> pyruvate --> acetyl-CoA. 5. The specific activities of the enzymes catalysing this metabolic sequence in cell-free extracts were great enough to account for the observed rate of glycollate metabolism of 0.25mumol/h per mg dry wt. of cells in the light.     

The Role of Glycollic Acid in the Photoassimilation of Acetate by Chlorella pyrenoidosa

The kinetics of ³H-acetate assimilation by Chlorella pyrenoidosain the light were examined. The primary products of assimilationwere glycollate and succinate. After 10 sec glycollate contained45 per cent and succinate 25 per cent of the tritium incorporatedby the cells. The percentage of the total tritium in glycollateand succinate fell with time while that in citrate increased.Initially the specific activities (µc of ³H per µmoleof acid) of succinate and glycollate were greater than citrate.When ³H-¹⁴C-2-acetate was added to the cells, total dpm for³H and ¹⁴C in glycollate rapidly reached a steady state andgave a ³H/¹⁴C ratio of 10, compared with a ³H/¹⁴C ratio of 4in the acetate. This ³H/¹⁴C ratio in glycollate is found because³H is derived from ³H-¹⁴C-2-acetate and because the ¹⁴C is dilutedwith cold carbon from elsewhere. The addition of ¹⁴CO₂ at thesame time as ³H-¹⁴C acetate decreased the ³H/¹⁴C ratio in glycollatebut incorporation of ¹⁴C from ¹⁴CO₂ into glycollate was slowerthan incorporation from ¹⁴C-2-acetate. Although ¹⁴C from acetaterapidly appeared in glycollate, ¹⁴C-labelled glyoxylate wasnot detected. The ³H/¹⁴C ratio observed in glycollate rulesout formation of glycollate from acetate via glycoaldehyde.The available evidence did not support glycollate formationvia the Calvin cycle. ¹⁴C from ¹⁴C-Z-acetate appeared in glycollatebefore it did in phosphoglyceric acid. Total dpm for ³H, ¹⁴C,and ³H/^l4C ratio in Calvin cycle intermediates were not in equilibriumwith glycollic acid.     

Biochemical studies of morpholine catabolism by an environmental mycobacterium

Summary When Mycobacterium strain MorG was grown with morpholine as sole source of carbon and nitrogen, enzymes for ethanolamine catabolism (via the ethanolamine-O-phosphate pathway) and glycollate catabolism (via the glycerate pathway) were strongly induced. Almost all morpholine-negative (Mor^–) mutants of MorG failed to utilize glycollate as a carbon source and were shown to be effective in one or more enzymes for its metabolism via the glycerate pathway. Growth of MorG with morpholine also induced the jacoby and Fredericks pathway for pyrrolidine catabolism, Mor^– mutants had invariably lost the ability to grow on pyrrolidine and 2(2-aminoethoxy)acetate was shown to be an intermediate in morpholine catabolism. This indicates that morpholine is initially catabolised by an analogous route to pyrrolidine, producing 2(2-aminoethoxy)acetate which can be oxidatively cleaved to give rise directly to glycollate and indirectly to ethanolamine. Offprint requests to: W. A. Venables     

Metabolism and decarboxylation of glycollate and serine in leaf peroxisomes

The linked utilization of glycollate and L-serine has been studied in peroxisomal preparations from leaves of spinach beet (Beta vulgaris L.). The generation of glycine from glycollate was found to be balanced by the production of hydroxypyruvate from serine and similarly by 2-oxoglutarate when L-glutamate was substituted for L-serine. In the presence of L-malate and catalytic quantities of NAD⁺, about 40% of the hydroxypyruvate was converted further to glycerate, whereas with substrate quantities of NADH, this conversion was almost quantitative. CO₂ was released from the carboxyl groups of both glycollate and serine. Since the decarboxylation of both substrates was greatly in creased by the catalase inhibitor, 3-amino-1,2,4-triazole, and abolished by bovine liver catalase, it was attributed to the nonenzymic attack of H₂O₂, generated in glycollate oxidation, upon glyoxylate and hydroxypyruvate respectively. At 25–30° C, about 10% of the glyoxylate and hydroxypyruvate accumulated was decarboxylated, and the release of CO₂ from each keto-acid was related to the amounts present. It is suggested that hydroxypyruvate decarboxylation might contribute significantly to photorespiration and provide a metabolic route for the complete oxidation of glycollate, the magnitude of this contribution depending upon the concentrations of glyoxylate and hydroxypyruvate in the peroxisomes.     

Tritium incorporation and retention in photosynthesizing algae

The ratios of incorporation and retention of tritium compared to protium into metabolites in Chlorella pyrenoidosa and in Anacystis nidulans growing in water labeled with tritium have been determined. The algae were continuously supplied during growth with CO₂ labeled with ¹⁴CO₂, and the ¹⁴C content of metabolites were used to determined their concentrations. The tritium/protium ratios (R) of metabolites in Chlorella were determined following growth at 10 °C, 20 °C and 25 °C.As previously reported, variations in R in Chlorella, range from 0.5–0.7 for most metabolites, to values of R around 1 for metabolites of the tricarboxylic acid pathway. The R value for fumarate has now been measured. The increased R values for tricarboxylic acid cycle intermediates and related amino acids can be accounted for in terms of specific isotope effects of several enzyme-mediated steps. Very different R values for certain metabolites were found in A. nidulans. For example, R for citrate was 1.81 (the highest value observed in these studies) while aspartate was only 0.59, comparable to other metabolites in both organisms not related to the tricarboxyclic acid cycle. This lower value for aspartate is explainable in terms of the in complete tricarboxylic acid cycle in A. nidulans.No significant differences in R values for C. pyrenoidosa grown at 20 °C and 25 °C were observed, but in cells grown at 10 °C, there was a small but significant increase in R for tricarboxylic acid cycle metabolites.If the increase in R from sugar phosphates to tricarboxylic acid cycle intermediates seen in these two types of algae may be taken as an indication of likely discriminatory retention of tritium in organisms higher in the food chain, it would appear that no serious concentration of tritium due to isotopic discrimination should occur in the biosphere. However, research workers using compounds labeled with hydrogen isotopes for studies of in vivo metabolism should take into account the likelihood of such discriminatory uptake and retention during specific metabolic steps.     

Anomalous nonstoichiometry detected by dual label analysis of ribulose 1,5-bisphosphate carboxylase

When ribulose-1,5-bisphosphate carboxylase is assayed under N₂ using [³H]ribulose 1,5-bisphosphate and ¹⁴CO₂, [³H]3-phosphoglycerate and [¹⁴C]3-phosphoglycerate are produced in nonstoichiometric amounts in a ratio which approaches 7 at low concentrations of CO₂ (2 micromolar) assuming a 1:1 ratio at V_max (280 micromolar). The log of the molar ratio varies as a linear function of log[CO₂]. Nonstoichiometry could be explained by CO₂ contaminatio of the reactants or tritium contamination of the products. However, the magnitude of CO₂ contamination required (18 ± 4 micromolar) is far in excess of controlled CO₂ (<0.1 micromolar), and the required tritium contaminant would have to vary from 30 to 85% of the purified 3-phosphoglycerate at the 58 and 2 micromolar CO₂ assay levels, respectively. This contrasts with detectable tritium contamination which is only 1 to 4% and correctable. Nonstoichiometry is evident using either 1 or 5 labeled [³H]ribulose 1,5-bisphosphate. When 3-phosphoglycerate is reisolated as glycerate the ³H/¹⁴C ratio remains unchanged.     

Composition and synthesis of DNA in synchronously growing cells of Chlorella pyrenoidosa

Summary The composition and synthesis of DNA in synchronous cultures of Chlorella pyrenoidosa strain 211/8b has been investigated. Analytical CsCl density gradient centrifugation gave a homogenous major DNA component with a (G+C) content of 51% and a minor component containing 28% (G+C). The (G+C) contents derived from melting profiles were 2–3% lower. A second minor component with approximately 41% (G+C) content was inferred from banding patterns of labelled DNA in preparative CsCl density gradients. ¹⁴C-uracil was readily incorporated into the pyrimidine moieties of the major (nuclear) DNA between the 10th and 18th hour after beginning of the light period, but not at any other time. ¹⁴C-uracil incorporation into the minor (satellite) component was low but continuous throughout the whole cell cycle. The incorporation is correlated with an increase in the proportion of satellite DNA from 6% up to 20% during the time when no nuclear DNA replication takes place. The results suggest that different regulatory mechanisms exist for the nuclear and for satellite DNA synthesis.     

Effect of glycollate on phosphate uptake in Chlorella pyrenoidosa

Summary A study was carried out on a strain of Chlorella pyrenoidosa known to excrete glycollic acid to see whether the presence of this acid had any stimulatory effect on phosphate uptake. Contrary to the results of a previous author working on Ankistrodesmus, no stimulation was found at any glycollate or phosphate concentration. However, 2×10^-4 M glycollate caused a marked inhibition of phosphate uptake during the initial period of uptake, but not on a subsequent phase of linear uptake.     

Some Physiological Responses of Chlorella pyrenoidosa to 2,4-Dichlorophenoxyacetic Acid

An 18-h treatment of synchronously-grown Chlorella pyrenoidosawith 2,4-D did not significantly alter the size, dry weight,degree of synchrony, or pigment content of the cells, nor weredetectable quantities of ethylene produced. When Chlorella pyrenoidosawas treated with 5?10^–4 M 2,4-D, there was a statisticallysignificant stimulation of both net oxygen uptake and productionwhile 5?10 M 2,4-D inhibited both processes. When Chlorellapyrenoidosa was treated with 5?10^–4 M and 5?10^–3M 2,4-D, significantly greater amounts of glycollate were presentin the culture medium, even though an assay for glycollate dehydrogenaseshowed that the activity of this enzyme from 2,4-D-treated Chlorellapyrenoidosa was three times greater than in control cells. Looselybound 2,4-D was partitioned from a nonaqueously isolated chloroplastfraction, while other cell fractions failed to show detectablequantities of 2,4-D. It is postulated that in Chlorella pyrenoidosathe chloroplast is a target for 2,4-D action and that interferencein photorespiratory processes may underlie the observed responses.     

The Kinetics of Extracellular Glycollate Production by Chlorella pyrenoidosa

Extracellular glycollate is liberated by Chlorella pyrenoidosaduring growth in medium bubbled with air or 3 per cent carbondioxide in air. With air the rate of release of glycollate percell decreases, with 3 per cent carbon dioxide it increases,with increase in cell number. Glycollate is released duringshort-term experiments when C. pyrenoidasa, grown under lowlight and high carbon dioxide, is transferred suddenly to highlight and low carbon dioxide. No other combination of thesefactors produces a comparable release of glycollate. The quantityof glycollate released in short-term experiments increases exponentiallywith the relative growth-rate of the culture from which thecells are derived. A crucial condition for maximum glycollaterelease is that growth of the culture prior to the experimentshould not be limited by carbon-dixoide concentration. The effectof pH is related to its effect on growth-rate; i.e. C. pyrenoidosahas a lower relative growth-rate at pH 8.3 and produces correspondinglyless glycollate than faster growing cultures at pH 6.4. Duringshort-term experiments under high light and low carbon dioxidethe rate of glycollate release drops after 50–100 minutessuggesting exhaustion of the glycollate precursor.     

The Effect of Hydroxymethanesulphonate on Photosynthesis in Chlorella pyrenoidosa

Photosynthesis under conditions known to favour glycollate excretionby algae did not result in glycollate excretion in a strainof Chlorella pyrenoidosa unless an inhibitor of glycollate oxidase,-hydroxypyridin-2yl-methane sulphonate (-HPMS), was present.This inhibitor increased the total amount of glycollate presentin the supernatant from the cells during photosynthetic carbondioxide fixation and gave accumulation of ¹⁴C in glycollateduring ¹⁴CO₂ fixation under conditions favouring glycollatesynthesis. At pH 8.3 -HPMS did not stimulate photosynthetic¹⁴CO₂ fixation in C. pyrenoidosa as occurs with some algae.Photoassimilation of acetate was inhibited by -HPMS, and thiswas shown to result from acetyl-CoA synthetase inhibition by-HPMS.     

Photoassimilation of acetate and metabolism of carbohydrate in Chlorobium thiosulfatophilum

1. Washed cell suspensions of Chlorobium thiosulfatophilum form large amounts of a polyglucose in the light. Addition of acetate to the cells increases the formation of polysaccharide considerably. During incubation in the dark, polysaccharide decreases with time, and organic acids such as succinic and propionic acid are excreted into the medium. 2. Glucose isolated from cells which had photoassimilated 1-, 2-, and U-¹⁴C-acetate had a specific activity which lay between 1 and 2 times that of the acetate substrates. 3. To analyse the distribution of radioactivity in the glucose units formed during photoassimilation of ¹⁴C-acetate, 2 microbial degradations, with bakers' yeast and Zymomonas mobilis respectively, were used. The results show that acetate gives rise to carbon atoms 1+2 and 5+6 of glucose, whereas carbon atomes 3+4 are not labelled. Further, the results indicate that glucose is not formed via the reductive pentose phosphate cycle when acetate is present.     

Glycolic Acid Labeling During Photosynthesis with CO(2) and Tritiated Water

Chlorella pyrenoidosa were allowed to photosynthesize for short periods of time in the presence of ¹⁴CO₂ and HTO. Analysis of tritium and ¹⁴C labeling of photosynthetic intermediate compounds showed that the T/¹⁴C ratio of glycolic acid was comparable to that of intermediate compounds of the photosynthetic carbon reduction cycle when photosynthesis was performed in nearly 100% oxygen and only slightly higher under steady-state conditions. It is concluded that formation of labeled glycolic acid as a consequence of its proposed hydrogen transport role in photosynthesis is quantitatively of limited importance compared to the net synthesis of glycolic acid from CO₂.     

Messenger RNA for isocitrate lyase from Chlorella fusca var. vacuolata

Chlorella fusca cultures growing in the light and adapting to acetate in the dark were labelled with adenine-³H and adenine-¹⁴C, respectively. Poly(A)-containing RNA from the mixed cultures was analysed for ¹⁴C/³H ratio after polyacrylamide gel electrophoresis in 98% formamide. The RNA from acetateadapting C. fusca cells contained excess label migrating in the gels at a position equivalent to about 0.85×10⁶ mol.wt. Partially purified anti-isocitrate lyase serum linked to p-aminobenzoyl-cellulose bound 3.5–13% of polysomes from acetate-adapting C. fusca, containing 5–10% of polysomal poly(A)-containing RNA. The antibody-bound poly(A)-containing RNA fraction showed a unimodal size distribution with a mean size of about 0.85×10⁶ mol.wt. after electrophoresis on 4% polyacrylamide gels in 98% formamide. Cell-free translation assays showed a three-fold enrichment of isocitrate lyase mRNA after antibody selection of polysomes and indicated that isocitrate lyase mRNA was abundant in acetate-adapting C. fusca cells.Abbreviations A ₂₆₀ unit The amount of material in 1.0 ml giving an absorbance of 1.0 at 260 nm in a 1 cm light path - PAB-cellulose p-aminobenzoyl-cellulose - SDS sodium lauryl sulphate To whom offprint requests are to be sent     

Chronic toxicity of methylparathion to the rotifer Brachionus calyciflorus fed on Nannochloris oculata and Chlorella pyrenoidosa

The effect of sublethal levels of methylparathion (0, 1, 3, 5, 7 mg l^–1) on the freshwater rotifer, Brachionus calyciflorus, during their entire life cycle was studied. Rotifers were fed on two species of unicellular algae: Nannochloris oculata and Chlorella pyrenoidosa; both algal concentrations were 5 × 10⁵ cell ml^–1.The parameters used to determine the toxicity of this compound were survival, fecundity, net reproductive rate (R)_o, generation time (T), intrinsic rate of natural increase (r), reproductive value (V _x/V_o) and life expectancy at hatching (eo). All the demographic parameters studied were affected by methyl-parathion exposure on rotifers fed on both species of algae, but the toxic effect was larger when animals were fed on Chlorella pyrenoidosa; in this case, animals showed a decreased in fertility and also a delayed first reproduction. Sublethal methylparathion levels produced a reduction in most of the parameters selected, especially after exposure to 7 mg l^–1, where the animals died before reproducing.     

Biodegradation of p-nitrophenol by microalgae

A study was made on the use of a mixed microalgal consortium to degrade p-nitrophenol. The consortium was obtained from a microbial community in a waste container fed with the remains and by-products of medium culture containing substituted aromatic pollutants (nitrophenols, chlorophenols, fluorobenzene). After selective enrichment with p-nitrophenol (p-NP), followed by an antibiotic treatment, an axenic microalgal consortium was recovered, which was able to degrade p-nitrophenol. At a concentration of 50 mg L^–1, total degradation occurred within 5 days. Two species, Chlorella vulgaris var. vulgaris f. minuscula and Coenochloris pyrenoidosa, were isolated from the microalgal consortium. The species were able to accomplish p-NP biodegradation when cultured separately, although Coenochloris pyrenoidosa was more efficient, achieving the same degradation rate as the original axenic microalgal consortium. When Coenochloris pyrenoidosa was associated with Chlorella vulgaris in a 3:1 ratio, complete removal of the nitro-aromatic compound occurred within three days. This is apparently the first report on the degradation of a nitro-aromatic compound by microalgae.     

Art und Menge der Ausscheidung 14C-markierter Verbindungen bei Chlorella pyrenoidosa unter dem Einfluss des osmotischen Drucks der Nährlösung

Chlorella pyrenoidosa was labelled by ¹⁴CO₂ and the nature and amount of excreted organic compounds in nutrient media of different osmotic pressure were determined after a 24 h period. The total rate of excretion of organic bound ¹⁴C was about 4 μg ¹⁴C per mg harvested algal dry matter or 1% of the total ¹⁴C content of the algae at the beginning of the excretion period. The main compounds found in the excretions were unidentified substances with a molecular weight higher than 700, amino acids, organic acids and sugars. The osmotic pressure of the nutrient medium did not affect the total amount of the organic excretions. However, the excreted amounts of some specific compounds differed in respect to the osmotic conditions of the nutrient medium.     

INORGANIC CARBON AND ACETATE ASSIMILATION IN BOTRYOCOCCUS BRAUNII(CHLOROPHYTA)1

Assimilation of ¹⁴CO₂ or ¹⁴C-acetate by the hydrocarbon producing alga Botryococcus braunii Kützing was investigated to determine the allocation of incorporated ¹⁴C among early metabolites of photosynthesis and secondary metabolites. When the cells were exposed to NaH¹⁴CO₃ for 10 sec, over 90% of incorporated ¹⁴C was detected in phosphoglycerate, suggesting that this alga assimilates inorganic carbon by the C-3 pathway. The distribution pattern of ¹⁴C in the number of metabolites revealed that organic acids, neutral sugars and amino acids were first labelled with ¹⁴C, and, after lag periods of a few minutes, lipids including hydrocarbon were increasingly labelled. Addition of 5 mM acetate to the culture medium did not affect the growth of this alga but enhanced cellular respiration. The incorporation of ¹⁴CO₂ into the lipid fraction was stimulated, but net photosynthesis was inhibited by the addition of acetate. ¹⁴C-acetate was incorporated into lipids at a very low rate in comparison with the rate of ¹⁴CO₂ incorporation.