Oxygen starvation induces cell death in Candida shehatae fermentations of d-xylose, but not d-glucose

Candida shehatae cells, cultivated on d-glucose and d-xylose, were subjected to a shift from fully aerobic to anaerobic fermentative conditions. After anaerobic conditions were imposed, growth was limited to approximately one doubling or less as C. shehatae rapidly entered a stationary phase of growth. Following the shift to anoxia, cell viability rapidly declined and the total cell volume declined in the d-xylose fermentations. Moreover, the cell volume distribution shifted to smaller volumes. Cell viability, measured by plate counts, declined nine times faster for d-xylose fermentations than for d-glucose fermentations. Anaerobic growth did not occur on either d-glucose or d-xylose. Selected vitamins and amino acids did not stimulate anaerobic growth in C. shehatae, but did enhance anaerobic growth on d-glucose in S. cerevisiae. The decline in cell viability and lack of anaerobic growth by C. shehatae were attributed to oxygen deficiency and not to ethanol inhibition. The results shed light on why C. shehatae anaerobic fermentations are not currently practical and suggest that research directed towards a biochemical understanding of why C. shehatae can not grow anaerobically will yield significant improvements in ethanol fermentations from d-xylose. Received 26 October 1998 / Received revision: 26 January 1999 / Accepted: 12 February 1999     

Phylogenetic and biochemical characterization of the oil-producing yeast Lipomyces starkeyi

Lipomyces starkeyi is an oleaginous yeast, and has been classified in four distinct groups, i.e., sensu stricto and custers α, β, and γ. Recently, L. starkeyi clusters α, β, and γ were recognized independent species, Lipomyces mesembrius, Lipomyces doorenjongii, and Lipomyces kockii, respectively. In this study, we investigated phylogenetic relationships within L. starkeyi, including 18 Japanese wild strains, and its related species, based on internal transcribed spacer sequences and evaluated biochemical characters which reflected the phylogenetic tree. Phylogenetic analysis showed that most of Japanese wild strains formed one clade and this clade is more closely related to L. starkeyi s.s. clade including one Japanese wild strain than other clades. Only three Japanese wild strains were genetically distinct from L. starkeyi. Lipomyces mesembrius and L. doorenjongii shared one clade, while L. kockii was genetically distinct from the other three species. Strains in L. starkeyi s.s. clade converted six sugars, d-glucose, d-xylose, l-arabinose, d-galactose, d-mannose, and d-cellobiose to produce high total lipid yields. The Japanese wild strains in subclades B, C, and D converted d-glucose, d-galactose, and d-mannose to produce high total lipid yields. Lipomyces mesembrius was divided into two subclades. Lipomyces mesembrius CBS 7737 converted d-xylose, l-arabinose, d-galactose, and d-cellobiose, while the other L. mesembrius strains did not. Lipomyces doorenjongii converted all the sugars except d-cellobiose. In comparison to L. starkeyi, L. mesembrius, and L. doorenjongii, L. kockii produced higher total lipid yields from d-glucose, d-galactose, and d-mannose. The type of sugar converted depended on the subclade classification elucidated in this study.     

A gene encoding alanine racemase is involved in spore germination in <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis>

Alanine racemase is a major component of the exosporium of Bacillus cereus spores. A gene homologous to that of alanine racemase (alrA) was cloned from Bacillus thuringiensis subsp. kurstaki, and RT-PCR showed that alrA was transcribed only in the sporulating cells. Disruption of alrA did not affect the growth and sporulation of B. thuringiensis, but promoted l-alanine-induced spore germination. When the spore germination rate was measured by monitoring DPA release, complementation of the alrA disruptant reduced the rate of l-alanine-induced spore germination below that of even wild-type spores. As previously reported for spores of other Bacillus species, d-alanine was an effective and competitive inhibitor of l-alanine-induced germination of B. thuringiensis spores. d-cycloserine alone stimulated inosine-induced germination of B. thuringiensis spores in addition to increasing l-alanine-induced germination by inhibiting alanine racemase. d-Alanine also increased the rate of inosine-induced germination of wild-type spores. However, d-alanine inhibited inosine-induced germination of the alrA disruptant spores. It is possible that AlrA converted d-alanine to l-alanine, and this in turn, stimulated spore germination in B. thuringiensis. These results suggest that alrA plays a crucial role in moderating the germination rate of B. thuringiensis spores.     

L-Arabinose metabolism in Candida arabinofermentans PYCC 5603T and Pichia guilliermondii PYCC 3012: influence of sugar and oxygen on product formation

l-Arabinose utilization by the yeasts Candida arabinofermentans PYCC 5603^T and Pichia guilliermondii PYCC 3012 was investigated in aerobic batch cultures and compared, under similar conditions, to d-glucose and d-xylose metabolism. At high aeration levels, only biomass was formed from all the three sugars. When oxygen became limited, ethanol was produced from d-glucose, demonstrating a fermentative pathway in these yeasts. However, pentoses were essentially respired and, under oxygen limitation, the respective polyols accumulated—arabitol from l-arabinose and xylitol from d-xylose. Different l-arabinose concentrations and oxygen conditions were tested to better understand l-arabinose metabolism. P. guilliermondii PYCC 3012 excreted considerably more arabitol from l-arabinose (and also xylitol from d-xylose) than C. arabinofermentans PYCC 5603^T. In contrast to the latter, P. guilliermondii PYCC 3012 did not produce any traces of ethanol in complex l-arabinose (80 g/l) medium under oxygen-limited conditions. Neither sustained growth nor active metabolism was observed under anaerobiosis. This study demonstrates, for the first time, the oxygen dependence of metabolite and product formation in l-arabinose-assimilating yeasts.     

Die Wirkung von d-Aminosäuren auf die Struktur und Biosynthese des Peptidoglycans

Zusammenfassung In einem Konzentrationsbereich von 0,02–0,2 M hemmt d-Serin das Wachstum aller untersuchten Bakterien. Gleichzeitig traten morphologische Veränderungen der Bakterienzellen auf. In den nucleotidaktivierten Vorstufen von gehemmten Zellen wurden die d-Alaninreste des Peptidanteils ganz oder teilweise durch d-Serin ersetzt. Auch das Peptidoglycan enthielt d-Serin anstelle von d-Alanin, jedoch weiniger als in den Vorstufen. Zusätzlich war das modifizierte Peptidoglycan zu einem geringeren Anteil quervernetzt als das normale. Vier weitere d-Aminosäuren (Threonin, Valin, Leucin, Methionin) verursachten bei einer Konzentration von 0.2 M ähnliche Wirkungen wie d-Serin. Die Wirkungsweise von d-Aminosäuren auf die Peptidoglycansynthese kann daher allgemein wie folgt beschreiben werden: In Gegenwart von wachstumshemmenden Konzentrationen an d-Aminosäuren werden modifizierte nucleotidaktivierte Peptidoglycanvorstufen synthetisiert, die zu einem geringeren Ausmaß in das Peptidoglycan eingebaut und im Peptidoglycan schlechter quervernetzt werden. Der Ersatz von d-Alanin in Position 4 der Peptiduntereinheit ist dabei in der Regel am wirkungsvollsten. Nur bei Corynebacterium insidiosum und Staphylococcus aureus erwies sich der Ersatz in Position 5 als stärker hemmend. Diese Wirkungsweise entspricht weitgehend derjenigen von Glycin. Im Unterschied zur Wirkung von Glycin kann l-Alanin in Position 1 der Peptiduntereinheit nicht durch d-Aminosäuren ersetzt werden.

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Mode of action of d-amino acids on the biosynthesis of peptidoglycan

The mechanism of growth inhibition by d-amino acids was studied. d-Serine at concentrations from 0.02–0.2 M was sufficient to cause partial growth inhibition in seven species of bacteria representing the four most common types of peptidoglycan. The inhibited cells displayed morphological alterations. In the nucleotide-activated peptidoglycan precursors of these cells, d-alanine residues in position 4 and/or 5 of the peptide moiety were partially or even completely replaced by d-serine. The peptidoglycan also contained d-serine instead of d-alanine, but the percentual content of d-serine was significantly lower than that in the precursors. In addition, the modified peptidoglycan was less cross-linked than the normal one. Four other d-amino acids (d-threonine, d-valine, d-leucine, d-methionine) at concentrations of about 0.2 M caused similar effects as did d-serine when applied to Corynebacterium callunae and Bacillus subtilis. Thus the mode of action of d-amino acids on peptidoglycan synthesis can be generally described as follows: in their presence, at growth inhibiting concentrations modified nucleotide-activated peptidoglycan precursors are formed in which d-alanine residues are replaced by the d-amino acids. They are less efficiently incorporated into peptidoglycan. A high percentage of the modified muropeptides remains non-cross-linked, since they are poor substrates for the transpeptidation reaction. In the majority of the organisms, cross-linking was decreased when d-alanine in position 4 of the peptide subunit was replaced, in two organisms (Corynebacterium insidiosum and Staphylococcus aureus) replacement in position 5 was most effective, however. The low extent of crosslinkage is consistent with the morphological aberrations of inhibited cells. In previous studies with glycine, results were described that were in close analogy to those obtained with d-amino acids. However, glycine can replace not only d-alanine residues in position 4 and 5 but also l-alanine in position 1 of the peptide subunit.

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Verwendete Abkürzungen Dab Diaminobuttersäure - m-Dmp meso-Diaminopimelinsäure - GlcNAc oder G N-Acetylglucosamin - MurNAc oder M N-Acetylmuraminsäure     

Single Taste Stimuli Elicit Either Increases or Decreases in Intracellular Calcium in Isolated Catfish Taste Cells

Taste cells are specialized epithelial cells that respond to stimulation with release of neurotransmitters onto afferent nerves that innervate taste buds. In analogy to neurotransmitter release in other cells, it is expected that neurotransmitter release in taste cells is dependent on an increase in intracellular Ca²⁺ ([Ca²⁺] _i ). We have studied changes in [Ca²⁺] _i elicited by the taste stimuli l- and d-arginine in isolated taste cells from the channel catfish (Ictalurus punctatus). In a sample of 119 cells, we found 15 cells responding to l-arginine, and 12 cells responding to d-arginine with an increase in [Ca²⁺] _i . The response to l-arginine was inhibited by equimolar d-arginine in cells where d-arginine alone did not cause a change in [Ca²⁺] _i , which is consistent with mediation of this response by a previously characterized l-arginine-gated nonspecific cation channel antagonized by d-arginine [31]. However, we also found that these taste stimuli elicited decreases in [Ca²⁺] _i in substantial number of cells (6 for l-Arg, and 2 for d-Arg, n= 119). These observations suggest that stimulation of taste cells with sapid stimuli may result in simultaneous excitation and inhibition of different taste cells within the taste bud, which could be involved in local processing of the taste signal. Received: 25 May 1995/Revised: 29 September 1995     

Formation of d(-)-1,2-propanediol and d(-)-lactate from glucose by Clostridium sphenoides under phosphate limitation

Clostridium sphenoides was grown on glucose in a phosphate-limited medium. Below 80 M phosphate two new products were formed in addition to ethanol, acetate, H₂ and CO₂: d(-)-1,2-propanediol and d(-)-lactate. These compounds were apparently synthesized via the methylglyoxal by-pass. The activity of the enzymes involvedmethylglyoxal synthase, methylglyoxal reductase, 1,2-propanediol dehydrogenase and glyoxalase-could be demonstrated in cell extracts of C. sphenoides. The formation of 1,2-propanediol from methylglyoxal proceeded via lactaldehyde. The enzyme methylgloxal synthase was inhibited by phosphate. Clostridium glycolicum, C. nexile, C. cellobioparum, C. oroticum and C. indolis did not produce propanediol under the condition of phosphate limitation. The latter two species, however, formed d(-)-lactate.Dedicated to Prof. Dr. G. Drews on the occasion of his 60th birthday     

Klebsiella ornithinolytica sp. nov., formerly known as ornithine-positiveKlebsiella oxytoca

The nameKlebsiella ornithinolytica sp. nov. is proposed for a group ofKlebsiella strains referred to previously as NIH Group 12 at the National Institute of Health, Tokyo. The members of this species are Gram-negative, encapsulated, nonmotile rods with the general characteristics of the familyEnterobacteriaceae and of the genusKlebsiella. They give positive results in tests for indole production, Voges-Proskauer, citrate utilization, lysine and ornithine decarboxylases, urease, -galactosidase, malonate utilization, growth in KCN, and esculin hydrolysis, and they produce acid and gas fromd-glucose, and acid froml-arabinose, cellobiose, lactose, melibiose, raffinose, rhamnose, sucrose, trehalose,d-xylose, adonitol,d-arabitol, myo-inositol, sorbitol, arbutin, salicin, -methyl-d-glucoside, and mucate. They give negative drolysis, DNase, pectinase, and acid production fromd-arabinose, melezitose, and dulcitol. They can grow at 4°C and 42°C, and do not produce any pigment. DNA relatedness of eight strains ofKlebsiella ornithinolytica to three strains including the type strain of this species averaged 88% in reaction at 75°C. DNA relatedness to the already recognizedKlebsiella species inEnterobacteriaceae was 1 to 20%. Phenotypic and DNA relatedness data also indicated that a group of organisms referred to as Enteric Group 47 orKlebsiella Group 47 at the Centers for Disease Control (Atlanta, Georgia) was identical withK. ornithinolytica. The type strain ofK. ornithinolytica is NIH 90-72 (JCM 6096).     

Human and climatic impact on mires: a case study of Les Amburnex mire,Swiss Jura Mountains

Modern period long-term human and climatic impacts on a small mire in the Jura Mountains were assessed using testate amoebae, macrofossils and pollen. This multiproxy data analysis permitted detailed interpretations of local and regional environmental change and thus a partial disentanglement of the different variables that influence long-term mire development. From the Middle Ages until a.d. 1700 the mire vegetation was characterised by ferns, Caltha and Vaccinium, but then abruptly changed into the modern vegetation characterised by Cyperaceae, Potentilla and Sphagnum. The cause for this change was most probably deforestation, possibly enhanced by climatic cooling. A decrease in trampling intensity by domestic animals from a.d. 1950 onwards allowed Sphagnum growth and climatic warming in the a.d. 1980s and 1990s may have been responsible for considerable changes in the species composition. The mire investigated is an example of the rapid changes in mire vegetation and peat development that occurred throughout the central European mountain region during the past centuries as a result of changing climate and land-use practice. These processes are still active today and will determine the future development of high-altitude mires.     

The effect of respiratory inhibitors on the fermentative ability of Pichia stipitis,Pachysolen tannophilus and Saccharomyces cerevisiae under various conditions of aerobiosis

Summary The growth and ethanol production by the d-xylose-fermenting yeasts Pichia stipitis and Pachysolen tannophilus under various conditions of aerobiosis responded similarly to the addition of the respiratory inhibitors potassium cyanide (KCN), antimycin A (AA), sodium azide and rotenone. However, the d-glucose-fermenting yeast Saccharomyces cerevisiae differed markedly from these yeasts in response to the inhibitors. In general the growth of the d-xylose-fermenting yeasts was inhibited by the respiratory inhibitors while ethanol production was either stimulated (especially when oxygen was available) or unaffected or inhibited by rotenone or AA or KCN and sodium azide, respectively. However, by exception KCN and AA stimulated ethanol production under aerobic conditions by Pichia stipitis and Pachysolen tannophilus respectively. Stimulatory or inhibitory effects by respiratory inhibitors were less marked in S. cerevisiae. These data suggest that unimpaired mitochondrial function is necessary for growth on d-xylose and optimal d-xylose fermentation. A requirement for membrane generated energy during d-xylose utilisation is indicated by 2,4-dinitrophenol inhibition of growth and fermentation.     

Leclercia adecarboxylata Gen. Nov., Comb. Nov., formerly known asEscherichia adecarboxylata.

The nameLeclercia adecarboxylata is proposed for a group of the family Enterobacteriacae previously known asEscherichia adecarboxylata. Leclercia adecarboxylata can be phenotypically differentiated from all other species of Enterobacteriaceae. The members of this species are positive for motility, indole production, methyl red, growth in the presence of KCN, malonate, beta-galactosidase, beta-xylosidase, esculin hydrolysis, gas production fromd-glucose, and acid production fromd-cellobiose,d-lactose, melibiose,l-rhamnose, adonitol,d-arabitol, dulcitol, and salicin; the strains were negative for Voges-Proskauer, citrate (Simmons), H₂S (Kligler), lysine and ornithine decarboxylases, arginine dihydrolase, phenylalanine deaminase, gelatinase, DNase, Tween-80 hydrolysis, and acid production from myoinositol and alpha-methyl-d-glucoside. Fermentation ofd-raffinose,d-sucrose, andd-sorbitol is variable with strains. DNA relatedness of 11 strains ofL. adecarboxylata to three strains including the type strain of this species averaged 80% in reactions at 65°C. DNA relatedness to other species in Enterobacteriaceae was 2%–32%, indicating that this species was placed in a new genusLeclercia gen. nov. The type strain ofL. adecarboxylata is ATCC 23216.     

Polysaccharides purified from the submerged culture of Ganoderma formosanum stimulate macrophage activation and protect mice against Listeria monocytogenes infection

The bioactive components of Ganoderma formosanum have not yet been characterized. We investigated the immunomodulatory activities of the extracellular polysaccharides produced from a submerged mycelial culture of G. formosanum. The polysaccharides were mainly composed of d-mannose, d-galactose and d-glucose. After gel filtration chromatography, three polysaccharide fractions (PS-F1, PS-F2 and PS-F3) were purified. PS-F2 stimulated mouse RAW264.7 macrophages to produce TNF-α and nitric oxide, and enhanced the phagocytic activity of macrophages. PS-F2 challenge in mice triggered an acute inflammatory response characterized by the recruitment of neutrophils and monocytes, which protected mice from subsequent infection of Listeria monocytogenes. The results indicate that the heteropolysaccharides produced by G. formosanum can activate the innate immune response on macrophages.     

Role of lactose on the production of d-arabitol by Kluyveromyces lactis grown on lactose

There are remarkably few reports on d-arabitol production from lactose. Previous studies in our laboratory have shown that the osmophilic yeast Kluyveromyces lactis NBRC 1903 convert lactose to extracellular d-arabitol. The present study was undertaken to determine the participation of osmotic stress caused by lactose on d-arabitol production by K. lactis NBRC 1903 and to provide the information on the kinetics of d-arabitol production from lactose by K. lactis NBRC 1903. It was confirmed that d-arabitol production was triggered when an initial lactose concentration was above 278 mmol L⁻¹. d-Arabitol yield increased with an increase in initial lactose concentration. The highest d-arabitol concentration of 79.5 mmol L⁻¹ was achieved in the cultivation of K. lactis NBRC 1903 in a medium containing 555 mmol L⁻¹ lactose and 40 g L⁻¹ yeast extract. Lactose was found to play two important roles in d-arabitol production by K. lactis NBRC 1903 grown on lactose. First, lactose was assimilated as the substrate both for cell growth and d-arabitol production. Second, a high lactose concentration induced cellular response to high osmotic stress and up-regulated the flow from d-glucose-6-phosphate to d-arabitol. The arrest of cell growth triggered d-arabitol production.     

Enzymatic properties of the glycine d-alanine aminopeptidase of <Emphasis Type="Italic">Aspergillus oryzae</Emphasis> and its activity profiles in liquid-cultured mycelia and solid-state rice culture (rice koji)

The gdaA gene encoding S12 family glycine–d-alanine aminopeptidase (GdaA) was found in the industrial fungus Aspergillus oryzae. GdaA shares 43% amino acid sequence identity with the d-aminopeptidase of the Gram-negative bacterium Ochrobactrum anthropi. GdaA purified from an A. oryzae gdaA-overexpressing strain exhibited high d-stereospecificity and efficiently released N-terminal glycine and d-alanine of substrates in a highly specific manner. The optimum pH and temperature were 8 to 9 and 40°C, respectively. This enzyme was stable under alkaline conditions at pH 8 to 11 and relatively resistant to acidic conditions until pH 5.0. The chelating reagent EDTA, serine protease inhibitors such as AEBSF, benzamidine, TPCK, and TLCK, and the thiol enzyme inhibitor PCMB inhibited the enzyme. The aminopeptidase inhibitor bestatin did not affect the activity. GdaA was largely responsible for intracellular glycine and d-alanine aminopeptidase activities in A. oryzae during stationary-phase growth in liquid media. In addition, the activity increased in response to the depletion of nitrogen or carbon sources in the growth media, although the GdaA-independent glycine aminopeptidase activity highly increased simultaneously. Aminopeptidases of A. oryzae attract attention because the enzymatic release of a variety of amino acids and peptides is important for the enhancement of the palatability of fermented foods. GdaA activity was found in extracts of a solid-state rice culture of A. oryzae (rice koji), which is widely used as a starter culture for Japanese traditional fermented foods, and was largely responsible for the glycine and d-alanine aminopeptidase activity detected at a pH range of 6 to 9.     

Anomalous uptake ofd-ribose byRhodotorula gracilis

d-Ribose was found to enter the cells ofRhodotorula gracilis by a mechanism resembling simple diffusion (proportionality between rate and concentration, no effect of inhibitors, of temperature, of other sugars) at concentrations from 0.001 to 10mm. With a lag of about 1 hour,d-ribose was oxidized and, with a lag of about 20 hours, it could serve as a growth substrate. The transport step appears to be rate-limiting for the subsequent metabolic processes. The oxidation was stimulated byd-xylose but unaffected byd-glucose. Dedicated to Academician Ivan Málek on the occasion of his 60th birthday     

Effect of temperature on <Emphasis Type="SmallCaps">d</Emphasis>-arabitol production from lactose by <Emphasis Type="Italic">Kluyveromyces lactis</Emphasis>

d-Arabitol production from lactose by Kluyveromyces lactis NBRC 1903 has been studied by following the time courses of concentrations of cell mass, lactose, d-arabitol, ethanol, and glycerol at different temperatures. It was found that temperature is a key factor in d-arabitol production. Within temperatures ranging from 25 to 39°C, the highest d-arabitol concentration of 99.2 mmol l⁻¹ was obtained from 555 mmol l⁻¹ of lactose after 120 h of batch cultivation at 37°C. The yield of d-arabitol production on cell mass growth increased drastically at temperatures higher than 35°C, and the yield reached 1.07 at 39°C. Increasing the cell mass concentration two-fold after 24 h of culture growth at 37°C, the d-arabitol concentration further increased to 168 mmol l⁻¹. According to the distribution of the metabolic products, metabolic changes related to growth phase were also discussed. The stationary-phase K. lactis cells in the batch culture that is started with exposing the precultured inoculum to high osmotic stress, high oxidative stress, and high heat stress are found to be preferable for d-arabitol production.     

Production of <Emphasis Type="SmallCaps">l</Emphasis>-alanine by metabolically engineered <Emphasis Type="Italic">Escherichia coli</Emphasis>

Escherichia coli W was genetically engineered to produce l-alanine as the primary fermentation product from sugars by replacing the native d-lactate dehydrogenase of E. coli SZ194 with alanine dehydrogenase from Geobacillus stearothermophilus. As a result, the heterologous alanine dehydrogenase gene was integrated under the regulation of the native d-lactate dehydrogenase (ldhA) promoter. This homologous promoter is growth-regulated and provides high levels of expression during anaerobic fermentation. Strain XZ111 accumulated alanine as the primary product during glucose fermentation. The methylglyoxal synthase gene (mgsA) was deleted to eliminate low levels of lactate and improve growth, and the catabolic alanine racemase gene (dadX) was deleted to minimize conversion of l-alanine to d-alanine. In these strains, reduced nicotinamide adenine dinucleotide oxidation during alanine biosynthesis is obligately linked to adenosine triphosphate production and cell growth. This linkage provided a basis for metabolic evolution where selection for improvements in growth coselected for increased glycolytic flux and alanine production. The resulting strain, XZ132, produced 1,279 mmol alanine from 120 g l⁻¹ glucose within 48 h during batch fermentation in the mineral salts medium. The alanine yield was 95% on a weight basis (g g⁻¹ glucose) with a chiral purity greater than 99.5% l-alanine. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Isocitrate dehydrogenase and glyoxylate cycle enzyme activities in Bradyrhizobium japonicum under various growth conditions

Bradyrhizobium japonicum, the nitrogen-fixing symbiotic partner of soybean, was grown on various carbon substrates and assayed for the presence of the glyoxylate cycle enzymes, isocitrate lyase and malate synthase. The highest levels of isocitrate lyase [165–170 nmol min^–1 (mg protein)^–1] were found in cells grown on acetate or β-hydroxybutyrate, intermediate activity was found after growth on pyruvate or galactose, and very little activity was found in cells grown on arabinose, malate, or glycerol. Malate synthase activity was present in arabinose- and malate-grown cultures and increased by only 50–80% when cells were grown on acetate. B. japonicum bacteroids, harvested at four different nodule ages, showed very little isocitrate lyase activity, implying that a complete glyoxylate cycle is not functional during symbiosis. The apparent K _m of isocitrate lyase for d,l-isocitrate was fourfold higher than that of isocitrate dehydrogenase (61.5 and 15.5 μM, respectively) in desalted crude extracts from acetate-grown B. japonicum. When isocitrate lyase was induced, neither the V _max nor the d,l-isocitrate K _m of isocitrate dehydrogenase changed, implying that isocitrate dehydrogenase is not inhibited by covalent modification to facilitate operation of the glyoxylate cycle in B. japonicum. Received: 10 October 1997 / Accepted: 16 January 1998     

Soluble sugars in the mycelium of the basidiomyceteOudemansiella mucida

Quantitative gas chromatography was used to determine soluble neutral sugars in an extract of the fungusOudemansiella mucida grown on a synthetic glucose medium. Apart from the usual fungal sugar components,viz. trehalose,d-glucose,d-mannitol,d-arabinitol, glycerol and inositol, the 6-day-old mycelium containedd-arabino-2-hexosulose (d-glucosone). In the period of maximum growth, this aldoketose was the predominant monosaccharide (3.4 % mycelial dry weight).