Uptake of volatilen-alkanes byPseudomonas PG-I

Using a bacterial speciesPseudomonas PG-1, evidence has been obtained which indicates that uptake ofn-pentane ton-octane by microbial cells takes place primarily from the gas phase either directly orvia the aqueous phase. Specific growth rate increased along with the increase in substrate concentration but above the alkane concentration of 0.3% by volume, specific growth rate decreased indicating substrate inhibition of growth. In the case of less volatile alkanes,n-nonane andn-decane, substrate transfer is predominantly through substrate solubilization system elaborated by the cells. EDTA, a strong inhibitor of hydrocarbon solubilization by the cells, inhibited growth on these two alkanes but had negligible effect on growth onn-pentane ton-octane.     

Continuous hydrocarbon fermentation with colloidal emulsion feed. A kinetic model for two-liquid phase culture

Candida tropicalis was cultured in a chemostat-type fermentor with n-hexadecane, dispersed in water as submicron droplets, as the only carbon substrate. The emulsion as well as the aqueous medium were fed continuously into the fermentor. A Monod-type equation can correlate the specific group rate in the continuous fermentor with the concentration of submicron droplets. The same equation can also be fitted to the data for the conventional-type batch culture in the same fermentor in which an oil phase as well as an aqueous phase existed, if the hydrocarbon concentration in the aqueous phase excluding oil drops is employed as the substrate concentration. This demonstrates that Candida tropicalis takes up only submicron droplets of n-hexadecane as the carbon substrate.     

Mode of uptake of insoluble solid substrates by microorganisms. I: Sterol uptake by an arthrobacter species

The mode of uptake of sterols, which are nearly insoluble in water by an Arthrobacter species, was studied on the basis of substrate transfer via the aqueous phase (solubilization/pseudosolubilization) and through direct contact with sterol particles. Growth of the organism, on stero powder was predominantly in nonlogarithmic in character, indicating a possible limitation of substrate transfer. Soluble sterol was shown to be the preferential form of the substrate for assimilation by the organism. Evidence was obtained for increased solubilizition of beta-sitosterol and cholesterol during microbial growth on these substrates. But the rate of solubilization of beta-sitosterol (3.06 mg L(-1) h(-1)) was too inadequate to account for the observed substrate uptake rare (107 mg L(-1) h(-1)) during growth. A cholesterol solubilization rate of 44 mg L(-1) h(-1) could, however, account to an appreciable extent for the observed cholesterol uptake rate of 140 mg L(-1) h(-1) during growth. Increasing attachement of cells to sterol particles during growth was observed by microscopic examination, indicating that growth may take place over the surface of sterol particles. By using the synthetic surfactant HYOXYD AAO (alkyl aryl polyglycol ether), which prevented attachment of cells to sterol particles without affecting the metabolic integrity of the cells, it was shown that growth indeed took place predominantly on the surface of the sterol particles. Increased generation of finer particles of sterol, which provides increased substrate surface area during growth, was demonstrated. It was concluded that with beta-sitosterol, growth takes place almost entirely by attachement, whereas with cholesterol, about 30% of the growth take place on solubilized substrate and the rest through attachament.     

Fermentation parameters of Peptostreptococcus productus on gaseous substrates (CO,H2/CO2)

Intrinsic growth and substrate uptake parameters were obtained for Peptostreptococcus productus, strain U-1, using carbon monoxide as the limiting substrate. A modified Monod model with substrate inhibition was used for modeling. In addition, a product yield of 0.25 mol acetate/mol CO and a cell yield of 0.034 g cells/g CO were obtained. While CO was found to be the primary substrate, P. productus is able to produce acetate from CO₂ and H₂, although this substrate could not sustain growth. Yeast extract was found to also be a growth substrate. A yield of 0.017 g cell/g yeast extract and a product yield of 0.14 g acetate/g yeast extract were obtained. In the presence of acetate, the maximum specific CO uptake rate was increased by 40% compared to the maximum without acetate present. Cell replication was inhibited at acetate concentrations of 30 g/l. Methionine was found to be an essential nutrient for growth and CO uptake by P. productus. A minimum amount of a complex medium such as yeast extract (0.01%) is, however, required.     

The metabolism of acetylcarnitine and acetate by bovine and hamster epididymal spermatozoa

Since acetylcarnitine has been identified in the epididymal plasma of many mammalian species, we investigated whether acetylcarnitine could serve as an energy substrate for epididymal bull and hamster spermatozoa. Intact caudal cells from both species oxidized [I-14C]acetyl-l-carnitine to 14CO2, in vitro, and the amount oxidized was dependent on time, substrate concentration, and cell number. Within each species, the rate of oxidation was the same as the rate at which free [1-14C]acetate was oxidized. Spermatozoa incubated with [3H]acetyl-L-carnitine hydrolyzed the compound and [3H]acetate accumulated in the medium. Unlabeled acetate added to the incubation medium competed with cellular uptake of [3H]acetate and resulted in further increase in [3H]acetate accumulation in the medium. Furthermore, the acetyl group of acetylcarnitine was oxidized by spermatozoa without concomitant uptake of the carnitine group. Purified plasma membrane vesicles contained an acetylcarnitine hydrolase activity that was solubilized from whole cells by detergents and that could be distinguished from acetylcholinesterase also present in the cells. The solubilized acetylcarnitine hydrolase activity was inhibited by p-hydroxymercuriphenylsulfonate, but not by the specific acetylcholinesterase inhibitors, eserine or BW63C47. The sulfhydryl blocker also inhibited the production of 14CO2 from [1-14C]acetylcarnitine by intact cells; acetylcholinesterase inhibitors did not. From estimates of sperm energy requirements, our results indicate that extracellular acetylcarnitine serves as a physiologically important energy substrate for maturing sperm cells.     

Saturable, energy-dependent uptake of phenanthrene in aqueous phase by Mycobacterium sp. strain RJGII-135

The mechanism of uptake of phenanthrene by Mycobacterium sp. strain RJGII-135, a polycyclic hydrocarbon-degrading bacterium, was examined with cultures grown on phenanthrene (induced for phenanthrene metabolism) and acetate (uninduced). Washed cells were suspended in aqueous solutions of [9-(14)C]phenanthrene, and then the cells were collected by filtration. Low-level steady-state (14)C concentrations in uninduced cells were achieved within the first 15 s of incubation. This immediate uptake did not show saturation kinetics and was not susceptible to inhibitors of active transport, cyanide and carbonyl cyanide m-chlorophenylhydrazone. These results indicated that phenanthrene enters rapidly into the cells by passive diffusion. However, induced cells showed cumulative uptake over several minutes. The initial uptake rates followed saturation kinetics, with an apparent affinity constant (K(t)) of 26 +/- 3 nM (mean +/- standard deviation). Uptake of phenanthrene by induced cells was strongly inhibited by the inhibitors. Analysis of cell-associated (14)C-labeled compounds revealed that the concurrent metabolism during uptake was rapid and was not saturated at the substrate concentrations tested, suggesting that the saturable uptake observed reflects membrane transport rather than intracellular metabolism. These results were consistent with the presence of a saturable, energy-dependent mechanism for transport of phenanthrene in induced cells. Moreover, the kinetic data for the cumulative uptake suggested that phenanthrene is specifically bound by induced cells, based on its saturation with an apparent dissociation constant (K(d)) of 41 +/- 21 nM (mean +/- standard deviation). Given the low values of K(t) and K(d), Mycobacterium sp. strain RJGII-135 may use a high-affinity transport system(s) to take up phenanthrene from the aqueous phase.     

Indophenyl acetate and acetylcholinesterase: binding of a non-specific substrate on the margin of the active center.

1. Indophenyl acetate is a very poor substrate of eel or bovine acetylcholinesterase (acetylcholine hydrolase, EC 3.1.1.7), with a V less than 5% of that of phenyl acetate, but it is a labile ester and in imidazole buffer is hydrolyzed, non-enzymically, even faster than phenyl acetate. 2. Indophenyl acetate completely protects the enzymes against inhibition by diisopropylphosphorofluoridate but promotes inhibition by methanesulfonyl fluoride. 3. With either of these inhibitors the measured rate of inactivation of eel acetylcholinesterase is the same whether activity is determined with this poor substrate or with a good substrate, acetylthiocholine. With bovine enzyme the inactivation rate is 25% lower when assayed with the former substrate. However this preparation contains a minor enzyme component which is involved in hydrolysis of indophenyl acetate but not good substrates, and which is not readily inhibited. When this is taken into account the inactivation rates for bovine acetylcholinesterase, too, are found to be the same in either assay. These and other observations in the literature can be explained if indophenyl acetate, because of its size, cannot fully penetrate into the active center and is bound in adjoining non-polar regions of the protein. From this external position it makes only intermittent contact with the esteratic site. Hence it is slowly hydrolyzed and fails to protect the enzyme against methanesulfonyl fluoride, though it does protect, possibly sterically, against the larger inhibitor diisopropylphosphorofluoridate.     

Ecophysiology of polyphosphate-accumulating organisms and glycogen-accumulating organisms in a continuously aerated enhanced biological phosphorus removal process

Aims: To investigate the ecophysiology of populations of polyphosphate-accumulating organisms (PAO) and glycogen-accumulating organisms (GAO) in communities of a novel acetate fed process removing phosphate from wastewater. Attempts were made to see if acetate could be replaced by an alternative carbon source which did not support the growth of the GAO. Methods and Results: A continuously aerated sequencing batch reactor was operated with different acetate feed levels. Fluorescence in situ hybridization (FISH) showed that Defluviicoccus GAO numbers increased at lower acetate feed levels. With FISH/microautoradiography (MAR) both detected morphotypes of Defluviicoccus assimilated a wider range of substrates aerobically than Accumulibacter PAO. Their uptake profile differed from that reported for the same phylotype in full scale anaerobic : aerobic EBPR plants. Conclusions: This suggests that replacing acetate with another substrate is unlikely to provide Accumulibacter with a selective advantage in this process. Why Defluviicoccus appeared to out-compete Accumulibacter at lower acetate concentrations was not clear. Data suggest physiological and morphological diversity may exist within a single Defluviicoccus phylotype. Significance and Impact of the Study: This study implies that the current FISH probes for Defluviicoccus GAO may not reveal the full extent of their biodiversity, and that more information is required before strategies for their control can be devised.     

STIMULATION OF GROWTH IN SCENEDESMUS OBLIQUUS (CHLOROPHYCEAE) BY HUMIC ACIDS UNDER IRON LIMITED CONDITIONS1,2

Stimulatory affects of humic acids of molecular weight 30,000 or greater on iron-starved Scenedesmus obliquus (Turp.) Kütz. in association with bacteria were studied by growth and Fe uptake experiments. Humic acids stimulated growth of Fe-starved cells by decreasing the lag phase and extending the growth phase. Humic acids stimulated increased algal growth in medium containing EDTA as well as in medium containing no EDTA, indicating humic acids are not stimulating algal growth under Fe limiting conditions by creating a soluble Fe pool. Humic acids decreased Fe availability to Fe-starved S. obliquus. Iron bound to humic acids is unavailable for uptake by Fe-starved cells indicating growth stimulation is not due to chelation effects alone. Stimulation of growth is not a membrane phenomenon as humic acids show the same stimulatory effect when in contact with cells or separated by dialysis membrane. Humic acids also stimulate growth in the dark, with and without aeration, indicating use as a heterotrophic substrate. A photoheterotrophic mechanism is indicated by increased algal growth caused by illuminating cultures, containing humic acids but excluding CO₂.     

Contact Toxicity and Repellency of the Essential Oil from Mentha haplocalyx Briq. against Lasioderma serricorne

The chemical composition of the essential oil obtained by hydrodistillation from the aerial parts of Mentha haplocalyx was investigated by GC‐FID and GC/MS analyses. In sum, 23 components, representing 92.88% of the total oil composition, were identified, and the main compounds were found to be menthol (59.71%), menthyl acetate (7.83%), limonene (6.98%), and menthone (4.44%). By bioassay‐guided fractionation (contact toxicity), three compounds were obtained from the essential oil and identified as menthol, menthyl acetate, and limonene. The essential oil and the three isolated compounds exhibited potent contact toxicity against Lasioderma serricorne adults, with LD₅₀ values of 16.5, 7.91, 5.96, and 13.7 μg/adult, respectively. Moreover, the oil and its isolated compounds also exhibited strong repellency against L. serricorne adults. At the lower concentrations tested and at 2 h after exposure, menthol showed even significantly stronger repellency than the positive control DEET. The study revealed that the bioactivity properties of the essential oil can be attributed to the synergistic effects of its diverse major and minor components, which indicates that the M. haplocalyx oil and its isolated compounds have potential for the development as natural insecticides and/or repellents to control insects in stored grains and traditional Chinese medicinal materials.     

Mechanisms of acetate formation and acetate activation in halophilic archaea

The halophilic archaea Halococcus (Hc.) saccharolyticus, Haloferax (Hf.) volcanii, and Halorubrum (Hr.) saccharovorum were found to generate acetate during growth on glucose and to utilize acetate as a growth substrate. The mechanisms of acetate formation from acetyl-CoA and of acetate activation to acetyl-CoA were studied. Hc. saccharolyticus, exponentially growing on complex medium with glucose, formed acetate and contained ADP-forming acetyl-CoA synthetase (ADP-ACS) rather than acetate kinase and phosphate acetyltransferase or AMP-forming acetyl-CoA synthetase. In the stationary phase, the excreted acetate was completely consumed, and cells contained AMP-forming acetyl-CoA synthetase (AMP-ACS) and a significantly reduced ADP-ACS activity. Hc. saccharolyticus, grown on acetate as carbon and energy source, contained only AMP-ACS rather than ADP-ACS or acetate kinase. Cell suspensions of Hc. saccharolyticus metabolized acetate only when they contained AMP-ACS activity, i.e., when they were obtained after growth on acetate or from the stationary phase after growth on glucose. Suspensions of exponential glucose-grown cells, containing only ADP-ACS but not AMP-ACS, did not consume acetate. Similar results were obtained for the phylogenetic distantly related halophilic archaea Hf. volcanii and Hf. saccharovorum. We conclude that, in halophilic archaea, the formation of acetate from acetyl-CoA is catalyzed by ADP-ACS, whereas the activation of acetate to acetyl-CoA is mediated by an inducible AMP-ACS.Abbreviations. Hc. Halococcus - Hf. Haloferax - Hr. Halorubrum - Hb. Halobacterium An erratum to this article can be found at     

Use of a two phase partitioning bioreactor for the biodegradation of phenol

Summary A two phase organic-aqueous bioreactor system was used to degrade high concentrations of phenol by partitioning the inhibitory substrate into the aqueous phase at sub-inhibitory levels. Pseudomonas putida was used to degrade 4 g of phenol in a fermentor containing 0.5L of 2-undecanone, in which the phenol was dissolved, and 1L of medium in just over 48 hours. This system has the advantage of being self regulating in terms of phenol delivery to the aqueous phase in response to the rate of consumption by the cells, and it eliminates the problem of substrate inhibition commonly observed at high concentrations in a batch system.     

Cometabolic turnover of aniline,phenol and some of their monochlorinated derivatives by the Rhodococcus mutant strain AM 144

One-step conversion of aniline, phenol and some of their monochlorinated derivatives into the corresponding catechols by resting pre-adapted cells of the Rhodococcus mutant strain AM 144 (defective in synthesis of catechol 1,2-dioxygenase) was shown to depend on the availability of an additional metabolizable carbon substrate, e.g. glucose or acetate. A stoichiometric relation existed between the amount of the latter compounds added and the amount of aniline (or phenol, respectively) converted into catechol suggesting that the primary function of the cosubstrates was to provide reducing power to the oxygenative transformation reaction. The observed cosubstrate-dependence generally parallels that seen in previous studies on turnover of different monochloroaromatic non-growth substrates by aromatics-utilizing Rhodococcus wildtype-strains. Cell cultures of strain AM 144 growing at the expense of acetate also proved able to convert aniline into catechol. Typically, growth of the cells was retarded during the phase of aniline transformation as compared to the respective control cultures. Based on the results of these model experiments, it was concluded that (i) in natural microbial communities cometabolically active bacteria would hardly enrich under cometabolic conditions over fast-growing non-cometabolizing bacteria if the latter organisms will tolerate the particular non-growth substrate, and (ii) cometabolizing bacteria would have a selective advantage only if the non-growth substrate to be transformed is a toxic one or if it can serve as a potential nutrient source (e.g., of nitrogen or sulfur).Abbreviations MCA monochloroaniline - MCP monochlorophenol - MCC monochlorocatechol - TLC thin-layer chromatography - MS mass spectrometry - GLC gas-liquid chromatography - UV ultraviolet (range of the spectrum)     

Comparative physiologial studies of the yeast and mycelial forms of Histoplasma capsulaum: uptake and incorporation of L-leucine

l-Leucine entered the cells of both morphological forms of Histoplasma capsulatum by a permease-like system at low external concentrations of substrate. However, at levels greater than 5 x 10(-5)m l-leucine, the amino acid entered the cells both through a simple diffusion-like process and the permease-like system. The rate of the amino acid diffusion into yeast and mycelial forms appeared to be the same, whereas the initial rate of accumulation through the permease-like system was 5 to 10 times faster in the mycelial phase than it was in the yeast phase. The Michaelis constants were 2.2 x 10(-5)m in yeast phase and 2 x 10(-5)m in mycelial phase cells. Transport of l-leucine at an external concentration of 10(-5)m showed all of the characteristics of a system of active transport, which was dependent on temperature and pH. Displacement or removal of the alpha-amino group, or modification of the alpha-carboxyl group abolished amino acid uptake. The process was competitively inhibited by neutral aliphatic side-chain amino acids (inhibition constants ranged from 1.5 x 10(-5) to 6.2 x 10(-5)m). Neutral aromatic side-chain amino acids and the d-isomers of leucine and valine did not inhibit l-leucine uptake. These data were interpreted to mean that the l-leucine transport system is stereospecific and is highly specific for neutral aliphatic side-chain amino acids. Incorporation of l-leucine into macromolecules occurred at almost the same rate in both morphological forms of the fungus. The mycelial phase but not the yeast phase showed a slight initial lag in incorporation. In both morphological forms the intracellular pool of l-leucine was of limited capacity, and the total uptake of the amino acid was a function of intracellular pool size. The initial rate of l-leucine uptake was independent of the level of intracellular pool. Both morphological forms deaminated and degraded only a minor fraction of the accumulated leucine.     

Synthesis of dipeptide precursors with an immobilized thermolysin in ethyl acetate

N-(Benzyloxycarbonyl)-L-aspartyl-L-phenylalanine methyl ester (Z-AspPheOMe), a precursor of the aspartame, and N-(benzyloxycarbonyl)-L-phenylalanyl-Lphenylalanine methyl ester (Z-PhePheOMe) were synthesized from the respective amino acid derivatives with an immobilized thermolysin (EC 3.4.24.4) in ethyl acetate. Various factors affecting the synthesis of these dipeptide precursors were clarified. The initial synthetic rate was the highest at the water content of 3.5% for both reactions. The substrate concentration dependencies of the initial synthetic rate of Z-AspkPheOMe and Z-PhePheOMe with the immobilized enzyme in ethyl acetate were different from those in an aqueous buffer solution saturated with ethyl acetate but similar to those in the aqueous/organic biphasic system using the free enzyme. Particularly, the initial synthetic rate of Z-AspPhOMe increased in order higher than first order with respect to the concentration of L-phenylalanine methyl ester (PheOMe), whereas it decreased sharply with the concentration of N-(benzyloxycarbonyl)-L-aspartic acid (Z-Asp). Such kinetic behavior could be explained by regarding the inside of the immobilized enzyme as being a biphasic mode composed from the organic phase and aqueous phase where the enzymatic reaction takes place. The reaction in the aqueous/organic biphasic system using the free enzyme could be simulated by taking into consideration the partition of the substrate and the initial rate of synthesis in the aqueous buffer saturated with ethyl acetate. Based on this analysis, the rate of reaction with the immobilized enzyme in ethyl acetate could also be predicted. Z-AsPheOMe and Z-PhePheOMe were synthesized by the fed-batch method where the acid component of the substrate was intermittently added during the course of reaction and by the batch method. In the synthesis of Z-AspPheOMe, the synthetic rate and maximum yield of reaction as well as the stability of the immobilized enzyme were higher in the fed-batch reaction than those in the batch reaction. In the synthesis of Z-PhePheOMe, the results obtained by both methods were similar. (c) 1994 John Wiley & Sons, Inc.     

Regulation of methylotrophic and heterotrophic metabolism in Arthrobacter P1. Growth on mixtures of methylamine and acetate in batch and continuous cultures

Incubations of Arthrobacter P1 in batch culture in media with mixtures of acetate and methylamine resulted in sequential utilization of the two carbon substrates, but not in diauxic growth. Irrespective of the way cells were pregrown, acetate was the preferred substrate and subsequent studies showed that this is due to the fact that acetate is a strong inhibitor of the methylamine transport system and amine oxidase in Arthrobacter P1. An analysis of enzyme activities in cell-free extracts showed that synthesis of amine oxidase occurred already in the first growth phase with acetate, whereas rapid synthesis of hexulose phosphate synthase was only observed once methylamine utilization started. It is therefore concluded that in Arthrobacter P1 the synthesis of the enzymes specific for methylamine oxidation is not regulated co-ordinately with those involved in formaldehyde fixation, but induced sequentially by methylamine and formaldehyde, respectively.During growth of Arthrobacter P1 on the same mixture in carbon- and energy source-limited continuous cultures both substrates were used simultaneously and completely at dilution rates below the _max on either of these substrates. Addition of methylamine, in concentrations as low as 0.5 mM, to the medium reservoir of an acetate-limited continuous culture (D=0.10 h^-1) already resulted in synthesis of both amine oxidase and hexulose phosphate synthase. In the reverse experiment, addition of acetate to the medium reservoir of a methylamine-limited continuous culture (D=0.10 h^-1), acetate was initially only used as an energy source. Synthesis of the glyoxylate cycle enzymes, however, did occur at acetate concentration in the feed above 7.5–10 mM. This indicates that at acetate concentrations below 10 mM the metabolism of the C₁ substrate methylamine is able to cause a complete repression of the synthesis of the enzymes involved in carbon assimilation from the C₂ substrate acetate.Abbreviations HPS Hexulose phosphate synthase - MS mineral salts - RuMP ribulose monophosphate     

Uptake modes of octadecane by Pseudomonas sp. DG17 and synthesis of biosurfactant

Aims: In order to gain more insight into the uptake modes of octadecane by bacteria. Methods and Results: A strain that could utilize octadecane well was isolated from crude oil contaminated soil, and named as Pseudomonas sp. DG17 by 16S rDNA analysis. Culture growth result showed that Pseudomonas sp. DG17 grew well in the addition of 200 and 400 mg l^?1 of octadecane, which showed that physical contact between substrate and bacteria was important in the substrate biodegradation. Meanwhile, Pseudomonas sp. DG17 produced rhamnolipids biosurfactant that contains 10 congeners, thus causing the surface tension of the culture medium decline and facilitating the contact between hydrocarbon and bacteria. Scanning‐electron‐microscopy results showed that a disruption of the surface membranes in certain zones was observed in some of the cells grown in 400 mg l^?1 octadecane at 176 h compared with the cells in exponential phase at 72 h due to the production of biosurfactant‐rhamnolipid. Conclusions: These results indicated the possibility that the direct contact with insoluble octadecane droplets occurred before the contact with pseudosolubilization smaller oil droplets. Significance: This report throws more light on the uptake mechanisms of octadecane by bacteria, and proposes the possibility that role of biosurfactant is to increase the contact between hydrocarbon and bacteria by changing the cell membrane structure which needs studied in depth. Impact of Study: Results of this study are useful in the bioremediation of petroleum polluted soil.     

Oxygen dependent lactate utilization by Lactobacillus plantarum

Lactobacillus plantarum P5 grew aerobically in rich media at the expense of lactate; no growth was observed in the absence of aeration. The oxygen-dependent growth was accompanied by the conversion of lactate to acetate which accumulated in the growth medium. Utilization of oxygen with lactate as substrate was observed in buffered suspensions of washed whole cells and in cell-free extracts. A pathway which accounts for the generation of adenosine triphosphate during aerobic metabolism of lactate to acetate via pyruvate and acetyl phosphate is proposed. Each of the enzyme activities involved, nicotinamide adenine dinucleotide independent lactic dehydrogenase, nicotinamide adenine dinucleotide dependent lactic dehydrogenase, pyruvate oxidase, acetate kinase and NADH oxidase were demonstrated in cell-free extracts. The production of pyruvate, acetyl phosphate and acetate was demonstrated using cell-free extracts and cofactors for the enzymes of the proposed pathway.Abbreviations MRS Man, Rogosa and Sharpe (1960) medium modified as in Materials and methods - TY Tryptone Yeast Extract broth - OUL Oxygen uptake with lactate as substrate - DCPIP 2,6-Dichlorophenolindophenol - LDH Lactic dehydrogenase     

Uptake of acetate by Acinetobacter calcoaceticus

The uptake of acetate by intact nongrowing cells of Acinetobacter calcoaceticus was studied in dependence on the C-source (acetate, n-alcanes, yeast extract, succinate, L-malate) and the growth phase. Single kinetic parameters of acetate uptake were determined. The best acetate uptake was observed with cells cultivated with acetate as the only C-source. Bacteria in the early growth phase were found to transfer acetate twice as fast as cells of the late logarithmic growth phase. The uptake of acetate can be described by a biphasic saturation kinetics with 2 Km values: the Km value for the first phase being 1.10(-5) M, and for the second one, 1.8 .10(-4) M. The corresponding maximal uptake rates are 8 and 37 mM/min/mg dry weight, respectively. Alpha-ketoglutarate, fumarate, L-malate, and oxalacetate inhibit the initial uptake of acetate. Uranylacetate, inhibitors of the respiratory chain and proton conductors in part completely inhibit the uptake of acetate.     

Metabolism of Monoterpenes : EVIDENCE FOR COMPARTMENTATION OF l-MENTHONE METABOLISM IN PEPPERMINT (MENTHA PIPERITA) LEAVES

Previous studies have shown that the monoterpene ketone l-[G-(3)H]-menthone is reduced to the epimeric alcohols l-menthol and d-neomenthol in leaf discs of flowering peppermint (Mentha piperita L.), and that a portion of the menthol is converted to menthyl acetate while the bulk of the neomenthol is transformed to neomenthyl-beta-d-glucoside (Croteau, Martinkus 1979 Plant Physiol 64: 169-175). The metabolic disposition of the epimeric reduction products of the ketone, which is a major constituent of peppermint oil, is highly specific, in that little neomenthyl acetate and little menthyl glucoside are formed. However, when l-[3-(3)H]menthol and d-[3-(3)H]neomenthol are separately administered to leaf discs, both menthyl and neomenthyl acetates and menthyl and neomenthyl glucosides are formed with nearly equal facility, suggesting that the metabolic specificity observed with the ketone precursor was not a function of the specificity of the transglucosylase or transacetylase but rather a result of compartmentation of each stereospecific dehydrogenase with the appropriate transferase. A UDP-glucose:monoterpenol glucosyltransferse, which utilized d-neomenthol or l-menthol as glucose acceptor, was demonstrated in the 105,000g supernatant of a peppermint leaf homogenate, and the enzyme was partially purified and characterized. Co-purification of the acceptor-mediated activities, and differential activation and inhibition studies, provided strong evidence that the same UDP-glucose-dependent enzyme could transfer glucose to either l-menthol or d-neomenthol. Determination of K(m) and V for the epimeric monoterpenols provided nearly identical values. The acetylcoenzyme A:monoterpenol acetyltransferase previously isolated from peppermint extracts (Croteau, Hooper 1978 Plant Physiol 61: 737-742) was re-examined using l-[3-(3)H]menthol and d-[3-(3)H]neomenthol as acetyl acceptors, and the K(m) and V for both epimers were, again, very similar. These results demonstrate that the specific in vivo conversion of l-menthone to l-menthyl acetate and d-neomenthyl-beta-d-glucoside cannot be attributed to the selectivity of the transferases, and they clearly indicate that the metabolic specificity observed is a result of compartmentation effects.