Relative expression of the products of glyoxylate bypass operon: contributions of transcription and translation

Although the genes of the aceBAK operon are expressed from the same promoter, the relative cellular levels of their products are approximately 0.3:1:0.003. Gene and operon fusions with lacZ were constructed to characterize this differential expression. The upshift in expression between aceB and aceA resulted from differences in translational efficiency. In contrast, inefficient translation and premature transcriptional termination contributed to the downshift in expression between aceA and aceK. Premature transcriptional termination occurred within aceK and appears to result from inefficient translation. Deletion of repetitive extragenic palindromic elements between aceA and aceK had little effect on the relative expression of these genes. Rather, the sequences responsible for inefficient expression of aceK lie within the aceK ribosome binding site.

Insulin accelerates the post germinative development of several fat-storing seeds

The effect of insulin and insulin like growth factors I and II on sunflower, watermelon and cucumber cotyledons has been examined. Each peptide stimulates an increase in the activity of several glyoxysomal enzymes which catalyze the conversion of fat to carbohydrate. These results provide the first evidence for the action of insulin and insulin like growth factors in plants.

Evidence for the glyoxylate cycle in human liver

The enzymatic activities unique to the glyoxylate cycle of higher plants and certain lower invertebrates, isocitrate lyase and malate synthase, have been demonstrated in homogenates prepared from human liver. Human liver can also carry out cyanide-insensitive fatty acid oxidation from palmitate. Utilizing light microscopic immunocytochemistry with an antibody produced against Euglena malate synthase, this enzyme localizes in numerous ovoid granules in human hepatocytes. Also, immunocytochemistry using antibodies produced against rat fatty acyl-CoA oxidase showed that this enzyme was localized in similar structures. With routine cytochemistry, catalase was seen in identical granular bodies. Both catalase and fatty acyl-CoA oxidase are peroxisomal enzymes. The presence of malate synthase in liver homogenates was further confirmed by Western blot analysis. These data suggest that the human liver may be capable of utilizing the carbon backbone of fatty acids for carbohydrate synthesis since the glyoxylate cycle in lower organisms subserves this anabolic function.

Differentially regulated malate synthase genes participate in carbon and nitrogen metabolism of S. cerevisiae

We have isolated a second gene (MLS1), which in addition to DAL7, encodes malate synthase from S. cerevisiae. Expression of the two genes is specific for their physiological roles in carbon and nitrogen metabolism. Expression of MLS1, which participates in the utilization of non-fermentable carbon sources, is sensitive to carbon catabolite repression, but nearly insensitive to nitrogen catabolite repression. DAL7, which participates in catabolism of the nitrogenous compound allantoin, is insensitive to carbon catabolite repression, but highly sensitive to nitrogen catabolite repression. Results obtained with null mutations in these genes suggest that S. cerevisiae contains at least one and perhaps two additional malate synthase genes.

Developmental regulation of expression of the malate synthase gene in transgenic plants

The cucumber malate synthase (MS) gene, including 1856 bp of 5' non-transcribed sequence, has been transferred into Petunia (Mitchell) and Nicotiana plumbaginifolia plants using an Agrobacterium binary vector. The transferred gene is found in variable copy number in different transformants, and is stably transmitted in each case as a single Mendelian character. Transgene mRNA accumulates in the seedling during the first three days of germination, then declines in amount as the cotyledons emerge from the seed. The decline is more pronounced in light-grown seedlings than in dark-grown seedlings. Expression of the MS transgene is also detected at a low level in petals of transformed Petunia plants. In these respects the pattern of MS gene expression is similar in cucumber and in transformed plants, showing that the transferred DNA fragment contains a functional MS gene. A 1076 bp fragment of 5' sequence was linked to the beta-glucuronidase reporter gene and transferred into Nicotiana, where it was shown to direct temporal and spatial patterns of expression similar to that of the complete MS gene. However, histochemical localisation of beta-glucuronidase activity demonstrated that the chimaeric gene is expressed not only in cotyledons of transgenic plants, but also in endosperm and some hypocotyl cells during early germination. The relevance of these findings to the control of malate synthase gene expression is discussed.

Premeiotic disruption of the Neurospora crassa malate synthase gene by native and divergent DNAs

Repeat-induced point mutation (RIP) has been used to generate new mutations in the previously uncharacterised gene for malate synthase in Neurospora crassa. Molecular clones carrying the am (NADP-glutamate dehydrogenase) gene and the malate synthase gene from either N. crassa or Aspergillus nidulans have been introduced into Neurospora as ectopic duplicate copies by transformation, selecting for the am+ function in a deletion host. A number of meiotic progeny derived from these transformants were unable to use acetate as sole carbon source, yielded no detectable malate synthase activity and demonstrated extensive cytosine methylation of their duplicated sequences. The new locus has been designated acu-9 and has been assigned to linkage group VII.

Translational or post-translational processes affect differentially the accumulation of isocitrate lyase and malate synthase proteins and enzyme activities in embryos and seedlings of Brassica napus

We have analyzed the accumulation of the glyoxylate cycle enzymes isocitrate lyase and malate synthase in embryos and seedlings of Brassica napus L. The two enzyme activities and proteins begin to accumulate during late embryogeny, reach maximal levels in seedlings, and are not detected in young leaves of mature plants. We showed previously that mRNAs encoding the two enzymes exhibit similar qualitative patterns of accumulation during development and that the two mRNAs accumulate to different levels in both embryos and seedlings (L. Comai et al., 1989, Plant Cell 1, 293-300). In this report, we show that the relative accumulation of the proteins and activities do not correspond to these mRNA levels. In embryos and seedlings, the specific activities of isocitrate lyase and malate synthase are approximately constant. By contrast, the ratio of malate synthase protein to mRNA is 14-fold higher than that of isocitrate lyase. Differences in the translational efficiencies of the two mRNAs in vitro do not appear to account for the discrepancy between mRNA and protein levels. Our results suggest that translational and/or post-translational processes affect differentially the accumulation of the proteins.

Hibernation activates glyoxylate cycle and gluconeogenesis in black bear brown adipose tissue

Biochemical studies on brown adipose tissue removed from a hibernating black bear and a non-hibernating control animal demonstrate that this tissue: (1) can carry out cyanide-insensitive fatty acid oxidation, and (2) possesses catalase activity and the enzyme activities unique to the glyoxylate cycle, isocitrate lyase and malate synthase. These activities are all markedly increased in brown fat obtained from the hibernating animal. Additionally, hibernation enhances the ability of the tissue to synthesize glycogen in the presence of a fatty acid substrate. The glyoxylate cycle enzymes and the ability to convert fatty acid carbons to glucose have been generally regarded as being absent from vertebrate cells and tissues.

Glyoxylate cycle in the epiphyseal growth plate: isocitrate lyase and malate synthase identified in mammalian cartilage

Peroxisomes were identified in chondrocytes from all zones of the mammalian epiphyseal growth plate by using light microscopic techniques for the cytochemical demonstration of catalase, the marker enzyme for these organelles. Additional cytochemistry showed the presence of malate-synthase-positive structures within the chondrocytes. The latter enzyme, also associated with peroxisomes, is unique to the glyoxylate shunt, a metabolic pathway thought to be absent in vertebrate tissues. The glyoxylate cycle allows the net conversion of lipid to carbohydrate, i.e., gluconeogenesis. Biochemical studies on growth plate cartilage indicate that this tissue has the capacity to carry out cyanide-insensitive B-oxidation of fatty acids. The latter takes place in a nonmitochondrial compartment, most likely the peroxisomal compartment. Additionally, both of the unique enzymes associated with the glyoxylate cycle, i.e., isocitrate lyase and malate synthase, were also identified in a cell-free homogenate of this cartilage. These studies indicate that cartilage, a poorly vascularized tissue characterized by its low oxygen tension and anaerobic glycolysis, may have the capacity to convert lipid to carbohydrate, i.e., gluconeogenesis via the glyoxylate pathway. In this way, cartilage may be unique among mammalian tissues.

Coordinate expression of transcriptionally regulated isocitrate lyase and malate synthase genes in Brassica napus L

We have analyzed the temporal and spatial expression of genes encoding the glycoxylate cycle enzymes isocitrate lyase and malate synthase in Brassica napus L. to determine whether they are coordinately expressed. Both enzymes participate in reactions associated with lipid mobilization in oilseed plant seedlings and are sequestered in a specialized organelle, the glyoxysome. We have identified an isocitrate lyase cDNA clone containing the complete protein coding region. RNA blot and in situ hybridization studies with isocitrate lyase and malate synthase cDNA clones from B. napus showed that the genes exhibit similar expression patterns. The mRNAs begin to accumulate during late embryogeny, reach maximal levels in seedling cotyledons, are not detected at significant amounts in leaves, and are distributed similarly in cotyledons and axes of seedlings. Furthermore, transcription studies with isolated nuclei indicate that the genes are controlled primarily although not exclusively at the transcriptional level. We conclude that glyoxysome biogenesis is regulated in part through the coordinate expression of isocitrate lyase and malate synthase genes.

Glyoxylate cycle in the rat liver: effect of vitamin D3 treatment

Evidence for the glyoxylate cycle in the mammalian rat liver was sought. Activity of two unique glyoxylate cycle enzymes, isocitrate lyase and malate synthase, was found in rat liver homogenates. Vitamin D3 treatment of rachitic animals produced a five- and fourfold increase, respectively, in the activity of these enzymes. Vitamin D3 also increased the peroxisomal fatty acid oxidation and the accumulation of glycogen in liver slices in the presence of palmitate. These data suggest that the mammalian rat liver can convert fatty acid carbon to carbohydrate carbon directly.

The glyoxylate cycle in rat epiphyseal cartilage: the effect of vitamin-D3 on the activity of the enzymes isocitrate lyase and malate synthase

The effect of vitamin-D deficiency and subsequent vitamin-D replacement on the metabolism of rat epiphyseal growth plate cartilage was studied. Biochemical analyses showed the presence of the two unique glyoxylate cycle enzymes isocitrate lyase and malate synthase in cartilage. The activity of these enzymes was markedly increased after treatment with the vitamin. Additionally, rat cartilage showed the capacity to oxidize fatty acid in the presence of cyanide. This cyanide-insensitive fatty acid oxidation is characteristic of peroxisomal B-oxidation rather than mitochondrial B-oxidation. Vitamin-D treatment also increased fatty acid oxidation. Lastly, incubation of rat cartilage in the presence of a fatty acid substrate such as palmitate, resulted in a higher tissue glycogen content. Tissue glycogen was further elevated by vitamin-D. Such data indicate the presence of glyoxylate cycle enzymes in a vertebrate tissue and raise the possibility that mammalian cartilage has the capacity to convert lipid to carbohydrate.

Molecular cloning, identification and transcriptional analysis of genes involved in acetate utilization in Neurospora crassa

Four Neurospora crassa genomic clones have been selected as hybridizing much more strongly to labelled mRNA isolated from acetate-grown mycelium than to mRNA from sucrose-grown mycelium. Hybridization of restriction fragments with acetate-specific mRNA or cDNA has been used to delimit the transcribed region(s) of each clone. The transcription of all four clones is strongly induced by transfer of growing mycelium from sucrose to acetate as sole carbon source. In wild-type mycelium, mRNAs corresponding to the four clones reach maximum levels after four hours of induction. They accumulate more rapidly and reach higher levels in an acetate non-utilizing mutant, acu-7, which has been found to overproduce enzymes of the glyoxylate cycle and to have a partial block in the TCA cycle. Molecular transformation of a Neurospora acu-5 mutant and of an Aspergillus nidulans acuE mutant by DNA of clone 2 and clone 1, respectively, strongly suggests that clone 2 codes for acetyl-coenzyme A synthetase and that clone 1 codes for malate synthase. The transcribed segments of clones 1 and 2 each hybridize to corresponding clones from Aspergillus nidulans (R. A. Sandeman and M. J. Hynes, personal communication).

Malate synthase: proof of a stepwise Claisen condensation using the double-isotope fractionation test

Although aldolase-catalyzed condensations proceed by stepwise mechanisms via the intermediacy of nucleophilic enol(ate)s or enamines, the mechanisms of those enzymes that catalyze Claisen-type condensations are unclear. The reaction pathway followed by an enzyme from this second group, malate synthase, has been studied by the double-isotope fractionation method to determine whether the reaction is stepwise or concerted. In agreement with earlier work, a deuterium kinetic isotope effect D(V/K) of 1.3 +/- 0.1 has been found when [2H3]acetyl-CoA is the substrate. The 13C isotope effect at the aldehydic carbon of glyoxylate has also been measured. For this determination, the malate product (containing the carbon of interest at C-2) was quantitatively transformed into a new sample of malate having the carbon of interest at C-4. This material was decarboxylated by malic enzyme to produce the appropriate CO2 for isotope ratio mass spectrometric analysis. The 13C isotope effect with [1H3]acetyl-CoA [that is, 13(V/K)H] is 1.0037 +/- 0.0004. By use of the known values of the intermolecular and intramolecular deuterium effects and of 13(V/K)H, the value of the 13C isotope effect when deuteriated [2H3]acetyl-CoA is the substrate [that is, 13(V/K)D] can be predicted for three possible mechanisms. If 13(V/K)H is a kinetic isotope effect and the reaction is concerted, the value of the 13C effect on deuteriation of acetyl-CoA will rise to 1.011; if 13(V/K)H is a kinetic isotope effect and the reaction is stepwise, the value of the 13C effect will fall to 1.0025; and if the 13C effect is an equilibrium isotope effect deriving from glyoxylate dehydration, the reaction is necessarily stepwise, and the value of 13(V/K)D will be 1.0037, unchanged from that of 13(V/K)H. Experimentally, the value of 13(V/K)D is 1.0037 +/- 0.0007, which requires that malate synthase follow a stepwise path. It is therefore clear that the two salient characteristics of enzymes that catalyze Claisen-like condensations, namely, the absence of enzyme-catalyzed proton exchange with solvent and the inversion of the configuration at the nucleophilic center, which had been suggestive of a concerted pathway, are not mechanistically diagnostic.

Isolation and characterization of Salmonella typhimurium glyoxylate shunt mutants

Growth of Salmonella typhimurium on acetate as a sole carbon source requires expression of the glyoxylate shunt; however, the genes for the glyoxylate shunt enzymes have not been previously identified in S. typhimurium. In this study, we isolated transposon insertions in the genes for the two unique enzymes of this pathway, aceA (isocitrate lyase) and aceB (malate synthase). The aceA and aceB genes were located at 89.5 min on the S. typhimurium genetic map. Genetic linkage to nearby loci indicated that the relative gene order is purDJ metA aceB aceA. Transposon insertions in aceB were polar on aceA, suggesting that the genes form an operon transcribed from aceB to aceA. Transcriptional regulation of the aceBA operon was studied by constructing mini-Mu d(lac Kan) operon fusions. Analysis of these fusions indicated that expression of the aceBA operon is regulated at the level of transcription; the aceBA genes were induced when acetate was present and repressing carbon sources were absent. Although glucose represses expression of the aceBA operon, repression does not seem to be mediated solely by cyclic AMP-cyclic AMP receptor protein complex. Mutants with altered regulation of the aceBA operon were isolated.

Metabolic studies on mycobacteria. IV. Assay of isocitrate lyase and malate synthase activity in M. leprae

Cell free extracts from M. tuberculosis H37 Rv, M. smegmatis armadillo derived M. leprae and normal armadillo liver homogenates were assayed for the presence of isocitrate lyase and malate synthase activity. It was observed that significant amount of isocitrate lyase and malate synthase activity was present in M. tuberculosis H37 Rv, M. smegmatis and armadillo derived M. leprae. No such activity was demonstrable in cell free extracts of normal armadillo liver. It is concluded that M. leprae like other mycobacteria has the capability to metabolise via glyoxylate bypass of TCA cycle. These findings may be relevant for understanding the energy metabolism of M. leprae under stress conditions and possibly the 'persister' stage.

Effects of unsaturated fatty acids on the peroxisomal enzyme activities of Tetrahymena pyriformis

The effects of unsaturated fatty acids on the activities of peroxisomal enzymes of Tetrahymena pyriformis were investigated. When saturated fatty acids and the corresponding unsaturated fatty acids (C18) were added to the culture medium at 0.05%, the activities of peroxisomal enzymes [fatty acyl-CoA oxidase (FAO), carnitine acetyltransferase (CAT), isocitrate lyase (ICL), and malate synthase (MS)] were significantly increased. The order of effectiveness was linoleic acid greater than oleic acid greater than stearic acid. However, alpha-linolenic acid and gamma-linolenic acid at the same concentration were lethal to the cells. The inhibitory effect on growth disappeared upon addition of an antioxidant, alpha-tocopherol. Lipid peroxides derived from unsaturated fatty acids induced marked cell lysis. In the presence of a low concentration (0.005%) of linolenic acid the production of lipid peroxide was lower and no inhibitory effect on the growth was observed, while the activities of peroxisomal enzymes participating in lipid metabolism and that of catalase were significantly increased. These results indicate that the peroxisomal enzyme systems related to the beta-oxidations of fatty acids and the glyoxylate cycle are regulated by unsaturated long-chain fatty acids, including linolenic acid, at low concentrations, as well as by saturated fatty acid in the medium.

Purification of peroxisomal malate synthase from alkane-grown Candida tropicalis and some properties of the purified enzyme

Malate synthase, one of the key enzymes in the glyoxylate cycle, was purified from peroxisomes of alkane-grown yeast, Candida tropicalis. The enzyme was mainly localized in the matrix of peroxisomes, judging from subcellular fractionation followed by exposure of the organelles to hypotonic conditions. The molecular mass of this peroxisomal malate synthase was determined to be 250,000 daltons by gel filtration on a Sepharose 6B column as well as by ultracentrifugation. On sodium dodecylsulfate/polyacrylamide slab-gel electrophoresis, the molecular mass of the subunit of the enzyme was demonstrated to be 61,000 daltons. These results revealed that the native form of this enzyme was homo-tetrameric. Peroxisomal malate synthase showed the optimal activity pH at 8.0 and absolutely required Mg2+ for enzymatic activity. The Km values for Mg2+, acetyl-CoA and glyoxylate were 4.7 mM, 80 microM and 1.0 mM, respectively.

Branch point control by the phosphorylation state of isocitrate dehydrogenase. A quantitative examination of fluxes during a regulatory transition

To understand how enzymatic pathways respond to changing external conditions, the fluxes through the tricarboxylic acid cycle and ancillary reactions were determined under three different growth conditions in Escherichia coli. The velocities through the major steps in each pathway were measured (a) for growth on acetate alone, (b) for growth on acetate plus glucose, and (c) during the transition caused by addition of glucose to cells growing on acetate. During the transition, the carbon flow through the Krebs cycle decreased by a factor of 5 despite an increase in the growth rate of the culture. Under these conditions, the dephosphorylation of isocitrate dehydrogenase caused a 4-fold increase in its activity. This, together with the decreased rate of substrate production and the kinetic parameters of the branch point enzymes, led to a cessation of the flux through the glyoxylate shunt. The decreased rate of acetyl-CoA turnover, not an inhibition of acetate transport, caused a slower rate of acetate uptake in the presence of glucose. The modulation of protein phosphorylation and metabolite levels is one of the regulatory mechanisms which enables the bacterium to make dramatic shifts between metabolic pathways within a fraction of a doubling time.

Metabolic studies on mycobacteria--II. Glyoxylate by-pass (TCA cycle) enzymes of slow and fast growing mycobacteria

Glyoxylate by-pass of tricarboxylic acid cycle (TCA) comes into prominence during survival of microorganisms under oxygen limitations and study of these enzymes may contribute to understanding of physiology of 'persisters' in various mycobacterial diseases. The enzymes of glyoxylate by-pass have been assayed in the extracts of various mycobacterial species, namely, M. tuberculosis H37Rv, M. tuberculosis H37Ra, M. flavescens, M. vaccae, M. smegmatis and Mycobacteria strain w (M.w.). M.w. has been included because of its close antigenic resemblance to M. leprae. It has been found that all of the above investigated species possess isocitrate lyase and malate synthetase, the key enzymes of glyoxylate by-pass. The presence of the enzymes is being reported for the first time in M. flavescens, M. vaccae and M.w. whereas these were earlier shown to be present in M. tuberculosis and M. smegmatis. It was also demonstrated in M.w. where acetate alone could not serve as sole source of carbon, but in the presence of glycerol stimulates the activity of glyoxylate pathway enzymes. The importance of these findings has been discussed.

A small-angle X-ray scattering study on pre-irradiated malate synthase. The influence of formate, superoxide dismutase, and catalase on the X-ray induced aggregation of the enzyme

The sulfhydryl enzyme malate synthase from baker's yeast was X-irradiated with 6 kGy in air-saturated aqueous solution (enzyme concentration: congruent to 10 mg/ml; volume: 120 microliters), in the absence or presence of the specific scavengers formate, superoxide dismutase, and catalase. After X-irradiation, a small aliquot of the irradiated solutions was tested for enzymic activity while the main portion was investigated by means of small-angle X-ray scattering. Additionally, an unirradiated sample without additives was investigated as a reference. Experiments yielded the following results: X-irradiation in the absence of the mentioned scavengers caused considerable aggregation, fragmentation, and inactivation of the enzyme. The dose Dt37 for total (= repairable + non-repairable) inactivation resulted as 4.4 kGy. The mean radius of gyration was found to be about 13 nm. The mean degree of aggregation was obtained as 5.7, without correction for fragmentation. An estimation based on the thickness factor revealed that about 19% of material might be strongly fragmented. When this amount of fragments was accordingly taken into account, a value of 7.1 was obtained as an upper limit for the mean degree of aggregation. The observed retention of the thickness factor and the finding of two different cross-section factors are in full accord with the two-dimensional aggregation model established previously (Zipper and Durchschlag, Radiat. Environ. Biophys. 18, 99-121 (1980)). The presence of catalytic amounts of superoxide dismutase and/or catalase, in the absence of formate, during X-irradiation reduced both aggregation and inactivation significantly. The presence of formate (10 or 100 mM) during X-irradiation led to a strong decrease of aggregation and inactivation.(ABSTRACT TRUNCATED AT 250 WORDS)

Sugar synthesis in Leptospira. II. Presence of glyoxylate cycle enzymes

The presence and some properties of the key enzymes of the glyoxylate cycle, isocitrate lyase (threo-Ds-isocitrate glyoxylate-lyase, EC 4.1.3.1) and malate synthase (L-malate glyoxylate-lyase (CoA-acetylating) EC 4.1.3.2), were investigated in Leptospira biflexa. Isocitrate lyase activity was found for the first time in the organism. The enzyme was induced by ethanol but not by acetate. The optimum pH was 6.8. The activity was inhibited by phosphoenolpyruvate, a specific inhibitor of isocitrate lyase. The optimum pH of malate synthase of L. biflexa was about 8.5. The Km value for glyoxylate was 3.0 X 10(-3) M and the activity was inhibited by glycolate, the inhibitor. The results strongly suggested the presence of a glyoxylate cycle in Leptospira. The possibility that the glyoxylate cycle plays an essential role in the synthesis of sugars, amino acids and other cellular components as an anaplerotic pathway of the tricarboxylic acid cycle in Leptospira was discussed.

Oligomerization of malate synthase during glyoxysome biosynthesis

The octameric malate synthase, found in glyoxysomes of plants, is synthesized as monomeric precursor in the cytoplasm. The precursor form does not possess a different subunit molecular weight than the mature organellar enzyme, but differs from the organellar protein by not oligomerizing and aggregating. This was shown by synthesis in a cell-free reticulocyte lysate system programmed with cucumber poly A+-mRNA followed by immunoprecipitation of the radiolabeled translation products. The precursor form of malate synthase was also detected in vivo in the cytosol of pulse-labeled cucumber cotyledons after immunoprecipitation of the radiolabeled polypeptide. At low salt concentrations, mature malate synthase can be converted into aggregated forms. However, the precursor form obtained either by in vitro translation or by extraction from the cytosol after short pulses of radioactive methionine, could neither be oligomerized into the octameric form nor aggregated into the 100-S form. Processing of malate synthase, assumed to be a requisite for oligomerization, took place rapidly in the glyoxysomes, but proceeded only slowly in the cytosol. This was demonstrated both by the uptake of in vitro-translated malate synthase into glyoxysomes, and by analysis of newly synthesized malate synthase detectable in glyoxysomes in vivo. In both cases the octamer was by far the predominant form.

Malate synthase: aggregation, deaggregation, and binding of phospholipids

Octameric malate synthase is located in the glyoxysomes of cucumber cotyledons. The enzyme is predominantly confined to the organelle's membrane and can be solubilized with Mg2+. Separation of cell structures in a zonal rotor afforded, besides glyoxysomes, two other zones with malate synthase activity, viz., in the gradient supernatant and in the range of the endoplasmic reticulum (ER). Malate synthases of these three fractions were purified to apparent homogeneity and classified according to their molecular weight. Differences in subunit molecular weight, however, could not be detected when malate synthases from the three fractions were compared. Mature malate synthase, as well as malate synthase prepared from fractions sedimenting similarly to the ER, exhibited the following behavior with respect to aggregation and deaggregation: at low salt concentrations and in the absence of Mg2+, the enzyme shifted to aggregated forms (approx 100 S); with 2 mM Mg2+, malate synthase deaggregated and occurred predominantly as an octamer (19 S). By changing buffer conditions, mature forms of malate synthase could be interconverted repeatedly between octameric and aggregated forms, whereas a monomeric form (5 S), prepared from soluble fractions assigned to the cytosol, did not oligomerize. The amphipathic properties of malate synthase were demonstrated by the enzyme's capacity for binding phospholipids.

Constitutive uptake and degradation of fatty acids by Yersinia pestis

Yersinia pestis was found to utilize palmitic acid as a primary carbon and energy source. No inhibition of growth by palmitic acid was observed. Comparison of palmitic acid uptake by cells pregrown either with or without palmitic acid demonstrated that fatty acid uptake was constitutive. High basal levels of two enzymes of beta-oxidation, beta-hydroxyacyl-coenzyme A dehydrogenase and thiolase, and the two enzymes of the glyoxylate shunt, isocitrate lyase and malate synthase, were found in cells grown in defined medium with glucose. Elevated levels of all four enzymes were found when cells were grown with acetate as a primary carbon and energy source, and even higher levels were observed when palmitic acid was provided as a primary carbon and energy source. High-pressure liquid chromatography was used to demonstrate that, in the presence of glucose, uniformly labeled [14C]palmitic acid was converted to intermediates of the tricarboxylic acid cycle and glyoxylate shunt. Pregrowth with palmitic acid was not required for this conversion. Strains lacking the 6- or the 47-megadalton plasmid did not take up [3H]palmitic acid but did possess levels of enzyme activity comparable to those observed in the wild-type strain.

The regulation of NADP-linked isocitrate dehydrogenase in Aspergillus nidulans

The regulation of NADP-linked isocitrate dehydrogenase (NADP-IDH) has been studied in wild-type and mutant strains of Aspergillus nidulans. In the wild-type strain studied, the levels of NADP-IDH vary in a similar way to those of acetamidase, acetyl-CoA synthase, isocitrate lyase and malate synthase under all growth conditions used. Similarly, fac mutants, which are altered in the regulation of these enzymes of acetate utilization, are affected in NADP-IDH levels in a parallel fashion, as are cre mutants, which show altered carbon catabolite repression of this group of enzymes. Possible functions of the NADP-IDH enzyme are considered.

Large-scale purification and some properties of malate synthase from baker's yeast

1. Malate synthase from baker's yeast (5 kg) was purified 400--500-fold to homogeneity. About 50--200 mg homogeneous enzyme were obtained within a week in a yield of 30% with reference to the total activity in cell-free crude extracts. The enzyme, pI = 7.5, was pure as judged from ultracentrifugal and gel electrophoretic studies. 2. Sedimentation and diffusion coefficients were determined: S 0 20,w = 8.26 +/- 0.05 S, D 0 20,w = 4.5 +/- 0.1 X 10(-7) cm2 s-1. The molecular weight of the synthase was found to be 175 000 +/- 10 000 and 180 000 +/- 10 000 by sedimentation/diffusion and by high-speed sedimentation equilibrium respectively. It was concluded from these and other results that malate synthase has a molecular mass of 180 000 +/- 10 000. 3. The synthase on sodium dodecylsulfate gel electrophoresis was dissociated to yield a single specimen of Mr about 66 000. The result indicates a composition of the native enzyme from three subunits of identical or nearly identical mass. 4. The binding of acetyl-coenzyme A to the synthase is independent of Mg2+ but that of glyoxylate is strictly dependent on the presence of Mg2+. Kinetic studies indicate that the malate synthase reaction follows a sequential random mechanism. 5. The intermolecular isotopic effect, kH:k2H = 1.4, was determined with acetyl-coenzyme A and [2H3]acetyl-coenzyme A under several different experimental conditions and was shown to reflect different maximal velocities of the two substrates. An enzymic procedure for the preparation of doubly labelled [3H, 14C]acetyl-coenzyme A is also presented.

Glyoxylate bypass enzymes in Yersinia species and multiple forms of isocitrate lyase in Yersinia pestis

Isocitrate lyase and malate synthase, the two unique enzymes of the glyoxylate cycle, were detected in crude extracts of Yersinia pestis, Y. pseudotuberculosis, and Y. enterocolitica. Y. pestis, unlike Escherichia coli and the other yersiniae tested, yielded two forms of isocitrate lyase during growth on acetate. These forms differed in electrophoretic mobility and temperature optima. One form (A) was present during growth on acetate, but was absent during growth on alternate carbon sources such as glucose. The second form (B) was not constitutive, but was found during growth on acetate, glucose, xylose, or other complex carbon sources. Itaconate, a succinate analog which inhibited both forms of isocitrate lyase in crude extracts, did not affect the growth of Y. pestis under conditions where little isocitrate lyase activity was detected. This inhibitor, however, retarded the growth of Y. pestis under conditions where acetate was provided as the primary carbon and energy source as well as under all conditions in which either form of isocitrate lyase was evident. This suggests that the B form may play an important role in the growth of this bacterium under conditions where a requirement for the classical anaplerotic sequence involving this enzyme is not apparent.

Role and control of isocitrate lyase in Candida lipolytica

Mutants of Candida lipolytica that were unable to grow on acetate but able to utilize succinate or glycerol as a sole carbon source were isolated. Amongst the mutants isolated, one strain (Icl-) was specifically deficient in isocitrate lyase activity, whereas another strain (Acos-) was deficient in acetyl coenzyme A synthetase activity. Since the Icl- mutant could not grow either on n-alkane or its derivatives, such as fatty acid and long-chain dicarboxylic acid, any anaplerotic route other than the glyoxylate pathway was inconceivable as far as growth on these carbon sources was concerned. Acetyl coenzyme A is most likely a metabolic inducer of isocitrate lyase and malate synthase, because the Acos- mutant was characterized by the least susceptibility to induction of these enzymes by acetate. The structural gene for isocitrate lyase was most probably impaired in the Icl- mutant, since revertants (Icl-) produced thermolabile isocitrate lyase. The production of isocitrate from n-alkane by the revertants was enhanced in comparison with the parental strain.

Occurrence and biosynthesis of glyoxysomal enzymes in ripening cucumber seeds

Glyoxysomal enzymes, being necessary during seed germination, are already synthesized at the stage of seed maturation. Two stages of embryogenesis of cucumber seeds (Cucumis sativus) were investigated. One was characterized by the presence of microbodies showing catalase and enoyl-CoA hydratase activities. Microbodies at a later stage contained, in addition, malate synthase and isocitrate lyase. The biosynthesis of three microbody components was followed in a pulse chase-labelling experiment which demonstrated that the biosynthesis of cytosolic species of malate synthase, isocitrate lyase and enoyl-CoA hydratase preceded the appearance of these proteins in microbodies.

19S cytosolic malate synthase. A small pool characterized by rapid turnover

A pool of 19S malate synthase was detected in the cytosol. This pool was separated from the microsomal and glyoxysomal malate synthase when cotyledons of germinating seed of Cucumis sativus were fractionated. An early stage of seed germination was selected for our investigations, when 100S "microsomal" malate synthase was also present. 1) When L-[35S]methionine was applied in vivo to label cellular proteins the small pool of 19S malate synthase was found to contain the highest specific activity compared to microsomal or glyoxysomal malate synthase. 2) The kinetics of specific radioactivity in malate synthase during a pulse chase-labelling experiment established that 19S malate synthase was a precursor of microsomal malate synthase. 3) By means of anti-malate synthase antibodies, 100S malate synthase could be recovered on protein A-Sepharose and thus separated from the endoplasmic reticulum. The data suggest that both microsomal and glyoxysomal malate synthase are synthesized in the cytosol rather than at the endoplasmic reticulum according to the signal hypothesis.

Glyoxylate cycle in Mucor racemosus

The dimorphic phycomycete Mucor racemosus was grown in media containing acetate, glutamate, and peptone as carbon sources. The component enzymes of the glyoxylate bypass, isocitrate lyase and malate synthase, were present under these conditions throughout the growth cycles. Highest specific activities for each enzyme were found in media with acetate as the carbon source. In an enriched peptone medium containing glucose, neither activity was detected until glucose was exhausted from the medium. Treatment of acetate-grown cells with glucose resulted in a rapid decline in the specific activities of both enzymes. The importance of this cycle in acetate-grown cells was indicated by the ability of itaconic acid (100 mM) to inhibit the growth of M. racemosus in acetate but not glutamate media. Itaconate was also shown to be a potent inhibitor of isocitrate lyase activity in vitro.

Glyoxylate cycle in toad urinary bladder: possible stimulation by aldosterone

A homogenate of the toad urinary bladder epithelial cell layer has the two enzymatic activities unique to the glyoxylate cycle--isocitrate lyase (threo-Ds-isocitrate glyoxylate-lyase, EC 4.1.3.1) and malate synthase [L-malate glyoxylate-lyase (CA-acetylating), EC 4.1.3.2]--as well as the capacity to carry out CN-insensitive palmitoyl-CoA oxidation. When tissue is incubated in the presence of a fatty acid substrate, tissue glycogen levels increase. Additionally, in the presence of aldosterone, glycogen levels are higher. These data demonstrate the presence of glyoxylate cycle enzymes in tissue of a higher animal and raise the possibility that such tissue can convert lipid to carbohydrate.

Nicotinic acid metabolism enzymic preparation and absolute configuration of the substrate for 2,3-dimethylmalate lyase

1) A convenient method for the enzymatic preparation of a chemically and optically pure isomer of 2,3-dimethylmalic acid in g-amounts is described. Propionate, pyruvate and partially purified 2,3-dimethylmalate lyase (from Clostridium barkeri) were applied. 2) The enzymically formed product, m.p. 99--100 degrees C, [alpha]D20 = -16.4 (water), is related to the known stereochemistry of the Senecio alkaloid jacobine and to a laevorotatory 2,3-dimethylmalic acid derived from jaconecic acid, a degradation product of the alkaloid. From this relationship it appears likely that the substrate of the lyase is a component of the threo racemate and is of (2R,3S) configuration. 3) A three-dimensional X-ray structure analysis was performed and the structure refined to an R value of 0.049. The asymmetric unit contains three independent threo dimethylmalic acid molecules. The anomalous dispersion effects of carbon and oxygen were used to determine the absolute configuration. These measurements yielded a (2R,3S) configuration. 4) We conclude from these results that (2R,3S)-2,3-dimethylmalate is the substrate of the lyase. The results also establish that previously isolated racemic 2,3-dimethylmalic acids, m.p. 143 degrees C and m.p. 104--106 degrees C, represent the erythro and threo pair, respectively.

Isolation and biochemical properties of two types of microbody from Neurospora crassa cells

Cells of the Neurospora crassa slime mutant grown in sucrose medium exhibited low activities of glyoxysomal marker enzymes isocitrate lyase (ICL), malate synthetase (MS), and malate dehydrogenase. Transfer of the cells to a medium containing acetate as sole carbon source ("acetate medium") induced a strong increase in the activities of these enzymes in both the soluble and the crude particulate cell fraction. Soluble isocitrate lyase activity increased rapidly after a lag phase of about 45 minutes. Addition of 0.1 mM cycloheximide to the acetate medium 3 hours after transfer of the cells halted the rise of isocitrate lyase activity in either cell fraction, but the inhibition of the incorporation of ICL activity into the particulate cell fraction was delayed by 1 hour. Addition of 20 g/l glucose resulted in the immediate decrease of both soluble and particulate ICL activities. Transfer to acetate medium induced no change in the activities of other microbody marker enzymes such as catalase, uricase or D-amino acid oxidase. Resolution of crude homogenates of "slime" cells by sucrose density gradient centrifugation yielded two major protein bands: A mitochondrial band at a density of 1.180 kg/l showing maximum activites of fumarase, isocitrate dehydrogenase and cytochrome c oxidase, and a microbody-rich band which obviously consisted of two types of organelles with different biochemical properties. Maximum activities of ICL and MS sedimented at a density of 1.21 kg/l while the peaks of particulate uricase and catalase activities were recovered at 1.24 kg/l.

Evidence for a functional glyoxylate cycle in the leishmaniae

Isocitrate lyase (EC 4.1.3.1) and malate synthase (EC 4.1.3.2), the two enzymes characteristic of the glyoxylate cycle, were demonstrated in promastigotes of five species of Leishmania (L. brasiliensis, L. donovani, L. mexicana, L. tarentolae, and L. tropica). Both enzymes were present in cells grown in a medium containing 10 mM glucose. Substitution of glucose with 20 mM acetate did not enhance enzyme levels. Acetate was readily taken up and metabolized by the cells. The distribution of label from acetate into various intermediary metabolites indicates a functional glyoxylate cycle and its role in gluconeogenesis/glyconeogenesis. The glyoxylate cycle in conjunction with alanine-glyoxylate aminotransferase and glyoxylate-aspartate aminotransferase could also be important in providing glyoxylate, the precursor for glycine biosynthesis.

Small-angle X-ray scattering on malate synthase from baker's yeast. The native substrate-free enzyme and enzyme-substrate complexes

Malate synthase from baker's yeast has been investigated in solution by the small-angle X-ray scattering technique. Size, shape and structure of the native substrate-free enzyme and of various enzyme-substrate complexes have been determined. As the enzyme was found to be rather unstable against X-rays, several precautions as well as sophisticated evaluation procedures had to be adopted to make sure that the results were not influenced by radiation damage. These included use of low primary intensity, short time of measurement, the presence of high concentrations of dithiothreitol, combined use of the conventional slit-collimation system and the new cone-collimation system. 1. For the native substrate-free enzyme the following molecular parameters could be established: radius of gyration R = 3.96 +/- 0.02 nm, maximum particle diameter D = 11.2 +/- 0.6 nm, radius of gyration of the thickness Rt = 1.04 +/- 0.04 nm, molecular weight Mr = 187000 +/- 3000, correlation volume Vc = 338 +/- 5 nm3, hydration x = 0.35 +/- 0.02 g/g, mean intersection length - l = 5.0 +/- 0.2 nm. Comparison of the experimental scattering curve with theoretical curves for various models showed that the enzyme is equivalent in scattering to an oblate ellipsoid of revolution rather than to a circular cylinder. The semiaxes of this ellipsoid are a = b = 6.06 nm and c = 2.21 nm. Thus with an axial ratio of about 1:0.36 the enzyme is of very anisometric shape. 2. Binding of the substrates (acetyl-CoA, glyoxylate) or the substrate analogue pyruvate causes slight structural changes of the enzyme. These changes are reflected mainly by a slight decrease of the radius of gyration (0.3--1.3%, as established both with the slit-smeared and the desmeared curves). Concomitantly there occurs a decrease of the maximum particle diameter and an increase of the radius of gyration of the thickness. These changes imply an increase of the axial ratio by 2.2--6.9%, i.e. substrate binding induces a decrease of anisometry. While the particle volume appears to be unchanged on binding glyoxylate or its analogue pyruvate, binding of acetyl-CoA causes slight changes of this parameter. In a similar manner the binding of acetyl-CoA leads to a slight enhancement of the molecular weight; this increase corresponds to the binding of 2.7 +/- 1 molecules of acetyl-CoA.