Light modulation of the activity of carbon metabolism enzymes in the crassulacean Acid metabolism plant kalanchoë

When intact Kalanchoë plants are illuminated NADP-linked malic dehydrogenase and three enzymes of the reductive pentose phosphate pathway, ribulose-5-phosphate kinase, NADP-linked glyceraldehyde-3-phosphate dehydrogenase, and sedoheptulose-1,7-diphosphate phosphatase, are activated. In crude extracts these enzymes are activated by dithiothreitol treatment. Light or dithiothreitol treatment does not inactivate the oxidative pentose phosphate pathway enzyme glucose-6-phosphate dehydrogenase. Likewise, neither light, in vivo, nor dithiothreitol, in vitro, affects fructose-1,6-diphosphate phosphatase. Apparently the potential for modulation of enzyme activity by the reductively activated light effect mediator system exists in Crassulacean acid metabolism plants, but some enzymes which are light-dark-modulated in the pea plant are not in Kalanchoë.     

The metabolism of α-tocopherol by plants

An enzyme system which metabolizes α-tocopherol has been identified in homogenates of etiolated pea shoots. Enzyme activity is considerably increased by the presence of 20% ethanol in the incubation mixture. The enzyme has an absolute requirement for phospholipid. The reaction utilizes molecular oxygen and it is proposed that the enzyme be called α-tocopherol oxidase.     

Microbial metabolism of monoterpenes — recent developments

Monoterpenes are important renewable resources for the perfume and flavour industry but the pathways and enzymology of their degradation by microorganisms are not well documented. Until recently the acyclic monoterpene alcohols, (+)-camphor and the isomers of limonene were the only compounds for which significant sections of catabolic pathways and associated enzymology had been reported. In this paper recent developments in our understanding of the enzymology of ring cleavage by microorganisms capable of growth with 1,8-cineole and -pinene are described. 1,8-Cineole has the carbocyclic skeleton of a monocyclic monoterpene with the added complication of an internal ether linkage. Ring hydroxylation strategy and biological Baeyer-Villiger oxygenation lead to an efficient method for cleaving the ether linkage. -Pinene is an unsaturated bicyclic monoterpene hydrocarbon. At least two catabolic pathways exist. Information concerning one of them, in which -pinene may be initially converted into limonene, is rudimentary. The other involves attack at the double bond resulting in formation of -pinene epoxide. Ring cleavage is then catalysed by a novel lyase that requires no additional components and breaks both carbocyclic rings in a concerted manner.     

Effects of β-endorphin on brain serotonin metabolism

Human β-endorphin (15 μg) administered intracisternally increased concentrations of serotonin (5HT) and its metabolite, 5-hydroxyindoleacetic. acid (5-HIAA), in brain stem and hypothalamus and decreased 5-HIAA concentrations in hippocampus. These data are compatible with the hypothesis that β-endorphin increases 5HT turnover in brain stem and hypothalamus and decreases 5HT turnover in hippocampus. β-endorphin increased in brain stem and hypothalamus and decreased in hippocampus the rate of pargyline-induced decline of 5-HIAA. β-endorphin decreased the rate of pargyline-induced accumulation of 5HT in all these brain regions. The probenecid-induced accumulation of 5-HIAA in brain stem was decreased by β-endorphin. These data are compatible with the hypothesis that β-endorphin increases release of 5HT from neurons in brain stem and hypothalamus and decreases release of 5HT from neurons in hippocampus. The data require further a hypothesis that β-endorphin either decreases 5HT reuptake in these three brain regions or increases 5-HIAA egress from brain.     

Role of thyroid receptor β in lipid metabolism

Thyroid hormones (THs) exert their actions by binding to thyroid hormone receptors (TRs) and thereby affect tissue differentiation, development, and metabolism in most tissues. TH-deficiency creates a less favorable lipid profile (e.g. increased plasma cholesterol levels), whereas TH-excess is associated with both positive (e.g. reduced plasma cholesterol levels) and negative (e.g. increased heart rate) effects. TRs are encoded by two genes, THRA and THRB, which, by alternative splicing, generate several isoforms (e.g. TRα1, TRα2, TRβ1, and TRβ2). TRα, the major TR in the heart, is crucial for heart rate and for cardiac contractility and relaxation, whereas TRβ1, the major TR in the liver, is important for lipid metabolism. Selective modulation of TRβ1 is thus considered as a potential therapeutic target to treat dyslipidemia without cardiac side effects. Several selective TH analogs have been tested in preclinical studies with promising results, but only a few of these compounds have so far been tested in clinical studies. This review focuses on the role of THs, TRs, and selective and non-selective TH analogs in lipid metabolism. This article is part of a Special Issue entitled: Translating nuclear receptors from health to disease.     

Alterations in carbohydrate metabolism of γ-irradiated cavendish banana

γ-Irradiation of preclimacteric banana resulted in a gradual increase in fructose content, which reached a maximum in 6 days. Although the catabolism of glucose-U-¹⁴C was less in irradiated banana, incorporation of label into fructose was high. Initial fructose accumulation in irradiated banana may be due to a shift in glucose utilization from the glycolytic to the pentose phosphate pathway. The ratio of resporatory CO₂ from glucose-6-¹⁴C and glucose-1-¹⁴C was halved in irradiated bananas indicating predominance of the pentose phosphate pathway. The radioactivity of fructose derived from glucose-6-¹⁴C was almost twice that from glucose-1-¹⁴C in irradiated bananas, whilst in control both fruit the labelled precursors yielded equal amounts. Studies on individual enzymes in these two pathways showed an increase in phosphorylase, phosphoglucomutase, glucose-6-phosphate dehydrogenase and fructose-6-phosphatase and a decrease in hexokinase in irradiated banana.     

Control of pancreatic β cell regeneration by glucose metabolism

Recent studies revealed a surprising regenerative capacity of insulin-producing β cells in mice, suggesting that regenerative therapy for human diabetes could in principle be achieved. Physiologic β cell regeneration under stressed conditions relies on accelerated proliferation of surviving β cells, but the factors that trigger and control this response remain unclear. Using islet transplantation experiments, we show that β cell mass is controlled systemically rather than by local factors such as tissue damage. Chronic changes in β cell glucose metabolism, rather than blood glucose levels per se, are the main positive regulator of basal and compensatory β cell proliferation in vivo. Intracellularly, genetic and pharmacologic manipulations reveal that glucose induces β cell replication via metabolism by glucokinase, the first step of glycolysis, followed by closure of K(ATP) channels and membrane depolarization. Our data provide a molecular mechanism for homeostatic control of β cell mass by metabolic demand.     

Sulfolobus aconitase,a regulator of iron metabolism?

The aconitase of Sulfolobus solfataricus, a hyperthermophilic crenarchaeon, was cloned and heterologously expressed in Escherichia coli. Enzymic analyses and EPR measurements indicated clearly that the iron-sulphur cluster of the thermophilic aconitase was already inserted in the mesophilic host. The enzyme was purified to a specific activity of approx. 44 units/mg and to 90% homogeneity. The enzymic parameters of the recombinant aconitase turned out to be in the same range as the respective values for the previously characterized native enzyme from the closely related S. acidocaldarius. Based on its primary sequence, the recombinant aconitase is closely related to bacterial A-like and to eukaryotic iron regulatory protein-like proteins. Specific aconitase activities in cytosolic extracts of S. acidocaldarius were found to be decreased markedly in iron-starved compared with iron-repleted cells. However, no differences in aconitase levels between iron-starved and iron-supplemented cells could be detected by immunostaining.     

Is canavanine a natural component of mammalian metabolism?

A group of non-protein amino acids of higher plants, namely l-canavanine, l-canaline, 0-ureido-l-homoserine, and l-canavaninosuccinic acid, have been implicated in mammalian intermediary metabolism. The clinical observations and biochemical basis for this hypothesis as well as conflicting experimental evidence are presented. A possible explanation for the apparent role of these non-protein amino acids in mammalian metabolism is offered.     

The metabolism of α-ionylidene compounds by Cercospora rosicola

α-Ionylidene ethanol was converted to 4′hydroxy-α -ionylidene acetic acid, 1′-deoxy-ABA and ABA by Cercospora rosicola. Both the 4′-(R) and 4′-(S-epimers of 4′-hydroxy-α-ionylidene acetic acid were detected but the configuration of the 1′-position was not established. Both epimers were metabolized to 1′-deoxy-ABA and ABA. Both the cis- and trans 1′,4′diols of ABA were also converted to ABA. 1′-Deoxy-ABA was stereospecifically hydroxylated to form ABA. 1′-Hydroxy-α-ionylidene derivatives inhibited ABA production and were only oxidised to ABA in low yield. α-Ionylidene ethanol, α-ionylidene acetic acid and both epimers of 4′-hydroxy-α-ionylidene acetic acid were identified as endogenous compounds.     

Isopropyl-β-d-thiogalactopyranoside influences the metabolism of Escherichia coli

Summary Addition of isopropyl -D-thiogalactopyranoside (IPTG) to a strain of Escherichia coli with one lac promoter in its chromosome causes reduction in synthesis rate for a set of protiens. One of these proteins, designated H35, is a prominent cellular protein present only during exponential growth. Reduction of H35 synthesis is transient and delayed following an IPTG pulse. Cellular response to an IPTG pulse during exponential growth shares several features with a heat shock response. Significant increases in the specific growth rate of cells in both amino-acid-supplemented minimal medium and complex medium were observed for some IPTG concentrations relative to IPTG-free cultures. Other IPTG concentrations caused a reduction in specific growth rate.Offprint requests to: J. E. Bailey     

‘Radicle' biochemistry: the biology of root-specific metabolism

The roots of higher plants are a fascinating and largely unexplored biological frontier. One of their features is the ability to synthesize a remarkable diversity of secondary metabolites, and to adjust their metabolic activities in response to biotic and abiotic stress. This includes the ability to exude a complex array of micro- and macromolecules into the rhizosphere, with the potential to affect the inter-relationships between plants and beneficial or deleterious soil-borne organisms. In the past, research on root biology has been hampered by the underground growth habit of roots and by the lack of a suitable experimental system. However, recent progess in growing roots in isolation has greatly facilitated the study of root-specific metabolism and contributed to our understanding of this remarkable plant organ.     

Chirality of pollutants—effects on metabolism and fate

In most cases, enantiomers of chiral compounds behave differently in biochemical processes. Therefore, the effects and the environmental fate of the enantiomers of chiral pollutants need to be investigated separately. In this review, the different fates of the enantiomers of chiral phenoxyalkanoic acid herbicides, acetamides, organochlorines, and linear alkylbenzenesulfonates are discussed. The focus lies on biological degradation, which may be enantioselective, in contrast to non-biotic conversions. The data show that it is difficult to predict which enantiomer may be enriched and that accumulation of an enantiomer is dependent on the environmental system, the species, and the organ. Racemization and enantiomerization processes occur and make interpretation of the data even more complex. Enantioselective degradation implies that the enzymes involved in the conversion of such compounds are able to differentiate between the enantiomers. Enzyme pairs have evolved which exhibit almost identical overall folding. Only subtle differences in their active site determine their enantioselectivities. At the other extreme, there are examples of non-homologous enzyme pairs that have developed through convergent evolution to enantioselectively turn over the enantiomers of a chiral compound. For a better understanding of enantioselective reactions, more detailed studies of enzymes involved in enantioselective degradation need to be performed.     

HEMETβ: improvement of hepatocyte metabolism mathematical model

This article describes hepatocyte metabolism mathematical model (HEMETβ), which is an improved version of HEMET, an effective and versatile virtual cell model based on hepatic cell metabolism. HEMET is based on a set of non-linear differential equations, implemented in Simulink?, which describes the biochemical reactions and energetic cell state, and completely mimics the principal metabolic pathways in hepatic cells. The cell energy function and modular structure are the core of this model. HEMETβ as HEMET model describes hepatic cellular metabolism in standard conditions (cell culture in a plastic multi-well placed in an incubator at 37° C with 5% of CO2) and with excess substrates concentration. The main improvements in HEMETβ are the introductions of Michaelis-Menten models for reversible reactions and enzymatic inhibition. In addition, we eliminated hard non-linearities and modelled cell proliferation and every single aminoacid degradation pathway. All these innovations, combined with a user-friendly aspect, allow researchers to create new cell types and validate new experimental protocols just varying 'peripheral' pathways or model inputs.     

The effects of a load of phen?lalanine on glucose metabolism

The clinical and experimental hyperphenylalaninemic conditions seem associated with disorders of carbohydrates metabolism. Examples are the increased liver glucose turnover and the glycogen depletion under Phenylalanine load and the hyperexcretion of glucose in the urine of PKU children. We studied the effects of an acute load of Phenylalanine on Glucose-3-H3 kinetics and plasma glucose levels in adult male Wistar rats. The effects of the load were very slow and after 40 minutes we observed an increase in the rate of plasma glucose production (Ra), that in normal animals in an almost exclusive liver function. As result of this glucose production there was a modest increase in plasma glucose levels.     

Occurrence and metabolism of 1′,4′-trans-diol of abscisic acid

The 1′,4′-trans-diol of abscisic acid was first identified in higher plants with GC-ECD and GC-SIM. The ²H-labelled derivative was converted into abscisic acid (ABA) in pea and avocado, but ²H-labelled ABA was not converted into the diol. These results suggest that the diol is one of the precursors of ABA in higher plants.     

Effect of α-p-chlorophenoxyisobutyrate on the metabolism of isoprenoid compounds in the rat

1. Feeding of alpha-p-chlorophenoxyisobutyrate (CPIB) to rats increased ubiquinone concentration in the liver but not in other tissues. The increase was progressive with the time of feeding and related to the concentration of CPIB in the diet. 2. Incorporation of [1-(14)C]acetate, but not of [2-(14)C]mevalonate, into sterols in the liver in vivo or by liver slices in vitro was decreased on feeding the rats with CPIB. However, incorporation of mevalonate into ubiquinone increased. 3. CPIB, when added in low concentrations to liver slices, had no effect on isoprene synthesis from acetate; higher concentrations, however, were inhibitory. 4. No activation of ubiquinone synthesis from mevalonate was observed when CPIB was added to the liver slices synthesizing ubiquinone. 5. The increase in ubiquinone in CPIB-fed animals appears to be due to increased synthesis in the initial stages and to decreased catabolism in the later stages. 6. An inverse relationship was found between the concentration of ubiquinone in the liver and the serum sterol concentration in CPIB-fed rats.