Effects of thyroxine on the synthesis of folate coenzymes in rat liver

1. The effects of thyroidectomy and of ;acute' and ;chronic' administration of thyroxine on the synthesis of folate coenzymes were studied by determining the liver contents of folate active derivatives and the enzymic activities involved in their biosynthesis. The effect of thyroxine on the same enzymes in vitro was also studied. 2. In thyroidectomized rats the liver contents of folate coenzymes did not change except for a slight decrease in the contents of 5-formyltetrahydrofolate and tetrahydrofolate compared with those in control rats. 3. In the same animals serine hydroxymethyltransferase and formyltetrahydrofolate synthetase activities decreased markedly. 4. The ;chronic' administration of thyroxine to thyroidectomized rats caused more evident variations in the liver contents of folate coenzymes and in particular a decrease in the contents of 5-formyltetrahydrofolate, tetrahydrofolate, 5(or 10)-formyl derivatives of tetrahydropteroylpolyglutamate and of 5(or 10)-formyl derivatives of pteroylpolyglutamate. 5. The enzymic activities did not show significant variations. 6. The ;acute' administration of thyroxine caused changes in the liver contents of some folate derivatives such as 10-formyldihydrofolate, 10-formylfolate, tetrahydrofolate and the 10-formyl derivative of dihydropteroylpolyglutamate. In these animals also the enzymic activities were unchanged. 7. No effect of thyroxine on enzymic activities in vitro was observed.     

Compartmentation of folate-mediated one-carbon metabolism in eukaryotes

Folate coenzymes supply the activated one-carbon units required in nucleic acid biosynthesis, mitochondrial and chloroplast protein biosynthesis, amino acid metabolism, methyl group biogenesis, and vitamin metabolism. Because of its central role in purine and thymidylate biosynthesis, folate-mediated one-carbon metabolism has been the target of many anticancer drug therapies. This review is a summary of recent results that suggest that folate-mediated one-carbon metabolism is highly compartmentalized in eukaryotic cells. Evidence exists for compartmentation of folate coenzymes and their one-carbon units between intracellular organelles, for substrate channeling of folate coenzymes, and for compartmentation by intracellular folate-binding proteins. Metabolic, regulatory, and therapeutic implications of these processes are discussed.     

Features of poly-ADP-ribosylation and chromatin structure under conditions of varying NAD content in the rat liver

It is shown that nicotinamide-induced in vivo stimulation of NAD biosynthesis in the liver nuclei of rats causes a decrease of the DNA sensitivity to treatment with DNAse I under conditions of weak hydrolysis. When rats are given synthetic vitamin PP-deprived food, the NAD level in the liver falls down to 40% and a great number of DNAse I-hypersensitive chromatin sites appear. A 24% decrease in the level of poly-ADP-ribosylation of total histones in comparison with the control has been observed with hypovitaminosis. Under conditions of vitamin PP deficiency nicotinamide administered to animals has increased the 14C NAD incorporation into histones 2 times (as compared with the control). These variations occur primarily due to increase of the label incorporation to histone H1. Fractionation of chromatin by solutions of different ionic strength has confirmed that vitamin PP deficiency and NAD amount decrease in the liver are accompanied by a relative increase of the NAD-pyrophosphorylase and poly-ADP-ribose polymerase activities in the fraction extracted by the low ionic solution.     

Vitamin A deficiency leads to severe functional disturbance of the intestinal epithelium enzymes associated with diarrhoea and increased bacterial translocation in gnotobiotic rats

A disturbance of the integrity of the intestinal epithelium with an increased risk for bacterial translocation is one of the suggested factors underlying the increased incidence of infections and septicaemia during vitamin A deficiency. In the present study the effects of vitamin A deficiency on the enzymic activity of enterocytes in response to bacterial colonization with a non-pathogenic Escherichia coli strain were studied in monocolonized and conventional Wistar rats. The monocolonized, but not the conventional, vitamin A-deficient rats had markedly reduced weight compared to their pair-fed controls and presented neurological symptoms, such as hind leg weakness, tremor and slow gait. Moreover, only in the monocolonized vitamin A-deficient rats were severe diarrhoea and bacterial translocation to extraintestinal sites-mainly kidneys-detected. Measurements of enterocyte brush-border enzyme activities revealed that lactase, sucrase, gamma-glutamyltranspeptidase (GGT) and dipeptidyl peptidase IV (DPP IV) were significantly reduced in the monocolonized vitamin A-deficient rats compared to the pair-fed controls, indicating a severe functional disturbance of the enterocytes. In conventional vitamin A-deficient rats only sucrase activity was markedly lower than in the respective controls. Our observation, that the deficient vitamin A status led to a strong reduction of enterocyte enzymic activities, associated with diarrhoea and increased bacterial translocation, mainly in the gnotobiotic rats, suggests that the composition of the bacterial flora, i.e. the colonization state, has a strong influence on triggering the severity of the functional disturbances of the intestinal epithelium, and adds to the clinical manifestations of vitamin A deficiency.     

The effect of coenzyme leakage and replacement on the growth and metabolism of two fusobacteria.

Suspensions in water of two species of Fusobacterium leaked several coenzymes when incubated at normal growth temperatures. Chromatography of filtrates from these suspensions revealed the presence of NAD, NADP, FMN, tetrahydrofolic acid and, in one of the two, pyridoxal phosphate. Analyses of some enzymic activities in whole organisms demonstrated deficiencies in coenzymes:glutamate dehydrogenase was virtually inactive in the absence of added NAD; tryptophanase activities were diminished by washing but the extent differed between strains; histidase activity was not decreased by washing or suspension in water or saline. Both lag phase and doubling time increased markedly in severely washed organisms inoculated into fresh medium. Addition of appropriate coenzymes shortened the lag phase for both strains and shortened the doubling time in one.     

Mechanism of the antimicrobial drug trimethoprim revisited.

We tested the hypothesis that the mechanism of action of the antifolate drug trimethoprim is through accumulation of bacterial dihydrofolate resulting in depletion of tetrahydrofolate coenzymes required for purine and pyrimidine biosynthesis. The folate pool of a strain of Escherichia coli (NCIMB 8879) was prelabeled with the folate biosynthetic precursor [(3)H]-p-aminobenzoic acid before treatment with trimethoprim. Folates in untreated E. coli were present as tetrahydrofolate coenzymes. In trimethoprim-treated cells, however, a rapid transient accumulation of dihydrofolate occurred, followed by complete conversion of all forms of folate to cleaved catabolites (pteridines and para-aminobenzoylglutamate) and the stable nonreduced form of the vitamin, folic acid. Both para-aminobenzoylglutamate and folic acid were present in the cell in the form of polyglutamates. Removal of trimethoprim resulted in the reconversion of the accumulated folic acid to tetrahydrofolate cofactors for subsequent participation in the one-carbon cycle. Whereas irreversible catabolism is probably bactericidal, conversion to folic acid may constitute a bacteriostatic mechanism since, as we show, folic acid can be used by the bacteria and proliferation is resumed once trimethoprim is removed. Thus, the clinical effectiveness of this important drug may depend on the extent to which the processes of either catabolism or folic acid production occur in different bacteria or during different therapeutic regimes.     

Supplementation of the cultivation media with B-group vitamins enhances lovastatin biosynthesis by Aspergillus terreus

The impact of the supplementation of cultivation media with B-group vitamins on the biosynthesis of lovastatin (mevinolinic acid) by Aspergillus terreus ATCC20542 was investigated. A hypothesis was formulated that as the biosynthesis of lovastatin requires a high throughput of coenzymes in the cells, the application of its precursors in the form of B-group vitamins might positively influence the process. In a nitrogen-deficient medium the B-group vitamins, both single, especially nicotinamide, pyridoxine and calcium D-pantothenate, and a mixture of thiamine, riboflavin, pyridoxine, calcium d-pantothenate and nicotinamide increased the efficiency of lovastatin biosynthesis. The vitamin supplementation also increased both volumetric and specific production rates of mevinolinic acid, especially before 80 h of the process, when no lactose limitation had been observed yet.     

透明颤菌vgb基因在脱氮假单胞菌中的表达及对维生素B12合成的碳中心代谢流分析

在为维生素B₁₂生产菌株脱氮假单胞菌确立合适的接合转移操作条件的基础上,通过单交换的方式,将vgb基因整合到脱氮假单胞菌染色体上,获得了vgb重组菌株Pvgb-16,并通过¹³C同位素标记实验,探索VHb蛋白对脱氮假单胞菌碳中心代谢流变化和维生素B₁₂合成的影响。研究结果表明,在相同的供氧条件下,vgb重组菌株Pvgb-16拥有更高的比生长速率和比产物合成速率,与出发菌株相比分别提升了22%和52%。碳代谢通量分布分析表明,vgb重组菌株Pvgb-16的PP途径改善,提升了NADPH合成通量;甘氨酸由甜菜碱合成的通量上升,促进了前体物质氨基乙酰丙酸的合成,进一步加速维生素B₁₂的合成。总体来看,含vgb基因的重组菌株与出发菌株相比在促进菌体的生长、维生素B₁₂的合成速率及得率上都有显著效果,对进一步的发酵生产应用研究具有重要意义。     

Pantothenate biosynthesis in higher plants: advances and challenges

Pantothenate (vitamin B₅) is the precursor of the 4'-phosphopantetheine moiety of coenzyme A and acyl-carrier protein. Plants and microorganisms make the vitamin de novo, whereas animals must obtain it from their diet. Pantothenate is produced commercially by chemical synthesis for vitamin supplements, feed additives and cosmetics. An attractive alternative for production is biotransformation, which would avoid expensive procedures for separation of racemic intermediates. The biosynthetic pathway in bacteria, comprising four enzymic reactions, is well-established, and enzymes from Escherichia coli have been fully characterized including the overexpression and purification of recombinant enzymes and the determination of their X-ray crystal structures. Pantothenate biosynthesis in higher plants is beginning to be elucidated, and genes encoding the first and last enzymes have been identified and characterized in Arabidopsis thaliana and Oryza sativa (rice). This review describes our current understanding of the pathway in plants and the challenges that lie ahead in engineering plants to make increased amounts of the vitamin.     

Effect of porphyrins and their derivatives on biosynthesis of vitamin B 12 and the development of Propionibacterium shermanii]

The effect of uroporphyrin, coproporphyrin and their cobalt-containing derivatives on the biosynthesis of vitamin B12 and development of propionibacterium shermanii was studied. The compounds under study stimulated the vitamin synthesis by growing cultures and resting suspensions of these bacteria. Cobalt porphyrins as the sole source of cobalt were used in the vitamin B12 biosynthesis. An addition of cobalt porphyrins to the growing culture of propionic bacteria increased in accumulation of their biomass. Possible mechanisms of porphyrin involvement in the biosynthesis of vitamin B12 and the specific role of cobalt porphyrins in the bacterial activity are discussed.     

Mitochondrial function and toxicity: role of B vitamins on the one-carbon transfer pathways

The B vitamins are water-soluble vitamins that are required as coenzymes for reactions essential for cellular function. This review focuses on the essential role of vitamins in maintaining the one-carbon transfer cycles. Folate and choline are believed to be central methyl donors required for mitochondrial protein and nucleic acid synthesis through their active forms, 5-methyltetrahydrofolate and betaine, respectively. Cobalamin (B12) may assist methyltetrahydrofolate in the synthesis of methionine, a cysteine source for glutathione biosynthesis. Pyridoxal, pyridoxine and pyridoxamine (B6) seem to be involved in the regeneration of tetrahydrofolate into the active methyl-bearing form and in glutathione biosynthesis from homocysteine. Other roles of these vitamins that are relevant to mitochondrial functions will also be discussed. However these roles for B vitamins in cell function are mostly theoretically based and still require verification at the cellular level. For instance it is still not known what B vitamins are depleted by xenobiotic toxins or which cellular targets, metabolic pathways or molecular toxic mechanisms are prevented by B vitamins. This review covers the current state of knowledge and suggests where this research field is heading so as to better understand the role vitamin Bs play in cellular function and intermediary metabolism as well as molecular, cellular and clinical consequences of vitamin deficiency. The current experimental and clinical evidence that supplementation alleviates deficiency symptoms as well as the effectiveness of vitamins as antioxidants will also be reviewed.     

Characterization of the non-saponifiable fraction of the liver lipids of the shark Carcharias taurus by mass-spectrometry

1. The non-saponifiable fractions (NSF) of the liver lipids of the common Nigerian shark Carcharias taurus were identified by mass-spectrometry. 2. The lipids were extracted from the liver microsomes. 3. Hydrocarbons made up 21.29% of the NSF, sterols 26.45% and coenzymes 52.26%. 4. Thin layer chromatography followed by mass-spectral analysis showed that squalene was the major hydrocarbon present. 5. The sterol fraction consisted of cholesterol, 1-octanol and 1-hexadecyl glycerol ether. 6. The coenzymes consisted clearly of vitamin A, coenzyme Q and probably also vitamin E.     

Basis for the historical stages for studying the biochemistry of vitamins. Noncoenzymatic mechanisms of vitamin B1

Biochemistry of vitamins is one of the leading trends in the fundamental researches of A. V. Palladin Institute of Biochemistry from the moment of its foundation in 1925. The Laboratory of Vitamins Biochemistry was organised in 1994, it was reorganized into the Department of Vitamins Biochemistry in 1966, and later it was renamed as the Department of Coenzymes Biochemistry. Now the investigations at the Coenzymes Biochemistry Department headed (from 1986) by G. V. Donchenko, Corr.-Member of the National Academy of Sciences of Ukraine, are directed to estimation of vitamins A, E, B1 and PP action molecular mechanisms. Investigation of specific protein-acceptors of vitamins and their biologically active derivatives is a contemporary and effective methodological approach to the estimation of some molecular mechanisms of vitamins action on cellular metabolism. Considering the challenging theoretical and practical aspects of the further fundamental investigation development in the molecular vitaminology the following items are currently being worked in the Department last time: 1. Study of some molecular mechanisms of thiamine and vitamin PP neurotropic action. These investigations are oriented to clearing some new aspects of noncoenzymic mechanism of its influence on the nervous cell functioning both in the norm and at some nervous diseases. 2. Study of some molecular mechanisms of regulation by means of fat-soluble vitamins A, E and their specific proteins-acceptors of DNA, RNA and protein biosynthesis in the nuclei and mitochondria of actively proliferous cells. These investigations are aimed to the estimation of molecular mechanisms of fat-soluble vitamins participation in the regulation of DNA-dependent synthesis of RNA, RNA-polymerase activity, mechanism of their anticancerogenous effect, vitamin E participation in the realisation of nuclear genetic information. 3. Study of intracellular protein-receptors, which take part in realisation of vitamins and their biologically active derivatives functions in the human and animals' organism. The investigations, directed to study of a role of retinol-binding proteins in exchange of the vitamin A and in biosynthesis of DNA, RNA and proteins, the role of tocopherol-binding proteins in realisation of biological action of vitamin E in cells and thiamine-binding proteins in realisation of neurotropic action of vitamin B1 are actively developed. 4. Investigation of mechanisms of antioxidizing and antiradical biological action of vitamin D3, ecdisterone and related biologically active compounds. Basing on the fundamental researches some vitamins preparations have been created, such as "Carotin-M", "Cardiovit", "Evit-1", "Soevit", "Metovit", "Caratel'ka" and others. The results of fundamental investigation of noncoenzymic thiamine function led us to elaboration of a new hypothesis about molecular mechanism of vitamin B1 neurotropic action. According to the hypothesis the thiamine high neuroactivity is a result of existence in the nervous ending a specific mobile thiamine pool and connection thiamine metabolism with nervous cell membrane potential and acetylcholine metabolism.     

The kinetics of the histochemical method for dihydrofolate dehydrogenase (dihydrofolate reductase).

The purpose of the present investigation is to report some histochemical and cytospectrophotometric observations providng more objective evidence for the specific activity of the histochemical method for dihydrofolate reductase activity (5.6.7.8-tetrahydrofolate: E.C. 1.5.1.3). Kinetic factors of the enzymic reaction, such as fixation, pH, coenzymes, substrate concentration, Michaelis constant, temperature, time of incubation, aerobiosis, and anaerobiosis, activators and inhibitors, were investigated.     

Noncoenzyme function of vitamin PP and its biologically active derivatives: the current state of the problem

This review is devoted to the current state of investigations of vitamin PP and nicotinamide dinucleotides noncoenzyme functions. Particular attention has been focused on the role of these compounds in post-translation modification of proteins (mono- and poly-ADP-ribosylation), in regulation of gene activity, calcium homeostasis and Ca2+ signalling as well as in modulation of synaptic transmission. Biological significance of these processes in cell function was elicited. The role of deregulation of vitamin PP mediated signalling mechanisms involved in control over the cell function under conditions of different diseases was emphasized.     

酵母麦角固醇生物合成及其基因调控的研究

麦角固醇是真菌细胞膜中的重要组成成分,是维生素D2的合成前体,也是一种重要医药材料。近年来,麦角固醇生物合成途径已经被弄清,其基因调控也获得了初步的进展。就麦角固醇的生物合成途径、酶在细胞内的分布及其基因调控进行综述。     

Metabolic-flux and network analysis in fourteen hemiascomycetous yeasts

In a quantitative comparative study, we elucidated the glucose metabolism in fourteen hemiascomycetous yeasts from the Genolevures project. The metabolic networks of these different species were first established by (13)C-labeling data and the inventory of the genomes. This information was subsequently used for metabolic-flux ratio analysis to quantify the intracellular carbon flux distributions in these yeast species. Firstly, we found that compartmentation of amino acid biosynthesis in most species was identical to that in Saccharomyces cerevisiae. Exceptions were the mitochondrial origin of aspartate biosynthesis in Yarrowia lipolytica and the cytosolic origin of alanine biosynthesis in S. kluyveri. Secondly, the control of flux through the TCA cycle was inversely correlated with the ethanol production rate, with S. cerevisiae being the yeast with the highest ethanol production capacity. The classification between respiratory and respiro-fermentative metabolism, however, was not qualitatively exclusive but quantitatively gradual. Thirdly, the flux through the pentose phosphate (PP) pathway was correlated to the yield of biomass, suggesting a balanced production and consumption of NADPH. Generally, this implies the lack of active transhydrogenase-like activities in hemiascomycetous yeasts under the tested growth condition, with Pichia angusta as the sole exception. In the latter case, about 40% of the NADPH was produced in the PP pathway in excess of the requirements for biomass production, which strongly suggests the operation of a yet unidentified mechanism for NADPH reoxidation in this species. In most yeasts, the PP pathway activity appears to be driven exclusively by the demand for NADPH.     

The kinetics of the histochemical method for dihydrofolate dehydrogenase (dihydrofolate reductase)

Summary The purpose of the present investigation is to report some histochemical and cytospectrophotometric observations providing more objective evidence for the specific activity of the histochemical method for dihydrofolate reductase activity (5.6.7.8-tetrahydrofolate: E.C. 1.5.1.3). Kinetic factors of the enzymic reaction, such as fixation, pH, coenzymes, substrate concentration, Michaelis constant, temperature, time of incubation, aerobiosis, and anaerobiosis, activators and inhibitors, were investigated.     

Occurrence of coenzyme forms of vitamin B12 in a cultured purple laver (Porphyla yezoensis)

Porphyra yezoensis (Susabinori, an edible purple laver), which was cultured aseptically for 12 weeks and then lyophilized, contained 50+/-2 microg/g of vitamin B(12) per 100 g dry weight. Coenzyme forms of vitamin B(12) (about 60% of the total vitamin B(12)) were found in the cultured purple laver aseptically, which may have the ability to biosynthesize the coenzymes.     

Life's utilization of B vitamins on early Earth

Coenzymes are essential across all domains of life. B vitamins (B₁‐thiamin, B₂‐riboflavin, B₃‐niacin, B₅‐pantothenate, B₆‐pyridoxine, B₇‐biotin, and B₁₂‐cobalamin) represent the largest class of coenzymes, which participate in a diverse set of reactions including C₁‐rearrangements, DNA repair, electron transfer, and fatty acid synthesis. B vitamin structures range from simple to complex heterocycles, yet, despite this complexity, multiple lines of evidence exist for their ancient origins including abiotic synthesis under putative early Earth conditions and/or meteorite transport. Thus, some of these critical coenzymes likely preceded life on Earth. Some modern organisms can synthesize their own B vitamins de novo while others must either scavenge them from the environment or establish a symbiotic relationship with a B vitamin producer. B vitamin requirements are widespread in some of the most ancient metabolisms including all six carbon fixation pathways, sulfate reduction, sulfur disproportionation, methanogenesis, acetogenesis, and photosynthesis. Understanding modern metabolic B vitamin requirements is critical for understanding the evolutionary conditions of ancient metabolisms as well as the biogeochemical cycling of critical elements such as S, C, and O.