Inhibition of thiamine transport in Saccharomyces cerevisiae by thiamine disulfides.

Both thiamine disulfide and O-benzoyl thiamine disulfide, which are thiolfrom derivatives of thiamine, strongly inhibited thiamine transport in Saccharomyces cerevisiae. The inhibition appeared to be due to a high affinity of the analogs for yeast cell membranes, in which thiamine transport component(s) may be integrated.     

Interaction of rat brain thiamine kinase with thiamine and its derivatives

Participation of the enzyme which provides the phosphorylation of thiamine to thiamindiphosphate (TDP) thiaminkinase (thiaminpyrophosphokinase, KF 2.7.6.2) of rat brain in the realization of thiamine action on the syntheses of acethylcholine (AC) was studied. The thiamine and its structure analogue, which differ the nature of the radicals in the 3-d and 5-e positions of the thiazollium cycle were used: 3-[(4-amino-2methylpyrimidinyl-5)methyl]-4-methylthiazolium chloride, 3-decyloxycarbonylmethyl-4-metyl-5-beta-hydrozyethylthiazolium chloride, 3-decyloxycarbonylmethyl-4-methylthiazolium chloride. All salts in the concentrations lower then Km render active influence on thiaminkinase. The analysis of data shows the presence of the regulation site on the enzyme distinguishing from the active enzyme centre and participating in the interaction with which the hydrophobic fragments of thiamine molecule participating. The comparative studies of thiamine and above mentioned derivatives influence on the inclusion of the labelled carbon with [2-(14)C] pyruvate in acethylcholine confirm an assumption about the key-role of the thiamine interaction with thiaminkinase (meaning its phosphorilation) regarding its action on the acethylcholine syntheses, and probably, on the function of the nervous cells as a whole.     

Phosphorylation of some thiamine analogs by yeast thiamine pyrophosphokinase]

A rapid efficient method of separation of the thiamine pyrophosphokinase reaction products (ATP: thiamine pyrophosphotransferase) on the column packed with DEAE-Sephadex A-25 and their subsequent identification by direct spectrophotometry is suggested. Phosphorylation of some thiamine analogs substituted at the second position of the pyrimidine ring was studied. It was shown that in addition to thiamine, the enzyme transfers the pyrophosphate group to some of its derivatives. The vitamin analogs devoid of quaternary nitrogen in the thiazole cycle, do not form pyrophosphate ethers (thus being unable to act as substrates), whereas 2'-phenoxythiamine, 2'-methoxythiamine and especially 2'-phenylthiamine are phosphorylated at a greater rate than does the "true" substrate, thiamine, under similar conditions.     

Interaction of thiamine pyrophosphokinase from brewer's yeast with thiamine and adenosine-5'-triphosphate]

The interaction of thiamine pyrophosphokinase (Thiaminkinase EC 2.7.6.2) with thiamine and ATP was studied. It was shown that the mechanism of the thiaminokinase reactions is Rapid Equilibrium Random Bi -- Bi. The enzyme binds 8 moles ATP and 1 mole thiamine per mole protein Ks = 0,8-10(-3) and 4.10(-6) M for ATP and thiamine respectively.     

Blood thiamine and thiamine phosphate ester concentrations in alcoholic and non-alcoholic liver diseases.

Thiamine state was investigated in patients with alcoholic liver disease, patients with various non-alcoholic liver diseases, and controls using a direct technique (thiochrome assay) to measure thiamine, thiamine monophospate, and the active coenzyme thiamine pyrophosphate in whole blood after isolating the fractions by ion exchange chromatography. Overall nutrition was similar in all groups as assessed by anthropometry, and no patient had clinical evidence of thiamine deficiency. There was no significant difference among the groups in mean concentration of any form of thiamine. The scatter was much greater in patients with alcoholic liver disease but only 8.7% had biochemical thiamine deficiency (defined as a blood concentration of the active coenzyme greater than 2 SD below the mean control value). An unexpected finding was of abnormally high total thiamine concentrations (greater than 2 SD above the mean control value) in 17.4% of patients with alcoholic liver disease, the highest concentrations being found in two patients with severe alcoholic hepatitis and cirrhosis. The ratio of phosphorylated to unphosphorylated thiamine was calculated as an index of phosphorylation and, although the mean did not differ significantly among the groups, the range was greatest in alcoholic liver disease. The lowest ratios occurred in the two patients with severe alcoholic hepatitis, but neither had evidence of thiamine pyrophosphate deficiency. Contrary to studies using indirect assay techniques, these results suggest that thiamine deficiency is unusual in well nourished patients with alcoholic liver disease. The new finding of unexpectedly high thiamine concentrations in some patients may be due to abnormalities of hepatic storage or release in liver disease, particularly in severe alcoholic hepatitis. There was no convincing evidence of impaired thiamine phosphorylation in any patients with liver disease. Conclusions from studies using indirect assays on the prevalence and mechanisms of thiamine deficiency in liver diseases may not be valid.     

A constitutive thiamine metabolism mutation, thi80, causing reduced thiamine pyrophosphokinase activity in Saccharomyces cerevisiae.

We identified a strain carrying a recessive constitutive mutation (thi80-1) with an altered thiamine transport system, thiamine-repressible acid phosphatase, and several enzymes of thiamine synthesis from 2-methyl-4-amino-5-hydroxymethylpyrimidine and 4-methyl-5-beta-hydroxyethylthiazole. The mutant shows markedly reduced activity of thiamine pyrophosphokinase (EC 2.7.6.2) and high resistance to oxythiamine, a thiamine antagonist whose potency depends on thiamine pyrophosphokinase activity. The intracellular thiamine pyrophosphate content of the mutant cells grown with exogenous thiamine (2 x 10(-7) M) was found to be about half that of the wild-type strain under the same conditions. These results suggest that the utilization and synthesis of thiamine in Saccharomyces cerevisiae is controlled negatively by the intracellular thiamine pyrophosphate level.     

Biosynthesis of thiamine triphosphate and identification of thiamine diphosphate-binding proteins in the rat liver hyaloplasm

The nature of the thiamine diphosphate binding proteins from rat liver hyaloplasm was studied. When [14C]thiamine was used as a marker, a [14C]thiamine diphosphate-containing electrophoretically homogeneous protein preparation was isolated from the liver soluble fraction and classified as transketolase. No other non-enzymatic proteins which bind thiamine diphosphate and can serve as substrates in the reaction of thiamine diphosphate synthesis in the hyaloplasm were found. It was shown that the phosphate group is transferred by rat liver thiamine diphosphate kinase to the free (but not to the protein-bound) thiamine diphosphate as it was believed earlier.     

Molecular mechanisms of thiamine utilization

Thiamine is required for all tissues and is found in high concentrations in skeletal muscle, heart, liver, kidneys and brain. A state of severe depletion is seen in patients on a strict thiamine-deficient diet in 18 days, but the most common cause of thiamine deficiency in affluent countries is alcoholism. Thiamine diphosphate is the active form of thiamine, and it serves as a cofactor for several enzymes involved primarily in carbohydrate catabolism. The enzymes are important in the biosynthesis of a number of cell constituents, including neurotransmitters, and for the production of reducing equivalents used in oxidant stress defenses and in biosyntheses and for synthesis of pentoses used as nucleic acid precursors. Because of the latter fact, thiamine utilization is increased in tumor cells. Thiamine uptake by the small intestines and by cells within various organs is mediated by a saturable, high affinity transport system. Alcohol affects thiamine uptake and other aspects of thiamine utilization, and these effects may contribute to the prevalence of thiamine deficiency in alcoholics. The major manifestations of thiamine deficiency in humans involve the cardiovascular (wet beriberi) and nervous (dry beriberi, or neuropathy and/or Wernicke-Korsakoff syndrome) systems. A number of inborn errors of metabolism have been described in which clinical improvements can be documented following administration of pharmacological doses of thiamine, such as thiamine-responsive megaloblastic anemia. Substantial efforts are being made to understand the genetic and biochemical determinants of inter-individual differences in susceptibility to development of thiamine deficiency-related disorders and of the differential vulnerabilities of tissues and cell types to thiamine deficiency.     

Transport and metabolism of thiamine in Ehrlich ascites-carcinoma cells

1. Aerobic or anaerobic incubation at 37 degrees of Ehrlich ascites-carcinoma cells in Krebs-Ringer bicarbonate medium containing glucose and labelled thiamine results in accumulation in the cell of labelled thiamine, so that the concentration of total labelled thiamine in the cells greatly exceeds (by a factor 7) that in the medium. This concentration ratio is approximately constant for small initial external concentrations of labelled thiamine but diminishes when the latter exceed 0.4mum. 2. All the labelled thiamine in the tumour cells is present as thiamine phosphates. 3. The uptake of labelled thiamine is markedly diminished by decrease of temperature. At 9 degrees concentration ratio (cells/medium) 0.5 is observed whereas at 37 degrees the concentration ratio is 8.6. 4. The extent of phosphorylation of labelled thiamine depends on the period of incubation. 5. The influx of labelled thiamine is diminished by the presence of its analogues, pyrithiamine and Amprol, and also by the presence of thiamine monophosphate and thiamine diphosphate, which are potent inhibitors of thiamine phosphorylation in Ehrlich ascites cells. 6. Labelled thiamine phosphates leak from the cell into the medium, so that eventually all the labelled thiamine, both in the cell and medium, is converted into thiamine phosphates. However, in the presence of 2,4-dinitrophenol (0.1mm) and iodoacetate (1mm) thiamine phosphorylation is diminished, the concentration ratio for labelled thiamine (cells/medium) falls to half its normal value and little or no labelled thiamine phosphates leaks into the medium. 7. In the presence of thiamine phosphates, free labelled thiamine accumulates in Ehrlich ascites cells against a concentration gradient, concentration ratios (cells/medium) greater than unity being evident. 8. The evidence supports the conclusion that thiamine is transferred into the Ehrlich ascites cell by a carrier-mediated energy-assisted process.     

Simultaneous liquid chromatographic assessment of thiamine,thiamine monophosphate and thiamine diphosphate in human erythrocytes: a study on alcoholics

An isocratic HPLC procedure for the assessment of thiamine (T), thiamine monophosphate (TMP) and thiamine diphosphate (TDP) in human erythrocytes is described. Several aspects of the procedure make it suitable for both clinical and research purposes: limits of detection and quantification of 1 and 2.5 nmol/l, respectively, recovery of 102% on average (range 93-112%), intra- and inter-day precisions within 5 and 9%, respectively, total elution time 15 min. This analytical methodology was applied to a case-control study on erythrocyte samples from 103 healthy subjects and 36 alcohol-dependent patients at risk of thiamine deficiency. Mean control values obtained were: T=89.6+/-22.7 nmol/l, TMP=4.4+/-6.6 nmol/l and TDP=222.23+/-56.3 nmol/l. T and TDP mean values of alcoholics were significantly lower than those of control cases: T=69.4+/-35.9 nmol/l (P<0.001) and TDP=127.4+/-62.5 nmol/l (P<10(-5)). The diagnostic role of TDP was evaluated and a significant role for thiamine was established in the study of alcohol related problems.     

Reduced folate carrier transports thiamine monophosphate: an alternative route for thiamine delivery into mammalian cells

Although the reduced folate carrierRFC1 and the thiamine transporters THTR-1 and THTR-2 share ~40% oftheir identity in protein sequence, RFC1 does not transport thiamineand THTR-1 and THTR-2 do not transport folates. In the present study,we demonstrate that transport of thiamine monophosphate (TMP), animportant thiamine metabolite present in plasma and cerebrospinalfluid, is mediated by RFC1 in L1210 murine leukemia cells. Transport ofTMP was augmented by a factor of five in cells (R16) that overexpressRFC1 and was markedly inhibited by methotrexate, an RFC1 substrate, butnot by thiamine. At a near-physiological concentration (50 nM), TMP influx mediated by RFC1 in wild-type L1210 cells was ~50% ofthiamine influx mediated by thiamine transporter(s). Within 1 min, the majority of TMP transported into R16 cells was hydrolyzed to thiamine with a component metabolized to thiamine pyrophosphate, the active enzyme cofactor. These data suggest that RFC1 may be one of the alternative transport routes available for TMP in some tissues whenTHTR-1 is mutated in the autosomal recessive disorderthiamine-responsive megaloblastic anemia.

     

Pathway of thiamine pyrophosphate synthesis in Micrococcus denitrificans.

The pathway of thiamine pyrophosphate (TPP) biosynthesis, which is formed either from exogeneously added thiamine or from the pyrimidine and thiazole moieties of thiamine, in Micrococcus denitrificans was investigated. The following indirect evidence shows that thiamine pyrophosphokinase (EC 2.7.6.2) catalyzes the synthesis of TPP from thiamine: (i) [35S]thiamine incubated with cells of this microorganism was detected in the form of [35S]thiamine; (ii) thiamine gave a much faster rate of TPP synthesis than thiamine monophosphate (TMP) when determined with the extracts; and (iii) a partially purified preparation of the extracts can use thiamine, but not TMP, as the substrate. The activities of the four enzymes involved in TMP synthesis from pyrimidine and thiazole moieties of thiamine were detected in the extracts of M. denitrificans. The extracts contained a high activity of the phosphatase, probably specific for TMP. After M. denitrificans cells were grown on a minimal medium containing 3 mM adenosine, which causes derepression of de novo thiamine biosynthesis in Escherichia coli, the activities of the four enzymes involved with TMP synthesis, the TMP phosphatase, and the thiamine pyrophosphokinase were enhanced two- to threefold. These results indicate that TPP is synthesized directly from thiamine without forming TMP as an intermediate and that de novo synthesis of TPP from the pyrimidine and thiazole moieties involves the formation of TMP, followed by hydrolysis to thiamine, which is then converted to TPP directly. Thus, the pathway of TPP synthesis from TMP synthesized de novo in M. denitrificans is different from that found in E. coli, in which TMP synthesized de novo is converted directly to TPP without producing thiamine.     

Reversibility of thiamine deficiency-induced partial necrosis and mitochondrial uncoupling by addition of thiamine to neuroblastoma cell suspensions

Culture of neuroblastoma cells in the presence of low thiamine concentration (6 nM) and of the transport inhibitor amprolium leads to the appearance of signs of necrosis: the chromatin condenses, the oxygen consumption decreases and is uncoupled, the mitochondrial cristae are disorganized, the thiamine diphosphate-dependent dehydrogenase activities are impaired. When 10 µM thiamine are added to these cells, the basal respiration increases, the coupled respiration is restored and mitochondrial morphology is recovered within 1 h. Addition of succinate, which is oxidized via a thiamine diphosphate-independent dehydrogenase, to digitonin-permeabilized cells immediately restores a coupled respiration. Our results suggest that the slowing of the citric acid cycle is the cause of the biochemical lesion induced by severe thiamine deficiency and that part of the mitochondria remain functional. (Mol Cell Biochem 174: 121–124, 1997)     

The prion protein binds thiamine

Although highly conserved throughout evolution, the exact biological function of the prion protein is still unclear. In an effort to identify the potential biological functions of the prion protein we conducted a small-molecule screening assay using the Syrian hamster prion protein [shPrP(90-232)]. The screen was performed using a library of 149 water-soluble metabolites that are known to pass through the blood-brain barrier. Using a combination of 1D NMR, fluorescence quenching and surface plasmon resonance we identified thiamine (vitamin B1) as a specific prion ligand with a binding constant of ~60 μM. Subsequent studies showed that this interaction is evolutionarily conserved, with similar binding constants being seen for mouse, hamster and human prions. Various protein construct lengths, both with and without the unstructured N-terminal region in the presence and absence of copper, were examined. This indicates that the N-terminus has no influence on the protein's ability to interact with thiamine. In addition to thiamine, the more biologically abundant forms of vitamin B1 (thiamine monophosphate and thiamine diphosphate) were also found to bind the prion protein with similar affinity. Heteronuclear NMR experiments were used to determine thiamine's interaction site, which is located between helix 1 and the preceding loop. These data, in conjunction with computer-aided docking and molecular dynamics, were used to model the thiamine-binding pharmacophore and a comparison with other thiamine binding proteins was performed to reveal the common features of interaction.     

Maternal influences on thiamine status of walleye Sander vitreus ova

Concentrations of the various forms of thiamine (vitamin B(1) ) were determined in walleye Sander vitreus ova from three central North American lakes. Total thiamine concentrations in ova from Lake Winnipeg S. vitreus were approximately three times greater (mean 12 nmol g(-1) ) than in those from Lakes Erie or Ontario. The percentage of thiamine in the active form (thiamine pyrophosphate, TPP) was highest in Lake Ontario ova (mean 88%) and lowest in those from Lake Winnipeg (mean 70%). Neither ova total thiamine concentration nor per cent ova thiamine as TPP showed any consistent relationships with maternal age, size, morphometric condition, somatic lipid concentrations or liver lipid concentrations. Ova total thiamine concentration, however, was negatively related to ovum size in some populations, as well as among populations, and was positively related to liver total thiamine concentration. Maternal transfer of thiamine to ova appears to be independent of female ontogenetic or conditional state in S. vitreus.     

Role of thiamine thiol form in nitric oxide metabolism

In alkaline media the thiamine cyclic form is converted into a thiol form (pK(a) 9.2) with an opened thiazole ring. The thiamine thiol form releases nitric oxide from S-nitrosoglutathione (GSNO). Thiamine disulfide, mixed thiamine disulfide with glutathione, and nitric oxide are produced in the reaction. Free glutathione was recorded in small amounts. The concentration of formed nitric oxide agreed well with the concentration of degraded GSNO. The concentration of released nitric oxide was determined under anaerobic conditions spectrophotometrically by production of nitrosohemoglobin. In air, the release of nitric oxide was recorded by the production of nitrite or the oxidation of oxyhemoglobin to methemoglobin. The concentration of the thiol form in the body under physiological pH values (7.2-7.4) did not exceed 1.5-2.0%. We believe that due to the exchange reactions between the thiamine thiol form and S-nitrosocysteine protein residues, nitric oxide can be released and mixed thiamine-protein disulfides are formed. The mixed thiamine disulfides (including thiamine ester disulfides) as well as the thiamine disulfide form are quite easily reduced by low molecular weight thiols to form the thiamine cyclic form with a closed thiazole ring. A possible role of the thiamine thiol form in releasing deposited nitric oxide from low-molecular-weight S-nitrosothiols and protein S-nitrosothiols and in regulation of blood flow in the vascular bed is discussed.     

Transport and metabolism of thiamine in rat brain cortex in vitro

1. Aerobic incubation at 37° of rat brain-cortex slices in Krebs–Ringer phosphate medium containing glucose and labelled thiamine results in accumulation in the tissue of labelled thiamine and labelled thiamine phosphates. The concentration of the labelled thiamine in the tissue cell water increases with increase of external labelled thiamine concentration in an approximately linear manner, the concentration ratio for labelled thiamine (tissue:medium) exceeding unity with low external thiamine concentrations (e.g. 0·2μm) and diminishing to about unity as the external thiamine concentration is increased to 1μm. The concentration of labelled phosphorylated thiamine in the tissue is at least double that of the labelled thiamine present and its amount increases with increase of external thiamine concentration. Labelled phosphorylated thiamine appears in the medium, its amount being about one-fifteenth of that in the tissue. Phosphorylation of thiamine in the tissue proceeds during incubation for 3hr. and, with an external labelled thiamine concentration of 0·2μm, about 48% conversion of thiamine takes place. 2. In the presence of ouabain (0·1mm), which does not inhibit thiamine phosphorylation in rat brain extract, there is a fall in the uptake of labelled thiamine by brain-cortex slices and the concentration ratio for the labelled thiamine (tissue:medium) falls to below unity. Anaerobiosis, lack of Na⁺ or the presence of Amprol (0·01mm) leads to marked inhibition of thiamine phosphorylation, and the concentration ratio for labelled thiamine (tissue:medium) falls to about unity. The facts lead to the conclusion that thiamine is conveyed into the brain cell against a concentration gradient by an energy-assisted process mediated by a membrane carrier. Pyri-thiamine is a marked inhibitor of thiamine phosphorylation in brain extract. 3. Thiamine monophosphate and thiamine diphosphate inhibit thiamine phosphorylation in brain extract. They diminish `total' thiamine (free and phosphorylated) uptake into brain-cortex slices and inhibit the transport of thiamine into the brain cell, possibly by competition for the carrier. 4. Phosphorylation of labelled thiamine in brain extract is brought about not only by adenosine triphosphate (in the presence of Mg²⁺) but apparently by adenosine diphosphate and uridine triphosphate.     

Thiamine, thiamine phosphates and thiamine metabolizing enzymes in synaptosomes of rat brain

Thiamine and thiamine mono-, pyro- and triphosphate were found at detectable levels in synaptosomes isolated from whole rat brain. Synaptosomes prepared from whole brain, cerebellum and medulla were also found to contain uridine and inosine mono- and diphosphatases as well as the thiamine pyrophosphate synthetizing and hydrolyzing enzymes, but no thiamine monophosphatase. By isoelectric focusing on thin layer polyacrylamide gel of Triton X-100 homogenates of synaptosomes, thiamine pyrophosphatase activity could be separated into 10 bands with different isoelectric points. The contents of thiamine compounds and enzymes in synaptosomes were generally lower than those found in neuronal cell bodies.     

The role of thiamine in nervous tissue

The possibility that thiamine (vitamin B₁) has a role in nervous tissue that is independent of its well-documented coenzyme function is discussed. After reviewing the localization and metabolism of the vitamin and its phosphate esters, the effects of either thiamine deprivation or antimetabolites of thiamine on conduction and transmission, and the relationship between thiamine triphosphate and the genetic, neurological disease, subacute necrotizing encephalomyelopathy (Leigh's disease), it is suggested that despite the lack of hard evidence, it is likely that the vitamin possesses this alternate function.     

Regional alterations of thiamine phosphate esters and of thiamine diphosphate-dependent enzymes in relation to function in experimental Wernicke's encephalopathy

Thiamine phosphate esters (thiamine monophosphate-TMP; thiamine diphosphate-TDP and thiamine triphosphate-TTP) were measured as their thiochrome derivatives by High Performance Liquid Chromatography in the brains of pyrithiamine-treated rats at various stages during the development of thiamine deficiency encephalopathy. Severe encephalopathy was accompanied by significant reductions of all three thiamine phosphate esters in brain. Neurological symptoms of thiamine deficiency appeared when brain levels of TMP and TDP fell below 15% of normal values. Activities of the TDP-dependent enzyme -ketoglutarate dehydrogenase were more severely reduced in thalamus compared to cerebral cortex, a less vulnerable brain structure. On the other hand, reductions of TTP, the non-cofactor form of thiamine, occurred to a greater extent in cerebral cortex than thalamus. Early reductions of TDP-dependent enzymes and the ensuing metabolic pertubations such as lactic acidosis impaired brain energy metabolism, and NMDA-receptor mediated excitotoxicity offer rational explanations for the selective vulnerability of brain structures such as thalamus to the deleterious effects of thiamine deficiency.