Thiamine triphosphate: a ubiquitous molecule in search of a physiological role.

Thiamine triphosphate (ThTP) was discovered over 60 years ago and it was long thought to be a specifically neuroactive compound. Its presence in most cell types, from bacteria to mammals, would suggest a more general role but this remains undefined. In contrast to thiamine diphosphate (ThDP), ThTP is not a coenzyme. In E. coli cells, ThTP is transiently produced in response to amino acid starvation, while in mammalian cells, it is constitutively produced at a low rate. Though it was long thought that ThTP was synthesized by a ThDP:ATP phosphotransferase, more recent studies indicate that it can be synthesized by two different enzymes: (1) adenylate kinase 1 in the cytosol and (2) FoF1-ATP synthase in brain mitochondria. Both mechanisms are conserved from bacteria to mammals. Thus ThTP synthesis does not seem to require a specific enzyme. In contrast, its hydrolysis is catalyzed, at least in mammalian tissues, by a very specific cytosolic thiamine triphosphatase (ThTPase), controlling the steady-state cellular concentration of ThTP. In some tissues where adenylate kinase activity is high and ThTPase is absent, ThTP accumulates, reaching ≥ 70% of total thiamine, with no obvious physiological consequences. In some animal tissues, ThTP was able to phosphorylate proteins, and activate a high-conductance anion channel in vitro. These observations raise the possibility that ThTP is part of a still uncharacterized cellular signaling pathway. On the other hand, its synthesis by a chemiosmotic mechanism in mitochondria and respiring bacteria might suggest a role in cellular energetics.

An alternative role of FoF1-ATP synthase in Escherichia coli: synthesis of thiamine triphosphate.

In E. coli, thiamine triphosphate (ThTP), a putative signaling molecule, transiently accumulates in response to amino acid starvation. This accumulation requires the presence of an energy substrate yielding pyruvate. Here we show that in intact bacteria ThTP is synthesized from free thiamine diphosphate (ThDP) and P(i), the reaction being energized by the proton-motive force (Δp) generated by the respiratory chain. ThTP production is suppressed in strains carrying mutations in F(1) or a deletion of the atp operon. Transformation with a plasmid encoding the whole atp operon fully restored ThTP production, highlighting the requirement for F(o)F(1)-ATP synthase in ThTP synthesis. Our results show that, under specific conditions of nutritional downshift, F(o)F(1)-ATP synthase catalyzes the synthesis of ThTP, rather than ATP, through a highly regulated process requiring pyruvate oxidation. Moreover, this chemiosmotic mechanism for ThTP production is conserved from E. coli to mammalian brain mitochondria.

Thiamine triphosphate synthesis in rat brain occurs in mitochondria and is coupled to the respiratory chain.

In animals, thiamine deficiency leads to specific brain lesions, generally attributed to decreased levels of thiamine diphosphate, an essential cofactor in brain energy metabolism. However, another far less abundant derivative, thiamine triphosphate (ThTP), may also have a neuronal function. Here, we show that in the rat brain, ThTP is essentially present and synthesized in mitochondria. In mitochondrial preparations from brain (but not liver), ThTP can be produced from thiamine diphosphate and P(i). This endergonic process is coupled to the oxidation of succinate or NADH through the respiratory chain but cannot be energized by ATP hydrolysis. ThTP synthesis is strongly inhibited by respiratory chain inhibitors, such as myxothiazol and inhibitors of the H(+) channel of F(0)F(1)-ATPase. It is also impaired by disruption of the mitochondria or by depolarization of the inner membrane (by protonophores or valinomycin), indicating that a proton-motive force (Deltap) is required. Collapsing Deltap after ThTP synthesis causes its rapid disappearance, suggesting that both synthesis and hydrolysis are catalyzed by a reversible H(+)-translocating ThTP synthase. The synthesized ThTP can be released from mitochondria in the presence of external P(i). However, ThTP probably does not accumulate in the cytoplasm in vivo, because it is not detected in the cytosolic fraction obtained from a brain homogenate. Our results show for the first time that a high energy triphosphate compound other than ATP can be produced by a chemiosmotic type of mechanism. This might shed a new light on our understanding of the mechanisms of thiamine deficiency-induced brain lesions.

[Vitamin B1: metabolism and functions].

The review highlights metabolism and biological functions of vitamin B1 (thiamine). Thiamine transport systems, enzymes of its biosynthesis and degradation in various organisms, as well as molecular basis of thiamine-dependent hereditary patologies are considered. A special emphasis is given to discuss the role of thiamine triphosphate and adenylated thiamine triphosphate, a new thiamine derivative recently discovered in living cells.

Thiamine diphosphate adenylyl transferase from E. coli: functional characterization of the enzyme synthesizing adenosine thiamine triphosphate.

BACKGROUND: We have recently identified a new thiamine derivative, adenosine thiamine triphosphate (AThTP), in E. coli. In intact bacteria, this nucleotide is synthesized only in the absence of a metabolizable carbon source and quickly disappears as soon as the cells receive a carbon source such as glucose. Thus, we hypothesized that AThTP may be a signal produced in response to carbon starvation. RESULTS: Here we show that, in bacterial extracts, the biosynthesis of AThTP is carried out from thiamine diphosphate (ThDP) and ADP or ATP by a soluble high molecular mass nucleotidyl transferase. We partially purified this enzyme and characterized some of its functional properties. The enzyme activity had an absolute requirement for divalent metal ions, such as Mn2+ or Mg2+, as well as for a heat-stable soluble activator present in bacterial extracts. The enzyme has a pH optimum of 6.5-7.0 and a high Km for ThDP (5 mM), suggesting that, in vivo, the rate of AThTP synthesis is proportional to the free ThDP concentration. When ADP was used as the variable substrate at a fixed ThDP concentration, a sigmoid curve was obtained, with a Hill coefficient of 2.1 and an S0.5 value of 0.08 mM. The specificity of the AThTP synthesizing enzyme with respect to nucleotide substrate is restricted to ATP/ADP, and only ThDP can serve as the second substrate of the reaction. We tentatively named this enzyme ThDP adenylyl transferase (EC 2.7.7.65). CONCLUSION: This is the first demonstration of an enzyme activity transferring a nucleotidyl group on thiamine diphosphate to produce AThTP. The existence of a mechanism for the enzymatic synthesis of this compound is in agreement with the hypothesis of a non-cofactor role for thiamine derivatives in living cells.

Adenylate kinase 1 knockout mice have normal thiamine triphosphate levels.

Thiamine triphosphate (ThTP) is found at low concentrations in most animal tissues and it may act as a phosphate donor for the phosphorylation of proteins, suggesting a potential role in cell signaling. Two mechanisms have been proposed for the enzymatic synthesis of ThTP. A thiamine diphosphate (ThDP) kinase (ThDP+ATP if ThTP+ADP) has been purified from brewer's yeast and shown to exist in rat liver. However, other data suggest that, at least in skeletal muscle, adenylate kinase 1 (AK1) is responsible for ThTP synthesis. In this study, we show that AK1 knockout mice have normal ThTP levels in skeletal muscle, heart, brain, liver and kidney, demonstrating that AK1 is not responsible for ThTP synthesis in those tissues. We predict that the high ThTP content of particular tissues like the Electrophorus electricus electric organ, or pig and chicken skeletal muscle is more tightly correlated with high ThDP kinase activity or low soluble ThTPase activity than with non-stringent substrate specificity and high activity of adenylate kinase.

Identification, purification and reconstitution of thiamin metabolizing enzymes in human red blood cells.

Thiamin and its mono- (TMP), di- (TDP) and triphosphate (TTP) were assayed in adult human whole blood using high-performance liquid chromatography (HPLC). TDP and TTP were detected in red blood cells (RBC), but not in plasma. After incubation with 20 microM thiamin and 5 mM glucose for 2 h, the TDP and TTP contents of RBC increased from 111 to 222 and 0.6 to 2.2 nmol/l of packed RBC, respectively, suggesting enzymatic conversion of thiamin to TDP and then to TTP. Thiamin pyrophosphokinase (TPK, EC 2.7.6.2) had not been isolated before from human materials, nor had cytosolic adenylate kinase (AK1, EC 2.7.4.3) in human RBC been demonstrated to catalyze the phosphorylation of TDP to TTP, although AK1 from pig and chicken skeletal muscle possess TTP-synthesizing activity. TPK and AK1 in a human RBC lysate were therefore purified by a series of the conventional techniques. The specific activity of the purified TPK, which was obtained as a single protein, was 720 nmol TDP formed/mg protein per h at 37 degrees C. A partially purified AK1 preparation catalyzed the formation of TTP from TDP (specific activity, 170 nmol/mg protein per h at 37 degrees C) in addition to its proper reaction to form ATP from ADP. After incubation of the purified TPK and AK1 with 20 microM thiamin in the presence of ATP, ADP and Mg2+ at 37 degrees C for 48 h, the amounts of TDP and TTP synthesized were 465 and 54.0 pmol/250 microliters reaction mixture, respectively. Neither TDP nor TTP was formed when TPK was omitted from the reaction mixture and an omission of AK1 resulted in the formation of TDP alone. These results indicate that thiamin is converted to TDP by TPK and, subsequently, to TTP by AK1 in human RBC.

Thiamin triphosphate synthesis in animals.

All the evidence obtained indicates that the synthesis of TTP in vitro and in vivo is catalyzed by cytosolic adenylate kinase. Further studies should explore whether adenylate kinase is the only enzyme involved in TTP synthesis, together with physiological roles of TTP in living organisms.

Properties of thiamin triphosphate-synthesizing activity of chicken cytosolic adenylate kinase and the effect of adenine nucleotides.

Cytosolic adenylate kinase synthesis thiamin triphosphate (TTP) from thiamin diphosphate (TDP) in vitro by a reversible reaction: TDP + ADP Mg2+ in equilibrium TTP + AMP. The backward (TTP----TDP) reaction rate was 3-times faster than the forward (TDP----TTP) reaction rate when all the substrate concentrations were 0.1 mM. This property of TTP-synthesizing activity of the enzyme did not explain the fact that the [TTP]/[TDP] molar ratio determined in chicken white skeletal muscle is 5.0 (Miyoshi, K., Egi, Y., Shioda, T. and Kawasaki, T. (1990) J. Biochem. 108, 267-270). To solve this problem, we have studied the properties of TTP-synthesizing activity of the purified recombinant chicken cytosolic adenylate kinase preparation and the effect of adenine nucleotides, especially of ATP. The backward reaction of the TTP synthesis did not proceed in the presence of 8.8 mM ATP, a physiological concentration in chicken white skeletal muscle, while the forward reaction proceeded at a reduced rate. The [TTP]/[TDP] ratio found after a long incubation period was 3.0 and 0.7, respectively, in the presence and absence of 8.8 mM ATP. These results indicate that the high [TTP]/[TDP] molar ratio found in chicken white muscle was demonstrated in vitro by the purified chicken cytosolic adenylate kinase and support in vivo TTP synthesis by this enzyme.

Synthesis and accumulation of thiamin triphosphate in Escherichia coli cells expressing chicken cytosolic adenylate kinase.

To examine whether cytosolic adenylate kinase (AK1, EC 2.7.4.3) catalyzes synthesis of thiamin triphosphate (TTP) in vivo, chicken AK1 was expressed in Escherichia coli, and cellular AK1 activity and TTP content were determined. E. coli harboring the vector plasmid was used as a control. Chicken AK1 was expressed in the producer strain at a high level (83 U/mg protein) even without inducers, and this expression was doubled (153 U/mg protein) by beta-D-isopropylthiogalactopyranoside (IPTG). TTP was accumulated in the producer cells at a high level (5.7 nmol/g dry weight) without IPTG and this was also doubled (10.2 nmol/g dry weight) by IPTG. TTP content in the control strain was very low (0.2-0.9 nmol/g dry weight) and was unaffected by IPTG. Neither bacterial growth curve nor cellular content of AMP, ADP, ATP, thiamin diphosphate or total thiamin (sum of thiamin and its phosphate esters) was different between the producer and the control strains. These results indicate that chicken AK1 expressed in E. coli catalyzed the synthesis and accumulation of TTP within the bacterial cells.

Evidence for in vivo synthesis of thiamin triphosphate by cytosolic adenylate kinase in chicken skeletal muscle.

We showed previously that cytosolic adenylate kinase (AK1) purified from pig skeletal muscle catalyzes in vitro formation of thiamin triphosphate (TTP) from thiamin diphosphate (TDP) and ADP in addition to ATP formation from ADP [Shikata, H. et al. (1989) Biochem. Int. 18, 933-942]. To obtain evidence for in vivo synthesis of TTP by AK1, changes in TTP content and AK1 activity were determined in chicken skeletal muscle during development after hatching. Thiamin phosphate metabolism in chicken skeletal muscle was also studied. i) An extremely high TTP content, 81% of total thiamin (thiamin plus thiamin phosphates), was detected in the white (fast-twitch) muscle of adult normal chicken (5th to 9th month) compared with a relatively high TTP content of 31% in the red (slow-tonic) muscle. Since approximately equivalent amounts of total thiamin were present in the two types of muscle, the ratio of TTP to TDP was high (5.0) in the white muscle and low (0.41) in the red muscle. ii) Rabbit anti-chicken AK1 antiserum against the purified chicken cytosolic AK1 preparation was obtained. Both AK1 activity and TTP-synthesizing activity in crude cytosol fraction of adult chicken white muscle were inhibited in parallel by the antiserum. iii) In the white muscle of normal chicken, the TTP content and AK1 activity responsible for forming either ATP or TTP were increased in a parallel manner up to day 16 after hatching, after which both remained constant. In the red muscle, on the other hand, both the TTP content and the AK1 activity were low in comparison with those in the white muscle, and were almost constant after hatching.(ABSTRACT TRUNCATED AT 250 WORDS)

Cytosolic adenylate kinase catalyzes the synthesis of thiamin triphosphate from thiamin diphosphate.

An attempt was made to purify a porcine skeletal muscle enzyme catalyzing the formation of thiamin triphosphate (TTP) from thiamin diphosphate (TDP), requiring ATP, Mg2+ and a cofactor (creatine). As the purification proceeded, the reaction requirements for ATP and creatine were lost and then a requirement for ADP was manifested. The activity responsible for TTP synthesis from TDP, ADP, and Mg2+ was found to be copurified with adenylate kinase [EC 2.7.4.3] activity, and was finally purified to a single band on SDS-PAGE. Antiserum obtained against the purified enzyme preparation inhibited both adenylate kinase activity and the TTP-synthesizing activity to exactly the same extent. These results indicate that adenylate kinase catalyzes TTP formation from TDP in vitro.

Properties of the thiamin triphosphate-synthesizing activity catalyzed by adenylate kinase (isoenzyme 1).

Adenylate kinase isozyme 1 (AK1) catalyzes thiamin triphosphate (TTP) formation from thiamin diphosphate (TDP) and ADP. The properties of the TTP-synthesizing activity of purified AK1 from porcine skeletal muscle were studied. The activity was found to require TDP, ADP, and Mg2+, and ATP was only 14.4% as active as ADP. Thiamin monophosphate (TMP) and thiamin were not utilized as substrates. ADP was specific as a phosphate donor; and CDP, UDP, and GDP supported TTP formation at rates less than 1% of that with ADP. Optimal pH and temperature for the TTP-synthesizing activity were 10.0 and 37 degrees C, respectively. The activity showed saturation kinetics for both substrates, and the Km values for TDP and ADP were calculated to be 0.83 mM and 43 microM, respectively. The enzyme catalyzed the reverse reaction (TTP + AMP----TDP + ADP) and stoichiometry between TTP and TDP was demonstrated in the forward and reverse reactions.

Hydrolysis and synthesis of thiamin triphosphate in bacteria.

Thiamin triphosphate (ThTP) in early stationary phase cells of Escherichia coli grown in nutrient broth with 0.1% yeast extract was found to constitute approximately 5-7% of cellular thiamin diphosphate (ThDP) or around 5 nmol/g cell. Nearly the same level of ThTP was obtained in a Bacillus strain. When E. coli was loaded with an excess of ThTP or ThDP, cellular ThTP was found to be controlled in the course of the long term to maintain its ratio to the amount of cellular ThDP. The ThTP vs. ThDP ratio in E. coli cells after short-term ThDP uptake was found to be a function of the cellular growth phase. The ratio in early exponential phase E. coli cells was found to be approximately 4% and it became lower (less than 3%) when cell growth proceeded to the late exponential stage. Two phosphatases specific for ThTP (ThTPase) among thiamin phosphates were detected in E. coli. One required Mg2+ and was found mainly in the soluble fraction, while the other was Mg2+-independent and originated from the membrane. The two ThTPases were similar to their rat tissue counterparts.

[Biosynthesis of thiamine triphosphate and identification of thiamine diphosphate-binding proteins in the rat liver hyaloplasm]. / Biosintez tiamintrifosfata i identifikatsiia tiamindifosfatsviazyvaiushchikh belkov gialoplazmy pecheni krys.

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.

Synthesis of thiamine triphosphate in rat brain in vivo.

Thiamine metabolism in vivo was studied by intracerebroventricular injection of labeled thiamine in rat brain. Labeled thiamine was found to be rapidly converted to the phosphorylated thiamine esters. The distribution of the radioactive thiamine compounds was reached to steady state at 3 hr after injection: thiamine, thiamine monophosphate, thiamine pyrophosphate, and thiamine triphosphate were 8-12%, 12-14%, 72-74%, and 2-3%, respectively, in cerebral cortex. The presence of labeled thiamine triphosphate in the brain was further confirmed by the treatment with thiamine triphosphatase which had an absolute substrate specificity for thiamine triphosphate. These results suggest that thiamine triphosphate is synthesized in vivo in rat brain.

[Thiamine triphosphate content of the liver of albino rats with different levels of thiamine]. / Soderzhanie tiamintrifosfata v pecheni belykh krys pri pazlichnoi obespechennosti tiaminom.

Content of thiamine triphosphate (TTP) was studied in rat liver tissue under conditions of normal state, thiamine deficiency and after loading with thiamine. The concentration of TTP in hepatocytes of control animals was found to be 3.2-3.6 micrograms/g, corresponding to 40% of the total thiamine pool in the cells. The TTP appears to serve as a reserve of vitamin B1 deposited in mitochondria of the cells in which the biosynthesis of thiamine pyrophosphate of their own did not take place. Administration of thiamine did not induce the TTP overproduction in hepatocytes; the content of TTP was maintained in the mitochondria of the hepatocytes at the constant level.