Phosphate Derivatives of Thiamine and Na+ Channel in Conducting Membranes

The results show that thiamine derivatives are copurified with the specific proteins forming the Na+ channel in conducting membranes. Therefore, thiamine derivatives could well play a specific role in the molecular aspects of bioelectrogenesis , an interpretation that could help explain the neurological symptoms observed in human pathology as well as in animals experimentally rendered deficient in vitamin B1.     

Regulation of ion uptake in membrane vesicles from rat brain by thiamine compounds

We examined the effects of thiamine derivatives on ion uptake in rat brain membrane vesicles. Thiamine triphosphate (1 mM) and pyrithiamine (0.1 mM) increase chloride uptake. Preincubation of crude homogenate with thiamine or pyrithiamine increases chloride uptake while oxythiamine has the reverse effect. Thiamine and oxythiamine also affect 22Na+ and 86Rb+ uptake in the same way as for 36Cl- but to a lesser extent. Thiamine-dependent 36Cl- uptake is activated by sodium bicarbonate (10 mM) and partially inhibited by bumetanide (0.1 mM) and 2,4-dinitrophenol (0.1 mM). Preincubation with thiamine increases the thiamine triphosphate content of the vesicles. The hypothesis that TTP is the activator of a particular chloride uptake mechanism is discussed.     

Thiamine and vasculopathies

After peroxynitrite addition to aqueous solutions of thiamine at neutral and alkaline pH formation of thiamine disulfide and fluorescent products was observed. The fluorescent compounds were identified as thiochrome (TChr) and oxodihydrothiochrome (ODTChr) using spectral and fluorescent methods as well as paper chromatography and mass spectrometry. TChr and ODTChr are not the end products of thiamine oxidation and in neutral medium are unstable to peroxynitrite action and degrade rapidly to form non-fluorescent products. Thiamine, TChr, and ODTChr protects tyrosine from its modification by peroxynitrite. In the presence of TChr and ODTChr modification of tyrosinyl residues in human serum albumin and cytocrome c decreased. The prolonged thiamine incubation with glucose, amino acids and nitrite was accompanied by oxidative transformation of thiamine and formation of fluorescent products. We have shown that thiamine is also oxidized into TChr and ODTChr, i.e., it forms the same products as after thiamine oxidation by peroxynitrite. Moreover, thiamine (or its derivatives) appears as peroxynitrite scavenger leading to toxic effects lowering at diabetes mellitus.     

Interaction of n-alkylguanidines with the sodium channels of squid axon membrane

The effects of n-alkylguanidine derivatives on sodium channel conductance were measured in voltage clamped, internally perfused squid giant axons. After destruction of the sodium inactivation mechanism by internal pronase treatment, internal application of n-amylguanidine (0.5 mM) or n-octylguanidine (0.03 mM) caused a time-dependent block of sodium channels. No time-dependent block was observed with shorter chain derivatives. No change in the rising phase of sodium current was seen and the block of steady-state sodium current was independent of the membrane potential. In axons with intact sodium inactivation, an apparent facilitation of inactivation was observed after application of either n-amylguanidine or n-octylguanidine. These results can be explained by a model in which alkylguanidines enter and occlude open sodium channels from inside the membrane with voltage-independent rate constants. Alkylguanidine block bears a close resemblance to natural sodium inactivation. This might be explained by the fact that alkylguanidines are related to arginine, which has a guanidino group and is thought to be an essential amino acid in the molecular mechanism of sodium inactivation. A strong correlation between alkyl chain length and blocking potency was found, suggesting that a hydrophobic binding site exists near the inner mouth of the sodium channel.     

Isomorphism on a physical system of the Hodgkin-Huxley equations for sodium conductance: toxin allosteric effects and gating currents

An isomorphism on a physical system of the Hodgkin-Huxley equations for sodium ion conductance in the nerve membrane is derived. The physical system consists of 8 states. It shows that the voltage dependence of the sodium conductance arises from a change in ionization of the molecule that provides the ion-selective conductance channels. It associates reversibly with singly charged (H+?) and doubly charged (Ca++?) ions. The inactivation process is the result of the associating of an ionized particle by half of the states. The effect of toxins and narcotics in blocking or inactivating sodium conductance can be understood as an enzyme or allosteric change of the standard free energy difference of the molecule that provides the sodium channels. The effect of changing pH and Ca++ substrate concentration on the sodium conductance is predicted. The gating charge current is predicted. The time constant predicted is in agreement with experiment.     

Changes in membrane hydrogen and sodium conductances during progesterone-induced maturation of Ambystoma oocytes

A voltage-gated hydrogen ion-selective conductance has been previously described in the immature oocyte of the urodele amphibian Ambystoma. The present study was prompted by reports that changes in membrane voltage and internal pH, as well as in internal sodium ion concentration, occur during the hormone-induced maturation of oocytes from other amphibians. As activation of membrane currents might mediate changes in internal ion concentrations in addition to altering the membrane voltage, microelectrode recording techniques have been employed to examine changes in membrane conductances which occur during maturation of Ambystoma oocytes. It was observed that during the first 5 hr of maturation the magnitude of the hydrogen ion conductance gradually decreased, and that subsequently there was an increase in the amplitude of a voltage-dependent noninactivating sodium conductance. After 6 to 7 hr, after the loss of the hydrogen conductance and at about the time of germinal vesicle breakdown, the resting potential of the oocyte spontaneously shifted from approximately -10 mV to approximately +30 mV, where it remained until at least 24 hr after the initiation of maturation. This voltage transition was due to the appearance of mechanisms generating inward current in the oocyte membrane; part of this inward current was due to the tonic activation of the sodium conductance. Changes in internal pH and internal sodium ion concentration occurred during maturation, as judged from shifts in the reversal potentials of both hydrogen and sodium currents. A gradual decrease in internal hydrogen ion concentration was observed up until the time of disappearance of the hydrogen conductance (change in internal pH from about 7.15 in immature oocytes to about 7.40 by 3 hr after application of progesterone). This was followed, as sodium conductance increased, by an apparent rise in the internal sodium ion concentration (from about 6 mM to about 17 mM by 10 hr postprogesterone).     

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.     

Transient polarization currents in the squid giant axon.

It has been repeatedly noted that the change of conformation of the molecules that serve as the ion-selective channels for sodium and potassium conductance in the nerve membrane will be accompanied by a change in the dipole moment of the molecule. This time-dependent change of dipole moment will produce transient currents in the membrane. The canonical form for these currents is determined with conventional statistical mechanics formalism. It is pointed out that the voltage dependence of the conductance channel conductance determines the free energy of the system to within a factor that is an unknown function of the voltage. Since the dipole currents do not depend on this unknown function, they are completely determined 0y the observed properties of the conductance system. The predicted properties of these dipole currents, their time constants and strengths, are calculated. By using the observed properties of gating currents, the density of the sodium channels is computed. The predicted properties of the dipole currents are found to compare satisfactorily with the observed properties of gating currents.     

The localization of transport properties in the frog lens.

The selectivity of fiber-cell membranes and surface-cell membranes in the frog lens is examined using a combination of ion substitutions and impedance studies. We replace bath sodium and chloride, one at a time, with less permeant substitute ions and we increase bath potassium at the expense of sodium. We then record the time course and steady-state value of the intracellular potential. Once a new steady state has been reached, we perform a small signal-frequency-domain impedance study. The impedance study allows us to separately determine the values of inner fiber-cell membrane conductance and surface-cell membrane conductance. If a membrane is permeable to a particular ion, we presume that the conductance of that membrane will change with the concentration of the permeant ion. Thus, the impedance studies allow us to localize the site of permeability to inner or surface membranes. Similarly, the time course of the change in intracellular potential will be rapid if surface membranes are the site of permeation whereas it will be slow if the new solution has to diffuse into the intercellular space to cause voltage changes. Lastly, the value of steady-state voltage change provides an estimate of the lens' permeability, at least for chloride and potassium. The results for sodium are complex and not well understood. From the above studies we conclude: (a) surface membranes are dominated by potassium permeability; (b) inner fiber-cell membranes are permeable to sodium and chloride, in approximately equal amounts; and (c) inner fiber-cell membranes have a rather small permeability to potassium.     

Agonistic effects of xanthines on tetrodotoxin-sensitive sodium channels in the rat dorsal root ganglion neurons

The effects of four xanthine derivatives, caffeine, caffeine benzoate, theophylline, and bromtheophylline, on sodium channels in internally perfused rat dorsal root ganglion neurons were studied under voltage-clamp and whole-cell patch-clamp conditions. Reversible acceleration, enhancement of the amplitude of sodium currents, and shifts of the current-voltage relation (plotted for their maxima), as well as of the steady-state inactivation curve toward more negative potentials, were observed at external applications of the above substances in the concentrations of 0.2–4.0 mM. Under long exposures, inactivation of sodium currents became slower in a part of the cells. Yet, when the exposure to 4 mM or higher concentrations was longer than 10 min, a rise in the passive conductance was obvious, and functional state of the cells became worse. Blocking effects of the xanthine derivatives on transient or delayed potassium currents were not observed. Thus, agonistic action of xanthines on sodium channels has been demonstrated, and it is supposed that a considerable component of their pharmacological effects is provided by the action on Na⁺/Ca²⁺ exchange.     

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.     

Blockage of Sodium Conductance Increase in Lobster Giant Axon by Tarichatoxin (Tetrodotoxin)

Tarichatoxin, isolated from California newt eggs, has been found to selectively block the increase of sodium conductance associated with excitation in lobster giant axons at nanomolar concentrations. This resulted from a reduction in the amplitude of the conductance increase rather than a change in its temporal characteristics. The normal potassium conductance increase with depolarization is not altered. A high concentration of calcium applied concomitantly with the toxin significantly improves the reversibility of the sodium blocking. This toxin has recently been identified as chemically identical with tetrodotoxin from the puffer fish. Toxins from the two sources are equally effective and are shown to have an action which is distinctly different from that of procaine.     

Features of thiamine diphosphate-dependent enzyme inhibition by oxodihydrothiochrome and its phosphorylated derivatives

Anticoenzyme action of new derivatives of thiamine: oxodihydrothiochrome and its mono- and diphosphoric esters has been studied in the experiments on mice. It is shown that the given compounds exert an inhibiting action on transketolase and pyruvate dehydrogenase and do not change activity of 2-oxoglutarate dehydrogenase in the animal organism. Antivitamin effect of the studied inhibitors is observed with the lower doses and in the earlier terms as compared with the other known inhibitors of thiamine-diphosphate-dependent enzymes. The preparations inhibit activity of the yeast pyruvate-decarboxylase by the mixed (with respect to thiamine-diphosphate) type (Ki for oxodihydrothiochrome and its mono- and diphosphoric esters: 2.3 x 10(-3), 7.2 x 10(-4), 5.6 x 10(-5) M, respectively). Possible mechanisms of the action of the mentioned compounds as thiamine antimetabolites are discussed.     

Effect of Sodium Nitrite on the Destruction of Thiamine

The effect of sodium nitrite on the destruction of thiamine was investigated. When sodium nitrite-containing thiamine solution was treated by the condition of heating at 75°C for 60 min, elemental sulfur and 4-methyl-5-(β-hydroxyethyl) thiazole were identified, and thiochrome was estimated. When sodium nitrite-free thiamine solution was heated at 75°C for 60 min, 4-methyl-5-(β-hydroxyethyl) thiazole was a main product, and elemental sulfur and thiochrome were not produced. From these results, it showed that elemental sulfur and thiochrome were produced from thiamine by the effect of sodium nitrite.     

Urinary proteases degrade epithelial sodium channels

Summary The mammalian urinary bladder epithelium accommodates volume changes by the insertion and withdrawal of cytoplasmic vesicles. Both apical membrane (which is entirely composed of fused vesicles) and the cytoplasmic vesicles contain three types of ionic conductances, one amiloride sensitive, an-other a cation-selective conductance and the third a cation conductance which seems to partition between the apical membrane and the mucosal solution. The transport properties of the apical membrane (which has been exposed to urine in vivo) differ from the cytoplasmic vesicles by possessing a lower density of amiloride-sensitive channels and a variable level of leak conductance. It was previously shown that glandular kallikrein was able to hydrolyze epithelial sodium channels into the leak conductance and that this leak conductance was further degraded into a channel which partitioned between the apical membrane and the mucosal solution. This report investigates whether kallikrein is the only urinary constituent capable of altering the apical membrane ionic permeability or whether other proteases or ionic conditions also irreversible modify apical membrane permeability.Alterations of mucosal pH, urea concentrations, calcium concentrations or osmolarity did not irreversible affect the apical membrane ionic conductances. However, urokinase and plasmin (both serine proteases found in mammalian urine) were found to cause an irreversible loss of amiloride-sensitive current, a variable change in the leak current as well as the appearance of a third conductance which was unstable in the apical membrane and appears to partition between the apical membrane and the mucosal solution. Amiloride protects the amiloride-sensitive conductance from hydrolysis but does not protect the leak pathway. Neither channel is protected by sodium. Fluctuation analysis demonstrated that the loss of amiloride-sensitive current was due to a decrease in the sodium-channel density and not a change in the single-channel current. Assuming a simple model of sequential degradation, estimates of single-channel currents and conductances for both the leak channel and unstable leak channel are determined.     

The Physical Interpretation of Mathematical Models for Sodium Permeability Changes in Excitable Membranes

This paper deals with the physical interpretation of existing mathematical models which describe the transient sodium conductance changes in excitable membranes. It is shown that there are clear limitations to the specificity of inferences which may be drawn about physical mechanism from the behavior of abstract models. Within these limitations, it is shown that a pronounced inactivation shift is not necessarily evidence for coupling between the events responsible for the rise and inactivation of the sodium conductance, but that the inactivation shift may be associated with an event whose rate explicitly depends on the rate of continuous voltage change or magnitude of instantaneous voltage change.     

Effect of various thiamine supplies of the body on the enzyme activity in the metabolism of xenobiotics and lipid peroxidation in rat liver microsomes

The effect of different thiamine supply of the organism on the enzymic activity in metabolism of xenobiotics and the processes of the lipid peroxidation in the liver microsomes with the application of phenobarbital, an inductor of microsomes' enzymes are studied in experiments on Wistar albino male rats. It is established that deficit of vitamin B1 increases the activity in most of processes studied in microsomes and also the intensity of lipids' peroxidation. Phenobarbital enhances the activity of microsomal oxidation irrespectively of vitamin B1 supply, whereas peroxidation of lipids is activated by phenobarbital only in animals fed on physiological doses of vitamin B1. The N-demethylation rate of dimethylaniline in experiments in vitro is inhibited by high doses of thiamine (150 microM), its derivatives inhibited this process in low concentrations (15 microM) as well.     

Molecular aspects of bioelectrogenesis

The action potential is a dissipative process producing entropy and using free energy. This is well demonstrated by: 1) the evolution of the Na conductance under voltage clamping conditions, 2) the microcalorimetric measurements, 3) the analysis of heat evolution during the conductance changes. The most appropriate explanation must involve an exogenous energy source since the energy dissipated by the ionic flows or even the applied stimulus depolarization are far too small to account for the overall energy balance. Thiamine triphosphate is a likely candidate as specific operating substance. The more so, since it is specifically hydrolyzed by a triphosphatase the activity of which is modulated by various anions. It is therefore suggested that the control of the Cl-permeability, a process requiring the hydrolysis of thiamine triphosphate, is the key to our understanding of the energetics of the action potential.     

Simultaneous detection of thiamine and its phosphate esters from microalgae by HPLC

We present an easy and sensitive method for measuring thiamine and its phosphate esters in small biological samples of microalgae (Amphidinium carterae Hulburt and Nitzschia microcephala Grun). The method consists of extraction of thiamine and its derivatives in acid solution, followed by liquid chromatography with fluorescence detection. The detection limit is as low as 15 fmol of thiamine. For comparison to microalgae, the method has been applied to evaluate thiamine levels in the crustacean Artemia salina Leach and is suitable for nutritional studies of the food web of the Baltic salmon, which suffers from thiamine deficiency. This method of HPLC analysis can be readily utilized to follow uptake and interconversion of thiamine and its phosphate esters in many micro- and macroalgae.