Effect of tongue-palate contact mode on food transport during mastication.

The physiological mechanisms underlying Stage II transport (STII), during which comminuted solid food is transported from the oral cavity into the meso-pharynx for aggregation into a pre-swallow bolus, have yet to be clarified. The purpose of the present study was to investigate relationships between tongue-palate contact during mastication and incidence of STII by synchronised analysis of tongue pressure production on a hard palate and video-endoscopic (VE) images during mastication. Tongue pressure at 5 measuring points with an ultra-thin sensor sheet attached to the hard palate and trans-nasal VE images while masticating corned beef was recorded for 12 healthy subjects. All recordings were divided into 2 groups: mastication with STII and without STII. Tongue pressure duration was longer at the anterior-median part in the group with STII than in the group without STII. Integrated values of tongue pressure were greater at the anterior-median parts and posterior circumferential part in the group with STII. Integrated values of tongue pressure per second were greater in late-stage mastication than in early-stage mastication in the group with STII. These results suggest that the tongue-palate contacting at the anterior-median and post-circumferential parts of the hard palate is related with the incidence of STII.

Oligonucleotide-targeting periostin ameliorates pulmonary fibrosis.

Idiopathic pulmonary fibrosis (IPF) is a fatal disease with a median survival of 3-4 years after diagnosis. It is the most frequent form of a group of interstitial pneumonias of unknown etiology. Current available therapies prevent deterioration of lung function but no therapy has shown to improve survival. Periostin is a matricellular protein of the fasciclin 1 family. There is increased deposition of periostin in lung fibrotic tissues. Here we evaluated whether small interfering RNA or antisense oligonucleotide against periostin inhibits lung fibrosis by direct administration into the lung by intranasal route. Pulmonary fibrosis was induced with bleomycin and RNA therapeutics was administered during both acute and chronic phases of the disease. The levels of periostin and transforming growth factor-ß1 in airway fluid and lung tissue, the deposition of collagen in lung tissue and the lung fibrosis score were significantly reduced in mice treated with siRNA and antisense against periostin compared to control mice. These findings suggest that direct administration of siRNA or antisense oligonucleotides against periostin into the lungs is a promising alternative therapeutic approach for the management of pulmonary fibrosis.

Primary systemic carnitine deficiency is caused by mutations in a gene encoding sodium ion-dependent carnitine transporter.

Primary systemic carnitine deficiency (SCD; OMIM 212140) is an autosomal recessive disorder characterized by progressive cardiomyopathy, skeletal myopathy, hypoglycaemia and hyperammonaemia. SCD has also been linked to sudden infant death syndrome. Membrane-physiological studies have suggested a defect of the carnitine transport system in the plasma membrane in SCD patients and in the mouse model, juvenile visceral steatosis. Although the responsible loci have been mapped in both human and mouse, the underlying gene has not yet been identified. Recently, we cloned and analysed the function of a novel transporter protein termed OCTN2. Our observation that OCTN2 has the ability to transport carnitine in a sodium-dependent manner prompted us to search for mutations in the gene encoding OCTN2, SLC22A5. Initially, we analysed the mouse gene and found a missense mutation in Slc22a5 in jvs mice. Biochemical analysis revealed that this mutation abrogates carnitine transport. Subsequent analysis of the human gene identified four mutations in three SCD pedigrees. Affected individuals in one family were homozygous for the deletion of a 113-bp region containing the start codon. In the second pedigree, the affected individual was shown to be a compound heterozygote for two mutations that cause a frameshift and a premature stop codon, respectively. In an affected individual belonging to a third family, we found a homozygous splice-site mutation also resulting in a premature stop codon. These mutations provide the first evidence that loss of OCTN2 function causes SCD.

Octopaminergic modulation of the single Ca2+ channel currents in Kenyon cells isolated from the mushroom body of the cricket brain.

Octopamine plays an important role in mediating reward signals in olfactory learning and memory formation in insect. However, its target molecules and signaling pathways are still unknown. In this study, we investigated the effects of octopamine on the voltage-activated Ca2+ channels expressed in native Kenyon cells isolated from the mushroom body of the cricket (Gryllus bimaculatus) brain. The cell-attached patch clamp recordings with 100 mM Ba2+ outside showed the presence of dihydropyridine (DHP) sensitive L-type Ca2+ channels with a single channel conductance of approximately 21+/-2 pS (n=12). The open probability (NPo) of single Ca2+ channel currents decreased by about 29+/-7% (n=6) by bath application of 10 microM octopamine. Octopamine-induced decrease in Po was imitated by bath application of 8-Br-cAMP, a membrane-permeable cAMP analog. Pre-treatment of Kenyon cells with the octopamine receptor antagonist phentolamine blocked the inhibitory effect of octopamine on Ca2+ channels. Pre-treatment of Kenyon cells with H-89, a selective inhibitor of cAMP-dependent protein kinase (PKA) attenuated the inhibitory effect of bath applied octopamine on Ca2+ channels. These results indicate that DHP-sensitive L-type Ca2+ channel is a target protein for octopamine and its modulation is mediated via cAMP and PKA-dependent signaling pathways in freshly isolated Kenyon cell in the cricket G. bimaculatus.

Molecular basis of argininemia. Identification of two discrete frame-shift deletions in the liver-type arginase gene.

Argininemia results from a deficiency of arginase (EC 3.5.3.1), the last enzyme of the urea cycle in the liver. We examined the molecular basis for argininemia by constructing a genomic library followed by cloning and DNA sequencing. Discrete mutations were found on two alleles from the patient, a product of a nonconsanguineous marriage. There was a four-base deletion at protein-coding region 262-265 or 263-266 in exon 3 that would lead to a reading-frame shift after amino acid residue 87 and make a new stop codon at residue 132. The other was a one-base deletion at 77 or 78 in exon 2 that would lead to a reading-frame shift after residue 26 and make a stop codon at residue 31. For confirmation, genomic DNAs from the patient and from her parents were amplified by the polymerase chain reaction method. The patient was shown to be a compound heterozygote, inheriting an allele with the four-base deletion from the father and the other allele with the one-base deletion from the mother. These data seem to be the first evidence of a case of argininemia caused by two different deletion mutations.

Biphasic change and disuse-mediated regression of canal network structure in cortical bone of growing rats.

The canal network in cortical bone is an indispensable basis of bone vascularity, and its structure changes according to bone growth. Using monochromatic synchrotron radiation microCT (SRmicroCT), we evaluated the structural change of the canal network in growing rat tibiae and the response of this network to disuse. Tibiae were harvested from both hindlimbs of 9- and 14-week-old male Wistar rats subjected to unilateral sciatic neurectomy (SN) at 6 weeks of age (W9, n=8; W14, n=8) and from intact hindlimbs of 6-week-old rats (W6, n=8). Images of distal diaphyseal segments were reconstructed by SRmicroCT with a voxel size of 5.83 mum and then translated into local mineral densities using a calibrated relation between linear absorption coefficients and the concentration of K(2)HPO(4) solution. The canal network was segmented by simple thresholding at a bone mineral density of 0.82 g.cm(-3) and its structural properties were determined. In intact hindlimbs, the canal network showed a biphasic change with growth, as represented by increases followed by decreases in canal volume fraction (Ca.vol.f), the density of canals running longitudinally (Ca.num.d), and the density of canal connections (Ca.con.d): Ca.vol.f=2.2, 3.1, and 1.8%, Ca.num.d=77, 98, and 70 mm(-2), and Ca.con.d=18, 41, and 21 mm(-3) in W6, W9, and W14, respectively. In SN hindlimbs, bone growth deceleration was accompanied by a 16% smaller Ca.vol.f and a 22% smaller Ca.con.d in W9 and a 27% smaller Ca.vol.f, a 12% smaller Ca.num.d, and a 39% smaller Ca.con.d in W14 than those in intact hindlimbs. Furthermore, the canal branching structure became more treelike in SN hindlimbs. The effect of SN on the canal network appeared mainly in the periosteal sector of the anteriolateral cortex in W9 and spread throughout the cortex in W14. These findings will lead to a better understanding of microcirculation in cortical bone growth.

Prooxidant action of furanone compounds: implication of reactive oxygen species in the metal-dependent strand breaks and the formation of 8-hydroxy-2'-deoxyguanosine in DNA.

Prooxidant properties of furanone compounds including 2,5-furanone (furaneol, 4-hydroxy-2,5-dimethyl-furan-3-one), 4,5-furanone (4,5-dimethyl-3-hydroxy-2(5H)-furanone) (sotolone) and cyclotene (2-hydroxy-3-methyl-2-cyclopenten-1-one) were analyzed in relation to the metal-reducing activity. Only 2.5-furanone known as a "strawberry or pineapple furanone" inactivated aconitase the most sensitive enzyme to active oxygen in the presence of ferrous sulfate, suggesting the furaneol/iron-mediated generation of reactive oxygen species. 2,5-Furanone caused strand scission of pBR322 DNA in the presence of copper. Treatment of calf thymus DNA with 2,5-furanone plus copper produced 8-hydroxy-2'-deoxyguanosine in DNA. 2,5-Furanone showed a potent copper-reducing activity, and thus, DNA strand breaks and the formation of 8-hydroxy-2'-deoxyguanosine by 2,5-furanone can be initiated by the production of superoxide radical through the reduction of cupric ion to cuprous ion, resulting in the conversion to hydrogen peroxide and hydroxyl radical. However, an isomer and analog of 2,5-furanone, 4,5-furanone and cyclotene, respectively, did not show an inactivation of aconitase, DNA injuries including strand breakage and the formation of 8-hydroxy-2'-deoxyguanosine, and copper-reducing activity. Cytotoxic effect of 2,5-furanone with hydroxyketone structure can be explained by its prooxidant properties: furaneol/transition metal complex generates reactive oxygen species causing the inactivation of aconitase and the formation of DNA base damage by hydroxyl radical.

Protective effect of NADP-isocitrate dehydrogenase on the paraquat-mediated oxidative inactivation of aconitase in heart mitochondria.

Protective role of NADP-isocitrate dehydrogenase in the oxidative inactivation of mitochondrial enzymes was analyzed. Administration of paraquat to the rat inactivated liver mitochondrial enzymes: the aconitase activity decreased to one quarter, and citrate synthase and fumarase to half, whereas cytosolic enzymes were not affected. Activities of heart mitochondrial and cytosolic enzymes were not at all changed in the rat treated with paraquat, but paraquat directly inactivated aconitase in the heart mitochondria isolated from the non-treated rats. The paraquat-dependent inactivation of aconitase was prevented by activating NADP-isocitrate dehydrogenase in the presence of oxidized glutathione. NADP-isocitrate dehydrogenase could regenerate glutathione in isolated heart mitochondria, indicating that paraquat-mediated inactivation depends on the glutathione-regenerating activity by enhanced NADPH supply. Lower NADP-isocitrate dehydrogenase activity in liver mitochondria cannot regenerate reduced glutathione for scavenging reactive oxygen species, resulting in the paraquat-induced oxidative inactivation of mitochondrial enzymes. However, higher activity of NADP-isocitrate dehydrogenase participates in the regeneration of reduced glutathione causing stabilization of enzymes in heart mitochondria.

A kinetic study of the inhibition of yeast AMP deaminase by polyphosphate.

Inorganic pyrophosphate and polyphosphates have acted as potent inhibitors of purified AMP deaminase (EC 3.5.4.6) from yeast: the activity fell to a definite limit with the increase in the concentration of the inhibitor. The effect of polyphosphate was largely on the maximal velocity of the enzyme with some decrease in affinity. The cooperative effect of AMP, analyzed in terms of a Hill coefficient, remained at 2 in the absence and presence of polyphosphate. Binding of polyphosphate to the enzyme showed no cooperativity. The inhibition of AMP deaminase by polyphosphate can be qualitatively and quantitatively accounted for by the partial mixed-type inhibition mechanism. Both the Ki value for the inhibitor and the breakdown rate of the enzyme-substrate-inhibitor complex are dependent on the chain length of polyphosphate, suggesting that the breakdown rate of the enzyme-substrate-inhibitor complex is regulated by binding of polyphosphate to a specific inhibitory site.

In situ studies on AMP deaminase as a control system of the adenylate energy charge in yeasts.

The role of AMP deaminase reaction in the stabilization of the adenylate energy charge was investigated using permeabilized yeast cells. The addition of Pi or Zn2+, which inhibits AMP deaminase, remarkably retarded the depletion of total adenylate pool and the recovery of the adenylate energy charge. Polyamine, an activator of the enzyme, decreased total adenylates, resulting in the enhanced recovery of the energy charge in situ. AMP deaminase can act as a regulatory enzyme in the system that stabilizes the adenylate energy charge in yeast cells under the conditions of severe metabolic stress.

The effect of spermine on the interaction of AMP deaminase with threonine dehydratase activity in yeast.

Evidence suggesting that AMP deaminase (EC 3.5.4.6) is responsible for the stimulation of threonine dehydratase (EC 4.2.1.16) activity in situ is presented using yeast cells which have been rendered permeable. The addition of polyamine, an activator of AMP deaminase, resulted in the increase in ammonia concentration, which can stimulate the activity of yeast threonine dehydratase. Polyamine may regulate the synthesis of isoleucine and valine, and of the intermediates of citric acid cycle through the activation of AMP deaminase-threonine dehydratase system as a 'cascade system' in yeast.

Inhibition of chicken erythrocyte AMP deaminase by tetraiodofluorescein compounds.

A kinetic study has been performed on the inhibition of the chicken erythrocyte AMP deaminase (AMP aminohydrolase, EC 3.5.4.6) reaction by tetraiodofluorescein and Rose Bengal. These dyes inhibited the enzyme by decreasing its affinity for the substrate without affecting the maximum velocity. Kinetic analysis has shown the inhibition constants for tetraiodofluorescein and Rose Bengal to be 350 and 55 micrometer, respectively, and the presence of 4 binding sites of the enzyme for the inhibitors per enzyme molecule. These results suggest that the fluorescein dyes mimic the AMP binding at the catalytic center of the enzyme, which can be formed by the "dinucleotide fold".

Role of cations in the regulation of baker's yeast AMP deaminase.

The effect of polyamines and divalent cations including alkaline earth metals and transition metals on the AMP deaminase (AMP aminohydrolase EC 3.5.4.6) purified from baker's yeast was investigated. (1) Polyamines and alkaline earth metals activated the enzyme in the absence of ATP: these cations largely enhanced the maximal velocity without alteration of S0.5 and nH (Hill coefficient) values. However, transition metals acted as potent inhibitors, which decreased the maximal velocity of the enzyme in the absence of ATP. (2) All of the divalent cations showed an activation of the enzyme in the presence of ATP, followed by a progressive decrease in activity as the concentrations of transition metals increased. (3) The increase in the concentrations of polyamines or alkaline earth metals showed no more activating effect when the enzyme was fully activated by the addition of excess alkali metals in the absence of ATP, but divalent cation-activation was observed in the presence of ATP even if alkali metals were saturating. These results suggest the presence of two types of binding sites for cations: 1, the sites for free cations and 2, those for ATP-metal complexes. The former sites include the activating sites for alkali metals, polyamines and free alkaline earth metals, and the inhibitory sites for free transition metals. The latter sites are the activating sites for ATP-metal complexes, which are suggested to be commonly occupied by alkaline earth metals and transition metals and to form an ATP bridge (E-ATP-M) complex.

Interaction of the AMP deaminase-ammonium system with glutamate dehydrogenase in yeast.

NH+4 produced as a result of the activation of AMP deaminase (AMP aminohydrolase, EC 3.5.4.6) was utilized effectively to form glutamate from 2-oxoglutarate by the action of NADP-glutamate dehydrogenase (L-glutamate:NADP+ oxidoreductase (deaminating), EC 1.4.1.4) under in situ conditions in yeast cells: the decrease in total adenylates stoichiometrically corresponded to the production of NH+4 plus glutamate. Reducing equivalents, NADPH, for the synthesis of glutamate can be supplied by the pentose phosphate pathway. The addition of spermine, an activator of AMP deaminase without changes in glutamate dehydrogenase activity, resulted in an increase in ammonium concentration, which can enhance the formation of glutamate from 2-oxoglutarate. A close correlation of NADP-glutamate dehydrogenase with AMP deaminase activity was observed under various growth conditions. The interaction of the AMP deaminase-ammonium system with glutamate dehydrogenase as an ammonium-assimilating reaction may participate in the control of the cellular NH+4 level, which can correlate with glycolysis.

The regulatory role of spermine and fatty acid in the interaction of AMP deaminase with phosphofructokinase.

The role of fatty acid and polyamine in the interaction of AMP deaminase (EC 3.5.4.6)-ammonium system with glycolysis was investigated using permeabilized yeast cells. (1) The addition of fatty acid inhibited the activity of AMP deaminase in situ, resulting in a decrease in the total adenylate pool depletion, and in the recovery of the adenylate energy charge. (2) The addition of fatty acid resulted in an indirect decrease in the activity of phosphofructokinase (EC 2.7.1.11) through a reduced level of ammonium ion; fatty acid itself did not inhibit phosphofructokinase activity in the presence of excess ammonium ion. (3) Spermine protected AMP deaminase from inhibition by fatty acid: the increased ammonium level enhanced phosphofructokinase activity, glycolytic flux and the recovery of the energy charge. In contrast, alkali metals, which are also activators of AMP deaminase had little effect on the inhibition of the enzyme. The inhibition of glycolysis by fatty acid and its reversal by polyamine can be accounted for by the changes in ammonium ion through the action of AMP deaminase-ammonium system, and the physiological relevance is discussed.

Ion-dependent activation of AMP nucleosidase from Azotobacter vinelandii.

The effect of divalent cations on the purified AMP nucleosidase (AMP phosphoribohydrolase, EC 3.2.2.4) from Azotobacter vinelandii was investigated. All alkaline earth metal-ATP complexes were essential activators of the enzyme, and free alkaline earths also activated the enzyme in an allosteric manner: the apparent Ka for ATP and nH values (Hill interaction coefficient) decreased from 0.45 to 0.05 mM, and from 4 to 2, respectively, with increase in Mg2+ concentration. Transition metal-ATP complex also activated AMP nucleosidase, but a potent activation of the enzyme was followed by a progressive decrease in activity as the concentrations of transition metals increase. The enzyme fully activated in the presence of Mg2+ was inhibited by the higher concentrations of transition metals with the identical I0.5 values when Mg2+ was present. These results suggest the presence of two classes of binding sites for divalent cations. One is the activating site for ATP-metal complex, which is suggested to be commonly occupied by alkaline earths and transition metals. The other sites are those for free metal binding, the sites for free alkaline earths and free transition metals are activating and inhibitory sites, respectively.

In vitro and in situ studies on the inhibition of yeast AMP deaminase by fatty acids.

The effect of various fatty acids on the purified and in situ AMP deaminase (AMP aminohydrolase, EC 3.5.4.6) was investigated: both the purified AMP deaminase and the permeabilized system of yeast cells were used as the enzyme sources. (1) All the saturated fatty acids, longer than 10 in the hydrocarbon chain, were inhibitors of the purified enzyme in the absence of ATP, whereas no or little inhibition of the enzyme was observed in the presence of ATP. Unsaturated fatty acids acted as more potent inhibitors of the purified enzyme, although the addition of ATP increased the I0.5 values for these fatty acids. Fatty acids acted as non-competitive inhibitors without alteration of the affinity for the substrate in the absence and presence of ATP. (2) Unsaturated fatty acids showed a powerful inhibition of the in situ AMP deaminase, and the presence of ATP could scarcely affect the inhibition of the in situ enzyme by these fatty acids. On the other hand, no or little inhibition of the in situ enzyme by saturated fatty acids was observed in the absence and presence of ATP. The difference in the kinetics properties between the in situ and the purified enzyme suggests that there is difference in protein interactions for AMP deaminase in situ and in vitro.

Activation by spermine of citrate synthase from porcine heart.

Spermine activated citrate synthase from porcine heart by decreasing the Km value for the substrate oxaloacetate without affecting the maximal velocity. Spermine markedly increased the maximal velocity of the saturation function with respect to acetyl-CoA as the substrate under conditions of intracellular concentrations of oxaloacetate, but the enzyme was not activated by spermine under conditions of higher concentrations of oxaloacetate. The concentration of spermine required for 50% activation of the enzyme was about 50 microM. Spermidine showed only a little activation, while putrescine caused no activation. Spermine, which contributes to an activation of Ca2(+)-sensitive dehydrogenases of the citric acid cycle by enhancing Ca2+ uptake into mitochondria, can activate citrate synthase directly, and is responsible for the stimulation of oxidative metabolism in mitochondria.

The role of polyamines in the regulation of AMP deaminase isozymes.

The differential effects of polyamines on the activity of AMP deaminase isozyme A (from rat muscle) and isozyme B (from rat liver) are reported. Polyamines activate isozyme B but inhibit isozyme A.

Effects of monovalent cations on AMP nucleosidase from Azotobacter vinelandii.

The effect of monovalent cations on the purified AMP nucleosidase (AMP phosphoribohydrolase, EC 3.2.2.4) from Azotobacter vinelandii was investigated. All the monovalent cations were activators of the enzyme: Rb+ and Cs+ were the most effective, followed by K+, Na+, NH4+ and Li+ in that order. The apparent Ka for MgATP and nH values (Hill's interaction coefficient) decreased from 0.9 to 0.1 mM, and from 4 to 1, respectively, with the increase in K+ concentration, suggesting that the cation effects are on MgATP binding rather than catalysis. Gel filtration studies have revealed that the enzyme forms a non-dissociable enzyme species with a Stokes radius of 6.0--6.2 nm in the presence of saturating concentrations of monovalent cations, which can be distinguished from the 5.5-nm enzyme species showing temperature-dependent dissociation of the molecule in sulfate or phosphate. These results suggest that these ligands affect the association of the subunits through changes in the environment of the hydrophobic side chains of the enzyme molecules.