Distribution and properties of CDP-diglyceride:inositol transferase from brain

CDP-diglyceride is converted to phosphatidyl inositol by several particulate subcellular fractions of guinea pig brain, with highest specific activity in the microsomal fraction. Optimal conditions with respect to pH, metal ion concentration, and substrate concentrations have been determined. The reaction was stimulated by the addition of bovine serum albumin and by Tween 80. Of several dl -CDP-diglycerides synthesized and used as substrates in a spectrophoto-metric assay for the enzyme, dl -CDP-didecanoin was the most active. The enzyme showed a high selectivity for myo-inositol. Of a number of compounds tested, only scyllo-inosose and epi-inosose served as substrates. Three inositol isomers and three myo-inositol monophosphates inhibited the reaction slightly. The most potent inhibitor found was galactinol, a myo-inositol galactoside.     

myo-Inositol dehydrogenase and scyllo-inositol dehydrogenase from Lactobacillus casei BL23 bind their substrates in very different orientations

Many bacteria can use myo-inositol as the sole carbon source using enzymes encoded in the iol operon. The first step is catalyzed by the well-characterized myo-inositol dehydrogenase (mIDH), which oxidizes the axial hydroxyl group of the substrate to form scyllo-inosose. Some bacteria, including Lactobacillus casei, contain more than one apparent mIDH-encoding gene in the iol operon, but such redundant enzymes have not been investigated. scyllo-Inositol, a stereoisomer of myo-inositol, is not a substrate for mIDH, but scyllo-inositol dehydrogenase (sIDH) enzymes have been reported, though never observed to be encoded within the iol operon. Sequences indicate these enzymes are related, but the structural basis by which they distinguish their substrates has not been determined. Here we report the substrate selectivity, kinetics, and high-resolution crystal structures of the proteins encoded by iolG1 and iolG2 from L. casei BL23, which we show encode a mIDH and sIDH, respectively. Comparison of the ternary complex of each enzyme with its preferred substrate reveals the key variations allowing for oxidation of an equatorial versus an axial hydroxyl group. Despite the overall similarity of the active site residues, scyllo-inositol is bound in an inverted, tilted orientation by sIDH relative to the orientation of myo-inositol by mIDH.     

The identification of MYO-inositol:NAD(P)+ oxidoreductase in mammalian brain.

$\text{myo}$-Inositol:NAD(P)⁺ oxidoreductase ($\text{myo}$-inositol oxidoreductase) has been identified in bovine brain. This enzyme elutes from DEAE cellulose with 0.3 M KCl in 50 mM Tris buffer, pH 7.5. Using NADH as cofactor $\text{myo}$-inosose-2 is reduced selectively to $\text{myo}$-inositol. With NADPH the enzyme forms both $\text{myo}$-inositol and $\text{scyllo}$-inositol, however, at a lower rate. The enzyme was chromatographed on G-100 Sephadex and found to have an apparent molecular weight of 74,000. This enzyme differs in DEAE binding, molecular weight and cofactor specificity from the previously described $\text{scyllo}$-inositol oxidoreductase which utilizes NADPH exclusively to produce 3 fold more $\text{scyllo}$-inositol than $\text{myo}$-inositol.     

Rat L6 myotubes as an in vitro model system to study GLUT4-dependent glucose uptake stimulated by inositol derivatives

Some of inositol derivatives have been reported to help the action of insulin stimulating glucose uptake in skeletal muscle cells. Rat L6 myotubes were employed in an attempt to develop an in vitro model system for investigation of the possible insulin-like effect of eight inositol derivatives, namely allo-inositol, d-chiro-inositol l-chiro-inositol, epi-inositol, muco-inositol, myo-inositol, scyllo-inositol and d-pinitol. At a higher concentration of 1 mM seven inositol derivatives other than myo-inositol were able to stimulate glucose uptake, while at 0.1 mM only d-chiro-inositol, l-chiro-inositol, epi-inositol and muco-inositol could induce glucose uptake, indicating their significant insulin-mimetic activity. Immunoblot analyses revealed that at least d-chiro-inositol, l-chiro-inositol, epi-inositol, muco-inositol and d-pinitol were able to induce translocation of glucose transporter 4 (GLUT4) to plasma membrane not only in L6 myotubes but also in skeletal muscles of rats ex vivo. These results demonstrated that L6 myotubes appeared efficient as an in vitro system to identify inositol derivatives exerting an insulin-like effect on muscle cells depending on the induced translocation of GLUT4.     

Preparative-scale separation by anion-exchange chromatography of six per-C-deuterated inositol epimers produced during C-1H-C-2H exchange reactions with raney nickel in deuterium oxide

After a ¹H-²H exchange reaction of myo-inositol with deuterated Raney nickel in deuterium oxide, six epimers (scyllo-, chiro-, neo-, allo-, muco-, and epi-inositol), in addition to myo-inositol, were identified as their per-O-(trimethylsilyl) derivatives by gas-liquid chromatography on a fused-silica capillary column of SE-30, and also by gas-liquid chromatography-mass spectrometry. Preparative-scale separation of six of these deuterium-labeled inositols (98–99% deuterated) was achieved by anion-exchange chromatography, after partial purification of the epimerization products by recrystallization. That is, anion-exchange chromatography using Dowex 1 resin completely resolved myo-, scyllo-, allo- and muco-inositol as their borate complexes. Although neo-inositol was only partially separated from chiro-inositol, these two inositols were completely resolved from the four other epimers.     

Metabolic engineering of Corynebacterium glutamicum for production of scyllo-inositol,a drug candidate against Alzheimer's disease

Scyllo-inositol has been identified as a potential drug for the treatment of Alzheimer's disease. Therefore, cost-efficient processes for the production of this compound are desirable. In this study, we analyzed and engineered Corynebacterium glutamicum with the aim to develop competitive scyllo-inositol producer strains. Initial studies revealed that C. glutamicum naturally produces scyllo-inositol when cultured with myo-inositol as carbon source. The conversion involves NAD⁺-dependent oxidation of myo-inositol to 2-keto-myo-inositol followed by NADPH-dependent reduction to scyllo-inositol. Use of myo-inositol for biomass formation was prevented by deletion of a cluster of 16 genes involved in myo-inositol catabolism (strain MB001(DE3)Δiol1). Deletion of a second cluster of four genes (oxiC-cg3390-oxiD-oxiE) related to inositol metabolism prevented conversion of 2-keto-myo-inositol to undesired products causing brown coloration (strain MB001(DE3)Δiol1Δiol2). The two chassis strains were used for plasmid-based overproduction of myo-inositol dehydrogenase (IolG) and scyllo-inositol dehydrogenase (IolW). In BHI medium containing glucose and myo-inositol, a complete conversion of the consumed myo-inositol into scyllo-inositol was achieved with the Δiol1Δiol2 strain. To enable scyllo-inositol production from cheap carbon sources, myo-inositol 1-phosphate synthase (Ino1) and myo-inositol 1-phosphatase (ImpA), which convert glucose 6-phosphate into myo-inositol, were overproduced in addition to IolG and IolW using plasmid pSI. Strain MB001(DE3)Δiol1Δiol2 (pSI) produced 1.8 g/L scyllo-inositol from 20 g/L glucose and even 4.4 g/L scyllo-inositol from 20 g/L sucrose within 72 h. Our results demonstrate that C. glutamicum is an attractive host for the biotechnological production of scyllo-inositol and potentially further myo-inositol-derived products.     

Identification of ononitol and O-methyl-scyllo-inositol in pea root nodules

Ononitol (4-O-methyl-myo-inositol) and O-methyl-scyllo-inositol were identified in pea (Pisum sativum L.) root nodules formed by twoRhizobium leguminosarum strains. Ononitol was the major soluble carbohydrate in nodules formed by strain 1045 while O-methyl-scyllo-inositol and two unidentified components were dominant in the carbohydrate pattern of the nodules formed by strain 1 a. The cyclitols were also present in the denodulated roots, but to a much smaller extent; in the above-ground plant parts only traces were found. The identification of ononitol and O-methyl-scyllo-inositol was established by gas chromatography and gas chromatography-mass spectrometry utilizing trimethylsilyl- and acetyl-derivatives.Abbreviations GC-MS gas chromatography-mass spectroscopy - TLC thin-layer chromatography     

Redistribution of Tritium during Germination of Grain Harvested from myo-[2-H]Inositol- and scyllo-[R-H]Inositol-Labeled Wheat

Wheat kernels from myo-[2-³H]inositol- or scyllo-[R-³H]inositol-labeled plants (Sasaki and Loewus 1980 Plant Physiol 66: 740-745) were used to study redistribution of ³H into growing regions during germination. Most of the labeled 1-α-galactinol (or the analogous scyllo-inositol galactoside) was hydrolyzed within 1 day. Water-soluble phytate was dephosphorylated within 3 days. A large reserve of bound phytate continued to release myo-inositol over several days. Translocation of free myo-inositol to growing regions provided substrate for the myo-inositol oxidation pathway and incorporation of ³H into new cell wall polysaccharides.     

Degradation of <Emphasis Type="Italic">myo</Emphasis>-inositol Hexakisphosphate by a Phytate-degrading Enzyme from <Emphasis Type="Italic">Pantoea agglomerans</Emphasis>

High-pressure liquid chromatography (HPLC) analysis established myo-inositol pentakisphosphate as the final product of phytate dephosphorylation by the phytate-degrading enzyme from Pantoea agglomerans. Neither product inhibition by phosphate nor inactivation of the Pantoea enzyme during the incubation period were responsible for the limited phytate hydrolysis as shown by addition of phytate-degrading enzyme and phytate, respectively, after the observed stop of enzymatic phytate degradation. In additon, the Pantoea enzyme did not possess activity toward the purified myo-inositol pentakisphosphate. Using a combination of High-Performance Ion Chromatography (HPIC) analysis and kinetic studies, the nature of the generated myo-inositol pentakisphosphate was established. The data demonstrate that the phytate-degrading enzyme from Pantoea agglomerans dephosphorylates myo-inositol hexakisphosphate in a stereospecific way to finally D-myo-inositol(1,2,4,5,6)pentakisphosphate.     

The enzymes involved in the synthesis of phytic acid in Lemna gibba (Studies on the biosynthesis of cyclitols,XL.)

Summary The biosynthesis of phytic acid is known to be catalyzed by enzymes causing a stepwise phosphorylation of myo-inositol or 1l-myo-inositol 1-phosphate with adenosine triphosphate as phosphate donor. The kinases responsible for these phosphorylations in Lemna gibba were purified by affinity chromatography on a Sepharose gel carrying myo-inositol 2-phosphate at the binding site. Three fractions with enzymatic activity could be identified; in the first one, we find myo-inositol kinase (EC 2.7.1.64) phosphorylating myo-inositol to 1l-myo-inositol 1-phosphate; the second one brings about the phosphorylation of myo-inositol trisphosphate to phytic acid; the third one phosphorylates myo-inositol 1-phosphate to a myo-inositol trisphosphate. An enzyme oxidizing 1l-myo-inositol 1-phosphate to an uronic acid derivative is found in the first two fractions. In the presence of ATP, Mg²⁺ Mn²⁺, and the second and the third enzyme fractions in an appropriate mixture, 1l-myo-inositol 1-phosphate can be phosphorylated to phytic acid. The structure of the trisphosphate acting as an intermediate is not yet known.     

An examination of some possible sources of soil inositol phosphates

Summary Examination of extracts prepared from soil fungi and yeast cells (S. cavlsbergensis) showed that phytate phosphorus was not present. Phytin was successfully extracted from the acorns ofQuercus robur andQ. hodgkinsonii but was apparently absent from acorns ofQ. ilex. Acorn phytin was shown to consist only of phosphate esters ofmyo-inositol although freescyllo-inositol is present in this plant tissue. Small amounts of phytate phosphorus were isolated from sand/clay cultures, after a period of incubation, but onlymyo-inositol derivatives appeared to be present.     

In <Emphasis Type="Italic">silico</Emphasis> study on the substrate binding manner in human <Emphasis Type="Italic">myo</Emphasis>-inositol monophosphatase 2

The human IMPA2 gene encoding myo-inositol monophosphatase 2 is highly implicated with bipolar disorder but the substrates and the reaction mechanism of myo-inositol monophosphatase 2 have not been well elucidated.9 In the present study, we constructed 3D models of three- and two-Mg²⁺-ion bound myo-inositol monophosphatase 2, and studied substrate-binding manners using the docking program AutoDock3. The subsequent study showed that the three-metal-ion model could interact with myo-inositol monophosphates, as follows: The phosphate moiety coordinated three Mg²⁺ ions, and the inositol ring formed hydrogen bonds with the amino acids conserved in the family. Furthermore, the OH group vicinal to the phosphate group formed a hydrogen bond with a non-bridging oxygen atom of the phosphate. These interactions have been proposed as crucial for forming the transitional state, bipyramidal structure in the bovine myo-inositol monophosphatase. We therefore propose that the human myo-inositol monophosphatase 2 interacts with myo-inositol monophosphates in the three-metal-ion bound form, and proceeds the dephosphorylation through the three-metal-ion theory.     

Studies on avian erythrocyte metabolism: purification and properties of myo-inositol 1-phosphatase form chick erythrocytes

An enzyme capable of hydrolyzing myo-inositol 1-phosphate was identified and partially purified from the erythrocytes of 7-day chicks. It has an apparent molecular weight of approximately 60,000, is heat stable, and has a pH of optimal activity between 6.5 and 7.3. In most regards the kinetic properties are similar to the myo-inositol 1-phosphatases of rat testis, rat mammary gland, bovine brain, and of yeast. The enzyme has an absolute requirement for a divalent cation; Mg²⁺ gave the greatest activity, with an optimal concentration of 2.5 mm in the standard assay employed. Zn²⁺, Co²⁺, and Mn²⁺ supported activity to a lesser degree. Activity was inhibited by NaF, HgCl₂, and p-hydroxymercuribenzoate. myo-Inositol tetrakis (dihydrogen phosphate) and myo-inositol 1,3,4,5,6-pentakis (dihydrogen phosphate) were not substrates for this enzyme and inhibited the hydrolysis of myo-inositol 1-phosphate. Unlike other phosphatases for myo-inositol 1-phosphate, this enzyme cleaved myo-inositol 1-phosphate (K_m = 8.6 × 10^?5 m) and myo-inositol 2-phosphate (K_m = 2.86 × 10^?4 m) at approximately the same rates. It also hydrolyzed 2′-purine and pyrimidine ribonucleotides about as well as myo-inositol 1-phosphate, but was only 20–30% as active against the 3′-ribonucleotides and had scarcely any activity against the 5′-ribonucleotides. The amount of enzyme activity in erythrocytes of embryos, chicks, and mature chickens was the same (~29 μmol/ml rbc/h). The biological function of this enzyme in avian erythrocytes is unclear at this time. Other tissues containing this phosphatase also have an enzyme which synthesizes myo-inositol 1-phosphate from glucose 6-phosphate, but we have been unable to detect the presence of such an enzyme in avian erythrocytes.     

Partial Purification and Characterization of Indol-3-Ylacetylglucosemyo-Inositol Indol-3-Ylacetyltransferase (Indoleacetic Acid-Inositol Synthase)

A procedure is described for the purification of the enzyme indol-3-ylacetylglucose:myo-inositol indol-3-ylacetyltransferase (IAA-myo-inositol synthase). This enzyme catalyzes the transfer of indol-3-ylacetate from 1-0-indol-3-ylacetyl-β-d-glucose to myo-inositol to form indol-3-ylacetyl-myo-inositol and glucose. A hexokinase or glucose oxidase based assay system is described. The enzyme has been purified approximately 16,000-fold, has an isoelectric point of pH 6.1 and yields three catalytically inactive bands upon acrylamide gel electrophoresis of the native protein. The enzyme shows maximum transferase activity with myo-inositol but shows some transferase activity with scyllo-inositol and myo-inosose-2. No transfer of IAA occurs with myo-inositol-d-galactopyranose, cyclohexanol, mannitol, or glycerol as acyl acceptor. The affinity of the enzyme for 1-0-indol-3-ylacetyl-β-d-glucose is, K_m = 30 micromolar, and for myo-inositol is, K_m = 4 millimolar. The enzyme does not catalyze the exchange incorporation of glucose into IAA-glucose indicating the reaction mechanism involves binding of IAA glucose to the enzyme with subsequent hydrolytic cleavage of the acyl moiety by the hydroxyl of myo-inositol to form IAA myo-inositol ester.     

Digalactosyldiacylglycerols Isolated from a Brown Alga as Effective Phagostimulants for a Young Abalone

Sinorhizobium fredii USDA191 is a Gram-negative bacterium capable of forming nitrogen-fixing nodules on soybean roots. The USDA191 idhA gene encoding myo-inositol dehydrogenase, an enzyme necessary for myo-inositol utilization, is known to be involved in competitive nodulation and nitrogen fixation. In Bacillus subtilis, myo-inositol dehydrogenase catalyzes the first step of the myo-inositol catabolic pathway. Recently iolE was identified as the gene encoding 2-keto-myo-inositol dehydratase, which catalyzes the second step in the pathway. Here we report the presence of 2-keto-myo-inositol dehydratase activity in free-living USDA191 cells cultured in a medium containing myo-inositol. An iolE ortholog was cloned from USDA191. USDA191 iolE was expressed in Escherichia coli as a His₆-tag fusion and purified to exhibit 2-keto-myo-inositol dehydratase activity. Inactivation of USDA191 iolE led to defective myo-inositol utilization. USDA191 iolE partially complemented a B. subtilis iolE deficient mutant. These results suggest that S. fredii USDA191 utilizes a myo-inositol catabolic pathway, analogous to that of B. subtilis, involving at least idhA and iolE.     

Myo-inositol oxygenase from oat seedlings

Summary Enzyme preparations from oat seedlings showing the activity ofmyo-inositol oxygenase (E.C.1.13.99.1) have been described previously. In contrast tomyo-inositol oxygenase preparations from other sources, e.g. rat kidney or yeast, the oat enzyme seemed to exhibit a somewhat less stringent activity, acting on other inositols and inositol methyl ethers as well as onmyo-inositol.By purification of the enzyme present in the extract from oat seedlings with the help of an affinity gel specific for enzymes acting onmyo-inositol a homogeneous enzyme preparation was obtained, which shows the same strict specificity as themyo-inositol oxygenase from other sources. It has a molecular weight of 62,000 and tends to aggregate to oligomers (up to tetramers) under physiological pH-values; in more alkaline media dissociation to monomers is observed. The action on the other inositols and inositol methyl ethers is apparently due to one or more other enzymes, which are also adsorbed on the affinity gel, but can be separated from themyo-inositol oxygenase by elution with increasing concentrations ofmyo-inositol.Dedicated to Professor Karl KRATZL on the occasion of his 60th birthday.     

Conversion of 1,6-Anhydromaltose into Pseudodisaccharides Containing Aminocyclitols as Constituent

1, 6-Anhydromaltose was chemically converted into a couple of pseudodisaccharides containing different inosamine (3-amino-3-deoxy-epi-and 1-amino-1-deoxy-1 l-myo-inositol) residues as constituents via 6-deoxy-6-nitro-maltose derivatives.     

Down-regulation of the <Emphasis Type="Italic">myo</Emphasis>-inositol oxygenase gene family has no effect on cell wall composition in Arabidopsis

The enzyme myo-inositol oxygenase (MIOX; E.C. 1.13.99.1) catalyzes the ring-opening four-electron oxidation of myo-inositol into glucuronic acid, which is subsequently activated to UDP-glucuronic acid (UDP-GlcA) and serves as a precursor for plant cell wall polysaccharides. Starting from single T-DNA insertion lines in different MIOX-genes a quadruple knockdown (miox1/2/4/5-mutant) was obtained by crossing, which exhibits greater than 90% down-regulation of all four functional MIOX genes. Miox1/2/4/5-mutant shows no visible phenotype and produces viable pollen. The alternative pathway to UDP-glucuronic acid via UDP-glucose is upregulated in the miox1/2/4/5-mutant as a compensatory mechanism. Miox1/2/4/5-mutant is impaired in the utilization of myo-inositol for seedling growth. The incorporation of myo-inositol derived sugars into cell walls is strongly (>90%) inhibited. Instead, myo-inositol and metabolites produced from myo-inositol such as galactinol accumulate in the miox1/2/4/5-mutant. The increase in galactinol and raffinose family oligosaccharides does not enhance stress tolerance. The ascorbic acid levels are the same in mutant and wild type plants.     

Ts65Dn Mouse,a Down Syndrome Model,Exhibits Elevated myo-Inositol in Selected Brain Regions and Peripheral Tissues

myo-Inositol is elevated in the Down syndrome (DS; trisomy 21) brain and may play a role in mental retardation. In the present study, we examined brain regions and peripheral tissues of Ts65Dn mouse, a recently characterized genetic model of DS, for abnormal myo-inositol accumulation. A GC/MS technique was used to quantitate myo-inositol and other polyol species (ribitol, arabitol, xylitol, and 1,5-anhydrosorbitol) in tissues from the Ts65Dn mice and control diploid mice. myo-Inositol was found to be elevated in frontal cortex, hippocampus, and brain stem but not in cerebellum of the Ts65Dn mouse. Among peripheral organs examined, liver and skeletal muscle were found to excessively accumulate myo-inositol. In all tissues, concentrations of polyol internal controls were normal. The Ts65Dn mouse is useful to study the possible effect of elevated myo-inositol on cellular processes.