Gradient ion chromatography of inositol phosphates

Inositol phosphates including phytic acid were separated in 30 min by gradient ion chromatography with postcolumn derivatization. All four pentakisphosphates were resolved, while four tetrakisphosphate peaks were detected. The limits of detection for all polyphosphates, including tris- and bisphosphates, were between 1 and 2 nmol. The method was used to compare nonenzymatic dephosphorylation of inositol hexakisphosphate at pH 4.0 versus pH 10.8. The only pentakisphosphate detected in calf brains was identified as myo-inositol 1,3,4,5,6-pentakisphosphate. The major pentakisphosphate in raw soybean seeds was myo-inositol 1,2,4,5,6-pentakisphosphate of unknown enantiomeric composition, while lesser amounts of myo-inositol 1,2,3,4,5-pentakisphosphate of unknown enantiomeric composition, myo-inositol 1,2,3,4,6-pentakisphosphate, and myo-inositol 1,3,4,5,6-pentakisphosphate were also present.     

Anion exchange chromatographic separation of inositol phosphates and their quantification by gas chromatography

The direct measurement of mass of inositol trisphosphate from biologic samples is described. Separation of inositol monophosphate, bisphosphate, trisphosphate, and inositol tetrakisphosphate was achieved using anion exchange chromatography with a sodium sulfate gradient. In addition, separation of the isomers of each inositol phosphate was performed using HPLC procedures. The individual inositol phosphate fractions were subsequently dephosphorylated and desalted. The myo-inositol from each fraction was then derivatized to the hexatrimethylsilyl derivative and the myo-inositol derivatives were quantified by a novel gas chromatographic analysis using the hexatrimethylsilyl derivative of chiro-inositol as an internal concentration reference. This method is a reproducible and relatively rapid procedure for the direct quantification of inositol phosphate mass which overcomes many of the problems associated with the use of radiolabeled precursors. The method is a significant improvement over existing procedures for the quantitative determination of the mass of inositol phosphate by virtue of improved recovery, sensitivity, and technical simplicity. The applicability of this method is illustrated by the quantitative determination of inositol trisphosphate in response to norepinephrine stimulation of adult canine myocytes and cerebral cortical brain slices and by measurement of the isomers of inositol trisphosphate in isolated myocytes.     

High-performance thin-layer chromatography method for inositol phosphate analysis

A simple and inexpensive high-performance thin-layer chromatography (HPTLC) method for the analysis of inositol mono- to hexakisphosphates on cellulose precoated plates is described. Plates were developed in 1-propanol–25% ammonia solution–water (5:4:1) and substance quantities as low as 100–200 pmol were detected by molybdate staining. Chromatographic mobilities of nucleotides and phosphorylated carbohydrates were also characterized. Charcoal treatment was employed to separate nucleotides from inositol phosphates with similar R_F values prior to HPTLC analysis. Practical application of the HPTLC system is demonstrated by analysis of grain extracts from wild type and low-phytate mutant barley as well as phytate degradation products resulting from barley phytase activity.     

A rapid separation method for inositol phosphates and their isomers.

The stimulation of phenylalanine hydroxylation in isolated liver cells by sub-maximally effective concentrations of glucagon (less than 0.1 microM) is antagonized by insulin (0.1 nM-0.1 microM). This phenomenon is a consequence of a decrease in the glucagon-stimulated phosphorylation of phenylalanine hydroxylase from liver cells incubated in the presence of insulin. The impact of insulin on the phosphorylation state and activity of the hydroxylase is mimicked by incubation of liver cells in the presence of orthovanadate (10 microM). A series of cyclic AMP and cyclic GMP analogues enhanced phenylalanine hydroxylation: in each case insulin diminished the stimulation of flux. These results are discussed in the light of the characteristics of insulin action on other metabolic processes.     

Determination of inositol phosphates and other biologically important anions by ion chromatography

Ion chromatography has been applied to the simultaneous, multi-component determination of biologically important anions. More than 20 different biologically important anions were separated on high performance ion-exchange columns and detected using chemically suppressed conductivity. Application of the technique to the separation of inositol mono-, bis-, and trisphosphates shows that these compounds can be separated from the other ions tested and can be detected at concentrations that may be found in vivo. For inositol monophosphate, the conductivity was proportional to the amount of compound from less than 20 pmol to more than 400 nmol. Although alternative methods are available for assaying each of these anions individually, the advantages of ion chromatography lie in the sensitivity of detection, the speed of separation, and the ability to simultaneously determine numerous ions. This method should be broadly applicable to studies of second messengers, measurements of reaction rates, and various metabolic studies.     

High-performance liquid chromatographic analysis of radiolabeled inositol phosphates

Separation of inositol phosphates by low-pressure anion-exchange chromatography yields unsatisfactory results, while previously described anion-exchange HPLC methods require such extensive processing times that they preclude efficient sample analysis. Using a low-capacity Vydac nucleotide anion-exchange column, we have developed a method which allows complete separation of myo-inositol, inositol 1-phosphate, inositol 1,4-bisphosphate, inositol 1,4,5-trisphosphate, and inositol 1,3,4,5-tetrakisphosphate in approximately 10 min followed by a 5-min column regeneration time. This method provided exceptional reproducibility and quantitative recovery of each inositol phosphate. One column was used for over 300 separations with no loss in performance or alteration in elution pattern. A modified procedure with a 14-min gradient was developed to separate the 1,3,4- and 1,4,5-isomers of inositol trisphosphate. These separation procedures were used to characterize the kinetics of degradation of inositol phosphates by lysates of erythrocytes and neutrophils. We conclude that these procedures are applicable for rapid and quantitative analysis of radiolabeled inositol phosphates in cellular extracts.     

High-performance liquid chromatography method for the quantification of entacapone in human plasma

A simple, sensitive and selective HPLC method with UV detection (315 nm) was developed and validated for quantitation of entacapone in human plasma, the newest addition to the group of antiparkinsonian agents. Following a single-step liquid-liquid extraction (LLE) with ethyl acetate/n-hexane (30/70, v/v), the analyte and internal standard (rofecoxib) were separated using an isocratic mobile phase of 30 mM phosphate buffer (pH 2.75)/acetonitrile (62/38, v/v) on a reverse phase C18 column. The lower limit of quantitation was 25 ng/mL, with a relative standard deviation of less than 8%. A linear range of 25-2500 ng/mL was established. This HPLC method was validated with between-batch and within-batch precision of 2.2-4.2% and 1.7-7.8%, respectively. The between-batch and within-batch accuracy was 98.7-107.5% and 97.5-106.0%, respectively. Frequently coadministered drugs did not interfere with the described methodology. Stability of entacapone in plasma was excellent, with no evidence of degradation during sample processing (autosampler) and 30 days storage in a freezer. This validated method is sensitive, simple and repeatable enough to be used in pharmacokinetic studies.     

High-performance liquid chromatography method for the quantification of pantoprazole in human plasma

A sensitive and selective HPLC method with UV detection (290 nm) was developed and validated for quantitation of pantoprazole, proton-pump inhibitor, in human plasma. Following a single-step liquid-liquid extraction with methyl tert-butyl ether/diethyl ether (70/30, v/v), the analyte and internal standard (zonisamide) were separated using an isocratic mobile phase of 10mM phosphate buffer (pH 6.0)/acetonitrile (61/39, v/v) on reverse phase Waters symmetry C18 column. The lower limit of quantitation was 20 ng/mL, with a relative standard deviation of less than 4%. A linear range of 20-5000 ng/mL was established. This HPLC method was validated with between-batch and within-batch precision of 1.3-3.2% and 0.7-3.3%, respectively. The between-batch and within-batch bias was -0.5 to 8.2 % and -2.5 to 12.1%, respectively. This validated method is sensitive and repeatable enough to be used in pharmacokinetic studies.     

Separation of inositol phosphates and glycerophosphoinositol phosphates by high-performance liquid chromatography

We developed a HPLC method which separates the following nine inositol-containing compounds of biological interest: inositol, inositol 1-monophosphate, inositol 2- or 4-monophosphate, inositol 1,2-cyclic phosphate, inositol 1,4-bisphosphate, inositol 1,4,5-trisphosphate, glycerophosphoinositol, glycerophosphoinositol 4-monophosphate, and glycerophosphoinositol 4,5-bisphosphate. The method shows good resolution and sufficient recovery (70-80%) for each compound. By applying this method to human platelets prelabeled with [3H]inositol and stimulated with thrombin, we found an early increase of inositol 1,4-bisphosphate and inositol 1,4,5-trisphosphate. Accumulation of glycerophosphoinositol, inositol 1-monophosphate, and an inositol monophosphate which cochromatographs with inositol 2- and inositol 4-monophosphate occurs later. The method is simple, and--after removal of salts from the incubation buffer--can be directly applied to the measurement of aqueous soluble [3H]inositol-labeled compounds in biological samples.     

The separation of [32P]inositol phosphates by ion-pair chromatography: optimization of the method and biological applications

We have developed an ion-pair reverse-phase HPLC method to measure inositol phosphates in 32P-labeled cells. The different chromatographic parameters were analyzed to optimize the resolution of the 32P-labeled metabolites. Analysis of inositol phosphates in biological samples was improved by a single charcoal pretreatment which eliminated interfering nucleotides without removing inositol phosphates. The kinetics of production of inositol phosphates in calcium-activated erythrocytes, vasopressin-stimulated hepatocytes, and thrombin-activated platelets were analyzed. Original data on the activation of phosphoinositide phospholipase C were obtained in intact erythrocytes by direct measurement of inositol (1,4,5)P3. Data from agonist-stimulated hepatocytes and platelets were consistent with those from previous studies. In conclusion, this technique offers many advantages over the methodologies currently employed involving anion-exchange chromatography and [3H]inositol labeling: (i) 32P labeling is less expensive and more efficient than 3H labeling and can be used with all types of cells without permeabilization treatments and (ii) ion-pair HPLC gives good resolution of inositol phosphates from nucleotides with shorter retention times, and long reequilibration periods are not required.     

A sensitive method for the quantification of the mass of inositol phosphates using gas chromatography-mass spectrometry

A sensitive method to directly measure the mass of inositol phosphates from biologic samples is described. The procedure uses ammonium sulfate gradient elution anion exchange column chromatography to isolate inositol monophosphate, bisphosphate, trisphosphate, and tetrakisphosphate. The isolated fractions are dephosphorylated and subsequently desalted by a novel approach using solid barium hydroxide in a 1:1 stoichiometric ratio to the amount of ammonium sulfate present in the dephosphorylated sample. The myo-inositol derived from each inositol phosphate species was quantified by stable isotope dilution gas chromatography-mass spectrometry of the hexakis(trimethylsilyl) derivative using hexadeutero-myo-inositol as the internal standard. The applicability and sensitivity of this method are illustrated by measuring the mass of individual inositol phosphates in isolated adult canine cardiac myocytes.     

High-performance liquid chromatography method for the quantification of rabeprazole in human plasma using solid-phase extraction

A simple, sensitive and selective HPLC method with UV detection (284 nm) was developed and validated for quantitation of rabeprazole in human plasma, the newest addition to the group of proton-pump inhibitors. Following solid-phase extraction using Waters Oasistrade mark SPE cartridges, the analyte and internal standard (Pantoprazole) were separated using an isocratic mobile phase of 5 mM ammonium acetate buffer (pH adjusted to 7.4 with sodium hydroxide solution)/acetonitrile/methanol (45/20/35, v/v) on reverse phase Waters symmetry C(18) column. The lower limit of quantitation was 20 ng/mL, with a relative standard deviation of less than 8%. A linear range of 20-1000 ng/mL was established. This HPLC method was validated with between- and within-batch precision of 2.4-7.2% and 2.2-7.3%, respectively. The between- and within-batch bias was -1.7 to 2.6% and -2.6 to 2.1%, respectively. Frequently coadministered drugs did not interfere with the described methodology. Stability of rabeprazole in plasma was excellent, with no evidence of degradation during sample processing (autosampler) and 3 months storage in a freezer. This validated method is sensitive, simple and repeatable enough to be used in pharmacokinetic studies.     

The separation of myo-inositol phosphates by ion-pair chromatography

The separation of myo-inositol phosphates by ion pair, reverse-phase high performance liquid chromatography has been investigated. The retention of the inositol phosphates is dependent on both the polarity of the hetaeron utilized and on the pH of the solvent. A method is presented which permits the isocratic separation of multiple forms of inositol phosphates including isomers of myo-inositol trisphosphate. This method appears to be superior to the anion exchange based systems currently employed because of smaller retention volumes, the low ionic strength of the solvent employed, the absence of a requirement for reequilibration, and the ability to perform separations isocratically.     

High-performance liquid chromatography separation of nikkomycins X and Z

A reversed-phase, C-18 HPLC method for separation, with baseline resolution, of the chitin synthase inhibitors nikkomycin X and Z is described. This permits, for the first time, satisfactory identification of nikkomycin X and Z contained in a mixture. The use of 30 mM ammonium formate (pH 4.7) containing the ion-pair agent heptanesulfonic acid (1 mM) was critical for the successful separation of these fungicides.     

High-performance immobilized metal ion affinity chromatography of peptides: analytical separation of biologically active synthetic peptides

The separation of more than 30 biologically active synthetic peptides and their analogs on a high-performance immobilized metal ion affinity chromatography column is described. The metal chelating gel (TSK gel chelate-5PW) contains iminodiacetic acid (IDA) covalently coupled to a hydrophilic, resin-based matrix with a bead diameter of 10 micron. The retention of the peptides on Cu(II), Ni(II), and Zn(II) ions immobilized on the chelating gel showed that some of them can be separated by isocratic elution while the majority of them are retained and are separated into distinct fractions by elution with a linear imidazole gradient or with a continuously decreasing pH gradient. Of the three immobilized metal ions investigated here, the IDA-Cu(II) chelate column gave the best resolution irrespective of the type of gradient used. This is amply illustrated by the resolution of angiotensins I and II and their seven synthetic analogs. The results obtained here serve as guidelines for the future exploitation of this separation method for the efficient fractionation of a wide variety of peptides on an analytical or preparative scale.     

Methods for the analysis of inositol phosphates

Interest in the inositol phospholipids was stimulated by the simultaneous discoveries that the products of hydrolysis of these lipids could serve as messengers to activate to synergistic signaling pathways in hormonally responsive cells, namely, inositol 1,4,5-trisphosphate which causes the release of Ca2+ from intracellular stores and diacylglycerol which promotes the activation of protein kinase C. At the same time, Berridge and co-workers introduced relatively simple approaches to study the inositol phospholipid cycle. These included the use of [3H]inositol to label the inositol metabolites, all of which are confined to this cycle, and of Li+ to decrease the rate of degradation of the inositol phosphates. Water-soluble inositol phosphates and chloroform-soluble inositol phospholipids could then be separated by solvent partition and the inositol phosphates further separated by use of an anion-exchange resin. However, the subsequent application of high-performance liquid chromatography as a separation technique indicated the existence of many isomers of the inositol phosphates formed by different pathways of dephosphorylation and phosphorylation. Mapping of these metabolic pathways may be substantially complete, but novel pathways may still be discovered. We review both old and new methods of analysis of the inositol phosphates for the measurement of mass and radioactivity. Although the complexity of the cycle sometimes demands the use of sophisticated methods of separation and rigorous identification, older and inexpensive methods may still be useful for some purposes.     

Metabolism and functions of inositol phosphates

Activation of Ca2+-mobilizing receptors rapidly increases the cytoplasmic Ca2+ concentration both by releasing Ca2+ stored in endoplasmic reticulum and by stimulating Ca2+ entry into the cells. The mechanism by which Ca2+ release occurs has recently been elucidated. Receptor activation of phospholipase C results in the hydrolysis of the plasma membrane lipid, phosphatidylinositol 4,5-bisphosphate (PIP2), to yield two intracellular messengers, diacylglycerol (DAG) and (1,4,5)inositol trisphosphate [(1,4,5)IP3]. DAG remains in the plasma membrane where it stimulates protein phosphorylation via the phospholipid-dependent protein kinase C. (1,4,5)IP3 diffuses to and interacts with specific sites on the endoplasmic reticulum to release stored Ca2+. Receptor stimulation of phospholipase C appears to be mediated by one or more guanine nucleotide-dependent regulatory proteins by a mechanism analogous to hormonal activation of adenylyl cyclase. The actions of (1,4,5)IP3 on Ca2+ mobilization are terminated by two metabolic pathways, sequential dephosphorylation to inositol bisphosphate (IP2), inositol monophosphate (IP) and inositol or by phosphorylation to inositol tetrakisphosphate (IP4) and sequential dephosphorylation to different inositol phosphates. A sustained cellular response also requires Ca2+ entry into the cell from the extracellular space. The mechanism by which hormones increase Ca2+ entry is not known; a recent proposal involving movement of Ca2+ through the endoplasmic reticulum, possibly regulated by IP4, will be considered here.