Extraction of steroidal glucosiduronic acids from aqueous solutions by anionic liquid ion-exchangers

A pilot study on the extraction of three steroidal glucosiduronic acids from water into organic solutions of liquid ion-exchangers is reported. A single extraction of a 0.5mm aqueous solution of either 11-deoxycorticosterone 21-glucosiduronic acid or cortisone 21-glucosiduronic acid with 0.1m-tetraheptylammonium chloride in chloroform took more than 99% of the conjugate into the organic phase; under the same conditions, the very polar conjugate, beta-cortol 3-glucosiduronic acid, was extracted to the extent of 43%. The presence of a small amount of chloride, acetate, or sulphate ion in the aqueous phase inhibited extraction, but making the aqueous phase 4.0m with ammonium sulphate promoted extraction strongly. An increase in the concentration of ion-exchanger in the organic phase also promoted extraction. The amount of cortisone 21-glucosiduronic acid extracted by tetraheptylammonium chloride over the pH range of 3.9 to 10.7 was essentially constant. Chloroform solutions of a tertiary, a secondary, or a primary amine hydrochloride also will extract cortisone 21-glucosiduronic acid from water. The various liquid ion exchangers will extract steroidal glucosiduronic acid methyl esters from water into chloroform, although less completely than the corresponding free acids. The extraction of the glucosiduronic acids from water by tetraheptylammonium chloride occurs by an ion-exchange process; extraction of the esters does not involve ion exchange.     

Synthesis of mono- and diglucosiduronates of metabolites of deoxycorticosterone and corticosterone and analysis by a new mass spectrometric technique

By condensing 3 alpha,21-dihydroxy-5 beta-pregnan-20-one, or its appropriate monoacetate, with methyl 2,3,4-tri-O-acetyl-1-bromo-1-deoxy-alpha-D-glucuronate in the Koenigs-Knorr reaction beta-D-glucosiduronates 10, 4, and 7 were obtained as polyacetate methyl esters. Alkaline hydrolysis of these substances cleaved the ester groups and gave the corresponding steroidal glucosiduronic acids 12, 6 and 8. Upon treatment with diazomethane, these acids produced the equivalent methyl esters. The C-3, the C-21 and the C-3,21 glucosiduronates of 3 alpha,21-dihydroxy-5 beta-pregnan-11,20-dione were prepared by previously reported methods and converted into the corresponding C-20 semicarbazones (14, 20 and 26). With C-20 stabilized by the semicarbazone group against reduction, it was possible to reduce the 11-oxo function in these substances to an 11 beta-hydroxyl group; after removal of the semi-carbazone moiety from these products at pH 2.0, glucosiduronic acids 18, 22 and 28 were obtained. The mass spectra of a representative group of the mono- and diglucosiduronic acids and esters were determined by utilizing fast atom bombardment and monitoring ions in both positive and negative modes of operation.     

Partition of fatty acids

The partition ratios of radioactive fatty acids between n-heptane and a physiological buffer at 37 degrees C were measured. The fatty acids included the saturated acids with an even number of carbons from 10 to 18 and the unsaturated acids oleic, linoleic, and linolenic. In addition, the partition ratios of decanoate, myristate, and palmitate were determined over a wide pH range. Any single plot of partition ratio vs. aqueous concentration of an acid gave a nearly straight line, a finding consistent with very little association in the aqueous phase. In the case of the acids with 16 and 18 carbon atoms, however, comparison of the constants calculated from these plots with the assumption of no aqueous phase association revealed several inconsistencies. These inconsistencies cannot be resolved completely by assuming the existence of fatty acid association in the aqueous solution. We believe that at least some of the deviations are due to the presence of trace quantities of radioactive impurities in the labeled fatty acids. For example, purification of a sample of supposedly pure [1-(14)C]myristate by a series of solvent extractions increased the partition ratio by a factor of 1.5. Although all of the observations cannot be explained by this interpretation, we believe that our studies suggest that there is no appreciable association of fatty acids under the usual physiological conditions.     

Simultaneous and rapid isolation of bacterial and eukaryotic DNA and RNA: a new approach for isolating DNA.

A very simple procedure for the simultaneous preparation of genomic DNA and total RNA is described. The procedure is essentially the same for eukaryotes and prokaryotes except for the lysis buffer and can be used for small or large numbers of cells. Mammalian cells are lysed in sodium dodecyl sulfate and bacterial cells are lysed in Triton X-100, both in the presence of EDTA. RNA is obtained in the aqueous phase after phenol (acidic pH):chloroform:isoamyl alcohol extraction. DNA is eluted out of the organic phase (and the interface) into the aqueous phase by increasing the pH with highly basic 1 M Tris solution. The method is extremely rapid for small or large numbers of cells, and several large samples can be processed in one day. The qualities of both nucleic acids are excellent and the yield is high.     

Ion-pairing separation of bioactive peptides using an aqueous/octan-1-ol micro-extraction system from bovine haemoglobin complex hydrolysates

The ion-pair concept was applied on complex haemoglobin hydrolysates to extract two opioid peptides, LVV-haemorphin-7 and VV-haemorphin-7, in an aqueous/octan-1-ol micro-extraction system in the presence of alkyl-sulfonic acid as a surfactant agent and in relation to the haemorphin physico-chemical properties (charge, hydrophobicity). The effect of combined alkyl chain length/aqueous phase pH and the haem behaviour during the extraction, on the haemorphin recovery yield and enrichment has been determined. It has proved that transport over the organic phase is mediated by the alkyl-sulfonic acids, whatever be the aqueous phase pH. However, increasing both the alkyl chain length and the pH in the aqueous phase shows an haemorphin enrichment ratio increase but a recovery decrease of the extracted opioid peptides in the organic phase. Therefore, the best conditions to extract LVVh-7 and VVh-7 are the use of the octane-sulfonic acid at aqueous phase pH of 5 or 7 and the octane or the heptane-sulfonic acid with an aqueous phase pH of 5 or 7 respectively. In these conditions, a partition coefficient of 1.64 and 1.60 respectively for LVVh-7 and VVh-7 are obtained and represent about 40 times that acquired without agent.     

New reactive extraction systems for separation of bio-succinic acid

Biotechnologically produced succinic acid has the potential to displace maleic acid and its uses and to become an important feedstock for the chemical industry. In addition to optimized production strains and fermentation processes, an efficient separation of succinic acid from the aqueous fermentation broth is indispensable to compete with the current petrochemical production processes. In this context, high molecular weight amines are known to be effective extractants for organic acids. For this reason, as a first step of isolation and purification, the reactive extraction of succinic acid was studied by mixing aqueous succinic acid solutions with 448 different amine–solvent mixtures as extraction agents (mixer-settler studies). The extraction agents consist either of one amine and one solvent (208 reactive extraction systems) or two amines and two solvents (240 reactive extraction systems). Maximum extraction yields of succinic acid from an aqueous solution with 423 mM succinic acid at pH 2.0 were obtained with more than 95% yield with trihexylamine solved in 1-octanol or with dihexylamine and diisooctylamine solved in 1-octanol and 1-hexanol. Applying these optimized reactive extraction systems with Escherichia coli fermentation broth resulted in extraction yields of 78–85% due to the increased ionic strength of the fermentation supernatant and the co-extraction of other organic acids (e.g., lactic acid and acetic acid), which represent typical fermentation byproducts.     

Protein partitioning in weakly charged polymer-surfactant aqueous two-phase systems

The study includes partitioning of proteins in aqueous two-phase systems consisting of the polymer dextran and the non-ionic surfactant C₁₂E₅ (pentaethylene glycol mono-n-dodecyl ether). In this system a micelle-enriched phase is in equilibrium with a polymer-enriched phase. Charges can be introduced into the micelles by the addition of charged surfactants. The charge of the mixed micelles is easily varied in sign and magnitude independently of pH, by the addition of different amounts of negatively charged surfactant, sodium dodecyl sulphate (SDS), or positively charged surfactant dodecyl trimethyl ammonium chloride (DoTAC). A series of water-soluble model proteins (BSA, β-lactoglobulin, myoglobin, cytochrome c and lysozyme), with different net charges at pH 7.1, have been partitioned in non-charged systems and in systems with charged mixed micelles or charged polymer (dextran sulphate). It is shown that partition coefficients for charged proteins in dextran-C₁₂E₅ systems can be strongly affected by addition of charged surfactants (SDS, DoTAC) or polymer (dextran sulphate) and that the effects are directly correlated to protein net charge.     

Analysis of Biogenic Amines in Bovine Retina by Gas Chromatography-Negative Ion Chemical Ionisation Mass Spectrometry

Biogenic amines in bovine retina have been identified and quantified by an extraction-derivatisation procedure involving their reaction with 3,5-di(trifluoromethyl)benzoyl chloride (DTFMBCl) in the aqueous phase followed by extraction into an organic solvent, hydrolysis of phenolic esters, and conversion of free hydroxyl groups to trimethylsilyl ethers. Subsequent analysis of these DTFMB-trimethylsilyl derivatives by gas chromatography-negative ion chemical ionisation mass spectrometry revealed that the molecular ion carried most (greater than 60%) of the ion current, which made the method highly specific and gave a potential limit of detection below the picogram level. This method establishes unequivocally that the principal amines in bovine retina are p-tyramine, dopamine, and 5-hydroxytryptamine.     

The indirect analysis of 17-oxosteroid glucosiduronates and sulphates in human urine

1. An analytical procedure has been developed for the determination of urinary 17-oxosteroid sulphates and 11-deoxy-17-oxosteroid glucosiduronates. 2. By submitting urine to the following operations: (a) extraction of the 17-oxosteroid conjugates into chloroform (in the presence of pyridinium sulphate), (b) solvolysis (in the absence of acid) of the steroid sulphates, (c) separation of the steroid glucosiduronates, (d) hydrolysis of the glucosiduronates, (e) oxidation with tert.-butyl chromate of the liberated steroids and (f) analysis of the final extracts by gas-liquid chromatography, the 17-oxosteroid conjugates are converted into and measured as androstanediones and androstane-(ene)triones. 3. Values for the daily excretion of 17-oxosteroid glucosiduronates and sulphates in normal men and women are given.     

Three phase partitioning as a novel method for purification of ragi (Eleusine coracana) bifunctional amylase/protease inhibitor

The technique of three-phase partitioning (TPP) was used to purify a bifunctional amylase/protease inhibitor from ragi (Eleusine coracana). This process of purification is a potential method used for separation of proteins directly from large volumes of crude suspension. It involves the addition of a salt (ammonium sulphate) to the crude extract followed by the addition of an organic solvent (t-butanol). The addition of t-butanol, in the presence of ammonium sulphate pushes the protein out of the solution to form an interfacial precipitate layer between the lower aqueous and upper organic layers. The process was carried out in two steps. The various conditions required for attaining efficient purification of the protein fractions were optimized. It was seen that 30% ammonium sulphate saturation with 1:1 ratio of crude extract to tert-butanol gave 8.9- and 8.65-fold purification with 83% and 80% yield of amylase inhibitor and trypsin inhibitor, respectively, in step I. In TPP-step II, 60% ammonium sulphate saturation and ratio of aqueous phase to t-butanol of 1:2 gave maximum 20.1- and 16-fold purification with 39.5% and 32% yield of amylase inhibitor and trypsin inhibitor, respectively. The sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis of the inhibitor protein showed substantial purification and the molecular weight of the protein was found to be 14 kDa.     

Arginine increases the solubility of alkyl gallates through interaction with the aromatic ring

We have recently proposed the application of solubilizing effects of arginine to poorly soluble aromatic compounds for drug discovery research. In this study, we compared the solubilizing effects of arginine with those of other amino acids, salts and a surfactant using alkyl gallates as model drug substances of low aqueous solubility. The solubilizing effects of arginine on the alkyl gallates were distinct compared with those of other amino acids and salts; the effects were even greater than those achieved using a strongly chaotropic guanidinium ion. Transfer free energy of the alkyl gallates from water to arginine solution depended weakly on their dissolution free energy in water, which is in contrast to sodium dodecyl sulphate that showed strong dependence. The present results suggest that arginine solubilizes alkyl gallates through interaction with the aromatic moiety and sodium dodecyl sulphate does so by interacting with alkyl groups.     

Purification of alkaline phosphatase from chicken intestine by three-phase partitioning and use of phenyl-Sepharose 6B in the batch mode

Alkaline phosphatase from chicken intestine was purified from the crude preparation employing three-phase partitioning and by the use of phenyl Sepharose-6B in the batch mode. TPP uses a combination of ammonium sulphate and t-butanol to precipitate proteins from crude aqueous extracts. The precipitated protein forms interface between lower aqueous phase and upper organic solvent phase. The fold purification of the finally purified enzyme was 80 and the activity recovery was 61%. The sodium dodecyl sulphate-polyacrylamide gel electrophoresis analysis of enzyme showed considerable purification and its molecular weight was found to be around 67 kDa.     

Complexing of heparin with phosphatidylcholine. A possible supramolecular assembly of plasma heparin.

In a series of attempts to reveal plasma heparin, we found that high ionic strength and modification of protein amino groups were not effective in extracting endogenous heparin (or, indeed, a large percentage of exogenous labelled heparin), whereas delipidation in the presence of 4M-guanidinium chloride gave high yields, indicating that plasma heparin may be assembled with compounds other than proteins, in a form making it inaccessible to water and ions. During the extraction of lipids, a paradoxical entry of heparin into the organic phase was observed. Detergents, including sodium dodecyl sulphate, did not shift heparin into the aqueous phase, whereas repeated chloroform/methanol extraction did so. Using purified compounds we were able to reproduce in vitro both the scavenging of heparin from water as well as the formation of heparin-phosphatidylcholine complexes soluble in organic solvents. Evidence for complexing of heparin with phosphatidylcholine was also obtained by electrophoretic and ultracentrifugation assays. The quaternary-ammonium-containing phosphatidylcholine was the more effective phospholipid in binding heparin; anionic phospholipids did not bind. Only heparin-like glycosaminoglycans bound phosphatidylcholine, but less-sulphated compounds (heparan sulphate and dermatan sulphate) were weaker ligands. Gel-filtration experiments showed that heparin was not bound to liposome vesicles, but that a measurable percentage of the phospholipids was stripped off from vesicles and was found in the form of a complex separable from liposomes by gel filtration. The molecular basis as well as the biological role of the interaction of heparin with major membrane phospholipids are discussed.     

Investigation of the separation of heterocyclic aromatic amines by reversed phase ion-pair liquid chromatography coupled with tandem mass spectrometry: the role of ion pair reagents on LC-MS/MS sensitivity

Reversed phase ion-pair chromatography (RP-IPC) of seven heterocyclic aromatic amines encompassing quinoline (IQ, MeIQ), quinoxaline (MeIQx), pyridine (PhIP) and carboline derivatives (AalphaC, Harman, Norharman) was carried out with formate as counter ion in an aqueous eluent with acetonitrile as organic modifier. TSKgel ODS-80TS was used as the stationary phase. With the aim of acquiring a better insight into the mutual influence of ion-pair reagent and the organic modifier upon solute retention, the study was performed by using an experimental design approach able to evidencing the effect of the simultaneous variation of the two factors. A model for the chromatographic behavior of the amines is proposed that includes classical ion-pair mechanism involving formate in the case of MeIQx, PhIP, Harman and Norharman. A competitive ion-exchange mechanism was hypothesized to govern retention of quinoline compounds, whereas electrostatic interactions and hydrogen bond formation with the silanols of the stationary phase were judged to be responsible for the retention of AalphaC. Further, the chromatographic behavior of the analytes using the formic acid-ammonium formate buffer in the mobile phase was compared with that observed using acetic acid-ammonium acetate buffer. The method based on the use of RP IPC with tandem mass spectrometry when the eluent contained formate buffer at pH 2.8 exhibited higher detectability with respect to that achieved using the acetate buffer.     

Enzyme activity in partly dissociated fragments of rat intestinal maltase/glucoamylase.

Pure rat intestinal maltase/glucoamylase was partially inactivated in 1% sodium dodecyl sulphage by heating at 40--70 degree C for 5 min at pH 7.5, or by lowering the pH to 5.4--6.6 at 24 degree C. When partially active preparations were electrophoresed in the presence of sodium dodecyl sulphate, a complicated protein band pattern of incompletely dissociated fragments of the enzyme was observed. Complete dissociation of the enzyme in sodium dodecyl sulphate, induced by boiling or by pH values below 5.4, was accompanied by total loss of enzyme activity and simplification of the protein pattern to five major species. Although the original enzyme band was absent from some partially dissociated preparations, enzyme activity was present and was associated with several transient protein bands on the gels. Maltase and alpha-glucosidase activities were detected in these bands, but glucoamylase activity was absent.     

tert.-Butyl aminocarbonate (tert.-butyloxycarbonyloxyamine)--a new acylating reagent for amines

tert.-Butyl amino carbonate (1, tert.-butyloxycarbonyloxyamine) was prepared by reaction of hydroxylamine with di-tert.-butyl dicarbonate (2). 1 was used to acylate different amino acids or amines in water or in aqueous dioxane. 1 was also prepared in situ and used to acylate amino acids directly. 1 reacted 1.5-2.5 times faster than 2 with all amines studied either in water or 50% (v/v) dioxane. Remarkably, 1 retained its ability to acylate amines even in acid solution; the rate of acylation of L-Phe at pH 6.5 (15 M-1 X min-1) was about 20% of the rate at pH 10 (72 M-1 X min-1). 2 was not an acylating reagent below pH 7.0 and as expected, the rate at pH 8.3 (4 M-1 X min-1) was about 10% of that at pH 9.3 (39 M-1 X min-1). Pure BOC-amino acids were obtained in high yield and could be quantitatively deprotected by standard procedures.     

Chromatographic mobilities and partition coefficients of synthetic corticosteroid glucosiduronates

Analytical data are presented on the free acids, the methyl esters, the methyl ester triacetates and the methyl ester triacetate semicarbazones of C-21 glucosiduronic acid conjugates of six adrenal hormones. Chromatographie mobilities of all of these compounds in three or more solvent systems are given. The stability of the steroidal glucosiduronic acids in alkali, their hydrolysis by β-glucuronidase and their partition coefficients in several solvent systems are also given.     

Effect of solid-state buffers on the catalytic activity of papain in low water media

The catalytic activity of papain in the synthesis of Z-Gly-Phe-NH₂ in tert-butanol has been studied in the presence of solid-state acid–base buffers (acids and their sodium salts). All buffer pairs tested reduced the reaction rate compared with the control, particularly the most acidic and basic (assessed by either aqueous pK_a or the response of an organic phase indicator). The highest rates, close to the control, were found with glutamic acid/glutamate-Na, PIPES/PIPES-Na and NaH₂PO₄/Na₂HPO₄. However, these pairs were unable to erase the pH memory phenomenon, or to overcome the effect of spiking with acetic acid. Hence, at least these buffers do not seem to be able to affect the protonation state and catalytic activity of papain. In the last aqueous solution before drying, the presence of activating agents (cysteine plus EDTA) was more important than buffer ions.     

Apolipoprotein E isoform-specific disruption of phosphoinositide hydrolysis: protection by estrogen and glutathione

The effect of non-esterified myristate (C14:0) or dodecyl sulfate was studied on passive swelling of rat liver mitochondria suspended in hypotonic alkaline KCl medium in the absence of the potassium ionophore valinomycin. Both compounds rapidly initiated large-amplitude swelling. However, they failed to initiate swelling when the mitochondria were suspended in hypotonic alkaline sucrose medium. In contrast to myristate or dodecyl sulfate, the non-ionic detergent Triton X-100 initiated swelling of mitochondria in both of the media. The following findings indicate that the inner mitochondrial membrane (IMM) is permeabilized by myristate to K+ and Cl- in a specific manner. (i) Swelling initiated by myristate did not respond to cyclosporin A, (ii) the protonophoric uncoupler FCCP was unable to mimic the myristate effect on swelling, and (iii) myristate-induced Cl- -permeation (measured with KCl medium plus valinomycin) was inhibited by N,N'-dicyclohexylcarbodiimide, quinine or ATP. Myristate- or dodecyl sulfate-initiated swelling was paralleled by the lowering of endogenous Mg2+ content. Both effects, stimulation of swelling and depletion of endogenous Mg2+ are correlated with each other. Similar effects have been reported previously for the carboxylic divalent cation ionophore calcimycin (A23187). The A23187-induced swelling has identical inhibiting characteristics on Cl- -permeation with respect to N,N'-dicyclohexylcarbodiimide, quinine and ATP as the myristate-stimulated swelling. Therefore, we conclude that non-esterified fatty acids increase the permeability of mitochondria to K+ and Cl- at alkaline pH by activating Mg2+-dependent ion-conducting pathways in IMM.     

Quantitative measurements on the acid taste and their bearing on the nature of the nerve receptor

Summary Quantitative determinations of the threshold concentrations for sourness of about 40 organic acids have been determined with an accuracy of about 6 per cent. Hydrogen ion concentrations have been obtained by use of the cell Hg/HgCl/KCl sat./organic acid/H₂. It is assumed that only undissociated acid molecules can cross the phase boundary between the aqueous solution and the nerve receptor, and that the stimulation of the sensation of sourness is due solely to hydrogen ion. All acids tasting equally sour should have the same pH within the nerve receptor. From the experimental data, relative concentration gradients for the nonionized acids have been calculated. It is shown that the addition of polar groups, such as OH, Cl, C=C, C=O, COOH, NH₂ to the organic acid make it from 20 to 500 times more difficult for the organic acid to penetrate into the nerve receptor. On the other hand, lengthening the carbon chain by addition of CH₂ groups makes penetration easier. The phenomena can be largely explained on the hypothesis that these organic acids are adsorbed into a tissue which is essentially like fat rather than like protein.