Separation of phosphomolybdate by affinity chromatography

A new method of separating phosphomolybdate from phosphoric esters and anhydrides using a small column of polyvinylpolypyrrolidone is introduced. When a mixture of phosphate compounds and ammonium molybdate (1–3%, pH 3-5) is poured onto such a column, inorganic orthophosphate (Pi)^p1 is selectively adsorbed onto the column material as phosphomolybdate, while other phosphate compounds, which do not react with molybdate, are drained through the column. Using radioisotopes, retention and recovery percentages were measured. At pH 3, 99.99% of Pi^p32 was retained in the column, while 97 ± 1% of ATP^p32 was recovered in the effluent. Retained Pi^p32 was eluted out later with 0.5 M ammonium hydroxide with a recovery percentage of 98 ± 1%. Unlike other methods of separating phosphomolybdate, the separation was little affected by the presence of reducing agents. The use of disposable columns, which can be prepared easily, packed ahead of time, and stored for later use, makes the radioisotopes assay convenient and contamination-free.     

Determination of binding constants by affinity chromatography

This review summarizes developments in the use of affinity chromatography to characterize biospecific interactions in terms of reaction stoichiometry and equilibrium constant. In that regard, the biospecificity incorporated into the design of the experiment ensures applicability of the method regardless of the sizes of the reacting solutes. By the adoption of different experimental strategies (column chromatography, simple partition equilibrium, solid-phase immunoassay and biosensor technology protocols) quantitatiative affinity chromatography can be used to characterize interactions governed by an extremely broad range of binding affinities. In addition, the link between ligand-binding studies and quantitative affinity chromatography is illustrated by means of partition equilibrium studies of glycolytic enzyme interactions with muscle myofibrils, an exercise which emphasizes that the same theoretical expressions apply to naturally occurring examples of affinity chromatography in the cellular environment.     

Determination of glycosylated hemoglobin by affinity chromatography

Conclusions The described new affinity chromatography method for the determination of glycosylated hemoglobins is rapid, specific and precise and has several advantages over other methods. It is relatively insensitive to changes in temperature and pH and appears to be free of interferences by labile Glyc-Hb. The results are independent over a wide range of hemolysate concentrations. The method offers good stabilities of specimen, buffers and columns. The possibility of a 10-fold reuse and a simple sample preparation by whole blood hemolysis without washing or incubation of erythrocytes make this method technically less complicated and more suited for routine use in a clinical laboratory.Correlation studies between affinity method and ion-exchange method show that as the level of glycosylation increases the affinity method gives progressively higher values (factor 1.3–1.4 in the pathological range). These results indicate that the affinity method measures not only the-terminal modified Hb molecules but all glycosylated hemoglobins, thus giving a better discrimination between normoglycemic and diabetic samples.

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Bestimmung von glykosyliertem Hämoglobin durch Affinitäts-Chromatographie

     

Principles of multienzyme purifications by affinity chromatography

Recently in our laboratory, up to 20 different enzymes and their genetic variants have been purified from mouse andDrosophila by affinity chromatography. By virtue of the specific coenzyme requirements, up to ten different enzymes could be copurified from a single tissue extract either by biospecific elutions with different coenzymes or inhibitors, or by sequential passages of the extract through several cofactor-related affinity columns. Important principles were developed to purify enzymes exhibiting low affinity to the affinity columns. By “affinity filtration” of the extract through the affinity column, enzymes of low affinity can be retarded and separated effectively from strongly bound and nonadsorbed proteins. By the “saturation readsorption” procedure, enzymes of low affinity could be effectively separated from those of high affinity by overloading of the extracts on the affinity columns. Readsorption of the leaked low affinity enzymes to a second affinity column often results in better enzyme purification because of the elimination of competitive high affinity enzymes. With the application of these principles, the following enzymes and their genetic variants were highly purified via a single- or two-step affinity column procedure: lactate dehydrogenase-A, lactate dehydrogenase-B, lactate dehydrogenase-X, phosphoglycerate kinase-A, phosphoglycerate kinase-B, cytoplasmic and mitochondrial isocitrate dehydrogenase, malate dehydrogenase, malic enzyme, glucose-6-phosphate dehydrogenase, glutathione reductase, phosphoglucose isomerase and pyruvate kinase from mouse tissues; alcohol dehydrogenase, malate dehydrogenase, α-glycerol-phosphate dehydrogenase, malic enzyme, and glucose-6-phosphate dehydrogenase fromDrosophila.     

Polymeric supports for affinity chromatography and high-performance affinity chromatography

Affinity chromatography is the most selective chromatographic method for the purification of biologically active materials. It is based on the biospecific interaction of the substrates with a ligand, which is chemically immobilized onto a suitable matrix (support). Different matrices provided by natural and synthetic polymers are used for the preparation of affinity supports. In this communication we describe and compare the properties of various supports based on polysaccharides, polyacrylamides and inorganic materials. In particular, we discuss the utility of different silica derivatives (especially primary hydroxyl silica) for the immobilization of ligands and high-performance affinity chromatography.     

High-performance affinity chromatography

High-performance affinity chromatography is a new technique for the fast and efficient purification of biologically active molecules. It combines the biospecificity of affinity chromatography with the high speed and resolution obtained in high-performance liquid chromatography. In particular, the immobilization of ligands to different silica derivatives and their suitability for high-performance affinity chromatography are discussed.     

Isolation of an urate-binding protein by affinity chromatography

This paper describes an affinity chromatography procedure to purify an urate binding protein from human serum. The specific ligand was 8-amino-2,6-dihydroxypurine bound to Sepharose through the amino group. The specific elution was obtained with an uric acid or allopurinol solution. Electrophoretic analysis of the eluted protein shows a single sharp band with an α₂-globulin mobility. Molecular weight, determined by gel filtration, is approximately 70,000 daltons.     

Facile purification of rare cucurbiturils by affinity chromatography

A practical method for the separation and purification of cucurbituril (CB) hexamers was developed on the basis of affinity chromatography using aminopentylaminomethylated polystyrene beads. This recyclable resin, which can be used repeatedly, facilitates the general preparation of cucurbituril derivatives and compensates for the usually moderate yields and mixed products that characterize the acid-catalyzed synthesis of CB derivatives. This technique allows convenient, rapid isolation of rare substituted cucurbiturils, including hexacyclohexanocucurbit[6]uril and dodecamethylcucurbit[6]uril. [reaction: see text]     

Purification of neutral protease by dye affinity chromatography

Twenty triazinic dyes were assayed as ligands for the chromatographic affinity purification of a neutral protease from Flavourzyme^™, a commercial preparation. Screening at pH 4.0 allowed the selection of eight dyes on the basis of their high protease adsorption. When the pH was set to 5.0 in order to increase selectivity, only Yellow HE-4R, Red HE-3B, and Cibacron Blue F3G-A maintained protease adsorption at high values. Neither maximum capacities nor dissociation constants calculated from isotherms measured at 8 and 25°C showed great differences. By contrast, a strong temperature effect was evidenced in the elution step: elution at 8°C allowed 70, 81, and 98% recovery of adsorbed protease with Yellow HE-4R, Red HE-3B, and Cibacron Blue F3G-A, respectively, whereas only 20% recovery was attained at 25°C. Based on the results obtained, a purification process for the neutral protease contained in Flavourzyme with Cibacron Blue F3G-A as the affinity ligand was developed, yielding 96% of electrophoretically pure enzyme in a single step, the specific activity rising from 850 to 3650 U/mg.     

Affinity purification of plasminogen by radial-flow affinity chromatography

A method for the purification of plasminogen using immobilized L-lysine on a membrane, the whole system being constructed in a radial flow cartridge, is described. Human plasma was applied to the cartridge at 20 ml/min. The results showed that under the chromatographic conditions chosen, in a single pass, greater than 85% recovery of plasminogen was attained with a 110-fold increase in specific activity.     

Immobilized metal ion affinity chromatography of synthetic peptides. Binding via the alpha-amino group.

Peptides synthesized by the solid-phase method can be efficiently purified in a single immobilized metal affinity chromatography step based on interaction with the alpha-amino group if, after coupling of each amino acid residue, unreacted amino groups are irreversibly blocked by acetylation and if no strongly metal-binding amino acids (His, Trp, Cys) are present in the sequence. A difference in basicity for alpha- and epsilon-amino functions of ca. 2 pH units is sufficiently large to allow selective binding of peptides to immobilized metal ions via the unprotonated alpha-amino group. The binding is pH-dependent: on Cu(2+)- and Ni(2+)-loaded supports most peptides are maximally retarded at pH values around 7.5 and 8.5, respectively. The decreased binding strength at lower pH values is due to protonation of the alpha-amino function, whereas the reduced affinity at higher pH is caused by metal ion transfer from the matrix to the peptide. The metal ion is captured in a multidentate chelate where, in addition to the alpha-amino group, up to three adjacent deprotonated amide nitrogens are coordinated to the metal. If the pH is raised further, additional metal ions may be bound in biuret-like structures. Immobilized Ni2+, owing to its higher selectivity and affinity, is the preferred chromatographic support if slightly basic conditions can be tolerated.     

Preparation of monospecific anti-Salmonelia lipopolysaccharide antibodies by affinity chromatography

The use of immunoadsorbent obtained by coupling aminohexylsepharose 4B with Salmonella lipopolysaccharide (LPS) by means of benzoquinone enabled us to obtain anti-O monospecific immune sera which can be used for a quick serological identification of some species of Salmonella in the course of a diagnosis. In this paper we describe a method for binding the LPS extracted from S. typhi-murium with aminohexyl-sepharose 4B, insoluble matrix as well as the preparation of monospecific anti-O5 antibodies from plurispecific anti-S. haifa rabbit immune sera. This separation of anti-O monospecific antibodies by affinity chromatography, avoids the repeated and often tedious adsorption of anti-Salmonella immune sera by the whole corresponding bacteria. Such immuno-adsorbents can be used several times without appreciable loss of their affinity properties.     

Separation of chitosan oligomers by immobilized metal affinity chromatography

A novel approach for chitosan oligosaccharide (COS) separation by immobilized metal affinity chromatography (IMAC) based on the differences in the interactions of chelated copper (II) ions with various COS (dimers, trimers, tetramers) is described. Polyhydroxylic chromatographic supports (agarose CL-6B and silica) were functionalized with various chelating functions such as iminodiacetate (IDA), carboxymethyl-aspartate (CM-Asp) and tris(carboxymethyl)ethylenediamine (TED). The COS retention capacities of the columns were between 2 and 6 mg/cm(3), depending on the chelating group. The COS were separated and/or enriched up to 95% for dimer and trimer and 90% for the tetramer, with yields of 60-95%.     

Efficacy of glycoprotein enrichment by microscale lectin affinity chromatography

Reproducible and efficient affinity enrichment is increasingly viewed as an essential step in many investigations leading to the discovery of new biomarkers. In this work, we have evaluated the repeatability of lectin enrichment of glycoproteins from human blood serum through both qualitative and quantitative proteomic approaches. In a comprehensive evaluation of lectin binding, we have performed 30 separate microscale lectin affinity chromatography experiments, followed by a conventional sample purification, and LC-MS/MS analysis of the enriched glycoproteins. Two lectin affinity matrixes, both with Con A lectin, immobilized to the same solid support but differing in the amount of immobilized lectin, were investigated to characterize their binding properties. Both qualitative and quantitative data indicate acceptable repeatability and binding efficiency for the lectin materials received from two different commercial sources.     

An easy purification of glycoluril clips by affinity chromatography

A convenient method for separation and purification of glycoluril clips was developed on the basis of affinity chromatography using a resorcinol-functionalized Merrifield resin. The modified resin was readily prepared via immobilization of phlroglucinol on Merrifield resin. It was used for successful isolation of the desired clip products from their corresponding reaction mixtures. Also, the resin could be repeatedly recycled and reused without any noticeable decrease in its effectiveness.