Purification of Arsenazo III,a Ca2+-sensitive dye

Commercial preparations of Arsenazo III. (o-(1,8 dihydroxy-3,6-disulfonaphthylene-2,7-bisazo)-bisbenzenearsonic acid), a dye useful for detection of micromolar concentrations of ionized Ca²⁺, have been found to be grossly and variably contaminated with colored impurities and Ca²⁺. In this paper, methods are described for detection of the colored impurities using DEAE-cellulose thinlayer chromatography in semiorganic solvents, along with methods for purification of the dye using DEAE-cellulose column chromatography and Chelex-100 ion-exchange resin. The impurities from one commercial lot are shown to exhibit significant absorbances over the range 400–725 nm; some of the impurities exhibit spectral shifts in the presence of Ca²⁺, implying Ca²⁺ binding. Thus, use of unpurified dye to quantitate ionized Ca²⁺ might yield data which vary with the source and batch of dye. The chromatographically pure Arsenazo III obtained from column chromatography is characterized with respect to Na⁺, Ca²⁺, and dye content.     

Selective antibody precipitation using polyelectrolytes: A novel approach to the purification of monoclonal antibodies

We evaluated the potential for polyelectrolyte induced precipitation of antibodies to replace traditional chromatography purification. We investigated the impact of solution pH, solution ionic strength and polyelectrolyte molecular weight on the degree of precipitation using the anionic polyelectrolytes polyvinylsulfonic acid (PVS), polyacrylic acid (PAA), and polystyrenesulfonic acid (PSS). As we approached the pI of the antibody, charge neutralization of the antibody reduced the antibody–polyelectrolyte interaction, reducing antibody precipitation. At a given pH, increasing solution ionic strength prevented the ionic interaction between the polyelectrolyte and the antibody, reducing antibody precipitation. With increasing pH of precipitation, there was an increase in impurity clearance. Increasing polyelectrolyte molecular weight allowed the precipitation to be performed under conditions of higher ionic strength. PVS was selected as the preferred polyelectrolyte based on step yield following resolubilization, purification performance, as well as the nature of the precipitate. We evaluated PVS precipitation as a replacement for the initial capture step, as well as an intermediate polishing step in the purification of a humanized monoclonal antibody. PVS precipitation separated the antibody from host cell impurities such as host cell proteins (HCP) and DNA, process impurities such as leached protein A, insulin and gentamicin, as well as antibody fragments and aggregates. PVS was subsequently removed from antibody pools to <1 µg/mg using anion exchange chromatography. PVS precipitation did not impact the biological activity of the resolubilized antibody. Biotechnol. Bioeng. 2009;102: 1141–1151. © 2008 Wiley Periodicals, Inc.     

Coenzyme binding capacity of yeast alcohol dehydrogenase.

Commercial lyophilized preparations of yeast alcohol dehydrogenase from Boehringer G.m.b.H. (Mannheim, Germany) bind 2 mols of reduced coenzyme/144000 g of enzyme (1). After the purification by a DEAE-Sephadex column chromatography, the coenzyme binding capacity is raised to 4 mols of NADH/mol of enzyme. Commercial preparations and ionexchange-purified preparations are homogeneous on the ionexchange column chromatography and the disc gel electrophoresis, after reduction with thioglycolic acid. Ionexchange chromatography does not increase the -SH titer, zinc content and the specific activity of enzyme. It is suggested that ionexchange chromatography raises the NADH-binding capacity by removing some impurities present in commercial enzyme preparations.     

The prevention of an anomalous chromatographic behavior and the resulting successful removal of viruses from monoclonal antibody with an asymmetric charge distribution by using a membrane adsorber in highly efficient,anion-exchange chromatography in flow-through mode

Anion exchange (AEX) chromatography in the flow-through mode is a widely employed purification process for removal of process/product-related impurities and exogenous/endogenous viruses from monoclonal antibodies (mAbs). The pH of the mobile phase for AEX chromatography is typically set at half a unit below the isoelectric point (pI) of each mAb (i.e., pI − 0.5) or lower and, in combination with a low ionic strength, these conditions are usually satisfactory for both the recovery of the mAb and removal of impurities. However, we have recently encountered a tight binding of mAb1 to AEX resins under these standard chromatographic conditions. This anomalous adsorption behavior appears to be an effect of the asymmetric charge distribution on the surface of the mAb1. We found that mAb1 did not bind to the AEX resins if the mobile phase has a much lower pH and higher ionic strength, but those conditions would not allow adequate virus removal. We predicted that the use of membrane adsorbers might provide effective mAb1 purification, since the supporting matrix has a network structure that would be less susceptible to interactions with the asymmetric charge distribution on the protein surface. We tested the Natriflo HD-Q AEX membrane adsorber under standard chromatographic conditions and found that mAb1 flowed through the membrane adsorber, resulting in successful separation from murine leukemia virus. This AEX membrane adsorber is expected to be useful for process development because mAbs can be purified under similar standard chromatographic conditions regardless of their charge distributions.     

Lipophilic impurities, not phenolsulfonphthalein, account for the estrogenic activity in commercial preparations of phenol red

Previously, we found that Phenol Red, a pH indicator dye commonly used in tissue culture media, had weak estrogenic activity, demonstrable by competitive binding to the estrogen receptor, stimulation of the growth rate of human breast cancer (MCF-7) cells, and elevation of progesterone receptor levels in these cells. We have now examined in more detail the source of this estrogenic activity, present in commercially available preparations of Phenol Red. By high performance liquid chromatography and solvent partitioning, we find that the receptor binding and growth promoting activity does not correspond to the indicator dye itself (phenolsulfonphthalein), but rather to more lipophilic impurities present in these preparations. There are numerous such impurities, many of which show some competitive binding activity, but the major receptor binding activity is accounted for by a single impurity component. Commercial preparations of Phenol Red can be purified by ether extraction of the sodium salt, whereby 95-99% of the lipophilic estrogenic impurities are removed, and the growth stimulating activity towards MCF-7 cells is reduced.     

Using precipitation by polyamines as an alternative to chromatographic separation in antibody purification processes

Polyamine precipitation conditions for removing host cell protein impurities from the cell culture fluid containing monoclonal antibody were studied. We examined the impact of polyamine concentration, size, structure, cell culture fluid pH and ionic strength. A 96-well microtiter plate based high throughput screening method was developed and used for evaluating different polyamines. Polyallylamine, polyvinylamine, branched polyethyleneimine and poly(dimethylamine-co-epichlorohydrin-ethylenediamine) were identified as efficient precipitants in removing host cell protein impurities. Leveraging from the screening results, we incorporated a polyamine precipitation step into a monoclonal antibody purification process to replace the Protein A chromatography step. The optimization of the overall purification process was performed by taking the mechanisms of both precipitation and chromatographic separation into account. The precipitation-containing process removed a similar amount of process-related impurities, including host cell proteins, DNA, insulin and gentamicin and maintained similar product quality in respect of size and charge variants to chromatography based purification. Overall recovery yield was comparable to the typical Protein A affinity chromatography based antibody purification process.     

Revealing binding sites for myeloperoxidase on the surface of human low density lipoproteins

Low density lipoproteins (LDL) of human blood, once oxidized, provoke cholesterol accumulation in cells of arterial wall, which favors the development of atherosclerosis. Oxidative modification of LDL can result from their interaction with hypochlorous acid produced in the halogenation cycle of myeloperoxidase (MPO). On account that MPO is able to form complexes with LDL it seems important to learn the forces promoting such contacts and to spot the likely binding sites for the enzyme on the surface of LDL particles. In this study affinity chromatography on MPO-Sepharose showed that MPO-LDL complexes are uncoupled at ionic strength above 0.3 M NaCl or when pH of solution goes below 3.6. This is an evidence of ionic interaction between MPO and LDL. We used spin probes of lipid nature embedded in phospholipid monolayer so that a variety of distances between the surface of an LDL particle and the paramagnetic center of a spin probes was provided. Since MPO interaction with labeled LDL caused no alteration of EPR spectra it was concluded that lipid components of LDL are not involved in MPO binding. Analysis of Mn²⁺ distribution between LDL surface and the aqueous milieu showed that the surface negative charge of LDL is not considerably changed upon interaction with MPO. It can be suggested that interaction of LDL with MPO does not involve phospholipids that are the principal carriers of the surface charge. Among synthetic oligopeptides with amino acid sequences mimicking those of apoB-100 fragments – ¹EEEMLEN⁷, ⁵³VELEVPQ⁵⁹ and ⁴⁴⁵EQIQDDCTGDED⁴⁵⁶ – only the latter could replace MPO in the complex with LDL. It is concluded that the likely site of interaction with MPO is the amino acid stretch 445–456 of apoB-100 in LDL.     

The interaction of insulin with phospholipids

1. A simple two-phase chloroform–aqueous buffer system was used to investigate the interaction of insulin with phospholipids and other amphipathic substances. 2. The distribution of ¹²⁵I-labelled insulin in this system was determined after incubation at 37°C. Phosphatidic acid, dicetylphosphoric acid and, to a lesser extent, phosphatidylcholine and cetyltrimethylammonium bromide solubilized ¹²⁵I-labelled insulin in the chloroform phase, indicating the formation of chloroform-soluble insulin–phospholipid or insulin–amphipath complexes. Phosphatidylethanolamine, sphingomyelin, cholesterol, stearylamine and Triton X-100 were without effect. 3. Formation of insulin–phospholipid complex was confirmed by paper chromatography. 4. The two-phase system was adapted to act as a simple functional system with which to investigate possible effects of insulin on the structural and functional properties of phospholipid micelles in chloroform, by using the distribution of [¹⁴C]glucose between the two phases as a monitor of phospholipid–insulin interactions. The ability of phospholipids to solubilize [¹⁴C]glucose in chloroform increased in the order phosphatidylcholine<sphingomyelin<phosphatidylethanolamine<phosphatidic acid. Insulin decreased the [¹⁴C]glucose solubilized by phosphatidylcholine, phosphatidylethanolamine and phosphatidic acid, but not by sphingomyelin. 5. The significance of these results and the molecular requirements for the formation of insulin–phospholipid complexes in chloroform are discussed.     

Improved two-step method for the assay of adenylate and guanylate cyclase.

A two-step assay for adenylate and guanylate cyclase is described utilizing α-³²P-labeled ATP or GTP as substrate and involving purification of the resulting ³²P-labeled cAMP or cGMP by sequential chromatography on Dowex 50 and alumina. The Dowex 50 chromatography is performed in acid, 50 mm HCl for cGMP and 10 mm HClO₄ for cAMP, and achieves complete separation from the radiochemical impurities in the substrate which are responsible for blank. The cAMP or cGMP peaks are collected directly onto alumina columns and, under acid conditions, are completely retained by the alumina. After washing the alumina with water, the ³²P-labeled cAMP or cGMP is eluted with 0.2 m imidazole buffer and counted. The method delivers blanks amounting to .0005% of the substrate radioactivity, high recoveries, and excellent reproducibility.     

Lovastatin reversed the enhanced sphingomyelin caused by 27-hydroxycholesterol in cultured vascular endothelial cells

Statins have pleiotropic properties which are involved in inhibiting the thrombogenic response. In this study, the effects of lovastatin on two phospholipids, phosphatidylcholine and sphingomyelin, were studied in cultured endothelial cells in the presence of an oxysterol, 27-hydroxycholesterol. After the cells were cultured with 50 nM of lovastatin for 60 h, lovastatin was found to decrease the incorporation of [³H]choline into phosphatidylcholine and sphingomyelin, inhibited CTP: phosphocholine cytidylyltransferase (CT) activity without altering the activity of sphingomyelin synthase and neutral sphingomyelinase. And lovastatin was not found to have a direct inhibitive effect on activity of CT. Exogenous mevalonic acid or cholesterol reversed the reduction of cholesterol concentration that was caused by lovastatin, but had no significant effect on the diminished [³H]sphingomyelin by lovastatin. The increase of [³H]sphingomyelin by 27-hydroxycholesterol was not detected in the presence of lovastatin. These findings suggest that (1) lovastatin can reduce sphingomyelin content by means of inhibiting phosphatidylcholine synthesis; and (2) The decrease in sphingomyelin is not related to the diminished cholesterol concentration or mevalonate-derived intermediates. This inhibitive effect of lovastatin on sphingomyelin may benefit cellular calcification caused by sphingomyelin.     

Physico-chemical characterization of proteins by capillary electrophoresis

The electrophoretic mobility of proteins was successfully determined by means of capillary electrophoresis (CE) with various background electrolytes (BGEs). The objective was focused on the variation in BGE physico-chemical composition and the consequential impact on the observed protein charge. Experimental and calculated mobilities, according to Henry's equation, versus ionic strength have been compared. For positively-charged lysozyme, a good agreement between observed and calculated mobilities was observed using triethanolamine chloride at pH 7.0 as the BGE. Mobility close to zero was shown using borate (pH 8.0) and phosphate (pH 7.0) at a low ionic strength of about 20 mmol l⁻¹, and as a consequence, specific adsorption of oxyanions was evidenced. Lysozyme retention in the case of reversed-phase high-performance liquid chromatography (RP-HPLC) was decreased by the presence of phosphate ions. CE and HPLC are complementary tools for characterizing the behaviour of lysozyme. On the other hand, the mobility of the negatively-charged α-lactalbumin remained constant as regards phosphate at pH 7.0 in the 20–200 mmol l⁻¹ range, contrary to the decrease that had been expected with the increasing ionic strength. β-Lactoglobulin exhibited increasingly lower mobilities than those expected of boric acid/borate at pH 7.0 and 8.0 (I=20 mmol l⁻¹).     

New method for the selective capture of antibodies under physiolgical conditions

Hydrophobic charge induction chromatography is a recently developed method for protein separation based on the use of dual-mode ligands. They are designed in such a way so as to combine a molecular interaction supported by a mild hydrophobic association effect in the absence of salts. When environmental pH is changed, the ligand becomes ionically charged resulting into the desorption of the protein. This method is applied to the separation of antibodies from ascite fluids and culture supernatants from hybridomas cultured in the presence of fetal bovine serum or in protein free environment. Typically adsorption from cell culture supernatants is accomplished without any pH or ionic strength adjustment; the column is then washed with a typical buffer to eliminate protein impurities. Antibodies are then desorbed using acetate buffer, pH 4. Antibody binding capacity is in the range of 30 mg per ml of resin at 10% breakthrough. Antibody purity varies according to the initial feed stock and can reach values higher than 90% in a single pass. One example of antibody purification process involving hydrophobic charge induction chromatography as a capture step followed by a polishing phase with DEAE Ceramic HyperD is described. Longevity and ligand leakage are compatible with large-scale applications.     

Retention of small charged impurities during ultrafiltration

Ultrafiltration is used to remove small impurities from a variety of processing streams. However, the clearance of small charged impurities may be inadequate due to electrostatic exclusion by the charged ultrafiltration membranes, an effect that has been largely unappreciated. Ultrafiltration experiments were performed to evaluate the transmission of several model impurities with different electrical charge through ultrafiltration membranes having different surface charge characteristics. Highly charged impurities are strongly rejected by charged cellulose and polyethersulfone membranes even though these solutes are much smaller than the membrane pore size. These effects could be eliminated by using high ionic strength solutions to shield the electrostatic interactions. The sieving data are in good agreement with model calculations based on the partitioning of charged spheres into charged cylindrical pores. Guidelines are developed for estimating conditions needed to obtain effective removal of small charged impurities through charged ultrafiltration membranes.     

Turnover rate of molecular species of sphingomyelin in rat brain

Turnover rate of individual molecular species of sphingomyelin of adult rat brain myelin and microsomal membranes was determined after an intracerebral injection of 100 Ci of [C³H₃]choline. Myelin and microsomal membrane sphingomyelins were isolated from the rest of the lipids. The individual molecular species of benzoylated sphingomyelin were separated and quantitated by reversed-phase high performance liquid chromatography. All individual major molecular species of microsomal and myelin sphingomyelin had maximum incorporation at 6 and 15 days, respectively, after the injection. The specific radioactivity of all the various molecular species of both myelin and microsomal sphingomyelin declined at a similar rate after reaching a maximum. There was no significant difference in the turnover rate of short chain (16:0, 18:0) and long chain (>22:0) fatty acid containing sphingomyelin. The average apparent turnover rate of myelin and microsomal sphingomyelin molecular species was about 14–16 days for the fast pool and about 45 days for the slow pool. It is concluded that individual molecular species of sphingomyelin of myelin and microsomal membranes turned over at a similar rate. Thus, turnover rate of sphingomyelin in myelin and microsomal membranes is not affected by the fatty acyl composition of the lipid.     

Stimulation of lysosomal sphingomyelin degradation by sphingolipid activator proteins

Lysosomal breakdown of glycosphingolipids with short hydrophilic carbohydrate headgroups is achieved by the simultaneous action of specific hydrolases and sphingolipid activator proteins (SAPs). Activator proteins are considered to facilitate the enzyme/substrate interaction between water-soluble enzymes and membrane-bound substrates. Sphingomyelin, containing the small hydrophilic phosphorylcholine moiety, is hydrolysed by acid sphingomyelinase (acid SMase). Recent experimental data on the in vivo and in vitro role of activator proteins in sphingomyelin breakdown by acid SMase are reviewed. These data combined with the results using homogenous protein preparations as well as a liposomal assay system mimicking the physiological conditions suggest that lysosomal sphingomyelin degradation is not critically dependent on any of the known activator proteins. Moreover, evidence is provided that the assumed intramolecular activator domain of acid SMase and especially the presence of negatively charged lipids in the lysosomes are sufficient for sphingomyelin turnover.     

Niemann Pick disease: presence of the magnesium-dependent sphingomyelinase in brain of the infantile form of the disease.

Abstract— Brain of a 14-month-old patient with the infantile form of Niemann Pick disease was found to be practically devoid of sphingomyelinase activity when assayed at pH 5. When assayed at pH 7.4, in the presence of magnesium ions considerable hydrolysis of sphingomyelin was obtained by brain preparations. The rate of hydrolis of a homogenate of grey matter was about 0.3 μmol. mg protein^?1. H^?1, corresponding to about 15 μmol of sphingomyelin hydrolysed perg brain in 1 h. The possibility is suggested that the presence of the extra-lysosomal, magnesium dependent sphingomyelinase in brain of Niemann Pick patients may be responsible, in part, for the lesser accumulation of sphingomyelin in this tissue relative to other organs, such as liver or spleen.     

Properties of a Solubilized Microsomal Auxin-binding Protein from Coleoptiles and Primary Leaves of Zea mays

An auxin-binding protein can be solubilized from microsomal membranes of Zea mays using either Triton X-100 extraction of the membranes or buffer extraction of the acetone-precipitated membranes. This paper describes the properties of the binding protein solubilized by these two methods. The binding is assayed by gel filtration chromatography in the presence of naphthalene [2-¹⁴C]acetic acid. Binding is rapid and reversible with an optimum at pH 5. Both preparations show similar molecular weights by gel filtration (80,000 daltons) at pH 7.6 and 0.1 molar NaCl, and both aggregate at low ionic strength. They appear to be the same active molecular species. The binding activity is destroyed by trypsin, pronase or para-chloromercuribenzoic acid, but not significantly reduced by phospholipase C, DNase, RNase, or dithioerythritol. Since saturating amounts of naphthalene acetic acid protect the molecule from inhibition by para-chloromercuribenzoic acid, it is concluded that the binding protein has a sulfhydryl group at the binding site, or protects such a group in its binding conformation. The dissociation constant of the protein for naphthalene acetic acid is 4.6 × 10⁻⁸ molar with 30 picomoles of sites per gram of tissue fresh weight. Binding constants were estimated for 13 other natural and synthetic auxins by competition with naphthalene[2-¹⁴C]acetic acid. Their dissociation constants are in general agreement with published values for their binding to intact membranes and their biological activity, although several exceptions were noted. A supernatant factor from the same tissue changes the apparent affinity of the protein for naphthalene acetic acid. This factor may be the same one as has been previously reported to alter the affinity of intact microsomes for auxin.     

Lactosylceramide-induced stimulation of liposome uptake by Kupffer cells in vivo

Incorporation of 8 mol percent lactosylceramide into small unilamellar vesicles consisting of cholesterol and sphingomyelin in an equimolar ratio and containing [³H]inulin as a marker resulted in an increase in total liver uptake and a drastic change in intrahepatic distribution of the liposomes after intravenous injection into rats. The control vesicles without glycolipid accumulated predominantly in the hepatocytes, but incorporation of the glycolipid resulted in a larger stimulation of Kupffer-cell uptake (3.2-fold) than of hepatocyte uptake (1.2-fold). Liposome preparations both with and without lactosylceramide in which part of the sphingomyelin was replaced by phosphatidylserine, resulting in a net negative charge of the vesicles, were cleared much more rapidly from the blood and taken up by the liver to higher extents. The negative charge had, however, no influence on the intrahepatic distributions. The fast hepatic uptake of the negatively charged liposomes allowed competition experiments with substrates for the galactose receptors on liver cells. Inhibition of blood clearance and liver uptake of lactosylceramide-containing liposomes by $\text{N-}\text{acetyl-}\text{d}\text{-galactosamine}$ indicated the involvement of specific recognition sites for the liposomal galactose residues. This inhibitory effect of $\text{N-}\text{acetyl-}\text{d}\text{-galactosamine}$ was shown to be mainly the result of a decreased liposome uptake by the Kupffer cells, compatible with the reported presence of a galactose specific receptor on this cell type (Kolb-Bachofen et al. (1982) Cell 29, 859–866). The difference between the results on sphingomyelin-based liposomes as described in this paper and those on phosphatidylcholine-based liposomes as published previously (Spanjer and Scherphof (1983) Biochim. Biophys. Acta 734, 40–47) are discussed.     

Hydrophobic binding sites on human interferon.

Human interferon binds to a omega-carboxpentyl-agarose column at low ionic strength (0.15 M NaCl) and is still retained when the ionic strength is raised (to 1.0 M NaCl). The binding can be reversed, however, by ethylene glycol, indicating a hydrophobic interaction. The binding of human interferon to omega-aminohexyl-agarose is weak, even at a low ionic strength, and is probably exclusively electrostatic. This disparate binding behavior may be caused by the presence of a positive charge, adjacent to the hydrophobic binding site, on human interferon. The interaction of human interferon with omega-carboxypentyl-agarose is quite selective, inasmuch as the majority of proteins present in interferon preparations pass through the column unretained. Hydrophobic chromatography of human interferon may thus be useful in its purification.