Optimization of conditions of preparative chromatography of carminomycin on a carboxylic cation exchanger

Time course of equilibrium and nonequilibrium sorption of carminomycin on carboxylic cation exchanger BDM-12 has been studied. Physicochemical requirements and limits of mobile phase flow rate are determined for the regular mode of preparative chromatography under the conditions of sharpening of the chromatographic zone.     

Optimization of Conditions of Preparative Chromatography of Carminomycin on a Carboxylic Cation Exchanger

The time course of equilibrium and nonequilibrium sorption of carminomycin on the carboxylic cation exchanger BDM-12 has been studied. Physicochemical requirements and the limits of the mobile phase flow rate are determined for the regular mode of preparative chromatography under the conditions of sharpening of the chromatographic zone.     

Identification of the sodium-calcium exchanger as the major ricin-binding glycoprotein of bovine rod outer segments and its localization to the plasma membrane

After neuraminidase treatment the Na+/Ca2+ exchanger of bovine rod outer segments was found to specifically bind Ricinus communis agglutinin. SDS gel electrophoresis and Western blotting of ricin-binding proteins purified from rod outer segment membranes by lectin affinity chromatography revealed the existence of two major polypeptides of Mr 215K and 103K, the former of which was found to specifically react with PMe 1B3, a monoclonal antibody specific for the 230-kDa non-neuraminidase-treated Na+/Ca2+ exchanger. Reconstitution of the ricin affinity-purified exchanger into calcium-containing liposomes revealed that neuraminidase treatment had no significant effect on the kinetics of Na+/Ca2+ exchange activation by sodium. We further investigated the density of the Na+/Ca2+ exchanger in disk and plasma membrane preparations using Western blotting, radioimmunoassays, immunoelectron microscopy, and reconstitution procedures. The results indicate that the Na+/Ca2+ exchanger is localized in the rod photoreceptor plasma membrane and is absent or present in extremely low concentrations in disk membranes, as we have previously shown to be the case for the cGMP-gated cation channel. Previous reports describing the existence of Na+/Ca2+ exchange activity in rod outer segment disk membrane preparations may be due to the fusion of plasma membrane components and/or the presence of contaminating plasma membrane vesicles.     

SURFACE CHARGE OF CHOLINE ACETYLTRANSFERASE FROM DIFFERENT SPECIES

—The adsorption of partially purified choline acetyltransferase (ChAc) from cat, rat, guinea-pig and pigeon brains by the cation exchange resins, CM-Sephadex (C-50) and Amberlite CG-50 II, was studied at various pH values and ionic strengths. ChAc from cat and rat were more strongly adsorbed by cation exchangers and therefore have a stronger net positive surface charge than those from guinea pig and pigeon. Experiments showed that the difference in adsorption between these two groups of enzymes could not be explained by overloading of the resin, by competitive effect of other proteins present in the enzyme preparations or by the presence of any component suppressing the adsorption of ChAc in any of the enzyme preparations. The adsorption of ChAc by a cation exchanger is very similar to its binding to synaptosome membranes. The significance of the positive surface charge of ChAc in studies on the compartmentation of ChAc in synaptosomes is discussed.     

A rapid radiometric assay for adenosine deaminase

A rapid radiochemical procedure for the measurement of adenosine deaminase is described. The method employs phospho-Sephadex, a weak cation exchanger, which permits the enzymic product inosine to pass unretarded through the gel while the radioactive substrate adenosine is retained. Use of a Millipore filter manifold permits rapid processing of samples and eliminates time-consuming column chromatographic, electrophoretic, or paper chromatographic techniques required for separation of product and substrate.The activity of adenosine deaminase was examined in spleen cell preparations prepared from normal CBA mice. Excellent agreement of results was obtained when the radioactive method was compared with two other independent assay techniques.     

Stoichiometry of the sodium-calcium exchanger in nerve terminals

The stoichiometry of the Na+-Ca2+ exchanger from synaptic plasma membranes was studied in both native and reconstituted preparations. In kinetic experiments performed with the native preparation, initial rates of Na+ gradient-dependent Ca2+ influx were compared to Ca2+-dependent Na+ efflux. These experiments showed that 4.82 Na+ ions are exchanged for each Ca2+ ion. A thermodynamic approach in which equilibrium measurements were made with the reconstituted preparation resulted in a similar (4.76) stoichiometry. The effects of membrane potential generated by valinomycin-induced K+ fluxes could be demonstrated in the reconstituted preparation. In addition, the direct contribution of the Na+-Ca2+ exchanger to the membrane potential across the reconstituted vesicle membrane could be demonstrated by using the lipophilic cation tetraphenylphosphonium.     

Models for biological ion exchangers. I. Proton magnetic resonance studies of water structure in Bio-Rex 70.

Bio-Rex 70, a carboxylic acid cation exchanger, is studied as a biological ion-exchanger resin model for cellular cytoplasm. High-resolution proton magnetic resonance spectra of 1l ionic forms of Bio-Rex 70 are determined. From measured cation exchange capacities, water contents, and chemical shifts for the resin-phase water protons, the dependence of the chemical shift on the counter ion is calculated. The observed chemical shifts (Hz/geq/kg internal water, referred to the Ba2+ form) for each ionic form are: H+, --0.5; Li+, --0.2; Na+, 1.2; K+, 2; Rb+, 2.1; Ag+, --0.4; NH4+, --2.0; NMe4+, 1.2; NEt4+, 1.8; Mg2+, --2.0; Ca2+, --1.5; Sr2+, --0.6; Ba2+, 0.0 Zn2+, --2.3; Cd2+, --4.7; and La3+, --3.3. The results are in good agreement with earlier studies on Dowex 50, indicating that the carboxylate ion exchanger behaves like a concentrated polyelectrolyte. The widths at half-height for the internal water peaks of the polyvalent forms are quite large, ranging from 40 to 100 Hz.     

Dependence of equilibrium and kinetic parameters of erythromycin a sorption on the structural characteristics of the biosorbent

The use of special synthetic sorbents with surface carboxyl groups allowed us to increase fourfold the effective diffusion coefficient for erythromycin. The maximum sorption capacity for the antibiotic exceeded twofold that observed in experiments with a macroporous sulfocation exchanger MN-500. The sorption of the antibiotic was completely reversible upon treatment with a combined eluant that competitively interacts with the sorbent and does not impair the structural characteristics of erythromycin.     

Dependence of equilibrium and kinetic parameters of erythromycin: a sorption on the structural characteristics of the biosorbent

The use of special synthetic sorbents with surface carboxyl groups allowed us to increase fourfold the effective diffusion coefficient for erythromycin. The maximum sorption capacity for the antibiotic exceeded twofold that observed in experiments with a macroporous sulfocation exchanger MN-500. The sorption of the antibiotic was completely reversible upon treatment with a combined eluant that competitively interacts with the sorbent and does not impair the structural characteristics of erythromycin.     

Characterization of polycationic amino acids fusion systems for ion-exchange purification of cyclodextrin glycosyltransferase from recombinant Escherichia coli

Fusion proteins with charged polycationic amino acid tails were constructed for the purpose of simple ion-exchange purification with high purity. A number of positively charged lysine and arginine tails were fused to the C-terminus of cyclodextrin glycosyltransferase (CGTase) derived from Bacillus macerans and expressed in Escherichia coli. The ionic binding forces provided by the tails allowed the selective recovery of CGTase from recombinant E. coli cell extracts, while CGTase by itself could not bind to the cation exchanger at neutral pH. The type of amino acids used and the length of the tail directly affected the purification factors. Most intracellular proteins of E. coli adsorbed on the cation exchanger could be removed by washing with 400 mM NaCl solution at pH 7.4, suggesting that a fusion partner suitable for purification purpose should be provided with high binding strength and the maintenance of adsorption by washing with NaCl solution. Among the fusion CGTases constructed, the CGTK10ase containing 10 lysine residues provided sufficiently high binding strength to allow purification to its homogeneity through simple ion-exchange chromatography.     

The cation/Ca(2+) exchanger superfamily: phylogenetic analysis and structural implications

Cation/Ca(2+) exchangers are an essential component of Ca(2+) signaling pathways and function to transport cytosolic Ca(2+) across membranes against its electrochemical gradient by utilizing the downhill gradients of other cation species such as H(+), Na(+), or K(+). The cation/Ca(2+) exchanger superfamily is composed of H(+)/Ca(2+) exchangers and Na(+)/Ca(2+) exchangers, which have been investigated extensively in both plant cells and animal cells. Recently, information from completely sequenced genomes of bacteria, archaea, and eukaryotes has revealed the presence of genes that encode homologues of cation/Ca(2+) exchangers in many organisms in which the role of these exchangers has not been clearly demonstrated. In this study, we report a comprehensive sequence alignment and the first phylogenetic analysis of the cation/Ca(2+) exchanger superfamily of 147 sequences. The results present a framework for structure-function relationships of cation/Ca(2+) exchangers, suggesting unique signature motifs of conserved residues that may underlie divergent functional properties. Construction of a phylogenetic tree with inclusion of cation/Ca(2+) exchangers with known functional properties defines five protein families and the evolutionary relationships between the members. Based on this analysis, the cation/Ca(2+) exchanger superfamily is classified into the YRBG, CAX, NCX, and NCKX families and a newly recognized family, designated CCX. These findings will provide guides for future studies concerning structures, functions, and evolutionary origins of the cation/Ca(2+) exchangers.     

Asymmetrical properties of the Na-Ca exchanger in voltage-clamped, internally dialyzed squid axons under symmetrical ionic conditions

In this work we have investigated whether the asymmetrical properties of the Na/Ca exchange process found in intact preparations are intrinsic to the exchange protein(s) or the result of the asymmetric ionic environment normally prevailing in living cells. The activation of the Na/Ca exchanger by Ca2+ ions, monovalent cations, ATP gamma S and the effect of membrane potential on the different operational modes of the exchanger (Nao/Cai, Cao/Nai, Cao/Cai, and Nao/Nai) was studied in voltage-clamped squid giant axons externally perfused and internally dialyzed with symmetrical ionic solutions. Under these conditions: (a) Ca ions activate with higher affinity from the inside (K1/2 = 22 microM) than from the outside (K1/2 = 300 microM); (b) experiments measuring the Cao-dependent Ca efflux in the conditions Lio-Trisi, Lio-Lii, Triso-Trisi, and Triso-Lii, show that the activating monovalent cation site on the exchanger faces the external surface; (c) ATP gamma S activates the Cao-dependent Ca efflux (Cao/Cai exchange) only at nonsaturating [Ca2+]i. Its effect appears to be on the Ca transport site since no alteration in the apparent affinity of the activating monovalent cation site was observed. The above results show that the Na/Ca exchange process is indeed a highly asymmetric transport mechanism. Finally, the voltage dependence of the components of the different exchange modes was measured over the range of +20 to -40 mV. The voltage dependence (approximately 26% change/25 mV) was found to be similar for all modes of operation of the exchanger except Nao/Nai exchange, which was found to be voltage insensitive. The sensitivity of the Cao/Cai exchange to voltage was found to be the same in the presence and in the complete absence of monovalent cations. This finding does not support the proposition that the voltage sensitivity of the Cao/Cao exchange is induced by the binding and transport of an external monovalent cation.     

Photoaffinity labeling of the organic cation/H+ exchanger in renal brush border membrane vesicles.

The brush border membrane of the proximal tubule contains two efflux pathways for organic cations from the cell to the tubular fluid: a P-glycoprotein and an organic cation/H+ exchanger. There is evidence that they transport many of the same substrates. Their structural relatedness is unknown and is the subject of this report. The experimental approach was to identify the exchanger with photoaffinity labeling reagents. The rationale was that if the P-glycoprotein and the organic cation/H+ exchanger transport many of the same substrates, then they might be photoaffinity labeled by the same reagents. [125I]Iodoarylazidoprazosin and [3H]azidopine are two reagents, which have been used, to photoaffinity label the P-glycoprotein. We found that several polypeptides were photolabeled in a time- and concentration-dependent manner. The photoincorporation into only two of these polypeptides (41 and 28 kDa) was blocked extensively by the presence of known substrates for the exchanger. The photoaffinity labeling of only the 41-kDa polypeptide was affected by treatment with the chemical reagents, N-ethylmaleimide and dithiothreitol, which are known to affect the exchanger reaction. The findings are consistent with the interpretation that a 41-kDa polypeptide is, or is a component of, the exchanger.     

Characterization of protein capacity of nanocation exchanger particles as filling material for functional magnetic beads for bioseparation purposes

In this study we describe the synthesis and characterization of nanocation exchanger particles (NCEX) as the functional filling material for magnetic beads. Polystyrene NCEX particles were synthesized from styrene via a mini-emulsion polymerization. The coupling of cation exchanger groups was done with chlorosulfuric acid after the polymerization reaction. The NCEX particles have an average diameter of 160-260 nm. Their ion exchange capacity amounts up to 4.58 mval/g. In an adsorption experiment it was possible to adsorb 192 mg lysozyme/g NCEX. Depending on the equilibrium concentration of lysozyme in the bulk solution 70-85% of the attached protein was desorbed. NCEX particles were used to produce magnetic beads with cation exchanger properties. Therefore an innovative production process for the synthesis of magnetic beads from different single components was used. The produced magnetic beads contained 40 wt % NCEX material and showed an ion exchanger capacity of 2 mequiv/g. It was possible to adsorb 75 mg lysozyme/g magnetic beads with a maximum recovery rate of 95%.     

Isolation and Purification of Bovine Testicular Hyaluronidase

We developed a one-step method for the chromatographic purification of hyaluronidase extract on Sepharose Blue, which produced the purified enzyme with a high yield (95%). Purification of hyaluronidase allowed us to obtain biological preparations standardized in protein composition and enzyme activity, which are useful for basic and applied studies.     

Characterization of reconstituted Fo from wild-type Escherichia coli and identification of two other fluxes co-purifying with Fo

We purified the ATPase Fo sector from a nonoverexpressing strain of Escherichia coli, reconstituted it into lipid vesicles made of either asolectin or two different mixtures of purified lipids, and measured proton flux through the reconstituted proton channel. We measured single-channel conductances and found that Fo activity depends on both lipids and reconstitution methods. In asolectin vesicles, Fo has a single-channel conductance of about 0.2 fS. Additionally, the relatively impure Fo prepared from cells carrying single-copy ATPase genes allowed us to observe two other fluxes, a nonselective cation leak (C(L)) and a slow H+ flux (Hs). Unlike the Fo flux, these fluxes could not be blocked by the Fo inhibitor DCCD. The C, reduces the total apparent trapped volume inside vesicles and therefore must equilibrate both H+ and K+ in the vesicles that contain it. When reconstituted into bilayers, these Fo preparations displayed a 120 pS cation channel with characteristics consistent with C(L) flux. The Hs conducts only H+ but at a slower rate than the Fo. We were therefore able to: 1) quantitate the single-channel conductance of the Fo, 2) demonstrate that our Fo purification method co-purified other membrane proteins that have ion-conduction properties, and 3) show that certain lipids are necessary for functional reconstitution of Fo.     

Monovalent cation effects on the activity of the xenobiotic/medium-chain fatty acid:CoA ligases are substrate specific

The effect of monovalent cation on the activity of the XL-I and XL-III forms of xenobiotic/medium-chain fatty acid:CoA ligase (XM-ligase) was investigated using a variety of different carboxylic acid substrates. With benzoate or p-hydroxybenzoate as substrate, the XL-I ligase was essentially inactive in the absence of monovalent cation. However, with phenylacetic acid and medium-chain fatty acids as substrate, the enzyme retained 3 to 10% activity upon removal of monovalent cation. Further, while Na+ was ineffective with benzoate and p-hydroxybenzoate as substrates, it was effective with other substrates, although still less effective than K+. For XL-III, activity toward benzoate, hydroxybenzoate, and salicylate was insignificant in the absence of monovalent cation, but this rate was 10% of the K(+)-supported rate for hexanoate and 20% for decanoate. Also, with decanoate as substrate, XL-III was activated more by Na+ than by K+. Thus, the nature of the dependence on monovalent cation for activity is substrate-selective. Kinetic analysis of the effect of K+ on the activity of XL-I and XL-III revealed that activation by K+ was not the result of alteration of the affinity of the enzymes for either ATP or the carboxylic acid. For both forms of XM-ligase, K+ was found to enhance the affinity of the enzyme for CoA, regardless of the substrate, although the extent of the enhancement was substrate-specific. In almost all cases there was further activation, even at saturating concentrations of CoA, which indicates an additional effect of monovalent cation on the catalytic rate constant for the reaction. The exception was activation of XL-III activity toward decanoate, which was solely the result of enhanced binding affinity for CoA.     

Isolation and purification of bovine testicular hyaluronidase

We developed a single-step method for chromatographic purification of the hyaluronidase extract on Sepharose blue, which produced high yield of the enzyme (95%) with high purity (40). Purification of hyaluronidase allowed us to obtain biological preparations standardized by the protein composition and enzyme activity and useful for basic and applied researches.     

Bioreactor controlled by PI algorithm and operated with a perfusion chamber to support endothelial cell survival and proliferation

This paper reports the optimization of a perfusion bioreactor system previously reported by us (Chouinard et al., 2009). The implementation of a proportional-integral (PI) controller algorithm to control oxygen concentration and pH is presented and discussed. P and I values used by the controller were first estimated using a First-Order-Plus-Dead-Time (FOPDT, Matlab Simulink) and then tuned manually. A new gas exchanger design compatible with the PI controller was introduced and validated to decrease interaction between the injected gases and overall inertia of the system. The gas exchanger was used to adjust both pH and dissolved oxygen (DO) concentration. This new bioreactor system allowed real-time PI control over pH and DO concentration at different flow rates (from 2 to 70 mL min(-1)). Cell viability and proliferation were investigated to validate the updated bioreactor design and performance.