Preparative affinity electrophoresis: application to human erythrocyte carbonic anhydrase

A modification of affinity electrophoresis for preparative purposes is described. This method has been applied to the purification of human erythrocyte carbonic anhydrases B and C. During conventional affinity chromatography some hemoglobin contamination occurs. By introduction of an electrophoretic purification step after the immobilization of carbonic anhydrase to the affinity gel, the hemoglobin impurity is reduced about eight and two times in the preparations of the B and C enzymes, respectively, compared to the enzymes purified by affinity chromatography.     

Enhancement of carbonic anhydrase activity by erythrocyte membranes

The human erythrocyte membrane is an efficient enhancer of both high (CA II) and low (CA I) activity isozymes of red blood cell carbonic anhydrase. The presence of membrane increased CO2 hydration catalyzed by bovine CA II 1.6-fold, human CA II 3.5-fold, and human CA I 1.6-fold. With the high activity CA isozymes, maximal stimulation was observed in the presence of 1-3 micrograms membrane protein/ml. The Vmax for bovine CA II (4 nM) rose from 0.302 to 0.839 mM/s, while that for human CA II (6 nM) increased from 0.113 to 0.414 mM/s in the absence and presence of membrane, respectively. The apparent Km for CO2 increased from 13.2 to 51.2 mM for bovine CA II, and from 6.5 to 38.5 mM for human CA II. Mixtures of membrane plus enzyme, upon centrifugation through linear sucrose density gradients, displayed enhanced Ca activity only in membrane-containing gradient fractions, verifying the stimulatory ability of membranes on enzyme activity and indicating tight and stable complex formation. Membrane enhancement of CA activity appears to be a general phenomenon in that mouse hepatocyte membranes also stimulated CA activity, although less efficiently than erythrocyte membranes. Of the many soluble putative effectors assayed, only imidazole enhanced CA II activity to an extent comparable with erythrocyte membranes; imidazole did not, however, stimulate the activity of human CA I. The data are consistent with a model of CA II activation by membrane association that may effect a distortion of the enzyme conformation in such a way as to facilitate intra- and/or intermolecular proton transfer between membrane-bound and enzyme-bound proton shuttling residues (perhaps the imidazole moiety of histidine) and the Zn-bound hydroxide at the catalytic site of the enzyme.     

Polymorphism of human erythrocyte carbonic anhydrase in the population of Moscow and in the native populations of Siberia detected by polyacrylamide gel electrophoresis

Carbonic anhydrase of human erythrocytes was separated by polyacrylamide electrophoresis into four fractions determined, obviously, by two loci, CAI and CAII. Investigation of Moscow population sample of 458 men (516 healthy and 42 with schizophrenia) showed monomorphism of carbonic anhydrase for these two loci. Carbonic anhydrase I and carbonic anhydrase II were differentiated with fluorogenic substrates. The polymorphic variant of CAII was discovered while studying the sample of Siberian mongoloids (Evenks and Jakuts) with frequency 0,047 and 0,045, respectively.     

Thermal denaturation of erythrocyte carbonic anhydrase

An experimental study on the thermal behaviour of erythrocyte carbonic anhydrase was carried out with the main aim to estimate the thermodynamic parameters that control the stability of the enzyme. The effects of thermal denaturation on the catalytic properties of the enzyme were also investigated. Below 60 degrees C the enzyme was found to be very stable, whereas between 60 and 65 degrees C a drastic decrease in the biological activity was observed. From the obtained results some considerations were made about the stabilization of the active form of the protein.     

Developmental changes in human erythrocyte carbonic anhydrase levels: coordinate expression with adult hemoglobin

In order to bolster the argument that parallel developmental changes in erythrocyte adult hemoglobin (HbA) and carbonic anhydrase (CA) content provide a potentially suitable model for the dissection of coordinate gene expression, the magnitude of fetal vs adult differences in CA I and CA II levels was examined in human red cell subpopulations obtained after varying periods of exposure to CA-dependent, NH4Cl-HCO-3-mediated, acetazolamide-modulated hemolysis. When content of CA I and CA II was immunologically assessed in cohorts surviving successively longer periods of hemolysis, cord blood red cells were divisible into two populations. Fifteen to thirty percent are rapidly disrupted and have CA I and CA II concentrations similar to those in adult blood erythrocytes. The remaining 70 to 85% have CA I concentrations which are 100-fold less and CA II concentrations which are 5- to 20-fold less than those found in adults. Thus, contrary to past reports, the magnitude of the developmental change in CA I concentration closely resembles the magnitude of change in HbA levels.     

Purification and characterization of carbonic anhydrase from bovine erythrocyte plasma membrane

Carbonic anhydrase (CA) was purified from bovine erythrocyte plasma membrane and characterized in this study. For this purpose, the blood taken from young animals was hemolysed, the membrane fraction was separated, and this fraction was repeatedly washed. The enzyme (CA) was removed from the membrane with buffered TritonX-100 (1%); it could be purified at a factor of 22.8 by affinity chromatography.The CA obtained from erythrocyte membrane has an esterase activity as well as hydratase activity. The Vmax and Km of the enzyme for the substrate (p-nitrophenyl acetate) are 1.948x10(-3) mM/L x dak, and 3.596 mM, respectively. The purification degree of the enzyme was controlled by SDS-PAGE (3-10), which showed two distinct bands. It was determined that the enzyme had activity within the pH range of 4.5-9.5 and that the optimal pH was 7.5. The temperature at which it showed activity was 20-60 degrees C and optimal temperature was 37 degrees C. Molecular weight of CA was found to be 29844 and 61706 Dalton by gel filtration. On the other hand, sulfanilamide and acetazolamide affected the enzyme.     

Partial amino acid sequence of erythrocyte carbonic anhydrase from tiger shark

1. A partial primary structure (197 residues) of carbonic anhydrase from tiger shark (Galeocerdo cuvieri) erythrocytes has been determined. 2. The amino acid sequence of the enzyme is identical to those of human cytoplasmic carbonic anhydrases (CA I-III) by as much as 52-60%. 3. It is shown that tiger shark CA most closely resembles the CA II isoenzyme of amniotes. 4. Isoelectric focusing and inhibition studies on carbonic anhydrase from dogfish (Squalus acanthias) blood and muscle indicate the presence of the same isoenzyme in shark blood and muscle.     

Binding of human carbonic anhydrase to human hemoglobin

The ability of human carbonic anhydrases to interact with human CO-hemoglobin have been studied with the counter-current distribution technique in aqueous/aqueous biphasic systems. The experimental results show that human carbonic anhydrase II interacts with human CO-hemoglobin whereas human carbonic anhydrase I does not. THe interaction between CO-hemoglobin and carbonic anhydrase II was quantified using the theoretical model developed previously for one-to-one interacting systems. [Backman, L. and Shanbhag, V.P. (1979) J. Chromatogr. 171, 1-13]. The apparent association constant was estimated to be 4.1 x 10(5) l mol-1 at pH 8.0 and 21 degrees C for the association of carbonic anhydrase II and CO-hemoglobin.     

Recovery of native proteins from preparative electrophoresis gel slices by reverse polarity elution

A technique for high yield recovery of native, biologically active proteins from preparative polyacrylamide gel slices by reverse polarity elution is described. No apparatus other than the standard slab gel electrophoresis system is required. Several proteins have been recovered in biologically active form at a 90% yield, in quantities ranging from 0.4 mg to 4.2 mg. The method is effective with both small (9,000 dalton) and large (186,000 dalton) polypeptides. Both simple and complex proteins are recovered intact. For example, the copper-zinc and manganese superoxide dismutases from crude soybean extracts are active upon recovery. Similarly, the vitamin D-dependent calcium binding proteins from rat kidney and intestine are isolated by this method in homogeneous, active form.     

Crystallization and preliminary data of Indian buffalo erythrocyte carbonic anhydrase

The most abundant anhydrase isoenzyme from the erythrocyte of Indian buffalo has been purified using affinity gel and DEAE-cellulose ion-exchange columns and single crystals suitable for X-ray diffraction studies have been obtained. The unit cell dimensions are a = 46.8 A, b = 104.5 A, c = 60.4 A, beta = 91.2 degrees and the space group is P2(1), with two molecules per asymmetric unit.     

Amino acid sequence of human erythrocyte carbonic anhydrase C

Human carbonic anhydrase C is the high-specific-activity form of the enzyme found in human red cells. A proposal for the primary structure of this enzyme is presented. Trypsin-catalyzed hydrolysis was restricted to the arginyl bonds of the protein by blocking the lysyl side chains by amidination. The arginine fragments were isolated and their amino acid sequences determined. The sequence contains 259 amino acid residues in a single polypeptide chain devoid of disulfide bonds. The structure obtained should be adequate to permit a detailed interpretation of the 2.0 Å X-ray crystallographic model of the enzyme previously determined. The primary structures of the human B and C enzymes have about 60% identities.     

The existence of glutathione and cysteine disulfide-linked to erythrocyte carbonic anhydrase from tiger shark

In this study it is shown that the higher molecular weight previously reported for tiger shark carbonic anhydrase (carbonate hydro-lyase, EC 4.2.1.1) compared to other carbonic anhydrases is decreased to a normal value around 30 000 after disulfide reduction of the enzyme. This difference in molecular weight is at least partly due to the existence of disulfide-linked glutathione and cysteine residues. Approx. 3 mol glutathione and a similar amount of cysteine are shown to be bound per mol enzyme. The presence of these factors also has effects on the enzyme activity.     

Carboxyl methylation of cytosolic proteins in intact human erythrocytes. Identification of numerous methyl-accepting proteins including hemoglobin and carbonic anhydrase

Intact human erythrocytes incubated with L-[methyl-3H]methionine incorporated radioactivity into base-labile linkages with membrane and cytosolic proteins which are characteristic of protein methyl esters. Kinetic analysis of the methylation reactions in intact cells shows that individual erythrocytes contain approximately 38,000 and 115,000 protein methyl esters with biological half-lives of 150 min or less in the membrane and cytosolic protein fractions, respectively. Fractionation of the methylated cytosolic species by gel filtration chromatography at pH 6.5 followed by sodium dodecyl sulfate-gel electrophoresis at pH 2.4 reveals that many different cytosolic proteins serve as methyl acceptors and that the degree of modification varies widely for individual proteins. For example, hemoglobin is modified to the extent of 3 methyl groups/10(6) polypeptide chains, while carbonic anhydrase contains 1 methyl group/approximately 16,500 polypeptide chains at steady state. Aspartic acid beta-[3H]methyl ester (Asp beta-[3H]Me) can be isolated from carboxypeptidase Y digests of cytosol proteins. By synthesizing and separating diastereomeric L-Leu-L-Asp beta Me and L-Leu-D-Asp beta Me dipeptides, we show that all of the Asp beta-[3H]Me recovered from cytosolic proteins is in the D-stereoconfiguration. Based on these data and on previous observations that erythrocytes contain a single methyltransferase which also methylates red cell membrane proteins at D-aspartyl residues both in vivo (McFadden, P. N., and Clarke, S. (1982) Proc. Natl. Acad. Sci. U. S. A. 79, 2460-2464) and in vitro (O'Connor, C. M., and Clarke, S. (1983) J. Biol. Chem. 258, 8485-8492), we propose that protein carboxyl methylation is part of a generalized mechanism for metabolizing damaged proteins. The infrequent and spontaneous occurrence of D-aspartyl residues in proteins adequately explains the broad substrate specificity and limited stoichiometries of protein carboxyl methylation reactions.