Genetic variation in the carbonic anhydrase isozymes of macaque monkeys. II. Inheritance of red cell carbonic anhydrase levels in different carbonic anhydrase I genotypes of the pig-tailed macaque,Macaca nemestrina

The inheritance of red blood cell levels of carbonic anhydrase isozymes (CA I and CA II) has been studied in different carbonic anhydrase I genotypes of the pig-tailed macaque, Macaca nemestrina. Quantitation of CA I isozymes in a series of animals indicates that the total CA I concentration is the sum of the average effects of each CA I structural allele and that the average effects are independent of the various allelic combinations. The relative average effects were 0.32:0.95:1.0 for the CA I ^a, CA I^b, and CA I ^c structural genes, respectively. It is also demonstrated that the level of CA II is related to the CA I genotypes. Multiple regression analysis demonstrated that each dose of CA I-deficiency gene present decreased the CA II concentration by approximately 30%, with this decrease in CA II level being solely related to the dose of CA I-deficiency gene and not to the level of CA I. The CA I-deficient animals produce CA I products that are similar to the common CA Ia, CA Ib, CA Ic electrophoretic types. Limited mating data indicate that the CA I components in CA I-deficient animals are inherited codominantly.Supported by U.S. Public Health Service Research Grant GM-15419.This report is a portion of a dissertation submitted to the University of Michigan in partial fulfillment of the requirements for the Doctor of Philosophy degree.U.S. Public Health Service Predoctoral Trainee (GM-71-14).     

Genetic variation in the carbonic anhydrase isozymes of macaque monkeys. I. The radioimmunosorbent assay

A radioimmunosorbent technique is described which is capable of independently detecting both isozymes of carbonic anhydrase, CA I and CA II, in concentrations as low as 1 ng/ml. The technique is used to quantitate the different electrophoretic variants of red cell CA I as well as levels of CA II in the pig-tailed macaque, Macaca nemestrina.Supported by U.S. Public Health Service research grant GM-15419.U.S. Public Health Service Predoctoral Trainee (GM-71-14).     

Genetic variation in the carbonic anhydrase isozymes of macaque monkeys. IV. Degradation by heat and proteolysis of normal and variant carbonic anhydrase isozymes of Macaca nemestrina

Studies were undertaken on the heat denaturation and proteolytic degradation by alpha-chymotrypsin of the normal red cell carbonic anhydrase isozyme, CA II, and two electrophoretic variants of carbonic anhydrase I, CA Ia and CA Ib, of the pigtail macaque. The heat degradation results showed a difference of about 40-fold in the rate constants between CA Ia and CA Ib, which is due to the marked thermostability of CA Ib compared to CA Ia. The enthalpies and entropies of activation were calculated from the heat denaturation constants. These values were compared, on enthalpy-entropy compensation plots, with those values previously determined for the human CA I and CA II isozymes. They were highly correlated and clearly fell into two distinct clusters, separated by about 200 kJ mol-1; one group comprising the macaque and human CA I isozymes and the other the CA II isozymes. The proteolytic degradation results showed that CA Ia is degraded about 2.5 times more rapidly than CA Ib by alpha-chymotrypsin. Thus, the characteristic 3/1 ratio of CA Ib/CA Ia in mature red cells could be accounted for by the greater susceptibility of CA Ia to degradation at some stage in red cell development.     

Quantitative genetic variation in carbonic anhydrase isozymes from tissues of the pig-tailed macaque,Macaca nemestrina

Two isozymes of carbonic anhydrase (CA I and CA II) were quantified by a radio-immunoassay in 10 different tissues of the pig-tailed macaque. There were clearly differences in relative amounts of the two isozymes, indicating a differential regulation of these two different gene products. An inherited deficiency variant reduced red cell CA I and CA II 5000-fold and 2.7-fold, respectively. In nine other tissues, CA I was reduced from approximately twofold to 110-fold, and CA II was essentially unchanged. The CA I in deficient red cells was immunochemically and electrophoretically identical to common electrophoretic variants of CA I in the pig-tailed macaque and was enzymatically active.This work was part of a doctoral dissertation submitted in partial fulfillment of the Doctor of Philosophy degree in the Horace H. Rackham School of Graduate Studies at The University of Michigan. Supported by NIH training grant 5-T01-GM-71-11 and NIH research grant GM-15419.     

Invertebrate red blood cell carbonic anhydrase

This is the first report documenting the presence of carbonic anhydrase (CA) for any invertebrate red cells. CA activity was measured in plasma, hemolysates of blood cells, and in hemolymph of selected species of invertebrates. Annelid red blood cells (RBC) and sipunculid pink blood cells both possessed significant levels of CA activity. Molluscan RBC, on the other hand, lacked CA activity. The distribution appears to have fallen along phylogenetic lines, with CA being present only in blood cells of the two more closely related groups. However, the presence of extracellular CA was confirmed in oyster hemolymph. Oyster hemolymph CA showed a similar affinity (Ki) for the sulfonamide inhibitors acetazolamide and ethoxzolamide, as did the vertebrate RBC CA II isozyme, supporting the idea that this isozyme could be the ancestral form of the enzyme.     

Studies on red cell carbonic anhydrase types in Korean cattle

Red cell carbonic anhydrase types in Korean cattle were investigated by means of starch gel electrophoresis.
A carbonic anhydrase zone (X) located ahead zone F was found in 12 out of 502 Korean cattle.
The distribution of CA phenotypes in 490 Korean cattle was CA FS type 92 and CA SS type 398. The CA FF type has not yet been recognized in Korean cattle. The gene frequencies were CA^F– 0.094 and CA^F = 0.906. No statistically significant differences were observed between gene frequencies in cattle from six different Korea provinces.     

Structure,function and applications of carbonic anhydrase isozymes

The carbonic anhydrases enzymes (CAs, EC 4.2.1.1) are zinc containing metalloproteins, which efficiently catalyse the reversible conversion of carbon dioxide to bicarbonate and release proton. These enzymes are essentially important for biological system and play several important physiological and patho-physiological functions. There are 16 different alpha-carbonic anhydrase isoforms studied, differing widely in their cellular localization and biophysical properties. The catalytic domains of all CAs possess a conserved tertiary structure fold, with predominately β-strands. We performed an extensive analysis of all 16 mammalian CAs for its structure and function in order to establish a structure–function relationship. CAs have been a potential therapeutic target for many diseases. Sulfonamides are considered as a strong and specific inhibitor of CA, and are being used as diuretics, anti-glaucoma, anti-epileptic, anti-ulcer agents. Currently CA inhibitors are widely used as a drug for the treatment of neurological disorders, anti-glaucoma drugs, anti-cancer, or anti-obesity agents. Here we tried to emphasize how CAs can be used for drug discovery, design and screening. Furthermore, we discussed the role of CA in carbon capture, carbon sensor and metabolon. We hope this review provide many useful information on structure, function, mechanism, and applications of CAs in various discipline.     

Genetic control of quantitative variation in carbonic anhydrase isozymes of mammals. I. The concentration within single erythrocytes of the mouse

The levels of the carbonic anhydrase isozymes (CA and CA II) in single erythrocytes of DBA/2J mice were assayed by measuring the specific immunofluorescence of CA I and CA II with a microspectrofluorometric technique. Measurements of 100 randomly selected cells showed a range (in relative fluorescence units) of 21-52 (mean 31.3 +/- 7.5) for CA I and 30-80 (mean 45.6 +/- 10.7) for CA II. The CA II/CA I ratio of the means obtained by the single-cell fluorescence assay was similar to the ratios obtained for the two isozymes from hemolysates of DBA/2J mice using an immunodiffusion assay. The influence of cell age on the variation in carbonic anhydrase levels was determined by separating red cells into several fractions by a gravity sedimentation procedure. The younger cells showed higher levels of CA I and CA II than the older cells; however, the extensive overlap in the variability between the cells from the different fractions indicated that although cell age was contributing to the overall heterogeneity, its influence was not pronounced.     

Selective tissue distribution of carbonic anhydrase isozymes in the ox.

By affinity chromatography the isozymic distribution of carbonic anhydrase (carbonate hydro-lyase, EC 4.2.1.1) has been studied in extract from various bovine tissues. Carbonic anhydrase II forms isolated from erythrocyte, kidney and brain are indistinguishable by specific activity, amino acid composition, fingerprint, electrophoretic and immunological behaviour. By these criteria they differ from carbonic anhydrase I isolated from rumen epithelium.     

Differential regulation of hepatic carbonic anhydrase isozymes in the streptozotocin-diabetic rat

Most work with the male rat liver carbonic anhydrase isozymes in the past decade has centered on the cytosolic CA III and the mitochondrial CA V. This paper reports that the relative activity of both isozymes is altered in streptozotocin-diabetes. Carbonic anhydrase activity of perfused liver homogenates and disrupted, isolated mitochondria was measured by the mass spectrometric 18O decay technique at 37 degrees C. The contributions of the different isozymes were determined based on intracellular location and sensitivity to acetazolamide inhibition. Diabetes resulted in a twofold increase in the activity of CA V but a halving in the activity of CA III. This is the first time that liver CA V has been shown to be altered by physiological stress. The total carbonic anhydrase activity in the diabetic rat liver was unaltered compared with control rats; however, CA III never accounted for more than 50% of this activity. Since CA isozymes I, II, and IV together account for 30% of the CA activity in control rats and 70% in diabetic rats it is concluded that one or more of these isozymes is subject to regulation in the diabetic male rat. The increase in CA V during diabetes is in accord with this isozyme having an important function in provision of substrate for hepatic gluconeogenesis and ureagenesis.     

Interaction between red cell membrane band 3 and cytosolic carbonic anhydrase

We have previously proposed that a membrane transport complex, centered on the human red cell anion transport protein, band 3, links the transport of anions, cations and glucose. Since band 3 is specialized for HCO ₃ ^– /Cl^– exchange, we thought there might also be a linkage with carbonic anhydrase (CA) which hydrates CO₂ to HCO ₃ ^– . CA is a cytosolic enzyme which is not present in the red cell membrane. The rate of reaction of CA with the fluorescent inhibitor, dansylsulfonamide (DNSA) can be measured by stopped-flow spectrofluorimetry and used to characterize the normal CA configuration. If a perturbation applied to a membrane protein alters DNSA/CA binding kinetics, we conclude that the perturbation has changed the CA configuration by either direct or allosteric means. Our experiments show that covalent reaction of the specific stilbene anion exchange inhibitor, DIDS, with the red cell membrane, significantly alters DNSA/CA binding kinetics. Another specific anion exchange inhibitor, benzene sulfonate (BSate), which has been shown to bind to the DIDS site causes a larger change in DNSA/CA binding kinetics; DIDS reverses the BSate effect. These experiments show that there is a linkage between band 3 and CA, consistent with CA interaction with the cytosolic pole of band 3.This work was supported in part by a grant-in-aid from the American Heart Association, by the Squibb Institute for Medical Research and by The Council for Tobacco Research.We should like to express our thanks to Dr. I.M. Wiener for kindly supplying us with the impermeable sulfonamide, ZBI, which we used in preliminary experiments and to Dr. T.H. Maren for analysis of a sample of BCA II.     

A radioimmunoassay for quantifying carbonic anhydrase isozymes in crude lysates

A radioimmunoassay was developed for quantifying each of the two genetically distinct forms of primate carbonic anhydrase, carbonic anhydrases I and II, in unpurified lysates. Under the given experimental conditions, the assay is capable of detecting a minimum of 0.025 g of carbonic anhydrase I and 0.005 g of carbonic anhydrase II. There is approximately 98% reproducibility upon repeated assays of a given hemolysate.Supported by NIH training grant 5-TO1-GM-71-11 and NIH research grant 1-PO1-GM-15419-02.NIH postdoctoral trainee.     

The cytoplasmic isozymes of carbonic anhydrase in the gastrointestinal tract of reindeer

The cytoplasmic isozymes of carbonic anhydrase: CA I and CA II, in the gastrointestinal tract tissues of reindeer were identified by electrophoresis and substrate-inhibitory tests. The study of the tissue distribution and composition of the cytoplasmic isozymes has shown, that isozyme CA II is found in the forestomachs and the colon mucosal tissue, whereas isozyme CA II predominates in the abomasum and small intestinal mucosa tissue.