Carbonic anhydrase activity in kidney and lower intestine of the European starling

A histochemical investigation of kidney and lower intestine of the European starling (Sturnus vulgaris) shows no carbonic anhydrase activity in proximal convoluted tubules, although activity is seen in similarly prepared sections of rat proximal tubules. Early distal tubule cells in the starling are stained throughout the cytoplasm and at the apical and highly infolded basolateral membranes. Late distal tubules lose apical activity and have reduced basolateral infolding, resulting in less intense staining. Darkly stained intercalated cells appear in the connecting tubules and cortical collecting ducts. Both of these segments also show intense basolateral staining. Medullary cones of the starling are highly organized, with central zones containing unstained thin descending limbs of loops of Henle, surrounded by both medullary collecting ducts with only scattered cells staining for enzyme, and by thick ascending limb segments. The latter contain many uniformly stained cells intermingled with occasional unstained cells. Scattered cells of the starling colonic villi demonstrate intense apical brush border membrane staining as well as cytoplasmic staining. Cells lining the cloaca stain less intensely. A biochemical assay for carbonic anhydrase was used to quantify enzyme activity in these tissues. Starling kidney contained 1.96 ± 0.33 (mean ± SEM) enzyme units/mg protein, less than half the activity seen in rat kidney. Stripped colonic epithelium contained 0.66 ± 0.15 enzyme units/mg protein. These quantitative results correlate well with the interpretations derived from the histochemical observations. The lack of proximal tubule carbonic anhydrase activity suggests that the avian kidney relies more on distal nephron segments to achieve net acidification of the urine.     

Carbonic anhydrase.

1. The G + C content of ribosomal RNA of animals seems correlated with the length of periods required for maturation of those organisms. 2. In Protostomes of the animal kingdom, the size of the 28S rRNA molecule does not seem to correlate with the evolutionary stage of the organism. 3. Aphids and water-fleas as well as some protozoa have the 18S rRNA with mol. wt of 0.9 x 10(6) against an overwhelming pressure of evolution to conserve the rRNA molecule of 0.7 x 10(6) daltons. 4. All the Deuterostomes examined were distinguished from Protostomes by having the 28S rRNA's void of the hidden break at the central point. 5. Aphids and nematodes are exceptional Protostomes in that they have the 28S rRNA's without the hidden break. This was discussed in the light of the evolutionary stage of these organisms. 6. Molecular properties of chloroplast rRNA seem to evidence for endosymbiotic origin of this organelle. Mitochondrial rRNA differs considerably from prokaryotic rRNA with respect to molecular size and base composition.     

Carbonic anhydrase inhibitors

Carbonic anhydrases (CAs, EC 4.2.1.1) are widespread enzymes in all organisms, catalyzing CO₂ hydration to bicarbonate and protons. Their inhibition is exploited clinically for decades for various classes of diuretics and systemically acting antiglaucoma agents. In the last years novel applications of CA inhibitors (CAIs) emerged, such as topically acting antiglaucoma, anticonvulsants, antiobesity, antipain, and antitumor agents/diagnostic tools. Such CAIs target diverse isozymes of the 13 catalytically active α-CA isoforms present in mammals. CAs belonging to the α-, β-, γ-, δ-, and ζ-families are found in many organisms all over the phylogenetic tree, and their inhibition was studied ultimately for some pathogenic protozoa (Plasmodium falciparum), fungi (Cryptococcus neoformans, Candida albicans, Candida glabrata, and Saccharomyces cerevisiae), and bacteria (Helicobacter pylori, Mycobacterium tuberculosis, and Brucella suis). Novel interesting chemotypes, in addition to the sulfonamide and sulfamate CAIs, such as coumarins, phenols, and fullerenes, were also reported recently, together with their mechanism of inhibition. This class of enzyme inhibitors shows promise for designing interesting pharmacological agents and understanding in detail protein–drug interactions at molecular level.     

Carbonic anhydrase IX

Cell migration can be principally viewed as a chain of well-orchestrated morphological events that lead to dynamic reshaping of the cell body. However, behind the scene of such a “morphological theater” there are very complex, interrelated molecular and physiological processes that drive the cell movement. Among them, ion transport and pH regulation play a key role, with carbonic anhydrase IX (CA IX) emerging as one of the important “molecular actors.” CA IX is a highly active cell surface enzyme expressed in a broad range of solid tumors in response to hypoxia and explored as a clinically useful biomarker of hypoxia and as a therapeutic target. Its biological role is to protect tumor cells from hypoxia and acidosis in the tumor microenvironment. The study published recently by our group showed that CA IX actively contributes to cell migration and invasion. For the first time, we demonstrated CA IX accumulation in lamellipodia of migrating cells and its direct in situ interaction with bicarbonate transporters. Our findings indicate that tumor cells need CA IX not only as a pro-survival factor in hypoxia and acidosis, but also as a pro-migratory component of the cellular apparatus driving epithelial-mesenchymal transition.     

Carbonic anhydrase of the cotton plant

Nonaqueous fractionation of leaves of the cotton plant suggested that carbonic anhydrase was associated with the chloroplasts. Activity of this enzyme in aqueous extracts prepared in media containing no reductants was stable at 4°. Response to sulfhydryl reagents varied. The results indicated that thiol groups, necessary for the activity of the enzyme, were partially protected from oxidation.     

Carbonic anhydrase in human platelets.

The carbonic anhydrase activity of human platelets was investigated by measuring the kinetics of CO2 hydration in supernatants of platelet lysates by using a pH stopped-flow apparatus. An average carbonic anhydrase concentration of 2.1 microM was determined for pellets of human platelets. Analysis of the kinetic properties of this carbonic anhydrase yielded a Km value of 1.0 mM, a catalytic-centre activity kcat. of 130000 s-1 and an inhibition constant Ki towards ethoxzolamide of 0.3 nM. From these values, CO2 hydration inside platelets is estimated to be accelerated by a factor of 2500. When platelet lysates were subjected to affinity chromatography, only the high-activity carbonic anhydrase II could be eluted from the affinity column, whereas the carbonic anhydrase isoenzyme I, which is known to occur in high concentrations in human erythrocytes, appeared to be absent.     

Carbonic anhydrase from bovine bone

In this research, carbonic anhydrase enzyme, which was taken from the bones of an animal, was purified and characterized for the first time. For this, the bones of a young cow were used. The purification treatment was completed in three steps. Three different isoenzymes, such as peripheral, cystolic, and integral from the bone-cell cytozolic isoenzyme were purified and characterized. In purification of the three isoenzymes, the technique of affinity chromatography, which utilized Sepharose-4B-L-Tyrosine-Sulphanylamide, was used. In measuring the activities of enzymes, two different methods were applied. These are the esterase methods that utilize hydratase and p-nitrophenylacetate as substrate. The measurement of proteins was done with the methods of Bradford and Coomassie Brillant Blue. The optimum pH and temperature of each enzyme were measured and molecular weights were measured by gel-filtration. Its purity was examined by SDS-PAGE (3-10% alternating) electrophoresis and the inferior unit was defined. The inhibition effects of some chemicals were tested for each of the three isoenzymes.     

Carbonic anhydrase localization in the elasmobranch rectal gland

Carbonic anhydrase (CA) activity was histochemically localized in the elasmobranch rectal gland at the light and electron microscopic levels. Reaction product in the secretory tubules was localized coincident with that reported for sodium-potassium activated adenosine triphosphatase (Na-K-ATPase): along the highly amplified basolateral plasma membranes of the epithelial cells. Reaction product was also localized along the plasma membrane of adjacent central canal epithelial cells. The results suggest that CA plays a role in modulating the environment of the intercellular space which in the secretory tubule is believed to be the paracellular pathway for sodium. The results also draw attention to the possible role of the central canal epithelium in modification of the secreted fluid.     

Carbonic anhydrase in relation to higher plants

The review incorporates recent information on carbonic anhydrase (CA, EC: 4.2.1.1) pertaining to types, homology, regulation, purification, in vitro stability, and biological functions with special reference to higher plants. CA, a ubiquitous enzyme in prokaryotes and higher organisms represented by four distinct families, is involved in diverse biological processes, including pH regulation, CO₂ transfer, ion exchange, respiration, and photosynthetic CO₂ fixation. CA from higher plants traces its origin with prokaryotes and exhibits compartmentalization among their organs, tissues, and cellular organelles commensurate with specific functions. In leaves, CA represents 1–20 % of total soluble protein and abundance next only to ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBPCO) in chloroplast, facilitating CO₂ supply to phosphoenol pyruvate carboxylase in C₄ and CAM plants and RuBPCO in C₃ plants. It confers special significance to CA as an efficient biochemical marker for carbon sequestration and environmental amelioration in the current global warming scenario linked with elevated CO₂ concentrations.     

Carbonic anhydrase II in new world monkeys

Carbonic anhydrase II electrophoretic patterns were investigated in 3113 animals belonging to 12 genera and 24 species of New World primates. Polymorphism was detected in 13 species. A total of 24 different alleles was postulated to explain the variability found; the genusAotus showed the highest (eight) number of such alleles. Three genera of the family Callitrichidae (Callithrix, Saguinus, andCebuella) presented five alleles that were not found among the Cebidae. Important markers at the generic level were observed inCallicebus (CA2 ^*6 andCA2 ^*12),Cebus (CA2 ^*10, CA2^*16, andCA2 ^*21), andAotus (CA2^*3, CA2^*4, CA2^*5, CA2^*9, CA2^*15, CA2^*17, CA2^*22, CA2^*23). CA2^*13 seems to be the most common allele among the Cebidae; six genera of this family showed frequencies higher than 70% of it.     

Carbonic anhydrase activity in primary sensory neurons

Neuronal subpopulations of dorsal root ganglion (DRG) cells in the chicken exhibit carbonic anhydrase (CA) activity. To determine whether CA activity is expressed by DRG cells maintained in in vitro cultures, dissociated DRG cells from 10-day-old chick embryos were cultured on a collagen substrate. The influence exerted by environmental factors on the enzyme expression was tested under various conditions of culture. Neuron-enriched cell cultures and mixed DRG-cell cultures (including numerous non-neuronal cells) were performed either in a defined medium or in a horse serum-supplemented medium. In all the tested conditions, subpopulations of cultured sensory neurons expressed CA activity in their cell bodies, while their neurites were rarely stained; in each case, the percentage of CA-positive neurons declined with the age of the cultures. The number and the persistence of neurons possessing CA activity as well as the intensity of the reaction were enhanced by addition of horse serum. In contrast, the expression of the neuronal CA activity was not affected by the presence of non-neuronal cells or by the rise of CO2 concentration. Thus, the appearance and disappearance of neuronal subpopulations expressing CA activity may be decisively influenced by factors contained in the horse serum. The loss of CA-positive neurons with time could result from a cell selection or from genetic repression. Analysis of the time curves does not support a preferential cell death of CA-positive neurons but suggests that the eventual conversion of CA-positive neurons into CA-negative neurons results from a loss of the enzyme activity. These results indicate that the phenotypic expression of cultured sensory neurons is dependent on defined environmental factors.     

Carbonic anhydrase C in white-skeletal-muscle tissue.

We investigated the activity of carbonic anhydrase in blood-free perfused white skeletal muscles of the rabbit. Carbonic anhydrase activities were measured in supernatants and in Triton extracts of the particulate fractions of white-skeletal-muscle homogenate by using a rapid-reaction stopped-flow apparatus equipped with a pH electrode. An average carbonic anhydrase concentration of about 0.5 microM was determined for white skeletal muscle. This concentration is about 1% of that inside the erythrocyte. Some 85% of the muscle enzyme was found in the homogenate supernatant, and only 15% appeared to be associated with membranes and organelles. White-skeletal-muscle carbonic anhydrase was characterized in terms of its Michaelis constant and catalytic-centre activity (turnover number) for CO2 and its inhibition constant towards ethoxzolamide. These properties were identical with those of the rabbit erythrocyte carbonic anhydrase C, suggesting that a type-C enzyme is present in white skeletal muscle. Affinity chromatography of muscle supernatant and of lysed erythrocytes showed that, whereas rabbit erythrocytes contain about equal amounts of carbonic anhydrase isoenzymes B and C, the B isoenzyme is practically absent from white skeletal muscle. Similarly, ethoxzolamide-inhibition curves suggested that white skeletal muscle contains no carbonic anhydrase A. It is concluded that white skeletal muscle contains essentially one carbonic anhydrase isoenzyme, the C form, most of which is probably of cytosolic origin.