Pulmonary carbonic anhydrase in the garter snake, Thamnophis sirtalis

This study examined whether the snake lung possesses intravascular carbonic anhydrase (CA). Lungs were perfused with control salines and with salines containing CA inhibitors. Perfusion with control salines resulted in a stable CO(2) excretion, whereas CA inhibitors significantly reduced pulmonary CO(2) excretion. Membrane-permeable and membrane-impermeable CA inhibitors produced comparable decreases in CO(2) excretion, suggesting that extracellular, intravascular CA participated in the pulmonary CO(2)-HCO3(-)-H(+) reactions. Treatment of lungs with phosphatidylinositol specific-phospholipase C (PI-PLC) significantly decreased CO(2) excretion, indicating that CA was connected to the luminal endothelial cell membrane by a phosphatidylinositol glycan linkage. Taken together, these results are the first to demonstrate the presence of membrane-bound, intravascular CA (CA IV) in the snake lung.     

Adaptations to a terrestrial existence by the robber crab,Birgus latro L.

Summary The activity of carbonic anhydrase (CA), which catalyses the equilibrium CO₂H⁺+HCO ₃ ^- , was investigated in various tissues implicated in the excretion of CO₂ by Birgus latro. Carbonic anhydrase was detected in the water-soluble fraction of gill tissue but also occurred in association with lipids (membrane bound). This is consistent with a CO₂ excretory role and an ion regulation function for the gills. In the lungs (branchial chamber lining) CA activity was found in the membrane bound fraction but was not detected in the soluble fraction, suggesting that the lung CA is not important for ion regulation. The specific CA activity of gill tissue homogenate (A=1.8±0.7·mg^-1) was higher than that measured for lung homogenates (A=0.4±0.2·mg^-1), but when the whole organ was considered the total CA activity in the lungs was not significantly different from total CA activity in the gills. In comparison to aquatic and amphibious crustaceans the specific activity of carbonic anhydrase in the lungs was high (25% cf. gill activity). This CA activity in the lungs could be correlated with significant CO₂ excretion by the lungs. CA may be retained in the branchial tissue as an adjunct to ion reabsorption by the gills.     

Adenosine triphosphatase activity in the osmoregulatory organs of vertebrates

Studies have been made on the activity of cation- and anion-stimulated ATPases, as well as succinic dehydrogenase in homogenates and subcellular fractions from osmoregulatory organs of marine (elasmobranch and teleost) and freshwater (teleost) fishes, amphibians, reptiles, birds and mammals. The activity of Na+, K+-ATPase was found to be rather similar in almost all osmoregulatory organs of the species investigated. The highest level of Cl-stimulated ATPase was found in microsomal fraction of the kidneys from birds and mammals. Succinic dehydrogenase activity is significantly higher in the renal tissue of mammals, both in total homogenates and in mitochondrial fraction.     

Differential effects of Ca2+-calmodulin on adenylate cyclase activity cyclase activity in mouse and rat pancreatic islets.

The subcellular localization of the beta-galactoside-binding protein, or lectin, from rat lung was investigated by the specific binding of anti-lectin immunoglobulin G to subcellular fractions. We used both adult and immature (12-day-old) rats; the immature rat lungs have an 8-10-fold greater concentration than adult rat lungs [Powell & Whitney (1980) Biochem. J. 188, 1-8]. In both groups of animals we observed greater specific binding of anti-lectin immunoglobulin G to intracellular membrane (mitochondrial and microsomal fractions) than to plasma membranes. Pre-incubation of membrane fractions with lactose resulted in a marked diminution of anti-lectin immunoglobulin G binding. In the adult rat lung most (approx. 80%) of the lectin activity was membrane-associated. In the immature rat lung only approx. 30% of the lectin activity was membrane associated and most of the beta-galactoside-binding protein appeared to be a soluble cytoplasmic component. The rat lung beta-galactoside-binding protein appeared to have a broad but predominantly intracellular location, being associated with membranes through one of its galactoside-binding sites.     

Hypoxic pulmonary vasoconstriction in reptiles: a comparative study of four species with different lung structures and pulmonary blood pressures

Low O2 levels in the lungs of birds and mammals cause constriction of the pulmonary vasculature that elevates resistance to pulmonary blood flow and increases pulmonary blood pressure. This hypoxic pulmonary vasoconstriction (HPV) diverts pulmonary blood flow from poorly ventilated and hypoxic areas of the lung to more well-ventilated parts and is considered important for the local matching of ventilation to blood perfusion. In the present study, the effects of acute hypoxia on pulmonary and systemic blood flows and pressures were measured in four species of anesthetized reptiles with diverse lung structures and heart morphologies: varanid lizards (Varanus exanthematicus), caimans (Caiman latirostris), rattlesnakes (Crotalus durissus), and tegu lizards (Tupinambis merianae). As previously shown in turtles, hypoxia causes a reversible constriction of the pulmonary vasculature in varanids and caimans, decreasing pulmonary vascular conductance by 37 and 31%, respectively. These three species possess complex multicameral lungs, and it is likely that HPV would aid to secure ventilation-perfusion homogeneity. There was no HPV in rattlesnakes, which have structurally simple lungs where local ventilation-perfusion inhomogeneities are less likely to occur. However, tegu lizards, which also have simple unicameral lungs, did exhibit HPV, decreasing pulmonary vascular conductance by 32%, albeit at a lower threshold than varanids and caimans (6.2 kPa oxygen in inspired air vs. 8.2 and 13.9 kPa, respectively). Although these observations suggest that HPV is more pronounced in species with complex lungs and functionally divided hearts, it is also clear that other components are involved.     

Development of the pulmonary surfactant system in two oviparous vertebrates

In birds and oviparous reptiles, hatching is often a lengthy and exhausting process, which commences with pipping followed by lung clearance and pulmonary ventilation. We examined the composition of pulmonary surfactant in the developing lungs of the chicken, Gallus gallus, and of the bearded dragon, Pogona vitticeps. Lung tissue was collected from chicken embryos at days 14, 16, 18 (prepipped), and 20 (postpipped) of incubation and from 1 day and 3 wk posthatch and adult animals. In chickens, surfactant protein A mRNA was detected using Northern blot analysis in lung tissue at all stages sampled, appearing relatively earlier in development compared with placental mammals. Chickens were lavaged at days 16, 18, and 20 of incubation and 1 day posthatch, whereas bearded dragons were lavaged at day 55, days 57-60 (postpipped), and days 58-61 (posthatched). In both species, total phospholipid (PL) from the lavage increased throughout incubation. Disaturated PL (DSP) was not measurable before 16 days of incubation in the chick embryo nor before 55 days in bearded dragons. However, the percentage of DSP/PL increased markedly throughout late development in both species. Because cholesterol (Chol) remained unchanged, the Chol/PL and Chol/DSP ratios decreased in both species. Thus the Chol and PL components are differentially regulated. The lizard surfactant system develops and matures over a relatively shorter time than that of birds and mammals. This probably reflects the highly precocial nature of hatchling reptiles.     

An evolutionary link for developing mammalian lungs

Lungs of the human infant and those of other mammals are filled with fluid immediately prior to birth. Studies of the ionic composition of this fluid indicate that active ionic transport processes occur in the epithelial cells of the potential airspaces. The purpose of this study was to see if these active ion pumps were present in developing species other than mammals thus providing a possible evolutionary link to mammals. A series of samples of lung liquid, amniotic fluid, and plasma were taken from embryonic marine turtles gathered from clutches incubating in the beach at Mon Repos, Queensland, Australia during the summer of 1986-87. The concentrations of sodium, potassium and chloride ions and protein measured in these liquids indicated that active pumping processes similar to that seen in the mammalian lung were present in the developing lungs of these marine reptiles and further, circumstantial evidence was gathered to suggest that this liquid was partially reabsorbed prior to hatching. The results support the notion that processes responsible for the normal development of the human lung and lungs of other mammals are also present in the hollow lungs of marine turtles. Thus there is an evolutionary counterpart controlling lung development in more ancient species. It may be possible to generalize this observation to the development of hollow lungs of other species.     

Concentration-activity profile of the modulation of cyclooxygenase product formation by reduced glutathione in microsomal fractions from the goat lung

Age-related changes in pulmonary formation of arachidonic acid (AA) metabolites are thought to play an important role in regulating cardiopulmonary function. This study addresses the potential role of reduced glutathione (GSH) in modulating cyclooxygenase product formation in the developing lung. Prostaglandin H2 (PGH2) metabolism was studied in microsomal fractions isolated from the lungs of unventilated fetal, neonatal and adult goats. GSH-dependent PGH2 to PGE2 isomerase activity in microsomal fractions from the perinatal (fetal and neonatal) goat lung was not saturable with respect to GSH and can respond to changes in GSH concentration over the range of 0.01 to 30 mM, which encompasses the full range the intracellular GSH levels reported in the literature. However, in fractions from the adult, a lower rate of PGE2 formation is observed at higher GSH concentrations. In addition, the tissue levels of GSH exhibited developmental stage-related differences with fetal being higher than neonatal or adult. The present observations may have physiologic relevance, in that decreases in pulmonary GSH levels after birth may contribute to decreases in plasma PGE2 levels by decreasing pulmonary PGE2 synthesis, thereby contributing to closure of the ductus arteriosus; conversely, increased GSH levels associated with hyperoxia may contribute to persistence of ductal patency. Formation of 6-keto-PGF1 alpha and of TXB2 (the stable metabolites of prostacyclin and TXA2) was decreased when PGE2 formation was increased by GSH activation of PGE2 isomerase in fractions isolated from all three developmental stages. A similar pattern of product formation was observed when AA was employed as substrate. These data suggest the possibility that changes in GSH concentration may modulate eicosanoid formation in cells that contain GSH-dependent PGE2 isomerase, as well as either or both prostacyclin or thromboxane synthase(s).     

Carbonic anhydrase activity of rabbit lungs

Pulmonary carbonic anhydrase (CA) activity was studied in rabbit lungs perfused with solutions containing no CA. Measurements were made of the amount of 14CO2 appearing in the expired gas following injections of H14CO3(-), 14CO2, or a 20:1 mixture of each into the pulmonary artery. The fraction of the injected label in the expired gas was only 17% greater for 14CO2 than for the mixture, suggesting that equilibration between H14CO3(-) and 14CO2 was nearly complete during the capillary transit time. Inhibition of pulmonary CA decreased excretion of H14CO3(-) and the mixture by 40 and 49% and increased the excretion of 14CO2 by 96%. Addition of CA to the perfusate had no effect. Thus, CO2 exchange is not significantly limited by pulmonary CA if inhibitors are absent. Tissue binding of [3H]acetazolamide injected into the pulmonary artery was diminished by 50% when acetazolamide concentrations reached 0.13 x 10(-6) M. Each liter of extravascular lung water contained 1.25 x 10(-6) mol of receptors for acetazolamide that were accessible to plasma during a single circulation. Binding of [3H]acetazolamide was also observed in lungs of anesthetized rabbits, suggesting that pulmonary CA is accessible to plasma in vivo as well as in situ.     

Gas transfer in dogfish: A unique model of CO2 excretion

Carbonic anhydrase (CA) is a zinc metalloenzyme that catalyzes the reversible hydration–dehydration reactions of CO₂. It is present in high abundance in the cytoplasm of vertebrate red blood cells, where it contributes to CO₂ excretion. A membrane-bound CA isoform (CA IV) is also present in the lungs of mammals and reptiles, but plays little role in CO₂ excretion. The gills of teleost fish appear to lack plasma-accessible CA activity. In elasmobranchs, however, evidence gathered using a variety of physiological, biochemical and molecular approaches suggests that CA IV is present in the gills, and that at least in dogfish, this CA IV makes a significant contribution to CO₂ excretion by catalyzing the dehydration of plasma HCO₃^?. The contribution of CA IV to CO₂ excretion is favoured by unusually high relative plasma buffering that aids in the provision of protons for HCO₃^? dehydration. Moreover, reduced emphasis on HCO₃^? flux through the red blood cell may reflect the occurrence of a slower turnover cytosolic CA in dogfish. This model of CO₂ excretion, in which HCO₃^? dehydration in the red blood cell catalyzed by cytosolic CA and HCO₃^? dehydration in the plasma catalyzed by membrane-bound CA IV are of comparable importance, has been described for the dogfish. Further work is required to determine whether it applies to elasmobranch fish as a group.     

In situ characterization of carbonic anhydrase activity in isolated rat lungs

Lung carbonic anhydrase (CA) participates directly in plasma CO2-HCO3(-)-H+ reactions. To characterize pulmonary CA activity in situ, CO2 excretion and capillary pH equilibration were examined in isolated saline-perfused rat lungs. Isolated lungs were perfused at 25, 30, and 37 degrees C with solutions containing various concentrations of HCO3- and a CA inhibitor, acetazolamide (ACTZ). Total CO2 excretion was partitioned into those fractions attributable to dissolved CO2, uncatalyzed HCO3- dehydration, and catalyzed HCO3- dehydration. Approximately 60% of the total CO2 excretion at each temperature was attributable to CA-catalyzed HCO3- dehydration. Inhibition of pulmonary CA diminished CO2 excretion and produced significant postcapillary perfusate pH disequilibria, the magnitude and time course of which were dependent on temperature and the extent of CA inhibition. The half time for pH equilibration increased from approximately 5 s at 37 degrees C to 14 s at 25 degrees C. For the HCO3- dehydration reaction, pulmonary CA in situ displayed an apparent inhibition constant for ACTZ of 0.9-2.2 microM, a Michaelis-Menten constant of 90 mM, a maximal reaction velocity of 9 mM/s, and an apparent activation energy of 3.0 kcal/mol.     

Characterization of CDPdiacylglycerol hydrolase in mitochondrial and microsomal fractions from rat lung

CDPdiacylglycerol pyrophosphatase (E.C. 3.6.1.26) activity has been examined in rat lung mitochondrial and microsomal fractions. While the mitochondrial hydrolase exhibited a broad pH optimum from pH 6-8, the microsomal activity decreased rapidly above pH 6.5. Apparent Km values of 36.2 and 23.6 microM and Vmax values of 311 and 197 pmol.min-1.mg protein-1 were observed for the mitochondrial and microsomal preparations, respectively. Addition of parachloromercuriphenylsulphonic acid led to a marked inhibition of the microsomal fraction but slightly stimulated the mitochondrial activity at low concentrations. Mercuric ions were inhibitory with both fractions. Although biosynthetic reactions utilizing CDPdiacylglycerol require divalent cations, addition of Mg2+, Mn2+, Ca2+, Zn2+, Co2+, and Cu2+ all inhibited the catabolic CDPdiacylglycerol hydrolase activity in both fractions. EDTA and EGTA also produced an inhibitory effect, especially with the mitochondrial fraction. Although addition of either adenine or cytidine nucleotides led to a decrease in activity with both fractions, the marked susceptibility to AMP previously reported for this enzyme in Escherichia coli membranes, guinea pig brain lysosomes, and pig liver mitochondria was not observed. These results indicate that rat lung mitochondria and microsomes contain specific CDPdiacylglycerol hydrolase activities, which could influence the rate of formation of phosphatidylinositol and phosphatidylglycerol for pulmonary surfactant.     

Pulmonary neutrophil kinetics after thrombin-induced intravascular coagulation

Previous studies have indicated that neutrophils are required for the development of increased lung vascular permeability after thrombin-induced pulmonary microembolization. In this study, we examined neutrophil kinetics and uptake in the sheep lung before and after lung vascular injury. Sheep neutrophils were isolated by a Percoll-gradient method and labeled with indium-111 oxine. A maximum lung activity of 40% of the injected indium-111 neutrophil activity was attained 8-12 min after the injection. The calculated half-lives of both circulating and pulmonary neutrophils were 700 min. The rate of washout of labeled neutrophils from the lungs was the same as the loss of the peripheral blood activity, indicating removal of neutrophils from the lung and blood by a common pathway (e.g., liver and spleen). Intravenous infusion of alpha-thrombin resulted in an immediate uptake of neutrophils of 14% above the base-line activity. The increased uptake was associated with an immediate decrease in the blood activity, indicating sequestration of the neutrophils in the pulmonary circulation. The neutrophil uptake after alpha-thrombin was transient, reaching a maximum 15 min after infusion. Neutrophil uptake did not occur with alpha-thrombin (which lacks the fibrinogen recognition site), suggesting that the uptake was secondary to intravascular coagulation. An increase in the pulmonary blood volume cannot explain the increased neutrophil sequestration because pulmonary blood volume determined by [99mTc]pertechnetate-labeled erythrocytes did not increase after the alpha-thrombin infusion. Therefore, alpha-thrombin results in a transient neutrophil sequestration in the lung, and the response is secondary to the intravascular coagulation induced by the alpha-thrombin.     

Purification and Properties of Rubrophilin: A Novel Brain Specific Membrane Polypeptide

Rubrophilin, a unique brain specific polypeptide, was purified to apparent homogeneity from microsomal fractions of bovine brains. The peptide stains pink with Coomassie Brilliant Blue R-250 (C.I. No. 42660) under specific conditions, has an apparent Mr of 53,000, and is acidic with an apparent pI of 4.9. The purification involves initial solubilization of delipidated microsomes in sodium dodecyl sulfate, followed by ammonium sulfate fractionation, reversed ammonium sulfate gradient elution from diatomaceous earth, gel filtration on polyacrylamide (Biogel P-200), gradient elution chromatography from hydroxylapatite, and reverse-phase chromatography from phenyl-Sepharose. A yield of about 5 mg of rubrophilin was obtained from 9 g of microsomal proteins. Amino acid analysis shows that rubrophilin contains only nine amino acids with residues/mol as follows: alanine (102), glutamic acid (97), lysine (65), proline (55), aspartic acid (48), glycine (44), serine (37), threonine (35), and valine (10). Cysteine, methionine, tryptophan, tyrosine, isoleucine, phenylalanine, histidine, and arginine could not be detected. Relative rubrophilin content of vertebrate brains was as follows: mammals greater than birds greater than reptiles greater than fishes. It is present in mouse retina and human neuroblastoma cell cultures but could not be detected in octopus optic lobe or in cultured C-6 rat glioma cells.     

Dexamethasone increases adult rat lung surfactant lipids

Prenatal administration of glucocorticoids stimulates epithelial cell maturation and induces a precocious development of pulmonary surfactant. The response of the adult lung to steroid administration is less well understood. We administered dexamethasone (2 mg X kg-1 X day-1) to adult male rats for 1 wk by daily subcutaneous injection. After pentobarbital anesthesia we lavaged the lungs and also isolated lamellar bodies from the tissue. Lipid analyses of the extracellular and intracellular surfactant compartments showed two- to fourfold greater amounts of total phospholipids and disaturated phosphatidylcholine compared with control. These changes were not found in kidney nor liver and were not present in plasma membrane, mitochondrial, or microsomal fractions from lungs. Morphometric analyses of the type II cells showed that anatomic measures of the lamellar body pool did not increase. We conclude that glucocorticoids have a significant effect to increase lung surfactant lipid pools of adult rat lungs by changing the phospholipid content of lamellar bodies, without changing lamellar body volume.     

Development of the pulmonary surfactant system in non-mammalian amniotes

Pulmonary surfactant (PS) is a complex mixture of phospholipids, neutral lipids and proteins that lines the inner surface of the lung. Here, it modulates surface tension thereby increasing lung compliance and preventing the transudation of fluid. In mammals, the PS system develops towards the end of gestation, characterized by an increase in the saturation of phospholipids in lung washings and the appearance of surfactant proteins in amniotic fluid. Birth, the transition from in utero to the external environment, is a rapid process. At this time, the PS system is important in opening and clearing the lung of fluid in order to initiate pulmonary ventilation. In oviparous vertebrates, escape from an egg can be a long and exhausting process. The young commence pulmonary ventilation and hatching by 'pipping' through the eggshell, where they remain for some time, presumably clearing their lungs. This paper relates changes in the development of the pulmonary surfactant system within the non-mammalian amniotes in response to birth strategy, lung morphology and phylogeny in order to determine the conservatism of this developmental process. Total phospholipid (PL), disaturated phospholipid (DSP) and cholesterol (Chol) were quantified from lung washings of embryonic and hatchling chickens, bearded dragons (oviparous), sleepy lizards (viviparous), snapping turtles and green sea turtles throughout the final stages of incubation and gestation. In all cases, the pattern of development of the pulmonary surfactant lipids was consistent with that of mammals. PL and DSP increased throughout the latter stages of development and Chol was differentially regulated from the PLs. Maximal secretion of both PL and DSP occurred at 'pipping' in oviparous reptiles, coincident with the onset of airbreathing. Similarly, the amount of DSP relative to total PL was maximal immediately after the initiation of airbreathing in chickens. The relative timing of the appearance of the lipids differed between groups. In the oviparous lizard, surfactant lipids were released over a relatively shorter time than that of the sleepy lizard, turtles, birds and mammals. Thus, despite temporal differences and vastly different lung morphologies, birth strategies and phylogenies, the overall development and maturation of the PS system is highly conserved amongst the amniotes.     

Total CA activity in isolated perfused guinea pig lung by 18O-exchange method

The rate of exchange of 18O between alveolar CO2 and lung water was measured in isolated perfused guinea pig lungs to quantify carbonic anhydrase (CA) activity. The average lung CA activity, with a reaction velocity constant of 5.32 +/- 2.2 s-1, is sufficient to accelerate CO2 reactions in lung water by two orders of magnitude over the uncatalyzed rate at 22 degrees C and a PCO2 of 40 Torr. Three sulfonamide inhibitors of CA with different human erythrocyte membrane permeabilities were used to determine the availability of the enzyme to the perfusate. Ethoxzolamide, the most permeable at 0.1 microM (100 times its inhibition constant, of Ki) inhibited 85% of enzyme activity after exposure of the lung for 3 min and 94% of enzyme activity after 30 min, whereas 1.25 microM (320 times its Ki) acetazolamide (1/165 as permeable) only inhibited CA 28% at 3 min and 75% at 30 min. Benzolamide (less than 1/1,000 as permeable) at 4 microM (1,000 times its Ki) inhibited only approximately 17% of control CA activity by 5 min and 48% by 30 min after the start of perfusion. These data indicate the CA available to pulmonary capillary plasma is approximately 10% of the total lung CA activity, in agreement with published measurements on the homogenized lung.     

Lung myeloperoxidase as a measure of pulmonary leukostasis in rabbits

Pulmonary leukostasis can be associated with acute lung injury. We studied lung peroxidase activity using myeloperoxidase (MPO) as a granulocyte marker to quantitate pulmonary leukostasis in rabbits. Lungs were homogenized in detergent, freeze-thawed, sonified, and centrifuged, and supernatants were assayed for MPO. Seven extractions were performed, and greater than 80% of cumulative MPO was found in the first three extractions. By use of a three-extraction procedure, the mean lung MPO (delta A X min-1 X g tissue-1) was determined in normal [20.9 +/- 5.2 (SE)], granulocyte-depleted (6.5 +/- 2.0), saline-injected (22.2 +/- 5.6), and pneumococcus (PNC)-challenged (69.7 +/- 10.6) animals. Lung MPO was significantly decreased in granulocyte-depleted compared with normal animals (P less than 0.005) and significantly increased in PNC-challenged compared with saline-injected animals (P less than 0.001). MPO extracted from granulocytes and lungs from normal as well as PNC-challenged animals were all biochemically identical. Lung extract did not inhibit MPO, and no MPO was detected in bronchoalveolar lavage fluid obtained from leukostatic lungs. Lung MPO significantly (P less than 0.01) correlated with intravascular intrapulmonary granulocytes. Determination of lung MPO is a relatively simple quantitative method that can be used to detect pulmonary leukostasis.     

Dipyridamole interferes with the incorporation of arachidonic acid and stimulates prostacyclin production in rat lungs

Following the injection of 4 nmol of 14C-arachidonic acid into the pulmonary circulation of rat isolated lungs more than 90% of the radioactivity was retained by the lung tissue. When dipyridamole (20 microM) was infused into the pulmonary circulation during 14C-arachidonate injection the amount of radiolabel was increased in diacylglycerols as well as in phosphatidylinositol and phosphatidylserine of the perfused lungs whereas the amount of radioactivity was decreased in phosphatidylethanolamine. When dipyridamole was infused into the lungs prelabelled with 14C-arachidonic acid the distribution of radiolabel in different lung lipid fractions was not changed significantly. However, dipyridamole seemed to stimulate the formation of prostacyclin in rat lungs as the amount of 6-keto-PGF1 alpha was increased in the perfusion effluent. The present study indicates that dipyridamole interferes with the incorporation of arachidonic acid into different lipids in rat lungs. In addition, the release of prostacyclin seems to be stimulated by dipyridamole.     

Carbonic anhydrase isozyme distribution and characterization in metabolic fiber types of the dorsal levator muscle of the blue crab, Callinectes sapidus

Carbonic anhydrase (CA) distribution and characterization were examined in white and light pink fibers of the dorsal levator muscle of the blue crab. White fibers were structurally and metabolically characterized as fast twitch glycolytic, while the light pink fibers were fast oxidative. All subcellular fractions of both fiber types had significant levels of CA activity; cytoplasmic and microsomal activity was significantly higher in light pink vs white fibers. Cytoplasmic CA from both fiber types was highly sensitive to the inhibitors acetazolamide and chlorzolamide, with Ki values of approximately 2 and 0.4 nM, respectively. Further analysis confirmed that cytoplasmic CA from both fiber types was kinetically similar to the high turnover Type II isoform. It appears that the evolution of the CA Type III isoform, found in vertebrate red muscle, did not occur with the differentiation of metabolic fiber types in crustaceans. Membrane-associated CA, which was also kinetically similar to the Type II isoform, was 20-fold higher in light pink fibers, suggesting a physiological role in facilitated CO2 efflux from the muscle fiber during periods of prolonged maximal activity.