Carbonic acid production and the role of carbonic anhydrase in decarboxylation in brain

Sudden oxygenation of a thin film of rat brain homogenate, suspended between the surface of a glass pH-sensitive electrode and a gas-permeable membrane, is accompanied by a fall in pH, which is greater when carbonic anhydrase is inhibited. The result suggests that oxidative decarboxylation yields carbonic acid (HCO(3)- and H(+)), which dissociates to form molecular carbon dioxide. Brain carbonic anhydrase facilitates the formation of carbon dioxide from the decarboxylation products.     

Stimulatory Effect of Malo-Lactic Fermentation on the Growth Rate of Leuconostoc oenos

Although l-malic acid is not an energy source for the malo-lactic organism Leuconostoc oenos (L. citrovorum) ML 34, the growth rate of the organism was found to be greatly increased by malo-lactic fermentation (the decarboxylation of l-malic acid to l-lactic acid). The stimulation was especially striking at the low pH (below pH 4) of wine, the natural habitat of this bacterium. The stimulation of growth did not result from changes in pH that accompany malo-lactic fermentation. Thus, these results suggest a biological function of malo-lactic fermentation.     

Carbonic anhydrase in Escherichia coli. A product of the cyn operon.

The product of the cynT gene of the cyn operon in Escherichia coli has been identified as a carbonic anhydrase. The cyn operon also includes the gene cynS, encoding the enzyme cyanase. Cyanase catalyzes the reaction of cyanate with bicarbonate to give ammonia and carbon dioxide. The carbonic anhydrase was isolated from an Escherichia coli strain overexpressing the cynT gene and characterized. The purified enzyme was shown to contain 1 Zn2+/subunit (24 kDa) and was found to behave as an oligomer in solution; the presence of bicarbonate resulted in partial dissociation of the oligomeric enzyme. The kinetic properties of the enzyme are similar to those of carbonic anhydrases from other species, including inhibition by sulfonamides and cyanate. The amino acid sequence shows a high degree of identity with the sequences of two plant carbonic anhydrases. but not with animal and algal carbonic anhydrases. Since carbon dioxide formed in the bicarbonate-dependent decomposition of cyanate diffuses out of the cell faster than it would be hydrated to bicarbonate, the apparent function of the induced carbonic anhydrase is to catalyze hydration of carbon dioxide and thus prevent depletion of cellular bicarbonate.     

Das Vorkommen von Malatenzym und Malo-Lactat-Enzym bei verschiedenen Milchsäurebakterien

1. Malic enzyme was induced by malic acid and malo-lactic enzyme was induced by malic acid and glucose in cells of three strains ofLactobacillus casei that were able to grow on malate as carbon source. Two strains ofStreptococcus faecalis formed malic enzyme only, whereas only malo-lactic enzyme was formed by a glucose requiring strain ofStreptococcus lactis.
2. Given sequential induction, cells ofLactobacillus casei M40 were found to contain malic enzyme and malo-lactic enzyme simultaneously.
3. Malic enzyme and malo-lactic enzyme have been separated by chromatography on Sephadex G-200. These two enzymes have a different pH optimum, different affinities for substrates, form different end products from malate, and have molecular weights of 120000 and 150000 daltons respectively.

     

Carbonic anhydrase III: the phosphatase activity is extrinsic

The carbonic anhydrases reversibly hydrate carbon dioxide to yield bicarbonate and hydrogen ion. They have a variety of physiological functions, although the specific roles of each of the 10 known isozymes are unclear. Carbonic anhydrase isozyme III is particularly rich in skeletal muscle and adipocytes, and it is unique among the isozymes in also exhibiting phosphatase activity. Previously published studies provided evidence that the phosphatase activity was intrinsic to carbonic anhydrase III, that it had specificity for tyrosine phosphate, and that activity was regulated by reversible glutathionylation of cysteine186. To study the mechanism of this phosphatase, we cloned and expressed the rat liver carbonic anhydrase III. The purified recombinant had the same specific activity as the carbonic anhydrase purified from rat liver, but it had virtually no phosphatase activity. We attempted to identify an activator of the phosphatase in rat liver and found a protein of approximately 14 kDa, the amount of which correlated with the phosphatase activity of the carbonic anhydrase III fractions. It was identified as liver fatty acid binding protein, which was then purified to test for activity as an activator of the phosphatase and for protein-protein interaction, but neither binding nor activation could be demonstrated. Immunoprecipitation experiments established that carbonic anhydrase III could be separated from the phosphatase activity. Finally, adding additional purification steps completely separated the phosphatase activity from the carbonic anhydrase activity. We conclude that the phosphatase activity previously considered to be intrinsic to carbonic anhydrase III is actually extrinsic. Thus, this isozyme exhibits only the carbon dioxide hydratase and esterase activities characteristic of the other mammalian isozymes, and the phosphatase previously shown to be activated by glutathionylation is not carbonic anhydrase III.     

Bio-sequestration of carbon dioxide using carbonic anhydrase enzyme purified from <Emphasis Type="Italic">Citrobacter freundii</Emphasis>

The increase in the atmospheric concentrations of one of the vital green house gasses, carbon dioxide, due to anthropogenic interventions has led to several undesirable consequences such as global warming and related changes. In the global effort to combat the predicted disaster, several CO₂ capture and storage technologies are being deliberated. One of the most promising biological carbon dioxide sequestration technologies is the enzyme catalyzed carbon dioxide sequestration into bicarbonates which was endeavored in this study with a purified C. freundii SW3 β-carbonic anhydrase (CA). An extensive screening process for biological sequestration using CA has been defined. Six bacteria with high CA activity were screened out of 102 colonies based on plate assay and presence of CA in these bacteria was further emphasized by activity staining and Western blot. The identity of selected bacteria was confirmed by 16S rDNA analysis. CA was purified to homogeneity from C. freundii SW3 by subsequent gel filtration and ion exchange chromatography which resulted in a 24 kDa polypeptide and this is in accordance with the Western blot results. The effect of host on metal ions, cations and anions which influence activity of the enzyme in sequestration studies suggests that mercury and HCO₃ ⁻ ion almost completely inhibit the enzyme whereas sulfate ion and zinc enhances carbonic anhydrase activity. Calcium carbonate deposition was observed in calcium chloride solution saturated with carbon dioxide catalyzed by purified enzyme and whereas a sharp decrease in calcium carbonate formation has been noted in purified enzyme samples inhibited by EDTA and acetazolamide.     

Oxaloacetate decarboxylase from Pseudomonas stutzeri: purification and characterization

Oxaloacetate decarboxylase (OXAD), the enzyme that catalyzes the decarboxylation of oxaloacetate to pyruvic acid and carbon dioxide, was purified 245-fold to homogeneity from Pseudomonas stutzeri. The three-step purification procedure comprised anion-exchange chromatography, metal-chelate affinity chromatography, and biomimetic-dye affinity chromatography. Estimates of molecular mass from sodium dodecyl sulfate-polyacrylamide gel electrophoresis and native high-performance gel-filtration liquid chromatography were, respectively, 63 and 64 kDa, suggesting a monomeric protein. OXAD required for maximum activity divalent metal cations such as Mn2+ and Mg2+ but not monovalent cations. The enzyme is not inhibited by avidin, but is competitively inhibited by adenosine 5'-diphosphate, acetic acid, phosphoenolpyruvate, malic acid, and oxalic acid. Initial velocity, product inhibition, and dead-end inhibition studies suggested a rapid-equilibrium ordered kinetic mechanism with Mn2+ being added to the enzyme first followed by oxaloacetate, and carbon dioxide is released first followed by pyruvate. Inhibition data as well as pH-dependence profiles and kinetic parameters are reported and discussed in terms of the mechanism operating for oxaloacetate decarboxylation.     

Coupling of "malic" enzyme and NADPH:NAD transhydrogenase in the energetics of Hymenolepis diminuta (Cestoda)

Acetylpyridine NADP replaced NADP in promoting the Mn2+ ion-requiring mitochondrial "malic" enzyme of Hymenolepis diminuta. Disrupted mitochondria displayed low levels of an apparent oxaloacetate-forming malate dehydrogenase activity when NAD or acetylpyridine NAD served as the coenzyme. Significant malate-dependent reduction of acetylpyridine NAD by H. diminuta mitochondria required Mn2+ ion and NADP, thereby indicating the tandem operation of "malic" enzyme and NADPH:NAD transhydrogenase. Incubation of mitochondrial preparations with oxaloacetate resulted in a non-enzymatic decarboxylation reaction. Coupling of malate oxidation with electron transport via the "malic" enzyme and transhydrogenase was demonstrated by polarographic assessment of mitochondrial reduced pyridine nucleotide oxidase activity.     

The sequestration of hydroxyl ions by C2 in liquid water: useful physiological roles for a reversible complex formation in the presence of protein catalysts

A second function of carbonic anhydrase (CA) isoforms has already been proposed. This involves the dispersal of complexes in which six carbon dioxide molecules sequester a hydroxyl ion when the gas reacts with liquid water. The semi-catalytic reaction does not require the formation of bicarbonate as an essential corollary. This function is, therefore, a likely activity of carbonic anhydrase related proteins that have recently been discovered and which lack the active zinc site essential for the hydration of carbon dioxide. Re-examination of possible functions for the complex of six CO2 molecules with a hydroxyl anion have brought to light several circumstances where the presence of fully reversible complexes could have physiological advantages. A catalytic synthesis and dissolution of the complexes could thus be the important function for the carbonic anhydrase-related proteins (CA-RP) molecules as well as of some CA isoforms. The possible mechanisms for this extended second catalytic function and examples are briefly discussed.     

Complete amino acid sequence of ovine salivary carbonic anhydrase

The primary structure of the secreted carbonic anhydrase from ovine salivary glands has been determined by automated Edman sequence analysis of peptides generated by cyanogen bromide and tryptic cleavage of the protein and Staphylococcus aureus V8 protease, trypsin, and alpha-chymotrypsin subdigests of the large cyanogen bromide peptides. The enzyme is a single polypeptide chain comprising 307 amino acids and contains two apparent sites of carbohydrate attachment at Asn-50 and Asn-239. The protein contains two half-cystine residues at 25 and 207 which appear to form an intramolecular disulfide bond. Salivary carbonic anhydrase shows 33% sequence identity with the ovine cytoplasmic carbonic anhydrase II enzyme, with residues involved in the active site highly conserved. Compared to the cytoplasmic carbonic anhydrases, the secreted enzyme has a carboxyl-terminal extension of 45 amino acids. This is the first report of the complete amino acid sequence of a secreted carbonic anhydrase (CA VI).     

A search for the function of human carbonic anhydrase B.

Because of the very high activity and abundance of human red cell carbonic anhydrase C (carbamate hydrolase, EC 4.2.1.1), it seemed likely that the second isozyme, B, might not be essential for CO2 metabolism. It was then found that physiological concentrations of Cl- inhibited catalysis of CO2 hydration by the B enzyme (but not by type C), suggesting further that type B does not function in vivo as a carbonic anhydrase. The versatility of the catalytic activity of carbonic anhydrase for a number of 'artificial' substrates suggested that enzyme B may be utilized in reactions of intermediary metabolism. A number of hydration, dehydration, decarboxylation, kinase, and phosphatase systems were tested to determine a possible physiological function for the enzyme. Results with eighteen possible substrates were negative and the possibility is discussed that mammalian carbonic anhydrase B is an evolutionary accident.     

Reverse reaction of malic enzyme for HCO3- fixation into pyruvic acid to synthesize L-malic acid with enzymatic coenzyme regeneration

Malic enzyme [L-malate: NAD(P)(+) oxidoreductase (EC 1.1.1.39)] catalyzes the oxidative decarboxylation of L-malic acid to produce pyruvic acid using the oxidized form of NAD(P) (NAD(P)(+)). We used a reverse reaction of the malic enzyme of Pseudomonas diminuta IFO 13182 for HCO(3)(-) fixation into pyruvic acid to produce L-malic acid with coenzyme (NADH) generation. Glucose-6-phosphate dehydrogenase (EC1.1.1.49) of Leuconostoc mesenteroides was suitable for coenzyme regeneration. Optimum conditions for the carboxylation of pyruvic acid were examined, including pyruvic acid, NAD(+), and both malic enzyme and glucose-6-phosphate dehydrogenase concentrations. Under optimal conditions, the ratio of HCO(3)(-) and pyruvic acid to malic acid was about 38% after 24 h of incubation at 30 degrees C, and the concentration of the accumulated L-malic acid in the reaction mixture was 38 mM. The malic enzyme reverse reaction was also carried out by the conjugated redox enzyme reaction with water-soluble polymer-bound NAD(+).     

Author index for volume 121

A method for the quantitative conversion of the individual carbon atoms of l-malic acid to CO₂ for high-precision carbon isotope ratio determination is presented. Malic acid is decarboxylated sequentially at C-4 and C-1 using malic enzyme and pyruvate decarboxylase. The acetaldehyde remaining following these reactions is oxidized to acetic acid, which is analyzed by pyrolysis and/or combustion. These methods permit measurement of the natural abundance of ¹³C in the individual carbon atoms of malic acid.     

Reflections on Edsall's carbonic anhydrase: paradoxes of an ultra fast enzyme

John Edsall's investigations of human erythrocyte carbonic anhydrase, a zinc metalloenzyme that powerfully catalyzes the reversible hydration of carbon dioxide, highlighted a conundrum regarding the correct hydration product. The measured kinetic parameters could not be reconciled with the choice of carbonic acid, since its bimolecular recombination rate with enzyme would exceed the diffusion limit. The alternate choice of bicarbonate obviated the recombination rate problem but required that the active site deprotonation exceed the diffusion-limited maximum rate by an even greater extent. This paradox was resolved in favor of bicarbonate when the unsuspected role of buffer species indirectly deprotonating the enzyme was finally proposed, spurring numerous investigations to verify the hypothesis. Edsall's laboratory also reported the accidental discovery of the first competitive inhibitor, imidazole. This opened new avenues to understanding the binding of the CO₂ substrate and stimulated many investigations on this inhibitor. Paramagnetic NMR and crystallographic studies demonstrated that the only other known competitive inhibitor, phenol, apparently shared this unusual binding site. Despite enormous progress since Edsall's retirement, particularly the use of site-directed mutagenesis approaches, the precise interactions of carbon dioxide and bicarbonate with specific active site moieties remain as elusive today as when Edsall first considered these questions.     

Structure of native and apo carbonic anhydrase II and structure of some of its anion-ligand complexes.

In order to obtain a better structural framework for understanding the catalytic mechanism of carbonic anhydrase, a number of inhibitor complexes of the enzyme were investigated crystallographically. The three-dimensional structure of free human carbonic anhydrase II was refined at pH 7.8 (1.54 A resolution) and at pH 6.0 (1.67 A resolution). The structure around the zinc ion was identical at both pH values. The structure of the zinc-free enzyme was virtually identical with that of the native enzyme, apart from a water molecule that had moved 0.9 A to fill the space that would be occupied by the zinc ion. The complexes with the anionic inhibitors bisulfite and formate were also studied at neutral pH. Bisulfite binds with one of its oxygen atoms, presumably protonized, to the zinc ion and replaces the zinc water. Formate, lacking a hydroxyl group, is bound with its oxygen atoms not far away from the position of the non-protonized oxygen atoms of the bisulfite complex, i.e. at hydrogen bond distance from Thr199 N and at a position between the zinc ion and the hydrophobic part of the active site. The result of these and other studies have implications for our view of the catalytic function of the enzyme, since virtually all inhibitors share some features with substrate, product or expected transition states. A reaction scheme where electrophilic activation of carbon dioxide plays an important role in the hydration reaction is presented. In the reverse direction, the protonized oxygen of the bicarbonate is forced upon the zinc ion, thereby facilitating cleavage of the carbon-oxygen bond. This is achieved by the combined action of the anionic binding site, which binds carboxyl groups, the side-chain of threonine 199, which discriminates between hydrogen bond donors and acceptors, and hydrophobic interaction between substrate and the active site cavity. The required proton transfer between the zinc water and His64 can take place through water molecules 292 and 318.     

Role of anions and carbonic anhydrase in epithelia

The existence of carbonic anhydrase (carbonate dehydratase, EC 4.2.1.1) in blood was suspected and sought because the rates of spontaneous hydration and dehydration of CO2 and carbonic acid were slow compared with the rates of exchange of CO2 with blood. The existence of the enzyme in absorbing and secreting epithelial tissues has, in contrast, often been sought because its presence was required for the operations of theoretical models for the movements of H+ ions or HCO-3 into or out of epithelial cells. In addition to the HCl-secreting gastric mucosal epithelium, the enzyme was subsequently found in the rumen, in the kidney, especially those of species that produce acid urine, and salivary gland, the liver and biliary duct system, the mucosa of the small intestine, caecum and colon, the choroid plexuses and ciliary body of mammals, in toad urinary bladder and in the Cl-secreting cells of fish gill. The presence of carbonic anhydrase in exocrine pancreas does not seem to be well established. The enzyme, of molecular mass about 30kDa and containing one zinc atom, exists in three related forms: one of high specific activity and two of low specific activity, one of which is found in red skeletal muscle. Although most, but not all, types of erythrocyte contain both varieties, epithelia usually contain only the high-activity enzyme; however, ox rumen contains large quantities of the low-activity variety as do guinea-pig caecal and colonic mucosae. Salt transport in the intestinal tract is associated with movements of HCO-3 and H+ ions, yet although carbon dioxide stimulates solute and fluid transport in the gall bladder in jejunum, and inhibitors of carbonic anhydrase reduce fluid and ion transport across many epithelia the role of the enzyme in epithelial transport is not clearly understood. Knowledge of the rates of hydration and dehydration of CO2/HCO-3 in the fraction of the tissue water responsible for the H+-HCO-3 movements in many secretory epithelia is currently lacking.     

碳酸酐酶Ⅵ的生理功能与酶缺陷性疾病

碳酸酐酶(carbonic anhydrase,CA)催化可逆的水合反应CO2+H2O?ΗCO3?+H+,参与维持pH值平衡、CO2与离子的转运、细胞凋亡等生理过程。碳酸酐酶VI(CA-VI)作为该类含锌酶中惟一的细胞分泌型碳酸酐酶,在哺乳动物及人的唾液腺、乳腺、泪腺、支气管等腺体中表达,对维持口腔、上消化道和呼吸道的生理功能起重要作用。     

Altered Circadian Period of Locomotor Activity in Carbonic Anhydrase II-Deficient Mice

This study finds lengthened circadian period in a congenic strain of mice homozygous for a null mutation in carbonic anhydrase isoenzyme-II gene on proximal Chromosome 3. Carbonic anhydrase II has the highest turnover rate of any constitutive enzyme. It catalyzes the reversible hydration of carbon dioxide to control intercellular acid/base balance. A strain of congenic mice has a carbonic anhydrase II null mutation within a DBA/2J inbred strain insert on a C57BL/6J inbred strain background. The locomotor activity levels and period of circadian rhythms were examined in the homozygous null mutants and their progenitors, mice heterozygous for the region around the carbonic anhydrase gene. The heterozygous mice siblings and the wild-type siblings served as the controls. During behavioral studies, male and female offspring and parents were housed singly in constant darkness. Locomotor activity was monitored using an infrared photobeam array. Mice homozygous for the carbonic anhydrase null mutation had a longer circadian period than either heterozygote or wild type littermates. Carbonic anhydrase null mutants also had low locomotor activity compared to either heterozygous or wild-type litter mates. This implies that either the physiological changes resulting from absence of carbonic anhydrase II isozyme or the presence of DBA/2J alleles around the carbonic anhydrase locus influence the circadian period and level of locomotor activity in laboratory mice.     

Carbonic anhydrase inhibitors: inhibition of isozymes I, II and IV by sulfamide and sulfamic acid derivatives

Sulfamide and sulfamic acid are the simplest compounds containing the SO2NH2 moiety, responsible for binding to the Zn(II) ion within carbonic anhydrase (CA, EC 4.2.1.1) active site, and thus acting as inhibitors of the many CA isozymes presently known. Here we describe two novel classes of CA inhibitors obtained by derivatizations of the lead molecules mentioned above. The new compounds, possessing the general formula RSO2NH-SO2X (X = OH, NH2), were obtained by reaction of sulfamide or sulfamic acid with alkyl/arylsulfonyl halides or arylsulfonyl isocyanates. A smaller series of derivatives has been obtained by reaction of aromatic aldehydes with sulfamide, leading to Schiff bases of the type ArCH = NSO2NH2. All the new compounds act as strong inhibitors of isozymes I, II and IV of carbonic anhydrase. Their mechanism of CA inhibition is also discussed based on electronic spectroscopic measurements on adducts with the Co(II)-substituted enzyme. These experiments led to the conclusion that the new inhibitors are directly coordinated (in a monodentate manner) to the metal ion within the enzyme active site, similarly to the classical inhibitors, the aromatic/heterocyclic sulfonamides.