Paramagnetic and fluorescent probes attached to "buried" sulfhydryl groups in human carbonic anhydrases. Application to inhibitor binding, denaturation and refolding

The Effect of Nanoparticles on the Structure and Enzymatic Activity of Human Carbonic Anhydrase I and II

Human carbonic anhydrases (hCAs) belong to a well characterized group of metalloenzymes that catalyze the conversion of carbonic dioxide into bicarbonate. There are currently 15 known human isoforms of carbonic anhydrase with different functions and distribution in the body. This links to the relevance of hCA variants to several diseases such as glaucoma, epilepsy, mountain sickness, ulcers, osteoporosis, obesity and cancer. This review will focus on two of the human isoforms, hCA I and hCA II. Both are cytosolic enzymes with similar topology and 60% sequence homology but different catalytic efficiency and stability. Proteins in general adsorb on surfaces and this is also the case for hCA I and hCA II. The adsorption process can lead to alteration of the original function of the protein. However, if the function is preserved interesting biotechnological applications can be developed. This review will cover the knowledge about the interaction between hCAs and nanomaterials. We will highlight how the interaction may lead to conformational changes that render the enzyme inactive. Moreover, the importance of different factors on the final effect on hCAs, such as protein stability, protein hydrophobic or charged patches and chemistry of the nanoparticle surface will be discussed.

Native mass spectrometry of human carbonic anhydrase I and its inhibitor complexes

Abstract

Native mass spectrometry is a potent technique to study and characterize biomacromolecules in their native state. Here, we have applied this method to explore the solution chemistry of human carbonic anhydrase I (hCA I) and its interactions with four different inhibitors, namely three sulfonamide inhibitors (AAZ, MZA, SLC-0111) and the dithiocarbamate derivative of morpholine (DTC). Through high-resolution ESI-Q-TOF measurements, the native state of hCA I and the binding of the above inhibitors were characterized in the molecular detail. Native mass spectrometry was also exploited to assess the direct competition in solution among the various inhibitors in relation to their affinity constants. Additional studies were conducted on the interaction of hCA I with the metallodrug auranofin, under various solution and instrumental conditions. Auranofin is a selective reagent for solvent-accessible free cysteine residues, and its reactivity was analyzed also in the presence of CA inhibitors. Overall, our investigation reveals that native mass spectrometry represents an excellent tool to characterize the solution behavior of carbonic anhydrase.

Graphic abstract

Electronic supplementary material

The online version of this article (10.1007/s00775-020-01818-8) contains supplementary material, which is available to authorized users.

Fluorescent labelling of 6-phosphogluconate dehydrogenase from Bacillus stearothermophilus

The thermophilic 6-phosphogluconate dehydrogenase from Bacillus stearothermophilus was inhibited upon specific modification of the -SH group of cysteine residues by 7-chloro-4-nitrobenzo-2-oxa-1, 3-diazole (NBD-Cl) at pH 7.0. By using 20-100-fold molar excess of NBD-CL the reaction occurs slowly at pH 7.0 as a first order process. Partial protection from inactivation was observed when the substrate 6-phosphogluconate or the coenzyme NADP was added to the reaction mixture. Complete inactivation was achieved upon modification of 1.9 of the six cysteine residues per mole of enzyme, which corresponds to nearly one residue per enzyme subunit. Circular dichroism measurements suggest that the gross structure of the protein molecule is practically unchanged upon reaction of the enzyme with NBD-Cl. Melting profile experiments revealed a single transition occurring at about 65 degrees C. Analogously, the profile of intensity of the fluorescence emission at 520 nm of the enzyme-bound S-NBD groups versus temperature indicated a midpoint of transition near 65 degrees C. Since this melting temperature corresponds closely to that observed with the native enzyme, these results would indicate that the molecular organizations of the native and modified enzyme are similar and stabilized by similar interactions within the polypeptide chain.

Recognition of Secondary Structures in Proteins by a Diiron(III) Complex via a Hydrolytic Pathway

The diiron(III) complex Fe(2)(DTPB)(mu(2)-O)(mu(2)-OAc)Cl(BF(4))(2) [DTPB = 1,1,4,7,7-pentakis(2'-benzimidazol-2-yl-methyl)triazaheptane, OAc = acetate] exhibits a similar affinity for proteins belonging to different structural patterns. However, this diiron complex is sensitive to secondary structures in a protein when it is used to promote the protein hydrolysis, indicating that some metal complexes, such as artificial proteolytic agents, could become a new hydrolytic probe of protein structures.

High-resolution 2D 1H-15N NMR characterization of persistent structural alterations of proteins induced by interactions with silica nanoparticles

The binding of protein to solid surfaces often induces changes in the structure, and to investigate these matters we have selected two different protein-nanoparticle systems. The first system concerns the enzyme human carbonic anhydrase II which binds essentially irreversibly to the nanoparticles, and the second system concerns human carbonic anhydrase I which alternate between the adsorbed and free state upon interaction with nanoparticles. Application of the TROSY pulse sequence has allowed high-resolution NMR analysis for both of the protein-nanoparticle systems. For HCAII it was possible to observe spectra of protein when bound to the nanoparticles. The results indicated that HCAII undergoes large rearrangements, forming an ensemble of molten globule-like structures on the surface. The spectra from the HCAI-nanoparticle system are dominated by HCAI molecules in solution. A comparative analysis of variations in intensity from 97 amide resonances in a 1H-15N TROSY spectrum revealed the effects from interaction with nanoparticle on the protein structure at amino acid resolution.

Protein adsorption onto silica nanoparticles: conformational changes depend on the particles' curvature and the protein stability

We have analyzed the adsorption of protein to the surfaces of silica nanoparticles with diameters of 6, 9, and 15 nm. The effects upon adsorption on variants of human carbonic anhydrase with differing conformational stabilities have been monitored using methods that give complementary information, i.e., circular dichroism (CD), nuclear magnetic resonance (NMR), analytical ultracentrifugation (AUC), and gel permeation chromatography. Human carbonic anhydrase I (HCAI), which is the most stable of the protein variants, establishes a dynamic equilibrium between bound and unbound protein following mixture with silica particles. Gel permeation and AUC experiments indicate that the residence time of HCAI is on the order of approximately 10 min and slowly increases with time, which allows us to study the effects of the interaction with the solid surface on the protein structure in more detail than would be possible for a process with faster kinetics. The effects on the protein conformation from the interaction have been characterized using CD and NMR measurements. This study shows that differences in particle curvature strongly influence the amount of the protein's secondary structure that is perturbed. Particles with a longer diameter allow formation of larger particle-protein interaction surfaces and cause larger perturbations of the protein's secondary structure upon interaction. In contrast, the effects on the tertiary structure seem to be independent of the particles' curvature.

High-resolution probing of local conformational changes in proteins by the use of multiple labeling: unfolding and self-assembly of human carbonic anhydrase II monitored by spin, fluorescent, and chemical reactivity probes

Two different spin labels, N-(1-oxyl-2,2,5,5-tetramethyl-3-pyrrolidinyl)iodoacetamide (IPSL) and (1-oxyl-2,2,5,5-tetramethylpyrroline-3-methyl) methanethiosulfonate (MTSSL), and two different fluorescent labels 5-((((2-iodoacetyl)amino)-ethyl)amino)naphtalene-1-sulfonic acid (IAEDANS) and 6-bromoacetyl-2-dimetylaminonaphtalene (BADAN), were attached to the introduced C79 in human carbonic anhydrase (HCA II) to probe local structural changes upon unfolding and aggregation. HCA II unfolds in a multi-step manner with an intermediate state populated between the native and unfolded states. The spin label IPSL and the fluorescent label IAEDANS reported on a substantial change in mobility and polarity at both unfolding transitions at a distance of 7.4-11.2 A from the backbone of position 79. The shorter and less flexible labels BADAN and MTSSL revealed less pronounced spectroscopic changes in the native-to-intermediate transition, 6.6-9.0 A from the backbone. At intermediate guanidine (Gu)-HCl concentrations the occurrence of soluble but irreversibly aggregated oligomeric protein was identified from refolding experiments. At approximately 1 M Gu-HCl the aggregation was found to be essentially complete. The size and structure of the aggregates could be varied by changing the protein concentration. EPR measurements and line-shape simulations together with fluorescence lifetime and anisotropy measurements provided a picture of the self-assembled protein as a disordered protein structure with a representation of both compact as well as dynamic and polar environments at the site of the molecular labels. This suggests that a partially folded intermediate of HCA II self-assembles by both local unfolding and intermolecular docking of the intermediates vicinal to position 79. The aggregates were determined to be 40-90 A in diameter depending on the experimental conditions and spectroscopic technique used.

Pyrene excimer fluorescence as a proximity probe for investigation of residual structure in the unfolded state of human carbonic anhydrase II

The excimer fluorescence from two pyrenyl moieties attached to cysteines in human carbonic anhydrase II has been monitored to characterize residual structure retained under strong denaturing conditions. A position in beta-strand 3, N67C, together with the single naturally occurring cysteine 206 in beta-strand 7, were used as attachment sites. The eximer formation by the pyrenyls, requiring proximity of the probes, revealed an unfolding transition at a GuHCl concentration significantly higher than that required to induce unfolding of the molten globule state as monitored by CD. These results indicate that the excimer transition monitors the unfolding of a residual compact structure that spans beta-strands 3-7. This region constitutes the central and the most hydrophobic part of the molecule, emphasizing the importance of hydrophobic interaction in maintaining residual structure under strong unfolding conditions.

Kinetics and motional dynamics of spin-labeled yeast iso-1-cytochrome c: 1. Stopped-flow electron paramagnetic resonance as a probe for protein folding/unfolding of the C-terminal helix spin-labeled at cysteine 102

The kinetics of chemically induced folding and unfolding processes in spin-labeled yeast iso-1-cytochrome c were measured by stopped-flow electron paramagnetic resonance (EPR). Stopped-flow EPR, based on a new dielectric resonator structure [Sienkiewicz, A., Qu, K., & Scholes, C. P. (1994) Rev. Sci. Instrum. 65, 68-74], gives a new temporal component to probing nanosecond molecular tumbling motions that are modulated by macromolecular processes requiring time resolution of milliseconds to seconds. The stopped-flow EPR technique presented in this work is a kinetic technique that has not been previously used with such a time resolution on spin-labeled systems, and it has the potential for application to numerous spin-labeled sites in this and other proteins. The cysteine-specific spin-label, methanethiosulfonate spin-label (MTSSL), was attached to yeast iso-1-cytochrome c at the single naturally occurring cysteine102, and the emphasis for this work was on this disulfide-attached spin-labeled prototype. This probe has the advantage of reflecting the protein tertiary fold, as shown by recent, systematic site-directed spin labeling of T4 lysozyme [Mchaourab, H. S. Lietzow, M. A., Hideg, K., & Hubbell, W. L. (1996) Biochemistry 35, 7692-7704], and protein backbone dynamics, as also shown by model peptide studies [Todd, A. P., & Millhauser, G. L. (1991) Biochemistry 30, 5515-5523]. The C-terminal cytochrome c helix where the label is attached is thought to be critical in the initial steps of protein folding and unfolding. Stopped-flow EPR resolved the monoexponential, guanidinium-induced unfolding process at pH 6.5 with an approximately 20 ms time constant; this experiment required less than 150 microL of 80 microM spin-labeled protein. We observed an approximately 50-fold decrease of this unfolding time from the 1 s range to the 20 ms time range as the guanidinium denaturant concentration was increased from 0.6 to 2.0 M. The more complex refolding kinetics of our labeled cytochrome were studied by stopped-flow EPR at pH 5.0 and 6.5. The spin probe showed a fast kinetic process compatible with the time range over which hydrogen/deuterium amide protection indicates helix formation; this process was monoexponential at pH 5.0. At pH 6.5, there was evidence of an additional slower kinetic phase resolved by stopped-flow EPR and by heme-ligation-sensitive UV-Vis that indicated a slower folding where heme misligation may be involved. Since the disulfide-attached probe has reported folding and backbone dynamics in other systems, the implication is that our kinetic experiments were directly sensing events of the C-terminal helix formation and possibly the N- and C-terminal helical interaction. The cysteine-labeled protein was also studied under equilibrium conditions to characterize probe mobility and the effect of the probe on protein thermodynamics. The difference in spin probe mobility between folded and denatured protein was marked, and in the folded protein, the motion of the probe was anisotropically restricted. The motion of the attached nitroxide in the folded protein appears to be restricted about the carbon and sulfur bonds which tether it to the cysteine. The original point of cysteine sulfur attachment is approximately 11 A from the heme iron within the C-terminal helix near its interface with the N-terminal helix, but the low-temperature EPR spin probe line width showed that the probe lies more distant (> 15 A) from the heme iron. By all physical evidence, the protein labeled at cysteine102 folded, but the spin probe in this prototype system perturbed packing which lowered the thermal melting temperature, the free energy of folding, the guanidinium concentration at the midpoint of the unfolding transition, the m parameter of the denaturant, and the helical CD signature. This study prepares the way for study of protein folding/unfolding kinetics using EPR spectroscopy of spin-labels placed at specific cysteine-mutated sites within

A comparative CD study of carbonic anhydrase isoenzymes with different number of tryptophans: impact on calculation of secondary structure content

The CD spectra of human carbonic anhydrase I and II and bovine carbonic anhydrase III were recorded and analyzed. The 3D structures of these isoenzymes are known, showing very similar secondary structure and polypeptide-chain fold. The tryptophan content, however, differs between the isoenzymes, i.e., isoenzymes I, II, and III possess 6, 7, and 8 tryptophans, respectively. All of the tryptophans except the additional tryptophans in isoenzymes II and III, i.e., W245 and W47, are conserved. Despite the fact that X-ray structure determinations showed that the isoenzymes had highly similar secondary structure, the contents of alpha-helix and beta-sheet structure differed considerably when using different CD algorithms for estimation of the fractions of various secondary structural elements. This shows that aromatic amino acids also interfere in the wavelength region (far-UV) used to calculate the amount of secondary structure. Such interference is especially problematic when analyzing proteins like carbonic anhydrase, which consist mainly of beta-structure that gives rise to weak ellipticity bands, compared to the bands arising from alpha-helical structure.

Folding of beta-sheet proteins

In the past year, interesting new information concerning various aspects of the folding process of beta-sheet proteins has been gleaned. Kinetic and equilibrium folding intermediates have been characterized. Studies of extensively denatured states and of model peptide fragments have enabled important steps to be taken towards an understanding of the initiation of the folding process of beta-sheet proteins. Site-directed mutagenesis has been used in combination with various probes to monitor folding events.

Characterization of a folding intermediate of human carbonic anhydrase II: probing local mobility by electron paramagnetic resonance

The spin-labeling method was used to investigate human carbonic anhydrase, HCA II, undergoing unfolding induced by guanidine-HCI (Gu-HCI). The spin-probe, N-(2,2,5,5-tetramethyl-1-yloxypyrrolidinyl-3-yl)iodoacetamide, was attached covalently to the single cysteine (position 206) in the enzyme. The electron paramagnetic resonance spectrum of the folded structure showed the characteristic slow motional spectra. When the concentration of the denaturing agent, Gu-HCI, was gradually increased, new spectral components with narrower lines evolved to give complex electron paramagnetic resonance spectra, apparently containing superimposed contributions from several components of different mobility. By a differentiation technique, it was possible to follow the relative increase of the narrow components as a function of Gu-HCI concentration. The amplitude of difference spectra versus Gu-HCI concentration showed two distinct maxima, indicating the existence of a folding intermediate state/structure. The results were found to agree with optical absorption data, which showed similar transitions at the same Gu-HCI concentrations. From line-shape simulations assuming a Brownian diffusion model, the rotational diffusion constants for the spin-label in the folded, folding intermediate, and unfolded structures were determined. The relative abundances of the three conformations in the region 0-4 M Gu-HCI were obtained by least squares fitting of the simulated spectra to the experimental ones. The folding intermediate was found to have a maximum population of 39 +/- 4% at approximately 0.7 M Gu-HCI.

Isomerase and chaperone activity of prolyl isomerase in the folding of carbonic anhydrase

Several proteins have been discovered that either catalyze slow protein-folding reactions or assist folding in the cell. Prolyl isomerase, which has been shown to accelerate rate-limiting cis-trans peptidyl-proline isomerization steps in the folding pathway, can also participate in the protein-folding process as a chaperone. This function is exerted on an early folding intermediate of carbonic anhydrase, which is thereby prevented from aggregating, whereas the isomerase activity is performed later in the folding process.

Cis-trans isomerization is rate-determining in the reactivation of denatured human carbonic anhydrase II as evidenced by proline isomerase

The refolding of human carbonic anhydrase II is a sequential process. The slowest step involved is the recovery of enzymic activity (t1/2 = 9 min). Kinetic data from 'double-jump' measurements indicate that proline isomerization might be rate determining in the reactivation of the denatured enzyme. Proof of this is provided by the effect of proline isomerase on the reactivation kinetics: the presence of isomerase during reactivation lowers the half-time of the reaction to 4 min, and inhibition of proline isomerase completely abolishes this kinetic effect. A similar acceleration of the refolding process by proline isomerase is also observed for bovine carbonic anhydrase II, in contrast to what has previously been reported. In human carbonic anhydrase II there are two cis-peptidyl-Pro bonds at Pro30 and Pro202. Two asparagine single mutants (P30N and P202N) and a glycine double mutant (P30G/P202G) were constructed to investigate the role of these prolines in the rate limitation of the reactivation process. Both in the presence and absence of PPIase the P202N mutant behaved exactly like the unmutated enzyme. Thus, cis-trans isomerization of the Pro202 cis-peptidyl bond is not rate determining in the reactivation process. The mutations at position 30 led to such extensive destabilization of the protein that the refolding reaction could not be studied.

Transfer of oxygen from an artificial protease to peptide carbon during proteolysis

Site-specific cleavage of proteins with metal chelates is an approach for designing artificial proteolytic reagents that are directed by proximity to a peptide bond rather than by an amino acid residue type. In the presence of ascorbate and H2O2, an iron chelate attached to Cys-212 of the enzyme human carbonic anhydrase I quickly cleaved the protein between residues Leu-189 and Asp-190 to produce two discrete fragments. The transfer of an 18O atom from [18O]H2O2 (or [18O]O2) to the carboxyl group of Leu-189 was demonstrated by mass spectrometry. Quantitative experiments revealed that one molecule of H2O2 and one molecule of ascorbate afforded the hydrolysis of one peptide bond (1:1:1 stoichiometry) and that the reaction required ascorbate and H2O2. The process is catalytic, since related experiments on the protein bovine serum albumin revealed two cleavage events for each polypeptide chain cleaved. Hydroxyl radical scavengers had no significant effect. These results may be explained by generation of a highly nucleophilic oxygen species, such as peroxide coordinated to the iron chelate, that attacks a carbonyl carbon nearby.

Folding around the C-terminus of human carbonic anhydrase II. Kinetic characterization by use of a chemically reactive SH-group introduced by protein engineering

We are characterizing the process of refolding of the enzyme human carbonic anhydrase II from the denatured state in guanidine hydrochloride. To describe the folding in defined parts of the protein we use protein engineering to introduce cysteine residues as unique chemically reactive probes. The accessibility of the cysteine SH-group to the alkylating reagent iodoacetate, at different stages during refolding, is used to give a kinetic description of the folding process. The structuration of the C-terminal part of the polypeptide chain, which is involved in a unique 'knot' topology, was investigated. Our results show that the structure around the C-terminal, composed of the outermost beta-strands in a dominating beta-structure that extends through the entire protein, is formed relatively late during refolding. In contrast, it was found that beta-strands located in the interior of the protein were structured very rapidly. The final native structure is formed in a process that is slower than those observed for formation of beta-structure.

The role of the metal ion in the refolding of denatured bovine Co(II)-carbonic anhydrase II

Conditions for reactivation of guanidine-HCl-denatured bovine Co(II)-carbonic anhydrase II are given. The renaturation is accompanied by recovery of the native Co(II)-spectrum of the enzyme. After studying the kinetics of the renaturation process, the metal ion involvement in the refolding pathway can be summarized as follows: (1) Formation of an inactive Co(II)-intermediate with the metal ion firmly bound. No native Co(II)-spectrum is observed in this state, probably due to octahedral coordination of the metal ion in this intermediate. (2) Formation of an inactive Co(II)-intermediate with a native Co(II)-spectrum. The final tetrahedral coordination of the metal ion seems to have been formed in this state. (3) Formation of the active conformation of the enzyme. A functioning active-site is formed after some rearrangements of the polypeptide chain. This isomerisation step does not need to be preceded by formation of the intermediate with a native Co(II)-spectrum. Coordination of Co2+ in a native-like manner is, however, a prerequisite for enzymic activity. It is tentatively suggested that the metal ion is involved in stabilizing a nucleation structure formed at the bottom of the active centre. This probably occurs through binding of Co2+ to some or all of its histidyl ligands in this region after an early structuration of the metal ion binding site. The mechanisms of Co2+ appear to be similar for the refolding enzyme and the native apoenzyme, inferring that the binding site formed as a result of the nucleation process probably has the same structure as in the native conformation.

Evidence for an initial fast nucleation process in the folding of human carbonic anhydrase I

Kinetic studies of the folding of carbonic anhydrase have indicated the occurrence of various conformational intermediates. Human carbonic anhydrase I contains a single cysteine residue, Cys-212, which in the native state is unavailable for alkylation. In the unfolded state, it can be specifically modified with iodoacetate. In this study the accessibility of Cys-212 in human carbonic anhydrase I to iodo[2-14C]acetate during the refolding process has been investigated. It is shown that Cys-212 is hidden to the alkylating agent as soon as the refolding is initiated. Since Cys-212 is located in the extensive beta-structure passing through the enzyme, it appears that the Cys-containing beta-strand is part of a rapidly formed nucleation center created during the folding process. This beta-strand (No. 7) together with its neighboring beta-strand (No. 6) constitute the most hydrophobic regions of the enzyme. Because hydrophobic contacts are considered to be important in predicting nucleation sites, these beta-strands probably partake in the formation of the nucleation center. These beta-strands are also partly involved in the bottom region of the active site cavity, indicating that this region is formed during the initial folding events. As a result of this study it was also observed that 2-mercaptoethanol is a potent inhibitor of the enzyme with a K1 = 26 microM at pH 8.0.

Influence of solvent conditions on refolding of bovine serum albumin

The effect of solvent conditions on the refolding of bovine serum albumin was studied. The rate and extent of refolding was affected by the type of monovalent salt used in the medium. While NaCl and NaBr promoted refolding, NaClO4 and NaSCN decreased the rate and extent of refolding at 0.2 M concentration. In this respect the relative order in which various anions influenced the refolding process followed the lyotropic series Cl-, Br-, I-, ClO4-, SCN-. Urea exhibited two opposite effects on the refolding of albumin: whereas at low concentrations urea increased the extent of refolding, at concentrations above 2.0 M the rate and extent of refolding were dramatically decreased. Addition of ethanol to the medium greatly decreased the refolding even at concentrations as low as 4% (v/v). The effects of these various additives on the refolding behavior of serum albumin is interpreted in terms of subtle changes in the structure of water. It is also shown that, while such changes in the solvent structure affected the rate and extent of refolding, they did not affect the pathway of refolding.

Activation of bovine muscle carbonic anhydrase by modification of thiol groups

Two of the five cysteine residues in bovine muscle carbonic anhydrase (isoenzyme III) react rapidly and stoichiometrically with Ellman's reagent without effect on the CO2 hydration activity. These residues, which can be alkylated with iodoacetamide, have been identified as Cys-183 and Cys-188. Treatment of the enzyme with a large excess of Ellman's reagent results in additional derivatization of thiol groups and a 180% increase of the CO2 hydration activity. The cysteine residues associated with this activation are Cys-66 as well as Cys-203 and/or Cys-206. Activation has also been achieved with 2,2'-dithiodipyridine (120%) and with methyl methanethiosulfonate (approx. 400%), whereas no activation could be obtained with iodoacetamide, iodoacetate or N-ethylmaleimide.

The molten globular intermediate form in the folding pathway of human carbonic anhydrase B

The acid-induced and guanidinium chloride-induced conformational transitions in human carbonic anhydrase B have been analyzed. A structural form was detected at pH 3, which has a higher secondary structural order than the native enzyme but little tertiary structure. The enzyme dissolved in an intermediate concentration of the denaturant guanidinium chloride (1 M at pH 7.5) also adopts a similar conformational state. This form, denoted as the intermediate form I, possesses most of the characteristics defined for the molten globular state of globular proteins and might serve as the embryonic structural intermediate during the self-organization of the protein into its functional native form.

Catalytic properties and inhibition of Cd2+-carbonic anhydrases

Cd2+ derivatives of human carbonic anhydrases I and II and bovine red cell carbonic anhydrase (carbonate hydro-lyase, EC 4.2.1.1) have been prepared. The metal ion in these derivatives is readily displaced by Zn2+. The Cd2+-carbonic anhydrases have appreciable 4-nitrophenyl acetate hydrolase activities. These activities increase with pH as if dependent on the basic form of a group with pKa near 10. The Cd2+-carbonic anhydrases also have significant CO2 hydration activities. The Cd2+ derivatives are strongly inhibited by monovalent anions. In particular, I- is a much more potent inhibitor of the Cd2+ enzymes than of the native enzymes. Acetazolamide (5-acetylamido-1,3,4-thiadiazole 2-sulfonamide) is also a strong inhibitor although its affinity for the Cd2+ enzyme is less than its affinity for the native enzyme.

'Molten-globule' state accumulates in carbonic anhydrase folding

Kinetics of folding and unfolding of bovine carbonic anhydrase B were monitored by circular dichroism, viscometry and esterase activity. It was shown that kinetic intermediate states accumulating in folding process reveal a native-like compactness and secondary structure but have a symmetrized average environment of aromatic side groups and no esterase activity. These properties allow one to consider these intermediate states as the 'molten-globule' state of a protein molecule previously described by us for several equilibrium forms of bovine and human alpha-lactalbumins and bovine carbonic anhydrase B.

Renaturation studies of free and immobilized D-amino-acid oxidase

The renaturation of free and Sepharose-immobilized D-amino-acid oxidase (D-amino-acid:oxygen oxidoreductase (deaminating), EC 1.4.3.3), after its denaturation with 6 M guanidine hydrochloride, was investigated. No reactivation, or extremely limited reactivation (less than or equal to 4+), was obtained with the free enzyme, is spite of various attempts including the use of dialysis or buffers containing cofactors, different types of anions, surfactants and low concentrations of denaturing agents. The main obstacle to renaturation appeared to be the interaction among denatured or partially renatured monomers giving rise to inactive aggregates. In contrast, using the immobilized enzyme approach, substantial renaturation (up to 50%) of D-amino-acid oxidase was achieved. The denaturation-renaturation process was followed by monitoring the catalytic activity as well as the intrinsic protein fluorescence. An inverse correlation was found to exist between the degree of matrix activation by CNBr and the yield of enzyme reactivation. The anions of the lyotropic series markedly influenced the reactivation, showing an effectiveness opposite to their salting-out potential (thiocyanate congruent to iodide greater than chloride greater than phosphate congruent to sulphate congruent to citrate). Instead, the anions considerably increased the activity and stability of free and immobilized enzyme, according to their salting-out potential. Immobilized monomers of D-amino-acid oxidase, which in solution undergoes self-association, showed poor capacity to interact with the free enzyme: thus they appear unsuitable for analytical and preparative purposes.

Characterization of reactivation produces from human carbonic anhydrase I denatured in various concentrations of guanidine hydrochloride

Denaturation in 1.7 M guanidine hydrochloride (Gnd-HCl), thermostability tests, immunological tests and polyacrylamide-gel electrophoresis were performed on the products of reactivation from human carbonic anhydrase I (CA I), initially denatured in various concentrations of Gnd-HCl. Reactivated protein from CA I denatured in 2 M Gnd-HCl exhibited different thermostability and immunological properties from the products of other Gnd-HCl concentrations. The CA I denatured in 2 M Gnd-HCl was found to be more heat stable and achieved complete inhibition at an antibody concentration one-fourth that of the other Gnd-HCl denaturation concentrations. These data suggest that 2 M Gnd-HCl produces a reactivation product with a different tertiary structure from 5 M or 0.5 M Gnd-HCl.

Reaction of chicken egg white lysozyme with 7-chloro-4-nitrobenz-2-oxa-1,3-diazole. II. Sites of modification

1. Procedure for the isolation of peptides from proteins bearing the chemically labile aromatic ether, O-tyrosyl-4-nitrobenz-2-oxa-1,3-diazole group, is described. 2. The tyrosyl residue reactive towards 7-chloro-4-nitrobenz-2-oxa-1,3-diazole in chicken egg white lysozyme (Aboderin, A. A., Boedefeld, E. and Luisi, P. L., (1973) Biochim. Biophys. Acta 328. 20-30) is tyrosine-23. The amino group in the protein whose reaction with the reagent is dependent on the prior reaction of tyrosine-23 is the epsilon-amino group of lysine-33.