Hydrolysis of peptides by carboxypeptidase A: equilibrium trapping of the ES2 intermediate

The cobalt absorption and electron paramagnetic resonance (EPR) spectra of cobalt carboxypeptidase undergo unique variations on formation of catalytic peptide and ester intermediates as previously recorded in cryoenzymologic experiments employing rapid-scanning spectroscopy and cryotrapping [Geoghegan, K. F., Galdes, A., Martinelli, R. A., Holmquist, B., Auld, D.S., & Vallee, B. L. (1983) Biochemistry 22, 2255-2262]. We here describe a means of stabilizing these intermediates, which we have termed "equilibrium trapping". It allows peptide intermediates to be observed for longer periods (much greater than 1 min) at ambient as well as subzero temperatures. The reaction intermediate with the rapidly turned over peptide substrate Dns-Ala-Ala-Phe is trapped when the cobalt enzyme (greater than 10 microM) has catalyzed the attainment of chemical equilibrium between high concentrations of the hydrolysis products Dns-Ala-Ala, 10 mM, and L-phenylalanine, 50 mM, and the product of their coupling Dns-Ala-Ala-Phe. Under these conditions, Dns-Ala-Ala-Phe is present in the equilibrated substrate-product reaction mixture at a level that exceeds the one predicted on the basis of K'eq for hydrolysis of this substrate and is close to the enzyme concentration. Other pairs of peptide hydrolysis products yield similar results. Visible absorption and EPR spectra of the cobalt enzyme show that the synthesized peptide binds to the active site in the mode previously recognized as the ES2 catalytic intermediate in peptide hydrolysis. Equilibrium trapping of the ES2 intermediate allows analysis of its physicochemical properties by methods that could not be employed readily under cryoenzymological conditions, e.g., circular dichroic and magnetic circular dichroic spectra.(ABSTRACT TRUNCATED AT 250 WORDS)     

Preparation and spectroscopic studies of cobalt(II)-substituted cucumber basic blue protein "plantacyanin"

The cobalt(II) derivative of cucumber basic blue copper protein "plantacyanin" has been prepared. The visible absorption, circular dichroic and magnetic circular dichroic spectra of Co(II)-plantacyanin are similar to those of Co(II)-plastocyanin, indicating that the stereochemistry of Co(II) is tetrahedral and at least one cysteinyl ligand around Co(II) ion is responsible for the strong charge transfer bands at 331 and ca. 390 nm.     

Electronic spectroscopy of cobalt angiotensin converting enzyme and its inhibitor complexes

Zinc, the catalytically essential metal of angiotensin converting enzyme (ACE), has been replaced by cobalt(II) to give an active, chromophoric enzyme that is spectroscopically responsive to inhibitor binding. Visible absorption spectroscopy and magnetic circular dichroic spectropolarimetry have been used to characterize the catalytic metal binding site in both the cobalt enzyme and in several enzyme-inhibitor complexes. The visible absorption spectrum of cobalt ACE exhibits a single broad maximum (525 nm) of relatively low absorptivity (epsilon = 75 M-1 cm-1). In contrast, the spectra of enzyme-inhibitor complexes display more clearly defined maxima at longer wavelengths (525-637 nm) and of markedly higher absorptivities (130-560 M-1 cm-1). The large spectral response indicates that changes in the cobalt ion coordination sphere occur on inhibitor binding. Magnetic circular dichroic spectropolarimetry has shown that the metal coordination geometry in the inhibitor complexes is tetrahedral and of higher symmetry than in cobalt ACE alone. The presence of sulfur----cobalt charge-transfer bands in both the visible absorption and magnetic circular dichroic spectra of the cobalt ACE-Captopril complex confirm direct ligation of the thiol group of the inhibitor to the active-site metal.     

Effects of mechanism-based reversible inhibitors on the metal environment of cobalt(II)carboxypeptidase A: an electronic spectral study

Electronic absorption, circular dichroic (CD), and magnetic circular dichroic (MCD) spectra have been determined for complexes of cobalt(II)-substituted carboxypeptidase A and five reversible inhibitors. Three of the inhibitors, N-(1-carboxy-5-butyloxycarbonylaminopentyl)-L-phenylalanine, (I); (R,S)-2-benzyl-4-oxobutanoic acid, (III); and 2-benzyl-4-oxo-5,5,5-trifluoropentanoic acid, (IV) are mechanism-based inhibitors. Another, N-(1-carboxy-5-carbobenzoxyaminopentyl)-glycyl-L-phenylalanine, (II), is a tight binding, slowly hydrolyzed substrate. The fifth, phosphoramidon, (V), is a mechanism-based inhibitor of thermolysin, and may also bind to carboxypeptidase in a mechanism-based mode. The absorption and CD spectra of the enzyme-inhibitor complexes all differ from the spectrum of the free enzyme and from each other. The MCD spectra indicate that the tetrahedral coordination geometry of cobalt, which is distorted in the free enzyme, is also distorted in the inhibitor complexes, although to various degrees. The complexes of I and III are spectrally similar despite being structurally dissimilar, and that of IV, whose structure resembles III, is spectrally distinct, indicating that I and III, but not IV, may perturb the metal in nearly the same way. The absorption spectrum of IV is identical to that, at high pH, of Co(II)carboxypeptidase in which Glu-270 has been modified by a carbodiimide reagent, possibly pointing to a common perturbation of this residue. The absorption and CD spectra of II are similar to those of the catalytic intermediate that precedes the rate-limiting step in peptide hydrolysis [D. S. Auld, A. Galdes, K. F. Geoghegan, B. Holmquist, R. Martinelli, and B. L. Vallee, Proc. Natl. Acad. Sci. USA 81, 4675-4681 (1984)]. Since II is a substrate, the steady-state bound species that it generates may therefore be a true productive intermediate rather than a nonproductive mimic of an intermediate. The spectra of the complexes with II and V differ considerably despite structural similarities. The negative CD ellipticity of the free enzyme is reversed in sign in the presence of V, a phenomenon previously observed with complexes of Co(II)carboxypeptidase and dipeptides. This resemblance may result from a similar interaction of cobalt with the phosphoramidate group of phosphoramidon and the N-terminal amine of dipeptides. The spectra of reversible, mechanism-based inhibitors permit general structural predictions about true intermediates but require caution when used for assigning precise conformation and ligands of bound catalytic species.     

Circular Dichroic Spectrum of the L Form and the Blue Light Product of the M Form of Purple Membrane

Simultaneously measured low temperature absorption and circular dichroic spectra are presented for different intermediates of the bacteriorhodopsin photocycle in suspension and hydrated film of purple membranes. The data for the L intermediate are in accord with excitonic interpretation of the visible part of the circular dichroic spectrum, suggesting that no large scale structural change of the purple membrane affecting its crystalline structure happens during the L formation. The structure of the membrane, which is disrupted in the M state, is recovered when M is illuminated with blue light at low temperature.     

Cryoenzymology of Bacillus cereus beta-lactamase II

The effects of cryosolvents and subzero temperatures on the metalloenzyme beta-lactamase II from Bacillus cereus have been investigated. Preliminary experiments led to the selection of suitable systems for the study of beta-lactamase II catalysis at low temperatures, namely, cobalt(II) beta-lactamase II hydrolysis of benzylpenicillin in 60% (v/v) ethylene glycol and zinc beta-lactamase II hydrolysis of the chromophoric cephalosporin nitrocefin in 60% (v/v) methanol. Progress curves for the hydrolysis of benzylpenicillin by cobalt beta-lactamase II in 60% (v/v) ethylene glycol at temperatures below -30 degrees C consisted of a transient followed by a steady-state phase. The amplitude of the transient implied a burst whose magnitude was greater than the concentration of enzyme, and the proposed mechanism comprises a branched pathway. The kinetics for the simplest variants of such pathways have been worked out, and the rate constants (and activation parameters) for the individual steps have been determined. The spectrum of the enzyme changed during turnover: when benzylpenicillin was added to cobalt beta-lactamase II, there was a large increase in the cysteine-cobalt(II) charge-transfer absorbance at 333 nm. This increase occurred within the time of mixing, even at -50 degrees C. The subsequent decrease in A333 was characterized by a rate constant that had the same value as the "branching" rate constant of the branched-pathway mechanism. This step is believed to be a change in conformation of the enzyme-substrate complex. Single-turnover experiments utilized the change in A333, and the results were consistent with pre-steady-state and steady-state experiments. When a single-turnover experiment at -48 degrees C was quenched with acid, the low molecular weight component of the intermediate was shown to be substrate. The mechanism advanced for the hydrolysis of benzylpenicillin by cobalt beta-lactamase II involves two noncovalent enzyme-substrate complexes that have been characterized by their electronic absorption spectra. When manganese beta-lactamase II was used, the same features (implying a branched pathway) were evident; these experiments were carried out at ordinary temperatures and did not utilize a cryosolvent. The hydrolysis of nitrocefin by zinc beta-lactamase II has been studied concurrently in 60% (v/v) methanol. Progress curves were triphasic. There were two transients preceding the linear steady-state phase. The stoichiometry of the burst again implied a branched pathway.(ABSTRACT TRUNCATED AT 400 WORDS)     

Structural and electronic mimics of the active site of cobalt(II)-substituted zinc metalloenzymes

Complexes of cobalt(II) and zinc(II) which involve monodentate coordination of two alkyl carboxylate and two imidazole ligands in a slightly distorted tetrahedral fashion have visible and magnetic circular dichroism spectra remarkably similar to the cobalt(II)-substituted proteolytic enzymes thermolysin and carboxypeptidase A. Single crystal x-ray structure determinations on [Co(C₂H₅COO)₂Im₂], Im = imidazole, and its zinc counterpart reveal only minor structural differences between the cobalt and zinc species. Electron paramagnetic resonance spectra of cobalt(II) doped into zinc(II) complexes with known structures demonstrate the extreme sensitivity of the g-values to minor structural differences.     

On the various types of circular dichroism induced on acridine orange bound to poly(S-carboxymethyl-L-cysteine).

Circular dichroism and absorption spectra are measured on mixed solutions of acridine orange and poly(S-carboxymethyl-L -cysteine) at different pH and P/D mixing ratios. The observed circular dichroism spectra are classified into several types, mainly based on the number and sign of circular dichroic bands in the visible region. Three of them are associated with the absorption spectra characteristic of dimeric dye or higher aggregates of dye. Type I is observed with solutions, of which the pH is acid and P/D is higher than 4, and it has an unsymmetrical pair of positive and negative dichroic bands at 470 and 430 nm. This type is induced on the dye bound to the polymer in the β-conformation. Types II and III are considered to be characteristic of randomly coiled polymers. Type II is exhibited by solutions of P/D higher than 1 at pH 5–7 and has two dichroic bands around the same wavelengths as Type I but with opposite signs and an additional positive band at 560 nm. Type III, shown by solutions of P/D 2–0.6 at pH 6–10.5, has three dichroic bands around the same wavelengths as Type II but with signs opposite to it. The other two types of circular dichroism, induced for the solutions of P/D less than 1 at slightly acid pH, are associated with the absorption spectra of monomeric dye and are observed with disordered or randomly coiled polymer. They have a pair of dichroic bands at 540 and 425 nm, and the signs of these bands are opposite to each other in these two types.     

Cryoenzymology of staphylococcal beta-lactamase: trapping a serine-70-linked acyl-enzyme

Various cryosolvents were investigated for their suitability in cryoenzymological experiments with beta-lactamase from Staphylococcus aureus PC1. On the basis of the minimal effects on the catalytic and structural properties of the enzyme, ternary solvents containing ethylene glycol, methanol, and water were found most suitable. The interaction of beta-lactamase with a number of substrates was studied at subzero temperatures. In general, the reaction profiles were similar to those in aqueous solution at above-zero temperatures, with the exception of the slower rates. For cephalosporin substrates, such as PADAC, in which the 3'-substituent may leave to form a more stable form of the acyl-enzyme [Faraci, W., & Pratt, R. (1985) Biochemistry 24, 903-910], this intermediate could be readily stabilized at subzero temperatures. At -40 degrees C the slow rate of deacylation in the reaction with the chromophoric substrate 6 beta-[(furylacryloyl)amino]penicillanic acid permitted the acyl-enzyme to be stoichiometrically accumulated. This intermediate was then stabilized at low pH with trifluoroacetic acid. Isolation by centrifugal gel filtration, followed by pepsin digestion, gave a penicilloyl-labeled peptide which was isolated by HPLC. Subsequent trypsinolysis of this peptide gave a single labeled peptide, corresponding to the octapeptide surrounding the active-site serine, Ser-70.     

Magnetic circular dichroic spectra of cobalt(II) substituted metalloenzymes.

The magnetic circular dichroic (MCD) spectra of cobalt(II) sugstituted metalloenzymes have been studied and compared to a series of four-, five-, and six-coordinate cobalt(II) model complexes previously examined (T. A. Kaden et al. (1974), Inorg. Chem. 13, 2582). The MCD spectra of cobalt substituted carboxypeptidase A, procarboxypeptidase ta, and thermolysin are consistent with earlier deductions of tetrahedral coordination from absorption spectra and also with X-ray structure analysis. Inhibitors fail to alter their MCD spectra significantly. The MCD spectra of cobalt alkaline phosphatase and carbonic anhydrase are more complex and their pH dependence and alteration by inhibitors are discussed in terms of known cobalt(II) models.     

Spectral studies of cobalt (II)- and Nickel (II)-metallothionein

The zinc and cadmium of native rabbit metallothionein-1 were replaced stoichiometrically with either cobalt (II) or nickel (II). The electronic, magnetic circular dichroic (MCD), and electron spin resonance spectra of Co (II)-metallothionein reflect distorted tetrahedral coordination of the cobalt atoms. Both the d-d and charge-transfer spectral regions closely resemble those of simple cobalt-tetrathiolate complexes, implying that their coordination chemistry is analogous. Ni (II) complex ions and Ni (II)-metallothionein similarly exhibit analogous MCD bands in the d-d region. The circular dichroic bands associated with ligand-metal charge-transfer transitions in the non-d-d region of Co (II)- and Ni (II)-metallothionein afford additional evidence for the similarity in tetrahedral microsymmetry of the two metal derivatives. The known ratio of 20 thiolate ligands to 7 metal ions, in conjunction with the spectral evidence for tetrathiolate coordination in metallothionein, represents good evidence that these metal thiolates are organized in clusters.     

Circular dichroism of phytochrome intermediates

Phototransformation P_t to P_fr was investigated with 124-kDa phytochrome from etiolated oat seedlings ( Avena sativa L. cv. Pirol) using circular dichroism spectroscopy at -110°C to +30°C. Using absorption spectra of the intermediates formed at the respective temperatures, circular dichroism spectra (300–800 nm) of pure intermediates were calculated.
The sign of the circular dichroic absorption bands changed upon formation of lumi-R, the primary photoproduct of P_r. This would be compatible with a Z→E isomerization taking place at this reaction step. The subsequent intermediates (meta-R_a and meta-R_c) as well as P_fr showed only small circular dichroism. Their absorption spectra were drastically shifted, but had similar spectral shapes. The results are discussed in terms of conformational changes of the phytochrome chromophore presumably taking place at the early steps of phototransformation P_r to P_fr.     

Circular dichroism of soybean leghemoglobin.

Circular dichroic (CD) spectra of soybean leghemoglobin, and some of its liganded derivatives were measured over the wavelength range of 650 to 200 nm. The heme-related circular dichroic bands in the visible, Soret and ultraviolet wavelength regions exhibit Cotton effects characteristic of each of the compounds examined. The positions of the dichroic bands vary with ligand substitutions and the oxidation state of the iron. All leghemoglobin derivatives, except the apoprotein, exhibit negative circular dichroic bands in the region of Soret absorption. In this region the optical activity of compounds with high-spin moments is greater than that of compounds with low or intermediate spin moments. The ellipticity of the heme band at about 260 nm is also altered by ligand binding and spin state. The dichroic spectra in the far-ultraviolet region indicated a high extent of alpha-helical structure (about 70%) in the native leghemoglobin and its liganded derivatives. The helicality of the apoprotein seems to diminish suggesting a decrease caused by the removal of the heme.     

A circular dichroic study of Cu(II) binding to bovine alpha-lactalbumin.

The visible and ultraviolet circular dichroic spectra resulting from the interaction of bovine alpha-lactalbumin with successive Cu(II) ions have been recorded under a variety of conditions. Analysis of the observed change-transfer and d-d band transitions can be made in terms of two kinds of binding sites: at a histidyl group and at the N-terminal amino group, respectively. At basic pH the amide nitrogens of the peptide backbone progressively take part in the coordination. The occupation of the high affinity calcium binding site by Ca(II) and Mn(II) does not influence the Cu(II) binding process, suggesting that there is no direct interaction between this site and the Cu(II) binding sites.     

Circular dichroism of aggregated deoxyhemoglobin S and the effect of amino acids.

It is well known that deoxyhemoglobin S (deoxy Hb S) aggregates at 37 °C and that it disaggregates at 1–5 °C. In this study solutions of pure Hb S at concentrations of 20–22 g/100 ml exhibit a normal circular dichroic spectrum in the range 250–650 nm at the temperature 1 °C. However, by the proper manipulation of the following parameters: temperatures of 1, 24 and 37 °C as well as the times required to change temperature and periods of maintaining at a certain temperature, five stages with different circular dichroic spectra can be produced. Not only the dichroic spectra of these stages are different but the kinetic behavior and stability of each of these stages are different. The evidence suggests that the mechanism of aggregation is similar to crystallization; that is, it exhibits a period of nucleation followed by growth. The overall kinetics of circular dichroic changes are described. At representative solution conditions the circular dichroic changes have been compared and found to parallel gel formation with pure Hb S. Also, the effect of certain anti-sickling amino acids (Sophianopoulos, A. J., et al. (1974) Clin. Biochem.7, 112–118) on the minimum Hb S concentration at which circular dichroic changes occur has been studied, and arginine chloride and arginine aspartate were found to raise this minimum concentration appreciably.     

Cryoenzymology and spectrophotometry of pea seedling diamine oxidase

Diamine oxidase follows bi-ter ping-pong kinetics, with an intermediate, "reduced" free-enzyme form being generated after the anaerobic conversion of amine to aldehyde. Visible spectra of diamine oxidase reacting at subzero temperatures provide evidence that this intermediate enzyme form is obtained via several other intermediates and that the environment of the Cu(II) changes dramatically during the course of the reaction [even though it is not reduced to Cu(I) during the catalytic cycle]. The spectrum of this form of diamine oxidase, which is obtained 0.5--2 h after the addition of amine at -5 to -15 degrees C, is independent of substrate, is identical with that obtained by anaerobic addition of substrate at room temperature, and provides evidence for a direct interaction of Cu(II) with the organic cofactor of the enzyme. This interaction is apparently charge transfer in nature. Upon removal of Cu(II) from the native enzyme, one obtains spectral evidence that the organic cofactor is still present. However, removal of the Cu(II) from the reduced (intermediate) enzyme form yields a featureless enzyme spectrum and a Cu(II)--chelate complex which contains a new ligand, which is presumably the second prosthetic group.     

The folding of staphylococcal nuclease in the presence of methanol or guanidine thiocyanate

The effect of methanol on the folding of staphylococcal nuclease has been investigated. Equilibrium thermal unfolding transitions were monitored by fluorescence emission. The transition was very sensitive to the presence of methanol (at pH 7.0), the Tm decreased from above 50 degrees C for aqueous solution to below 0 degree C for 70% methanol. The transitions were fully reversible and conformed to two-state behavior. A linear relationship was observed between the hydrophobicity of the solvent and both the Tm and the change in delta G for unfolding. The effect of pH on the transition in 50% methanol at 0 degree C was essentially the same as for aqueous solution, with a cooperative transition in the vicinity of apparent pH (pH*) 4. The unfolding transition was determined as a function of guanidine thiocyanate in aqueous and 50% methanol solvents. The midpoints of the transitions were 0.30 and 0.20 M, respectively, at 2.1 degrees C. The kinetics of folding at 0 degree C were compared in aqueous, 50% methanol and 0.30 M guanidine thiocyanate solvents, by monitoring changes in the tryptophan fluorescence intensity. Triphasic kinetics for refolding in both aqueous and 50% methanol solutions were observed in stopped-flow experiments. In both solvent systems the slowest phase is ascribed to proline isomerization. The kinetics of refolding were monitored at subzero temperatures in 50% methanol at pH* 7.0 in manual mixing experiments. Biphasic kinetics were observed at temperatures between 0 and -35 degrees C. A third, faster phase, was inferred from the missing amplitude. The energies of activation were 20.0 and 17.2 kcal mol-1, respectively, for the two slower phases. At -33.8 degrees C, the observed pseudo first-order rate constants were 1.2 x 10(-3) and 2.1 x 10(-5) s-1. At temperatures above -35 degrees C, the sum of the observed amplitudes was essentially constant at 70-75% of the expected total amplitude. At lower temperatures the amplitude of the refolding reaction decreased, and the native state was not formed (unless the temperature was increased), due to the formation of a trapped intermediate state. This intermediate has circular dichroism and fluorescence properties consistent with a compact state with some molten globule characteristics.     

Interactions between tetrahydrofolate and palladium(II) complexes

Interactions between folate derivatives and palladium(II) complexes are monitored in 1 : 1 molar ratio mixtures by circular dichroic spectra. The results are consistent with the following conclusions, i.e., tetrahydrofolate forms a chelate complex with palladium(II) through nitrogens 5 and 10 which is characterized by a unique circular dichroic spectrum. Mixtures of pallodium (II) complexes and dihydrofolate on methylenetetrahydrofolate could not be expected to, nor do they, give rise to similar circualr dichroic spectra for the following reasons: (1) The N5, N10 chelation site of tetrahydrofolate is blocked in methylenetetrahydrofolate, so coordination of a palladium(II) species must occur at some secondary site. (2) The N5, N10 chelation site is available but carbon six of the pteridine ring system is no longer asymmetric in dihydrofolate. Mixtures of dihdrofolate and palladium(II) complexes have no measurable circular dichroic spectra under the experimental conditions used.     

Elucidation of the chemical nature of the steady-state intermediates in the mechanism of carboxypeptidase A

Cryospectrokinetic studies of zinc and cobalt carboxypeptidase A disclosed two intermediates in the hydrolysis of both peptides and depsipeptides and furnished all the rate and equilibrium constants for the reaction scheme E + S in equilibrium ES1 in equilibrium ES2---E + P [Auld, D. S., Galdes, A., Geoghegan, K. F., Holmquist, B., Martinelli, R. A., & Vallee, B. L. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 5041-5045]. Since the ES2 intermediate is the predominate enzyme species present at steady state, its chemical nature is deducible from subzero chemical quench studies done after steady state is established. Extrapolation of the product concentration to zero time, [P0], measures the concentration of the enzyme species in which bond cleavage has occurred. For peptides, the [P0]values are zero, indicating that no product is generated prior to turnover and therefore the ES2 intermediate involves a complex between enzyme and intact peptide substrate. For depsipeptides, [P0] values are 1 mol of produce per mole of enzyme over the entire temperature range -20 to -50 degrees C, indicating cleavage of the ester bond occurs prior to the rate-limiting step so that ES2 is more properly denoted by EP1P2, where P1 and P2 are the substrates for the reverse reaction. The rate-limiting step for depsipeptides thus involves release of the products which may occur directly or through a mandatory conformational change followed by rapid product release.     

Characterization and improved separation of soybean leghemoglobins.

An improved separation procedure is described for isolating five leghemoglobin components from the nodules of soybean plants. After a preliminary oxidation with ferricyanide, and separation from endogenous nicotinate at pH 9.2, the ferrileghemoglobins are separated by DEAE-cellulose chromatography using gradient elution with acetate buffer (pH 5.2). The components have been characterized by their acetate and nicotinate binding affinities, gel electrophoretic, visible, and circular dichroic spectra in the ultraviolet, Soret and visible regions. Two formerly unresolved components of leghemoglobin c have indistinguishable circular dichroic, electrophoretic, and ligand binding properties, but differ in their spin states as judged by their visible spectra, their amino acid analyses, and their tryptic maps.