Conformational states of sarcoplasmic reticulum Ca2+-ATPase as studied by proteolytic cleavage

Summary Conformational states in sarcoplasmic reticulum Ca²⁺-ATPase have been examined by tryptic and chymotryptic cleavage. High affinity Ca²⁺ binding (E₁ state) exposes a peptide bond in the A fragment of the polypeptide chain to trypsin. Absence of Ca²⁺ (E₂ state) exposes bonds in the B fragment, which are protected by binding of Mg²⁺ or ATP. After phosphorylation from ATP the tryptic cleavage pattern depends on the predominant phosphoenzyme species present. ADP-sensitive E₁P and ADP-insensitive E₂P have cleavage patterns identical to those of unphosphorylated E₁ and E₂, respectively, indicating that two major conformational states are involved in Ca²⁺ translocation. The transition from E₁P to E₂P is inhibited by secondary tryptic splits in the A fragment, suggesting that parts of this fragment are of particular importance for the energy transduction process.The tryptic cleavage patterns of phosphorylated forms of detergent solubilized monomeric Ca²⁺-ATPase were similar to those of the membrane-bound enzyme, indicating that Ca²⁺ translocation depends mainly on structural changes within a single peptide chain. On the other hand, the protection of the second cleavage site as observed after vanadate binding to membranous Ca²⁺-ATPase could not be achieved in the soluble monomeric enzyme. Shielding of this peptide bond may therefore be due to protein-protein interactions in the semicrystalline state of the vanadate-bound Ca²⁺-ATPase in membranous form.     

Hydrolysis of allylic phosphates by enzymes from the flavedo of Citrus sinensis

Acid phosphatase activities have been partially purified from an aqueous extract of an acetone powder from orange flavedo. The use of a gel filtration step with an ionic gradient allowed a dissociation of proteins from pigments, thus facilitating purification and stabilization of the enzymes. The enzymes do not require metals for full activity, and they hydrolysed a wide spectrum of phosphorylated substrates. C₁₀–C₂₀ allylic pyrophosphates and monophosphates were hydrolysed sequentially by these ‘prenylphosphatases’. The final product was the corresponding unrearranged prenyl alcohol. This demonstrated the absence of E-Z isomerization and suggested an OP bond cleavage. Prenylphosphatases exhibited a certain degree of chain length specificity. Although the E or Z conformation of the C-2 double bond was not important, its presence was required for full activity. Excess prenylpyrophosphate inhibited the rate of formation of alcohols, most likely through the inhibition of phosphomonoesterase activity. These prenylphosphatases generated the alcoholic components of essential oils from the corresponding pyrophosphates and removed them from the chain lengthening process.     

News & Notes: Specificity of a Neutral Zn-Dependent Proteinase from Thermoactinomyces sacchari Toward the Oxidized Insulin B Chain

The proteolytic specificity of the neutral Zn-dependent proteinase from Thermoactinomyces sacchari was determined by analysis of the peptides obtained after incubation with the oxidized insulin B chain as a substrate. The enzyme is an endopeptidase with broad specificity. In total, 12 peptide bonds in the B chain of insulin were hydrolyzed. The major requirement is that a hydrophobic residue such as Leu, Val, or Phe should participate with the α-amino group in the bond to be cleaved. However, hydrolysis of bonds at the N-terminal side of His, Thr, and Gly was also observed. The peptide bond Leu 15–Tyr 16 in the oxidized insulin B chain, which is the major cleavage site for the alkaline microbial proteinases, is resistant to the attacks of the enzyme from Thermoactinomyces sacchari and other neutral proteinases. The proteolytic activity of the Zn-dependent proteinase from T. sacchari is different from those of other metalloendopeptidases from microorganisms. Received: 10 November 1999 / Accepted: 15 December 1999     

Heme-bound nitroxyl, hydroxylamine, and ammonia ligands as intermediates in the reaction cycle of cytochrome c nitrite reductase: a theoretical study

In this article, we consider, in detail, the second half-cycle of the six-electron nitrite reduction mechanism catalyzed by cytochrome c nitrite reductase. In total, three electrons and four protons must be provided to reach the final product, ammonia, starting from the HNO intermediate. According to our results, the first event in this half-cycle is the reduction of the HNO intermediate, which is accomplished by two PCET reactions. Two isomeric radical intermediates, HNOH^? and H₂NO^?, are formed. Both intermediates are readily transformed into hydroxylamine, most likely through intramolecular proton transfer from either Arg₁₁₄ or His₂₇₇. An extra proton must enter the active site of the enzyme to initiate heterolytic cleavage of the N–O bond. As a result of N–O bond cleavage, the H₂N⁺ intermediate is formed. The latter readily picks up an electron, forming H₂N^+?, which in turn reacts with Tyr₂₁₈. Interestingly, evidence for Tyr₂₁₈ activity was provided by the mutational studies of Lukat (Biochemistry 47:2080, 2008), but this has never been observed in the initial stages of the overall reduction process. According to our results, an intramolecular reaction with Tyr₂₁₈ in the final step of the nitrite reduction process leads directly to the final product, ammonia. Dissociation of the final product proceeds concomitantly with a change in spin state, which was also observed in the resonance Raman investigations of Martins et al. (J Phys Chem B 114:5563, 2010).     

Protein engineering of chymosin; modification of the optimum pH of enzyme catalysis

The aspartic proteinase chymosin exhibits a local network of hydrogen bonds involving the active site aspartates and surrounding residues which may have an influence on the rate and optimal pH of substrate cleavage. We have introduced into chymosin B the following substitutions: Asp304 to Ala (D304A), Thr218 to Ala (T218A) and Gly244 to Asp (G244D, chymosin A), using oligonucleotide-directed mutagenesis. Kinetic analysis of these active mutants shows shifts in their pH optima to 4.4 D304A, 4.2 T218A and 4.0 G244D compared with 3.8 for chymosin B using a synthetic octapeptide substrate. The upward shift of the D304A and T218A may be due to the loss of hydrogen bond interactions indirectly affecting the catalytic aspartates 32 and 215. The G244D mutation which is in a flexible loop on the surface of the enzyme may alter the conformation of the specificity pockets on the prime side of the scissile bond.     

Proteolysis and flash photolysis of bacteriorhodopsin in purple membrane fragments

Pronase treatment of aqueous suspensions of purple membrane fragments from H. halobium leads to the cleavage of bacteriorhodopsin. The protein fragments remaining in the membrane after treatment with relatively small concentrations of enzyme (2% w/w) in normal daylight range in molecular weight from 20,000-21,000 daltons, indicating that cleavage occurs mainly near the extremities of the protein chain. At higher enzyme concentrations the relative amounts of protein fragments having smaller molecular weight increase. Generally, the relative loss of retinal chromophore is larger than that of protein and thus the retinal binding site seems to be located near one of the chain ends that is cleaved off by enzyme.Irradiation with white light during the time of proteolysis (at both low and high enzyme concentrations) results in extensive cleavage, so that under certain conditions no high molecular weight components can be detected in SDS-polyacrylamide gels. It, therefore, appears that parts of the bacteriorhodopsin chain become more exposed to enzyme digestion when the purple membrane is illuminated.Enzyme treated aqueous purple membrane fragment suspensions still show photocycle activity. The main consequence of proteolysis is a pronounced appearance of biphasicity in the decay of M₄₁₂ and the regeneration of bR₅₇₀. Simultaneously the yield of O₆₆₀ is reduced. As with untreated purple membrane, the correlation between the rates of decay of M₄₁₂ and regeneration of bR₅₇₀ is greatest when the yield of O₆₆₀ is lowest.     

A QM/MM study of the reaction mechanism of (R)‐hydroxynitrile lyases from Arabidopsis thaliana (AtHNL)

Hydroxynitrile lyases (HNLs) catalyze the conversion of chiral cyanohydrins to hydrocyanic acid (HCN) and aldehyde or ketone. Hydroxynitrile lyase from Arabidopsis thaliana (AtHNL) is the first R‐selective HNL enzyme containing an α/β‐hydrolases fold. In this article, the catalytic mechanism of AtHNL was theoretically studied by using QM/MM approach based on the recently obtained crystal structure in 2012. Two computational models were constructed, and two possible reaction pathways were considered. In Path A, the calculation results indicate that the proton transfer from the hydroxyl group of cyanohydrin occurs firstly, and then the cleavage of C1‐C2 bond and the rotation of the generated cyanide ion (CN^?) follow, afterwards, CN^? abstracts a proton from His236 via Ser81. The C1‐C2 bond cleavage and the protonation of CN^? correspond to comparable free energy barriers (12.1 vs. 12.2 kcal mol^?1), suggesting that both of the two processes contribute a lot to rate‐limiting. In Path B, the deprotonation of the hydroxyl group of cyanohydrin and the cleavage of C1‐C2 bond take place in a concerted manner, which corresponds to the highest free energy barrier of 13.2 kcal mol^?1. The free energy barriers of Path A and B are very similar and basically agree well with the experimental value of HbHNL, a similar enzyme of AtHNL. Therefore, both of the two pathways are possible. In the reaction, the catalytic triad (His236, Ser81, and Asp208) acts as the general acid/base, and the generated CN^? is stabilized by the hydroxyl group of Ser81 and the main‐chain NH‐groups of Ala13 and Phe82. Proteins 2015; 83:66–77. © 2014 Wiley Periodicals, Inc.     

Human pancreatic ribonuclease presents higher endonucleolytic activity than ribonuclease A

Analyzing the pattern of oligonucleotide formation induced by HP-RNase cleavage shows that the enzyme does not act randomly and follows a more endonucleolytic pattern when compared to RNase A. The enzyme prefers the binding and cleavage of longer substrate molecules, especially when the phosphodiester bond that is broken is 8-11 nucleotides away from at least one of the ends of the substrate molecule. This more endonucleolytic pattern is more appropriate for an enzyme with a regulatory role. Deleting two positive charges on the N-terminus (Arg4 and Lys6) modifies this pattern of external/internal phosphodiester bond cleavage preference, and produces a more exonucleolytic enzyme. These residues may reinforce the strength of a non-catalytic secondary phosphate binding (p₂) or, alternatively, constitute a new non-catalytic phosphate binding subsite (p₃).     

Fructose-1, 6-bisphosphate aldolase from rabbit muscle: Different catalytic behavior of the dihydroxyacetone phosphate binding sites at low temperature

The equivalence of the four dihydroxyacetone phosphate binding sites of aldolase was abolished by lowering the temperature. At pH 6.2 and ?13 2C, four binding sites were detected by gel filtration; two sites with a K_diss ?0.1 μm, and a second set of sites with a K_diss = 4 μm. The alteration of the binding was accompanied by the alteration of the catalytic activity. The low-affinity sites were incapable of catalyzing the cleavage of the (3S) CH bond of dihydroxyacetone phosphate, and form only the ketimine phosphate intermediate. The high-affinity sites were still able to cleave the (3S) CH bond of dihydroxyacetone phosphate; however, the eneamine phosphate intermediate formed was almost fully converted into the eneamine-aldehyde … phosphate intermediate, which was the prevailing species at the equilibrium. The mechanism of the half-of-the sites reactivity of aldolase at low temperature has been explained and the nonequivalence of sites in promoting catalysis has been utilized to dissect and characterize the individual partial reactions of the enzyme. In the course of these studies it has been shown that the rate of hydration-dehydration of dihydroxyacetone phosphate at ?24 °C was too slow to measure.     

A new mode of B12 binding and the direct participation of a potassium ion in enzyme catalysis: X-ray structure of diol dehydratase

Background: Diol dehydratase is an enzyme that catalyzes the adenosylcobalamin (coenzyme B₁₂) dependent conversion of 1,2-diols to the corresponding aldehydes. The reaction initiated by homolytic cleavage of the cobalt–carbon bond of the coenzyme proceeds by a radical mechanism. The enzyme is an α₂β₂γ₂ heterooligomer and has an absolute requirement for a potassium ion for catalytic activity. The crystal structure analysis of a diol dehydratase–cyanocobalamin complex was carried out in order to help understand the mechanism of action of this enzyme.Results: The three-dimensional structure of diol dehydratase in complex with cyanocobalamin was determined at 2.2 Å resolution. The enzyme exists as a dimer of heterotrimers (α β γ)₂. The cobalamin molecule is bound between the α and β subunits in the ‘base-on’ mode, that is, 5,6-dimethylbenzimidazole of the nucleotide moiety coordinates to the cobalt atom in the lower axial position. The α subunit includes a (β/α)₈ barrel. The substrate, 1,2-propanediol, and an essential potassium ion are deeply buried inside the barrel. The two hydroxyl groups of the substrate coordinate directly to the potassium ion.Conclusions: This is the first crystallographic indication of the ‘base-on’ mode of cobalamin binding. An unusually long cobalt–base bond seems to favor homolytic cleavage of the cobalt–carbon bond and therefore to favor radical enzyme catalysis. Reactive radical intermediates can be protected from side reactions by spatial isolation inside the barrel. On the basis of unique direct interactions between the potassium ion and the two hydroxyl groups of the substrate, direct participation of a potassium ion in enzyme catalysis is strongly suggested.     

Active site mutations change the cleavage specificity of neprilysin

Neprilysin (NEP), a member of the M13 subgroup of the zinc-dependent endopeptidase family is a membrane bound peptidase capable of cleaving a variety of physiological peptides. We have generated a series of neprilysin variants containing mutations at either one of two active site residues, Phe⁵⁶³ and Ser⁵⁴⁶. Among the mutants studied in detail we observed changes in their activity towards leucine⁵-enkephalin, insulin B chain, and amyloid β_1–40. For example, NEP^F563I displayed an increase in preference towards cleaving leucine⁵-enkephalin relative to insulin B chain, while mutant NEP^S546E was less discriminating than neprilysin. Mutants NEP^F563L and NEP^S546E exhibit different cleavage site preferences than neprilysin with insulin B chain and amyloid ß_1–40 as substrates. These data indicate that it is possible to alter the cleavage site specificity of neprilysin opening the way for the development of substrate specific or substrate exclusive forms of the enzyme with enhanced therapeutic potential.     

Inhibition of Topoisomerases by Fatty Acids

The inhibitory effects of various fatty acids on topoisomerases were examined, and their structure-activity relationships and mechanism of action were studied. Saturated fatty acids (C_6:0 to C_22:0) did not inhibit topoisomerase I, but cis-unsaturated fatty acids (C_16:1 to C_22:1) with one double bond showed strong inhibition of the enzyme. The inhibitory potency depended on the carbon chain length and the position of the double bond in the fatty acid molecule. The trans-isomer, methyl ester and hydroxyl derivative of oleic acid had no or little inhibitory effect on topoisomerases I and II. Among the compounds studied petroselinic acid and vaccenic acid (C_18:1) with a cis-double bond were the potent inhibitors. Petroselinic acid was a topoisomerase inhibitor of the cleavable complex-nonforming type and acted directly on the enzyme molecule in a noncompetitive manner without DNA intercalation.     

Purification and properties of barley leaf ribonuclease

The principal ribonuclease from young barley plants was purified 29 200-fold by a six-step procedure. The enzyme showed a high specific activity (15 5OO ΔA₂₆₀ units/min/mg protein) and a molecular weight of about 25 000 was indicated by gel filtration and equilibrium sedimentation. Kinetic analysis of the cleavage of dinucleoside monophosphates and of yeast RNA indicated a base preference of Gua > Ade ≥ Ura ? Cyt, and was sensitive to the base located on either side of the phosphodiester bond. The enzyme resembles the Type I class of plant ribonucleases (E.C. 2.7.7.x).     

Lipoxygenase-mediated cleavage of fatty acids to carbonyl fragments in tomato fruits

Homogenates of tomato fruits catalysed the enzymic conversion of linoleic and linolenic acids (but not oleic acid) to C₆ aldehydes in low (3–5%) molar yield. Hexanal was formed from linoleic acid; cis-3-hexenal and smaller amounts of trans-2-hexenal were formed from linolenic acid. With the fatty acids as substrates, the major products were fatty acid hydroperoxides (50–80% yield) and the ratio of 9- to 13-hydroperoxides as isolated from an incubation with linoleic acid was at least 95:5 in favour of the 9-hydroperoxide isomer. When the 9- and 13-hydroperoxides of linoleic acid were used as substrates with tomato homogenates, the 13-hydroperoxide was readily cleaved to hexanal in high molar yield (60%) but the 9-hydroperoxide isomer was not converted to cleavage products. Properties of the hydroperoxide cleavage system are described. The results indicate that the C₆ aldehydes are formed from C₁₈ polyunsaturated fatty acids in a sequential enzyme system involving lipoxygenase (which preferentially oxygenates at the 9-position) followed by a hydroperoxide cleavage system which is, however, specific for the 13-hydroperoxy isomers.     

Crystal structures of Melanocarpus albomyces cellobiohydrolase Cel7B in complex with cello-oligomers show high flexibility in the substrate binding

Cellobiohydrolase from Melanocarpus albomyces (Cel7B) is a thermostable, single-module, cellulose-degrading enzyme. It has relatively low catalytic activity under normal temperatures, which allows structural studies of the binding of unmodified substrates to the native enzyme. In this study, we have determined the crystal structure of native Ma Cel7B free and in complex with three different cello-oligomers: cellobiose (Glc₂), cellotriose (Glc₃), and cellotetraose (Glc₄), at high resolution (1.6–2.1 Å). In each case, four molecules were found in the asymmetric unit, which provided 12 different complex structures. The overall fold of the enzyme is characteristic of a glycoside hydrolase family 7 cellobiohydrolase, where the loops extending from the core β-sandwich structure form a long tunnel composed of multiple subsites for the binding of the glycosyl units of a cellulose chain. The catalytic residues at the reducing end of the tunnel are conserved, and the mechanism is expected to be retaining similarly to the other family 7 members. The oligosaccharides in different complex structures occupied different subsite sets, which partly overlapped and ranged from −5 to +2. In four cellotriose and one cellotetraose complex structures, the cello-oligosaccharide also spanned over the cleavage site (−1/+1). There were surprisingly large variations in the amino acid side chain conformations and in the positions of glycosyl units in the different cello-oligomer complexes, particularly at subsites near the catalytic site. However, in each complex structure, all glycosyl residues were in the chair (⁴C₁) conformation. Implications in relation to the complex structures with respect to the reaction mechanism are discussed.     

Role of the N-terminal region of the a chain in β1-bungarotoxin from the venom ofBungarus multicinctus (Taiwan-banded krait)

The N-terminal α-amino groups of β₁-bungarotoxin (β₁-Bgt) fromBungarus multicinctus venom were modified with trinitrobenzene sulfonic acid and the modified derivative was separated by high performance liquid chromatography. The trinitrophenylated (TNP) derivative contained two TNP groups at the α-amino groups of A chain and B chain and showed a marked decrease in enzymatic activity. Methionine residues at positions 6 and 8 of the A chain were oxidized with chloramine T or cleaved with cyanogen bromide to remove the N-terminal octapeptide. Oxidation of methionine residues and removal of the N-terminal octapeptide caused a precipitous decrease in enzymatic activity, whereas antigenicity remained unchanged. The presence of dihexanoyllecithin influenced the interaction between β₁-Bgt and 8-antilinonaphthalene sulfonate (ANS) and revealed that β₁-Bgt consists of two types of ANS-binding sites, one at the substrate binding site of the A chain and the other might be at the B chain. The modified derivatives still retained their affinity for Ca²⁺ and ANS, indicating that the N-terminal region is not involved in Ca²⁺ and substrate binding. A fluorescence study revealed that the α-amino group of the A chain was in the vicinity of substrate binding site and that the TNP α-amino groups were in proximity to Trp-19 of the A chain. In addition, the study showed that the N-terminal region is important for stabilizing the architectural environment of Trp-19. The results, together with the proposal that Trp-19 of the A chain is involved in substrate binding, suggest that the N-terminal region of the A chain plays a crucial role in maintaining a functional active site for β₁-Bgt.     

Dihydrofolate reductase from a methotrexate-resistant strain of Escherichia coli: dihydrofolate monooxygenase activity

Dihydrofolate reductase from strain MB 1428 of Escherichia coli was shown to catalyze the oxidative cleavage of dihydrofolate at the C(9)N(10) bond. One of the products of the reaction was identified as 7,8-dihydropterin-6-carboxaldehyde through its proton magnetic resonance spectrum. The maximal enzymatic rate was 0.05 moles dihydrofolate cleaved per minute per mole enzyme at 25° and pH 7.2, and the K_M for dihydrofolate was 17.5 ± 2.5 μM. The enzymatic reaction was fully inhibitable with methotrexate. The mechanism of enzyme action was proposed to be an apparent “acidification” of dihydrofolate upon binding to the enzyme. Folate underwent an analogous oxidative cleavage by enzyme with a turnover number of 0.0014, which produced pterin-6-carboxaldehyde. Methotrexate was also slowly degraded by the enzyme.     

Purification and Characterization of Intracellular Proteinases in Pleurotus ostreatus Fruiting Bodies

A serine proteinase (ProA, EC 3.4.22.9) and two metalloendopeptidases (ProB, EC 3.4.99.32 and ProC, 3.4.24.4), have been purified to homogeneity from the fruiting bodies of Pleurotus ostreatus. ProA is a serine proteinase with a mass of 30 kDa, which has amidolytic and esterolytic activities besides proteolysis and catalyzes preferential cleavage of the peptide bonds involving the carboxyl groups of hydrophobic amino acid residues in oxidized bovine insulin B chain. The N-terminal amino acid sequence was VTQTNAPWGLSRL.

ProB is a zinc-enzyme with a mass of 18 kDa, which is devoid of lysine, and its N-terminal sequence was ATFVGCSATRQ. The enzyme is inactivated completely by EDTA and 1,10-phenanthroline, and Zn²⁺-depleted ProB can regain the activity with Zn²⁺, Co²⁺, or Mn²⁺. Specific cleavage of Pro₂₉-LYS₃₀ in oxidized bovine insulin B chain, preferential generation of lysylpeptides from proteins, and a high susceptibility of polylysine suggest that ProB splits specifically the peptide bonds involving the α-amino group of lysyl residues.

ProC is a metalloendopeptidase of a mass of 42.5 kDa, and Zn²⁺ was the most effective divalent metal ion to activate the EDTA-inactivated enzyme.     

Gamma-glutamyl hydrolase conjugase). Purification and properties of the bovine hepatic enzyme.

Bovine hepatic gamma-glutamyl hydrolase (conjugase) has been purified to homogeneity. A feature of the purification procedure was the use of high affinity macromolecular polyanion enzyme inhibitors which formed tight complexes with the enzyme altering its solubility, gel filtration, and ion exchange properties. The enzyme, which cleaves the gamma-glutamyl bonds of pteroylpolyglutamates, has a molecular weight of 108,000. It is a glycoprotein with an acid pH optimum, properties consistent with its lysosomal localization. Zinc is essential for enzyme stability. The presence of highly reactive sulfhydryl groups was evident from the extreme sensitivity to oxidizing agents and organomercurials. Very little thermal denaturation occurs below 65 degrees, but the enzyme is extremely sensitive to 0uffer anions, in keeping with the polyanionic nature of the substrate. In order to study the mechanism of action of the enzyme, a wide range of pteroylpolyglutamates, N-t-Boc polyglutamates and free polyglutamates were synthesized containing L-[U-14C]glutamic acid residues in different positions. Two pteroyltriglutamate derivatives were also synthesized in which an alpha bond replaced one of the two available gamma bonds. Time course studies of the products of the action of conjugase on these various substrates enabled us to draw the following conclusions about the enzyme: (a) peptide bond cleavage occurred only at gamma-glutamyl bonds and the presence of a COOH-terminal gamma bond was essential for enzyme action; (b) bond cleavage occurred with equal facility at internal points of the peptide chain and the enzyme should therefore be more appropriately classified as an acid hydrolase; (c) longer chain gamma-glutamyl peptides were preferentially attacked by the enzyme, the cleavage of diglutamyl peptides being extremely slow; and (d) cleavage of gamma bonds was independent of the NH2-terminal pteroyl moiety. Studies with polyanions such as the glycosaminoglycans and dextran sulfate supported the concept that the polyanion structure of the substrate was a major factor in substrate-active site interaction.