Stereochemical aspects of peptide hydrolysis catalyzed by serine proteases of the chymotrypsin type

The steric course of peptide hydrolysis catalyzed by serine proteases has been studied on the basis of the available, extensive structural data and taking into account the stereoelectronic theory of Deslongchamps (Heterocycles, 7, 1271 (1977)). These studies allowed elucidation of the structure of intermediates, in particular of the tetrahedral intermediate, and of the main structural events taking place during catalysis. They reveal a difficulty inherent in the generally accepted mechanism of peptide hydrolysis: protonation of the leaving nitrogen in the configuration arising from nucleophilic attack of Ser-195 on the carbonyl carbon cannot take place internally from His-57. Two alternative mechanisms are discussed which are compatible with all implications of the stereoelectronic theory. The main features of the more probable mechanism are: (i) a conformational change allowing the imidazole ring of His-57 to occupy two distinct positions; in one position a proton is abstracted from O^γ of Ser-195, and in the other this proton is donated to the leaving nitrogen; (ii) a configurational change (inversion) of the pyramidal leaving nitrogen reorienting the lone-pair orbital developed during nucleophilic attack; in one orientation CO bond breaking, and in the other CN bond breaking, is allowed. This inversion process confers on the nitrogen the property of a switch controlling the breakdown of the tetrahedral intermediate.     

Molecular dynamics simulations of the acyl-enzyme and the tetrahedral intermediate in the deacylation step of serine proteases

Despite the availability of many experimental data and some modeling studies, questions remain as to the precise mechanism of the serine proteases. Here we report molecular dynamics simulations on the acyl-enzyme complex and the tetrahedral intermediate during the deacylation step in elastase catalyzed hydrolysis of a simple peptide. The models are based on recent crystallographic data for an acyl-enzyme intermediate at pH 5 and a time-resolved study on the deacylation step. Simulations were carried out on the acyl enzyme complex with His-57 in protonated (as for the pH 5 crystallographic work) and deprotonated forms. In both cases, a water molecule that could provide the nucleophilic hydroxide ion to attack the ester carbonyl was located between the imidazole ring of His-57 and the carbonyl carbon, close to the hydrolytic position assigned in the crystal structure. In the "neutral pH" simulations of the acyl-enzyme complex, the hydrolytic water oxygen was hydrogen bonded to the imidazole ring and the side chain of Arg-61. Alternative stable locations for water in the active site were also observed. Movement of the His-57 side-chain from that observed in the crystal structure allowed more solvent waters to enter the active site, suggesting that an alternative hydrolytic process directly involving two water molecules may be possible. At the acyl-enzyme stage, the ester carbonyl was found to flip easily in and out of the oxyanion hole. In contrast, simulations on the tetrahedral intermediate showed no significant movement of His-57 and the ester carbonyl was constantly located in the oxyanion hole. A comparison between the simulated tetrahedral intermediate and a time-resolved crystallographic structure assigned as predominantly reflecting the tetrahedral intermediate suggests that the experimental structure may not precisely represent an optimal arrangement for catalysis in solution. Movement of loop residues 216-223 and P3 residue, seen both in the tetrahedral simulation and the experimental analysis, could be related to product release. Furthermore, an analysis of the geometric data obtained from the simulations and the pH 5 crystal structure of the acyl-enzyme suggests that since His-57 is protonated, in some aspects, this crystal structure resembles the tetrahedral intermediate.     

Investigation of an active site histidine-aspartate couple in Trimeresurus flavoviridis phospholipase A2

When Trimeresurus flavoviridis phospholipase A2 was reacted with methyl p-nitrobenzenesulfonate, its activity decreased following first-order kinetics. The pH dependence of the rate constants of inactivation showed that His-48 with an apparent pKa of 6.5 controls the reaction. In the pH region below 6.5, N1-methylhistidine was predominantly formed. On the other hand, N1,N3-dimethylhistidine was almost exclusively produced in the pH region above 6.5. No N3-methylhistidine was detected at any pH tested. Such observations suggested that the first methylation occurred at the N1-position of the imidazole ring followed by a second methylation at the N3-position, and that His-48 couples the carboxylate of Asp-99 at the N3-position of the imidazole ring, in accord with the interaction observed in the crystal structure of homologous Crotalus atrox phospholipase A2. As it has been reported that, in the reaction of chymotrypsin with methyl p-nitrobenzenesulfonate at pH 7.8, only monomethylation occurred at the N1-position of the His-57 imidazole group (Nakagawa, Y. & Bender, M.L. (1970) Biochemistry 9, 259-267), the nature of the active site histidine-aspartate couple of T. flavoviridis phospholipase A2 seems not to be identical with that of chymotrypsin.     

Complex of alpha-chymotrypsin and N-acetyl-L-leucyl-L-phenylalanyl trifluoromethyl ketone: structural studies with NMR spectroscopy

A dipeptidyl trifluoromethyl ketone, N-acetyl-L-leucyl-L-[1-13C]phenylalanyl trifluoromethyl ketone, was synthesized. This compound inhibits chymotrypsin with Ki = 1.2 microM [Imperiali B., & Abeles, R.H. (1986) Biochemistry 25, 3760-3767]. The complex formed between this inhibitor and alpha-chymotrypsin was examined with 1H, 13C, and 19F NMR spectroscopy to establish its structure in solution. The keto group of the trifluoro ketone is present as an ionized hemiketal group as deduced from the comparison of its 13C chemical shift with those of model hemiketals. The pKa of the hemiketal hydroxyl in the complex is approximately 4.9, which is about 4.2 units lower than the pKa of model hemiketals. This observation provides direct evidence that serine proteases are able to stabilize the oxyanions of tetrahedral adducts. Evidence is also presented for the presence of an Asp-His H bond and protonation of the imidazole group of His-57 in the tetrahedral adduct. The pKa of His-57 is higher than 10. This observation directly indicates that the pKa of His-57 is elevated in a complex containing a tetrahedral adduct.     

Copper-induced structural propensities of the amyloidogenic region of human prion protein

Transmissible spongiform encephalopathies are associated with the misfolding of the cellular Prion Protein (PrP^C) to an abnormal protein isoform, called scrapie prion protein (PrP^Sc). The structural rearrangement of the fragment of N-terminal domain of the protein spanning residues 91–127 is critical for the observed structural transition. The amyloidogenic domain of the protein encloses two copper-binding sites corresponding to His-96 and His-111 residues that act as anchors for metal ion binding. Previous studies have shown that Cu(II) sequestration by both sites may modulate the peptide’s tendency to aggregation as it inflicts the hairpin-like structure that stabilizes the transition states leading to β-sheet formation. On the other hand, since both His sites differ in their ability to Cu(II) sequestration, with His-111 as a preferred binding site, we found it interesting to test the role of Cu(II) coordination to this single site on the structural properties of amyloidogenic domain. The obtained results reveal that copper binding to His-111 site imposes precise backbone bending and weakens the natural tendency of apo peptide to β-sheet formation.     

A new structural form in the SAM/metal-dependent o‑methyltransferase family: MycE from the mycinamicin biosynthetic pathway

O-linked methylation of sugar substituents is a common modification in the biosynthesis of many natural products and is catalyzed by multiple families of S-adenosyl-l-methionine (SAM or AdoMet)-dependent methyltransferases (MTs). Mycinamicins, potent antibiotics from Micromonospora griseorubida, can be methylated at two positions on a 6-deoxyallose substituent. The first methylation is catalyzed by MycE, a SAM- and metal-dependent MT. Crystal structures were determined for MycE bound to the product S-adenosyl-l-homocysteine (AdoHcy) and magnesium, both with and without the natural substrate mycinamicin VI. This represents the first structure of a natural product sugar MT in complex with its natural substrate. MycE is a tetramer of a two-domain polypeptide, comprising a C-terminal catalytic MT domain and an N-terminal auxiliary domain, which is important for quaternary assembly and for substrate binding. The symmetric MycE tetramer has a novel MT organization in which each of the four active sites is formed at the junction of three monomers within the tetramer. The active-site structure supports a mechanism in which a conserved histidine acts as a general base, and the metal ion helps to position the methyl acceptor and to stabilize a hydroxylate intermediate. A conserved tyrosine is suggested to support activity through interactions with the transferred methyl group from the SAM methyl donor. The structure of the free enzyme reveals a dramatic order-disorder transition in the active site relative to the S-adenosyl-l-homocysteine complexes, suggesting a mechanism for product/substrate exchange through concerted movement of five loops and the polypeptide C-terminus.     

Structural diversity within the mononuclear and binuclear active sites of N-acetyl-D-glucosamine-6-phosphate deacetylase

NagA catalyzes the hydrolysis of N-acetyl-d-glucosamine-6-phosphate to d-glucosamine-6-phosphate and acetate. X-ray crystal structures of NagA from Escherichia coli were determined to establish the number and ligation scheme for the binding of zinc to the active site and to elucidate the molecular interactions between the protein and substrate. The three-dimensional structures of the apo-NagA, Zn-NagA, and the D273N mutant enzyme in the presence of a tight-binding N-methylhydroxyphosphinyl-d-glucosamine-6-phosphate inhibitor were determined. The structure of the Zn-NagA confirms that this enzyme binds a single divalent cation at the beta-position in the active site via ligation to Glu-131, His-195, and His-216. A water molecule completes the ligation shell, which is also in position to be hydrogen bonded to Asp-273. In the structure of NagA bound to the tight binding inhibitor that mimics the tetrahedral intermediate, the methyl phosphonate moiety has displaced the hydrolytic water molecule and is directly coordinated to the zinc within the active site. The side chain of Asp-273 is positioned to activate the hydrolytic water molecule via general base catalysis and to deliver this proton to the amino group upon cleavage of the amide bond of the substrate. His-143 is positioned to help polarize the carbonyl group of the substrate in conjunction with Lewis acid catalysis by the bound zinc. The inhibitor is bound in the alpha-configuration at the anomeric carbon through a hydrogen bonding interaction of the hydroxyl group at C-1 with the side chain of His-251. The phosphate group of the inhibitor attached to the hydroxyl at C-6 is ion paired with Arg-227 from the adjacent subunit. NagA from Thermotoga maritima was shown to require a single divalent cation for full catalytic activity.     

Active site dynamics of acyl-chymotrypsin

The motions of water molecules, the acyl moiety, the catalytic triad, and the oxyanion binding site of acyl-chymotrypsin were studied by means of a stochastic boundary molecular dynamics simulation. A water molecule that could provide the nucleophilic OH^? for the deacylation stage of the catalysis was found to be trapped between the imidazole ring of His-57 and the carbonyl carbon of the acyl group. It makes a hydrogen bond with the N^ε2 of His-57 and is heldin place through a network of hydrogen-bonded water molecules in theactive site. The water molecule was found as close as 2.8 Å to the carbonyl carbon. This appears to be due to the constraints imposed by nonbonded interaction in the active site. Configurations were found in which one hydrogen of the trapped water shared a bifurcated hydrogen bond with His-57-N^ε2 and Ser-195-0^γ with the water oxygen very close to the carbonyl carbon. The existence of such a water molecule suggests that large movement of the His-57 imidazole ring between positions suitable for providing general-base catalyzed assistance and for providing general-acid catalyzed assistance may notbe required during the reaction. The simulation indicates that the side chains of residues involved in catalysis (i.e., His-57, Ser-195, and Asp-102) are significantly less flexible than other side chains in the protein. The 40% reduction in rms fluctuations is consistent with a comparable reduction calculated from the temperature factors obtained in the X-ray crystal-lographic data of γ-chymotrypsin. The greater rigidity of active site residues seems to result from interconnected hydrogen bonding networks among the residues and between the residues and the solvent water in the active site. © Wiley-Liss, Inc.     

High resolution nuclear magnetic resonance studies of the active site of chymotrypsin. II. Polarization of histidine 57 by substrate analogues and competitive inhibitors

The proton nuclear magnetic resonance signal of the His57-Asp102 hydrogen bonded proton in the charge relay system of chymotrypsinogen A and chymotrypsin A_δ has been monitored to determine the influence of substrate analogues and competitive inhibitors on the electronic state of the active site regions. Borate ion, benzene boronic acid and 2-phenylethylboronic acid, when bound to chymotrypsin at pH 9.5 shift the resonance position of the His-Asp hydrogen bonded proton to ?15.9, ?16.3 and ?17.2 parts per million, respectively. These positions are intermediate between the low pH position in the free enzyme of ?18.0 parts per million and the high pH position of ?14.9 parts per million. The presence of these analogues prevents the His-Asp proton resonance from titrating in the region of pH 6 to 9.5. Similar low field shifts are observed for the hydrogen bonded proton resonance of subtilisin BPN′ when complexed with these boronic acids. The results support the chemical and crystallographic data which show that negatively charged tetrahedral adducts of the boronic acid substrate analogues are formed at the active sites of these enzymes. When combined with similar nuclear magnetic resonance data for the binding of N-acetyl-l-tryptophan to chymotrypsin A_δ, they suggest that a direct interaction occurs between the active site histidine and the atom occupying the leaving group position of the substrate, presumably a hydrogen bond.The His-Asp proton resonance was also monitored in complexes of chymotrypsin A_δ with bovine pancreatic trypsin inhibitor over the pH range 4 to 9. In the complex the low field proton resonance had a field position of ?14.9 parts per million over the pH range 4 to 9 indicating that His57 is in the neutral form, similar to the active enzyme at high pH.     

Structural and biochemical analyses of hemimethylated DNA binding by the SeqA protein

The Escherichia coli SeqA protein recognizes the 11 hemimethylated G-^mA-T-C sites in the oriC region of the chromosome, and prevents replication over-initiation within one cell cycle. The crystal structure of the SeqA C-terminal domain with hemimethylated DNA revealed the N⁶-methyladenine recognition mechanism; however, the mechanism of discrimination between the hemimethylated and fully methylated states has remained elusive. In the present study, we performed mutational analyses of hemimethylated G-^mA-T-C sequences with the minimal DNA-binding domain of SeqA (SeqA_71–181), and found that SeqA_71–181 specifically binds to hemimethylated DNA containing a sequence with a mismatched ^mA:G base pair [G-^mA(:G)-T-C] as efficiently as the normal hemimethylated G-^mA(:T)-T-C sequence. We determined the crystal structures of SeqA_71–181 complexed with the mismatched and normal hemimethylated DNAs at 2.5 and 3.0 Å resolutions, respectively, and found that the mismatched ^mA:G base pair and the normal ^mA:T base pair are recognized by SeqA in a similar manner. Furthermore, in both crystal structures, an electron density is present near the unmethylated adenine, which is only methylated in the fully methylated state. This electron density, which may be due to a water molecule or a metal ion, can exist in the hemimethylated state, but not in the fully methylated state, because of steric clash with the additional methyl group.     

Binding of the chymotrypsin substrate,tryptophan methyl ester,by rat α-fetoprotein

We studied how tryptophan methyl ester and related compounds inhibit binding of estrone to rat α-fetoprotein and find that: (a) like chymotrypsin, α-fetoprotein binds tryptophan esters with higher affinity than tryptophan or its amides; (b) the affinity of α-fetoprotein for tryptophan methyl ester is 3.7 · 10^?4 M, which is close to the affinity of chymotrypsin (10^?4 M); (c) α-fetoprotein binding of tryptophan methyl ester is stereoselective and pH dependent. All of these observations suggest that there is a specific interaction between α-fetoprotein and the chymotrypsin substrate, tryptophan methyl ester, and that rat α-fetoprotein contains a site with some structural similarities to the catalytic site in chymotrypsin. Since we also find that tryptophan methyl ester is a competitive inhibitor of estrone binding to α-fetoprotein, it is possible that the protease substrate binding site on α-fetoprotein is spatially close to the estrone binding site.     

Dynamics of RNA modification by a multi-site-specific tRNA methyltransferase

In most organisms, the widely conserved 1-methyl-adenosine58 (m¹A₅₈) tRNA modification is catalyzed by an S-adenosyl-L-methionine (SAM)-dependent, site-specific enzyme TrmI. In archaea, TrmI also methylates the adjacent adenine 57, m¹A₅₇ being an obligatory intermediate of 1-methyl-inosine57 formation. To study this multi-site specificity, we used three oligoribonucleotide substrates of Pyrococcus abyssi TrmI (_PabTrmI) containing a fluorescent 2-aminopurine (2-AP) at the two target positions and followed the RNA binding kinetics and methylation reactions by stopped-flow and mass spectrometry. _PabTrmI did not modify 2-AP but methylated the adjacent target adenine. 2-AP seriously impaired the methylation of A₅₇ but not A₅₈, confirming that _PabTrmI methylates efficiently the first adenine of the A₅₇A₅₈A₅₉ sequence. _PabTrmI binding provoked a rapid increase of fluorescence, attributed to base unstacking in the environment of 2-AP. Then, a slow decrease was observed only with 2-AP at position 57 and SAM, suggesting that m¹A₅₈ formation triggers RNA release. A model of the protein–tRNA complex shows both target adenines in proximity of SAM and emphasizes no major tRNA conformational change except base flipping during the reaction. The solvent accessibility of the SAM pocket is not affected by the tRNA, thereby enabling S-adenosyl-L-homocysteine to be replaced by SAM without prior release of monomethylated tRNA.     

Differences in lysine pKa values may be used to improve NMR signal dispersion in reductively methylated proteins

Reductive methylation of lysine residues in proteins offers a way to introduce ¹³C methyl groups into otherwise unlabeled molecules. The ¹³C methyl groups on lysines possess favorable relaxation properties that allow highly sensitive NMR signal detection. One of the major limitations in the use of reductive methylation in NMR is the signal overlap of ¹³C methyl groups in NMR spectra. Here we show that the uniform influence of the solvent on chemical shifts of exposed lysine methyl groups could be overcome by adjusting the pH of the buffering solution closer to the pKa of lysine side chains. Under these conditions, due to variable pKa values of individual lysine side chains in the protein of interest different levels of lysine protonation are observed. These differences are reflected in the chemical shift differences of methyl groups in reductively methylated lysines. We show that this approach is successful in four different proteins including Ca²⁺-bound Calmodulin, Lysozyme, Ca²⁺-bound Troponin C, and Glutathione S-Transferase. In all cases significant improvement in NMR spectral resolution of methyl signals in reductively methylated proteins was obtained. The increased spectral resolution helps with more precise characterization of protein structural rearrangements caused by ligand binding as shown by studying binding of Calmodulin antagonist trifluoperazine to Calmodulin. Thus, this approach may be used to increase resolution in NMR spectra of ¹³C methyl groups on lysine residues in reductively methylated proteins that enhances the accuracy of protein structural assessment. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Catalysis by dienelactone hydrolase: A variation on the protease mechanism

Dienelactone hydrolase (DLH), an enzyme from the β-ketoadipate pathway, catalyzes the hydrolysis of dienelactone to maleylacetate. Our inhibitor binding studies suggest that its substrate, dienelactone, is held in the active site by hydrophobic interactions around the lactone ring and by the ion pairs between its carboxylate and Arg-81 and Arg-206. Like the cysteine/serine proteases, DLH has a catalytic triad (Cys-123, His-202, Asp-171) and its mechanism probably involves the formation of covalently bound acyl intermediate via a tetrahedral intermediate. Unlike the proteases, DLH seems to protonate the incipient leaving group only after the collapse of the first tetrahedral intermediate, rendering DLH incapable of hydrolyzing amide analogues of its ester substrate. In addition, the triad His probably does not protonate the leaving group (enolate) or deprotonate the water for deacylation; rather, the enolate anion abstracts a proton from water and, in doing so, supplies the hydroxyl for deacylation. © 1993 Wiley-Liss, Inc.     

The deuterium isotope effect on the NMR signal of the low-barrier hydrogen bond in a transition-state analog complex of chymotrypsin

The participation of a low-barrier hydrogen bond (LBHB) in the mechanism of action of chymotrypsin introduces a new role for Asp 102 and His 57 in catalysis [C. S. Cassidy, J. Lin, and P. A. Frey (1997) Biochemistry 36, 4576-4584]. It is postulated that the LBHB increases the basicity of His 57-N(epsilon2) in the transition state, thereby facilitating the abstraction of a proton from Ser 195, and stabilizes the tetrahedral intermediate in the acylation step. Evidence for this mechanism includes the downfield chemical shift of the proton bridging His 57 and Asp 102 in transition-state analog complexes and the low deuterium fractionation factors for this proton in the same complexes. We present additional spectroscopic evidence supporting the assignment of an LBHB between His 57 and Asp 102. The tetrahedral addition complex between Ser 195 of chymotrypsin and N-acetyl-l-leucyl-l-phenylalanyl trifluoromethylketone is regarded as a close structural analog of a tetrahedral intermediate. The deuterium NMR signal for the downfield deuteron bridging His 57 and Asp 102 in D(2)O has now been observed as a broad band centered at 17.8 +/- 0.5 ppm. The proton NMR signal in H(2)O is centered at 18.9 +/- 0.05 ppm. The two signals are clearly separated corresponding to a deuterium isotope effect of Delta[delta(H) - delta(D)] = 1.1 +/- 0.5 ppm. Deuterium isotope effects in this range are characteristic of LBHBs, and this observation provides further support for the assignment of the proton bridging His 57 and Asp 102 in transition-state analog complexes as an LBHB.     

Transition-state stabilization at the oxyanion binding sites of serine and thiol proteinases: hydrolyses of thiono and oxygen esters

X-ray diffraction studies suggested that the tetrahedral intermediate formed during the catalysis by serine and thiol proteinases can be stabilized by hydrogen bonds from the protein to the oxyanion of the intermediate [cf. Kraut, J. (1977) Annu. Rev. Biochem. 46, 331-358; Drenth, J., Kalk, K.H., & Swen, H.M. (1976) Biochemistry 15, 3731-3738]. To obtain evidence in favor or against this hypothesis, we synthesized thiono substrates (the derivatives of N-benzoyl-glycine methyl ester and N-acetylphenylalanine ethyl ester) containing a sulfur in place of the carbonyl oxygen atom of the scissile ester bond. We anticipated that this relatively subtle structural change specifically directed to the oxyanion binding site should produce serious catalytic consequences owing to the different properties of oxygen and sulfur if transition-state stabilization in the oxyanion hole is indeed important. In fact, while in alkaline hydrolysis the chemical reactivities of oxygen esters and corresponding thiono esters proved to be similar, neither chymotrypsin nor subtilisin hydrolyzed the thiono esters at a measurable rate. This result substantiates the crucial role of the oxyanion binding site in serine proteinase catalysis. On the basis of the similar values of the binding constants found for oxygen esters and their thiono counterparts, it can be concluded that the substitution of sulfur for oxygen significantly influences transition state stabilization but not substrate binding. The thiol proteinases papain and chymopapain react with the oxygen and thiono esters of N-benzoylglycine at similar rates. Apparently, in these reactions the above stabilizing mechanism is absent or not important, which is a major mechanistic difference between the catalyses by serine and thiol proteinases.     

Catalytic mechanism of rhomboid protease GlpG probed by 3,4-dichloroisocoumarin and diisopropyl fluorophosphonate

Rhomboid proteases have many important biological functions. Unlike soluble serine proteases such as chymotrypsin, the active site of rhomboid protease, which contains a Ser-His catalytic dyad, is submerged in the membrane and surrounded by membrane-spanning helices. Previous crystallographic analyses of GlpG, a bacterial rhomboid protease, and its complex with isocoumarin have provided insights into the mechanism of the membrane protease. Here, we studied the interaction of GlpG with 3,4-dichloroisocoumarin and diisopropyl fluorophosphonate, both mechanism-based inhibitors for the serine protease, and describe the crystal structure of the covalent adduct between GlpG and diisopropyl fluorophosphonate, which mimics the oxyanion-containing tetrahedral intermediate of the hydrolytic reaction. The crystal structure confirms that the oxyanion is stabilized by the main chain amide of Ser-201 and by the side chains of His-150 and Asn-154. The phosphorylation of the catalytic Ser-201 weakens its interaction with His-254, causing the catalytic histidine to rotate away from the serine. The rotation of His-254 is accompanied by further rearrangement of the side chains of Tyr-205 and Trp-236 within the substrate-binding groove. The formation of the tetrahedral adduct is also accompanied by opening of the L5 cap and movement of transmembrane helix S5 toward S6 in a direction different from that predicted by the lateral gating model. Combining the new structural data with those on the isocoumarin complex sheds further light on the plasticity of the active site of rhomboid membrane protease.     

Mechanistic characterization of N-formimino-L-glutamate iminohydrolase from Pseudomonas aeruginosa

N-Formimino-l-glutamate iminohydrolase (HutF) from Pseudomonas aeruginosa catalyzes the deimination of N-formimino-l-glutamate in the histidine degradation pathway. An amino acid sequence alignment between HutF and members of the amidohydrolase superfamily containing mononuclear metal centers indicated that residues Glu-235, His-269, and Asp-320 are involved in substrate binding and activation of the nucleophilic water molecule. The purified enzyme contained up to one equivalent of zinc. The metal was removed by dialysis against the metal chelator dipicolinate with the complete loss of catalytic activity. Enzymatic activity was restored by incubation of the apoprotein with Zn2+, Cd2+, Ni2+, or Cu2+. The mutation of Glu-235, His-269, or Asp-320 resulted in the diminution of catalytic activity by two to six orders of magnitude. Bell-shaped profiles were observed for kcat and kcat/Km as a function of pH. The pKa of the group that must be unprotonated for catalytic activity was consistent with the ionization of His-269. This residue is proposed to function as a general base in the abstraction of a proton from the metal-bound water molecule. In the proposed catalytic mechanism, the reaction is initiated by the abstraction of a proton from the metal-bound water molecule by the side chain imidazole of His-269 to generate a tetrahedral intermediate of the substrate. The collapse of the tetrahedral intermediate commences with the abstraction of a second proton via the side chain carboxylate of Asp-320. The C-N bond of the substrate is subsequently cleaved with proton transfer from His-269 to form ammonia and the N-formyl product. The postulated role of the invariant Glu-235 is to ion pair with the positively charged formimino group of the substrate.     

Studies of the mechanism of action and regulation of cAMP-dependent protein kinase

Magnetic resonance and kinetic studies of the catalytic subunit of a Type II cAMP-dependent protein kinase from bovine heart have established the active complex to be an enzyme-ATP-metal bridge. The metal ion is β,γ coordinated with Δ chirality at the β-phosphorous atom. The binding of a second metal ion at the active site which bridges the enzyme to the three phosphoryl groups of ATP, partially inhibits the reaction. Binding of the metal-ATP substrate to the enzyme occurs in a diffusion-controlled reaction followed by a 40 ° change in the glycosidic torsional angle. This conformational change results from strong interaction of the nucleotide base with the enzyme. NMR studies of four ATP-utilizing enzymes show a correlation between such conformational changes and high nucleotide base specificity. Heptapeptide substrates and substrate analogs bind to the active site of the catalytic subunit at a rate significantly lower than collision frequency indicating conformational selection by the enzyme or a subsequent slow conformational change. NMR studies of the conformation of the enzyme-bound peptide substrates have ruled out α-helical and β-pleated sheet structures. The results of kinetic studies of peptide substrates in which the amino acid sequence was systematically varied were used to rule out the obligatory requirement for all possible β-turn conformations within the heptapeptide although an enzymatic preference for a β_2–5 or β_3–6 turn could not be excluded. Hence if protein kinase has an absolute requirement for a specific secondary structure, then this structure must be a coil. In the enzyme-substrate complex the distance along the reaction coordinate between the γ-P of ATP and the serine oxygen of the peptide substrate (5.3 ± 0.7 Å) allows room for a metaphosphate intermediate. This finding together with kinetic observations as well as the location of the inhibitory metal suggest a dissociative mechanism for protein kinase, although a mechanism with some associative character remains possible. Regulation of protein kinase is accomplished by competition between the regulatory subunit and peptide or protein substrates at the active site of the catalytic subunit. Thus, the regulatory subunit is found by NMR to block the binding of the peptide substrate to the active site of protein kinase but allows the binding of the nucleotide substrate and divalent cations. The dissociation constant of the regulatory subunit from the active site (10^?10m) is increased ~10-fold by phosphorylation and ~10⁴-fold by the binding of cAMP, to a value (10^?5m) which exceeds the intracellular concentration of the R₂C₂ holoenzyme complex (10^?6m). The resulting dissociation of the holoenzyme releases the catalytic subunit, permitting the active site binding of peptide or protein substrates.     

A novel post-translational modification of yeast elongation factor 1A. Methylesterification at the C terminus

Protein methylation reactions can play important roles in cell physiology. After labeling intact Saccharomyces cerevisiae cells with S-adenosyl-l-[methyl-(3)H]methionine, we identified a major methylated 49-kDa polypeptide containing [(3)H]methyl groups in two distinct types of linkages. Peptide sequence analysis of the purified methylated protein revealed that it is eukaryotic elongation factor 1A (eEF1A, formerly EF-1alpha), the protein that forms a complex with GTP and aminoacyl-tRNAs for binding to the ribosomal A site during protein translation. Previous studies have shown that eEF1A is methylated on several internal lysine residues to give mono-, di-, and tri-N-epsilon-methyl-lysine derivatives. We confirm this finding but also detect methylation that is released as volatile methyl groups after base hydrolysis, characteristic of ester linkages. In cycloheximide-treated cells, methyl esterified eEF1A was detected largely in the ribosome and polysome fractions; little or no methylated protein was found in the soluble fraction. Because the base-labile, volatile [methyl-(3)H]radioactivity of eEF1A could be released by trypsin treatment but not by carboxypeptidase Y or chymotrypsin treatment, we suggest that the methyl ester is present on the alpha-carboxyl group of its C-terminal lysine residue. From the results of pulse-chase experiments using radiolabeled intact yeast cells, we find that the N-methylated lysine residues of eEF1A are stable over 4 h, whereas the eEF1A carboxyl methyl ester has a half-life of less than 10 min. The rapid turnover of the methyl ester suggests that the methylation/demethylation of eEF1A at the C-terminal carboxyl group may represent a novel mode of regulation of the activity of this protein in yeast.