Crystal structures of penicillin acylase enzyme-substrate complexes: structural insights into the catalytic mechanism

The crystal structure of penicillin G acylase from Escherichia coli has been determined to a resolution of 1.3 A from a crystal form grown in the presence of ethylene glycol. To study aspects of the substrate specificity and catalytic mechanism of this key biotechnological enzyme, mutants were made to generate inactive protein useful for producing enzyme-substrate complexes. Owing to the intimate association of enzyme activity and precursor processing in this protein family (the Ntn hydrolases), most attempts to alter active-site residues lead to processing defects. Mutation of the invariant residue Arg B263 results in the accumulation of a protein precursor form. However, the mutation of Asn B241, a residue implicated in stabilisation of the tetrahedral intermediate during catalysis, inactivates the enzyme but does not prevent autocatalytic processing or the ability to bind substrates. The crystal structure of the Asn B241 Ala oxyanion hole mutant enzyme has been determined in its native form and in complex with penicillin G and penicillin G sulphoxide. We show that Asn B241 has an important role in maintaining the active site geometry and in productive substrate binding, hence the structure of the mutant protein is a poor model for the Michaelis complex. For this reason, we subsequently solved the structure of the wild-type protein in complex with the slowly processed substrate penicillin G sulphoxide. Analysis of this structure suggests that the reaction mechanism proceeds via direct nucleophilic attack of Ser B1 on the scissile amide and not as previously proposed via a tightly H-bonded water molecule acting as a "virtual" base.     

Rat procathepsin B. Proteolytic processing to the mature form in vitro.

Expression of rat procathepsin B in yeast led to the secretion of both the latent and mature forms of the enzyme. Culture in the presence of a cysteine proteinase inhibitor prevented this processing. We have expressed and purified a mutant form of rat procathepsin B whose active-site cysteine residue has been changed to a serine, and which also lacks the glycosylation site in the mature region of the protein. This non-active mutant protein was secreted essentially in an unprocessed form. The purified protein has been incubated with a variety of proteinases, and results indicate that cathepsins D and L, as well as mature cathepsin B itself, can produce a processed (single-chain) form of cathepsin B from this precursor. Amino-terminal sequencing of these processed forms has revealed that they are all elongated by a few residues with respect to the mature form found in vivo. The action of a combination of cathepsin B with dipeptidylpeptidase I produced a single-chain form of cathepsin B with the correct amino terminus. This work has also shown that the processing of procathepsin B to a single-chain form can be an autocatalytic process, in at least an intermolecular manner.     

Structure mediation in substrate binding and post‐translational processing of penicillin acylases: Information from mutant structures of Kluyvera citrophila penicillin G acylase

Penicillin acylases are industrially important enzymes for the production of 6‐APA, which is used extensively in the synthesis of secondary antibiotics. The enzyme translates into an inactive single chain precursor that subsequently gets processed by the removal of a spacer peptide connecting the chains of the mature active heterodimer. We have cloned the penicillin G acylase from Kluyvera citrophila (KcPGA) and prepared two mutants by site‐directed mutagenesis. Replacement of N‐terminal serine of the β‐subunit with cysteine (Serβ1Cys) resulted in a fully processed but inactive enzyme. The second mutant in which this serine is replaced by glycine (Serβ1Gly) remained in the unprocessed and inactive form. The crystals of both mutants belonged to space group P1 with four molecules in the asymmetric unit. The three‐dimensional structures of these mutants were refined at resolutions 2.8 and 2.5 Å, respectively. Comparison of these structures with similar structures of Escherichia coli PGA (EcPGA) revealed various conformational changes that lead to autocatalytic processing and consequent removal of the spacer peptide. The large displacements of residues such as Arg168 and Arg477 toward the N‐terminal cleavage site of the spacer peptide or the conformational changes of Arg145 and Phe146 near the active site in these structures suggested probable steps in the processing dynamics. A comparison between the structures of the processed Serβ1Cys mutant and that of the processed form of EcPGA showed conformational differences in residues Argα145, Pheα146, and Pheβ24 at the substrate binding pocket. Three conformational transitions of Argα145 and Pheα146 residues were seen when processed and unprocessed forms of KcPGA were compared with the substrate bound structure of EcPGA. Structure mediation in activity difference between KcPGA and EcPGA toward acyl homoserine lactone (AHL) is elucidated.     

Crystal structure of the gamma-glutamyltranspeptidase precursor protein from Escherichia coli. Structural changes upon autocatalytic processing and implications for the maturation mechanism

Gamma-glutamyltranspeptidase (GGT) is an extracellular enzyme that plays a key role in glutathione metabolism. The mature GGT is a heterodimer consisting of L- and S-subunits that is generated by posttranslational cleavage of the peptide bond between Gln-390 and Thr-391 in the precursor protein. Thr-391, which becomes the N-terminal residue of the S-subunit, acts as the active residue in the catalytic reaction. The crystal structure of a mutant GGT, T391A, that is unable to undergo autocatalytic processing, has been determined at 2.55-A resolution. Structural comparison of the precursor protein and mature GGT demonstrates that the structures of the core regions in the two proteins are unchanged, but marked differences are found near the active site. In particular, in the precursor, the segment corresponding to the C-terminal region of the L-subunit occupies the site where the loop (residues 438-449) forms the lid of the gamma-glutamyl group-binding pocket in the mature GGT. This result demonstrates that, upon cleavage of the N-terminal peptide bond of Thr-391, the newly produced C terminus (residues 375-390) flips out, allowing the 438-449 segment to form the gamma-glutamyl group-binding pocket. The electron density map for the T391A protein also identified a water molecule near the carbonyl carbon atom of Gln-390. The spatial arrangement around the water and Thr-391 relative to the scissile peptide bond appears suitable for the initiation of autocatalytic processing, as in other members of the N-terminal nucleophile hydrolase superfamily.     

A bound water molecule is crucial in initiating autocatalytic precursor activation in an N-terminal hydrolase

Cephalosporin acylase is a member of the N-terminal hydrolase family, which is activated from an inactive precursor by autoproteolytic processing to generate a new N-terminal nucleophile Ser or Thr. The gene structure of the precursor cephalosporin acylases generally consists of a signal peptide that is followed by an alpha-subunit, a spacer sequence, and a beta-subunit. The cephalosporin acylase precursor is post-translationally modified into an active heterodimeric enzyme with alpha- and beta-subunits, first by intramolecular cleavage and, second, by intermolecular cleavage. Intramolecular autocatalytic proteolysis is initiated by nucleophilic attack of the residue Ser-1beta onto the adjacent scissile carbonyl carbon. This study determined the precursor structure after disabling the intramolecular cleavage. This study also provides experimental evidence showing that a conserved water molecule plays an important role in assisting the polarization of the OG atom of Ser-1beta to generate a strong nucleophile and to direct the OG atom of the Ser-1beta to a target carbonyl carbon. Intramolecular proteolysis is disabled as a result of a mutation of the residues causing conformational distortion to the active site. This is because distortion affects the existence of the catalytically crucial water at the proper position. This study provides the first evidence showing that a bound water molecule plays a critical role in initiating intramolecular cleavage in the post-translational modification of the precursor enzyme.     

Crystal structures of glutaryl 7-aminocephalosporanic acid acylase: insight into autoproteolytic activation

Glutaryl 7-aminocephalosporanic acid acylase (GCA, EC 3.5.1.11) is a member of N-terminal nucleophile (Ntn) hydrolases. The native enzyme is an (alpha beta)(2) heterotetramer originated from an enzymatically inactive precursor of a single polypeptide. The activation of precursor GCA consists of primary and secondary autoproteolytic cleavages, generating a terminal residue with both a nucleophile and a base and releasing a nine amino acid spacer peptide. We have determined the crystal structures of the recombinant selenomethionyl native and S170A mutant precursor from Pseudomonas sp. strain GK16. Precursor activation is likely triggered by conformational constraints within the spacer peptide, probably inducing a peptide flip. Autoproteolytic site solvent molecules, which have been trapped in a hydrophobic environment by the spacer peptide, may play a role as a general base for nucleophilic attack. The activation results in building up a catalytic triad composed of Ser170/His192/Glu624. However, the triad is not linked to the usual hydroxyl but the free alpha-amino group of the N-terminal serine residue of the native GCA. Mutagenesis and structural data support the notion that the stabilization of a transient hydroxazolidine ring during autoproteolysis would be critical during the N --> O acyl shift. The autoproteolytic activation mechanism for GCA is described.     

In vivo post-translational processing and subunit reconstitution of cephalosporin acylase from Pseudomonas sp. 130.

Cephalosporin acylases are a group of enzymes that hydrolyze cephalosporin C (CPC) and/or glutaryl 7-amino cephalosporanic acid (GL-7ACA) to produce 7-amino cephalosporanic acid (7-ACA). The acylase from Pseudomonas sp. 130 (CA-130) is highly active on GL-7ACA and glutaryl 7-aminodesacetoxycephalosporanic acid (GL-7ADCA), but much less active on CPC and penicillin G. The gene encoding the enzyme is expressed as a precursor polypeptide consisting of a signal peptide followed by alpha- and beta-subunits, which are separated by a spacer peptide. Removing the signal peptide has little effect on precursor processing or enzyme activity. Substitution of the first residue of the beta-subunit, Ser, results in a complete loss of enzyme activity, and substitution of the last residue of the spacer, Gly, leads to an inactive and unprocessed precursor. The precursor is supposed to be processed autocatalytically, probably intramolecularly. The two subunits of the acylase, which separately are inactive, can generate enzyme activity when coexpressed in Escherichia coli. Data on this and other related acylases indicate that the cephalosporin acylases may belong to a novel class of enzymes (N-terminal nucleophile hydrolases) described recently.     

Activation of the proteinase B precursor of the yeast Saccharomyces cerevisiae by autocatalysis and by an internal sequence.

Proteinase B (PrB) is a subtilisin-like serine protease found in the vacuole of the yeast Saccharomyces cerevisiae. It is first made as a large precursor that consists of a putative signal sequence, a 260-amino acid pro region, the serine protease domain, and two small COOH-terminal post regions (Moehle, C. M., Dixon, C. K., and Jones, E. W. (1989) J. Cell Biol. 108, 309-324). This precursor is glycosylated and proteolytically processed at least three times before mature enzyme is formed. To determine whether an intact PrB catalytic site is required for proteolytic processing of the precursor, point mutations were generated at the codons for the active site serine or aspartate residues by site-directed mutagenesis. The effect of these mutations on PrB processing suggests that the large pro region may be cleaved by an intramolecular, autocatalytic mechanism. The properties of a prb1 mutant that accumulates a 37-kDa precursor in addition to mature sized mutant PrB antigen suggests that the final proteolytic cleavage step is also autocatalytic. A prb1 deletion that lacks codons for the large pro region was made to test whether this part of the precursor is required for formation of mature PrB. Analysis of this mutant revealed two functions for this region: it prevents N-linked glycosylation of the serine protease domain and it allows the PrB precursor to be processed by proteinase A. The pro region can fulfill this latter function if added as a separate molecule, so long as glycosylation of the catalytic domain is prevented by other means.     

A novel 7-β-(4-carboxybutanamido)-cephalosporanic acid acylase isolated from Pseudomonas strain C427 and its high-level production in Escherichia coli

We cloned the gene for 7-β-(4-carboxybutanamido)-cephalosporanic acid (GL-7ACA) acylase from Pseudomonas strain C427. The DNA sequence revealed an open reading frame of 2154 bp coding for 718 amino acid residues. The deduced amino acid sequence consists of 4 structural domains: (i) a signal peptide (positions 1–27), (ii) a small subunit of the acylase (positions 28–190), designated as α, (iii) a spacer peptide (positions 191–198), (iv) a large subunit (positions 199–718), designated as β. Plasmids were constructed to direct the synthesis of the acylase in Escherichia coli and the following results were obtained. The active acylase consists of two subunits which are processed from a single precursor protein, removing the spacer peptide during processing. A proportion of active acylase is secreted into the periplasm and the remainder is retained in the cytoplasm. The amount of precursor protein accumulated in the cytoplasm is greatly reduced when plasmids for the acylase lacking the signal sequence are expressed. Therefore, processing is independent of the translocation of the gene product through the cytoplasmic membrane, in contrast to the situation for penicillin G acylase. A high level of active enzyme production was achieved with a plasmid coding for an acylase in which the amino terminal sequence (positions 1–32) of native acylase is replaced by MFPTT.     

The N-terminal nucleophile serine of cephalosporin acylase executes the second autoproteolytic cleavage and acylpeptide hydrolysis

Cephalosporin acylase (CA) precursor is translated as a single polypeptide chain and folds into a self-activating pre-protein. Activation requires two peptide bond cleavages that excise an internal spacer to form the mature αβ heterodimer. Using Q-TOF LC-MS, we located the second cleavage site between Glu(159) and Gly(160), and detected the corresponding 10-aa spacer (160)GDPPDLADQG(169) of CA mutants. The site of the second cleavage depended on Glu(159): moving Glu into the spacer or removing 5-10 residues from the spacer sequence resulted in shorter spacers with the cleavage at the carboxylic side of Glu. The mutant E159D was cleaved more slowly than the wild-type, as were mutants G160A and G160L. This allowed kinetic measurements showing that the second cleavage reaction was a first-order, intra-molecular process. Glutaryl-7-aminocephalosporanic acid is the classic substrate of CA, in which the N-terminal Ser(170) of the β-subunit, is the nucleophile. Glu and Asp resemble glutaryl, suggesting that CA might also remove N-terminal Glu or Asp from peptides. This was indeed the case, suggesting that the N-terminal nucleophile also performed the second proteolytic cleavage. We also found that CA is an acylpeptide hydrolase rather than a previously expected acylamino acid acylase. It only exhibited exopeptidase activity for the hydrolysis of an externally added peptide, supporting the intra-molecular interaction. We propose that the final CA activation is an intra-molecular process performed by an N-terminal nucleophile, during which large conformational changes in the α-subunit C-terminal region are required to bridge the gap between Glu(159) and Ser(170).     

Amino acid sequence of the active site of human serum cholinesterase from usual,atypical, and atypical-silent genotypes

Active-site tryptic peptides were isolated from three genetic types of human serum cholinesterase. The active-site peptide was identified by labeling the active-site serine with [³H] diisopropylfluorophosphate. Peptides were purified by high-performance liquid chromatography. Amino acid composition and sequence analysis showed that the peptide from the usual genotype contained 29 residues with the sequence Ser-Val-Thr-Leu-Phe-Gly-Glu-Ser-Ala-Gly-Ala-Ala-Ser-Val-Ser-Leu-His-Leu-Leu-Ser-Pro-Gly-Ser-His-Ser-Leu-Phe-Thr-Arg. The active-site serine was the eighth residue from the N- terminal. The peptide containing the active-site serine from the atypical genotype contained 22 residues with the sequence Ser-Val-Thr-Leu-Phe-Gly-Glu-Ser-Ala-Gly-Ala-Ala-Ser-Val-Ser-Leu-His-Leu-Leu-Ser-Pro-Gly. The peptide from the atypical-silent genotype contained eight residues with the sequence Gly-Glu-Ser-Ala-Gly-Ala-Ala-Ser. Thus, the sequences of the atypical and atypical-silent active-site peptides were identical to the corresponding portions of the usual peptide.This work was supported by U.S. Army Medical Research and Development Command Contract DAMD 17-82-C-2271 (to O.L.) and NIH Grant GM 27028 (to B.N.L.).     

The role of alpha-amino group of the N-terminal serine of beta subunit for enzyme catalysis and autoproteolytic activation of glutaryl 7-aminocephalosporanic acid acylase

Glutaryl 7-aminocephalosporanic acid (GL-7-ACA) acylase of Pseudomonas sp. strain GK16 catalyzes the cleavage of the amide bond in the GL-7-ACA side chain to produce glutaric acid and 7-aminocephalosporanic acid (7-ACA). The active enzyme is an (alphabeta)(2) heterotetramer of two non-identical subunits that are cleaved autoproteolytically from an enzymatically inactive precursor polypeptide. In this study, we prepared and characterized a chemically modified enzyme, and also examined an effect of the modification on enzyme catalysis and autocatalytic processing of the enzyme precursor. We found that treatment of the enzyme with cyanate ion led to a significant loss of the enzyme activity. Structural and functional analyses of the modified enzyme showed that carbamylation of the free alpha-amino group of the N-terminal Ser-199 of the beta subunit resulted in the loss of the enzyme activity. The pH dependence of the kinetic parameters indicates that a single ionizing group is involved in enzyme catalysis with pK(a) = 6.0, which could be attributed to the alpha-amino group of the N-terminal Ser-199. The carbamylation also inhibited the secondary processing of the enzyme precursor, suggesting a possible role of the alpha-amino group for the reaction. Mutagenesis of the invariant N-terminal residue Ser-199 confirmed the key function of its side chain hydroxyl group in both enzyme catalysis and autoproteolytic activation. Partial activity and correct processing of a mutant S199T were in agreement with the general mechanism of N-terminal nucleophile hydrolases. Our results indicate that GL-7-ACA acylase utilizes as a nucleophile Ser-199 in both enzyme activity and autocatalytic processing and most importantly its own alpha-amino group of the Ser-199 as a general base catalyst for the activation of the hydroxyl group both in enzyme catalysis and in the secondary cleavage of the enzyme precursor. All of the data also imply that GL-7-ACA acylase is a member of a novel class of N-terminal nucleophile hydrolases that have a single catalytic center for enzyme catalysis.     

Effects of site-directed mutations on processing and activities of penicillin G acylase from Escherichia coli ATCC 11105.

Penicillin G acylase from Escherichia coli ATCC 11105 is synthesized from its precursor polypeptide into a catalytically active heterodimer via a complex posttranslational processing pathway. Substitutions in the pair of aminoacyl residues at the cleavage site for processing the small and large subunits were made. Their processing phenotypes and penicillin G acylase activities were analyzed. By the introduction of a prolyl residue at either position, the processing of the small subunit was blocked without a change in enzymatic activity. Four other substitutions had no effect. At the site for processing the large subunit, four substitutions out of the seven examined blocked processing. In general, penicillin G acylase activity seemed to be proportional to the efficiency of the large-subunit-processing step. Ser-290 is an amino acid critical for processing and also for the enzymatic activity of penicillin G acylase. In the mutant pAATC, in which Ser-290 is mutated to Cys, the precursor is processed, but there is no detectable enzymatic activity. This suggests that there is a difference in the structural requirements for the processing pathway and for enzymatic activity. Recombination analysis of several mutants demonstrated that the small subunit can be processed only when the large subunit is processed first. Some site-directed mutants from which signal peptides were removed showed partial processing phenotypes and reduced enzymatic activities. Their expression showed that the prerequisite for penicillin G acylase activity is the efficient processing of the large subunit and that the maturation of the small subunit does not affect the enzymatic activity.     

Catalysis of poliovirus VP0 maturation cleavage is not mediated by serine 10 of VP2.

The maturation of the poliovirus capsid occurs as the result of a single unexplained proteolytic event during which 58 to 59 copies of the 60 VP0 capsid protein precursors are cleaved. An autocatalytic mechanism for cleavage of VP0 to VP4 and VP2 was proposed by Arnold et al. (E. Arnold, M. Luo, G. Vriend, M. G. Rossman, A. C. Palmenberg, G. D. Parks, M. J. Nicklin, and E. Wimmer, Proc. Natl. Acad. Sci. USA 84:21-25, 1987) in which serine 10 of VP2 is activated by virion RNA to catalyze VP4-VP2 processing. The hypothesis rests on the observation that a hydrogen bond was observed between serine 10 of VP2 (S2010) and the carboxyl terminus of VP4 in three mature picornaviral atomic structures: rhinovirus 14, mengovirus, and poliovirus type 1 (Mahoney). We constructed mutant viruses with cysteine (S2010C) or alanine (S2010A) replacing serine 10 of VP2; these exhibited normal proteolytic processing of VP0. While our results do not exclude an autocatalytic mechanism for the maturation cleavage, they do eliminate the conserved S2010 residue as the catalytic amino acid.     

Penicillin acylase from E. coli: unique gene-protein relation.

The nucleotide sequence of the gene (pac) coding for penicillin G acylase from E. coli ATCC 11105 was determined and correlated with the primary structure of the two constituent subunits of this enzyme. The pac gene open reading frame consists of four structural domains: Nucleotide positions 1-78 coding for a signal peptide, positions 79-705 coding for the alpha subunit, positions 706-867 coding for a spacer peptide, and positions 868-2538 coding for the beta subunit. Plasmids were constructed which direct the synthesis of a pac gene product lacking the signal peptide, and the synthesis of the alpha subunit or the beta subunit. The following results were obtained: The two dissimilar subunits are processing products of a single precursor polypeptide; the spacer peptide is removed during processing; the precursor polypeptide lacking the signal sequence is accumulated in the cytoplasm; it is not processed proteolytically in the cytoplasm and it does not display enzyme activity. Processing, therefore, requires translocation through the cytoplasmic membrane; processing follows a distinct sequential pathway in vitro.     

Mutations in the processing site of the precursor of ribulose-1,5-bisphosphate carboxylase/oxygenase small subunit: effects on import,processing, assembly and stability

The small subunit (SSU) of Rubisco is synthesized in the cytosol in a precursor form. Upon import into the chloroplast, it is proteolytically processed at a Cys-Met bond to yield the mature form of the protein. To assess the importance of the Met residue for recognition and processing by the stromal peptidase, we substituted this residue with either Thr, Arg or Asp. The mutant precursor proteins were imported into isolated chloroplasts, and the products of the import reactions were analyzed. Mutants containing Thr or Arg residues at the putative processing site were processed to a single peptide, comigrating with the wild-type protein. N-terminal radio-sequencing revealed that these mutants were processed at the Cys-Thr and the Cys-Arg bond, respectively. After import of the Asp-containing mutant, four processed forms of the protein were observed. Analysis of the most abundant one, co-migrating with the wild-type protein, demonstrated that this species was also a product of correct processing, at the Cys-Asp bond. All the correctly processed peptides were found to be associated with the holoenzyme of Rubisco, and remained stable within the chloroplast, like the wild-type protein. The results of this study, together with previous ones, suggest that proper recognition and processing of the SSU precursor are more affected by residues N-terminal to the processing site than by the residue on the C-terminal side of this site.     

Production of a fully functional, permuted single-chain penicillin G acylase

Penicillin G acylase (PGA) is a heterodimeric enzyme synthesized as a single-polypeptide precursor that undergoes an autocatalytic processing to remove an internal spacer peptide to produce the active enzyme. We constructed a single-chain PGA not dependent on autoproteolytic processing. The mature sequence of the beta-domain was expressed as the N terminus of a new polypeptide, connected by a random tetra-peptide to the alpha-domain, to afford a permuted protein. We found several active enzymes among variants differing in their linker peptides. Protein expression analysis showed that the functional single-chain variants were produced when using a Sec-dependent leader peptide, or when expressed inside the bacterial cytoplasm. Active-site titration experiments showed that the single-chain proteins displayed similar k(cat) values to the ones obtained with the wild-type enzyme. Interestingly, the single-chain proteins also displayed close to 100% of functional active sites compared to 40% to 70% functional yield usually obtained with the heterodimeric protein.     

SEA domain autoproteolysis accelerated by conformational strain: mechanistic aspects

A subclass of SEA (sea urchin sperm protein, enterokinase, and agrin) domain proteins undergoes autoproteolysis between glycine and serine in a conserved G^− 1S^+ 1VVV motif to generate stable heterodimers. Autoproteolysis has been suggested to involve only the intramolecular catalytic action of the conserved serine hydroxyl in combination with conformational strain of the glycine-serine peptide bond. We conducted a number of experiments and simulations on the SEA domain from the MUC1 mucin to test this mechanism. Alanine-scanning mutagenesis of polar residues in the vicinity of the cleavage site demonstrates that only the nucleophile at position + 1 is required for efficient proteolysis. Molecular modeling shows that an uncleaved trans peptide is incompatible with the native heterodimeric structure, resulting in disruption of secondary structure elements and distortion of the scissile peptide bond. Insertion of glycine residues (to obtain G_nG^− 1S^+ 1VVV motifs) appears to relieve strain, and autoproteolysis is 100 times slower in a 1G (n = 1) mutant and not measurable in 2G and 4G mutants. Removal of the catalytic serine hydroxyl hampers cleavage considerably, but measurable autoproteolysis of this S1098A mutant still proceeds in the presence of strain alone. The uncleaved SEA precursor populates interconverting partially folded conformations, and autoproteolysis coincides with adoption of proper β-sheet secondary structure and completed folding. Molecular dynamics simulations of the precursor show that the serine hydroxyl and the preceding glycine carbonyl carbon can be in van der Waals contact at the same time as the scissile peptide bond becomes strained. These observations are all consistent with autoproteolysis accelerated by N → O acyl shift and conformational strain imposed upon protein folding in a reaction for which the free-energy barrier is decreased by substrate destabilization rather than by transition-state stabilization. The energetics of this coupled folding and autoproteolysis mechanism is accounted for in an accompanying article.     

Cloning and Molecular Modeling of Duodenase with Respect to Evolution of Substrate Specificity within Mammalian Serine Proteases That Have Lost a Conserved Active-Site Disulfide Bond

Mammalian serine proteases such as the chromosome 14 (Homo sapiens, Mus musculus) located granzymes, chymases, cathepsin G, and related enzymes including duodenase collectively represent a special group within the chymotrypsin family which we refer to here as "granases". Enzymes of this group have lost the ancient active-site disulfide bond Cys191-Cys220 (bovine chymotrypsinogen A numbering) which is strongly conserved in classic serine proteases such as pancreatic, blood coagulation, and fibrinolysis proteases and others (granzymes A, M, K and leukocyte elastases). We sequenced the cDNA encoding bovine (Bos taurus) duodenase, a granase with unusual dual trypsin-like and chymotrypsin-like specificity. The sequence revealed a 17-residue signal peptide and two-residue (GlyLys) activation peptide typical for granases. Production of the mature enzyme is apparently accompanied by further proteolytic processing of the C-terminal pentapeptide extension of duodenase. Similar C-terminal processing is known for another dual-specific granase, human cathepsin G. Using phylogenetic analysis based on 39 granases we retraced the evolution of residues 189 and 226 crucial for serine protease primary specificity. The analysis revealed that while there is no obvious link between mutability of residue 189 and the appearance of novel catalytic properties in granases, the mutability of residue 226 evidently gives rise to different specificity subgroups within this enzyme group. The architecture of the extended substrate-binding site of granases and structural basis of duodenase dual specificity based on molecular dynamic method are discussed. We conclude that the marked selectivity of granases that is crucial to their role as regulatory proteases has evolved through the fine-tuning of specificity at three levels--primary, secondary, and conformational.     

Two-Step Autocatalytic Processing of the Glutaryl 7-Aminocephalosporanic Acid Acylase from Pseudomonas sp. Strain GK16

The glutaryl-7-aminocephalosporanic acid (GL-7-ACA) acylase of Pseudomonas sp. strain GK16 is an (αβ)₂ heterotetramer of two nonidentical subunits. These subunits are derived from nascent polypeptides that are cleaved proteolytically between Gly198 and Ser199 after the nascent polypeptides have been translocated into the periplasm. The activation mechanism of the GL-7-ACA acylase has been analyzed by both in vivo and in vitro expression studies, site-directed mutagenesis, in vitro renaturation of inactive enzyme precursors, and enzyme reconstitution. An active enzyme complex was found in the cytoplasm when its translocation into the periplasm was suppressed. In addition, the in vitro-expressed GL-7-ACA acylase was processed into α and β subunits, and the inactive enzyme aggregate of the precursor was also processed and became active during the renaturation step. Mutation of Ser199 to Cys199 and enzyme reconstitution allowed us to identify the secondary processing site that resides in the α subunit and to show that Ser199 of the β subunit is essential for these two sequential processing steps. Mass spectrometry clearly indicated that the secondary processing occurs at Gly189-Asp190. All of the data suggest that the enzyme is activated through a two-step autocatalytic process upon folding: the first step is an intramolecular cleavage of the precursor between Gly198 and Ser199 for generation of the α subunit, containing the spacer peptide, and the β subunit; the second is an intermolecular event, which is catalyzed by the N-terminal Ser (Ser199) of the β subunit and results in a further cleavage and the removal of the spacer peptide (Asp190 to Gly198).