Cathepsin D propeptide: mechanism and regulation of its interaction with the catalytic core

Propeptide blocks the active site in the inactive zymogen of cathepsin D and is cleaved off during zymogen activation. We have designed a set of peptidic fragments derived from the propeptide structure and evaluated their inhibitory potency against mature cathepsin D using a kinetic assay. Our mapping of the cathepsin D propeptide indicated two domains in the propeptide involved in the inhibitory interaction with the enzyme core: the active site "anchor" domain and the N-terminus of the propeptide. The latter plays a dominant role in propeptide inhibition (nanomolar Ki), and its high-affinity binding was corroborated by fluorescence polarization measurements. In addition to the inhibitory domains of propeptide, a fragment derived from the N-terminus of mature cathepsin D displayed inhibition. This finding supports its proposed regulatory function. The interaction mechanisms of the identified inhibitory domains were characterized by determining their modes of inhibition as well as by spatial modeling of the propeptide in the zymogen molecule. The inhibitory interaction of the N-terminal propeptide domain was abolished in the presence of sulfated polysaccharides, which interact with basic propeptide residues. The inhibitory potency of the active site anchor domain was affected by the Ala38pVal substitution, a propeptide polymorphism reported to be associated with the pathology of Alzheimer's disease. We infer that propeptide is a sensitive tethered ligand that allows for complex modulation of cathepsin D zymogen activation.     

A mutated bovine prochymosin zymogen can be activated without proteolytic processing at low pH

As a first step towards understanding how the zymogen structure of prochymosin contributes to the process by which active enzyme is produced, we altered the nucleotide sequence which encodes the amino-terminal (or propeptide) region of the protein. Of the two sites for autoproteolysis of prochymosin, one where pseudochymosin is formed at a pH of 2 and the other where chymosin is formed at pH 4-5, we changed the former by removing one codon and changing two other codons. This genetically modified prochymosin was proteolytically processed and activated normally at pH 4.5. However, at pH 2.0 we observed only partial activation of the zymogen and found no evidence of proteolytic processing. The properties of this engineered prochymosin suggest that zymogen activation does not require proteolysis and that the two different zymogen processing sites can function independently from one another.     

Autocatalytic activation of C1r subcomponent of the first component of human complement

Autoactivation of the proenzyme form of a subunit of the first component (C1r) was performed in the presence and absence of diisopropyl fluorophosphate (DFP). The time-course of autoactivation of zymogen C1r followed a sigmoidal curve and was accelerated by addition of the enzyme C1r and by increasing the concentration of C1r, suggesting that autoactivation of C1r consists of two intermolecular reactions, i.e. zymogen(C1r)- and enzyme(C1r)-catalyzed reactions. In the presence of 10 mM DFP, the enzyme-catalyzed autoactivation of C1r was completely inhibited, while the zymogen-catalyzed autoactivation still proceeded depending upon C1r concentration. These results suggested that the zymogen-catalyzed autoactivation of C1r is a DFP-insensitive second-order reaction and is mediated by an active site generated in a single chain C1r through a conformational change (Kassahara et al. (1982) FEBS lett. 141, 128-131). Based on these results, a possible reaction process of autoactivation of C1r was proposed, as follows: (formula; see text) where C1r represents a conformational isomer which catalyzes the autoactivation of C1r, and the rate constants, k2 and k3, are of second-order. Utilizing a computer, we simulated the autoactivation of C1r and found the above scheme to be a reasonable model of C1r autoactivation. Evidence which supports the formation of a conformational isomer of C1r, C1r, as an intermediate in its autoactivation was also obtained by a surface radiolabeling method.     

Role of zymogenicity-determining residues of coagulation factor VII/VIIa in cofactor interaction and macromolecular substrate recognition

Factor VIIa (VIIa) remains in a zymogen-like state following proteolytic activation and depends on interactions with the cofactor tissue factor (TF) for function. Val(21), Glu(154), and Met(156) are residues that are spatially close in available zymogen and enzyme structures, despite major conformational differences in the corresponding loop segments. This residue triad displays unusual side chain properties in comparison to the properties of other coagulation serine proteases. By mutagenesis, we demonstrate that these residues cooperate to stabilize the enzyme conformation and to enhance the affinity for TF. In zymogen VII, however, substitution of the triad did not change the cofactor affinity, further emphasizing the crucial role of the activation pocket in specifically stabilizing the active enzyme conformation. In comparison to VIIa(Q156), the triple mutant VIIa(N21I154Q156) had a stabilized amino-terminal Ile(16)-Asp(194) salt bridge and enhanced catalytic function. However, proteolytic and amidolytic activities of free VIIa variants were not concordantly increased. Rather, a negatively charged Asp at position 21 was the critical factor that determined whether an amidolytically more active VIIa variant also more efficiently activated the macromolecular substrate. These data thus demonstrate an unexpected complexity by which the zymogenicity-determining triad in the activation pocket of VIIa controls the active enzyme conformation and contributes to exosite interactions with the macromolecular substrate.     

Quantitative Characterization of the Activation Steps of Mannan-binding Lectin (MBL)-associated Serine Proteases (MASPs) Points to the Central Role of MASP-1 in the Initiation of the Complement Lectin Pathway

Mannan-binding lectin (MBL)-associated serine proteases, MASP-1 and MASP-2, have been thought to autoactivate when MBL/ficolin·MASP complexes bind to pathogens triggering the complement lectin pathway. Autoactivation of MASPs occurs in two steps: 1) zymogen autoactivation, when one proenzyme cleaves another proenzyme molecule of the same protease, and 2) autocatalytic activation, when the activated protease cleaves its own zymogen. Using recombinant catalytic fragments, we demonstrated that a stable proenzyme MASP-1 variant (R448Q) cleaved the inactive, catalytic site Ser-to-Ala variant (S646A). The autoactivation steps of MASP-1 were separately quantified using these mutants and the wild type enzyme. Analogous mutants were made for MASP-2, and rate constants of the autoactivation steps as well as the possible cross-activation steps between MASP-1 and MASP-2 were determined. Based on the rate constants, a kinetic model of lectin pathway activation was outlined. The zymogen autoactivation rate of MASP-1 is ∼3000-fold higher, and the autocatalytic activation of MASP-1 is about 140-fold faster than those of MASP-2. Moreover, both activated and proenzyme MASP-1 can effectively cleave proenzyme MASP-2. MASP-3, which does not autoactivate, is also cleaved by MASP-1 quite efficiently. The structure of the catalytic region of proenzyme MASP-1 R448Q was solved at 2.5 Å. Proenzyme MASP-1 R448Q readily cleaves synthetic substrates, and it is inhibited by a specific canonical inhibitor developed against active MASP-1, indicating that zymogen MASP-1 fluctuates between an inactive and an active-like conformation. The determined structure provides a feasible explanation for this phenomenon. In summary, autoactivation of MASP-1 is crucial for the activation of MBL/ficolin·MASP complexes, and in the proenzymic phase zymogen MASP-1 controls the process.     

Protein sorting in yeast: the localization determinant of yeast vacuolar carboxypeptidase Y resides in the propeptide

We have isolated cis-acting mutations in the gene encoding the yeast vacuolar protein carboxypeptidase Y (CPY) that result in missorting and aberrant secretion of up to 95% of newly synthesized CPY. The CPY polypeptides synthesized by these mutants use the late secretory pathway to exit the cell, since the late-acting sec1 mutation prevents their secretion. The mutant versions of CPY are secreted as the proCPY zymogen and are enzymatically activatable in vivo and in vitro. All the mutations, including small deletions and an amino acid substitution, map to the amino-terminal propeptide region and define a discrete yeast vacuolar localization domain whose integrity is required for efficient sorting of the CPY zymogen. Thus, the N-terminal propeptide of CPY carries out at least three functions: it mediates translocation across the endoplasmic reticulum, renders the enzyme inactive during transit, and targets the molecule to the vacuole.     

Streptomyces griseus Protease B: Secretion Correlates with the Length of the Propeptide

Streptomyces griseus protease B, a member of the chymotrypsin superfamily, is encoded by a gene that expresses a pre-pro-mature protein. During secretion the precursor protein is processed into a mature, fully folded protease. In this study, we constructed a family of genes which encode deletions at the amino-terminal end of the propeptide. The secretion of active protease B was seen to decrease in an exponential manner according to the length of the deletion. The results underscore the intimate relationship between folding and secretion in bacterial protease expression. They further suggest that the propeptide segment of the zymogen stabilizes the folding of the mature enzyme through many small binding interactions over the entire surface of the peptide rather than through a few specific contacts.     

Use of surface-enhanced laser desorption ionization protein chip system to analyze streptococcal exotoxin B activity secreted by Streptococcus pyogenes.

Ciphergen surface-enhanced laser desorption ionization (SELDI) protein chip technology was used to analyze the secretion and autoactivation of the Streptococcus pyogenes cysteine protease SpeB. This method allowed rapid identification of both the zymogen form of the protein Mr approximately 41,000 and the fully active enzyme Mr approximately 28,500. SpeB production in culture supernatants was demonstrated to be growth-phase regulated and SpeB positive and negative variants of a blood passaged S. pyogenes isolate could readily be distinguished. In kinetic studies of the autoactivation of the zymogen form of SpeB, the sequential generation of four intermediates was detected before the accumulation of the fully active enzyme. The methods described enabled enhanced speed, use of lower sample volumes and concentrations, and a more complete molecular characterization of SpeB than allowed by existing methods of analysis using SDS-PAGE and Western immunoblotting.     

Activation profiles of the zymogen of aspergilloglutamic peptidase

Aspergilloglutamic peptidase produced by Aspergillus niger var. macrosporus belongs to the novel glutamic peptidase family. Its zymogen is autocatalytically activated under acidic conditions to the mature enzyme with a two-chain structure. Analyses by SDS-PAGE and mass spectrometry of the activation products of the recombinant zymogen showed that the major pathway of activation includes initial fast cleavage at Glu12-Ala13, followed by stepwise cleavages in the N-terminal and intervening propeptide regions. Essentially the same activation profile was obtained with the recombinant zymogen lacking the N-terminal 12-aa sequence. The missing region includes the most prominent cluster of basic residues of the propeptide, indicating low importance of this cluster for activation and refolding of the zymogen.     

Disulfide-linked propeptides stabilize the structure of zymogen and mature pancreatic serine proteases.

Chymotrypsinogen and proelastase 2 are the only pancreatic proteases with propeptides that remain attached to the active enzyme via a disulfide bridge. It is likely, although not proven, that these propeptides are functionally important in the active enzymes, as well as in the zymogens. A mutant chymotrypsin was constructed to test this hypothesis, but it was demonstrated that the lack of the propeptide had no effect on the catalytic efficiency, substrate specificity, or folding of the protein [Venekei, I., et al. (1996) FEBS Lett. 379, 139-142]. In this paper, we investigate the role of the disulfide-linked propeptide in the conformational stability of chymotrypsin(ogen). We compare the stabilities of the wild-type and mutant proteins (lacking propeptide-enzyme interactions) in their zymogen (chymotrypsinogen) and active (chymotrypsin) forms. The mutants exhibited a substantially increased sensitivity to heat denaturation and guanidine hydrochloride unfolding, and a faster loss of activity at extremes of pH relative to those of their wild-type counterparts. From guanidine hydrochloride denaturation experiments, we determined that covalently linked propeptide provides about 24 kJ/mol of free energy of extra stabilization (DeltaDeltaG). In addition, the mutant chymotrypsinogen lacked the normal resistance to digestion by pepsin. This may also explain (besides keeping the zymogen inactive) the evolutionary conservation of the propeptide-enzyme interactions. Tryptophan fluorescence, circular dichroism, microcalorimetric, and activity measurements suggest that the propeptide of chymotrypsin restricts the relative mobility between the two domains of the molecule. In pancreatic serine proteases, such as trypsin, that lose the propeptide upon activation, this function appears to be accomplished via alternative interdomain contacts.     

Identification of critical residues in the propeptide of LasA protease of Pseudomonas aeruginosa involved in the formation of a stable mature protease

LasA protease is a 20-kDa elastolytic and staphylolytic enzyme secreted by Pseudomonas aeruginosa. LasA is synthesized as a preproenzyme that undergoes proteolysis to remove a 22-kDa amino-terminal propeptide. Like the propeptides of other bacterial proteases, the LasA propeptide may act as an intramolecular chaperone that correctly folds the mature domain into an active protease. To locate regions of functional importance within proLasA, linker-scanning insertional mutagenesis was employed using a plasmid containing lasA as the target. Among the 5 missense insertions found in the mature domain of proLasA, all abolished enzymatic activity but not secretion. In general, the propeptide domain was more tolerant to insertions. However, insertions within a 9-amino-acid region in the propeptide caused dramatic reductions in LasA enzymatic activity. All mutant proLasA proteins were still secreted, but extracellular stability was low due to clustered insertions within the propeptide. The codons of 16 residues within and surrounding the identified 9-amino-acid region were subjected to site-directed mutagenesis. Among the alanine substitutions in the propeptide that had a major effect on extracellular LasA activity, two (L92A and W95A) resulted in highly unstable proteins that were susceptible to proteolytic degradation and three (H94A, I101A, and N102A) were moderately unstable and allowed the production of a LasA protein with low enzymatic activity. These data suggest that these clustered residues in the propeptide may play an important role in promoting the correct protein conformation of the mature LasA protease domain.     

Isolation and partial characterization of the amino-terminal propeptide of type II procollagen from chick embryos

The amino-terminal propeptide from type II procollagen was isolated from organ cultures of sternal cartilages from 17-day-old chick embryos. The procedure provided the first isolation of the propeptide in amounts adequate for chemical characterization. The propeptide had an apparent molecular weight of 18000 as estimated by gel electrophoresis in sodium dodecyl sulfate. It contained a collagen-like domain as demonstrated by its amino acid composition, circular dichroism spectrum, and susceptibility to bacterial collagenase. One residue of hydroxylysine was present, the first time this amino acid has been detected in a propeptide. The peptide contained no methionine and only two residues of half-cystine. Antibodies were prepared to the propeptide and were used to establish its identity. The antibodies precipitated type II procollagen but did not precipitate type II procollagen from which the amino and carboxy propeptides were removed with pepsin. Also, they did not precipitate the carboxy propeptide of type II procollagen. The data demonstrated th at the type II amino propeptide was similar to the amino propeptides of type I and type III procollagens in that it contained a collagen-like domain. It differed, however, in that it lacked a globular domain as large as the globular domain of 77-86 residues found at the amino-terminal ends of the pro alpha 1 chains of type I and type III procollagens.     

The role of the cathepsin E propeptide in correct folding, maturation and sorting to the endosome

Cathepsin E (CE) is an endosomal aspartic proteinase of the A1 family that is highly homologous to the lysosomal aspartic proteinase cathepsin D (CD). Newly synthesized CE undergoes several proteolytic processing events to yield mature CE, from which the N-terminal propeptide usually comprising 39 amino acids is removed. To define the role of the propeptide of CE in its biosynthesis and processing, we constructed two fusion proteins using chimeric DNAs encoding the CE propeptide fused to the mature CD tagged with HA at the COOH terminus (termed ED-HA) and encoding the CD propeptide fused to the mature CE (termed DE). Pulse-chase analysis revealed that wild-type CE expressed in human embryonic kidney cells is autoproteolytically processed into mature CE within a 12-h chase, whereas the chimeric DE failed to be converted into mature CE even after a 24-h chase. The DE chimera was nevertheless capable of acid-dependent autoactivation in vitro to yield a catalytically active form, although its specificity constants (kcat/Km) were considerably high but less (35%) than those of the wild-type CE. By contrast, the chimeric ED-HA expressed in HeLa cells underwent neither processing into a catalytically active enzyme nor acid-dependent autoactivation in vitro. The ED-HA protein was less stable than wt-CD-HA, as determined on pulse-chase analysis and on trypsin digestion. These data indicate that the propeptide of CE is essential for the correct folding, maturation, and targeting of this protein to its final destination.     

A true autoactivating enzyme. Structural insight into mannose-binding lectin-associated serine protease-2 activations

Few reports have described in detail a true autoactivation process, where no extrinsic cleavage factors are required to initiate the autoactivation of a zymogen. Herein, we provide structural and mechanistic insight into the autoactivation of a multidomain serine protease: mannose-binding lectin-associated serine protease-2 (MASP-2), the first enzymatic component in the lectin pathway of complement activation. We characterized the proenzyme form of a MASP-2 catalytic fragment encompassing its C-terminal three domains and solved its crystal structure at 2.4 A resolution. Surprisingly, zymogen MASP-2 is capable of cleaving its natural substrate C4, with an efficiency about 10% that of active MASP-2. Comparison of the zymogen and active structures of MASP-2 reveals that, in addition to the activation domain, other loops of the serine protease domain undergo significant conformational changes. This additional flexibility could play a key role in the transition of zymogen MASP-2 into a proteolytically active form. Based on the three-dimensional structures of proenzyme and active MASP-2 catalytic fragments, we present model for the active zymogen MASP-2 complex and propose a mechanism for the autoactivation process.     

The amino-terminal sequence of the catalytic subunit of bovine enterokinase

Bovine enterokinase (enteropeptidase) is a serine protease and functions as the physiological activator of trypsinogen. The enzyme has a heavy chain (115 kD) covalently linked to a light or catalytic subunit (35 kD). The amino acid composition showed that the light chain has nine half-cystine residues (four as intramolecular disulfides) and that one half-cystine was in a disulfide link between the light and heavy subunits. The amino-terminal 27 residues of the S-vinylpyridyl derivative of the light chain were determined by gas-phase Edman degradation. The sequence has homologies with other serine proteases containing one or two chains. The homologies suggest that the catalytic subunit has the same three-dimensional structure and, therefore, the same mechanism of enzymatic action as pancreatic chymotrypsin, trypsin, and elastase. The presence of the conserved amino-terminal activation peptide sequence (IVGG) shows that enterokinase must have a zymogen precursor and that the two-chain enzyme arises from limited proteolysis during posttranslational processing.     

Vitamin K-dependent carboxylase: influence of the "propeptide" region on enzyme activity

The liver microsomal vitamin K-dependent carboxylase catalyzes the post-translational conversion of specific glutamyl to gamma-carboxyglutamyl (Gla) residues in precursor forms of a limited number of proteins. These proteins contain an amino-terminal extension (propeptide) that is presumed to serve as an enzyme recognition site to assure their normal processing. The free, noncovalently bound propeptide has also been shown to stimulate the in vitro activity of this enzyme. This peptide has now been shown to lower the app Km of a low-molecular-weight Glu site substrate while having no influence on the app Km of the other substrates, vitamin KH2, O2, and CO2/HCO3-. Propeptide addition was shown to have no influence on the ratio of the two products of the enzyme, Gla and vitamin K-2,3-epoxide. Stimulation of carboxylase activity by the propeptide from human factor X was observed in a number of rat tissues and in the liver of a number of different species. Stability of the enzyme in crude microsomal preparations was greatly enhanced by the presence of propeptide. These observations are consistent with the hypothesis that this region of the protein substrates for the carboxylase not only serves an enzyme recognition or docking function but also modulates the activity of the enzyme by altering the affinity for one of its substrates.     

Proregion of Bombyx mori cysteine proteinase functions as an intramolecular chaperone to promote proper folding of the mature enzyme.

A cDNA encoding the proform of Bombyx cysteine proteinase (BCP) was expressed at a high level in Escherichia coli using the T7 polymerase expression system. The insoluble recombinant zymogen was solubilized and renatured by modifying a method applied to human pro-cathepsin L. Like the natural BCP precursor, the recombinant proenzyme was spontaneously converted to an active proteinase at pH 3.75. A deletion in the central region of the propeptide resulted in much loss of the activity, suggesting that the propeptide is essential for proper folding during renaturation. In contrast, the renatured mature form of recombinant BCP was not active but regained activity by including the propeptide in the renaturing buffer, suggesting that the propeptide, acting as an intramolecular chaperone, promotes refolding of the associated proteinase domain into an active conformation. The mature form of natural BCP rapidly lost its activity at neutral pH, whereas its proform was stable. The mature enzyme retained some activity in the presence of the propeptide. Arch.     

Proclotting enzyme from horseshoe crab hemocytes. cDNA cloning, disulfide locations, and subcellular localization

Proclotting enzyme is an intracellular serine protease zymogen closely associated with an endotoxin-sensitive hemolymph coagulation system in limulus. Its active form, clotting enzyme, catalyzes conversion of coagulogen to insoluble coagulin gel. We present here the cDNA and amino acid sequences, disulfide locations, and subcellular localization of proclotting enzyme. The isolated cDNA for proclotting enzyme consists of 1,501 base pairs. The open reading frame of 1,125 base pairs encodes a sequence comprising 29 amino acid residues of prepro-sequence and 346 residues of the mature protein with a molecular mass of 38,194 Da. Three potential glycosylation sites for N-linked carbohydrate chains were confirmed to be glycosylated. Moreover, the zymogen contains six O-linked carbohydrate chains in the amino-terminal light chain generated after activation. The cleavage site that accompanies activation catalyzed by trypsin-like active factor B, proved to be an Arg-Ile bond. The resulting carboxyl-terminal heavy chain is composed of a typical serine protease domain, with a sequence similar to that of human coagulation factor XIa (34.5%) or factor Xa (34.1%). The light chain has a unique disulfide-knotted domain which shows no significant homology with any other known proteins. Thus, this proclotting enzyme has a mammalian serine protease domain and a structural domain not heretofore identified in coagulation and complement factors. Immunohistochemical studies showed that the proclotting enzyme is localized in large granules of hemocytes.     

Structural insights into the activation and inhibition of histo-aspartic protease from Plasmodium falciparum

Histo-aspartic protease (HAP) from Plasmodium falciparum is a promising target for the development of novel antimalarial drugs. The sequence of HAP is highly similar to those of pepsin-like aspartic proteases, but one of the two catalytic aspartates, Asp32, is replaced with histidine. Crystal structures of the truncated zymogen of HAP and of the complex of the mature enzyme with inhibitor KNI-10395 have been determined at 2.1 and 2.5 ? resolution, respectively. As in other proplasmepsins, the propeptide of the zymogen interacts with the C-terminal domain of the enzyme, forcing the N- and C-terminal domains apart, thereby separating His32 and Asp215 and preventing formation of the mature active site. In the inhibitor complex, the enzyme forms a tight domain-swapped dimer, not previously seen in any aspartic proteases. The inhibitor is found in an unprecedented conformation resembling the letter U, stabilized by two intramolecular hydrogen bonds. Surprisingly, the location and conformation of the inhibitor are similar to those of the fragment of helix 2 comprising residues 34p-38p in the prosegments of the zymogens of gastric aspartic proteases; a corresponding helix assumes a vastly different orientation in proplasmepsins. Each inhibitor molecule is in contact with two molecules of HAP, interacting with the carboxylate group of the catalytic Asp215 of one HAP protomer through a water molecule, while also making a direct hydrogen bond to Glu278A' of the other protomer. A comparison of the shifts in the positions of the catalytic residues in the inhibitor complex presented here with those published previously gives further hints regarding the enzymatic mechanism of HAP.     

Mutational analysis of Bacillus subtilis glutamine phosphoribosylpyrophosphate amidotransferase propeptide processing

Glutamine phosphoribosylpyrophosphate amidotransferase from Bacillus subtilis is a member of an N-terminal nucleophile hydrolase enzyme superfamily, several of which undergo autocatalytic propeptide processing to generate the mature active enzyme. A series of mutations was analyzed to determine whether amino acid residues required for catalysis are also used for propeptide processing. Propeptide cleavage was strongly inhibited by replacement of the cysteine nucleophile and two residues of an oxyanion hole that are required for glutaminase function. However, significant propeptide processing was retained in a deletion mutant with multiple defects in catalysis that was devoid of enzyme activity. Intermolecular processing of noncleaved mutant enzyme subunits by active wild-type enzyme subunits was not detected in hetero-oligomers obtained from a coexpression experiment. While direct in vitro evidence for autocatalytic propeptide cleavage was not obtained, the results indicate that some but not all of the amino acid residues that have a role in catalysis are also needed for propeptide processing.