Inhibition of aspartic proteinases by propart peptides of human procathepsin D and chicken pepsinogen

The Relationship between the Concentration of Cathepsin A, D, and E and the Concentration of Copper and Zinc, and the Size of the Aneurysmal Enlargement in the Wall of the Abdominal Aortic Aneurysm

BACKGROUND

Despite advances in diagnostics and treatment, aortic aneurysms are an important clinical problem, mainly due to the accompanying complications that may lead to direct loss of life, also the number of diagnosed and operated aneurysms is constantly increasing. The aim of this study is to determine the relationship between the concentration of lysosomal peptidases cathepsin A, D, and E in the wall of the abdominal aortic aneurysm and the concentration of copper and zinc, and the size of the aneurysm widening in the wall of the abdominal aortic aneurysm.

METHODS

The study included 27 patients with abdominal aortic aneurysm from the Department of Vascular Surgery and Transplantation of the University Clinical Hospital in Bialystok. The research material was the wall of the abdominal aortic aneurysm collected intraoperatively. The control material consisted of fragments of the abdominal aorta obtained from organ donors for transplantation. The concentration of cathepsin A, D, and E was determined using enzyme-linked immunosorbent assays. Concentrations of copper and zinc were determined by flame atomic absorption spectrometry after prior mineralization of the samples. All patients were interviewed and asked about basic demographic data, comorbidities, and risk factors for cardiovascular disease to which they were exposed in the past. The statistical analysis was performed using Statistica 10 statistical package. Mann-Whitney U-tests were used and also Spearman's r correlation assuming a significance level of P < 0.05.

RESULTS

The concentration of cathepsin A, D, and E was higher in the aortic wall altered by the aneurysm than in the wall of the control aorta (P < 0.05). The analysis of the data showed that there was a positive correlation between the concentration of cathepsin A and D and the width of the aneurysmal widening (r = 0.699 and 0.750, respectively). There was no correlation between cathepsin E concentration and aneurysm width.

CONCLUSIONS

The higher contents of cathepsin A, D, and E in the wall of the aortic aneurysm than in the normal aortic wall, as well as a positive correlation between the concentration of cathepsin A and D and the width of the aneurysmal widening, allow to assume the participation of these enzymes in the pathogenesis of the aneurysm.

Propeptides as modulators of functional activity of proteases

Most proteases are synthesized in the cell as precursor-containing propeptides. These structural elements can determine the folding of the cognate protein, function as an inhibitor/activator peptide, mediate enzyme sorting, and mediate the protease interaction with other molecules and supramolecular structures. The data presented in this review demonstrate modulatory activity of propeptides irrespective of the specific mechanism of action. Changes in propeptide structure, sometimes minor, can crucially alter protein function in the living organism. Modulatory activity coupled with high variation allows us to consider propeptides as specific evolutionary modules that can transform biological properties of proteases without significant changes in the highly conserved catalytic domains. As the considered properties of propeptides are not unique to proteases, propeptide-mediated evolution seems to be a universal biological mechanism.

Recombinant prosegment peptide acts as a folding catalyst and inhibitor of native pepsin

Porcine pepsin A, a gastric aspartic peptidase, is initially produced as the zymogen pepsinogen that contains an N-terminal, 44 residue prosegment (PS) domain. In the absence of the PS, native pepsin (Np) is irreversibly denatured and when placed under refolding conditions, folds to a thermodynamically stable denatured state. This denatured, refolded pepsin (Rp) state can be converted to Np by the exogenous addition of the PS, which catalyzes the folding of Rp to Np. In order to thoroughly study the mechanism by which the PS catalyzes pepsin folding, a soluble protein expression system was developed to produce recombinant PS peptide in a highly pure form. Using this system, the wild-type and three-mutant PS forms, in which single residue substitutions were made (V4A, R8A and K36A), were expressed and purified. These PS peptides were characterized for their ability to inhibit Np enzymatic activity and to catalyze the folding of Rp to Np. The V4A, R8A and K36A mutant PS peptides were found to have nanomolar inhibition constants, Ki, of 82.4, 58.3 and 95.6 nM, respectively, approximately a two-fold increase from that of the wild-type PS (36.2 nM). All three-mutant PS peptides were found to catalyze Np folding with a rate constant of 0.06 min(-1), five-fold lower than that of the wild-type. The observation that the mutant PS peptides retained their inhibition and folding-catalyst functionality suggests a high level of resilience to mutations of the pepsin PS.

Protective effects of a cysteine proteinase propeptide expressed in transgenic soybean roots

Sedentary endoparasitic nematodes cause extensive damage to a large number of ornamental plants and food crops, with estimated economical losses over 100 billion US$ worldwide. Various efforts have put forth in order to minimize nematode damage, which typically involve the use of nematicides that have high cost and enhanced toxicity to humans and the environment. Additionally, different strategies have been applied in order to develop genetically modified plants with improved nematode resistance. Among the strategies are anti-invasion and migration, feeding-cell attenuation, and anti-nematode feeding. In the present study, we focus on anti-nematode feeding, which involves the evaluation and potential use of the cysteine proteinase (CPs) propeptide as a control alternative. The cysteine proteinase prodomain, isolated from Heterodera glycines (HGCP prodomain), is a natural inhibitory peptide used to transform soybean cotyledons using Agrobacterium rhizogenes. Genetically modified soybean roots expressing the propeptide were detected by Western blot and expression levels were measured by ELISA (around 0.3%). The transgenic roots expressing the propeptide were inoculated with a thousand H. glycines at the second juvenile stage, and a remarkable reduction in the number of females and eggs was observed. A reduction of female length and diameter was also observed after 35 days post-inoculation. Furthermore, the H. glycines mature protein was detected in females fed on soybean transformed root expressing or not expressing the propeptide. The data presented here indicate that the HGCP propeptide can reduce soybean cyst nematode infection and this strategy could be applied in the near future to generate resistant crop cultivars.

Multifunctional aspartic peptidase prosegments

The structure-function relationships of aspartic peptidases (APs) (EC 3.4.23.X) have been extensively investigated, yet much remains to be elucidated regarding the various molecular mechanisms of these enzymes. Over the past years, APs have received considerable interest for food applications (e.g. cheese, fermented foods) and as potential targets for pharmaceutical intervention in human diseases including hypertension, cancer, Alzheimer's disease, AIDS (acquired immune deficiency syndrome), and malaria. A deeper understanding of the structure and function of APs, therefore, will have a direct impact on the design of peptidase inhibitors developed to treat such diseases. Most APs are synthesized as zymogens which contain an N-terminal prosegment (PS) domain that is removed at acidic pH by proteolytic cleavage resulting in the active enzyme. While the nature of the AP PS function is not entirely understood, the PS can be important in processes such as the initiation of correct folding, protein stability, blockage of the active site, pH-dependence of activation, and intracellular sorting of the zymogen. This review summarizes the current knowledge of AP PS function (especially within the A1 family), with particular emphasis on protein folding, cellular sorting, and inhibition.

Human cathepsin D

A literature survey was performed of human cathepsin D gene, cathepsin D biosynthesis, posttranslatory modifications, transport within the cell, substrate specificity and catalytic effect. Methods used to determine the activity and level of this proteinase as well as its role in the biochemistry and pathobiochemistry of cells, tissues and organs were considered.

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.

The N-terminal propeptide of Vibrio vulnificus extracellular metalloprotease is both an inhibitor of and a substrate for the enzyme

Vibrio vulnificus, a marine bacterium capable of causing wound infection and septicemia, secretes a 45-kDa metalloprotease (vEP) with many biological activities. The precursor of vEP consists of four regions: a signal peptide, an N-terminal propeptide (nPP), a C-terminal propeptide, and the mature protease. Two forms of vEP-vEP-45, which contains the mature protease plus the C-terminal propeptide, and vEP-34, which contains only the mature protease-were expressed in Escherichia coli and purified. vEP-45 and vEP-34 had similar activities with azocasein as a substrate, but vEP-34 had reduced activity toward insoluble proteins. The nPP of vEP was expressed as a His tag fusion protein, and its effect on vEP activity was investigated. nPP inhibited the activities of both vEP-45 and vEP-34 but not that of thermolysin, a different but related zinc-dependent protease. The inhibition of vEP by nPP was further examined using vEP-34 as a representative enzyme. The inhibition could be completely reversed under conditions of low enzyme and propeptide concentrations and with prolonged incubation, which resulted from the degradation of nPP by vEP. However, even at high nPP and vEP concentrations, inhibition of vEP by nPP at high temperatures was not effective, resulting in the degradation of both nPP and vEP. These results demonstrate that the nPP of vEP could bind to vEP and inhibit its activity, resulting in the degradation of the propeptide.

A new mechanism for prolactin processing into 16K PRL by secreted cathepsin D

Cathepsins are lysosomal enzymes that were shown to release the antiangiogenic fragments 16K prolactin (PRL), endostatin, and angiostatin by processing precursors at acidic pH in vitro. However, the physiological relevance of these findings is questionable because the neutral pH of physiological fluids is not compatible with the acidic conditions required for the proteolytic activity of these enzymes. Here we show that cathepsin D secreted from various tissues is able to process PRL into 16K PRL outside the cell. To specifically target extracellular proteolysis, we used tissues from PRL receptor-deficient mice, which are unable to internalize PRL. As assessed by the use of specific inhibitors of proton extruders, we show that the proteolytic activity of cathepsin D requires local acid secretion driven by Na(+)/H(+) exchangers and H(+)/ATPase. Although it is usually assumed that cathepsin-mediated generation of antiangiogenic peptides occurs in the moderately acidic pericellular milieu found in malignant tumors, we propose a new mechanism explaining the extracellular activity of this acidic protease under physiological pH. Our data support the concept that secreted lysosomal enzymes could be involved in the maintenance of angiogenesis dormancy via the generation of active antiangiogenic peptides in nonpathological contexts.

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.

Functional characterization of the propeptide of Plasmodium falciparum subtilisin-like protease-1

Erythrocyte invasion by the malaria merozoite is prevented by serine protease inhibitors. Various aspects of the biology of Plasmodium falciparum subtilisin-like protease-1 (PfSUB-1), including the timing of its expression and its apical location in the merozoite, suggest that this enzyme is involved in invasion. Recombinant PfSUB-1 expressed in a baculovirus system is secreted in the p54 form, noncovalently bound to its cognate propeptide, p31. To understand the role of p31 in PfSUB-1 maturation, we examined interactions between p31 and both recombinant and native enzymes. CD analyses revealed that recombinant p31 (rp31) possesses significant secondary structure on its own, comparable with that of folded propeptides of some bacterial subtilisins. Kinetic studies demonstrated that rp31 is a fast binding, high affinity inhibitor of PfSUB-1. Inhibition of two bacterial subtilisins by rp31 was much less effective, with inhibition constants 49-60-fold higher than that for PfSUB-1. Single (at the P4 or P1 position) or double (at P4 and P1 positions) point mutations of residues within the C-terminal region of rp31 had little effect on its inhibitory activity, and truncation of 11 residues from the rp31 C terminus substantially reduced, but did not abolish, inhibition. None of these modifications prevented binding to the PfSUB-1 catalytic domain or rendered the propeptide susceptible to proteolytic digestion by PfSUB-1. These studies provide new insights into the function of the propeptide in PfSUB-1 activation and shed light on the structural requirements for interaction with the catalytic domain.

Utility of (His)6 tag for purification and refolding of proplasmepsin-2 and mutants with altered activation properties

Plasmepsin-2 is a malarial aspartic proteinase that has been implicated in the initial steps of hemoglobin degradation in parasites and thus represents an attractive antimalarial target. Escherichia coli expressed proplasmepsin-2 is capable of activation at acidic pH by autocatalytic cleavage of the pro part region, which results in products of different length. We designed a 10-amino-acid deletion in the pro part region that allows faster generation of homogeneous enzyme upon activation. Incorporation of a (His)6 tag onto the N-terminus of the pro part enables on-column refolding of proplasmepsin-2 and simplifies proenzyme purification and pro part separation after activation. The proposed purification procedure results in highly pure and easily crystallizable enzyme.

The pro domain of beta-secretase does not confer strict zymogen-like properties but does assist proper folding of the protease domain

beta-Secretase (BACE) is a membrane-bound aspartyl protease that cleaves the amyloid precursor protein to generate the N terminus of the amyloid beta peptide. BACE is expressed as a precursor protein containing Pre, Pro, protease, transmembrane, and cytosolic domains. A soluble BACE derivative (PreProBACE460) that is truncated between the protease and transmembrane domains was produced by baculovirus-mediated expression. ProBACE460 was purified from conditioned media of infected insect cells using immobilized concanavalin A and immobilized BACE inhibitor, P10-P4' Stat(Val). Furin cleaves ProBACE460 between the Pro and protease regions to generate mature BACE460. The k(cat)/K(m) of ProBACE460 when assayed with a polypeptide substrate is only 2.3-fold less than that of BACE460. This finding and the similar inhibitory potency of P10-P4' Stat(Val) for ProBACE460 and BACE460 suggest that the Pro domain has little effect on the BACE active site. Exposure of ProBACE460 to guanidine denaturation/renaturation results in a 7-fold higher recovery of BACE activity than when BACE460 is similarly treated. The presence of free BACE Pro peptide during renaturation of BACE460 but not ProBACE460 increases recovery of activity. These findings show that the Pro domain in ProBACE460 does not suppress activity as in a strict zymogen but does appear to facilitate proper folding of an active protease domain.

Purification and characterization of active recombinant human napsin A

Recombinant human napsin A expressed in human embryonic kidney 293 cells was purified to homogeneity by a single-step procedure using part of napsin A propeptide as affinity ligand. N-Terminal amino-acid sequencing of the purified enzyme identified the mature form of napsin A. Treatment of purified napsin A with endoglycosidases F and H resulted in a decrease in its molecular mass from 39 kDa to approximately 37 kDa, confirming that napsin A is glycosylated. The kinetic properties were analyzed by using two fluorogenic synthetic substrates K(Dabsyl)-TSLLMAAPQ-Lucifer yellow (DS1) and K(Dabsyl)-TSVLMAAPQ-Lucifer yellow (DS3). The Km values obtained were 1.7 microM and 6.2 microM, respectively. A substrate-specificity study using a napsin A-targeted peptide library confirmed the preference of napsin A for hydrophobic residues at positions P1 and P1'. Adjacent positions, P2-P4 and P2'-P4', appeared less restricted in distribution of amino acids. A pH optimum between 4.0 and 5.5 at room temperature was determined. The purified enzyme was fully active for more than 10 h at pH 5.0 and 6.0, while a half-life of 4 h was determined at pH 7.0 and 37 degrees C.

Propeptide of the metalloprotease of Brevibacillus brevis 7882 is a strong inhibitor of the mature enzyme

A metalloprotease gene of Brevibacillus brevis (npr) was expressed in Escherichia coli in a soluble form as native Npr precursor. A significant fraction of the precursor was spontaneously processed, producing the N-terminal propeptide and the mature enzyme. A strong inhibition of the mature Npr by its own propeptide in the crude lysate was observed even in the absence of the covalent linkage between them. Pure precursor, propeptide and the mature Npr were isolated and kinetic parameters of the mature enzyme inhibition by the propeptide were determined. The inhibition is of the tight-binding competitive type with Ki 0.17 nM. Inhibition of metalloproteases from Brevibacillus megaterium and thermolysine by the heterologous propeptide of the Npr from B. brevis was much weaker or none.

Conformational switching in an aspartic proteinase

The crystal structure of a catalytically inactive form of cathepsin D (CatDhi) has been obtained at pH 7.5. The N-terminal strand relocates by 30 A from its position in the interdomain beta-sheet and inserts into the active site cleft, effectively blocking substrate access. CatDhi has a five-stranded interdomain beta-sheet and resembles Intermediate 3, a hypothetical structure proposed to be transiently formed during proteolytic activation of the proenzyme precursor. Interconversion between active and inactive forms of CatD is reversible and may be regulated by an ionizable switch involving the carboxylate side chains of Glu 5, Glu 180, and Asp 187. Our findings provide a structural basis for the pH-dependent regulation of aspartic proteinase activity and suggest a novel mechanism for pH-dependent modulation of substrate specificity.

Pro region C-terminus:protease active site interactions are critical in catalyzing the folding of alpha-lytic protease

alpha-Lytic protease is encoded with a large (166 amino acid) N-terminal pro region that is required transiently both in vivo and in vitro for the correct folding of the protease domain [Silen, J. L. , and Agard, D. A. (1989) Nature 341, 462-464; Baker, D., et al. (1992) Nature 356, 263-265]. The pro region also acts as a potent inhibitor of the mature enzyme [Baker, D., et al. (1992) Proteins: Struct.,Funct., Genet. 12, 339-344]. This inhibition is mediated through direct steric occlusion of the active site by the C-terminal residues of the pro region [Sohl, J. L., et al. (1997) Biochemistry 36, 3894-3904]. Through mutagenesis and structure-function analyses we have begun to investigate the mechanism by which the pro region acts as a single turnover catalyst to facilitate folding of the mature protease. Of central interest has been mapping the interface between the pro region and the protease and identifying interactions critical for stabilizing the rate-limiting folding transition state. Progressive C-terminal deletions of the pro region were found to have drastic effects on the rate at which the pro region folds the protease but surprisingly little effect on inhibition of protease activity. The observed kinetic data strongly support a model in which the detailed interactions between the pro region C-terminus and the protease are remarkably similar to those of known substrate/inhibitor complexes. Further, mutation of two protease residues near the active site have significant effects on stabilization of the folding transition state (kcat) or in binding to the folding intermediate (KM). Our results suggest a model for the alpha-lytic protease pro region-mediated folding reaction that may be generally applicable to other pro region-dependent folding reactions.

pH-induced conformational transitions of the propeptide of human cathepsin L. A role for a molten globule state in zymogen activation

Synthesis of proteases as inactive zymogens is a very important mechanism for the regulation of their activity. For lysosomal proteases proteolytic cleavage of the propeptide is triggered by the acidic pH. By using fluorescence, circular dichroism, and NMR spectroscopy, we show that upon decreasing the pH from 6.5 to 3 the propeptide of cathepsin L loses most of the tertiary structure, but almost none of the secondary structure is lost. Another partially structured intermediate, prone to aggregation, was identified between pH 6.5 and 4. The conformation, populated below pH 4, where the activation of cathepsin L occurs, is not completely unfolded and has the properties of molten globule, including characteristic binding of the 1-anilinonaphthalene-8-sulfonic acid. This pH unfolding of the propeptide parallels a decrease of its affinity for cathepsin L and suggests the mechanism for the acidic zymogen activation. Addition of anionic polysaccharides that activate cathepsin L already at pH 5.5 unfolds the tertiary structure of the propeptide at this pH. Propeptide of human cathepsin L which is able to fold independently represents an evolutionary intermediate in the emergence of novel inhibitors originating from the enzyme proregions.

The inhibition of cathepsin S by its propeptide--specificity and mechanism of action

The interaction of human recombinant full-length cathepsin S propeptide (amino acids 16-114) with mature cysteine proteinases was studied with respect to selectivity and pH dependence. The inhibitory capacity was tested towards mature human recombinant cathepsin S, purified cathepsin L from rat and Paramecium tetraurelia, rat cathepsin B, human cathepsin H, and papain. The propeptide of cathepsin S strongly inhibited cathepsin S (Ki = 0.27 nM) and the two cathepsin L species (Ki = 0.36 nM) at neutral pH. Papain, and to a minor extent cathepsin H, hydrolyzed the propeptide of cathepsin S, leading to competition with the hydrolysis of the fluorogenic substrates in the respective assays. Cathepsin B activity was nearly unaffected up to micromolar propeptide concentrations in the assay. The inhibition of cathepsin-L-like peptidases was diminished with decreasing pH, probably due to dramatic changes in the conformation of the propeptide. This assumption was supported by far-ultraviolet CD spectroscopy and by the finding of rapid hydrolysis of the cathepsin S propeptide by cathepsin L at pH values less than 5.5.

Histidine-rich human salivary peptides are inhibitors of proprotein convertases furin and PC7 but act as substrates for PC1

A 32 amino acid peptide called histatin-3 (H3; 22% His) and its N-terminal 24 amino acid fragment histatin-5 (H5, 33% His), are found in human saliva and possess powerful antimicrobial properties. These His-rich peptides have been synthesized by Fmoc-based solid-phase chemistry. Their sequences are: DSHAKRHHGYKRKFHEKHHSHRGYRSNYLYDN (H3) and DSHAKRHHGYKRKFHEKHHSHRGY (H5). In addition, we also prepared two H5 and one H3 mutants. The H5 mutants were: DH5 (all amino acids in D configuration) and H5F (where all His are replaced by Phe at positions 3, 7, 8, 15, 18, 19, 21). The 9-24 segment of H3 with all the His at positions 15,18,19,21 replaced by Tyr was also prepared (delta 1-8 H3Y). The behavior of these five peptides was examined with three proprotein convertases (PC's) which possess cleavage specificity directed towards single and pairs of basic residues. These were: human (h)PC1, an endocrine and neural convertase, hfurin and rat (r)PC7, two widely expressed enzymes. All are serine endoproteases belonging to the kexin/subtilisin family. Our in vitro study revealed that H3 behaves as a substrate for PC1, being cleaved by this endoprotease primarily at a site carboxy terminal to the single Arg25 residue (HRGYR decrease SN). On prolonged incubation some minor cleavage was also observed C-terminal to the first LysArg6 pairs of basic amino acids namely at: HAKR decrease HH, which contains a P4 as well as P'1 and P'2 His residues. The second potential site YKRK12-FH which does not have a P4 basic residues is not cleaved, even upon incubation with excess protease. PC1 only poorly cleaves H5 at the same site mentioned above for H3, i.e., at HAKR decrease HH. As expected, neither the D-amino acid analogue (DH5), nor the Phe and Tyr mutant analogues of the long and short histatins, respectively, are cleaved at all. In contrast to the above findings for hPC1, the convertase hfurin did not cleave any of the five synthetic peptides. Instead, H3 and H5 were found to be moderately potent inhibitors of the furin-mediated cleavage of the pentapeptide pGlu-Arg-Thr-Lys-Arg-MCA fluorogenic substrate. This inhibition was reversible and competitive, with an estimated inhibition constant Ki of 1.98 microM for H3 and 2.98 microM for H5. The other analogs exhibited only a moderate to weak inhibition of furin, suggesting that substitution of all His by aromatic residues (Phe or Tyr) drastically reduces their inhibitory potency. When tested against rPC7, H3 exhibited almost identical inhibition profile with a measured Ki of 2.4 microM. The partial sequence identity of H3 to the inhibitory pro-peptide of furin and PC7 provides a rationale for our observation.

Inhibition of alpha-lytic protease by pro region C-terminal steric occlusion of the active site

alpha-Lytic protease, a chymotrypsin-like serine protease, is synthesized with an N-terminal 166 amino acid pro region which is absolutely required for folding of the protease. The pro region is also the most potent inhibitor of the protease known with a Ki of approximately 10(-10) M. Compared to its role in the folding reaction, relatively little is known about the mechanism by which the pro region inhibits the mature protease. While proteinaceous protease inhibitors generally function by occluding the active sites of their respective targets [Bode, W., & Huber, R. (1992) Eur. J. Biochem. 204, 433-451], the pro region of alpha-lytic protease with its dual roles in folding and inhibition might be expected to show a novel mechanism of inhibition. However, experiments that probe both the structural and enzymatic consequences of pro region binding indicate that the pro region does not measurably distort the protease active site. Instead, the catalytic site is fully functional in the complex. Pro region inhibition of the protease is due to simple steric obstruction; the pro region C-terminus lies in the substrate binding sites of the protease. The implications of these results are discussed with regard to alpha-lytic protease maturation and folding. In addition, the proposed mechanism of alpha-lytic protease pro region inhibition is discussed with respect to data from other pro region families.

Inhibition of cathepsin B by its propeptide: use of overlapping peptides to identify a critical segment

Ten overlapping 15-mer peptides (peptidyl amides) spanning the proregion of rat cathepsin B (residues 1p-60p) were constructed to identify minimal segments having inhibitory activity towards the mature enzyme, that could be used to develop a new generation of peptide-derived inhibitors specifically targeting the active site of the corresponding proteinase. Three synthetic peptides, containing the pentapeptide Leu-Cys-Gly-Thr-Val (residues 41p-45p) in their sequence, inhibited cathepsin B with Ki values in the micromolar range. Alkylation of the thiol group of Cys-42p of peptide PB8 (36p-50p) resulted in its rapid proteolytic degradation, suggesting that this residue is essential for inhibition. The inhibition constant was slightly improved (Ki = 2 microM) using a longer peptide (26p-50p) which was completely resistant to cleavage even after a prolonged incubation. Alkylation of its cysteinyl residue also resulted in rapid cleavage of the peptide chain. Peptides derived from the rat cathepsin B prosequence also inhibited human cathepsin B with similar Ki values. Unlike rat cathepsin B, which cleaves peptide PB8 at the G47p-G48p bond after prolonged incubation, the human enzyme cleaved both PB8 and PB11 at the Lys-40p-Leu-41p bond, in agreement with the different kinetic properties of these two proteinases. New probes with improved specificity for cysteine proteinases may therefore be designed based on the sequences of their propeptides.

Potency and selectivity of the cathepsin L propeptide as an inhibitor of cysteine proteases

The cathepsin L propeptide (phcl-2) was expressed in Saccharomyces cerevisiae using a human procathepsin L/alpha-factor fusion construct containing a stop codon at position -1 (the C-terminal amino acid of the proregion). Since the yield after purification was very low, the cathepsin L propeptide was also obtained by an alternate procedure through controlled processing of an inactive mutant of procathepsin L (Cys25Ser/Thrl10Ala) expressed in Pichia pastoris, by small amounts of cathepsin L. The peptide resulting from the cleavage of the proenzyme (phcl-1) was then purified by HPLC. The purified propeptides were characterized by N-terminal sequencing and mass spectrometry and correspond to incomplete forms of the proregion (87 and 81 aa for phcl-1 and phcl-2 respectively, compared to 96 aa for the complete cathepsin L propeptide). The two peptides were found to be potent and selective inhibitors of cathepsin L at pH 5.5, with Ki values of 0.088 nM for phcl-1 and 0.66 nM for phcl-2. The Ki for inhibition of cathepsin S was much higher (44.6 nM with phcl-1), and no inhibition of cathepsin B or papain could be detected at up to 1 microM of the propeptide. The inhibitory activity was also found to be strongly pH-dependent. Two synthetic peptides of 75 and 44 aa corresponding to N-terminal truncated versions of the propeptide were also prepared by solid phase synthesis and displayed Ki values of 11 nM and 2900 nM, respectively, against cathepsin L. The data obtained for the 4 propeptide derivatives of various lengths indicate that the first 20 residues in the N-terminal region of the propeptide are more important for inhibition than the C-terminal region which contributes little to the overall inhibitory activity.

Cathepsin L is an intracellular and extracellular protease in Paramecium tetraurelia. Purification, cloning, sequencing and specific inhibition by its expressed propeptide

The ciliate Paramecium tetraurelia secretes large amounts of a cysteine protease into the growth medium, presumably for extracellular food digestion. Two endoprotease isozymes (30 and 33 kDa on SDS/PAGE, respectively), both present in cell homogenates and in spent growth medium, were purified to homogeneity. Peptide sequence analysis revealed that these isozymes share identities at the amino acid level but are probably differently processed. Enzymatic characterization of the isolated proteases and sequencing of the cloned cDNA demonstrated that the enzymes belong to the cathepsin-L protease subfamily. Although the identity with mammalian and other protozoan L cathepsins was only around 30%, all important signature sequences for cathepsin L in the preproregion as well as in the catalyst of the enzyme were fully retained. The cDNA of this cysteine protease codes for a preproregion of 108 amino acids. The putative proregion of 86 amino acids which contained the characteristic conserved ERFNIN motif, was fused with a His6 tag, expressed in Escherichia coli, and purified. Both cathepsin L isozymes of Paramecium tetraurelia were inhibited by their cognate propeptide in the nanomolar concentration range. All other cysteine proteases tested (papain and mammalian cathepsin B, G and H) were unaffected by the propeptide up to 10 microM.

Specific inhibition of mature fungal serine proteinases and metalloproteinases by their propeptides

The function of the long propeptides of fungal proteinases is not known. Aspergillus fumigatus produces a 33-kDa serine proteinase of the subtilisin family and a 42-kDa metalloproteinase of the thermolysin family. These extracellular enzymes are synthesized as preproenzymes containing large amino-terminal propeptides. Recombinant propeptides were produced in Escherichia coli as soluble fusion proteins with glutathione S-transferase or thioredoxin and purified by affinity chromatography. A. fumigatus serine proteinase propeptide competitively inhibited serine proteinase, with a Ki of 5.3 x 10(-6) M, whereas a homologous serine proteinase from A. flavus was less strongly inhibited and subtilisin was not inhibited. Binding of metalloproteinase propeptide from A. fumigatus to the mature metalloenzyme was demonstrated. This propeptide strongly inhibited its mature enzyme, with a Ki of 3 x 10(-9) M, whereas thermolysin and a metalloproteinase from A. flavus were not inhibited by this propeptide. Enzymatically inactive metalloproteinase propeptide complex could be completely activated by trypsin treatment. These results demonstrate that the propeptides of the fungal proteinases bind specifically and inhibit the respective mature enzymes, probably reflecting a biological role of keeping these extracellular enzymes inactive until secretion.

Processing of the papain precursor. The ionization state of a conserved amino acid motif within the Pro region participates in the regulation of intramolecular processing

The cysteine protease papain is synthesized as a 40-kDa inactive precursor with a 107-amino-acid N-terminal pro region. Although sequence conservation in the pro region is lower than in the mature proteases, a conserved motif (Gly-Xaa-Asn-Xaa-Phe-Xaa-Asp-36, papain precursor numbering) was found within the pro region of cysteine proteases of the papain superfamily. To determinate the function to this conserved motif, we have mutagenized at random each of the 4 residues individually within the pro region of the papain precursor. Precursor mutants were expressed in yeast, screened according to their ability to be processed through either a cis or trans reaction, into mature active papain. Three classes of mutants were found. Non-functional propapain mutants of the first class are completely degraded by subtilisin indicating that they are not folded into a native state. Mutants of the second class were neutral with respect to cis and trans processing. The third class included mutants that mostly accumulated as mature papain in the yeast vacuole. They had mutations that had lost the negatively charged Asp-36 residues and a mutation that probably introduces a positive charge, Phe-38His. The precursor of the Phe-38His mutant could be recovered by expression in a vph1 mutant yeast strain which has a vacuolar pH of about 7. The Phe-38His propapain mutant has an optimum pH of autoactivation about one pH unit higher than the wild type molecule. These results indicate that the electrostatic status of the conserved motif participates in the control of intramolecular processing of the papain precursor.

Pro-sequence-assisted protein folding

Many proteins, including proteases and growth factors, are synthesized as precursors in the form of pre-pro-proteins. Whereas the pre-sequences usually act as signal peptides for transport, the pro-sequences of an increasing number of these proteins have been found to be essential for the correct folding of their associated proteins. In contrast to the action of molecular chaperones, pro-sequences appear to catalyse the protein-folding reaction directly. The similarity between the pro-sequence-assisted folding mechanisms of different proteases supports the hypothesis that a common folding mechanism has developed through convergent evolution. Further, the frequent requirement of the pro-sequences for both folding and intracellular transport or secretion suggests that these two functionalities are intimately related.

The propeptide is nonessential for the expression of human cathepsin D

When the 44-amino acid propeptide of human procathepsin D was deleted by mutagenesis in vitro, the mature protein was stably expressed and secreted from transfected mammalian cells. The secreted protein was correctly folded as judged by its binding to pepstatinylagarose. We were unable to detect lysosomal targeting of the propeptide-deleted protein, and targeting was not restored by the substitution of the propeptides from pepsin or renin. We conclude that its propeptide is not essential for the folding of nascent cathepsin D. Efficient lysosomal targeting in mammalian cells appears to require the precursor form of the molecule.

Multiple functions of pro-parts of aspartic proteinase zymogens

The importance of aspartic proteinases in human pathophysiology continues to initiate extensive research. With burgeoning information on their biological functions and structures, the traditional view of the role of activation peptides of aspartic proteinases solely as inhibitors of the active site is changing. These peptide segments, or pro-parts, are deemed important for correct folding, targeting, and control of the activation of aspartic proteinase zymogens. Consequently, the primary structures of pro-parts reflect these functions. We discuss guidelines for formation of hypotheses derived from comparing the physiological function of aspartic proteinases and sequences of their pro-parts.

Regulation of proteolytic activity in tissues

Degradation of tissue proteins is controlled by multiple means. These include regulation of the synthesis of proteinases, activation of the zymogen forms, the activity of the mature proteinase, and the degradation of these enzymes and the substrates. Mature proteinases can be controlled by pH, calcium ions, ATP, lipids and the formation of complexes with other proteinases, proteoglycans, and inhibitors.

The role of pro regions in protein folding

In vivo, many proteases are synthesized as larger precursors. During the maturation process, the catalytically active protease domain is released from the larger polypeptide or pro-enzyme by one or more proteolytic processing steps. In several well studied cases, amino-terminal pro regions have been shown to play a fundamental role in the folding of the associated protease domains. The mechanism by which pro regions facilitate folding appears to be significantly different from that used by the molecular chaperones. Recent results suggest that the pro region assisted folding mechanism may be used by a wide variety of proteases, and perhaps even by non-proteases.