Hydrolysis of alanine oligomers and of elastin by P. aeruginosa proteinases and thermolysin

The hydrolysis of alanine oligomers by P. aeruginosa proteinases, thermolysin and porcine pancreatic elastase was studied. The concentrations of substrates and cleavage products were determined using reverse phase high pressure liquid chromatography. Tetraalanine was the shortest oligomer for which we could demonstrate hydrolysis by all the proteinases, except for porcine pancreatic elastase which only significantly hydrolyzed peptides longer than hexaalanine. Porcine pancreatic elastase hydrolyzes hexaalanine at a single site, whereas the other enzymes may split it either into two trialanine molecules, or into di- and tetraalanine, the latter being further cleavable to dialanine. A kinetic model based on first-order kinetic rate constants is proposed and the individual constants determined. Although P. aeruginosa elastase and thermolysin are closely similar in structure, they have shown a marked difference in their hydrolysis of either elastin or tetraalanine. Elastolytic activity of thermolysin was higher than that of elastase but tetraalanine was hydrolyzed more slowly by thermolysin.     

Substrate specificity of human pancreatic elastase 2

The substrate specificity of human pancreatic elastase 2 was investigated by using a series of peptide p-nitroanilides. The kinetic constants, kcat and Km, for the hydrolysis of these peptides revealed that this serine protease preferentially hydrolyzes peptides containing P1 amino acids which have medium to large hydrophobic side chains, except for those which are disubstituted on the first carbon of the side chain. Thus, human pancreatic elastase 2 appears to be similar in peptide bond specificity to the recently described porcine pancreatic elastase 2 [Gertler, A., Weiss, Y., & Burstein, Y. (1977) Biochemistry 16, 2709] but differs significantly in specificity from porcine elastase 1. The best substrates for human pancreatic elastase 2 were glutaryl-Ala-Ala-Pro-Leu-p nitroanilide and succinyl-Ala-Ala-Pro-Met-p-nitroanilide. However, there was little difference among substrates with leucine, methionine, phenylalanine, tyrosine, norvaline, or norleucine in the P1 position. Changes in the hydrolysis rate of peptides with differing P5 residues indicate that this enzyme has an extended binding site which interacts with at least five residues of peptide substrates. The overall catalytic efficiency of human pancreatic elastase 2 is significantly lower than that of porcine elastase 1 or bovine chymotrypsin with the compounds studied.     

Identification of two metabolites induced by a butyrolactone autoregulator IM-2 in Streptomyces sp. FRI-5

Abstract In order to determine whether non-elastase-producing strains of Pseudomonas aeruginosa such as N-10, PA103 and IFO3080 can express foreign elastase genes, we introduced elastase genes from P. aeruginosa IFO3455 (elastase-producing) as well as from PA103 and N-10 into non-elastase-producing P. aeruginosa strains. Results suggested that gene expression, secretion, and precursor processing systems of elastase were essentially normal in P. aeruginosa N-10 and IFO3080. Our studies using various elastase genes showed that both the elastase structural gene and 5'-upstream regions of P. aeruginosa PA103 were also normal. This was confirmed by the finding that P. aeruginosa N-10 and IFO3080 which carry the PA103 elastase gene produced elastase. Several deleted or chimeric genes were constructed using the 5'-upstream regions of elastase genes from P. aeruginosa N-10 or PA103 and studies of expression revealed that two individual DNA bases seem to be important in suppressing P. aeruginosa N-10 elastase gene expression. Possible reasons for the lack of elastase in these non-elastase-producing strains are discussed.     

Detection of elastase production in Escherichia coli with the elastase structural gene from several non-elastase-producing strains of Pseudomonas aeruginosa.

The elastase structural gene from Pseudomonas aeruginosa IFO 3455 has been cloned and sequenced. Using this gene as a probe, we cloned the DNA fragments (pEL3080R, pEL10, and pEL103R) of the elastase gene from non-elastase-producing strains (P. aeruginosa IFO 3080, N-10, and PA103 respectively). These three Pseudomonas strains showed no detectable levels of elastase antigenicity by Western blotting (immunoblotting) or by elastase activity. When elastase structural genes about 8 kb in length were cloned into pUC18, an Escherichia coli expression vector, we were able to detect both elastase antigenicity and elastolytic activity in two bacterial clones (E. coli pEL10 and E. coli pEL103R). However, neither elastolytic activity nor elastase antigenicity was detected in the E. coli pEL3080R clone, although elastase mRNA was observed. The partial restriction map determined with several restriction enzymes of these three structural genes corresponded to that of P. aeruginosa IFO 3455. We sequenced the three DNA segments of the elastase gene from non-elastase-producing strains and compared the sequences with those from the elastase-producing P. aeruginosa strains IFO 3455 and PAO1. In P. aeruginosa N-10 and PA103, the sequences were almost identical to those from elastase-producing strains, except for several nucleotide differences. These minor differences may reflect a microheterogeneity of the elastase gene. These results suggest that two of the non-elastase-producing strains have the normal elastase structural gene and that elastase production is repressed by regulation of this gene expression in P. aeruginosa. Possible reasons for the lack of expression in these two strains are offered in this paper. In P. aeruginosa IFO 3080, the sequence had a 1-base deletion in the coding region, which should have caused a frameshift variation in the amino acid sequence. At present, we have no explanation for the abnormal posttransciptional behavior of this strain.     

The role of Pseudomonas aeruginosa elastase as a potent inflammatory factor in a rat air pouch inflammation model

Pseudomonas aeruginosa, an opportunistic pathogen, can cause life threatening infections in patients compromised by underlying respiratory disease like bronchiectasis, cystic fibrosis and diffuse panbronchiolitis. Most strains of P. aeruginosa produce some kind of protease with broad substrate specificities during the infectious state in the host. P. aeruginosa elastase, one of the strongest exotoxins, has a tissue-damaging proteolytic activity and is capable of degrading such plasma proteins as immunoglobulins, complement factor and cytokines. The present study focused on the effect of P. aeruginosa elastase and was designed to evaluate the neutrophil accumulation at the inflammation site mediated by P. aeruginosa elastase in the inflammatory response in the host. An air pouch model in rats, considered as a useful model of inflammation, was used to analyze the number of leukocytes, the volume of exudate and the concentration of interleukin-8 after the injection of P. aeruginosa elastase into the pouch cavity. The number of neutrophils and the volume of exudate in the pouch cavity increased significantly at 4 h, peaked at 8 h in a dose-dependent manner and then decreased at 24 h. The concentration of interleukin-8 in pouch fluid peaked 4 h earlier than the peak of the neutrophil number. The enzymatic activity of P. aeruginosa elastase seemed to reinforce the inflammation process. The influence of lipopolysaccharide contamination was negligible. Although these observations were made in the subcutaneous cavity, they indicate that P. aeruginosa elastase plays a role as an immunoprovocative factor in the inflammatory response in cases of infection with P. aeruginosa.     

Antibacterial activity in vivo and in vitro in the hemolymph of Galleria mellonella infected with Pseudomonas aeruginosa

The antibacterial activity of hemolymph from Galleria mellonella infected with entomopathogenic strain of Pseudomonas aeruginosa and non-pathogenic bacterium Escherichia coli was studied. In vivo, the antimicrobial activity appeared shortly after P. aeruginosa infection, reached the maximum level 18 h postinjection, while 30 h later only trace activity was noted. The activity induced by E. coli sustained on the high level until 48 h after infection. We also noted that the antimicrobial activity level induced by the non-pathogenic bacterium was higher in comparison to that measured in insects infected with the pathogenic strain of P. aeruginosa. The results of our in vitro studies indicated that inducible antimicrobial peptides of G. mellonella larvae were digested by P. aeruginosa elastase B. After 1 h incubation of cell-free hemolymph of immune-challenged larvae with elastase B, no antibacterial activity was observed. It was also shown that elastase B degraded synthetic cecropin B while in the presence of 6 mM EDTA antibacterial activity of cell-free hemolymph as well as cecropin B, was not changed which confirmed that the activity was abolished by the metalloprotease.     

Investigation of the active center of rat pancreatic elastase

We have isolated rat pancreatic elastase I (EC 3.4.21.36) using a fast two-step procedure and we have investigated its active center with p-nitroanilide substrates and trifluoroacetylated inhibitors. These ligands were also used to probe porcine pancreatic elastase I whose amino acid sequence is 84% homologous to rat pancreatic elastase I as reported by MacDonald, et al. (Biochemistry 21, (1982) 1453-1463). Both proteinases exhibited non-Michaelian kinetics for substrates composed of three or four residues: substrate inhibition was observed for most enzyme substrate pairs, but with Ala3-p-nitroanilide, rat elastase showed substrate inhibition, whereas porcine elastase exhibited substrate activation. With most of the longer substrates, Michaelian kinetics were observed. The kcat/Km ratio was used to compare the catalytic efficiency of the two elastases on the different substrates. For both elastases, occupancy of subsite S4 was a prerequisite for efficient catalysis, occupancy of subsite S5 further increased the catalytic efficiency, P2 proline favored catalysis and P1 valine had an unfavorable effect. Rat elastase has probably one more subsite (S6) than its porcine counterpart. The rate-limiting step for the hydrolysis of N-succinyl-Ala3-p-nitroanilide by rat elastase was essentially acylation, whereas both acylation and deacylation rate constants participated in the turnover of this substrate by porcine elastase. For both enzymes, trifluoroacetylated peptides were much better inhibitors than acetylated peptides and trifluoroacetyldipeptide anilides were more potent than trifluoroacetyltripeptide anilides. A number of quantitative differences were found, however, and with one exception, trifluoroacetylated inhibitors were less efficient with rat elastase than with the porcine enzyme.     

Cloning and characterization of elastase genes from Pseudomonas aeruginosa.

A gene bank was constructed from Pseudomonas aeruginosa PAO1 and used to complement three P. aeruginosa elastase-deficient strains. One clone, pRF1, contained a gene which restored elastase production in two P. aeruginosa isolates deficient in elastase production (PA-E15 and PAO-E105). This gene also encoded production of elastase antigen and activity in Escherichia coli and is the structural gene for Pseudomonas elastase. A second clone, pHN13, contained a 20-kilobase (kb) EcoRI insert which was not related to the 8-kb EcoRI insert of pRF1 as determined by restriction analysis and DNA hybridization. A 2.2-kb SalI-HindIII fragment from pHN3 was subcloned into pUC18, forming pRB1822-1. Plasmid pRB1822-1 restored normal elastolytic activity to PAO-E64, a mutant for elastase activity. Clones derived from pHN13 failed to elicit elastase antigen or enzymatic activity in E. coli.     

Cloning, expression and characterization of recombinant elastase from Pseudomonas aeruginosa in Picha pastoris

The gene lasB from Pseudomonas aeruginosa, which encoded elastase, was cloned and firstly successfully expressed in Pichia pastoris stain KM71 under the control of AOX promoter. The effects on the recombinant elastase activities of different pH, different temperatures and different metal ions were assayed. The full-length gene (1497 bp) encodes a preproenzyme including an N-terminal signal peptide (23 aa), a propeptide (197 aa) and mature elastase (301 aa). The recombinant elastase was secreted into culture supernatants using signal sequence from lasB and showed a single band at about 34 kDa by SDS-PAGE. The recombinant elastase expression hit the highest level of approximately 450 mg/L and the specific elastolytic activity of the recombinant elastase was 130 U/ml, which was approximately 26-fold higher than that of elastase obtained from P. aeruginosa. The optimal temperature and pH of the recombinant elastase was 28 degrees C and 7.4, respectively. The enzyme possessed high resistance to heat, and can be activated by Ca(2+). These enzyme properties suggested that it could be produced in an industrial scale and has the potential to be a commercial enzyme.     

Stabilisation of carboxypeptidases in acid extracts of ovine pancreas

Carboxypeptidases A (CPA) and B (CPB) are pancreatic exopeptidases that are very sensitive to environmental stresses such as freezing, drying, temperature and pH. Traditional low pH methods of extracting pancreatic enzymes destroy carboxypeptidase activity. The use of sucrose as a stabilising agent prevents pH induced denaturation of carboxypeptidases during their extraction. Greater than 70% carboxypeptidase A activity can be retained at pHs as low as 3.5 using 0.5 M sucrose. In addition extraction at low pH ensures good trypsin and chymotrypsin recovery while elastase recovery is improved due to the stabilising effect of sucrose. Further fractionation of the extract produces preparations enriched in endopeptidases or exopeptidase suitable for use in protein hydrolysis applications.     

Purification and characterization of an active fragment of the LasA protein from Pseudomonas aeruginosa: enhancement of elastase activity.

A 22-kilodalton protein purified from the culture supernatant fraction of Pseudomonas aeruginosa (strains PA220 and PAO1) was found to enhance the elastolytic activity of purified P. aeruginosa elastase. N-terminal sequence analysis identified the protein as a fragment of the lasA gene product (P.A. Schad and B.H. Iglewski, J. Bacteriol. 170:2784-2789, 1988). However, comparative analysis with the reported LasA sequence indicated that the purified LasA fragment is longer than the deduced sequence reported. The purified LasA fragment had minimal elastolytic and proteolytic activity and did not enhance the proteolytic activity of purified elastase, yet enhanced the elastolytic activity more than 25-fold. The LasA fragment was found to also enhance the elastolytic activities of thermolysin, human neutrophil elastase, and proteinase K. The results presented here suggest that the LasA protein interacts with the elastin substrate rather than modifying elastase.     

A secreted aminopeptidase of Pseudomonas aeruginosa. Identification, primary structure, and relationship to other aminopeptidases

Using leucine-p-nitroanilide (Leu-pNA) as a substrate, we demonstrated aminopeptidase activity in the culture filtrates of several Pseudomonas aeruginosa strains. The aminopeptidase was partially purified by DEAE-cellulose chromatography and found to be heat stable. The apparent molecular mass of the enzyme was approximately 56 kDa; hence, it was designated AP(56). Heating (70 degrees C) of the partially purified aminopeptidase preparations led to the conversion of AP(56) to a approximately 28-kDa protein (AP(28)) that retained enzyme activity, a reaction that depended on elastase (LasB). The pH optimum for Leu-pNA hydrolysis by AP(28) was 8.5. This activity was inhibited by Zn chelators but not by inhibitors of serine- or thiol-proteases, suggesting that AP(28) is a Zn-dependent enzyme. Of several amino acid p-nitroanilide derivatives examined, Leu-pNA was the preferred substrate. The sequences of the first 20 residues of AP(56) and AP(28) were determined. A search of the P. aeruginosa genomic data base revealed a perfect match of these sequences with positions 39-58 and 273-291, respectively, in a 536-amino acid residue open reading frame predicted to encode an aminopeptidase. A search for sequence similarities with other proteins revealed 52% identity with Streptomyces griseus aminopeptidase, approximately 35% identity with Saccharomyces cerevisiae aminopeptidase Y and a hypothetical aminopeptidase from Bacillus subtilis, and 29-32% with Aeromonas caviae, Vibrio proteolyticus, and Vibrio cholerae aminopeptidases. The residues potentially involved in zinc coordination were conserved in all these proteins. Thus, P. aeruginosa aminopeptidase may belong to the same family (M28) of metalloproteases.     

Monoclonal antibodies against Pseudomonas aeruginosa elastase: a neutralizing antibody which recognizes a conformational epitope related to an active site of elastase.

We have established seven murine hybridoma cell lines which produce monoclonal antibodies (mAbs) against Pseudomonas aeruginosa elastase. The seven mAbs recognized at least six different epitopes on the elastase molecule. All mAbs inhibited both enzymatic activities of elastase and protease, in which elastin fluorescein and hide powder azure were used as substrates, respectively. One of them, mAb E-4D3, strongly neutralized enzymatic activities of peptidase in which furylacryloyl-glycyl-leucinamide was used as a substrate, as well as of elastase and protease. In contrast, the other six mAbs did not neutralize peptidase activity at all. The Ki value for furylacryloyl-glycl-leucinamide of E-4D3, as well as its Fab fragment, was comparable to those for metalloprotease inhibitors such as phosphoramidon and Zincov inhibitor. The binding of mAb E-4D3 was inhibited by phosphoramidon and Zincov inhibitor, but not by metal chelators such as EDTA and o-phenanthroline. A line of evidence suggests that mAb E-4D3 directly interacts with active site and highly neutralizes enzymatic activity of P. aeruginosa elastase. Data of Western blotting and ELISA suggest that mAb E-4D3 is likely to recognize an elastase molecule in a conformation-dependent manner as an epitope. In contrast, the neutralizing activity of the other mAbs against elastase and protease seems to be caused by a low accessibility of an enzyme to insoluble and high-molecular-mass substrates through the binding and steric hindrance of the mAbs to an enzyme.     

Identification of an immunomodulating metalloprotease of Pseudomonas aeruginosa (IMPa)

Phagocytosis by neutrophils is the essential step in fighting Pseudomonas infections. The first step in neutrophil recruitment to the site infection is the interaction of P-selectin (on endothelial cells) with P-selectin glycoprotein ligand-1 (PSGL-1) on neutrophils. Pseudomonas aeruginosa secretes various proteases that degrade proteins that are essential for host defence, such as elastase and alkaline protease. Here we identify PA0572 of P. aeruginosa as an inhibitor of PSGL-1 and named this secreted hypothetical protease immunomodulating metalloprotease of P. aeruginosa or IMPa. Proteolytic activity was confirmed by cleavage of recombinant and cell-surface expressed PSGL-1. Functional inhibition was demonstrated by impaired PSGL-1-mediated rolling of IMPa-treated neutrophils under flow conditions. Next to PSGL-1, IMPa targets CD43 and CD44 that are also involved in leucocyte homing. These data indicate that IMPa prevents neutrophil extravasation and thereby protects P. aeruginosa from neutrophil attack.     

Elastinolytic activity of human cathepsin L.

The hydrolysis of a tritiated elastin substrate by the human cysteine proteinases cathepsins B and L has been studied. Cathepsin L was found to be at least 100-fold more active on this substrate than cathepsin B. The specific activity of cathepsin L at pH 5.5 for hydrolysis of elastin was about the same as that of pig pancreatic elastase at its optimum pH of 8.8.     

Efficient production and processing of elastase and LasA by Pseudomonas aeruginosa require zinc and calcium ions.

The ability of Pseudomonas aeruginosa to degrade elastin, a major component of connective tissue, likely contributes to its pathogenicity and multiplication in human tissues. Two extracellular enzymes are required for P. aeruginosa elastolytic activity: elastase and LasA. Elastase is a zinc metalloprotease, but little is known about the structure of LasA. When grown under metal ion-deficient conditions, P. aeruginosa culture supernatants were found to exhibit a low level of elastolytic activity, which coincided with production of low levels of the 51-kDa proelastase and no detectable LasA. By using this fact to identify factors that promote elastolytic activity, P. aeruginosa PAO1, FRD2, and DG1 were grown in metal ion-deficient medium supplemented with zinc (10(-4) M ZnCl2), calcium (2.5 x 10(-3) M CaCl2), or iron (10(-4) M FeCl3). High levels of proteolytic and elastolytic activity were exhibited by all strains when cultured in the presence of both zinc and calcium, and this was associated with the production of mature 33-kDa elastase and 21-kDa LasA. Supplementing DG1 and PAO1 cultures with zinc alone stimulated the production of 33-kDa elastase, which, because of the calcium-deficient conditions, exhibited low proteolytic and elastolytic activities. Zinc also stimulated the production of a 41-kDa form of LasA in DG1 and PAO1 culture supernatants. Elastase production by FRD2 cultured in the presence of zinc alone differed from that by the other two strains in that supernatants contained 33-kDa elastase, a 21-kDa form of LasA, and exhibited high proteolytic and elastolytic activities. Such strain-associated differences in LasA processing and elastase activity can be explained by differences in metal ion-scavenging mechanisms adapted by the strains. Supplementing cultures with calcium stimulated the production of elastase but had no effect on LasA production. The elastase produced exhibited variable sizes, possibly resulting from aberrant processing reactions, and showed little proteolytic activity. Proteolytic activity could be recovered from 33-kDa elastase produced in the presence of calcium by inclusion of zinc in the enzymatic assay. Although iron was previously found to exert a repressive effect on P. aeruginosa elastolytic activity, iron exerted little effect on elastolytic activity when added to cultures containing both zinc and calcium. These studies support the conclusion that elastase production and processing are promoted by both zinc and calcium. LasA production, in comparison, is stimulated by zinc, with both zinc and calcium facilitating its processing. The association of 41-kDa LasA with a low level of elastolytic activity and of 21-kDa LasA with a high level of activity supports the conclusion that lasA encodes a larger, precursor protein which is processed to an active 21-kDa form during secretion.     

A novel locust (Schistocerca gregaria) serine protease inhibitor with a high affinity for neutrophil elastase

We have purified to homogeneity two forms of a new serine protease inhibitor specific for elastase/chymotrypsin from the ovary gland of the desert locust Schistocerca gregaria. This protein, greglin, has 83 amino acid residues and bears putative phosphorylation sites. Amino acid sequence alignments revealed no homology with pacifastin insect inhibitors and only a distant relationship with Kazal-type inhibitors. This was confirmed by computer-based structural studies. The most closely related homologue is a putative gene product from Ciona intestinalis with which it shares 38% sequence homology. Greglin is a fast-acting and tight binding inhibitor of human neutrophil elastase (k(ass)=1.2x10(7) M(-1) x s(-1), K(i)=3.6 nM) and subtilisin. It also binds neutrophil cathepsin G, pancreatic elastase and chymotrypsin with a lower affinity (26 nM< or =K(i)< or =153 nM), but does not inhibit neutrophil protease 3 or pancreatic trypsin. The capacity of greglin to inhibit neutrophil elastase was not significantly affected by exposure to acetonitrile, high temperature (90 degrees C), low or high pH (2.5-11.0), N-chlorosuccinimide-mediated oxidation or the proteolytic enzymes trypsin, papain and pseudolysin from Pseudomonas aeruginosa. Greglin efficiently inhibits the neutrophil elastase activity of sputum supernatants from cystic fibrosis patients. Its biological function in the locust ovary gland is currently unknown, but its physicochemical properties suggest that it can be used as a template to design a new generation of highly resistant elastase inhibitors for treating inflammatory diseases.     

Different susceptibility of elastase inhibitors to inactivation by proteinases from Staphylococcus aureus and Pseudomonas aeruginosa.

Neutrophil elastase is thought to contribute to the lung pathology in patients with cystic fibrosis (CF). Therefore, intrapulmonary application of elastase inhibitors might be beneficial for these patients. Inactivation of such inhibitors by bacterial proteinases, however, is an important consideration in this therapy. We studied the effects of Staphylococcus aureus proteinase (STAP) and Pseudomonas aeruginosa elastase (PsE) on native (alpha 1-AT) and recombinant (rAAT) alpha 1-antitrypsin, recombinant secretory leukocyte proteinase inhibitor (rSLPI) and the leech inhibitor eglin C. All inhibitors were inactivated by these bacterial proteinases showing pronounced differences in their susceptibilities to proteolytic cleavage. Comparing the turnover rate (mol of inhibitor inactivated by one mol bacterial proteinase/min), rAAT and alpha 1-AT were approximately 20,000-fold more susceptible to STAP than rSLPI and 50,000-fold more susceptible than eglin C. Pseudomonas aeruginosa elastase inactivated all inhibitors more rapidly than STAP. rAAT and alpha 1-AT were 13-fold and 17,000-fold more susceptible than rSLPI and eglin C, respectively. Incubation of the rAAT-elastase complex with equimolar amounts of STAP did not result in release of elastase activity. Upon simultaneous addition of STAP and leukocyte elastase to rAAT, there was undisturbed elastase inhibition indicating that complex formation with elastase proceeded at a faster rate than inactivation of rAAT by the bacterial proteinase. From these results of inactivation in vitro and considering the immunogenic potential of the inhibitors studied here, we conclude that rSLPI may be the appropriate choice for anti-elastase therapy in CF.     

Legionella pneumophila zinc metalloprotease is structurally and functionally homologous to Pseudomonas aeruginosa elastase.

The sequence of the structural gene encoding the Legionella pneumophila extracellular zinc metalloprotease has been determined and was found to possess a single large open reading frame (ORF) of 1,629 nucleotides (nt). This ORF was preceded by consensus promoter (TTAACT . . . 17 nt . . . TATAAC) and ribosome-binding (TAAGGAG) sequences. The deduced polypeptide contained a putative signal sequence and a total of 543 amino acid residues with a computed molecular size of 60,775 daltons, substantially larger than the observed 38,000 daltons of the native and recombinant proteins. A homology search revealed extensive amino acid identity with Pseudomonas aeruginosa elastase, a protein that is also encoded by an ORF substantially larger than that predicted for the mature size of the protein. The structural identity between the L. pneumophila protease and P. aeruginosa elastase was most pronounced in the regions forming the enzymatic active site of elastase. Amino acid residues constituting the active-site cleft of elastase were greater than 75% conserved. Elastase residues that interact with and mediate proteolysis of substrate peptides were 100% conserved. Competitive inhibitors of elastase and the structurally and functionally related thermolysin (phosphoramidon and a phosphoramidate analog, Z-GlyP(O)Leu-Ala), were shown to be equally potent at inhibiting the proteolytic activity of the L. pneumophila protease. These inhibitor studies along with the amino acid sequence similarities provide strong evidence that the L. pneumophila protease and P. aeruginosa elastase share a similar molecular mechanism of proteolysis.     

Role of the propeptide in folding and secretion of elastase of Pseudomonas aeruginosa

Elastase of Pseudomonas aeruginosa is synthesized as a pre-proprotein. The propeptide has been shown to inhibit the enzymatic activity of elastase. In this study, we investigated a possible additional role of the propeptide in the folding and secretion of the enzyme. When elastase was expressed in Escherichia coli without its propeptide, no active elastase was produced. The enzyme was poorly released from the cytoplasmic membrane and, depending on the expression level, it was either degraded or it accumulated in an inactive form in the cell envelopes, probably as aggregates. Since proper folding is required for the release of translocated proteins from the cytoplasmic membrane and for the acquirement of a stable and active conformation, these results suggest that the propeptide is involved in the proper folding of the elastase and that it functions as an intramolecular chaperone. When mature elastase was expressed without its propeptide in P. aeruginosa , the enzyme was not secreted, and it was degraded. Therefore, proper folding of mature elastase appears to be required for secretion of the enzyme. Expression of the propeptide, as a separate polypeptide, in trans with mature elastase resulted in the formation of active elastase. This active enzyme was secreted in P. aeruginosa . Apparently, the propeptide can also function as an intermolecular chaperone.