Substitution of active-site His-223 in Pseudomonas aeruginosa elastase and expression of the mutated lasB alleles in Escherichia coli show evidence for autoproteolytic processing of proelastase.

The neutral metalloprotease elastase is one of the major proteins secreted into the culture medium by many Pseudomonas aeruginosa strains. Encoded by the lasB gene, the 33-kDa elastase is initially synthesized as a 53-kDa preproenzyme which is processed to the mature form via a 51-kDa proelastase intermediate. To facilitate studies on proteolytic processing of elastase precursors and on secretion, we developed systems for overexpression of lasB in Escherichia coli under the control of the inducible T7 and tac promoters. Although the 51-kDa proelastase form was detectable in E. coli under inducible conditions, most of the elastase produced under these conditions was found in an enzymatically active 33-kDa form. The amino-terminal sequence of the first 15 amino acid residues of this 33-kDa elastase species was identical to that of the mature P. aeruginosa enzyme, suggesting that processing was autocatalytic. To test this possibility, the codon in lasB encoding His-223, a presumed active-site residue, was changed to encode Asp-223 (lasB1) and Tyr-223 (lasB2). The effects of these mutations on enzyme activity and processing were examined. No proteolytic or elastolytic activities were detected in extracts of E. coli cells containing the lasB mutant alleles. Overexpression of the mutated lasB genes in E. coli resulted in the accumulation of the corresponding 51-kDa proelastase species. These were processed in vitro to the respective 33-kDa forms by incubation with exogenous purified elastase, without an increase in proteolytic activity. Molecular modeling studies suggest that the mutations have little or no effect on the conformation of the mutant elastases. In addition, wild-type elastase and the mutant proelastases were localized to the periplasm of E. coli. The present results confirm that His-223 is essential for elastase activity and provide evidence for autoproteolytic processing of proelastase.     

Secretion of Elastinolytic Enzymes and Their Propeptides by Pseudomonas aeruginosa

Elastase of Pseudomonas aeruginosa is synthesized as a preproenzyme. The signal sequence is cleaved off during transport across the inner membrane and, in the periplasm, proelastase is further processed. We demonstrate that the propeptide and the mature elastase are both secreted but that the propeptide is degraded extracellularly. In addition, reduction of the extracellular proteolytic activity led to the accumulation of unprocessed forms of LasA and LasD in the extracellular medium, which shows that these enzymes are secreted in association with their propeptides. Furthermore, a hitherto undefined protein with homology to a Streptomyces griseus aminopeptidase accumulated under these conditions.     

Activation of an elastase precursor by the lasA gene product of Pseudomonas aeruginosa.

To study the role of the lasA gene product in the secretion of enzymatically active elastase by Pseudomonas aeruginosa, we constructed mutants by gene replacement with in vitro-derived insertion and deletion mutations in the cloned lasA gene. lasA mutants were deficient in the production of elastolytic activity. A membrane-associated, higher-molecular-weight (approximately 47,000) precursor of elastase was observed in both the wild-type and the lasA mutants. Unlike the wild-type strain, the lasA mutant accumulated the 47,000-molecular weight elastase species in the soluble fraction of the cell, suggesting that the lasA gene product has a role in elastase secretion. Although lasA mutants were deficient in elastolytic activity, they produced a proelastase with a mature molecular weight (approximately 37,000) that still retained general proteolytic activity. Final yields of elastase-related material were approximately the same in both the wild-type strain and lasA mutant supernatants. The lasA gene was expressed in Escherichia coli, and the approximate molecular weight of the lasA gene product was 31,000. Extracts of E. coli containing the lasA gene product were shown in vitro to activate the proelastase produced by P. aeruginosa lasA mutants to an enzyme with elastolytic activity. Thus the lasA gene product has a direct effect on broadening the substrate specificity of secreted proelastase, as well as a second role (direct or indirect) in the secretion of elastase.     

Identification of cleavage sites involved in proteolytic processing of Pseudomonas aeruginosa preproelastase.

The extracellular elastase (33 kDa) of Pseudomonas aeruginosa is synthesized as a 53.6 kDa preproenzyme containing a long, N-terminal propeptide. The free propeptide and the elastase precursor generated upon propeptide removal were isolated from P. aeruginosa cells and subjected to N-terminal amino acid sequence analysis. The results identified Ala-174 and Ala+1 as the amino terminal residues of the propeptide and the elastase precursor, respectively, indicating that: (1) the signal peptide consists of 23 amino acid residues and its molecular weight is 2.4 kDa, (2) the propeptide contains 174 amino acid residues and is of 18.1 kDa molecular weight, and (3) no additional N-terminal proteolytic cleavage is required for elastase maturation.     

Isolation of two forms of activated C1s, a subcomponent of the first component of rabbit complement.

Two forms of activated C1s, a subcomponent of the first component of complement, were present in preparations of C1 specifically purified from rabbit serum by affinity chromatography on IgG-Sepharose 6B and were separated by DEAE-cellulose chromatography in the presence of EDTA. These two activated C1s, designated C1s(I) and C1s(II), were indistinguishable with regard to hemolytic activity as well as C1s esterase activity, though they had different molecular weights. C1s(I) had a molecular weight of 106,000, consisting of H and L chains connected by disulfide bonds; the molecular weights of the chains were 70,000 and 36,000, respectively. On the other hand, C1s(II), with a molecular weight of 72,000, consisted of two chains each with a molecular weight of about 37,000, which were also connected by disulfide bonds. These results suggest that, in the case of rabbit C1s, the primary product of activation with C1r, C1s(I), may be susceptible to further cleavage of its H chain without any loss of C1s activity, resulting in the formation of C1s(II), though the active principle responsible for this conversion remains to be elucidated.     

Pseudomonas aeruginosa lasB1 mutants produce an elastase, substituted at active-site His-223, that is defective in activity, processing, and secretion.

Pseudomonas aeruginosa secretes elastase in a multistep process which begins with the synthesis of a preproelastase (53.6 kDa) encoded by lasB, is followed by processing to proelastase (51 kDa), and concludes with the rapid accumulation of mature elastase (33 kDa) in the extracellular environment. In this study, mutants of P. aeruginosa were constructed by gene replacement which expressed lasB1, an allele altered in vitro at an active-site His-223-encoding codon. The lasB1 allele was exchanged for chromosomal lasB sequences in two strain backgrounds, FRD2 and PAO1, through a selectable-cassette strategy which placed a downstream Tn501 marker next to lasB1 and provided the selection for homologous recombination with the chromosome. Two lasB1 mutants, FRD720 and PDO220, were characterized, and their culture supernatants contained greatly reduced proteolytic (9-fold) and elastolytic (14- to 20-fold) activities compared with their respective parental lasB+ strains. This was primarily due to the effect of His-223 substitution on substrate binding by elastase and thus its proteolytic activity. However, the concentration of supernatant elastase antigen was also reduced (five- to sevenfold) in the mutant strains compared with the parental strains. An immunoblot analysis of cell extracts showed a large accumulation of 51-kDa proelastase within lasB1 mutant cells which was not seen in wild-type cell extracts. A time course study showed that production of extracellular elastase was inefficient in the lasB1 mutants compared with that of parental strains. This showed that expression of an enzymatically defective elastase inhibits proper processing of proelastase and provides further evidence for autoproteolytic processing of proelastase in P. aeruginosa. Unlike the parental strains, culture supernatants of the lasB1 mutants contained two prominent elastase species that were 33 and 36 kDa in size. Extracellular 51-kDa proelastase was barely detectable, even though it accumulated to high concentrations within the lasB1 mutant cells. These data suggest that production of an enzymatically defective elastase affects proper secretion because autoproteolytic processing of proelastase is necessary for efficient localization to the extracellular milieu. The appearance of reduced amounts of extracellular elastase and their sizes of 33 and 36 kDa suggest that lasB1-encoded elastase was processed by alternate, less-efficient processing mechanisms. Thus, proelastase must be processed by removal of nearly all of the 18-kDa propeptide before elastase is a protein competent for extracellular secretion.     

Partial purification and characterization of an inactive precursor of Pseudomonas aeruginosa elastase.

An inactive precursor of the extracellular elastase of Pseudomonas aeruginosa was extensively purified by immunoadsorption chromatography of the soluble bacterial cell fraction on a column of Sepharose coupled to antielastase antibodies. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the purified precursor fraction revealed two major protein bands with molecular weights of about 36,000 (P36) and 20,000 (P20) that in the absence of sodium dodecyl sulfate were associated with each other. The following findings identify P36 as the elastase precursor and indicate that proteolytic processing of this molecule is required for activation: (i) P36 is larger than the elastase, and it binds antielastase antibodies; (ii) trypsin activation is associated with the disappearance of P36 and the appearance of a new protein band migrating identically with the elastase and reacting with antibodies against the elastase; (iii) peptide maps generated from P36 and the elastase are similar although not identical. P20 by itself was not recognized by antielastase antibodies. Its association with P36 accounts for its adsorption to the immunoaffinity column and suggests that it may serve in elastase secretion.     

Aminopeptidases of Bacillus subtilis.

Three enzymes with L- and one enzyme with D-aminopeptidase (EC 3.4.11; alpha-aminoacyl peptide hydrolase) activity have been separated from each other and partially purified from Bacillus subtilis 168 W.T., distinguished with respect to their molecular weights and catalytic properties, and studied in relation to the physiology of this bacterium. One L-aminopeptidase, designated aminopeptidase I, has a molecular weight of 210,000 +/- 20,000, is produced early in growth, and hydrolyzes L-alanyl-beta-naphthylamide most rapidly. Another, designated aminopeptidase II, molecular weight 67,000 +/- 10,000, is also produced early in growth and hydrolyzes L-lysyl-beta-naphthylamide most rapidly. A third, aminopeptidase III, molecular weight 228,000 +/- 20,000, is produced predominantly in early stationary phase and most efficiently utilizes L-alpha-aspartyl-beta-naphthylamide as substrate. The synthesis of aminopeptidase III in early stationary phase suggests that selective catabolism of peptides occurs at this time, perhaps related to the cessation of growth or the onset of early sporulation-associated events. A D-aminopeptidase which hydrolyzes the carboxyl-blocked dipeptide D-alanyl-D-alanyl-beta-naphthylamide (as well as D-alanyl-beta-naphthylamide and D-alanyl-D-alanyl-D-alanine) has also been identified, separated from aminopeptidase II, and purified 170-fold. D-Aminopeptidase, molecular weight 220,000 +/- 20,000, is localized predominantly in the cell wall and periplasm of the organism. This evidence and the variation of the activity during the growth cycle suggest an important function in cell wall or peptide antibiotic metabolism.     

Synthesis and mechanism of action of novel thiocarbamate inhibitors of human leukocyte elastase

Several peptidyl thiocarbamate inhibitors of human leukocyte elastase were synthesized in the molecular weight range of 700-800. Two different sequences with lysine at the P3 and ornithine at the P4 positions were synthesized. Most of the inhibitors with large molecular weights showed high inhibitory capacity with Ki values as low as 10(-8)M. Compounds immobilized on poly,alpha,beta-[N-(2-hydroxyethyl)-D,L-aspartamide] (PHEA) polymers with an average molecular weight of 36,000 showed higher inhibitory capacity than their free forms.     

Purification of a periplasmic insulin-cleaving proteinase from Acinetobacter calcoaceticus

Cells of Acinetobacter calcoaceticus contain a constitutive periplasmic metalloproteinase showing similar properties as the periplasmic metalloproteinase of Escherichia coli. The periplasmic proteinase of A. calcoaceticus was purified, starting from periplasm, by ammonium sulfate precipitation, hydrophobic interaction chromatography and chromatofocusing up to the homogeneity of the enzyme in SDS-electrophoresis with a yield of 6.7% and a purification factor of 417. The enzyme has a molecular mass of 108000 (gel filtration) or 112000 (native electrophoresis), and consists of four identical subunits with a molecular mass of 27 000 (SDS-electrophoresis). The purified enzyme degrades preferentially polypeptides such as glucagon and insulin. Larger proteins are accepted as substrates to a considerably lower extent. All tested synthetic substrates with trypsin, chymotrypsin, elastase and thermolysin specificity were not cleaved. Therefore, the described enzyme was designated “insulin-cleaving proteinase” (ICP).     

Phosphorylation of yeast DNA-dependent RNA polymerases in vivo and in vitro. Isolation of enzymes and identification of phosphorylated subunits.

Yeast DNA-dependent RNA polymerases I, II, and III are phosphorylated in vivo. Yeast cells were grown continuously in 32Pi and the RNA polymerases were isolated by a new procedure which allows the simultaneous purification of these enzymes from small quantities (35 to 60 g) of cells. Each of the RNA polymerases was phosphorylated. The following phosphorylated polymerase polypeptides were identified: polymerase I subunits of 185,000, 44,000, 36,000, 24,000, and 20,000 daltons; a polymerase II subunit of 24,000 daltons; and polymerase III subunits of 24,000 and 20,000 daltons. The incorporated 32P was acid-stable but base-labile. Phosphoserine and phosphothreonine were identified after partial acid hydrolysis of purified [32P]polymerase I. A yeast protein kinase that co-purifies with polymerase I during part of the isolation procedure was partially purified and characterized. This protein kinase phosphorylates the subunits of the purified polymerases that are phosphorylated in vivo and, in addition, a polymerase I subunit of 48,000 daltons and a polymerase II subunit of 33,500 daltons. Phosphorylation of the purified enzymes with this protein kinase had no substantial effect on polymerase activity in simple assays using native yeast DNA as a template. Preincubation of purified polymerase I with acid or alkaline phosphatase also had no detectable effect on polymerase activity.     

Synthesis and Mechanism of Action of Novel Thiocarbamate Inhibitors of Human Leukocyte Elastase

Several peptidyl thiocarbamate inhibitors of human leukocyte elastase were synthesized in the molecular weight range of 700-800. Two different sequences with lysine at the P(3) and ornithine at the P(4) positions were synthesized. Most of the inhibitors with large molecular weights showed high inhibitory capacity with Ki values as low as 10(-8) M. Compounds immobilized on poly,alpha,beta-[N-(2-hydroxyethyl)-d,l-aspartamide] (PHEA) polymers with an average molecular weight of 36,000 showed higher inhibitory capacity than their free forms.     

Characterization of Bromodeoxyuridine-Induced Endogenous Guinea Pig Virus

An endogenous virus (GPV) was induced after 5-bromodeoxyuridine treatment of cultured guinea pig cells. Compared to Gross murine leukemia virus (G-MuLV) GPV has a reproducibly heterogenous density of about 1.16 to 1.18 g/ml. The virion-associated RNA is slightly larger than that in G-MuLV. Sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis of dissociated GPV resolved five major structural proteins: I (molecular weight 70,000), II (molecular weight 36,000), III (molecular weight 24,000), IV (molecular weight 18,000), and V (molecular weight 16,000) which are similar to but distinct from G-MuLV proteins. Proteins I and II were demonstrated to be glycoproteins by incorporation of [(3)H]glucosamine. GPV and G-MuLV did not have any appreciable genetic homology or any common group-specific antigens when analyzed by immunodiffusion, radioimmunoassay, and indirect immunofluorescence. Morphogenesis of GPV also differed from that of a typical type C oncornavirus and proceeded via two pathways: (i) a majority of virus particles were formed in cytoplasmic vacuoles and were released after cellular disruption; and (ii) a minor population of particles were assembled in the cytoplasmic matrix and then migrated to the plasma membrane where they budded into the extracellular space. To date, GPV has been unable to initiate or maintain a productive replication in any cell line tested.     

Primary structure of two distinct rat pancreatic preproelastases determined by sequence analysis of the complete cloned messenger ribonucleic acid sequences

The mRNA sequences for two rat pancreatic elastolytic enzymes have been cloned by recombinant DNA technology and their nucleotide sequences determined. Rat elastase I mRNA is 1113 nucleotides in length, plus a poly(A) tail, and encodes a preproelastase of 266 amino acids. The amino acid sequence of the predicted active form of rat elastase I is 84% homologous to porcine elastase 1. Key amino acid residues involved in determining substrate specificity of porcine elastase 1 are retained in the rat enzyme. The activation peptide of the zymogen does not appear related to that of other mammalian pancreatic serine proteases. The mRNA for elastase I is localized in the rough endoplasmic reticulum of acinar cells, as expected for the site of synthesis of an exocrine secretory enzyme. Rat elastase II mRNA is 910 nucleotides in length, plus a poly(A) tail, and encodes a preproenzyme of 271 amino acids. The amino acid sequence is more closely related to porcine elastase 1 (58% sequence identity) than to the other pancreatic serine proteases (33-39% sequence identity). Predictions of substrate preference based upon key amino acid residues that define the substrate binding cleft are consistent with the broad specificity observed for mammalian pancreatic elastase 2. The activation peptide is similar to that of the chymotrypsinogens and retains an N-terminal cysteine available to form a disulfide link to an internal conserved cysteine residue.     

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.     

Reconstitution of maltose transport in malB mutants of Escherichia coli through calcium-induced disruptions of the outer membrane.

The barrier function of the Escherichia coli outer membrane against low concentrations of maltose in strains missing the lambda receptor was partially overcome by treating the cells for 3 h with 25 mM Ca2+. Kinetic analysis of maltose-transport revealed a Ca2+-induced shift of the apparent Km of the system from about 100 microM in cells pretreated with Tris to about 15 microM in cells pretreated with Tris plus Ca2+. In contrast to maltose transport in untreated cells, that of Ca2+-treated lamB cells was inhibited by molecules with a high molecular weight, such as amylopectin (molecular weight, 20,000), and anti-maltose-binding protein antibodies. In addition, lysozyme was shown to attack Ca2+-treated cells in contrast to untreated cells. The Ca2+-induced permeability increase of the outer membrane allowed reconstitution of maltose transport in a mutant missing the maltose-binding protein with osmotic shock fluid containing the maltose-binding protein. Even though Ca2+-treatment allowed the entry of large molecules, the release of the periplasmic maltose-binding protein or alkaline phosphatase was negligible.     

Direct metal transfer between periplasmic proteins identifies a bacterial copper chaperone

Transition metals require exquisite handling within cells to ensure that cells are not harmed by an excess of free metal species. In gram-negative bacteria, copper is required in only small amounts in the periplasm, not in the cytoplasm, so a key aspect of protection under excess metal conditions is to export copper from the periplasm. Additional protection could be conferred by a periplasmic chaperone to limit the free metal species prior to export. Using isothermal titration calorimetry, we have demonstrated that two periplasmic proteins, CusF and CusB, of the Escherichia coli Cu(I)/Ag(I) efflux system undergo a metal-dependent interaction. Through the development of a novel X-ray absorption spectroscopy approach using selenomethionine labeling to distinguish the metal sites of the two proteins, we have demonstrated transfer of Cu(I) occurs between CusF and CusB. The interaction between these proteins is highly specific, as a homologue of CusF with a 51% identical sequence and a similar affinity for metal, did not function in metal transfer. These experiments establish a metallochaperone activity for CusF in the periplasm of gram-negative bacteria, serving to protect the periplasm from metal-mediated damage.     

Utilization by Escherichia coli of a high-molecular-weight, linear polyphosphate: roles of phosphatases and pore proteins.

We observed that wild-type Escherichia coli utilized a linear polyphosphate with a chain length of 100 phosphate residues (poly-P100) as the sole source of phosphate in growth medium. A mutation in the gene phoA of alkaline phosphatase or phoB, the positive regulatory gene, prevented growth in this medium. Since no alkaline phosphatase activity was detected outside the wild-type cells, the periplasmic presence of the enzyme was necessary for the degradation of polyphosphate. A 90% reduction in the activity of periplasmic acid phosphatase with a pH optimum of 2.5 (delta appA mutants) did not affect polyphosphate utilization. Of the porins analyzed (OmpC, OmpF, and PhoE), the phoB-inducible porin PhoE was not essential since its absence did not prevent growth. To study how poly-P100 diffused into the cells, we used high-resolution 31P nuclear magnetic resonance (31P NMR) spectroscopy. The results suggest that poly-P100 entered the periplasm and remained in equilibrium between the periplasm and the medium. When present individually, porins PhoE and OmpF facilitated a higher permeability for poly-P100 than porin OmpC did. The degradation of polyphosphate by intact cells of E. coli observed by 31P NMR showed a time-dependent increase in cellular phosphate and a decrease in polyphosphate concentration.     

Identification of a periplasmic C-type cytochrome as electron donor to the plasma membrane-bound cytochrome oxidase of the cyanobacterium Nostoc Mac

Photoautotrophically grown cyanobacterium Nostoc sp. strain Mac (PCC 8009) released up to about 10 nmol of a c-type cytochrome per ml packed cells after treatment with EDTA under conditions that left the plasma membrane absolutely intact as judged from the absence of cytosolic proteins in the supernatant. Spectra of the ascorbate reduced cytochrome revealed peaks at 553, 522 and 416 nm. The protein was purified to an A-553/A-275 ratio of 0.8. Midpoint potential (at pH 7), isoelectric point and apparent molecular weight of the cytochrome were +0.35 V, 8.6, and around 10,500, respectively. The cytochrome proved to be an excellent electron donor to the aa3-type cytochrome oxidase in both plasma and thylakoid membranes isolated and purified from Nostoc Mac. Chemoheterotrophic growth of the cells increased the level of periplasmic cytochrome c up to 10-fold and cytochrome oxidase activity of plasma membranes up to 90-fold. The periplasmic cytochrome also transferred electrons to photosystem I in illuminated thylakoid membranes. We conclude that cyanobacteria contain a periplasmic c-type cytochrome presumably identical to so-called cytochrome c6 or c-553 which has long been known as a photosynthetic (i.e. thylakoid-associated) redox protein in these organisms, and which is capable of donating electrons (from the periplasmic space) to the cytochrome oxidase in the plasma membrane and (from the thylakoid lumen) to both P700 and cytochrome oxidase in the thylakoid membrane.