Comparative studies on extracellular protease secretion and glucoamylase production by free and immobilized <Emphasis Type="Italic">Aspergillus niger</Emphasis> cultures

The effects of cell immobilization on the secretion of extracellular proteases and glucoamylase production by Aspergillus niger were investigated under a variety of immobilization techniques and culture conditions. Immobilization was achieved by means of cell attachment on metal surfaces or spore entrapment and subsequent growth on porous Celite beads. Free-suspension cultures were compared with immobilized mycelium under culture conditions that included growth in shake flasks and an airlift bioreactor. Cell attachment on metal surfaces minimized the secretion of proteases while enhancing glucoamylase production by the fungus. Growth on Celite beads in shake-flask cultures reduced the specific activity of the secreted proteases from 128 to 61 U g⁻¹, while glucoamylase specific activity increased from 205 to 350 U g⁻¹. The effect was more pronounced in bioreactor cultures. A reduction of six orders of magnitude in protease specific activities was observed when the fungus grew immobilized on a rolled metal screen, which served as the draft tube of an airlift bioreactor. Received 29 October 2001/ Accepted in revised form 14 June 2002     

Characterization of proteolytic and collagenolytic enzymes from the larvae of Lucilia cuprina, the sheep blowfly

Isoelectric focusing was used to characterize proteolytic enzymes in homogenate and excretory-secretory preparations of the larvae of L. cuprina, the sheep blowfly. Zymogram overlays showed that the larvae produce a number of highly active proteases which have a wide range of isoelectric points and molecular weights. The alkaline and neutral pI proteases were inhibited by phenylmethyl-sulfonylfluoride, leupeptin and aprotinin; this indicated the presence of serine in the active site. Pepstatin and the metal chelating agent ethylenediaminetetraacetic acid had no effect on the activity of any of the proteases. Optimal pH for activity of the proteases was between 7 and 8. In addition, the proteases were found to be heat labile. Digestion of collagen fibrils confirmed the existence of collagenolytic activity in the excretory-secretory enzyme preparations. It is suggested that these enzymes may be involved in the nutrition of the larvae and in the pathogenesis of the lesion on the skin.     

Multiple proteases from Streptomyces moderatus. II. Physicochemical and enzymatic properties of the extracellular proteases

The physicochemical and enzymatic properties of five different extracellular proteases of Streptomyces moderatus were studied. The first protease was found to be a metal chelator sensitive protease with a Mr of 21,000 +/- 1000 a and a pI of 4.6. The second enzyme was an anionic trypsin-like protease (Mr 19,000 +/- 1000; pI 3.8) with a Km value of 4.76 X 10(-4) M on N-benzoyl-L-arginine-p-nitroanilide. A Km value of 1.52 X 10(-4) M was obtained when N-benzoyl-L-arginine ethyl ester was used as the substrate. The other three enzymes were found to be serine alkaline proteases with Mr's of 22,000, 29,000, and 23,000 +/- 1000 and with respective pI's of 7.8, 8.4, and 9.2. All the proteases showed optimum activity in the alkaline pH range. One of the three proteases was found to possess chymotrypsin and elastase-like properties. All five proteases were found to be unstable at temperatures above 60 degrees C. Except the trypsin-like protease, which was stable only in acidic pH, all other enzymes were found to be stable over a wide range of pH.     

Effects of cadmium, nickel and lead on growth, chlorophyll content and proteins of weeds

The effects of Cd, Ni and Pb on the growth, chlorophyll (Chl) and protein contents, and content of proteases of potted weed plants Cyperus difformis, Chenopodium ambrosioides and Digitaria sanguinolis were determined. The three heavy metals inhibited the shoot growth but were less suppresive to root growth. They also lowered leaf Chl content. The changes in root and shoot protein and proteases contents of weeds were interrelated. The heavy metal additions to soil increased their contents in both roots and shoots, several times more in roots than in shoots. This revised version was published online in July 2006 with corrections to the Cover Date.     

Activities and partial purification of extracellular proteases of Bacteroides nodosus from virulent and benign footrot

In an attempt to differentiate virulent and benign strains of B. nodosus, the extracellular proteolytic activity of these cultures was assayed with elastin, casein and hide powder azure, and the stability to heating at 55 degrees C was determined. Broth cultures of both strains hydrolysed 125I-labelled elastin, indicating that this activity is not a unique marker of virulence. When cultures were grown in Trypticase-arginine-serine broth medium modified by omitting Na2CO3 and thioglycollic acid, the total proteolytic activity and its stability at 55 degrees C could be used to differentiate isolates causing virulent or benign footrot lesions. However, when other broth cultures were used, these parameters could no longer be used to make such a distinction. The proteases of a virulent and benign strain of B. nodosus were partially purified and characterized. Four to five closely related proteases were detected by polyacrylamide gel electrophoresis at pH 8.8 in both types of isolates. The proteases are serine-type enzymes requiring a divalent metal ion such as calcium for activity. The proteases of the benign strain were somewhat less stable to heat than the enzymes of the virulent strain. Differences in the relative mobilities of the proteases of virulent and benign strains of B. nodosus, on electrophoresis at pH 8.8, suggest that this property may be used to distinguish virulent and benign strains.     

Proteases produced by a proteolytic mutant of Clostridium botulinum type E.

A proteolytic mutant from Clostridium botulinum type E produced extracellular proteases after the end of exponential growth coinciding with the period of sporulation. Proteases were separated into four fractions by chromatography on a DEAE-cellulose column. One was a sulphydryl-dependent protease that also apparently required a divalent cation for enzyme activity since it was inhibited by EDTA. This enzyme hydrolysed synthetic amide and ester compounds containing an arginine residue, and showed some activity towards L-lysine methyl ester. It appeared that two of the other proteases were serine proteases and the fourth was a metal protease. These last three proteases did not require a thiol agent and did not hydrolyse any of the synthetic amides or esters examined. Only the sulphydryl-dependent protease could activate C. botulinum type B, E and F toxins. The ability of this enzyme to activate type B and E toxins was markedly lower than that of trypsin. The susceptibility of type B toxin to this protease was lower than that of type E toxin. C2 toxin was not activated by this enzyme. It is suggested that the sulphydryl-dependent protease in this proteolytic mutant of C. botulinum type E has properties similar to those of proteases from C. botulinum types B and F.     

Purification and some properties of the extracellular acid proteases from Mucor renninus

A complex of proteases was fractionated into three enzymes by chromatography of a crude enzyme preparation obtained from culture fluid of the fungus Mucor renninus on biospecific polystyrene adsorbent. Electrophoretically homogeneous proteases I-III were obtained by subsequent rechromatography on biospecific adsorbent and gel filtration on Sephadex G-75. Optimal proteolytic activities occurred at pH 4.25; 3.5 and 2.5 for enzymes I, II and III, respectively. Milk-clotting activity was exhibited only by protease II. All three proteases hydrolysed haemoglobin, Na caseinate and bovine serum albumin. Enzyme I hydrolysed Na caseinate the most effectively, while haemoglobin was the most effective substrate for proteases II and III. Trypsinogen was activated only by protease I. All three enzymes have a molecular weight ～35 000 as determined by gel chromatography on Sephadex G-75 column and by sodium dodecylsulphate disc electrophoresis. Isoelectric points, pH-stability range, amino acid composition, carbohydrate content were determined for each enzyme and the influence of metal ions (Ca²⁺, Mg²⁺, Cu²⁺, Co²⁺) on proteolytic activities of these enzymes studied.     

Fibronectin-degrading proteases from the membranes of transformed cells

The local degradation of fibronectin substrata by Rous sarcoma virus-transformed chick embryonic fibroblasts requires cell-contact-related metalloendoprotease and serine-protease activities. Using fibronectin-containing SDS gels, two large proteases with apparent molecular weights of 120K and 150K were found only in the membrane fraction of transformed cells and were absent in normal cells. Both 120K and 150K proteases were active at neutral pH, but showed preferential inhibitor sensitivities of serine and metal proteases, respectively. The 150K protease appeared to account for most of the proteolytic activity since metalloendoprotease inhibitors completely blocked proteolytic activity of the 150K in fibronectin gels, more than 80% of the fibronectin-degrading activity of solubilized membranes, and largely suppressed the appearance of fibronectin degradation spots in cultures of transformed cells.     

Overexpression,Purification and Functional Characterisation of Wild-Type HIV-1 Subtype C Protease and Two Variants Using a Thioredoxin and His-Tag Protein Fusion System

In recent years, various strategies have been used to overexpress and purify HIV-1 protease because it is an essential drug target in anti-retroviral therapy. Obtaining sufficient quantities of the enzyme, however, remains challenging. Overexpression of large quantities is prevented due to the enzyme’s autolytic nature and its inherent cytotoxicity in Escherichia coli cells. Here, we describe a novel HIV-1 protease purification method using a thioredoxin–hexahistidine fusion system for the wild-type and two variant proteases. The fusion proteases were overexpressed in E. coli and recovered by immobilised metal ion affinity chromatography. The proteases were cleaved from the fusion constructs using thrombin. When compared to the standard overexpression and purification protocol in use in our laboratory, the expression of the fusion-derived wild-type protease was increased from 0.83 to 2.5 mg/l of culture medium. The expression levels of the two variant proteases ranged from 1.5 to 2 mg/l of culture medium. The fusion wild-type and variant proteases were inactive before the cleavage of the thioredoxin–hexahistidine fusion tag as no enzymatic activity was observed. The proteases were, however, active after cleavage of the tag. The novel thioredoxin–hexahistidine fusion system, therefore, enables the successful overexpression and purification of catalytically active HIV-1 proteases.     

Purification and characterization of the highly thermostable proteases from Bacillus stearothermophilus TLS33

Three thermostable proteases, designated S, N, and B, are extracellular enzymes produced by Bacillus stearothermophilus strain TLS33. They were purified by lysine affinity chromatography, strong anion exchange Q HyperD chromatography, and Ultrogel AcA44 gel filtration. The molecular masses of the enzymes determined by SDS-PAGE and zymography were approximately 36, 53, and 71 kDa, respectively. Thermostable protease S bound strongly to the lysine affinity column and could be purified by this single step. The optimum pH values of proteases S, N, and B were shown to be 8.5, 7.5, and 7.0, respectively. The maximum activities for the enzymes were at 70, 85, and 90 degrees C, respectively. Proteases S, N, and B at pH 7.0 in the presence of 5 mM CaCl(2) retained half their activities after 30 min at 72, 78, and 90 degrees C, respectively. All three thermostable proteases were strongly inhibited by the metal chelators EDTA and 1,10-phenanthroline, and the proteolytic activities were restored by addition of ZnCl(2). They can thus be classified as Zn(2+) metalloproteases. The cleavage specificities of proteases S, N, and B on a 30-residue synthetic peptide from pro-BPN' subtilisin were Tyr-Ile, Phe-Lys, and Gly-Phe, respectively.     

A lead discovery strategy driven by a comprehensive analysis of proteases in the peptide substrate space

We present here a comprehensive analysis of proteases in the peptide substrate space and demonstrate its applicability for lead discovery. Aligned octapeptide substrates of 498 proteases taken from the MEROPS peptidase database were used for the in silico analysis. A multiple‐category naïve Bayes model, trained on the two‐dimensional chemical features of the substrates, was able to classify the substrates of 365 (73%) proteases and elucidate statistically significant chemical features for each of their specific substrate positions. The positional awareness of the method allows us to identify the most similar substrate positions between proteases. Our analysis reveals that proteases from different families, based on the traditional classification (aspartic, cysteine, serine, and metallo), could have substrates that differ at the cleavage site (P1–P1′) but are similar away from it. Caspase‐3 (cysteine protease) and granzyme B (serine protease) are previously known examples of cross‐family neighbors identified by this method. To assess whether peptide substrate similarity between unrelated proteases could reliably translate into the discovery of low molecular weight synthetic inhibitors, a lead discovery strategy was tested on two other cross‐family neighbors—namely cathepsin L2 and matrix metallo proteinase 9, and calpain 1 and pepsin A. For both these pairs, a naïve Bayes classifier model trained on inhibitors of one protease could successfully enrich those of its neighbor from a different family and vice versa, indicating that this approach could be prospectively applied to lead discovery for a novel protease target with no known synthetic inhibitors.     

Periplasmic proteases of Escherichia coli

In the course of examining the turnover of enzymes and proteins subject to catabolite inhibition and/or catabolite repression in Escherichia coli, we have observed at least three novel calcium- or manganese-activated proteolytic activities restricted to the periplasmic space. The occurrence and level of these proteolytic activities vary with the stage of cell growth and carbon source. Each of these proteases are neutral metalloendoproteases capable of degrading test substrates such as casein, insulin, globin, and protamine and appear to be unique when compared with the known periplasmic proteases in E. coli. One of these proteases (designated protease VII) has been purified to homogeneity and characterized in regard to subunit structure, sensitivity to protease inhibitors and metal ions, and substrate specificity. Immunological and genetic approaches are being employed to determine if these novel proteases arise from a common gene product. The physiological role of these proteases remains to be established.     

Zymogens and cofactors of blood coagulation

Blood coagulation is a system in which a series of zymogens of serine proteases are sequentially activated. In this regard, there is little fundamental difference between coagulation and the activation of the homologous pancreatic zymogens. There are, however, several aspects unique to coagulation which are discussed in detail. These are (1) the requirement for a high-molecular-weight protein or lipoprotein cofactor for optimal reaction rates, (2) the requirement for membranes or a membrane-like surface which further distinguishes this system; (3) a metal ion requirement for most reactions (in contrast to the pancreatic serine proteases) relating to the content of the newly described amino acid gamma-carboxyglutamic acid in the four vitamin K-dependent proteins, regarding which recent data relating to the metal binding sites on prothrombin are discussed in detail; and (4) the uniqueness of the initiating reactions in comparison to those which activate the pancreatic zymogens, insofar as no enzyme corresponding to enterokinase has been identified. The implications of this phenomenon are analyzed with particular attention to the potential role of the endogenous activity of certain zymogens in initiating coagulation. The article deals finally with the specific problems attendant on analyzing a system in which many serine proteases lacking absolute specificity are generated and regulated.     

Histidine mapping of serine protease: a synergic study by IMAC and molecular modelling

The immobilized metal ion affinity (IMA) interaction of different serine proteases, namely porcine and bovine trypsins and BPN' and Carlsberg subtilisins, was studied on Sepharose-IDA-CuII. Both trypsins were resolved into their different subspecies, whereas the subtilisins appeared as only one species. The use of diethyl pyrocarbonate-modified enzymes demonstrated the contribution of histidine(s) as the sole interacting site(s). The use of different peptidic and chemical inhibitors complexed to the enzymes confirmed the contribution of histidine(s) as the interacting site(s) and further resulted in different chromatographic patterns for the free and complexed serine proteases. Comparison of the chromatographic data for each enzyme with the accessible surface area calculation by molecular modelling on the available crystallographic structure allowed us to hypothesize a map of the surface-accessible histidine on each enzyme.     

Breaking the singleton of germination protease

Germination protease (GPR) plays an important role in the germination of spores of Bacillus and Clostridium species. A few very similar GPRs form a singleton group without significant sequence similarities to any other proteins. Their active site locations and catalytic mechanisms are unclear, despite the recent 3-D structure determination of Bacillus megaterium GPR. Using structural comparison and sequence analysis, we show that GPR is homologous to bacterial hydrogenase maturation protease (HybD). HybD's activity relies on the recognition and binding of metal ions in Ni-Fe hydrogenase, its substrate. Two highly conserved motifs are shared among GPRs, hydrogenase maturation proteases, and another group of hypothetical proteins. Conservation of two acidic residues in all these homologs indicates that metal binding is important for their function. Our analysis helps localize the active site of GPRs and provides insight into the catalytic mechanisms of a superfamily of putative metal-regulated proteases.     

Purification and Properties of Proteases from a Marine-psychrophilic Bacterium

Protease which was found in the culture fluid of Pseudomonas sp. No. 548 was fractionated into four components with protease activity by a two step chromatography using DEAE-cellulose. Each protease was further purified by gel filtration on Sephadex G-100 and/or G-75. The protease of Ia was obtained in crystalline form and was shown to be homogeneous by analysis with electrophoresis, while the other three enzymes were also highly purified. The enzymatic properties of the proteases were investigated. All of the four enzymes were inactivated by ethylene diamine tetraacetate. Proteases Ia, Ib, and IIb were inactivated by diisopropylfluorophosphate. The optimum activity of protease Ia was shown to be at pH 10.0, and that of the other enzymes were at pH 7.0 to 8.0. The proteases of Ia, Ib, and IIb were stabilized by calcium ion. The effect of temperature, pH, and metal ions on the activity of the enzyme were also investigated.     

High-molecular-mass proteases (possible proteasomes) in Escherichia coli K12

Two high-molecular-mass proteases have been detected in E.coli K12 and isolated from the periplasmic fraction released by osmotic shock. The two proteases, designated Protease peri7 and Protease peri8, have similar molecular masses (greater than 2000 kDa) and degrade alpha- and beta-casein, but not insulin B chain. Protease peri7 is a metalloprotease activated 3-6 fold by ATP, dATP and GTP but inhibited by AMP. Nucleotide hydrolysis occurs during protein breakdown. Protease peri8, in contrast, is a serine protease unaffected by nucleotides or metal chelators. The two proteases appear by electron microscopy to be ring-shaped particles of approximately 125 A degrees in diameter. These proteases appear to be very similar to the multi-protease complexes (Proteasomes) detected in a variety of eukaryotic cells.     

The influence of enzymatic treatment on wool fibre properties using PEG-modified proteases

The main contribution of the presented work was to introduce the use of proteases modified with the soluble polymer polyethylene glycol (PEG) in the bio-finishing process of wool fibres, to target enzyme action to the outer parts of wool fibres, i.e. to avoid the diffusion and consequent destroying of the inner parts of the wool fibre structure, in the case of native proteases using.

Different proteolytic enzymes from Bacillus lentus and Bacillus subtilis in native and PEG-modified forms were investigated and their influence on the modification of wool fibres morphology surface, chemical structure, as well as the hydrolysis of wool proteins, the physico-mechanical properties, and the sorption properties of 1:2 metal complex dye during dyeing were studied. SEM images of wool fibres confirmed smoother and cleaner fibre surfaces without fibre damages using PEG-modified proteases. Modified enzyme products have a benefit effect on the wool fibres felting behaviours (14%) in the case when PEG-modified B. lentus is used, without markedly fibre damage expressed by tensile strength and weight loss of the fibre. Meanwhile the dye exhaustion showed slower but comparable level of dye uptake at the end of the dyeing.