Localization of Peptidases in Lactococci

The localization of two aminopeptidases, an X-prolyl-dipeptidyl aminopeptidase, an endopeptidase, and a tripeptidase in Lactococcus lactis was studied. Polyclonal antibodies raised against each purified peptidase are specific and do not cross-react with other peptidases. Experiments were performed by immunoblotting after cell fractionation and by electron microscopy of immunogold-labeled peptidases. All peptidases were found to be intracellular. However, immunogold studies showed a peripheral labeling of the X-prolyl-dipeptidyl aminopeptidase, the tripeptidase, and the endopeptidase. This peripheral location was further supported by the detection of these three enzymes in cell membrane fractions in which none of the two aminopeptidases was present.     

Brush border membrane hydrolysis of S-benzyl-cysteine-p-nitroanilide, and activity of aminopeptidase M

A peptidase activity which can hydrolyze cysteinylglycine and S-benzyl-cysteine-p-nitroanilide was purified from rat renal brush border membranes. The purified peptidase exhibits an even greater specific activity when assayed with substrates for aminopeptidase M, leucine-p-nitroanilide and alanine-p-nitroanilide. All three activities copurify and coelectrophorese. In addition titration of the three activities in isolated brush border membrane vesicles with Fab antibodies prepared against the highly purified peptidase produced similar inactivation profiles. Therefore, the activity within brush border membrane towards S-benzyl-cysteine-p-nitroanilide is due to the action of aminopeptidase M (EC 3.4.11.2.)     

Enzyme cytochemistry of rat organs after uremia with special reference to proteases

Wistar rat organs and tissues were investigated after acute and chronic uremia using enzyme cytochemical means whereby special attention was paid to plasma membrane and lysosomal proteases. Heart muscle, pancreas, spleen, stomach, duodenum, jejunum, colon and skeletal muscle did not show any clear-cut indications of alterations. After acute uremia activities of dipeptidyl peptidase IV, glutamyl aminopeptidase and microsomal alanyl aminopeptidase were decreased in the extraorbital gland and that of dipeptidyl peptidase IV in the submandibular gland. The thymus showed an increased staining for glutamyl aminopeptidase and lysosomal proteases. An activity increase of dipeptidyl peptidase IV, acid phosphatase and beta-N-acetyl-D-glucosaminidase occurred in bronchial lavage cells among which the alveolar macrophages predominated. In addition, their number was comparatively higher. Non-specific esterase activity was lowered in these cells. Alkaline phosphatase activity was drastically enhanced at the biliary pole of hepatocytes. Following chronic uremia all effects were less pronounced except for the lavage cells which were positive for glutamyl aminopeptidase, microsomal alanyl aminopeptidase and gamma-glutamyl transpeptidase and showed increased staining for lysosomal proteases, glycosidases and nonspecific phosphatases.     

Experimental evidence for interactions between bacterial peptidase and alkaline phosphatase activity in the Baltic Sea

From the observed pattern of aminopeptidase and alkaline phosphatase activities in the Baltic Sea, the question arose whether there is an interaction between the activities of both enzymes. In experiments with 0.8 m filtered seawater, the effects of commercial alkaline phosphatase on bacterial aminopeptidase, the effects of commercial peptidase on bacterial alkaline phosphatase activity (APA), and the effects of proteins, carbohydrates and inorganic nutrients on the activities of both enzymes were investigated.Addition of commercial alkaline phosphatase stimulated bacterial aminopeptidase activity and, similarly, the addition of commercial peptidase increased the APA in bacteria. The proteins, albumin and casein, stimulated aminopeptidase activity and APA simultaneously. Experiments using ammonium and glucose suggested that stimulation of APA by peptidase could be mediated by nitrogen and carbon availability. There were also some indications that stimulation of aminopeptidase activity by alkaline phosphatase functioned by catalysing phosphate release from organic phosphorus compounds.     

Biosynthesis of intestinal microvillar proteins. Pulse-chase labelling studies on maltase-glucoamylase, aminopeptidase A and dipeptidyl peptidase IV

The biogenesis of three intestinal microvillar enzymes, maltase-glucoamylase (EC 3.2.1.20), aminopeptidase A (aspartate aminopeptidase, EC 3.4.11.7) and dipeptidyl peptidase IV (EC 3.4.14.5), was studied by pulse-chase labelling of pig small-intestinal explants kept in organ culture. The earliest detectable forms of the enzymes were polypeptides of Mr 225000, 140000 and 115000 respectively. These were found to represent the enzymes in a 'high-mannose' state of glycosylation, as judged by their susceptibility to treatment with endo-beta-N-acetylglucosaminidase H (EC 3.2.1.96). After about 40-60 min of chase, maltase-glucoamylase, aminopeptidase A and dipeptidyl peptidase IV were further modified to yield the mature polypeptides of Mr 245000, 170000 and 137000 respectively, which were expressed at the microvillar membrane after 60-90 min of chase. The fact that the enzymes before reaching the microvillar membrane were found in a Ca2+-precipitated membrane fraction (intracellular and basolateral membranes), but not in soluble form, indicates that during biogenesis maltase-glucoamylase, aminopeptidase A and dipeptidyl peptidase IV are transported and assembled in a membrane-bound state.     

A comparison of membrane enzymes of human and pig oesophagus; the pig oesophagus is a good model for studies of the gullet in man

Summary The distribution and relative catalytic activities of five plasma membrane enzymes (alkaline phosphatase, dipeptidyl peptidase IV, γ-glutamyl transpeptidase, microsomal alanyl aminopeptidase and glutamyl aminopeptidase) were examined in human and pig oesophagus. In both species, alkaline phosphatase activity occurred in basal and suprabasal cells of the epithelium and in capillaries. Stromal cells in the human submucosa were particularly reactive. Dipeptidyl peptidase IV was present in blood vessels and capillaries in man and pig and in submucous glands in the pig. The enzyme was also present in both species in the lamina propria cells immediately adjacent to the epithelial basal lamina. In the human, γ-glutamyl transpeptidase occurred in the epithelial basal cells and in isolated basal and lower prickle cells in the pig. Stromal cells in the human submucosa were strongly reactive and capillaries in the muscularis propria in both species moderately active. Microsomal alanyl aminopeptidase was detected in lamina propria cells adjacent to the epithelial basal cell layer in man and pig and at the apices of mucous cells in pig submucous glands. Weak glutamyl aminopeptidase activity was confined to capillaries in both species. The findings of this study, along with the ready availability of pig oesophagus, suggest that the pig may be a suitable model for studies of the gullet in man.     

Seasonal changes in peptidase activities and their properties in the surface water of Lake Shinryu

Serial monthly peptidase activities were assayed in the surface water of Lake Shinryu, located in the Chugoku district of Japan, using artificial fluorescent peptidase substrates. The results indicated that the lake water had higher aminopeptidase activities than endopeptidase activities except in November and December, whereas lake water filtrated using membranes with a pore size of 0.2 μm showed higher endopeptidase activities than aminopeptidase activities from June to December, with peaks in June and November. The serial aminopeptidase activity profile was relatively similar to that of the chlorophyll-a concentration. The size distribution of aminopeptidase activities indicated that half of the total activity was retained in the fraction between 5 and 100 μm. These results suggest that phytoplankton participate in the digestion of peptides with aminopeptidase activities. Electrophoretic analysis detected the presence of three peptidase bands (1, 2, and 3) in the lake water that passed through the 0.2-μm membranes. Samples from June, September, and November dominantly contained these active bands in different electrophoretic profiles.     

Localization of angiotensin-converting enzyme,prolyl endopeptidase and other peptidases in cultured neuronal or glial cells

To determine the cellular localization of nervous tissue peptidases, 7 peptidases and 2 lysosomal marker enzyme activities were measured in cultured mouse and rat cells. Neuronal cells of both species exhibited higher activities of angiotensin-converting enzyme (ACE) and prolyl endopeptidase (Pro-EP) than glial cells did. In contrast, arginyl endopeptidase and lysosomal enzymes (acid phosphatase, β-glucuronidase) in the neuronal cell lines were lower than those in the glial cell lines. Other peptidases (alanyl aminopeptidase, arginyl aminopeptidase, leucyl aminopeptidase, dipeptidyl aminopeptidase) activities were not specifically localized in either cell lines. The effects of cellular differentiation on these peptidase activities in the PC 12h cell line and rat glioblasts were also examined using nerve growth factor (NGF) and glia maturation factor (GMF), respectively. Neuron specific peptidase (ACE and Pro-EP) activities were decreased in PC12h cells cultured with NGF, and Pro-EP activity was increased in the glioblast cells cultured with GMF. These results support the idea that some of the peptidases are differentially localized in neuronal or glial cells, and play physiological roles in central or peripheral neural tissues.     

Efficient Implementation of Consecutive Reactions by Peptidases at the Periphery of the Streptococcus cremoris Membrane

Activities detectable in Streptococcus cremoris with the chymotrypsin substrate N-glutaryl-l-phenylalanine-4-nitroanilide and formerly designated endopeptidases P37 and P50 (F. A. Exterkate, Appl. Environ. Microbiol. 47:177-183, 1984) are both coupled peptidase reactions. These coupled reactions involve a membrane-bound, restricted l-alpha-glutamyl aminopeptidase which is responsible for the initial release of the glutaryl moiety. The subsequent reaction is catalyzed by either a so-called low-temperature or a high-temperature phenylalanyl aminopeptidase activity, both located at the outside surface of the membrane. Altered microenvironmental conditions created by the membrane-perturbing action of n-butanol or obtained by solubilization resulted in the removal of a restriction on the activity of l-alpha-glutamyl aminopeptidase and in a less efficient functioning of the coupled reactions; a long transient phase occurred before the steady state was reached. The results suggest that the in situ spatial organization is conducive to an efficient attuning of at least three peptidases which are located at the outer membrane surface and in the membrane. The possibility that peptidases in these locations exist as a cluster with physiological significance is discussed in relation to growth of S. cremoris in milk.     

Biochemical studies on liver functions in primary cultured hepatocytes of adult rats. III. Changes of enzyme activities on cell membranes during culture

When liver cells were dispersed with collagenase, their 5'-nucleotidase activity decreased to half the initial level, but it increased to the original level again on culture of the cells for a few days. The activity of another membrane enzyme, alkaline phosphatase, did not decrease on dispersion of the cells, but it increased about 10-fold on culture of the cells. These inductions did not require any hormone, but the effects were greater at a high cell density. These enzymes are located in both the plasma membranes and the cytoplasm, but the enzymes in these two locations can be distinguished by differences in their pH optima, substrate specificities, and susceptibilities to inhibitors. The increases were found to be due to increases in the activity of only the enzymes in the plasma membranes. The increases in enzyme activities were inhibited by actinomycin D, cycloheximide, and puromycin. The activities of leucine aminopeptidase and aminopeptidase B, other membrane enzymes, remained constant during dispersion and culture of the cells. These results show that enzymes in the cell membranes are affected in different ways by cell dispersion with collagenase and subsequent culture of the cells.     

Hydrolysis of milk-derived bioactive peptides by cell-associated extracellular peptidases of Streptococcus thermophilus

The trend to confer new functional properties to fermented dairy products by supplementation with bioactive peptides is growing in order to encounter the challenge of health-promoting foods. But these functional ingredients have not to be hydrolysed by proteases of bacteria used in the manufacture of these products. One of the two yoghurt bacteria, Streptococcus thermophilus, has long been considered as weakly proteolytic since its only cell wall-associated subtilisin-like protease, called PrtS, is not always present. Nevertheless, a recent study pointed out a possible peptidase activity in certain strains. In this present study, the stability of milk-derived bioactive peptides, e.g. the anxiolytic peptide, α_s1-CN-(f91-97), in the presence of two different S. thermophilus strains with PrtS⁺ or PrtS^? phenotype was studied. Both strains appeared to be capable of hydrolysing the α_s1-CN-(f91-97) and other bioactive peptides by recurrent removal of N-terminal residues. The hydrolysis was neither due to intracellular peptidases nor to HtrA protease. Results obtained showed that the observed activity originates from the presence at the surface of both strains of an extracellular aminopeptidase activity. Moreover, a cell wall-associated X-prolyl dipeptidyl peptidase activity was also highlighted when β-casomorphin-7 was used as substrate. All of these findings suggest that, in order to use fermented milks as vector of bioactive peptides, the stability of these bioactive peptides in this kind of products implies to carefully characterize the potential action of the surface proteolytic enzymes of S. thermophilus.     

Proteolytic enzymes in human leukemic lymphoid cells. III. Aminopeptidases, angiotensin-converting enzyme, and its inhibitor in cells of different immunological phenotype

Activities of plasma membrane proteinases such as angiotensin-converting enzyme (ACE), aminopeptidases, and dipeptidyl peptidase IV (DPP-IV) were determined in lymphoid cells of various immunological phenotype which were obtained from 30 patients with lymphoproliferative diseases. The enzyme activities significantly varied depending on the immunological phenotype and stage of cell differentiation, but no correlation was found between activities of ACE, DPP-IV, and aminopeptidases in the cells of different type. The cell lysates studied contained at least two classes of aminopeptidases: metal- and sulfhydryl-dependent enzymes. A sulfhydryl-dependent aminopeptidase with activity optimum at pH 8. 5-9.0 was found for the first time and is suggested to be from a poorly studied aminopeptidase family. In addition to ACE, lysates of leukemic T- and B-cells were found to contain an inhibitor of ACE which was not previously described for these cells.     

Enzyme cytochemistry of rat organs after uremia with special reference to proteases

Summary Wistar rat organs and tissues were investigated after acute and chronic uremia using enzyme cytochemical means whereby special attention was paid to plasma membrane and lysosomal proteases. Heart muscle, pancreas, spleen, stomach, duodenum, jejunum, colon and skeletal muscle did not show any clear-cut indications of alterations. After acute uremia activities of dipeptidyl peptidase IV, glutamyl aminopeptidase and microsomal alanyl aminopeptidase were decreased in the extraorbital gland and that of dipeptidyl peptidase IV in the submandibular gland. The thymus showed and increased staining for glutamyl aminopeptidase and lysosomal proteases. An activity increase of dipeptidyl peptidase IV, acid phosphatase and -N-acetyl-d-glucosaminidase occurred in bronchial lavage cells among which the alveolar macrophages predominated. In addition, their number was comparatively higher. Non-specific esterase activity was lowered in these cells. Alkaline phosphatase activity was drastically enhanced at the biliary pole of hepatocytes. Following chronic uremia all effects were less pronounced except for the lavage cells which were positive for glutamyl aminopeptidase, microsomal alanyl aminopeptidase and -glutamyl transpeptidase and showed increased staining for lysosomal proteases, glycosidases and nonspecific phosphatases.Dedicated to Professor Dr. T.H. Schiebler on the occasion of his 65th birthdaySupported by the German Research Foundation (Sfb 174)     

Expression of Six Peptidases from Lactobacillus helveticus in Lactococcus lactis

For development of novel starter strains with improved proteolytic properties, the ability of Lactococcus lactis to produce Lactobacillus helveticus aminopeptidase N (PepN), aminopeptidase C (PepC), X-prolyl dipeptidyl aminopeptidase (PepX), proline iminopeptidase (PepI), prolinase (PepR), and dipeptidase (PepD) was studied by introducing the genes encoding these enzymes into L. lactis MG1363 and its derivatives. According to Northern analyses and enzyme activity measurements, the L. helveticus aminopeptidase genes pepN, pepC, and pepX are expressed under the control of their own promoters in L. lactis. The highest expression level, using a low-copy-number vector, was obtained with the L. helveticus pepN gene, which resulted in a 25-fold increase in PepN activity compared to that of wild-type L. lactis. The L. helveticus pepI gene, residing as a third gene in an operon in its host, was expressed in L. lactis under the control of the L. helveticus pepX promoter. The genetic background of the L. lactis derivatives tested did not affect the expression level of any of the L. helveticus peptidases studied. However, the growth medium used affected both the recombinant peptidase profiles in transformant strains and the resident peptidase activities. The levels of expression of the L. helveticus pepD and pepR clones under the control of their own promoters were below the detection limit in L. lactis. However, substantial amounts of recombinant pepD and PepR activities were obtained in L. lactis when pepD and pepR were expressed under the control of the inducible lactococcal nisA promoter at an optimized nisin concentration.     

Regulation of peptidase activity in a three-dimensional aggregate model of brain tumor vasculature

The abnormal vascular system of brain cancers inappropriately expresses membrane proteins, including proteolytic enzymes, ultimately resulting in blood extravasation. The production of inflammatory mediators, such as cytokines and nitric oxide, and tumor hypoxia have been implicated in these effects. We have previously shown that the activity of aminopeptidase A is increased in the abnormal vascular system of human and rat brain tumors. To study the mechanisms regulating the activities of peptidases in cerebral vasculature in brain tumors, we have developed a three-dimensional model of differentiated rat brain cells in aggregate cultures in which rat brain microvessels were incorporated. The secretion of interleukin-6 (IL-6) in the culture medium of aggregates was used as an indicator of inflammatory activation. Addition to these aggregates of C6 glioma cell medium (C6-CM) conditioned under hypoxic or normoxic conditions or serum mimicked tumor-dependent hypoxia or conditions of dysfunction of brain tumor vasculature. Hypoxic and normoxic C6-CM, but not serum, regulated peptidase activity in aggregates, and in particular it increased the activity of aminopeptidase A determined using histoenzymography. Serum, but not C6-CM, increased IL-6 production, but did not increase aminopeptidase A activity in aggregates. Thus soluble glioma-derived factors, but not serum-derived factors, induce dysfunctions of cerebral vasculature by directly regulating the activity of peptidases, not involving inflammatory activation. Tumor hypoxia is not necessary to modulate peptidase activity.     

Variations des zymogrammes du tube digestif et du muscle chez Cyclonassa neritea en fonction de la température d''acclimatation

Soluble proteins, esterases 2C, acid phosphatases of the digestive gland and foot muscle of Cyclonassa neritea, were compared using polyacrylamide gradient gels. α-Glucosidases, alkaline phosphatases, l-leucine aminopeptidase and peptidase were studied from digestive gland extracts. Molecular weights of isoenzymes were evaluated with 5000 d accuracy. Variation in activity of the most important isoenzymes of each enzyme under the influence of acclimation temperature was measured. In both muscle and digestive gland, the concentration of soluble proteins is stable. Through the whole acclimation temperature range, esterase activity per mg protein decreased with increased temperature. l-Leucine aminopeptidase activity decreases steadily from 10 to 25°, even though the two alkaline phosphatase isoenzyme activities increase. The other enzymes have their maximum activities at 20°.     

Localization and characterization of soluble and plasma membrane aminopeptidase activities in Arabidopsis seedlings

We previously demonstrated that N,1-naphthylphthalamic acid is hydrolyzed at the root-hypocotyl transition zone and other regions of Arabidopsis thaliana seedlings, and that this reaction, like NPA-induced growth inhibition, is strongly promoted by blue light. In addition, NPA amidase activity was detected in plasma membrane-enriched fractions obtained from Arabidopsis seedlings. To further investigate this phenomenon, we tested the hypothesis that the arylamidase(s) responsible for NPA hydrolysis may also have aminopeptidase activity. The responses of Arabidopsis seedlings to various aminopeptidase substrates were tested. The hydrolysis of Tyr-, Trp-, Pro- and Gly-Pro-β-naphthylamide aminopeptidase substrates was shown to be histochemically localized at the root-hypocotyl transition zone and other regions where NPA hydrolysis also occurs. Blue light stimulated the in vivo activity of Tyr- and Pro-aminopeptidase activities, and far-red light stimulated the activity of the Trp-aminopeptidase. These same substrates also induced NPA-like growth inhibitory effects. In parallel experiments, aminopeptidase activities were detected in the supernatant and plasma membrane fractions of seedling extracts. The soluble AP activities resemble previously described neutral aminopeptidases with specificity for aromatic residues. The plasma membrane fraction hydrolyzed Tyr-, Trp-, Ala-Pro- and Pro-AP substrates, and also exhibited activity against Phe- and Leu-substrates. Many of the properties of the aminopeptidases, such as pH optima, metal requirements and responses to inhibitors, overlap with those of the previously characterized NPA amidase, suggesting that the latter may represent the combined activities of multiple aminopeptidases.     

Radiation inactivation analysis of kidney microvillar peptidases

Five membrane peptidases were studied by radiation inactivation analysis of pig kidney microvillar membranes. One heterodimeric enzyme, gamma-glutamyl transferase, presented a target size corresponding to the dimeric Mr. The other enzymes are known to be homodimers. Three of these, aminopeptidase A. aminopeptidase N and dipeptidyl peptidase IV, gave results clearly indicating the monomer to be the target and, hence, in this group the association of the subunits was not essential for activity. The target size for endopeptidase-24.11 was intermediate between those for monomer and dimer and its functional state was not resolved by the experiments.     

Histochemistry of some proteases in the normal rabbit, pig and ox corneas

The distribution of activities of membrane aminopeptidases (aminopeptidase M (APM), aminopeptidase A (APA), dipeptidyl peptidase IV (DPP IV), gamma-glutamyltransferase (GGT) and lysosomal exopeptidases (dipeptidyl peptidase I (DPP I), dipeptidyl peptidase II (DPP II)) was investigated in rabbit, ox and pig corneas. Cryostat sections of snap-frozen corneas treated with chloroform-acetone (4 degrees C) were used for the demonstration of membrane-bound enzymes and sections of corneas fixed in 4% paraformaldehyde (4 degrees C) for the demonstration of lysosomal enzymes. In activities of proteases species differences were found. The rabbit cornea was most active, followed by ox and pig corneas. Individual corneal layers reacted differently. Of membrane proteases a high APM activity was found in keratocytes, whereas epithelium and endothelium were negative. On the other hand, APA and GGT were active in the epithelium and endothelium. Their activities in keratocytes were less pronounced. DPP IV activity was demonstrated in some keratocytes beneath the epithelium only. Lysosomal enzymes DPP I and DPP II were active in all corneal layers. The epithelium displayed the highest activity. Differences in activities in the centro-peripheral and epithelio-endothelial directions were found. DPP I, DPP II, and APM were most active in the limbal region in all corneal layers.     

Subcellular localization and levels of aminopeptidases and dipeptidase in Saccharomyces cerevisiae.

Three aminopeptidases (L-aminoacyl L-peptide hydrolases, EC 3.4.11) and a single dipeptidase (L-aminoacyl L-amino acid hydrolase, EC 3.4.13) are present in homogenates of Saccharomyces cerevisiae. Bassed on differences in substrate specificity and the sensitivity to Zn2+ activation, methods were developed that allow the selective assay of these enzymes in crude cell extracts. Experiments with isolated vacuoles showed that aminopeptidase I is the only yeast peptidase located in the vacuolar compartment. Aminopeptidase II (the other major aminopeptidase of yeast) seems to be an external enzyme, located mainly outside the plasmalemma. The synthesis of aminopeptidase I is repressed in media containing more than 1% glucose. In the presence of ammonia as the sole nitrogen source its activity is enhanced 3--10-fold when compared to that in cells grown on peptone. In contrast, the levels of aminopeptidase II and dipeptidase are less markedly dependent on growth medium composition. It is concluded that aminopeptidase II facilitates amino acid uptake by degrading peptides extracellularly, whereas aminopeptidase I is involved in intracellular protein degradation.