Opposite and selective effects of epidermal growth factor and human platelet transforming growth factor-beta on the production of secreted proteins by murine 3T3 cells and human fibroblasts

Growth regulators such as epidermal growth factor (EGF) and type beta transforming growth factor (TGF-beta) regulate the synthesis and secretion of certain proteins by cells in culture. The secretion pattern of each cell line and the effect of growth regulators on the secretion pattern are unique. EGF increased the secreted and intracellular levels of mitogen-regulated protein (MRP) and major excreted protein (MEP) by Swiss 3T3 cells. MRP is related by sequence to prolactin. MEP is a thiol protease located intracellularly in the lysosomes. EGF also selectively induced a 52,000-dalton mitogen-induced protein (MIP 52) secreted by human fibroblasts. Two types of TGF-betas were tested for their effects on the expression of secreted proteins in mouse and human fibroblasts: TGF-beta from human platelets and a growth inhibitor (GI/TGF-beta) secreted by BSC-1 cells. Each selectively decreased the levels of the two secreted proteins induced by growth factors in mouse embryo 3T3 cells and one secreted protein induced by growth factors in human fibroblasts. Platelet TGF-beta and GI/TGF-beta also induced one 48,000-dalton protein secreted by human fibroblasts. Synthesis of DNA and the incorporation of [35S]methionine into total protein in Swiss 3T3 cells were not affected by platelet TGF-beta or GI/TGF-beta. Thus, the inhibitory effect of platelet TGF-beta on the synthesis and secretion of these three proteins is due to a specific effect of platelet TGF-beta on the regulation of MRP and MEP that does not interfere with the ability of EGF to stimulate DNA or protein synthesis.     

Use of a cloned multidrug resistance gene for coamplification and overproduction of major excreted protein, a transformation-regulated secreted acid protease.

Malignantly transformed mouse fibroblasts synthesize and secrete large amounts of major excreted protein (MEP), a 39,000-dalton precursor to an acid protease (cathepsin L). To evaluate the possible role of this protease in the transformed phenotype, we transfected cloned genes for mouse or human MEP into mouse NIH 3T3 cells with an expression vector for the dominant, selectable human multidrug resistance (MDR1) gene. The cotransfected MEP sequences were efficiently coamplified and transcribed during stepwise selection for multidrug resistance in colchicine. The transfected NIH 3T3 cell lines containing amplified MEP sequences synthesized as much MEP as did Kirsten sarcoma virus-transformed NIH 3T3 cells. The MEP synthesized by cells transfected with the cloned mouse and human MEP genes was also secreted. Elevated synthesis and secretion of MEP by NIH 3T3 cells did not change the nontransformed phenotype of these cells.     

Protein cleavage in virus-infected cells

A variety of proteins, including viral precursor polypeptides, were bound to a solid support and used in a sensitive assay for proteolytic enzymes in HeLa cells. A trypsin-like endoprotease, present on ribosomes of HeLa cells, loses activity after picornavirus infection. The decline follows synthesis and processing of a viral protein. Inhibition of cellfree activity of HeLa protease occurs when protein trypsin inhibitors or double-stranded RNA are added. After the mid-point of infection, protease activity with enhanced specificity for viral substrates is detected. The new protease has a pH optimum and heat stability different from endogenous host enzymes, and is synthesized following infection. A viral mutant was isolated which produces a temperature-sensitive protease. The results indicate that a poliovirus gene product participates enzymatically in the final cleavages of some polioviral proteins. A model for the regulation of poliovirus replication based on specific proteolysis is presented.     

Modulation of the transport of a lysosomal enzyme by PDGF

The major excreted protein (MEP) of transformed mouse fibroblasts is the lysosomal protease, cathepsin L. MEP is also secreted by untransformed mouse cells in response to growth factors and tumor promoters, and is thought to play a role in cell growth and transformation. To determine the relationship between MEP synthesis and MEP secretion, we have examined these events in PDGF-treated NIH 3T3 cells. PDGF enhanced MEP synthesis and caused the diversion of MEP from the lysosomal delivery pathway to a secretory pathway. These two effects were found to be regulated independently at various times after growth factor addition. Short PDGF treatments (0.5 or 1 h) resulted in quantitative secretion of MEP although synthesis was near the control level. High levels of both synthesis and secretion occurred between 2 and 14 h of PDGF treatment. Between 18 and 30 h, the amount of secreted MEP returned to the low control level even though synthesis remained elevated. The secretion was specific for MEP; other lysosomal enzymes were not found in the media from PDGF-treated cells. PDGF-induced secretion of MEP was inhibited 84% by cycloheximide, suggesting that protein synthesis is required to elicit this effect. PDGF also caused a time-dependent increase in mannose 6-phosphate (Man-6-P) receptor-mediated endocytosis. These data support a model in which PDGF alters the distribution of Man-6-P receptors such that the Golgi concentration of receptors becomes limiting, thereby causing the selective secretion of the low affinity ligand, MEP.     

Basis for low affinity binding of a lysosomal cysteine protease to the cation-independent mannose 6-phosphate receptor

In cultured mouse fibroblasts, secretion of the lysosomal cysteine protease, MEP (major excreted protein) is regulated by growth factors and viral transformation. The ability of this protein to be regulated has been attributed to its intrinsic low affinity for the cation-independent mannose 6-phosphate (Man-6-P) receptor (Dong, J., Prence, E. M., and Sahagian, G. G. (1989) J. Biol. Chem. 264, 7377-7383). In this study, the basis for this low affinity was examined. Chromatography on a cation-independent Man-6-P receptor affinity matrix was used to assess relative affinities of Man-6-P-containing oligosaccharides and proteins, and the state of phosphorylation of the oligosaccharides was determined by ion exchange chromatography on QAE-Sephadex. MEP proteins synthesized by normal NIH 3T3 cells or NIH cells transformed with Kirsten sarcoma virus displayed a similar low affinity for the receptor and were found to possess oligosaccharide species with two phosphomonoester moieties. The affinity of these oligosaccharides for the receptor was the same as intact MEP protein and as great as phosphorylated oligosaccharides obtained from lysosomal proteins with the usual high affinity for the receptor. These results indicate that the polypeptide portion of MEP has no effect on binding of the protein to the receptor and that the difference in affinity of MEP and lysosomal proteins with high affinity cannot be attributed to differences in oligosaccharide structure. To investigate this further, we examined the binding characteristics of MEP made by CHO cells. In contrast to mouse MEP, CHO MEP bound to the receptor with high affinity. Partial endoglycosidase H treatment indicated that CHO MEP has two phosphorylated oligosaccharides, whereas the mouse protein has only one. Both oligosaccharides of the CHO cell protein contained two phosphomonoester moieties and displayed an affinity for the receptor that was indistinguishable from that of oligosaccharides of the mouse protein. Conversion of CHO MEP to a one-oligosaccharide species by partial endoglycosidase H treatment produced a protein that displayed low affinity binding similar to that of mouse MEP. A substantial portion of the pool of CHO cell lysosomal protein was also converted to a low affinity ligand by this treatment. Taken together, these results suggest that high affinity binding to the cation-independent receptor involves a divalent interaction with lysosomal proteins that contain two or more phosphorylated oligosaccharides, and that the low affinity of MEP results from an inability to form this multivalent interaction.     

Processing and lysosomal localization of a glycoprotein whose secretion is transformation stimulated

The major excreted protein (MEP) of transformed mouse fibroblasts is a mannose 6-phosphate-containing glycoprotein whose synthesis and secretion are increased in malignantly transformed 3T3 cells and whose synthesis is increased by treatment of 3T3 cells with tumor promoters or growth factors. When pulse-labeled extracts from Kirsten virus-transformed NIH 3T3 (KNIH) cells were immunoprecipitated using an antibody against secreted MEP, one cellular protein was immunoprecipitated that had the same molecular weight and tryptic peptide map as the secreted protein. Pulse-chase labeling experiments showed that 50-60% of this 39,000-mol-wt form was secreted in transformed cells. Of the 40-50% remaining, approximately 5% was processed into two lower molecular weight forms (29,000 and 20,000) which are sequestered within the cell. Similar processing of these proteins was observed in the nontransformed parent NIH 3T3 (NIH) cells. However, in NIH cells, much less of the synthesized MEP was secreted. Measurements of steady-state levels of these three forms of cellular MEP by Western blot immunolocalization revealed approximately fourfold more MEP in KNIH cells than in NIH cells as well as differences in the relative distribution of MEP forms in transformed and nontransformed cells. Subcellular fractionation of KNIH cells on a Percoll gradient demonstrated a distribution of total MEP similar to that of several lysosomal enzymes. The light lysosomal/Golgi peak from these gradients contained both the precursor 39,000-mol-wt form of MEP and the 20,000-mol-wt form, whereas the heavy lysosomal peak was enriched in the 20,000-mol-wt form. The distribution of MEP forms was found to be similar in NIH cells except that the 29,000-mol-wt form was also seen to be enriched in the heavy lysosomal peak. This biochemical localization of MEP was confirmed by immunolocalization with light and electron microscopy. These data support the hypothesis that MEP is a lysosomal protein that is secreted by transformed cells.     

Genetic or chemical protease inhibition causes significant changes in the Bacillus subtilis exoproteome

Bacillus subtilis is a prolific producer of enzymes and biopharmaceuticals. However, the susceptibility of heterologous proteins to degradation by (extracellular) proteases is a major limitation for use of B. subtilis as a protein cell factory. An increase in protein production levels has previously been achieved by using either protease-deficient strains or addition of protease inhibitors to B. subtilis cultures. Notably, the effects of genetic and chemical inhibition of proteases have thus far not been compared in a systematic way. In the present studies, we therefore compared the exoproteomes of cells in which extracellular proteases were genetically or chemically inactivated. The results show substantial differences in the relative abundance of various extracellular proteins. Furthermore, a comparison of the effects of genetic and/or chemical protease inhibition on the stress response triggered by (over) production of secreted proteins showed that chemical protease inhibition provoked a genuine secretion stress response. From a physiological point of view, this suggests that the deletion of protease genes is a better way to prevent product degradation than the use of protease inhibitors. Importantly however, studies with human interleukin-3 show that chemical protease inhibition can result in improved production of protease-sensitive secreted proteins even in mutant strains lacking eight extracellular proteases.     

Sequence and expression of the cDNA for MEP (major excreted protein), a transformation-regulated secreted cathepsin.

The major excreted protein (MEP) of malignantly transformed mouse fibroblasts is a secreted thiol proteinase. Sequencing of the MEP cDNA shows the coding region for the protein to be identical with the sequence for a mouse cysteine proteinase isolated from macrophages, but the MEP cDNA is polyadenylated at a different site in the 3' non-coding region. Strong homology of MEP with human cathepsin L suggests that MEP is the mouse analogue of cathepsin L. Amino acid sequencing of the N-terminus of the secreted form of MEP indicates that, during secretion, the polypeptide is cleaved between amino acids 17 and 18. We have placed the MEP cDNA in a eukaryotic expression vector and demonstrated the production of the 39 kDa polypeptide form of mouse MEP in monkey CV-1 cells.     

Prostasin is a glycosylphosphatidylinositol-anchored active serine protease

A recombinant human prostasin serine protease was expressed in several human cell lines. Subcellular fractionation showed that this serine protease is synthesized as a membrane-bound protein while a free-form prostasin is secreted into the culture medium. Prostasin was identified in nuclear and membrane fractions. Membrane-bound prostasin can be released by phosphatidylinositol-specific phospholipase C treatment, or labeled by [(3)H]ethanolamine, indicating a glycosylphosphatidylinositol anchorage. A prostasin-binding protein was identified in mouse and human seminal vesicle fluid. Both the secreted and the membrane-bound prostasin were able to form a covalently linked 82-kDa complex when incubated with seminal vesicle fluid. The complex formation between prostasin and the prostasin-binding protein was inhibited by a prostasin antibody, heparin, and serine protease inhibitors. Prostasin's serine protease activity was inhibited when bound to the prostasin-binding protein in mouse seminal vesicle fluid. This study indicates that prostasin is an active serine protease in its membrane-bound form.     

Characterization and Regulation of Protease Synthesis and Activity in Bacillus licheniformis

Extracts of growing and sporulating cells contain a protease activity that has a broad pH optimum and an unusually broad specificity. The activity, which resides in at least two protein fractions, hydrolyzes all peptide bonds and can reduce a mixture of proteins into a mixture of free amino acids with a high efficiency. No inhibitors of the activity were found, but the protease showed a definite preference for denatured protein as substrate. The synthesis of the intracellular protease activity is under catabolite repression control, as is the extracellular activity. However, the synthesis of the two activities is not coordinate, making the relationship between the two unclear. Due to (i) the specificity of the intracellular activity, (ii) the fact that it is synthesized most rapidly under slow or nongrowing conditions, and (iii) our inability to measure in vivo protein turnover in cells containing high levels of enzyme, a scavenger role is postulated for the enzyme. The rate of protein turnover is not a function of the protease content of the cells.     

Relation between the regulation of DNA synthesis and the production of two secreted glycoproteins by 12-O-tetradecanoylphorbol-13-acetate in 3T3 cells and in phorbol ester nonresponsive 3T3 variants

12-O-tetradecanoylphorbol-13-acetate (TPA), a potent tumor promoter, acts similarly to growth factors by selectively increasing the rate of production of the secreted proteins, mitogen regulated protein (MRP) and major excreted protein (MEP) by murine 3T3 cells. MRP, a 34 kilodalton (kDa) glycoprotein, is a member of the prolactin-growth hormone family of proteins. MEP, a 39 kDa glycoprotein, is a lysosomal thiol protease that is also secreted. The aim of our investigation was to determine the relation between increases in MRP and MEP production and the initiation of DNA synthesis in response to mitogens. The TNR-9 cell line is a variant of 3T3 cells in which growth factors, but not TPA and teleocidin, stimulate DNA synthesis and cell division. Using [35S]methionine to metabolically label proteins and SDS polyacrylamide gel electrophoresis to resolve the proteins, we found that growing cultures of 3T3 and TNR-9 cells responded equally well to TPA and teleocidin with increased rates of production of MRP and MEP. By contrast, the responses of quiescent TNR-9 cells to these tumor promoters in the increased production of MRP and MEP was greatly diminished compared with quiescent 3T3 cells. The changes in production of MRP in response to tumor promoters in quiescent and growing cells paralleled similar changes in the level of MRP mRNA. In summary, the ability to TPA and teleocidin to increase the rate of production of MRP and MEP correlated with the ability of these tumor promoters to stimulate DNA synthesis in quiescent 3T3 and TNR-9 cells. Evidently the biochemical condition that distinguishes TNR-9 from 3T3 cells and that limits the ability of tumor promoters to stimulate the production of MEP and MRP, and perhaps also DNA synthesis in TNR-9 cells occurs only when the cells are quiescent.     

Purification and characterization of a 33 kDa serine protease from Acanthamoeba lugdunensis KA/E2 isolated from a Korean keratitis patient

In order to evaluate the possible roles of secretory proteases in the pathogenesis of amoebic keratitis, we purified and characterized a serine protease secreted by Acanthamoeba lugdunensis KA/E2, isolated from a Korean keratitis patient. The ammonium sulfate-precipitated culture supernatant of the isolate was purified by sequential chromatography on CM-Sepharose, Sephacryl S-200, and mono Q-anion exchange column. The purified 33 kDa protease had a pH optimum of 8.5 and a temperature optimum of 55 degrees C. Phenylmethylsulfonylfluoride and 4-(2- Aminoethyl)-benzenesulfonyl-fluoride, both serine protease specific inhibitors, inhibited almost completely the activity of the 33 kDa protease whereas other classes of inhibitors did not affect its activity. The 33 kDa enzyme degraded various extracellular matrix proteins and serum proteins. Our results strongly suggest that the 33 kDa serine protease secreted from this keratopathogenic Acanthamoeba play important roles in the pathogenesis of amoebic keratitis, such as in corneal tissue invasion, immune evasion and nutrient uptake.     

Protease activity associated with HeLa cell ribosomes

HeLa cells contain endoprotease activity, detected by a sensitive, solid phase assay. The endoprotease has the ability to cleave a variety of protein substrates and is trypsin-like in its sensitivity to inhibitors. The activity is in part associated with cellular ribosomes and polysomes. A variety of biological and physical-chemical treatments which alter ribosomes or protein synthesis also directly affect the ribosomal protease activity.     

Mechanism for selective secretion of a lysosomal protease by transformed mouse fibroblasts

Studies in recent years have indicated that secretion of certain lysosomal hydrolases can be enhanced under various conditions. One such protein, the major excreted protein (MEP) of Kirsten virus-transformed NIH 3T3 (KNIH) fibroblasts, is a lysosomal cysteine protease whose synthesis and secretion are affected by viral transformation and growth factors. We have been studying the synthesis and transport of MEP in order to understand better the mechanisms responsible for regulation of lysosomal enzyme secretion. Synthesis of MEP in KNIH cells was found to be 25-fold greater than that in untransformed NIH cells, and 94% of the MEP made was secreted. This was in contrast to NIH cells which secreted only 11% of the newly synthesized MEP. The high level of secretion by the transformed cells was relatively specific in that most other lysosomal enzymes were retained. MEP isolated from both NIH and KNIH cells exhibited a low intrinsic affinity for the mannose-6-phosphate receptor which was at least 10-fold lower than that of other lysosomal enzymes. On the basis of these results, we suggest that both the high level of MEP synthesis and the intrinsic low affinity of MEP for the receptor are responsible for the specific increase in MEP secretion by transformed cells.     

The 52-kDa estrogen-induced protein secreted by MCF7 cells is a lysosomal acidic protease

An estrogen-induced 52-kDa glycoprotein secreted by human breast cancer cells and able to autostimulate the growth of MCF7 cells has been purified, using monoclonal antibodies, and characterized. The protein contains mannose 6-phosphate signals on its N-linked high-mannose chains, suggesting that it is a lysosomal enzyme. Both the secreted 52-kDa protein and its processed cellular forms (52-, 48- and 34-kDa) were identified as carboxyl proteinases having an optimal activity at pH 3.5 and being specifically inhibited by pepstatin. This protease is characterized by its inducibility by estrogens and its high concentration in proliferative benign and malignant mammary tissue, when detected by immunohistochemistry. The estrogen-induced secretion of this protease may help to understand how estrogens stimulate mammary tumor growth and/or invasion.     

Purification and characterization of a vimentin-specific protease in mouse myeloid leukemia cells. Regulation during differentiation and identity with cathepsin G.

Strong vimentin-degrading activity was found in a mouse myelomonocytic leukemic cell line, M1. When M1 cells were induced to differentiate into macrophage-like cells, this degrading activity decreased, while expression of the vimentin gene increased as reported previously [Tsuru, A., Nakamura, N., Takayama, E., Suzuki, Y., Hirayoshi, K. and Nagata, K. (1990) J. Cell Biol. 110, 1655-1664]. This activity was not due to calpain, which was reported to degrade vimentin, because it was independent of the presence or absence of Ca2+. This activity was revealed to be strongly associated with membranes by differential-centrifugation experiments. To identify this protease, purification of the degradation enzyme was performed. A membrane fraction was prepared and extracted with a buffer containing Triton X-100, then subjected to column chromatography using carboxymethyl-Sepharose and heparin-Sepharose. Quantitative analysis using the purified protease revealed that the specificity of this protease was more than 1000-fold higher for vimentin than for bovine serum albumin, ovalbumin and actin. Four protein bands expressing the activity were finally identified by SDS/PAGE. Amino-terminal sequences of these four proteins were identical, suggesting lower-molecular-mass proteins were degradative products. Furthermore, it was revealed that the sequence had the highest similarity with that of human cathepsin G. This result was consistent with the cathpsin-G-like properties of the purified protease, such as the optimum pH and the specificities for inhibitors. The purified protease degraded a synthetic substrate for cathespin G, succinyl-alanyl-alanyl-prolyl-phenylalanyl-p-nitroanilide, with a comparable specific activity to human cathespin G and was specifically detected with anti-(human cathepsin G) serum in immunoblot analysis. The purified protease thus belongs to the 'cathepsin G family', and perhaps is a mouse homologue of human cathepsin G.     

Identification, gene cloning and expression of serine proteases in the extracellular medium of Nicotiana tabacum cells

Recombinant proteins secreted from plant suspension cells into the medium are susceptible to degradation by host proteases secreted during growth. Some degradation phenomena are inhibited in the presence of various protease inhibitors, such as EDTA or AEBSF/PMSF, suggesting the presence of different classes of proteases in the medium. Here, we report the results of a proteomic analysis of the extracellular medium of a Nicotiana tabacum bright yellow 2 culture. Several serine proteases belonging to a Solanaceae-specific subtilase subfamily were identified and the genes for four cloned. Their expression at the RNA level during culture growth varied depending on the gene. An in-gel protease assay (zymography) demonstrated serine protease activity in the extracellular medium from cultures. This was confirmed by testing the degradation of an antibody added to the culture medium. This particular subtilase subfamily, therefore, represents an interesting target for gene silencing to improve recombinant protein production. Key message The extracellular medium of Nicotiana tabacum suspension cells contains serine proteases that degrade antibodies.     

Identification of protease IV of E.coli: An outer membrane bound enzyme

The proteolytic activity of $\text{E.coli}$ measured using ¹²⁵I-labelled αS1 casein as substrate, is mainly localised in the outer membrane and is due to an intrinsic outer membrane protein which can be solubilized by deoxycholate. This enzyme exhibits maximum activity at pH 7,5 in Tris-HCl buffer, is resistant to thermal denaturation with a half-life of 28 min. at 90°C in deoxycholate-NaCl buffer and is inhibited by ethylene-diamine tetraacetate, high concentrations of p-aminobenzamidine, tosyl-L-lysine chloromethyl ketone, tosyl-L-phenylalaninechloromethyl ketone and by two inhibitors of the processing of the secreted protein precursors, procaine and phenehylalcohol. Whole cells do not exhibit proteolytic activity, nevertheless, some is unmasked when the outer membrane is permeabilized by Tris or ethylenediamine tetraacetate or when vesicles are sonicated. This suggests that the protease is on the inner side of the outer membrane. Because the protease is different from the soluble proteases described in $\text{E.coli}$, and especially from proteases I,II and III, it has been called protease IV.     

A novel ATP-requiring protease from skeletal muscle that hydrolyzes non-ubiquitinated proteins

Previously, we isolated an ATP-dependent proteolytic pathway in muscle, liver, and reticulocytes that requires ubiquitin and the enzymes which conjugate ubiquitin to proteins. We report here that skeletal muscle contains another soluble alkaline energy-dependent (but ubiquitin-independent) proteolytic activity. The cleavage of non-ubiquitinated protein substrates by the partially purified protease requires ATP hydrolysis since ATP in the absence of Mg2+, nonhydrolyzable ATP analogs, and pyrophosphate all fail to stimulate proteolysis. Proteolytic activity is also stimulated by UTP, CTP, and GTP, although not as effectively as by ATP (Km(ATP) = 0.027 mM). The enzyme is inactivated by the serine protease inhibitors diisopropyl fluorophosphate and 3,4-dichloroisocoumarin, but not by specific inhibitors of aspartic, thiol, or metalloproteases. It is maximally active at pH 8 and has a molecular weight of approximately 600,000. This new activity differs from the 720-kDa multicatalytic proteinase, but resembles the soluble ATP-dependent proteolytic system that we previously isolated from murine erythroleukemia cells.