An alternate targeting pathway for procathepsin L in mouse fibroblasts

In transformed mouse fibroblasts, a significant proportion of the lysosomal cysteine protease cathepsin L remains in cells as an inactive precursor which associates with membranes by a mannose phosphate-independent interaction. When microsomes prepared from these cells were resolved on sucrose gradients, this procathepsin L was localized in dense vesicles distinct from those enriched for growth hormone, which is secreted constitutively when expressed in fibroblasts. Ultrastructural studies using antibodies directed against the propeptide to avoid detection of the mature enzyme in lysosomes revealed that the proenzyme was concentrated in dense cores within small vesicles and multivesicular endosomes which labeled with antibodies specific for CD63. Consistent with the resemblance of these cores to those of regulated secretory granules, secretion of procathepsin L from fibroblasts was modestly stimulated by phorbol, 12-myristate, 13-acetate. When protein synthesis was blocked with cycloheximide and lysosomal proteolysis inhibited with leupeptin, procathepsin L was found to gradually convert to the active single-chain protease. The data suggest that when synthesis levels are high, a portion of the procathepsin L is packaged in dense cores within multivesicular endosomes localized near the plasma membrane. Gradual activation of this proenzyme achieves targeting of the proenzyme to lysosomes by a mannose phosphate receptor-independent pathway.     

Group X secreted phospholipase A2 proenzyme is matured by a furin-like proprotein convertase and releases arachidonic acid inside of human HEK293 cells

Among mammalian secreted phospholipases A(2) (sPLA(2)s), group X sPLA(2) has the most potent hydrolyzing activity toward phosphatidylcholine and is involved in arachidonic acid (AA) release. Group X sPLA(2) is produced as a proenzyme and contains a short propeptide of 11 amino acids ending with a dibasic motif, suggesting cleavage by proprotein convertases. Although the removal of this propeptide is clearly required for enzymatic activity, the cellular location and the protease(s) involved in proenzyme conversion are unknown. Here we have analyzed the maturation of group X sPLA(2) in HEK293 cells, which have been extensively used to analyze sPLA(2)-induced AA release. Using recombinant mouse (PromGX) and human (ProhGX) proenzymes; HEK293 cells transfected with cDNAs coding for full-length ProhGX, PromGX, and propeptide mutants; and various permeable and non-permeable sPLA(2) inhibitors and protease inhibitors, we demonstrate that group X sPLA(2) is mainly converted intracellularly and releases AA before externalization from the cell. Most strikingly, the exogenous proenzyme does not elicit AA release, whereas the transfected proenzyme does elicit AA release in a way insensitive to non-permeable sPLA(2) inhibitors. In transfected cells, a permeable proprotein convertase inhibitor, but not a non-permeable one, prevents group X sPLA(2) maturation and partially blocks AA release. Mutations at the dibasic motif of the propeptide indicate that the last basic residue is required and sufficient for efficient maturation and AA release. All together, these results argue for the intracellular maturation of group X proenzyme in HEK293 cells by a furin-like proprotein convertase, leading to intracellular release of AA during secretion.     

Procathepsin L self-association as a mechanism for selective secretion

The lysosomal cysteine pro-protease procathepsin L was enriched in dense vesicles detectable when microsomes prepared from wild-type or transformed mouse fibroblasts were resolved on sucrose gradients. These dense vesicles did not comigrate with proteins characteristic of the endoplasmic reticulum, Golgi, endosomes or lysosomes. When gradient fraction vesicles were lysed at acidic pH in the presence of excess mannose 6-phosphate to prevent binding to mannose phosphate receptors, the majority of the procathepsin L was associated with the membrane, not the soluble, fraction. Immunogold labeling of procathepsin L in thin sections of cells or gradient fractions, using antibodies directed against the propeptide to avoid detection of the mature enzyme in dense lysosomes, revealed that the proenzyme was concentrated in dense cores localized in small vesicles near the plasma membrane and in multivesicular bodies. Consistent with the density of the gradient fraction and the electron density of the cores, yeast two-hybrid assays indicated the proenzyme could bind itself but could not interact with the aspartic proprotease procathepsin D. The data suggest that in mouse fibroblasts procathepsin L may self-associate into aggregates, initiating the formation of dense vesicles that could mediate the selective secretion of procathepsin L independent of mannose phosphate receptors.     

Involvement of the carboxyl-terminal propeptide of beta-glucuronidase in its compartmentalization within the endoplasmic reticulum as determined by a synthetic peptide approach

The proenzyme form of beta-glucuronidase is compartmentalized in large quantities within the endoplasmic reticulum by binding to the esterase, egasyn. Also, the propeptide of the proenzyme form of beta-glucuronidase is likely located at the carboxyl terminus. We have, therefore, tested if this carboxyl-terminal peptide is important in binding to egasyn. A polyclonal antibody to a 30-mer synthetic peptide, corresponding to the carboxyl-terminal 30 amino acids of pro-beta-glucuronidase, provided evidence that egasyn binds to the carboxyl terminus of beta-glucuronidase. This antibody interacted with proenzyme beta-glucuronidase-egasyn complexes in which one, two, or three egasyn molecules were bound to the beta-glucuronidase tetramer, but not with those complexes (M4) which contained four egasyn molecules. We interpret these results as indicating that all available carboxyl termini of the beta-glucuronidase proenzyme tetramer are shielded by egasyn in the M4 complexes. The same antibody did not recognize the mature lysosomal form of beta-glucuronidase, indicating that only the proenzyme form of microsomal beta-glucuronidase contains the original carboxyl terminus. Also, the synthetic 30-mer was found to be a specific and potent inhibitor (50% inhibition at 1.3 microM) of the esterase activity of purified egasyn but exhibited little inhibitory activity toward other purified esterases including a rat trifluoroacetylated esterase or egasyn esterase from another species. Together, these data describe a potent interaction of the exposed carboxyl terminus of precursor glucuronidase with the esterase catalytic site of egasyn, which in turn results in the specific localization of glucuronidase within the lumen of the endoplasmic reticulum.     

Purification and primary structure determination of human lysosomal dipeptidase

The lysosomal metallopeptidase is an enzyme that acts preferentially on dipeptides with unsubstituted N- and C-termini. Its activity is highest in slightly acidic pH. Here we describe the isolation and characterization of lysosomal dipeptidase from human kidney. The isolated enzyme has the amino-terminal sequence DVAKAIINLAVY and is a homodimer with a molecular mass of 100 kDa. So far no amino acid sequence has been determined for this metallopeptidase. The complete primary structure as deduced from the nucleotide sequence revealed that the isolated dipeptidase is similar to blood plasma glutamate carboxypeptidase.     

Green fluorescent protein as an indicator to monitor membrane protein overexpression in Escherichia coli.

Escherichia coli is one of the most widely used vehicles to overexpress membrane proteins (MPs). Currently, it is not possible to predict if an overexpressed MP will end up in the cytoplasmic membrane or in inclusion bodies. Overexpression of MPs in the cytoplasmic membrane is strongly favoured to overexpression in inclusion bodies, since it is relatively easy to isolate MPs from membranes and usually impossible to isolate them from inclusion bodies. Here we show that green fluorescent protein (GFP), when fused to an overexpressed MP, can be used as an indicator to monitor membrane insertion versus inclusion body formation of overexpressed MPs in E. coli. Furthermore, we show that an overexpressed MP can be recovered from a MP-GFP fusion using a site specific protease. This makes GFP an excellent tool for large-scale MP target selection in structural genomics projects.     

Structure of human prostasin, a target for the regulation of hypertension

Prostasin (also called channel activating protease-1 (CAP1)) is an extracellular serine protease implicated in the modulation of fluid and electrolyte regulation via proteolysis of the epithelial sodium channel. Several disease states, particularly hypertension, can be affected by modulation of epithelial sodium channel activity. Thus, understanding the biochemical function of prostasin and developing specific agents to inhibit its activity could have a significant impact on a widespread disease. We report the expression of the prostasin proenzyme in Escherichia coli as insoluble inclusion bodies, refolding and activating via proteolytic removal of the N-terminal propeptide. The refolded and activated enzyme was shown to be pure and monomeric, with kinetic characteristics very similar to prostasin expressed from eukaryotic systems. Active prostasin was crystallized, and the structure was determined to 1.45 A resolution. These apoprotein crystals were soaked with nafamostat, allowing the structure of the inhibited acyl-enzyme intermediate structure to be determined to 2.0 A resolution. Comparison of the inhibited and apoprotein forms of prostasin suggest a mechanism of regulation through stabilization of a loop which interferes with substrate recognition.     

Distribution of dipeptidase activity between lysosomes and soluble fraction of rat liver.

Dipeptidase activity toward Arg-Phe, Arg-Gly, and Trp-Leu exhibited bimodal distribution in the lysosomal and soluble fractions of rat liver. The majority (50-70 percent) of the dipeptidase activity was present in the soluble fraction. Some evidence for a plasma membrane dipeptidase, which hydrolyzes Trp-Leu but not Arg-Phe or Arg-Gly, also was found. The lysosomal dipeptidase activity had a pH optimum of 6.0-7.0, and was activated by sulfhydryl reagents. Lysosomal localization for some of the dipeptidase activity was established with Triton WR-1339 fractionation and latency experiments.     

Large-scale expression, refolding, and purification of the catalytic domain of human macrophage metalloelastase (MMP-12) in Escherichia coli

We have cloned, overexpressed, and purified the catalytic domain (residues Gly106 to Asn268) of human macrophage metalloelastase (MMP-12) in Escherichia coli. This construct represents a truncated form of the enzyme, lacking the N-terminal propeptide domain and the C-terminal hemopexin-like domain. The overexpressed protein was localized exclusively to insoluble inclusion bodies, in which it was present as both an intact form and an N-terminally truncated form. Inclusion bodies were solubilized in an 8 M guanidine-HCl buffer and purified by gel filtration chromatography under denaturing conditions. Partial refolding of the protein by dialysis into a 3 M urea buffer caused selective degradation of the truncated form of the protein, while the intact catalytic domain was unaffected by proteolysis. An SP-Sepharose chromatography step purified the protein to homogeneity and served also to complete the refolding. The purified protein was homogeneous by mass spectrometry and had an activity similar to that of the recombinant enzyme purified from mammalian cells. The protein was both soluble and monodisperse at a concentration of 9 mg/ml. This purification procedure enables the production of 23 mg of protein per liter of E. coli culture and is amenable to large-scale protein production for structural studies.     

RGD-dependent binding of procathepsin X to integrin alphavbeta3 mediates cell-adhesive properties

Secreted lysosomal cysteine proteases (cathepsins) are involved in degradation and remodeling of the extracellular matrix, thus contributing to cell adhesion and migration. Among the eleven human lysosomal cysteine proteases, only procathepsin X contains an RGD motif located in a highly exposed region of the propeptide, which may allow binding of the proenzyme to RGD-recognizing integrins. Here, we have tested procathepsin X for cell-adhesive properties and found that it supports integrin alpha(v)beta(3)-dependent attachment and spreading of human umbilical vein endothelial cells. Using site-directed mutants of procathepsin X, we proved that this effect is mediated by the RGD sequence within the proregion of the protease. Endogenous procathepsin X is transported to the plasma membrane, accumulates in vesicles at lamellipodia of the human umbilical vein endothelial cell, and is partly associated with the cell surface, as shown by immunofluorescence. In addition, procathepsin X is partly co-localized with integrin beta(3), as detected by immunogold electron microscopy. A direct interaction between endogenous procathepsin X and alpha(v)beta(3) was demonstrated by co-immunoprecipitation. Moreover, surface plasmon resonance analysis revealed significant and RGD-dependent binding of procathepsin X to integrin alpha(v)beta(3). Our results provide for the first time evidence that the extracellular function of cathepsin X may include binding to integrins thereby modulating the attachment of migrating cells to ECM components.     

Structure-function relationships in class CA1 cysteine peptidase propeptides

Regulation of proteolytic enzyme activity is an essential requirement for cells and tissues because proteolysis at a wrong time and location may be lethal. Proteases are synthesized as inactive or less active precursor molecules in order to prevent such inappropriate proteolysis. They are activated by limited intra- or intermolecular proteolysis cleaving off an inhibitory peptide. These regulatory proenzyme regions have attracted much attention during the last decade, since it became obvious that they harbour much more information than just triggering activation. In this review we summarize the structural background of three functions of clan CA1 cysteine peptidase (papain family) proparts, namely the selectivity of their inhibitory potency, the participation in correct intracellular targeting and assistance in folding of the mature enzyme. Today, we know more than 500 cysteine peptidases of this family from the plant and animal kingdoms, e.g. papain and the lysosomal cathepsins L and B. As it will be shown, the propeptide functions are determined by certain structural motifs conserved over millions of years of evolution.     

Biosynthesis,glycosylation, and enzymatic processing in vivo of human tripeptidyl-peptidase I

Human tripeptidyl-peptidase I (TPP I, CLN2 protein) is a lysosomal serine protease that removes tripeptides from the free N termini of small polypeptides and also shows a minor endoprotease activity. Due to various naturally occurring mutations, an inherited deficiency of TPP I activity causes a fatal lysosomal storage disorder, classic late infantile neuronal ceroid lipofuscinosis (CLN2). In the present study, we analyzed biosynthesis, glycosylation, transport, and proteolytic processing of this enzyme in stably transfected Chinese hamster ovary cells as well as maturation of the endocytosed proenzyme in CLN2 lymphoblasts, fibroblasts, and N2a cells. Human TPP I was initially identified as a single precursor polypeptide of approximately 68 kDa, which, within a few hours, was converted to the mature enzyme of approximately 48 kDa. Compounds affecting the pH of intracellular acidic compartments, those interfering with the intracellular vesicular transport as well as inhibition of the fusion between late endosomes and lysosomes by temperature block or 3-methyladenine, hampered the conversion of TPP I proenzyme into the mature form, suggesting that this process takes place in lysosomal compartments. Digestion of immunoprecipitated TPP I proenzyme with both N-glycosidase F and endoglycosidase H as well as treatment of the cells with tunicamycin reduced the molecular mass of TPP I proenzyme by approximately 10 kDa, which indicates that all five potential N-glycosylation sites in TPP I are utilized. Mature TPP I was found to be partially resistant to endo H treatment; thus, some of its N-linked oligosaccharides are of the complex/hybrid type. Analysis of the effect of various classes of protease inhibitors and mutation of the active site Ser(475) on human TPP I maturation in cultured cells demonstrated that although TPP I zymogen is capable of autoactivation in vitro, a serine protease that is sensitive to AEBSF participates in processing of the proenzyme to the mature, active form in vivo.     

In vitro stepwise autoprocessing of the proform of pro-aminopeptidase processing protease from Aeromonas caviae T-64

PA protease (pro-aminopeptidase processing protease) is an extracellular zinc metalloprotease produced by the Gram-negative bacterium Aeromonas caviae T-64. The 590-amino-acid precursor of PA protease is composed of a putative 19-amino-acid signal sequence, a 165-amino-acid N-terminal propeptide, a 33 kDa mature protease domain and an 11 kDa C-terminal propeptide. The proform of PA protease, which was produced as inclusion bodies in Escherichia coli, was subjected to in vitro refolding. It was revealed that the processing of the proform involved a stepwise autoprocessing mechanism. Firstly, the N-terminal propeptide was autocatalytically removed on completion of refolding and secondly, the C-terminal propeptide was autoprocessed after the degradation of the N-terminal propeptide. Both the N- and C-terminal propeptides existed as intact peptides after their successive removal, and they were subsequently degraded gradually. The degradation of the N-terminal propeptide appears to be the rate-limiting step in the maturation of the proform of PA protease.     

Substrate binding of gelatinase B induces its enzymatic activity in the presence of intact propeptide

Expression of gelatinase B (matrix metalloprotease 9) in human placenta is developmentally regulated, presumably to fulfill a proteolytic function. Here we demonstrate that gelatinolytic activity in situ, in tissue sections of term placenta, is co-localized with gelatinase B. Judging by molecular mass, however, all the enzyme extracted from this tissue was found in a proform. To address this apparent incongruity, we examined the activity of gelatinase B bound to either gelatin- or type IV collagen-coated surfaces. Surprisingly, we found that upon binding, the purified proenzyme acquired activity against both the fluorogenic peptide (7-methoxycoumarin-4-yl)-acetic acid (MCA)-Pro-Leu-Gly-Leu-3-(2,4-dinitrophenyl)-l-2,3-diaminopropionyl-Ala-Arg-NH(2) and gelatin substrates, whereas its propeptide remained intact. These results suggest that although activation of all known matrix metalloproteases in vitro is accomplished by proteolytic processing of the propeptide, other mechanisms, such as binding to a ligand or to a substrate, may lead to a disengagement of the propeptide from the active center of the enzyme, causing its activation.     

Synthesis and processing of lysosomal enzymes of mouse kidney after treatment with [3H]fucose

[3H]Fucose, intravenously injected into androgen-treated mice, was incorporated at high rates into the immunopurified kidney lysosomal enzymes beta-glucuronidase and beta-galactosidase. Initially, label was incorporated into high molecular weight proenzyme forms. Processing of fucose-labeled proenzyme forms to lower molecular weight mature forms was very rapid, being detectable at 30 min, and complete by 90 min, compared with the several hours required for processing of lysosomal enzymes labeled with amino acids. This result is consistent with addition of fucose residues within the Golgi apparatus just before transfer of lysosomal proenzyme forms to the lysosome where maturation is thought to occur. The combination of the high rates of incorporation of [3H]fucose and the known metabolic stability of this precursor sugar suggests that the mouse kidney system is advantageous for studies of the synthesis, processing, and degradation of fucose-containing complex oligosaccharides of lysosomal enzymes and, by extension, of other kidney glycoproteins.     

The propeptide is not required to produce catalytically active neutral protease from Bacillus stearothermophilus

The thermolysin-like neutral protease from Bacillus stearothermophilus (TLP-ste) is usually produced extracellularly in Bacillus subtilis, where it is expressed as preproenzyme and subsequently processed in an autocatalytic, intramolecular process. To create the basis for the production of inactive mutants of TLP-ste, which cannot be processed in B. subtilis, we studied the expression of TLP-ste and its propeptide in cis and in trans in Escherichia coli. In contrast to thermolysin, subtilisin and alpha-lytic protease, which could be obtained only in the presence of the corresponding propeptides, TLP-ste could be produced as an active mature enzyme in E. coli in the absence of its prosequence. Surprisingly, however, a much more effective access to active mature protease was found when TLP-ste (devoid of its prosequence) was expressed as protein with an N-terminal His6 tag which accumulated in the form of inclusion bodies. Completely unexpected, the protein could be renatured from the inclusion bodies after solubilization in guanidine hydrochloride solutions in high yields. Purification to homogeneity was possible by affinity chromatography on Bacitracin silica as well as by immobilized metal ion affinity chromatography. By addition of separately expressed propeptide to the renaturation mixture yields of renaturation could not be increased significantly, confirming that the propeptide is not essential for proper folding of the enzyme or its stabilization during the folding process. Also in vivo, the expression levels of active mature TLP-ste in Escherichia coli did not significantly differ when the mature sequence was expressed alone or coexpressed with the prosequence in cis or in trans.     

Mechanism of lysosome rupture by dipeptides

Low concentrations of some neutral dipeptides, such as L -Ala-L -Ala, rapidly disrupt rat liver lysosmes. The phenomenon has been attributed to an osmotic imbalance generated by the production of amino acids in the lysosme by lysosomal dipeptidase activity. This hypothesis is challenged by testing several pairs of dipeptides available in both D - and L -forms and a range of dipeptides whose susceptibility to lysosomal dipeptidase activity is known. A good correlation was found between the lytic ability of dipeptides and their capacity to cross the lysosome membrane and be hydrolysed by lysosomal dipeptidase. The osmotic-imbalance hypothesis is critically evaluated in the light of the results and of recent information concerning the carrier-mediated transport of amino acids and dipeptides across the lysosome membrane. It is concluded that intralysosomal generation of amino acids remains the most plausible explanation of the lytic activity of dipeptides, and that the dipeptide proter(s) in the lysosome membrane must have higher K_m than the amino acid porters.     

Lysosomal storage causes cellular dysfunction in mucolipidosis II skin fibroblasts

Mucolipidosis II (ML-II) is a fatal inherited metabolic disease caused by deficiency of GlcNAc-phosphotransferase, which plays a role in generating the mannose 6-phosphate recognition marker on lysosomal enzymes. In ML-II, many lysosomal acid hydrolases are mistargeted out of cells, and lysosomes become filled with undigested substrates, which explains inclusion cell disease as an alternative name for this disease. In this study, we revealed various cellular phenotypes in ML-II skin fibroblasts. We quantitated phospholipid and cholesterol within cells and showed ~2-fold accumulation in ML-II as compared with normal cells. Lysosomal pH of ML-II cells was higher than that of normal cells (5.29 ± 0.08 versus 4.79 ± 0.10, p < 0.001). The proliferated lysosomes in ML-II cells were accumulated ~3-fold in amount as compared with normal cells. Intracellular logistics including endocytosis and mannose 6-phosphate receptor recycling were impaired in ML-II cells. To confirm whether these ML-II cellular phenotypes derive from deficient lysosomal acid hydrolases within lysosomes, we performed supplementation of lysosomal enzymes using a partially purified total enzyme mixture, which was derived from the conditioned culture medium of normal skin fibroblasts after NH(4)Cl treatment. This supplementation corrected all of the previously described ML-II phenotypes. In addition, the autophagic and mitochondrial impairment that we have previously reported improved, and inclusion bodies disappeared on electron micrography following total lysosomal enzyme supplementation. Our results indicate that various cellular phenotypes in ML-II are caused by the deficiency of many lysosomal enzymes and massive accumulation of undigested substrates.     

Effect of chemical chaperones in improving the solubility of recombinant proteins in Escherichia coli

The recovery of active proteins from inclusion bodies usually involves chaotrope-induced denaturation, followed by refolding of the unfolded protein. The efficiency of renaturation is low, leading to reduced yield of the final product. In this work, we report that recombinant proteins can be overexpressed in the soluble form in the host expression system by incorporating compatible solutes during protein expression. Green fluorescent protein (GFP), which was otherwise expressed as inclusion bodies, could be made to partition off into the soluble fraction when sorbitol and arginine, but not ethylene glycol, were present in the growth medium. Arginine and sorbitol increased the production of soluble protein, while ethylene glycol did not. Production of ATP increased in the presence of sorbitol and arginine, but not ethylene glycol. A control experiment with fructose addition indicated that protein solubilization was not due to a simple ATP increase. We have successfully reproduced these results with the N-terminal domain of HypF (HypF-N), a bacterial protein which forms inclusion bodies in Escherichia coli. Instead of forming inclusion bodies, HypF-N could be expressed as a soluble protein in the presence of sorbitol, arginine, and trehalose in the expression medium.     

Role of NifS in maturation of glutamine phosphoribosylpyrophosphate amidotransferase.

Glutamine phosphoribosylpyrophosphate amidotransferase from Bacillus subtilis is synthesized as an inactive precursor that requires two maturation steps: incorporation of a [4Fe-4S] center and cleavage of an 11-residue NH2-terminal propeptide. Overproduction from a multicopy plasmid in Escherichia coli leads to the formation of soluble proenzyme and mature enzyme forms as well as a small fraction of insoluble proenzyme. Heterologous expression of Azotobacter vinelandii nifS from a compatible plasmid increased the maturation of the soluble proenzyme three- to fourfold without influencing the content of the insoluble fraction. These results support a role for NifS in heterologous Fe-S cluster assembly and enzyme maturation.