Ca(2+)-induced structural changes in rat m-calpain revealed by partial proteolysis

Partial proteolysis by exogenous proteases in the presence and absence of Ca(2+) was used to map the protease-resistant domains in m-calpain, and to obtain evidence for the conformational changes induced in this thiol protease by Ca(2+). The complication of autoproteolysis was avoided by using the inactive Cys105Ser calpain mutant. Both trypsin and chymotrypsin produced similar cleavage patterns from the large subunit (domains I-IV), while the small subunit (domain VI) was largely unaffected. N-Terminal sequencing of the major products showed that hydrolysis occurred in the N-terminal anchor peptide, which binds domain I to domain VI, at a site close to the C terminus of domain II, and at several sites within domain III. Of particular importance to the overall Ca(2+)-induced conformational changes was the increase in mobility and accessibility of domain III. The same sites were cleaved in the presence and absence of Ca(2+), but with one exception digestion was much more rapid in the presence of Ca(2+). The exception was a site close to residue 255 located within the active site cleft. This site was accessible to cleavage in the absence of Ca(2+), when the active site is not assembled, but was protected in the presence of Ca(2+). This result supports the hypothesis that Ca(2+) induces movement of domains I and II closer together to form the functional active site of calpain.     

Domain II of m-calpain is a Ca(2+)-dependent cysteine protease

Calpain, a Ca(2+)-dependent cytosolic cysteine protease, proteolytically modulates specific substrates involved in Ca(2+)-mediated intracellular events, such as signal transduction, cell cycle, differentiation, and apoptosis. The 3D structure of m-calpain, in the absence of Ca(2+), revealed that the two subdomains (domains IIa and IIb) of the protease domain (II) have an 'open' conformation, probably due to interactions with other domains. Although the presence of an EF-hand structure was once predicted in the protease domain, no explicit Ca(2+)-binding structure was identified in the 3D structure. Therefore, it is predicted that if the protease domain is excised from the calpain molecule, it will have a Ca(2+)-independent protease activity. In this study, we have characterized a truncated human m-calpain that consists of only the protease domain. Unexpectedly, the proteolytic activity was Ca(2+)-dependent, very weak, and not effectively inhibited by calpastatin, a calpain inhibitor. Ca(2+)-dependent modification of the protease domain by the cysteine protease inhibitor, E-64c, was clearly observed as a SDS-PAGE migration change, indicating that the conformational changes of this domain are a result of Ca(2+) binding. These results suggest that the Ca(2+) binding to domain II, as well as to domains III, IV, and VI, is critical in the process of complete activation of calpain.     

Dissociation and aggregation of calpain in the presence of calcium

Calpain is a heterodimeric Ca(2+)-dependent cysteine protease consisting of a large (80 kDa) catalytic subunit and a small (28 kDa) regulatory subunit. The effects of Ca(2+) on the enzyme include activation, aggregation, and autolysis. They may also include subunit dissociation, which has been the subject of some debate. Using the inactive C105S-80k/21k form of calpain to eliminate autolysis, we have studied its disassociation and aggregation in the presence of Ca(2+) and the inhibition of its aggregation by means of crystallization, light scattering, and sedimentation. Aggregation, as assessed by light scattering, depended on the ionic strength and pH of the buffer, on the Ca(2+) concentration, and on the presence or absence of calpastatin. At low ionic strength, calpain aggregated rapidly in the presence of Ca(2+), but this was fully reversible by EDTA. With Ca(2+) in 0.2 m NaCl, no aggregation was visible but ultracentrifugation showed that a mixture of soluble high molecular weight complexes was present. Calpastatin prevented aggregation, leading instead to the formation of a calpastatin-calpain complex. Crystallization in the presence of Ca(2+) gave rise to crystals mixed with an amorphous precipitate. The crystals contained only the small subunit, thereby demonstrating subunit dissociation, and the precipitate was highly enriched in the large subunit. Reversible dissociation in the presence of Ca(2+) was also unequivocally demonstrated by the exchange of slightly different small subunits between mu-calpain and m-calpain. We conclude that subunit dissociation is a dynamic process and is not complete in most buffer conditions unless driven by factors such as crystal formation or autolysis of active enzymes. Exposure of the hydrophobic dimerization surface following subunit dissociation may be the main factor responsible for Ca(2+)-induced aggregation of calpain. It is likely that dissociation serves as an early step in calpain activation by releasing the constraints upon protease domain I.     

Conformational changes of calpain from human erythrocytes in the presence of Ca2+

Small angle x-ray scattering has been used to monitor calpain structural transitions during the activation process triggered by Ca(2+) binding. The scattering pattern of the unliganded enzyme in solution does not display any significant difference with that calculated from the crystal structure. The addition of Ca(2+) promotes the formation of large aggregates, indicating the exposure of hydrophobic patches on the surface of the protease. In contrast, Ca(2+) addition in the presence of the thiol proteinase inhibitor E64 or of the inhibitor leupeptin causes a small conformational change with no dissociation of the heterodimer. The resulting conformation appears to be slightly more extended than the unliganded form. From the comparison between ab initio models derived from our data with the crystal structure, the major observable conformational change appears to be localized at level of the L-subunit and in particular seems to confirm the mutual movement already observed by the crystallographic analysis of the dII (dIIb) and the dI (dIIa) domains creating a functional active site. This work not only provides another piece of supporting evidence for the calpain conformational change in the presence of Ca(2+), but actually constitutes the first experimental observation of this change for intact heterodimeric calpain in solution.     

Subcellular localization and in vivo subunit interactions of ubiquitous mu-calpain

Ubiquitously expressed calpains are Ca(2+)-dependent, intracellular cysteine proteases comprising a large catalytic subunit (domains DI-DIV) and a noncovalently bound small regulatory subunit (domains DV and DVI). It is unclear whether Ca(2+)-induced calpain activation is followed by subunit dissociation or not. Here, we have applied advanced fluorescence microscopy techniques to study calpain subunit interactions in living cells using recombinant calpain subunits or domains fused to enhanced cyan and enhanced yellow fluorescent reporter proteins. All of the overexpressed variants of the catalytic subunit (DI-IV, DI-III, and DI-IIb) were active and Ca(2+)-dependent. The intact large subunit, but not its truncated variants, associates with the small subunit under resting and ionomycin-activated conditions. All of the variants were localized in cytoplasm and nuclei, except DI-IIb, which accumulates in the nucleus and in nucleoli as shown by microscopy and cell fractionation. Localization studies with mutated and chimeric variants indicate that nuclear targeting of the DI-IIb variant is conferred by the two N-terminal helices of DI. Only those variants that contain DIII migrated to membranes upon the addition of ionomycin, suggesting that DIII is essential for membrane targeting. We propose that intracellular localization and in particular membrane targeting of activated calpain, but not dissociation of its intact subunits, contribute to regulate its proteolytic activity in vivo.     

Interactions of calcineurin A, calcineurin B, and Ca2+.

Calcineurin B (CN-B) is the Ca(2+)-binding, regulatory subunit of the phosphatase calcineurin. Point mutations to Ca(2+)-binding sites in CN-B were generated to disable individual Ca(2+)-binding sites and evaluate contributions from each site to calcineurin heterodimer formation. Ca(2+)-binding properties of four CN-B mutants and wild-type CN-B were analyzed by flow dialysis confirming that each CN-B mutant binds three Ca2+ and that wild-type CN-B binds four Ca2+. Macroscopic dissociation constants indicate that N-terminal Ca(2+)-binding sites have lower affinity for Ca2+ than the C-terminal sites. Each CN-B mutant was coexpressed with the catalytic subunit of calcineurin, CN-A, to produce heterodimers with specific disruption of one Ca(2+)-binding site. Enzymes containing CN-B with a mutation in Ca(2+)-binding sites 1 or 2 have a lower ratio of CN-B to CN-A and a lower phosphatase activity than those containing wild-type CN-B or mutants in sites 3 or 4. Effects of heterodimer formation on Ca2+ binding were assessed by monitoring (45)Ca2+ exchange by flow dialysis. Enzymes containing wild-type CN-B and mutants in sites 1 and 2 exchange (45)Ca2+ slowly from two sites whereas mutants in sites 3 and 4 exchange (45)Ca2+ slowly from a single site. These data indicate that the Ca2+ bound to sites 1 and 2 is likely to vary with Ca2+ concentration and may act in dynamic modulation of enzyme function, whereas Ca(2+)-binding sites 3 and 4 are saturated at all times and that Ca2+ bound to these sites is structural.     

Calpain activation by cooperative Ca2+ binding at two non-EF-hand sites

The active site residues in calpain are mis-aligned in the apo, Ca(2+)-free form. Alignment for catalysis requires binding of Ca2+ to two non-EF-hand sites, one in each of the core domains I and II. Using domain swap constructs between the protease cores of the mu and m isoforms (which have different Ca2+ requirements) and structural and biochemical characterization of site-directed mutants, we have deduced the order of Ca2+ binding and the basis of the cooperativity between the two sites. Ca2+ binds first to the partially preformed site in domain I. Knockout of this site through D106A substitution eliminates binding to this domain as shown by the crystal structure of D106A muI-II. However, at elevated Ca2+ concentrations this mutant still forms the double salt bridge that links the two Ca2+ sites and becomes nearly as active as muI-II. Elimination of the bridge in E333A muI-II has a more drastic effect on enzyme action, especially at low Ca2+ concentrations. Domain II Ca2+ binding appears essential, because Ca(2+)-coordinating side-chain mutants E302R and D333A have severely impaired muI-II activation and activity. The introduction of mutations into the whole heterodimeric enzyme that eliminate the salt bridge or Ca2+ binding to domain II produce similar phenotypes, suggesting that the protease core Ca2+ switch is crucial and cannot be overridden by Ca2+ binding to other domains.     

Autolysis of calpain large subunit inducing irreversible dissociation of stoichiometric heterodimer of calpain

Calpain, a calcium dependent cysteine protease, consists of a catalytic large subunit and a regulatory small subunit. Two models have been proposed to explain calpain activation: an autolysis model and a dissociation model. In the autolysis model, the autolyzed form is the active species, which is sensitized to Ca2+. In the dissociation model, dissociated large subunit is the active species. We have reported that the Ca2+ concentration regulates reversible dissociation of subunits. We found further that in chicken micro/m-calpain autolysis of the large subunit induces irreversible dissociation from the small subunit as well as activation. So we could propose a new mechanism for activation of the calpain by combining our findings. Our model insists that autolyzed large subunit remains dissociated from the small subunit even after the removal of Ca2+ to keep it sensitized to Ca2+. This model could be expanded to other calpains and give a new perspective on calpain activation.     

Crystal structure of human grancalcin, a member of the penta-EF-hand protein family

Grancalcin is a Ca(2+)-binding protein expressed at high level in neutrophils. It belongs to the PEF family, proteins containing five EF-hand motifs and which are known to associate with membranes in Ca(2+)-dependent manner. Prototypic members of this family are Ca(2+)-binding domains of calpain. Our recent finding that grancalcin interacts with L-plastin, a protein known to have actin bundling activity, suggests that grancalcin may play a role in regulation of adherence and migration of neutrophils. The structure of human grancalcin has been determined at 1.9 A resolution in the absence of calcium (R-factor of 0.212 and R-free of 0.249) and at 2. 5 A resolution in the presence of calcium (R-factor of 0.226 and R-free of 0.281). The molecule is predominantly alpha-helical: it contains eight alpha-helices and only two short stretches of two-stranded beta-sheets between the loops of paired EF-hands. Grancalcin forms dimers through the association of the unpaired EF5 hands in a manner similar to that observed in calpain, confirming this mode of association as a paradigm for the PEF family. Only one Ca(2+) was found per dimer under crystallization conditions that included CaCl(2). This cation binds to EF3 in one molecule, while this site in the second molecule of the dimer is unoccupied. This unoccupied site shows higher mobility. The structure determined in the presence of calcium, although does not represent a fully Ca(2+)-loaded form, suggests that calcium induces rather small conformational rearrangements. Comparison with calpain suggests further that the relatively small magnitude of conformational changes invoked by calcium alone may be a characteristic feature of the PEF family. Moreover, the largest differences are localized to the EF1, thus supporting the notion that calcium signaling occurs through this portion of the molecule and that it may involve the N-terminal Gly/Pro rich segment. Electrostatic potential distribution shows significant differences between grancalcin and calpain domain VI demonstrating their distinct character.     

Evolutionary and physical linkage between calpains and penta-EF-hand Ca2+-binding proteins

The name calpain was historically given to a protease that is activated by Ca(2+) and whose primary structure contains a Ca(2+)-binding penta-EF-hand (PEF) as well as a calpain cysteine protease (CysPc) domain and a C2-domain-like (C2L) domain. In the human genome, CysPc domains are found in 15 genes, but only nine of them encode PEF domains. Fungi and budding yeasts have calpain-like sequences that lack the PEF domain, and each protein (designated PalB and Rim13, respectively) is orthologous to human calpain-7, indicating that the calpain-7 orthologs are evolutionarily more conserved than classical calpains possessing PEF domains. An N-terminal region of calpain-7 has a tandem repeat of microtubule-interacting and transport domains that interact with a subset of endosomal sorting complex required for transport (ESCRT) III proteins. In addition to calpains, PEF domains are found in other Ca(2+)-binding proteins including ALG-2 that associates with ALIX (an ESCRT-III accessory protein) and TSG101 (an ESCRT-I subunit). Phylogenetic comparison of dissected domain structures of calpains and experimentally confirmed protein-protein interaction networks imply that there is an evolutionary and physical linkage between mammalian calpains and PEF proteins involving the ESCRT system.     

Is calpain activity regulated by membranes and autolysis or by calcium and calpastatin?

Although the Ca(2+)-dependent proteinase (calpain) system has been found in every vertebrate cell that has been examined for its presence and has been detected in Drosophila and parasites, the physiological function(s) of this system remains unclear. Calpain activity has been associated with cleavages that alter regulation of various enzyme activities, with remodeling or disassembly of the cell cytoskeleton, and with cleavages of hormone receptors. The mechanism regulating activity of the calpain system in vivo also is unknown. It has been proposed that binding of the calpains to phospholipid in a cell membrane lowers the Ca2+ concentration, [Ca2+], required for the calpains to autolyze, and that autolysis converts an inactive proenzyme into an active protease. Recent studies, however, show that the calpains bind to specific proteins and not to phospholipids, and that binding to cell membranes does not affect the [Ca2+] required for autolysis. It seems likely that calpain activity is regulated by binding of Ca2+ to specific sites on the calpain molecule, with binding to each site eliciting a response (proteolytic activity, calpastatin binding, etc.) specific for that site. Regulation must also involve an, as yet, undiscovered mechanism that increases the affinity of the Ca(2+)-binding sites for Ca2+.     

Purification and characterization of a Ca(2+)-activated thiol protease from Drosophila melanogaster.

A Ca(2+)-activated thiol protease was purified from Drosophila melanogaster. The procedure involves Phenyl-Sepharose, Reactive Red-Agarose and Q-Sepharose fast flow (or MonoQ) chromatographic steps. The enzyme eluting from Q-Sepharose fast flow seems to be homogeneous as judged by silver staining on SDS-PAGE: it consists of a single polypeptide chain of M(r),app = 94K and pI = 5.46. The proteolytic activity of the purified enzyme is absolutely Ca(2+)-dependent, characterized by 0.6 mM free Ca2+ at half-maximal activity. Ca2+ ions cannot be replaced effectively by the divalent cations Mg2+, Mn2+, Zn2+, Ba2+, and Cd2+. The enzyme shows the inhibitor pattern of thiol proteases. Human recombinant calpastatin (domain I) completely inhibits the enzyme at a nearly 1:1 molar ratio. Several of these properties resemble those of vertebrate calpain II. However, various attempts to detect a small subunit of M(r) approximately 30K, common with vertebrate calpains, remained unsuccessful. We suggest that the Drosophila enzyme is a novel calpain II-like protease.     

Stomach-specific calpain, nCL-2/calpain 8, is active without calpain regulatory subunit and oligomerizes through C2-like domains

Calpains constitute a family of intracellular Ca(2+)-regulated cysteine proteases that are indispensable in the regulation of a wide variety of cellular functions. The improper activation of calpain causes lethality or various disorders, such as muscular dystrophies and tumor formation. nCL-2/calpain 8 is predominantly expressed in the stomach, where it appears to be involved in membrane trafficking in the gastric surface mucus cells (pit cells). Although the primary structure of nCL-2 is quite similar to that of the ubiquitous m-calpain large subunit, the enzymatic properties of nCL-2 have never been reported. Here, to characterize nCL-2, the recombinant protein was prepared using an Escherichia coli expression system and purified to homogeneity. nCL-2 was stably produced as a soluble and active enzyme without the conventional calpain regulatory subunit (30K). Purified nCL-2 showed Ca(2+)-dependent activity, with half-maximal activity at about 0.3 mM Ca(2+), similar to that of m-calpain, whereas its optimal pH and temperature were comparatively low. Immunoprecipitation analysis revealed that nCL-2 exists in both monomeric and homo-oligomeric forms, but not as a heterodimer with 30K or 30K-2, and that the oligomerization occurs through domains other than the 5EF-hand domain IV, most probably through domain III, suggesting a novel regulatory system for nCL-2.     

Digestion of mu- and m-calpain by trypsin and chymotrypsin

Proteolytic digestion by trypsin and chymotrypsin was used to probe conformation and domain structure of the mu- and m-calpain molecules in the presence and the absence of Ca(2+). Both calpains have a compact structure in the absence of Ca(2+); incubation with either protease for 120 min results in only three or four major fragments. A 24-kDa fragment was produced by removal of the Gly-rich area in domain V of the 28-kDa subunit. The other fragments were from the 80-kDa subunit. Except for trypsin digestion of m-calpain, the region between amino acids 245 and 265 (human sequence) was very susceptible to cleavage by both proteases in the absence of Ca(2+); this region is in domain II (IIb of the crystallographic structure). Although no proteolytically active fragments could be isolated from either tryptic or chymotryptic digests, the calpain molecule can remain assembled in a proteolytically active complex even after the 80-kDa subunit has been completely degraded. The results suggest that interaction among different regions of the entire calpain molecule is required for its full proteolytic activity. In the presence of 1 mM Ca(2+), both calpains are degraded to fragments less than 40-kDa in less than 5 min. The C-terminal ends of both subunits, from amino acids 503 to 506 to the end of the 80-kDa subunit and from amino acids 85 to 88 to the end of the 28-kDa subunit, were resistant to degradation by either protease in the presence or in the absence of Ca(2+). Hence, this part of the calpain molecule is in a compact structure that does not change significantly in the presence of Ca(2+).     

Association of calpastatin with inactive calpain: a novel mechanism to control the activation of the protease?

It is generally accepted that the Ca(2+)-dependent interaction of calpain with calpastatin is the most relevant mechanism involved in the regulation of Ca(2+)-induced proteolysis. We now report that a calpain-calpastatin association can occur also in the absence of Ca(2+) or at very low Ca(2+) concentrations, reflecting the physiological conditions under which calpain retains its inactive conformational state. The calpastatin binding region is localized in the non-inhibitory L-domain containing the amino acid sequences encoded by exons 4-7. This calpastatin region recognizes a calpain sequence located near the end of the DII-domain. Interaction of calpain with calpastatins lacking these sequences becomes strictly Ca(2+)-dependent because, under these conditions, the transition to an active state of the protease is an obligatory requirement. The occurrence of the molecular association between Ca(2+)-free calpain and various recombinant calpastatin forms has been demonstrated by the following experimental results. Addition of calpastatin protected calpain from trypsin digestion. Calpain was coprecipitated when calpastatin was immunoprecipitated. The calpastatin molecular size increased following exposure to calpain. The two proteins comigrated in zymogram analysis. Furthermore, calpain-calpastatin interaction was perturbed by protein kinase C phosphorylation occurring at sites located at the exons involved in the association. At a functional level, calpain-calpastatin interaction at a physiological concentration of Ca(2+) represents a novel mechanism for the control of the amount of the active form of the protease potentially generated in response to an intracellular Ca(2+) influx.     

Generation of constitutively active calcineurin by calpain contributes to delayed neuronal death following mouse brain ischemia

Calpain, a Ca(2+)-dependent cysteine protease, in vitro converts calcineurin (CaN) to constitutively active forms of 45 kDa and 48 kDa by cleaving the autoinhibitory domain of the 60 kDa subunit. In a mouse middle cerebral artery occlusion (MCAO) model, calpain converted the CaN A subunit to the constitutively active form with 48 kDa in vivo. We also confirmed increased Ca(2+)/CaM-independent CaN activity in brain extracts. The generation of constitutively active and Ca(2+)/CaM-independent activity of CaN peaked 2 h after reperfusion in brain extracts. Increased constitutively active CaN activity was associated with dephosphorylation of dopamine-regulated phosphoprotein-32 in the brain. Generation of constitutively active CaN was accompanied by translocation of nuclear factor of activated T-cells (NFAT) into nuclei of hippocampal CA1 pyramidal neurons. In addition, a novel calmodulin antagonist, DY-9760e, blocked the generation of constitutively active CaN by calpain, thereby inhibiting NFAT nuclear translocation. Together with previous studies indicating that NFAT plays a critical role in apoptosis, we propose that calpain-induced CaN activation in part mediates delayed neuronal death in brain ischemia.     

Effect of orthophosphate, nucleotide analogues, ADP, and phosphorylation on the cytoplasmic domains of Ca(2+)-ATPase from scallop sarcoplasmic reticulum

The effects of orthophosphate, nucleotide analogues, ADP, and covalent phosphorylation on the tryptic fragmentation patterns of the E1 and E2 forms of scallop Ca-ATPase were examined. Sites preferentially cleaved by trypsin in the E1 form of the Ca-ATPase were detected in the nucleotide (N) and phosphorylation (P) domains, as well as the actuator (A) domain. These sites were occluded in the E2 (Ca(2+)-free) form of the enzyme, consistent with mutual protection of the A, N, and P domains through their association into a clustered structure. Similar protection of cytoplasmic Ca(2+)-dependent tryptic cleavage sites was observed when the catalytic binding site for substrate on the E1 form of scallop Ca-ATPase was occupied by Pi, AMP-PNP, AMP-PCP, or ADP despite the presence of saturating levels of Ca2+. These results suggest that occupation of the catalytic site on E1 can induce condensation of the cytoplasmic domains to yield a unique structural intermediate that may be related to the form of the enzyme in which the active site is prepared for phosphoryl transfer. The effect of Pi on the E2 form of the scallop Ca-ATPase was also investigated, when it was found that formation of E2-P led to extreme resistance toward secondary cleavage by trypsin and stabilization of enzymatic activity for long periods of time.     

Identification and functional analysis of two Ca2+-binding EF-hand motifs in the B"/PR72 subunit of protein phosphatase 2A

Protein phosphatase 2A (PP2A) is a multifunctional serine/threonine phosphatase that is critical to many cellular processes including cell cycle regulation and signal transduction. PP2A is a heterotrimer containing a structural (A) and catalytic (C) subunit, associated with one variable regulatory or targeting B-type subunit, of which three families have been described to date (B/PR55, B'/PR61, and B"/PR72). We identified two functional and highly conserved Ca(2+)-binding EF-hand motifs in human B"/PR72 (denoted EF1 and EF2), demonstrating for the first time the ability of Ca(2+) to interact directly with and regulate PP2A. EF1 and EF2 apparently bind Ca(2+) with different affinities. Ca(2+) induces a significant conformational change, which is dependent on the integrity of the motifs. We have further evaluated the effects of Ca(2+) on subunit composition, subcellular targeting, catalytic activity, and function during the cell cycle of a PR72-containing PP2A trimer (PP2A(T72)) by site-directed mutagenesis of either or both motifs. The results suggest that integrity of EF2 is required for A/PR65 subunit interaction and proper nuclear targeting of PR72, whereas EF1 might mediate the effects of Ca(2+) on PP2A(T72) activity in vitro and is at least partially required for the ability of PR72 to alter cell cycle progression upon forced expression.     

Calpains: an elaborate proteolytic system

Calpain is an intracellular Ca(2+)-dependent cysteine protease (EC 3.4.22.17; Clan CA, family C02). Recent expansion of sequence data across the species definitively shows that calpain has been present throughout evolution; calpains are found in almost all eukaryotes and some bacteria, but not in archaebacteria. Fifteen genes within the human genome encode a calpain-like protease domain. Interestingly, some human calpains, particularly those with non-classical domain structures, are very similar to calpain homologs identified in evolutionarily distant organisms. Three-dimensional structural analyses have helped to identify calpain's unique mechanism of activation; the calpain protease domain comprises two core domains that fuse to form a functional protease only when bound to Ca(2+)via well-conserved amino acids. This finding highlights the mechanistic characteristics shared by the numerous calpain homologs, despite the fact that they have divergent domain structures. In other words, calpains function through the same mechanism but are regulated independently. This article reviews the recent progress in calpain research, focusing on those studies that have helped to elucidate its mechanism of action. This article is part of a Special Issue entitled: Proteolysis 50 years after the discovery of lysosome.