Azadirachtin-induced apoptosis involves lysosomal membrane permeabilization and cathepsin L release in Spodoptera frugiperda Sf9 cells

Azadirachtin as a kind of botanical insecticide has been widely used in pest control. We previously reported that azadirachtin could induce apoptosis of Spodoptera litura cultured cell line Sl-1, which involves in the up-regulation of P53 protein. However, the detailed mechanism of azadirachtin-induced apoptosis is not clearly understood in insect cultured cells. The aim of the present study was to address the involvement of lysosome and lysosomal protease in azadirachtin-induced apoptosis in Sf9 cells. The result confirmed that azadirachtin indeed inhibited proliferation and induced apoptosis. The lysosomes were divided into different types as time-dependent manner, which suggested that changes of lysosomes were necessarily physiological processes in azadirachtin-induced apoptosis in Sf9 cells. Interestingly, we noticed that azadirachtin could trigger lysosomal membrane permeabilization and cathepsin L releasing to cytosol. Z-FF-FMK (a cathepsin L inhibitor), but not CA-074me (a cathepsin B inhibitor), could effectively hinder the apoptosis induced by azadirachtin in Sf9 cells. Meanwhile, the activity of caspase-3 could also be inactivated by the inhibition of cathepsin L enzymatic activity induced by Z-FF-FMK. Taken together, our findings suggest that azadirachtin could induce apoptosis in Sf9 cells in a lysosomal pathway, and cathepsin L plays a pro-apoptosis role in this process through releasing to cytosol and activating caspase-3.     

Phosphatidylinositol-hydrolyzing enzymes in chicken liver cells

Phosphatidylinositol-hydrolyzing activities were found in mitochondrial, lysosomal, microsomal, and cytosol fractions of chicken liver. At least two different activities were detected; cytosolic activiti(es) was maximally exhibited around pH 6.0, activated by Ca2+, and inhibited by EDTA; whereas lysosomal activiti(es) had a optimal pH 5.0, being unaffected by Ca2+ or EDTA.     

Phosphatidic acid mediates the targeting of tBid to induce lysosomal membrane permeabilization and apoptosis

Upon apoptotic stimuli, lysosomal proteases, including cathepsins and chymotrypsin, are released into cytosol due to lysosomal membrane permeabilization (LMP), where they trigger apoptosis via the lysosomal-mitochondrial pathway of apoptosis. Herein, the mechanism of LMP was investigated. We found that caspase 8-cleaved Bid (tBid) could result in LMP directly. Although Bax or Bak might modestly enhance tBid-triggered LMP, they are not necessary for LMP. To study this further, large unilamellar vesicles (LUVs), model membranes mimicking the lipid constitution of lysosomes, were used to reconstitute the membrane permeabilization process in vitro. We found that phosphatidic acid (PA), one of the major acidic phospholipids found in lysosome membrane, is essential for tBid-induced LMP. PA facilitates the insertion of tBid deeply into lipid bilayers, where it undergoes homo-oligomerization and triggers the formation of highly curved nonbilayer lipid phases. These events induce LMP via pore formation mechanisms because encapsulated fluorescein-conjugated dextran (FD)-20 was released more significantly than FD-70 or FD-250 from LUVs due to its smaller molecular size. On the basis of these data, we proposed tBid-PA interactions in the lysosomal membranes form lipidic pores and result in LMP. We further noted that chymotrypsin-cleaved Bid is more potent than tBid at binding to PA, inserting into the lipid bilayer, and promoting LMP. This amplification mechanism likely contributes to the culmination of apoptotic signaling.     

Aging changes in intracellular protein breakdown

Using radioactively labelled cytosol proteins as substrates we were able to exclude the possible accumulation of any specific inhibitor for the lysosomal proteases in rat liver cytosol during the aging process. There were also no gross changes in the molecular weight patterns of these proteins during the aging process. The percentage of more hydrophobic proteins seems to be identical in both the "old" and "young" cytosol proteins. From immunological experiments we suppose a qualitative change in the composition of rat liver cytosol proteins or of their properties during the aging process.     

The protonophore CCCP interferes with lysosomal degradation of autophagic cargo in yeast and mammalian cells

Mitophagy is a selective pathway, which targets and delivers mitochondria to the lysosomes for degradation. Depolarization of mitochondria by the protonophore CCCP is a strategy increasingly used to experimentally trigger not only mitophagy, but also bulk autophagy. Using live-cell fluorescence microscopy we found that treatment of HeLa cells with CCCP caused redistribution of mitochondrially targeted dyes, including DiOC6, TMRM, MTR, and MTG, from mitochondria to the cytosol, and subsequently to lysosomal compartments. Localization of mitochondrial dyes to lysosomal compartments was caused by retargeting of the dye, rather than delivery of mitochondrial components to the lysosome. We showed that CCCP interfered with lysosomal function and autophagosomal degradation in both yeast and mammalian cells, inhibited starvation-induced mitophagy in mammalian cells, and blocked the induction of mitophagy in yeast cells. PARK2/Parkin-expressing mammalian cells treated with CCCP have been reported to undergo high levels of mitophagy and clearance of all mitochondria during extensive treatment with CCCP. Using correlative light and electron microscopy in PARK2-expressing HeLa cells, we showed that mitochondrial remnants remained present in the cell after 24 h of CCCP treatment, although they were no longer easily identifiable as such due to morphological alterations. Our results showed that CCCP inhibits autophagy at both the initiation and lysosomal degradation stages. In addition, our data demonstrated that caution should be taken when using organelle-specific dyes in conjunction with strategies affecting membrane potential.     

Conversion of proinsulin into insulin by cathepsins B and L from rat liver lysosomes

Conversion of proinsulin and intermediate forms of proinsulin into insulin were studied with rat liver cell fractions and purified lysosomal proteinases by using the technique of polyacrylamide disc-electrophoresis. Both substrates were degraded very rapidly by homogenates and crude lysosomal fractions to split products not detectable on disc-electropherograms. Neither breakdown nor conversion were detected with the cytosol and the microsomal fraction. With partially purified lysosomal fractions (mol. wt. approx. 25 000) or with highly purified cathepsin L or cathepsin B (B1) proinsulin was converted into products migrating like the intermediate forms and insulin, and the intermediates were converted into products migrating like insulin and deoctapeptide-insulin in disc-electropherograms. The mechanism of conversion seems to be different for both enzymes. The results force us to conclude that lysosomal cathepsins, especially cathepsins L and B might be involved in the process of conversion of proinsulin into insulin and perhaps also of other precursors into biologically active proteins in vivo.     

Tumor necrosis factor-related apoptosis-inducing ligand activates a lysosomal pathway of apoptosis that is regulated by Bcl-2 proteins

The present studies were performed to determine whether lysosomal permeabilization contributes to tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) cytotoxicity and to reconcile a role for lysosomes with prior observations that Bcl-2 family members regulate TRAIL-induced apoptosis. In KMCH cholangiocarcinoma cells stably expressing Mcl-1 small interference RNA (siRNA), treatment with TRAIL induced a redistribution of the cathepsin B from lysosomes to the cytosol. Pharmacological and small hairpin RNA-targeted inhibition of cathepsin B attenuated TRAIL-mediated apoptosis as assessed by morphological, biochemical, and clonogenic assays. Neither Bid siRNA nor Bak siRNA prevented cathepsin B release. In contrast, treatment of the cells with Bim siRNA or the JNK inhibitor SP600125 attenuated lysosomal permeabilization and cell death. Moreover, Bim and active Bax co-localized to lysosomes in TRAIL-treated cells in a JNK-dependent manner, and Bax siRNA reduced TRAIL-induced lysosomal permeabilization and cell death. Finally, BH3 domain peptides permeabilized isolated lysosomes in the presence of Bax. Collectively, these data suggest that TRAIL can trigger an apoptotic pathway that involves JNK-dependent activation of Bim, which in turn induces Bax-mediated permeabilization of lysosomes.     

Lysosomal membrane permeabilization as apoptogenic factor

Lysosomal membrane labilizing agents (incl. proapoptotic proteins of Bcl-2 family, LAPF, p53), estimation of lysosomal membrane permeabilization in living cells, the new data on differential permeabilization of lysosomal membranes, membrane stabilizing factors (incl. Hsp70), relations between lysosomal membrane damage, and initiation of apoptosis were considered. Signal effect of lysosomal membrane permeabilization is caused preferentially by release of cathepsin B and D in cytosol. Subsequent numerous pathways of apoptogenic signalization include proteolytic attack/activation on signal cytosolic proteins, mitochondria, procaspases, cell nuclei. The mainstream of the cell damage is connected with activation pf proapoptotic Bid and Bax, leading to permeabilization of the outer mitochondrial membrane, release of cytochrome c into cytosol and activation of caspase cascade. Translocation of the lysosoma enzymes in cytosol is capable to induce both the caspase-dependent and caspase-independent paths of apoptosis.     

Vacuole-mitochondrial cross-talk during apoptosis in yeast: a model for understanding lysosome-mitochondria-mediated apoptosis in mammals

The yeast apoptosis field emerged with the finding that key components of the apoptotic machinery are conserved in these simple eukaryotes. Thus it became possible to exploit these genetically tractable organisms to improve our understanding of the intricate mechanisms of cell death in higher eukaryotes and of severe human diseases associated with apoptosis dysfunctions. Early on, it was recognized that a mitochondria-mediated apoptotic pathway showing similarities to the mammalian intrinsic pathway was conserved in yeast. Recently, lysosomes have also emerged as central players in mammalian apoptosis. Following LMP (lysosomal membrane permeabilization), lysosomal proteases such as cathepsins B, D and L are released into the cytosol and can trigger a mitochondrial apoptotic cascade. CatD (cathepsin D) can also have anti-apoptotic effects in some cellular types and specific contexts. Nonetheless, the mechanisms underlying LMP and the specific role of cathepsins after their release into the cytosol remain poorly understood. We have recently shown that yeast vacuoles, membrane-bound acidic organelles, which share many similarities to plant vacuoles and mammalian lysosomes, are also involved in the regulation of apoptosis and that the vacuolar protease Pep4p, orthologue of the human CatD, is released from the vacuole into the cytosol in response to acetic acid. Here, we discuss how the conservation of cell-death regulation mechanisms in yeast by the lysosome-like organelle and mitochondria may provide new insights into the understanding of the complex interplay between the mitochondria and lysosome-mediated signalling routes during mammalian apoptosis.     

Localization and some properties of lysosomal dipeptidases in rat liver.

1. The rates of hydrolysis of 26 synthetic dipeptides by extracts from highly purified lysosomal fractions from rat liver at pH 5.0 and by whole liver homogenates at pH 7.4 have been determined. Extracts from the lysosomal fractions hydrolysed most peptides at a lower rate per mg protein than the homogenates, and some peptides not at all. 2. Properties of two dipeptidases present in the extracts from the lysosomal fractions, splitting Ile-Glu and Leu-Gly, respectively, were studied in greater detail. The enzyme that hydrolysed Ile-Glu was strongly activated by dithiothreitol, showed optimal activity at pH 4.5 and had a molecular weight of about 120 000. Leu-Gly dipeptidase did apparently not contain an essential thiol group and had a molecular weight of approx. 90 000. It showed maximal activity at pH 6.5. 3. After differential centrifugation of liver homogenates, Ile-Glu and Leu-Gly-splitting activities were determined in the fractions, under the optimal conditions mentioned above. The Ile-Glu-hydrolysing enzyme activity showed about the same distribution as the lysosomal marker enzyme acid phosphatase. Leu-Gly-splitting activity, however, was largely present in the cytosol fraction, with only a small peak in the lysosomal fraction. We obtained evidence that the activities present in the lysosomal fraction and in the cytosol fraction were due to different enzymes, and that one of these enzymes was localized exclusively in lysosomes. 4. It is concluded that some dipeptides originating from intralysosomal proteolysis might be split by lysosomal dipeptidases, whereas others are probably hydrolysed only in the extra-lysosomal compartment of the cell.     

Fate of alpha-1,4-glucosidases and cathepsin D in the rat epididymis after vasectomy

Short-term vasectomy was studied in adult male rats in order to ascertain whether cytosolic or lysosomal hydrolases were differently affected 100 days after vas ligation. The secretory form of alpha-1,4-glucosidase remained unchanged while the lysosomal form of the enzyme and also cathepsin D increased in the cytosol of both caput and cauda epididymis. This set of data demonstrates for the first time that a triggering mechanism which stimulates lysosomal activity is present all along the rat epididymis. Disposal of the continuous influx of spermatozoa from the testis could therefore require both an active and a passive process.     

Lysosomal–mitochondrial cross-talk during cell death

Lysosomes are membrane-bound organelles, which contain an arsenal of different hydrolases, enabling them to act as the terminal degradative compartment of the endocytotic, phagocytic and autophagic pathways. During the last decade, it was convincingly shown that destabilization of lysosomal membrane and release of lysosomal content into the cytosol can initiate the lysosomal apoptotic pathway, which is dependent on mitochondria destabilization. The cleavage of BID to t-BID and degradation of anti-apoptotic BCL-2 proteins by lysosomal cysteine cathepsins were identified as links to the mitochondrial cytochrome c release, which eventually leads to caspase activation. There have also been reports about the involvement of lysosome destabilization and lysosomal proteases in the extrinsic apoptotic pathway, although the molecular mechanism is still under debate. In the present article, we discuss the cross-talk between lysosomes and mitochondria during apoptosis and its consequences for the fate of the cell.     

Substrate specificities of rat kidney lysosomal and cytosolic alpha-D-mannosidases and effects of swainsonine suggest a role of the cytosolic enzyme in glycoprotein catabolism

Swainsonine is a potent inhibitor of lysosomal alpha-D-mannosidase, causes the production of hybrid glycoproteins, and is reported to produce a phenocopy of hereditary alpha-mannosidosis. We now report that the effects of swainsonine administration in the rat are different in two respects from those found in other animals thus far studied. Swainsonine caused the accumulation of oligosaccharide in kidney and urine but not in liver or brain. The accumulated oligosaccharides were mainly Man(alpha 1-3)[Man(alpha 1-6)]Man(beta 1-4)GlcNAc, Man(alpha 1-3)[Man(alpha 1-6)[Man(alpha 1-3)]Man(beta 1-4) GlcNAc, and Man(alpha 1-3)[Man(alpha 1-6)]Man(alpha 1-6)[Man(alpha 1-3)]Man(beta 1-4)GlcNAc. Analogous branched Man4 and Man5 structures are found in pig and sheep tissues, but they are N, N'-diacetylchitobiose derivatives. The substrate specificities of rat kidney lysosomal and cytosolic alpha-D-mannosidases were investigated because in one type of hereditary alpha-mannosidosis, that occurring in man, the major storage products are linear rather than branched oligosaccharides. The lysosomal enzyme showed much greater activity toward linear oligosaccharides than toward the branched oligosaccharides induced in the kidney by swainsonine. On the other hand, cytosolic alpha-D-mannosidase preferred the branched oligosaccharides, a result suggesting that this mannosidase might be inhibitable by swainsonine and that the enzyme might play a normal role in glycoprotein catabolism. Swainsonine was indeed found to inhibit this enzyme at relatively high concentrations (I50 at 100 microM swainsonine), and concentrations of this magnitude were in fact found in the cytosol of kidney of swainsonine-fed rats. The kidney cytosolic alpha-D-mannosidase levels were reduced in these rats and, more important, the accumulated oligosaccharides were present mainly in the cytosol rather than in lysosomes. These results point to possible involvement of cytosolic alpha-D-mannosidase in glycoprotein degradation in the rat.     

Functional characterization of starvation-induced lysosomal activity in Saccharomyces cerevisiae

Starvation induces significant alterations in lysosomal enzymes, and reduced concentrations of glucose increases the activity of several lysosomal enzymes. Therefore, to evaluate the lysosomal antimicrobial activity under starvation conditions, we added 0, 5, 10, 20, or 40 g/l of glucose (0%, 0.5%, 1%, 2%, or 4% glucose) supplemented YP medium to cultured Saccharomyces cerevisiae, and lysosomal fractions were isolated from S. cerevisiae grown under the various culture conditions. The lysosomes isolated from each condition exhibited increased antimicrobial activity against Escherichia coli as determined by a decrease in glucose concentration. In addition, a starvation-dependent increase in lysosomal activity coincided with increased lysosome intensity at the cytosol and distinct protein expression from lysosomes in S. cerevisiae. It also was determined found that the lysosomes have antimicrobial activity against seven different microorganisms, including E. coli, and starvation-induced lysosomes showed enhanced antimicrobial activity compared to those from normal lysosomes. These results suggest the possibility that lysosomal alterations during starvation may induce conditions that activate lysosomes for future development of efficient antimicrobial agents.     

Lysosomal metabolism of glycoproteins

The lysosomal catabolism of glycoproteins is part of the normal turnover of cellular constituents and the cellular homeostasis of glycosylation. Glycoproteins are delivered to lysosomes for catabolism either by endocytosis from outside the cell or by autophagy within the cell. Once inside the lysosome, glycoproteins are broken down by a combination of proteases and glycosidases, with the characteristic properties of soluble lysosomal hydrolases. The proteases consist of a mixture of endopeptidases and exopeptidases, which act in concert to produce a mixture of amino acids and dipeptides, which are transported across the lysosomal membrane into the cytosol by a combination of diffusion and carrier-mediated transport. Although the glycans of all mature glycoproteins are probably degraded in lysosomes, the breakdown of N-linked glycans has been studied most intensively. The catabolic pathways for high-mannose, hybrid, and complex glycans have been established. They are bidirectional with concurrent sequential removal of monosaccharides from the nonreducing end by exoglycosidases and proteolysis and digestion of the carbohydrate-polypeptide linkage at the reducing end. The process is initiated by the removal of any core and peripheral fucose, which is a prerequisite for the action of the peptide N-glycanase aspartylglucosaminidase, which hydrolyzes the glycan-peptide bond. This enzyme also requires free alpha carboxyl and amino groups on the asparagine residue, implying extensive prior proteolysis. The catabolism of O-linked glycans has not been studied so intensively, but many lysosomal glycosidases appear to act on the same linkages whether they are in N- or O-linked glycans, glycosaminoglycans, or glycolipids. The monosaccharides liberated during the breakdown of N- and O-linked glycans are transported across the lysosomal membrane into the cytosol by a combination of diffusion and carrier-mediated transport. Defects in these pathways lead to lysosomal storage diseases. The structures of some of the oligosaccharides that accumulate in these diseases are not digestion intermediates in the lysosomal catabolic pathways but correspond to intermediates in the biosynthetic pathway for N-linked glycans, suggesting another route of delivery of glycans to the lysosome. Incorrectly folded or glycosylated proteins that are rejected by the quality control mechanism are broken down in the ER and cytoplasm and the end product of the cytosolic degradation of N-glycans is delivered to the lysosomes. This route is enhanced in cells actively secreting glycoproteins or producing increased amounts of aberrant glycoproteins. Thus interaction between the lysosome and proteasome is important for the regulation of the biosynthesis and distribution of N-linked glycoproteins. Another example of the extralysosomal function of lysosomal enzymes is the release of lysosomal proteases into the cytosol to initiate the lysosomal pathway of apoptosis.     

Guanosine 5′-[γ-thio]triphosphate-Mediated Activation of Cytosol Phospholipase C Caused Lysosomal Destabilization

Lysosomal disintegration is critical for the organelle functions and cellular viability. In this study, we established that guanosine 5′-[γ-thio]triphosphate (GTP-γ-S)-activated cytosol of rat hepatocytes could increase lysosomal permeability to both potassium ions and protons and osmotically destabilize the lysosomes via K⁺/H⁺ exchange. These results were obtained through measurements of lysosomal β-hexosaminidase-free activity, membrane potential and intralysosomal pH. Assays of phospholipase C (PLC) activity show that cytosolic PLC was activated upon addition of GTP-γ-S to the cytosol. The effects of cytosol on the lysosomes could be abolished by D609, an inhibitor of PLC, but not by the inhibitors of phospholipase A₂. The cytosol-treated lysosomes disintegrated markedly in hypotonic sucrose medium, reflecting that the lysosomal osmotic sensitivity increased. Microscopic observations showed that the lysosomes became more swollen in hypotonic sucrose medium. This indicates that the cytosol treatment induced osmotic shock to the lysosomes and an influx of water into the organelle. Xiang Wang and Li-Li Wang contributed equally to this work.     

Siramesine triggers cell death through destabilisation of mitochondria,but not lysosomes

A sigma-2 receptor agonist siramesine has been shown to trigger cell death of cancer cells and to exhibit a potent anticancer activity in vivo. However, its mechanism of action is still poorly understood. We show that siramesine can induce rapid cell death in a number of cell lines at concentrations above 20 μM. In HaCaT cells, cell death was accompanied by caspase activation, rapid loss of mitochondrial membrane potential (MMP), cytochrome c release, cardiolipin peroxidation and typical apoptotic morphology, whereas in U-87MG cells most apoptotic hallmarks were not notable, although MMP was rapidly lost. In contrast to the rapid loss of MMP above 20 μM siramesine, a rapid increase in lysosomal pH was observed at all concentrations tested (5–40 μM); however, it was not accompanied by lysosomal membrane permeabilisation (LMP) and the release of lysosomal enzymes into the cytosol. Increased lysosomal pH reduced the lysosomal degradation potential as indicated by the accumulation of immature forms of cysteine cathepsins. The lipophilic antioxidant α-tocopherol, but not the hydrophilic antioxidant N-acetyl-cysteine, considerably reduced cell death and destabilisation of mitochondrial membranes, but did not prevent the increase in lysosomal pH. At concentrations below 15 μM, siramesine triggered cell death after 2 days or later, which seems to be associated with a general metabolic and energy imbalance due to defects in the endocytic pathway, intracellular trafficking and energy production, and not by a specific molecular event. Overall, we show that cell death in siramesine-treated cells is induced by destabilisation of mitochondria and is independent of LMP and the release of cathepsins into the cytosol. Moreover, it is unlikely that siramesine acts exclusively through sigma-2 receptors, but rather through multiple molecular targets inside the cell. Our findings are therefore of significant importance in designing the next generation of siramesine analogues with high anticancer potential.     

Proteases and proteinase inhibitors in experimental glucocorticosteroid myopathy

The unknown enzymatic mechanism of enhanced protein breakdown in steroid myopathy was studied in functionally and biochemically different muscles of rabbits treated with dexamethasone for three weeks. After glucocorticoid administration the fast-twitch glycolytic semimembraneous muscle of treated animals was atrophied, whereas the weight of the slow-twitch oxidative soleus muscle was not altered. The specific activity of the lysosomal endo- and exopeptidases (cathepsin D, E, B and L, lysosomal carboxypeptidase A and dipeptidylpeptidase I) was increased about 2-fold in the atrophied white muscle. The activity of the cytosol enzyme Ca++-activated neutral proteinase was also elevated, whereas that of the other cytosol endopeptidase, chymotrypsin-like enzyme, was unaltered. The level of alanine aminopeptidase was only slightly increased. On the other hand, there were no unequivocal changes in protease activity in the soleus muscle. These findings are in agreement with the known differences in glucocorticoid-sensitivity of the various muscles. Our results suggest that the lysosomal proteolytic system and the Ca++-activated neutral proteinase may play an important role in the glucocorticoid-induced intracellular protein catabolism in muscle. The inhibitor capacities of cathepsin B and trypsin detectable in muscle cytosol were not altered after steroid treatment. Consequently, the increase in cathepsin B activity was not due to the loss of its inhibitor.     

Non-selective autophagy

Autophagy is the major process by which cells degrade their own cytoplasm. Autophagy begins with the sequestration of a portion of the cytoplasm by a membraneous organelle called a phagophore. The resulting vacuole (autophagosome) can fuse with an endocytic vacuole to form am amphisome, which subsequently fuses with a lysosome to have its mixed autophagic/endocytic content degraded by lysosomal enzymes. Autophagy is a non-selective bulk process as indicated by the fact that hepatocytic cytosol enzymes with widely different half-lives are sequestered at the same rate. Regulation of autophagy is exerted at the sequestration step by amino acids, purines, ATP-depleting metabolites, cyclic nucleotides, phosphorylation, and hormones like insulin, glucagon and alpha-adrenergic agonists.     

Calpains mediate epithelial-cell death during mammary gland involution: mitochondria and lysosomal destabilization

Our aim was to elucidate the physiological role of calpains (CAPN) in mammary gland involution. Both CAPN-1 and -2 were induced after weaning and its activity increased in isolated mitochondria and lysosomes. CAPN activation within the mitochondria could trigger the release of cytochrome c and other pro-apoptotic factors, whereas in lysosomes it might be essential for tissue remodeling by releasing cathepsins into the cytosol. Immunohistochemical analysis localized CAPNs mainly at the luminal side of alveoli. During weaning, CAPNs translocate to the lysosomes processing membrane proteins. To identify these substrates, lysosomal fractions were treated with recombinant CAPN and cleaved products were identified by 2D-DIGE. The subunit b(2) of the v-type H(+) ATPase is proteolyzed and so is the lysosomal-associated membrane protein 2a (LAMP2a). Both proteins are also cleaved in vivo. Furthermore, LAMP2a cleavage was confirmed in vitro by addition of CAPNs to isolated lysosomes and several CAPN inhibitors prevented it. Finally, in vivo inhibition of CAPN1 in 72-h-weaned mice decreased LAMP2a cleavage. Indeed, calpeptin-treated mice showed a substantial delay in tissue remodeling and involution of the mammary gland. These results suggest that CAPNs are responsible for mitochondrial and lysosomal membrane permeabilization, supporting the idea that lysosomal-mediated cell death is a new hallmark of mammary gland involution.