Anamorsin,a Novel Caspase-3 Substrate in Neurodegeneration

Activated caspases play a central role in the execution of apoptosis by cleaving endogenous substrates. Here, we developed a high throughput screening method to identify novel substrates for caspase-3 in a neuronal cell line. Critical steps in our strategy consist of two-dimensional electrophoresis-based protein separation and in vitro caspase-3 incubation of immobilized proteins to sort out direct substrates. Among 46 putative substrates identified in MN9D neuronal cells, we further evaluated whether caspase-3-mediated cleavage of anamorsin, a recently recognized cell death-defying factor in hematopoiesis, is a general feature of apoptosis. In vitro and cell-based cleavage assays indicated that anamorsin was specifically cleaved by caspase-3 but not by other caspases, generating 25- and 10-kDa fragments. Thus, in apoptosis of neuronal and non-neuronal cells induced by various stimuli including staurosporine, etoposide, or 6-hydroxydopamine, the cleavage of anamorsin was found to be blocked in the presence of caspase inhibitor. Among four tetrapeptide consensus DXXD motifs existing in anamorsin, we mapped a specific cleavage site for caspase-3 at DSVD²⁰⁹↓L. Intriguingly, the 25-kDa cleaved fragment of anamorsin was also detected in post-mortem brains of Alzheimer and Parkinson disease patients. Although the RNA interference-mediated knockdown of anamorsin rendered neuronal cells more vulnerable to staurosporine treatment, reintroduction of full-length anamorsin into an anamorsin knock-out stromal cell line made cells resistant to staurosporine-induced caspase activation, indicating the antiapoptotic function of anamorsin. Taken together, our approach seems to be effective to identify novel substrates for caspases and has the potential to provide meaningful insights into newly identified substrates involved in neurodegenerative processes.     

Yeast two-hybrid screening using constitutive-active caspase-7 as bait in the identification of PA28gamma as an effector caspase substrate

Caspase-3 and -7 represent executioner/effector caspases that directly cause apoptotic morphological changes by cleaving various death substrates. The substrates for caspases generally interact with active caspases, but not with inactive zymogens of caspase or procaspases. Here, to isolate proteins that interact with caspase-7, we established a yeast two-hybrid screening system using reversed-caspase-7, a constitutive active mutant of caspase-7 as a bait plasmid. Screening of an adult brain cDNA library led to isolation of proteasome activator 28 subunit, PA28gamma. In vitro translates of PA28gamma were cleaved by both recombinant caspase-3 and -7. Mutagenesis of potential cleavage site DGLD80 to EGLE80 completely abolished caspase-mediated cleavage. Moreover, endogenous PA28gamma was cleaved during not only Fas-induced apoptosis of HeLa cells, but also cisplatin-induced cell death of MCF7 cells, which are devoid of caspase-3. These findings indicate that PA28gamma is an endogenous substrate for caspase-3 and -7 and that yeast two-hybrid screening using reversed-caspase is a novel and useful approach to clone substrates for effector caspases.     

The Caspase-8 Homolog Dredd Cleaves Imd and Relish but Is Not Inhibited by p35

In Drosophila, the Imd pathway is activated by diaminopimelic acid-type peptidoglycan and triggers the humoral innate immune response, including the robust induction of antimicrobial peptide gene expression. Imd and Relish, two essential components of this pathway, are both endoproteolytically cleaved upon immune stimulation. Genetic analyses have shown that these cleavage events are dependent on the caspase-8 like Dredd, suggesting that Imd and Relish are direct substrates of Dredd. Among the seven Drosophila caspases, we find that Dredd uniquely promotes Imd and Relish processing, and purified recombinant Dredd cleaves Imd and Relish in vitro. In addition, interdomain cleavage of Dredd is not required for Imd or Relish processing and is not observed during immune stimulation. Baculovirus p35, a suicide substrate of executioner caspases, is not cleaved by purified Dredd in vitro. Consistent with this biochemistry but contrary to earlier reports, p35 does not interfere with Imd signaling in S2* cells or in vivo.     

Identification of Functional Regions Defining Different Activity in Caspase-3 and Caspase-7 within Cells

Caspases are central to apoptosis, and the principal executioner caspases, caspase-3 and -7, were reported to be similar in activity, primary structure, and three-dimensional structure. Here, we identified different activity in caspase-3 and -7 within cells and examined the relationship between their structure and function using human cells expressing almost equal amounts of exogenous caspase-3, caspase-7, and/or chimeric constructs after down-regulation of endogenous caspase-3 and -7 expression. Caspase-3 (produced in human cells) showed much stronger cleaving activity than caspase-7 against a low molecular weight substrate in vitro dependent on four specific amino acid regions. Within cells, however, an additional three regions were required for caspase-3 to exert much stronger protease activity than caspase-7 against cellular substrates. Three of the former four regions and the latter three regions were shown to form two different three-dimensional structures that were located at the interface of the homodimer of procaspase-7 on opposite sides. In addition, procaspase-3 and -7 revealed specific homodimer-forming activity within cells dependent on five amino acid regions, which were included in the regions critical to the cleaving activity within cells. Thus, human caspase-3 and -7 exhibit differences in protease activity, specific homodimer-forming activity, and three-dimensional structural features, all of which are closely interrelated.     

Inducible Dimerization and Inducible Cleavage Reveal a Requirement for Both Processes in Caspase-8 Activation

Caspase-8 is a cysteine protease activated by membrane-bound receptors at the cytosolic face of the cell membrane, initiating the extrinsic pathway of apoptosis. Caspase-8 activation relies on recruitment of inactive monomeric zymogens to activated receptor complexes, where they produce a fully active enzyme composed of two catalytic domains. Although in vitro studies using drug-mediated affinity systems or kosmotropic salts to drive dimerization have indicated that uncleaved caspase-8 can be readily activated by dimerization alone, in vivo results using mouse models have reached the opposite conclusion. Furthermore, in addition to interdomain autoprocessing, caspase-8 can be cleaved by activated executioner caspases, and reports of whether this cleavage event can lead to activation of caspase-8 have been conflicting. Here, we address these questions by carrying out studies of the activation characteristics of caspase-8 mutants bearing prohibitive mutations at the interdomain cleavage sites both in vitro and in cell lines lacking endogenous caspase-8, and we find that elimination of these cleavage sites precludes caspase-8 activation by prodomain-driven dimerization. We then further explore the consequences of interdomain cleavage of caspase-8 by adapting the tobacco etch virus protease to create a system in which both the cleavage and the dimerization of caspase-8 can be independently controlled in living cells. We find that unlike the executioner caspases, which are readily activated by interdomain cleavage alone, neither dimerization nor cleavage of caspase-8 alone is sufficient to activate caspase-8 or induce apoptosis and that only the coordinated dimerization and cleavage of the zymogen produce efficient activation in vitro and apoptosis in cellular systems.     

Cloning and characterization of the executioner caspases 3, 6, 7 and Hsp70 in hyperthermic Atlantic salmon (Salmo salar) embryos

Hyperthermia during embryogenesis has been reported to induce deformities in Atlantic salmon (Salmo salar). To examine the involvement of executioner caspases in hyperthermia-induced cell-death in a poikilotherm vertebrate species, five genes encoding caspase-3,-6, and -7 were cloned from Atlantic salmon, and the expression was studied in thermal stressed salmon embryos. The salmon genome contained two genetically distinct variants of both salmon caspase-3 and caspase-6 that is likely the result of two independent chromosome or genome duplications. Whereas only partial caspase-3A encoding sequences were isolated, the full-length caspase-3B cDNA encodes the inactive proenzyme of 279 amino acids (aa) consisting of an N-terminal prodomain and the large and the small subunit. The salmon caspase-6A and caspase-6B proenzymes include an additional linker region between the two subunits. The deduced salmon caspase-7 consists of only 245 aa and lacks the prodomain and part of the large subunit similar to the predicted caspase-7 of the puffer fish Tetraodon sp.. Increased apoptotic activity as evidenced by cleavage of nuclear DNA was demonstrated in salmon embryos incubated at 18-20 degrees C for 84 h after acclimatization at 8 degrees C. Hyperthermia-induced activation of the executioner caspases was indicated by the increased mRNA levels of caspase-3B, caspase-6A/B and caspase-7 after 54 h heat exposure as quantified by real-time RT-PCR. The 2-2.5 fold increase in the mRNA expression of the heat shock protein Hsp70 gene coincided with the peak mRNA values of the executioner caspases. Whole-mount in situ hybridization of the salmon embryo identified caspase-7 mRNA in the lens exclusively, while caspase-3B and caspase-6A/B were expressed in multiple tissues of exposed and control embryos. Interestingly, cardiac expression of caspase-6A/B was only identified in heat stressed embryos. Altogether, these results shed light on evolutionary aspects of the executioner caspases in vertebrates and their expression in salmon embryos exposed to hyperthermia. In particular, the heat sensitive caspase-6 expression in the embryonic heart is of interest since cardiac malformations are an emergent problem in salmon aquaculture.     

Calpain-1 Cleaves and Activates Caspase-7

Caspase-7 is an executioner caspase that plays a key role in apoptosis, cancer, and a number of neurodegenerative diseases. The mechanism of caspase-7 activation by granzyme B and caspase-3 has been well characterized. However, whether other proteases such as calpains activate or inactivate caspase-7 is not known. Here, we present that recombinant caspase-7 is directly cleaved by calpain-1 within the large subunit of caspase-7 to produce two novel products, large subunit p18 and p17. This new form of caspase-7 has a 6-fold increase in V_max when compared with the previously characterized p20/p12 form. Zymography revealed that the smaller caspase-7 product (p17) is 18-fold more active than either the caspase-3-cleaved product (p20) or the larger calpain-1 product of caspase-7 (p18). Mass spectrometry and site-directed mutagenesis identified the calpain cleavage sites within the caspase-7 large subunit at amino acid 36 and 45/47. These proteolysis events occur in vivo as indicated by the accumulation of caspase-7 p18 and p17 subunits in cortical neurons undergoing Ca²⁺ dysregulation. Further, cleavage at amino acid 45/47 of caspase-7 by calpain results in a reduction in nuclear localization when compared with the caspase-3 cleavage product of caspase-7 (p20). Our studies suggest the calpain-activated form of caspase-7 has unique enzymatic activity, localization, and binding affinity when compared with the caspase-activated form.Apoptosis is a well-defined cellular destruction pathway that primarily utilizes a family of cysteine proteases, the caspases (1, 2). This cell death program can be initiated by cell death receptor activation (extrinsic pathway) or a variety of drugs or cellular stresses (intrinsic pathway) leading to activation of apical caspase-8, -9, and/or -10 (1, 3, 4). These initiator caspases in turn directly activate the executioner caspases, caspase-3 and -7, which through proteolysis of defined substrates are responsible for the dismantling of the cell and subsequent death (3, 4). Granzyme B, released by cytotoxic T lymphocytes to protect the host from pathogens and tumor cells, can also initiate this apoptotic cascade and therefore is considered an apical caspase mimic (5–7). All caspases, as well as granzyme B, preferentially cleave after aspartic acid residues, with many having well-defined consensus sequences, making substrate cleavage sites easy to predict and establish (3, 4, 7, 8).Caspases exist in a latent form prior to activation. Both the initiator and executioner caspases are synthesized as a single chain protein, which require proteolytic cleavage to become active. Procaspase-7 is expressed as a 303-amino acid residue polypeptide chain. The activation and regulation of executioner caspase-7 by caspases and granzyme B has been extensively studied. Caspase-7 requires cleavage by caspase-3 and caspase-8/-10 or granzyme B, for activation (6, 9). Current evidence suggests that caspase-3 initially cleaves off the first 23 amino acids (propeptide, 2 kDa), followed by caspase-8/-10 or granzyme B cleaving between the large (20 kDa) and small (12 kDa) subunit after amino acid 198 to activate the enzyme. The large subunit containing the catalytic His-237 and Cys-285 (caspase-1 numbering convention), and the small subunit are involved in the formation of the substrate-binding region. In vitro, granzyme B can also activate caspase-7 independently of caspase-3, but this does not appear to occur in vivo (5, 6). Currently, there is no evidence that other classes of proteases play a role in activating or modulating caspase-7 activity.Changes in intracellular Ca²⁺ levels influence apoptosis in a number of cell types (10–13). Because in many of these apoptotic cell models the Ca²⁺-dependent cysteine proteases, calpains, are activated upstream of caspases (14–16), it is possible that calpains may activate and/or modulate caspase activity via direct cleavage. Studies directed at understanding calpains with respect to caspase activation are limited. Calpain-2 was shown to cleave procaspase-9, decreasing its activity (17). In the same study, calpain-2 treatment cleaved procaspase-7 to produce a single, novel fragment, but in this case the effect on enzymatic activity was not investigated (17). To improve our understanding of calpains and the role of calcium in cell death, we carried out studies directed at understanding how calpains activate or modulate caspase activity. We found that calpain treatment produced a large increase in caspase-7 activity. Calpain cleaves procaspase-7 to produce two large subunits of 18.5 and 17.2 kDa, the smaller of which has a robust increase in activity relative to the 20-kDa large subunit produced by caspase-3 cleavage of caspase-7. Both calpain cleavage sites in caspase-7 are identified using mass spectrometry. N-methyl-d-aspartate-induced Ca²⁺-dependent cell death in primary cortical neurons produced calpain-derived caspase-7 cleavage products in vivo. Lastly, the strictly cytosolic localization of the smaller calpain fragment confirms that a previously identified nuclear localization signal (18) is involved in caspase-7 cytosolic/nuclear distribution. Our data suggest that increases in Ca²⁺ leading to activation of calpains may significantly modulate caspase-7 activity and thus, apoptosis.     

Plasticity of S2-S4 specificity pockets of executioner caspase-7 revealed by structural and kinetic analysis

Many protein substrates of caspases are cleaved at noncanonical sites in comparison to the recognition motifs reported for the three caspase subgroups. To provide insight into the specificity and aid in the design of drugs to control cell death, crystal structures of caspase-7 were determined in complexes with six peptide analogs (Ac-DMQD-Cho, Ac-DQMD-Cho, Ac-DNLD-Cho, Ac-IEPD-Cho, Ac-ESMD-Cho, Ac-WEHD-Cho) that span the major recognition motifs of the three subgroups. The crystal structures show that the S2 pocket of caspase-7 can accommodate diverse residues. Glu is not required at the P3 position because Ac-DMQD-Cho, Ac-DQMD-Cho and Ac-DNLD-Cho with varied P3 residues are almost as potent as the canonical Ac-DEVD-Cho. P4 Asp was present in the better inhibitors of caspase-7. However, the S4 pocket of executioner caspase-7 has alternate regions for binding of small branched aliphatic or polar residues similar to those of initiator caspase-8. The observed plasticity of the caspase subsites agrees very well with the reported cleavage of many proteins at noncanonical sites. The results imply that factors other than the P4-P1 sequence, such as exosites, contribute to the in vivo substrate specificity of caspases. The novel peptide binding site identified on the molecular surface of the current structures is suggested to be an exosite of caspase-7. These results should be considered in the design of selective small molecule inhibitors of this pharmacologically important protease.     

Caspase-9 Activation by the Apoptosome Is Not Required for Fas-mediated Apoptosis in Type II Jurkat Cells

Activation of executioner caspases during receptor-mediated apoptosis in type II cells requires the engagement of the mitochondrial apoptotic pathway. Although it is well established that recruitment of mitochondria in this context involves the cleavage of Bid to truncated Bid (tBid), the precise post-mitochondrial signaling responsible for executioner caspase activation is controversial. Here, we used distinct clones of type II Jurkat T-lymphocytes in which the mitochondrial apoptotic pathway had been inhibited to investigate the molecular requirements necessary for Fas-induced apoptosis. Cells overexpressing either Bcl-2 or Bcl-x_L were protected from apoptosis induced by agonistic anti-Fas antibody. By comparison, Apaf-1-deficient Jurkat cells were sensitive to anti-Fas, exhibiting Bid cleavage, Bak activation, the release of cytochrome c and Smac, and activation of executioner caspase-3. Inhibiting downstream caspase activation with the pharmacological inhibitor Z-DEVD-fmk or by expressing the BIR1/BIR2 domains of X-linked inhibitor of apoptosis protein (XIAP) decreased all anti-Fas-induced apoptotic changes. Additionally, pretreatment of Bcl-x_L-overexpressing cells with a Smac mimetic sensitized these cells to Fas-induced apoptosis. Combined, our findings strongly suggest that Fas-mediated activation of executioner caspases and induction of apoptosis do not depend on apoptosome-mediated caspase-9 activation in prototypical type II cells.     

Sensors for Caspase Activities

Cysteine proteases, caspases, play an important role in the process of programmed cell death. In apoptosis, the cell signaling pathways overlap at executioner caspases regardless of the initial stimulus. Caspase-3 is the key one. This review considers the sensors for activity of caspase-3 and some other caspases. Over the past decade, many such sensors utilizing a variety of detection principles have been created; fluorescence and luminescence are the most common detection methods. The intracellular sensors are of particular interest; they allow visualization of the activation of caspases in living systems. Herein, we briefly describe sensors of various designs, the advantages and disadvantages of which must be taken into account when choosing a sensor for a particular experimental system.

     

Unnatural amino acids increase sensitivity and provide for the design of highly selective caspase substrates

Traditional combinatorial peptidyl substrate library approaches generally utilize natural amino acids, limiting the usefulness of this tool in generating selective substrates for proteases that share similar substrate specificity profiles. To address this limitation, we synthesized a Hybrid Combinatorial Substrate Library (HyCoSuL) with the general formula of Ac-P4-P3-P2-Asp-ACC, testing the approach on a family of closely related proteases – the human caspases. The power of this library for caspase discrimination extends far beyond traditional PS-SCL approach, as in addition to 19 natural amino acids we also used 110 diverse unnatural amino acids that can more extensively explore the chemical space represented by caspase-active sites. Using this approach we identified and employed peptide-based substrates that provided excellent discrimination between individual caspases, allowing us to simultaneously resolve the individual contribution of the apical caspase-9 and the executioner caspase-3 and caspase-7 in the development of cytochrome-c-dependent apoptosis for the first time.Apoptosis, the most well-understood form of programmed cell death, is a highly regulated process controlled and executed by proteolytic enzymes called caspases. The apoptotic process is somewhat hierarchical and caspases can be assigned as initiators (2, 8, 9, and 10) and executioners (3, 6, and 7).^{1, 2, 3} Apoptosis can be triggered extrinsically via ligation of a death receptor by its cognate ligands, leading to the activation of caspases 8 and 10, or intrinsically following the release of cytochrome c from mitochondria with formation of a caspase 9 activation complex known as the apoptosome.^{3, 4, 5} Mechanistically, caspases display a near absolute preference for aspartate at the P1 position of their substrates. In addition, they require a minimum substrate length of four amino acids N-terminal of the scissile bond. Thornberry et al.^{6, 7} used a combinatorial library of fluorogenic substrates to profile nine human caspases at the P4–P2 region, demonstrating that the caspases tended to have specificity profiles that enabled grouping based on substrate preferences.^{6, 7} This work provided a great insight into caspase recognition patterns and opened the door for others to pursue small molecule probes for caspase investigations.To date, various types of substrates and inhibitors have been developed and biologically evaluated against caspases.^{2, 8, 9, 10, 11} Unfortunately, most of them lack selectivity and cannot be used for selectively targeting or analyzing particular enzymes in complex biological environments.^{12, 13, 14, 15} This is entirely because of the overlapping specificities of the caspases on their preferred natural amino acid sequences. To address this problem we designed and synthesized a Hybrid Combinatorial Substrate Library (HyCoSuL) containing 19 natural amino acids (omitting cysteine) and 110 unnatural amino acids. We propose that such a large and varied set of chemical structures provides an excellent tool to investigate caspases and distinguish between them. In this work we dissected the kinetic profiles of six human apoptotic recombinant caspases through HyCoSuL screening. We then designed and synthesized new caspase substrates with the ability to discriminate these enzymes within a group. To further test the specificity and utility of the designed hybrid substrates, we performed a series of experiments in a cell-free model of apoptosis where multiple caspases are activated.     

Epidermal differentiation does not involve the pro-apoptotic executioner caspases, but is associated with caspase-14 induction and processing

The epidermis is a stratified squamous epithelium in which keratinocytes progressively undergo terminal differentiation towards the skin surface leading to programmed cell death. In this respect we studied the role of caspases. Here, we show that caspase-14 synthesis in the skin is restricted to differentiating keratinocytes and that caspase-14 processing is associated with terminal epidermal differentiation. The pro-apoptotic executioner caspases-3, -6, and -7 are not activated during epidermal differentiation. Caspase-14 does not participate in apoptotic pathways elicited by treatment of differentiated keratinocytes with various death-inducing stimuli, in contrast to caspase-3. In addition, we show that non-cornifying oral keratinocyte epithelium does not express caspase-14 and that the parakeratotic regions of psoriatic skin lesions contain very low levels of caspase-14 as compared to normal stratum corneum. These observations strongly suggest that caspase-14 is involved in the keratinocyte terminal differentiation program leading to normal skin cornification, while the executioner caspases are not implicated. Cell Death and Differentiation (2000) 7, 1218 - 1224     

Identification of early intermediates of caspase activation using selective inhibitors and activity-based probes

Caspases are cysteine proteases that are key effectors in apoptotic cell death. Currently, there is a lack of tools that can be used to monitor the regulation of specific caspases in the context of distinct apoptotic programs. We describe the development of highly selective inhibitors and active site probes and their applications to directly monitor executioner (caspase-3 and -7) and initiator (caspase-8 and -9) caspase activity. Specifically, these reagents were used to dissect the kinetics of caspase activation upon stimulation of apoptosis in cell-free extracts and intact cells. These studies identified a full-length caspase-7 intermediate that becomes catalytically activated early in the pathway and whose further processing is mediated by mature executioner caspases rather than initiator caspases. This form also shows distinct inhibitor sensitivity compared to processed caspase-7. Our data suggest that caspase-7 activation proceeds through a previously uncharacterized intermediate that is formed without cleavage of the intact zymogen.     

Caspase Functions in Cell Death and Disease

Caspases are a family of endoproteases that provide critical links in cell regulatory networks controlling inflammation and cell death. The activation of these enzymes is tightly controlled by their production as inactive zymogens that gain catalytic activity following signaling events promoting their aggregation into dimers or macromolecular complexes. Activation of apoptotic caspases results in inactivation or activation of substrates, and the generation of a cascade of signaling events permitting the controlled demolition of cellular components. Activation of inflammatory caspases results in the production of active proinflammatory cytokines and the promotion of innate immune responses to various internal and external insults. Dysregulation of caspases underlies human diseases including cancer and inflammatory disorders, and major efforts to design better therapies for these diseases seek to understand how these enzymes work and how they can be controlled.Caspases are a family of genes important for maintaining homeostasis through regulating cell death and inflammation. Here we will attempt to summarize what we currently know about how caspases normally work, and what happens when members of this diverse gene family fail to work correctly.Caspases are endoproteases that hydrolyze peptide bonds in a reaction that depends on catalytic cysteine residues in the caspase active site and occurs only after certain aspartic acid residues in the substrate. Although caspase-mediated processing can result in substrate inactivation, it may also generate active signaling molecules that participate in ordered processes such as apoptosis and inflammation. Accordingly, caspases have been broadly classified by their known roles in apoptosis (caspase-3, -6, -7, -8, and -9 in mammals), and in inflammation (caspase-1, -4, -5, -12 in humans and caspase-1, -11, and -12 in mice) (Fig. 1). The functions of caspase-2, -10, and -14 are less easily categorized. Caspases involved in apoptosis have been subclassified by their mechanism of action and are either initiator caspases (caspase-8 and -9) or executioner caspases (caspase-3, -6, and -7).Figure 1.Domain structure of human caspases.Caspases are initially produced as inactive monomeric procaspases that require dimerization and often cleavage for activation. Assembly into dimers is facilitated by various adapter proteins that bind to specific regions in the prodomain of the procaspase. The exact mechanism of assembly depends on the specific adapter involved. Different caspases have different protein–protein interaction domains in their prodomains, allowing them to complex with different adapters. For example, caspase-1, -2, -4, -5, and -9 contain a caspase recruitment domain (CARD), whereas caspase-8 and -10 have a death effector domain (DED) (Taylor et al. 2008).     

Identification of caspase-3 degradome by two-dimensional gel electrophoresis and matrix-assisted laser desorption/ionization-time of flight analysis

The activation of caspases is a critical event for the execution phase of programmed cell death. Caspases are highly specific in their ability to activate or inhibit many crucial proteins in the cell via site-specific cleavage. To date, more than 60 proteins have been shown to be substrates of one or more caspases in mammalian cells, and the list is still growing. In this study, to identify human caspase-3 substrates, we digested lysates obtained from a caspase-3-deficient MCF-7 cell line with purified caspase-3 and analyzed eliminated or decreased spots by 2-DE. Proteins degraded by caspase-3, termed as caspase-3 degradome, are involved in a variety of cellular functions, such as stress-responsive proteins, signaling molecules, structural proteins, and unclassified proteins. Interestingly, the cellular level of vinculin, a caspase-3 substrate, was dramatically reduced during the apoptotic process, where the expression level of caspase-3 was increased. This degradomic approach could provide a powerful tool in finding physiological substrates of many proteolytic enzymes whose functions remain to be determined.     

Effect of Hypoxia on Caspase-3, -8, and -9 Activity and Expression in the Cerebral Cortex of Newborn Piglets

Caspases play an important role in programmed cell death. Caspase-3 is a key executioner of apoptosis, whose activation is mediated by the initiator caspases, caspase-8 and caspase-9. The present study tested the hypothesis that cerebral hypoxia results in increased activation and expression of caspases-3, -8, and -9 in the cytosolic fraction of the cerebral cortex of newborn piglets. To test this hypothesis the activity and expression of caspases-3, -8, and -9 were determined in newborn piglets divided into normoxic and hypoxic groups. Caspase activity was determined spectrofluorometrically using enzyme specific substrates. The expression of caspase protein was assessed by Western blot analysis using enzyme specific antibody. Caspases-3, -8, and -9 activity and expression was significantly higher in the hypoxic group than in the normoxic group. These results demonstrate that hypoxia induces activation and increased expression of both the initiator caspases and the executioner caspase in the cerebral cortex of newborn piglets. We conclude that hypoxia results in stimulation of both the pathways of caspase-3 activation.     

Proteome-wide Substrate Analysis Indicates Substrate Exclusion as a Mechanism to Generate Caspase-7 Versus Caspase-3 Specificity

Caspase-3 and -7 are considered functionally redundant proteases with similar proteolytic specificities. We performed a proteome-wide screen on a mouse macrophage lysate using the N-terminal combined fractional diagonal chromatography technology and identified 46 shared, three caspase-3-specific, and six caspase-7-specific cleavage sites. Further analysis of these cleavage sites and substitution mutation experiments revealed that for certain cleavage sites a lysine at the P5 position contributes to the discrimination between caspase-7 and -3 specificity. One of the caspase-7-specific substrates, the 40 S ribosomal protein S18, was studied in detail. The RPS18-derived P6–P5′ undecapeptide retained complete specificity for caspase-7. The corresponding P6–P1 hexapeptide still displayed caspase-7 preference but lost strict specificity, suggesting that P′ residues are additionally required for caspase-7-specific cleavage. Analysis of truncated peptide mutants revealed that in the case of RPS18 the P4–P1 residues constitute the core cleavage site but that P6, P5, P2′, and P3′ residues critically contribute to caspase-7 specificity. Interestingly, specific cleavage by caspase-7 relies on excluding recognition by caspase-3 and not on increasing binding for caspase-7.Caspases, a family of evolutionarily conserved proteases, mediate apoptosis, inflammation, proliferation, and differentiation by cleaving many cellular substrates (1–3). The apoptotic initiator caspases (caspase-8, -9, and -10) are activated in large signaling platforms and propagate the death signal by cleavage-induced activation of executioner caspase-3 and -7 (4, 5). Most of the cleavage events occurring during apoptosis have been attributed to the proteolytic activity of these two executioner caspases, which can act on several hundreds of proteins (2, 3, 6, 7). The substrate degradomes of the two main executioner caspases have not been determined but their identification is important to gaining greater insight in their cleavage specificity and biological functions.The specificity of caspases was rigorously profiled by using combinatorial tetrapeptide libraries (8), proteome-derived peptide libraries (9), and sets of individual peptide substrates (10, 11). The results of these studies indicate that specificity motifs for caspase-3 and -7 are nearly indistinguishable with the canonical peptide substrate, DEVD, used to monitor the enzymatic activity of both caspase-3 and -7 in biological samples. This overlap in cleavage specificity is manifested in their generation of similar cleavage fragments from a variety of apoptosis-related substrates such as inhibitor of caspase-activated DNase, keratin 18, PARP,1 protein-disulfide isomerase, and Rho kinase I (for reviews, see Refs. 2, 3, and 7). This propagated the view that these two caspases have completely redundant functions during apoptosis. Surprisingly, mice deficient in one of these caspases (as well as mice deficient in both) have distinct phenotypes. Depending on the genetic background of the mice, caspase-3-deficient mice either die before birth (129/SvJ) or develop almost normally (C57BL/6J) (12–14). This suggests that dynamics in the genetic background, such as increased caspase-7 expression, compensate for the functional loss of caspase-3 (15). In the C57BL/6J background, caspase-7 single deficient mice are also viable, whereas caspase-3 and -7 double deficient mice die as embryos, further suggesting redundancy (12–14). However, because caspase-3 and -7 probably arose from gene duplication between the Cephalochordata-Vertebrata diversion (16), they might have acquired different substrate specificities during evolution. Caspase-3 and -7 do exhibit different activities on a few arbitrarily identified natural substrates, including BID, X-linked inhibitor of apoptosis protein, gelsolin, caspase-6, ataxin-7, and co-chaperone p23 (17–20). In addition, caspase-3 generally cleaves more substrates during apoptosis than caspase-7 and therefore appears to be the major executioner caspase. Moreover, a recent report describing caspase-1-dependent activation of caspase-7, but not of caspase-3, in macrophages in response to microbial stimuli supports the idea of a non-redundant function for caspase-7 downstream of caspase-1 (21).Commercially available “caspase-specific” tetrapeptide substrates are widely used for specific caspase detection, but they display substantial promiscuity and cannot be used to monitor individual caspases in cells (22, 23). Detecting proteolysis by measuring the release of C-terminal fluorophores, such as 7-amino-4-methylcoumarin (amc), restricts the specificity of these peptide substrates to non-prime cleavage site residues, which may have hampered the identification of specific cleavage events. To address this limitation, a recently developed proteomics technique, called proteomic identification of protease cleavage sites, was used to map both non-prime and prime preferences for caspase-3 and -7 on a tryptic peptide library (9). However, no clear distinction in peptide recognition motifs between caspase-3 and -7 could be observed (9). Because not all classical caspase cleavage sites are processed (7), structural or post-translational higher order constraints are likely involved in steering the cleavage site selectivity. Peptide-based approaches generally overlook such aspects.We made use of the COFRADIC N-terminal peptide sorting methodology (24–26) to profile proteolytic events of caspase-3 and -7 in a macrophage proteome labeled by triple stable isotope labeling by amino acids in cell culture (SILAC), which allowed direct comparison of peak intensities in peptide MS spectra and consequent quantification of N termini that are equally, preferably, or exclusively generated by the action of caspase-3 or -7 (26, 27). We identified 55 cleavage sites in 48 protein substrates, encompassing mutual, preferred, and unique caspase-3 and -7 cleavage sites.