Stability and oligomeric equilibria of refolded interleukin-1beta converting enzyme

Uncoupled pyroptosis and IL-1β secretion downstream of inflammasome signaling

Inflammasomes are supramolecular platforms that organize in response to various damage-associated molecular patterns and pathogen-associated molecular patterns. Upon activation, inflammasome sensors (with or without the help of ASC) activate caspase-1 and other inflammatory caspases that cleave gasdermin D and pro-IL-1β/pro-IL-18, leading to pyroptosis and mature cytokine secretion. Pyroptosis enables intracellular pathogen niche disruption and intracellular content release at the cost of cell death, inducing pro-inflammatory responses in the neighboring cells. IL-1β is a potent pro-inflammatory regulator for neutrophil recruitment, macrophage activation, and T-cell expansion. Thus, pyroptosis and cytokine secretion are the two main mechanisms that occur downstream of inflammasome signaling; they maintain homeostasis, drive the innate immune response, and shape adaptive immunity. This review aims to discuss the possible mechanisms, timing, consequences, and significance of the two uncoupling preferences downstream of inflammasome signaling. While pyroptosis and cytokine secretion may be usually coupled, pyroptosis-predominant and cytokine-predominant uncoupling are also observed in a stimulus-, cell type-, or context-dependent manner, contributing to the pathogenesis and development of numerous pathological conditions such as cryopyrin-associated periodic syndromes, LPS-induced sepsis, and Salmonella enterica serovar Typhimurium infection. Hyperactive cells consistently release IL-1β without LDH leakage and pyroptotic death, thereby leading to prolonged inflammation, expanding the lifespans of pyroptosis-resistant neutrophils, and hyperactivating stimuli-challenged macrophages, dendritic cells, monocytes, and specific nonimmune cells. Death inflammasome activation also induces GSDMD-mediated pyroptosis with no IL-1β secretion, which may increase lethality in vivo. The sublytic GSDMD pore formation associated with lower expressions of pyroptotic components, GSDMD-mediated extracellular vesicles, or other GSDMD-independent pathways that involve unconventional secretion could contribute to the cytokine-predominant uncoupling; the regulation of caspase-1 dynamics, which may generate various active species with different activities in terms of GSDMD or pro-IL-1β, could lead to pyroptosis-predominant uncoupling. These uncoupling preferences enable precise reactions to different stimuli of different intensities under specific conditions at the single-cell level, promoting cooperative cell and host fate decisions and participating in the pathogen "game". Appropriate decisions in terms of coupling and uncoupling are required to heal tissues and eliminate threats, and further studies exploring the inflammasome tilt toward pyroptosis or cytokine secretion may be helpful.

The intricate biophysical puzzle of caspase-1 activation

This review takes a closer look at the structural components of the molecules involved in the processes leading to caspase-1 activation. Interleukins 1β and 18 (IL-1β, IL-18) are well-known proinflammatory cytokines that are produced following cleavage of their respective precursor proteins by the cysteine protease caspase-1. Active caspase-1 is the final step of the NLRP3 inflammasome, a three-protein intracellular complex involved in inflammation and induction of pyroptosis (a proinflammatory cell-death process). NLRP3 activators facilitate assembly of the inflammasome complex and subsequent activation of caspase-1 by autoproteolysis. However, the definitive structural components of active caspase-1 are still unclear and new data add to the complexity of this process. This review outlines the historical and recent findings that provide supporting evidence for the structural aspects of caspase-1 autoproteolysis and activation.

A clear and present danger: inflammasomes DAMPing down disorders of pregnancy

BACKGROUND

When the normal progression of pregnancy is threatened, inflammatory processes are often amplified in order to minimize detrimental effects and eliminate noxious agents. Inflammasomes are unique, intracellular, multiprotein assemblies that enable caspase-1 mediated proteolytic processing of the proinflammatory cytokine interleukin-1β, levels of which are elevated in some forms of preterm birth and maternal metabolic disorders.

METHODS

A comprehensive review based on a search of PubMed and Medline for terms and combinations of terms incorporating 'inflammation', 'inflammasome', 'pregnancy', 'preterm birth', 'pre-eclampsia', 'interleukin-1', 'caspase-1' and others selected to capture key articles.

RESULTS

In the decade since the discovery of the inflammasome, between January 2002 and June 2014 over 2200 articles have been published. Articles in the reproductive field are scarce but there is clear evidence for a role of the inflammasome axis in pregnancy, preterm birth and the maternal metabolic syndrome.

CONCLUSION

Further investigations on the inflammasome in pregnancy are needed in order to elucidate the biology of this unique structure in reproduction. Coordination of maternal, fetal and placental aspects of inflammasome function will potentially yield new information on the detection and transduction of host and non-host signals in the inflammatory response.

A multipronged approach for compiling a global map of allosteric regulation in the apoptotic caspases

One of the most promising and as yet underutilized means of regulating protein function is exploitation of allosteric sites. All caspases catalyze the same overall reaction, but they perform different biological roles and are differentially regulated. It is our hypothesis that many allosteric sites exist on various caspases and that understanding both the distinct and overlapping mechanisms by which each caspase can be allosterically controlled should ultimately enable caspase-specific inhibition. Here we describe the ongoing work and methods for compiling a comprehensive map of apoptotic caspase allostery. Central to this approach are the use of (i) the embedded record of naturally evolved allosteric sites that are sensitive to zinc-mediated inhibition, phosphorylation, and other posttranslational modifications, (ii) structural and mutagenic approaches, and (iii) novel binding sites identified by both rationally-designed and screening-derived small-molecule inhibitors.

Extracellular acidosis is a novel danger signal alerting innate immunity via the NLRP3 inflammasome

BACKGROUND

Local acidosis has been demonstrated in ischemic tissues and at inflammatory sites.

RESULTS

Acidic extracellular pH triggers NLRP3 inflammasome activation and interleukin-1β secretion in human macrophages.

CONCLUSION

Acidic pH represents a novel danger signal alerting the innate immunity.

SIGNIFICANCE

Local acidosis may promote inflammation at ischemic and inflammatory sites. Local extracellular acidification has been demonstrated at sites of ischemia and inflammation. IL-1β is one of the key proinflammatory cytokines, and thus, its synthesis and secretion are tightly regulated. The NLRP3 (nucleotide-binding domain leucine-rich repeat containing family, pyrin domain containing 3) inflammasome complex, assembled in response to microbial components or endogenous danger signals, triggers caspase-1-mediated maturation and secretion of IL-1β. In this study, we explored whether acidic environment is sensed by immune cells as an inflammasome-activating danger signal. Human macrophages were exposed to custom cell culture media at pH 7.5-6.0. Acidic medium triggered pH-dependent secretion of IL-1β and activation of caspase-1 via a mechanism involving potassium efflux from the cells. Acidic extracellular pH caused rapid intracellular acidification, and the IL-1β-inducing effect of acidic medium could be mimicked by acidifying the cytosol with bafilomycin A1, a proton pump inhibitor. Knocking down the mRNA expression of NLRP3 receptor abolished IL-1β secretion at acidic pH. Remarkably, alkaline extracellular pH strongly inhibited the IL-1β response to several known NLRP3 activators, demonstrating bipartite regulatory potential of pH on the activity of this inflammasome. The data suggest that acidic environment represents a novel endogenous danger signal alerting the innate immunity. Low pH may thus contribute to inflammation in acidosis-associated pathologies such as atherosclerosis and post-ischemic inflammatory responses.

Substrate and inhibitor-induced dimerization and cooperativity in caspase-1 but not caspase-3

Caspases are intracellular cysteine-class proteases with aspartate specificity that is critical for driving processes as diverse as the innate immune response and apoptosis, exemplified by caspase-1 and caspase-3, respectively. Interestingly, caspase-1 cleaves far fewer cellular substrates than caspase-3 and also shows strong positive cooperativity between the two active sites of the homodimer, unlike caspase-3. Biophysical and kinetic studies here present a molecular basis for this difference. Analytical ultracentrifugation experiments show that mature caspase-1 exists predominantly as a monomer under physiological concentrations that undergoes dimerization in the presence of substrate; specifically, substrate binding shifts the KD for dimerization by 20-fold. We have created a hemi-active site-labeled dimer of caspase-1, where one site is blocked with the covalent active site inhibitor, benzyloxycarbonyl-Val-Ala-Asp-fluoromethylketone. This hemi-labeled enzyme is about 9-fold more active than the apo-dimer of caspase-1. These studies suggest that substrate not only drives dimerization but also, once bound to one site in the dimer, promotes an active conformation in the other monomer. Steady-state kinetic analysis and modeling independently support this model, where binding of one substrate molecule not only increases substrate binding in preformed dimers but also drives the formation of heterodimers. Thus, the cooperativity in caspase-1 is driven both by substrate-induced dimerization as well as substrate-induced activation. Substrate-induced dimerization and activation seen in caspase-1 and not in caspase-3 may reflect their biological roles. Whereas caspase-1 cleaves a dramatically smaller number of cellular substrates that need to be concentrated near inflammasomes, caspase-3 is a constitutively active dimer that cleaves many more substrates located diffusely throughout the cell.

Caspase-1 promiscuity is counterbalanced by rapid inactivation of processed enzyme

Members of the caspase family of cysteine proteases coordinate the highly disparate processes of apoptosis and inflammation. However, although hundreds of substrates for the apoptosis effector caspases (caspase-3 and caspase-7) have been identified, only two confirmed substrates for the key inflammatory protease (caspase-1) are known. Whether this reflects intrinsic differences in the substrate specificity of inflammatory versus apoptotic caspases or their relative abundance in vivo is unknown. To address this issue, we have compared the specificity of caspases-1, -3, and -7 toward peptide and protein substrates. Contrary to expectation, caspase-1 displayed concentration-dependent promiscuity toward a variety of substrates, suggesting that caspase-1 specificity is maintained by restricting its abundance. Although endogenous concentrations of caspase-1 were found to be similar to caspase-3, processed caspase-1 was found to be much more labile, with a half-life of ∼9 min. This contrasted sharply with the active forms of caspase-3 and caspase-7, which exhibited half-lives of 8 and 11 h, respectively. We propose that the high degree of substrate specificity displayed by caspase-1 is maintained through rapid spontaneous inactivation of this protease.

Apoptotic caspase activation and activity

Caspases are central to the execution of apoptosis. Their proteolytic activity is responsible for the demise of cells in many physiological and pathological states. Great advances in understanding caspases have been made using recombinant caspase expression and enzymatic characterization. Assays to measure caspase activity in apoptotic cell extracts and the development of a reconstituted cell-free assay were also critical in establishing the hierarchy in the caspase activation cascade and comprehend how caspase-9 is activated by the apoptosome. More recently, new tools such as activity-based probes allowed us to detect caspase activation in their working environment providing readout of the system with minimal interference. This chapter describes some of the methods used by our group to study the activation mechanisms of caspases and their activity.

Cytokine response modifier a inhibition of initiator caspases results in covalent complex formation and dissociation of the caspase tetramer

Active caspases are generally composed of two catalytic domains, each containing a large (p20) and a small (p10) subunit so that a fully active caspase has the organization (p20-p10)(2). The cowpox serpin crmA suppresses host apoptosis and inflammation by inhibiting endogenous caspases. We report on the mechanism crmA uses to inhibit caspases 1, 6, and 8. Native PAGE showed formation of tight crmA-caspase complexes. Matrix-assisted laser desorption ionization time-of-flight mass spectrometry provided evidence for a covalent crmA-p20 thioester linkage. SDS-PAGE of isolated complexes showed near complete loss of the p10 subunit from initiator caspases 1 and 8 but not from the executioner caspase-6. This was confirmed for caspase-1 by sequencing and Western blotting. Size exclusion chromatography indicated a size of approximately 60 kDa for complexes with caspases 1 and 8, consistent with a crmA.p20 species, suggesting that the p20-p10 interface and possibly the p10-p10 interface had been disrupted. In contrast, crmA.caspase-6 complex behaved as an equilibrium mixture of crmA(2).(p20-p10)(2) and crmA.(p20-p10). Complex deacylation rates were all slow, suggesting effective kinetic trapping of the covalent thioacyl intermediate. These results suggest a novel serpin inhibition mechanism through which crmA down-regulates apoptosis and inflammation. This involves (i) rapid formation of covalent complex with initiator caspases 8 or 1, (ii) very slow deacylation, and (iii) loss of the caspase p10 subunit for initiator but not for executioner caspases, so that any free p20 formed by deacylation of initiator caspases cannot reassociate to active heterotetramer, thus resulting in irreversible inhibition of apoptosis and inflammation.

The apoptosome activates caspase-9 by dimerization

The apical protease of the human intrinsic apoptotic pathway, caspase-9, is activated in a polymeric activation platform known as the apoptosome. The mechanism has been debated, and two contrasting hypotheses have been suggested. One of these postulates an allosteric activation of monomeric caspase-9; the other postulates a dimer-driven assembly at the surface of the apoptosome--the "induced proximity" model. We show that both Hofmeister salts and a reconstituted mini-apoptosome activate caspase-9 by a second-order process, compatible with a conserved dimer-driven process. Significantly, replacement of the recruitment domain of the apical caspase of the extrinsic apoptotic pathway, caspase-8, by that of caspase-9 allows activation of this hybrid caspase by the apoptosome. Consequently, apical caspases can be activated simply by directing their zymogens to the apoptosome, ruling out the requirement for allosteric activation and supporting an induced proximity dimerization model for apical caspase activation in vivo.

Ionic interactions near the loop L4 are important for maintaining the active-site environment and the dimer stability of (pro)caspase 3

We have examined the role of a salt bridge between Lys242 and Glu246 in loop L4 of procaspase 3 and of mature caspase 3, and we show that the interactions are required for stabilizing the active site. Replacing either of the residues with an alanine residue results in a complete loss of procaspase 3 activity. Although both mutants are active in the context of the mature caspase 3, the mutations result in an increase in K(m) and a decrease in kcat when compared with the wild-type caspase 3. In addition, the mutations result in an increase in the pK(a) value associated with a change in kcat with pH, but does not affect the transition observed for Km versus pH. The mutations also affect the accessibility of the active-site solvent as measured by tryptophan fluorescence emission in the presence of quenching agents and as a function of pH. We show that, as the pH is lowered, the (pro)caspase dissociates, and the mutations increase the pH-dependent instability of the dimer. Overall, the results suggest that the contacts lost in the procaspase as a result of replacing Lys242 and Glu246 are compensated partially in the mature caspase as a result of new contacts that are known to form on zymogen processing

Folding pathways for initiator and effector procaspases from computer simulations

The folding pathways of procaspases 3, 7, and 8 have been studied using a Go-like Hamiltonian and molecular dynamics simulations coupled with a parallel tempering scheme. The folding pathways and the overall structures of procaspases 3 and 7 are similar, and are characterized by monomeric as well as dimeric folding intermediates in agreement with the available structural and thermochemical data. The folding pathway of procaspase 8, on the other hand, is characterized by a larger population of monomers and partially folded dimer intermediates, and only a relatively small population of folded dimer species. The most stable structure predicted for procaspase 8 is a dimer, in which the position of the linker is remarkably different from the one observed in procaspases 3 and 7, leading to the fact that all the contacts that stabilize the active site are essentially formed. This novel and unexpected structure provides a rationale for the observed activity of the procaspase 8 dimer, and thus could be highly relevant for the initiation of FAS-mediated apoptosis.

The protein structures that shape caspase activity, specificity, activation and inhibition

The death morphology commonly known as apoptosis results from a post-translational pathway driven largely by specific limited proteolysis. In the last decade the structural basis for apoptosis regulation has moved from nothing to 'quite good', and we now know the fundamental structures of examples from the initiator phase, the pre-mitochondrial regulator phase, the executioner phase, inhibitors and their antagonists, and even the structures of some substrates. The field is as well advanced as the best known of proteolytic pathways, the coagulation cascade. Fundamentally new mechanisms in protease regulation have been disclosed. Structural evidence suggests that caspases have an unusual catalytic mechanism, and that they are activated by apparently unrelated events, depending on which position in the apoptotic pathway they occupy. Some naturally occurring caspase inhibitors have adopted classic inhibition strategies, but other have revealed completely novel mechanisms. All of the structural and mechanistic information can, and is, being applied to drive therapeutic strategies to combat overactivation of apoptosis in degenerative disease, and underactivation in neoplasia. We present a comprehensive review of the caspases, their regulators and inhibitors from a structural and mechanistic point of view, and with an aim to consolidate the many threads that define the rapid growth of this field.

Geranylgeraniol regulates negatively caspase-1 autoprocessing: implication in the Th1 response against Mycobacterium tuberculosis

Caspase-1 is a cysteine protease composed by two 20-kDa and two 10-kDa subunits that processes pro-IL-1beta and pro-IL-18 to their mature forms. This enzyme is present in cells as a latent zymogen that becomes active through a tightly regulated proteolytic cascade. Activation is initiated by the oligomerization of an adaptor molecule, or by the formation of a multiprotein complex named inflammasome. Negative regulation of caspase-1 activation is exerted by proteins that compete with the adaptor molecule or with the inflammasome formation. We previously reported that fluvastatin, an inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A reductase, increases caspase-1 activity in PBMC. This effect was strengthened by Mycobacterium tuberculosis, rending an exacerbated IL-1beta, IL-18, and IFN-gamma production. Mevalonate, the product of 3-hydroxy-3-methylglutaryl coenzyme A reductase, is a precursor for both nonsterol isoprenoid and sterol formation. In this study, we studied the involvement of mevalonate derivatives in the regulation of caspase-1 activation. Inhibition of sterol formation by SKF-104976 or haloperidol had no effect on IL-1beta release. However, the isoprenoid geranylgeraniol prevented both caspase-1 activation and the exacerbated IL production induced by fluvastatin. This isoprenoid significantly reduced the release of IL-18 and IFN-gamma by PBMC treated with mycobacteria, even in the absence of fluvastatin. In correlation with the increased caspase-1 activity, fluvastatin stimulated the proforms cleavage, enhancing the formation of active subunit p10. Geranylgeraniol not only prevented this effect, but induced proforms accumulation. Present results suggest that, once the proteolytic cascade is initiated, geranylgeraniol may exert an additional negative regulation on caspase-1 cleavage process.

Role of caspases in the regulation of apoptotic pancreatic islet beta-cells death

The homeostatic control of beta-cell mass in normal and pathological conditions is based on the balance of proliferation, differentiation, and death of the insulin-secreting cells. A considerable body of evidence, accumulated during the last decade, has emphasized the significance of the disregulation of the mechanisms regulating the apoptosis of beta-cells in the sequence of events that lead to the development of diabetes. The identification of agents capable of interfering with this process needs to be based on a better understanding of the beta-cell specific pathways that are activated during apoptosis. The aim of this article is fivefold: (1) a review of the evidence for beta-cell apoptosis in Type I diabetes, Type II diabetes, and islet transplantation, (2) to review the common stimuli and their mechanisms in pancreatic beta-cell apoptosis, (3) to review the role of caspases and their activation pathway in beta-cell apoptosis, (4) to review the caspase cascade and morphological cellular changes in apoptotic beta-cells, and (5) to highlight the putative strategies for preventing pancreatic beta-cells from apoptosis.

Molecular dynamics simulations of structural changes during procaspase 3 activation

Molecular dynamics (MD) simulations of the structural rearrangements on the pathway leading to procaspase 3 activation are presented. A retrostructural approach is used to build procaspase 3 from mature caspase 3. The peptide bond that is cleaved during enzyme maturation is gradually reformed during the MD simulation and the most relevant structural changes that occur as a consequence are analyzed. The main structural features that characterize this procaspase 3 model are compared with the available X-ray structure of procaspase 7 as the only zymogen structure that has been crystallised so far. The MD simulations indicate that in the free caspase 3, the flexible selectivity loop is already preorganized to accomodate the substrate. Such a preorganization is not present in either monomeric caspase 3 or in the procaspase 3 dimer, indicating that the structure of the selectivity loop is highly sensitive to perturbations.

Crystal structure of caspase-2, apical initiator of the intrinsic apoptotic pathway

The cell death protease caspase-2 has recently been recognized as the most apical caspase in the apoptotic cascade ignited during cell stress signaling. Cytotoxic stress, such as that caused by cancer therapies, leads to activation of caspase-2, which acts as a direct effector of the mitochondrion-dependent apoptotic pathway resulting in programmed cell death. Here we report the x-ray structure of caspase-2 in complex with the inhibitor acetyl-Leu-Asp-Glu-Ser-Asp-aldehyde at 1.65-A resolution. Compared with other caspases, significant structural differences prevail in the active site region and the dimer interface. The structure reveals the hydrophobic properties of the S5 specificity pocket, which is unique to caspase-2, and provides the details of the inhibitor-protein interactions in subsites S1-S4. These features form the basis of caspase-2 specificity and allow the design of caspase-2-directed ligands for medical and analytical use. Another unique feature of caspase-2 is a disulfide bridge at the dimer interface, which covalently links the two monomers. Consistent with this finding, caspase-2 exists as a (p19/p12)2 dimer in solution, even in the absence of substrates or inhibitors. The intersubunit disulfide bridge stabilizes the dimeric form of caspase-2, whereas all other long prodomain caspases exist as monomers in solution, and dimer formation is driven by ligand binding. Therefore, the central disulfide bridge appears to represent a novel way of dimer stabilization in caspases.

Structure-based thermodynamic analysis of caspases reveals key residues for dimerization and activity

Cysteine-dependent aspartic proteases (caspases) are a family of enzymes which play a crucial role in apoptosis. Caspases accumulate in eukaryotic cells in the form of low-activity proenzyme precursors. Proteolytic cleavage of specific sites triggers conformational changes that lead to full activation and thus to the initiation of the apoptotic cascade. Several experimental observations suggest that dimerization is crucial for activity and regulation, but the underlying molecular mechanisms have not yet been completely resolved. In this work, we have used a structure-based thermodynamic analysis method [Edgcomb, S. P., and Murphy, K. P. (2000) Curr. Opin. Biotechnol. 11, 62-66] to calculate the free energy of association and folding for all the caspases and procaspases whose structures are known at present. In all cases, analysis of the single-residue contributions to the dimerization energy shows that 30-50% of the dimer stability originates from the highly specific interaction of 12-14 residues located at the N- and C-termini of the large and small subunits, respectively. Moreover, our calculations indicate that these residues are also critical for stabilizing the conformation of the active site loops, which in turn is crucial for the binding of substrates and inhibitors. Thus, our results help to rationalize the relation between dimerization and activity in this important class of enzymes and can be used as a starting point for an active manipulation of the monomer-dimer equilibrium for preparatory and regulatory purposes.

Molecular dynamics studies of caspase-3

Caspase-3 is a fundamental target for pharmaceutical interventions against a variety of diseases involving disregulated apoptosis. The enzyme is active as a dimer with two symmetry-related active sites, each featuring a Cys-His catalytic dyad and a selectivity loop, which recognizes the characteristic DEVD pattern of the substrate. Here, a molecular dynamics study of the enzyme in complex with two pentapeptide substrates DEVDG is presented, which provides a characterization of the dynamic properties of the active form in aqueous solution. The mobility of the substrate and that of the catalytic residues are rather low indicating a distinct preorganization effect of the Michaelis complex. An essential mode analysis permits us to identify coupled motions between the two monomers. In particular, it is found that the motions of the two active site loops are correlated and tend to steer the substrate toward the reactive center, suggesting that dimerization has a distinct effect on the dynamic properties of the active site regions. The selectivity loop of one monomer turns out to be correlated with the N-terminal region of the p12 subunit of the other monomer, an interaction that is also found to play a fundamental role in the electrostatic stabilization of the quaternary structure. To further characterize the specific influence of dimerization on the enzyme essential motions, a molecular dynamics analysis is also performed on the isolated monomer.

Insights into the regulatory mechanism for caspase-8 activation

In the death receptor induced apoptotic pathway, caspase-8 autocatalytically cleaves itself at specific cleavage sites. To better understand the regulatory mechanisms behind caspase-8 activation, we compared active wild-type caspase-8 (wtC8) and an uncleavable form of procaspase-8 (uncleavable C8). We demonstrate that wtC8 predominantly exists as a monomer and dimerizes in a concentration and inhibitor binding-dependent fashion. The K(D) for dimeric wtC8 is approximately 50 micro M and decreases when inhibitor bound. Uncleavable C8 is mainly monomeric, but a small amount that dimerizes is as active as wtC8. Inhibitor binding does not favor dimerization but induces active site rearrangements in uncleavable C8. Our findings suggest that dimerization is the crucial factor for caspase-8 activation.

Dimer formation drives the activation of the cell death protease caspase 9

A critical step in the induction of apoptosis is the activation of the apoptotic initiator caspase 9. We show that at its normal physiological concentration, caspase 9 is primarily an inactive monomer (zymogen), and that activity is associated with a dimeric species. At the high concentrations used for crystal formation, caspase 9 is dimeric, and the structure reveals two very different active-site conformations within each dimer. One site closely resembles the catalytically competent sites of other caspases, whereas in the second, expulsion of the "activation loop" disrupts the catalytic machinery. We propose that the inactive domain resembles monomeric caspase 9. Activation is induced by dimerization, with interactions at the dimer interface promoting reorientation of the activation loop. These observations support a model in which recruitment by Apaf-1 creates high local concentrations of caspase 9 to provide a pathway for dimer-induced activation.

[W206R]-procaspase 3: an inactivatable substrate for caspase 8

We report here the cloning and high-level expression of a soluble proform of human caspase 3 (Ser(24)-H(277)) engineered to contain a short stretch of N-terminal sequence (MTISDSPREQD) from the prosegment of procaspase 8 and a C-terminal heptahistidine tag. The precursor protein isolated from extracts of recombinant Escherichia coli by immobilized metal-ion affinity chromatography was predominantly unprocessed and migrated as a 32-kDa polypeptide on sodium dodecyl sulfate-polyacrylamide gels. Incubation of this protein with recombinant human caspase 8 produced fragments characteristic of the properly processed caspase 3, but the product was inactive. Amino-terminal sequence analysis of the caspase 3 polypeptides proved that caspase 8 had specifically cleaved the Asp(175)-Ser(176) bond to yield the expected p18 and p12 subunits, with partial cleavage at the Asp(28)-Ser(29) bond to release the prosegment. The lack of caspase 3 activity was found to be the result of a fortuitous mutation in which Trp(206) in the S4 subsite was replaced by arginine (W206R). This mutant procaspase 3, which we call m-pro3, serves as a useful reagent with which to test the efficacy of caspase 8 inhibitors in blocking processing of the natural polypeptide substrate of this enzyme and may be valuable as a source of "proenzyme" for crystallographic analysis.

Caspase 8: an efficient method for large-scale autoactivation of recombinant procaspase 8 by matrix adsorption and characterization of the active enzyme

A gene coding for a truncated form of human procaspase 8 has been cloned and expressed in Escherichia coli. This construct contains M(206) through D(479) of human procaspase 8, preceded by an N-terminal polyhistidine tag. The recombinant protein, containing 286 amino acids, was expressed in high yield in the form of inclusion bodies (IB). The IB were solubilized in guanidinium chloride and dialyzed against 50% acetic acid. The solution was mixed with 9 volumes of H(2)O and then rapidly diluted from the acidic medium to one containing 1.0 M Tris, pH 8.0, and 5 mM DTT. SDS-PAGE analysis of the soluble, dilute protein solution (20-30 microgram of protein/ml) showed a single 33-kDa band corresponding to the nonprocessed, inactive procaspase 8. Concentration of the dilute protein to levels as high as 2 mg/ml resulted in only modest (1-10%) autocatalytic conversion to the 19- and 11-kDa polypeptide subunits which are characteristic of the activated enzyme. Further concentration of these protein solutions to a near-dry state on the ultrafiltration membrane, followed by washing of the membrane with buffer, led to extracts containing high yields of enzyme showing a specific activity of 8.43 micromol/min/mg against the chromogenic substrate Ac-IETD-pNA. SDS-PAGE, protein sequencing, and mass spectrometric analysis of these extracts showed complete conversion of the 33-kDa procaspase 8 to the 19- and 11-kDa subunits of activated caspase 8. This method allows for preparation of 100-mg quantities of highly pure and active recombinant human caspase 8. Enzyme activity was shown to be associated with a heterotetrameric complex that is converted to an inactive dimer upon storage.

Partial purification and characterization of two distinct types of caspases from human epidermis

Recent observations demonstrated that interleukin-1beta converting enzyme family proteases, now referred to as caspase family, play central roles in apoptosis, or programmed cell death. In this study, we tried to isolate and characterize epidermal caspases. By DEAE-Sephacel anion-exchange chromatography, human cornified cell extract showed two caspase-like fractions (F-I and F-II) with different substrate specificities. These were further purified by Sephacryl S-200, Mono Q ion exchange and Superose 6 gel chromatography. F-I showed a molecular weight of 30 kDa and specifically hydrolyzed acetyl-Asp-Glu-Val-Asp-methylcoumarinamide, a fluorogenic substrate for caspase-3 (CPP32) with a Km value of 13.8 microM. F-I generated a characteristic 85 kDa fragment from poly(ADP-ribose) polymerase. Inhibitor susceptibility of F-I was very similar to that of caspase-3, further confirming the caspase-3-like properties of F-I. In contrast, the molecular weight of F-II was estimated to be 110 kDa, which was much higher than the other caspases. F-II equally hydrolyzed acetyl-Asp-Glu-Val-Asp-methylcoumarinamide, and acetyl-Tyr-Val-Ala-Asp-methylcoumarinamide, caspase-1 (interleukin-1beta converting enzyme)-specific substrate, and was inhibited by acetyl-Tyr-Val-Ala-Asp-aldehyde and acetyl-Tyr-Val-Ala-Asp-aldehyde. Affinity labeling using biotinylated YVAD-cmk demonstrated several positive bands ranging from 25 to 35 kDa, supporting the hypothesis that F-II is a complex of multiple caspases. Reverse transcriptase-polymerase chain reaction analysis demonstrated that among known caspases tested, caspase-1, -2, -3, -4, and -7 were expressed in cultured human keratinocytes. These results suggest that multiple caspases are synthesized in human keratinocytes and are involved in terminal differentiation.

ICE family proteases in inflammation and apoptosis

The interleukin-1 beta converting enzyme (ICE) was first identified as a unique cysteine protease that processes the inactive precursor of the pro-inflammatory cytokine IL-1 beta to its mature active form. Subsequent revelation that a C. elegans cell death gene ced-3 bears sequence homology to ICE has led to rapid identification of at least nine other members of this gene family in humans, some of which are involved in apoptosis. Analyses of ICE-deficient mice generated by gene targeting technology reveal that this enzyme is important in maturation of several cytokines. The ICE deficient mice are resistant in several models of localized and systemic inflammation. ICE itself, however, is not required for Fas-mediated apoptosis, a physiological process for elimination of activated lymphocytes. Selective inhibitors of ICE would be novel therapeutic agents for treatment of diseases where excess inflammation contributes to pathological processes.

Biochemical characteristics of caspases-3, -6, -7, and -8

The observation that the nematode cell death effector gene product Ced-3 is homologous to human interleukin-1beta-converting enzyme (caspase-1) has led to the discovery of at least nine other human caspases, many of which are implicated as mediators of apoptosis. Significant interest has been given to aspects of the cell biology and substrate specificity of this family of proteases; however, quantitative descriptions of their biochemical characteristics have lagged behind. We describe the influence of a number of environmental parameters, including pH, ionic strength, detergent, and specific ion concentrations, on the activity and stability of four caspases involved in death receptor-mediated apoptosis. Based on these observations, we recommend the following buffer as optimal for investigation of their characteristics in vitro: 20 mM piperazine-N,N'-bis(2-ethanesulfonic acid) (PIPES), 100 mM NaCl, 10 mM dithiothreitol, 1 mM EDTA, 0.1% 3-[(3-cholamidopropyl)dimethylammonio]-2-hydroxy-1-propanesulfonic acid (CHAPS), 10% sucrose, pH 7.2. Caspase activity is not affected by concentrations of Ca2+ below 100 mM, but is abolished by Zn2+ in the submicromolar range, a common characteristic of cysteine proteases. Optimal pH values vary from 6.8 for caspase-8 to 7.4 for caspase-3, and activity of all is relatively stable between 0 and 150 mM NaCl. Consequently, changes in the physiologic pH and ionic strength would not significantly alter the activity of the enzymes, inasmuch as all four caspases are optimally active within the range of these parameters found in the cytosol of living and dying human cells.

Substrate specificities of caspase family proteases

The caspase family represents a new class of intracellular cysteine proteases with known or suspected roles in cytokine maturation and apoptosis. These enzymes display a preference for Asp in the P1 position of substrates. To clarify differences in the biological roles of the interleukin-1beta converting enzyme (ICE) family proteases, we have examined in detail the specificities beyond the P1 position of caspase-1, -2, -3, -4, -6, and -7 toward minimal length peptide substrates in vitro. We find differences and similarities between the enzymes that suggest a functional subgrouping of the family different from that based on overall sequence alignment. The primary specificities of ICE homologs explain many observed enzyme preferences for macromolecular substrates and can be used to support predictions of their natural function(s). The results also suggest the design of optimal peptidic substrates and inhibitors.

Preparation of an autolysis-resistant interleukin-1 beta converting enzyme mutant

We describe the expression, purification, and characterization of human interleukin-1 beta converting enzyme (ICE) containing an affinity tag and modified to resist autoproteolysis. The point mutation Asp381 to Glu was added to eliminate the major site of autolytic degradation while maintaining catalytic activity, and an N-terminal polyhistidine tag was added in place of the ICE pro-region to facilitate purification. N-His (D381E) ICE was expressed in Escherichia coli and purified by nickel-chelating Sepharose and size-exclusion chromatography (SEC). The enzyme was stabilized greater than 80-fold against autolytic degradation relative to wild-type N-His ICE. SDS-PAGE analysis with silver-staining revealed no impurities, and 85% of the protein was catalytically active as determined by titration with a novel titrant, PD 163594 (3-[2-(2-benzyloxycarbonylamino-3-methylbutyrylamino)prop ionylamino]-4- oxo-5-(2-oxo-2H-chromen-7-yloxypentanoic acid). An oxidized adduct of ICE with glutathione, formed by disulfide rearrangement with oxidized glutathione to inhibit and stabilize the enzyme during purification, was rapidly reduced upon exposure to 5 mM DTT. One mole of glutathione was released per mole of active enzyme. Of the nine cysteines in ICE, eight were present in their reduced form in the glutathione adduct. N-His (D381E) ICE cleaved Ac-YVAD-Amc with the Michaelis-Menten parameters K(M) = 14 microM and Kcat = 0.7 s-1, values essentially identical to those reported for enzyme from natural sources.