SMART: CASc domain annotation

CASc Caspase, interleukin-1 beta converting enzyme (ICE) homologues

SMART accession number:	SM00115
Description:	Cysteine aspartases that mediate programmed cell death (apoptosis). Caspases are synthesised as zymogens and activated by proteolysis of the peptide backbone adjacent to an aspartate. The resulting two subunits associate to form an (alpha)2(beta)2-tetramer which is the active enzyme. Activation of caspases can be mediated by other caspase homologues.
Interpro abstract (IPR015917):	In the MEROPS database peptidases and peptidase homologues are grouped into clans and families. Clans are groups of families for which there is evidence of common ancestry based on a common structural fold: Each clan is identified with two letters, the first representing the catalytic type of the families included in the clan (with the letter 'P' being used for a clan containing families of more than one of the catalytic types serine, threonine and cysteine). Some families cannot yet be assigned to clans, and when a formal assignment is required, such a family is described as belonging to clan A-, C-, M-, N-, S-, T- or U-, according to the catalytic type. Some clans are divided into subclans because there is evidence of a very ancient divergence within the clan, for example MA(E), the gluzincins, and MA(M), the metzincins. Peptidase families are grouped by their catalytic type, the first character representing the catalytic type: A, aspartic; C, cysteine; G, glutamic acid; M, metallo; N, asparagine; S, serine; T, threonine; and U, unknown. The serine, threonine and cysteine peptidases utilise the amino acid as a nucleophile and form an acyl intermediate - these peptidases can also readily act as transferases. In the case of aspartic, glutamic and metallopeptidases, the nucleophile is an activated water molecule. In the case of the asparagine endopeptidases, the nucleophile is asparagine and all are self-processing endopeptidases. In many instances the structural protein fold that characterises the clan or family may have lost its catalytic activity, yet retain its function in protein recognition and binding. Cysteine peptidases have characteristic molecular topologies, which can be seen not only in their three-dimensional structures, but commonly also in the two-dimensional structures. These are peptidases in which the nucleophile is the sulphydryl group of a cysteine residue. Cysteine proteases are divided into clans (proteins which are evolutionary related), and further sub-divided into families, on the basis of the architecture of their catalytic dyad or triad [(PUBMED:11517925)]. This group of sequences represent the core of p45 (45 kDa) precursor of caspases, which can be processed to produce the active p20 (20 kDa) and p10 (10 kDa) subunits. Caspases (Cysteine-dependent ASPartyl-specific proteASE) are cysteine peptidases that belong to the MEROPS peptidase family C14 (caspase family, clan CD) based on the architecture of their catalytic dyad or triad [(PUBMED:11517925)]. Caspases are tightly regulated proteins that require zymogen activation to become active, and once active can be regulated by caspase inhibitors. Activated caspases act as cysteine proteases, using the sulphydryl group of a cysteine side chain for catalysing peptide bond cleavage at aspartyl residues in their substrates. The catalytic cysteine and histidine residues are on the p20 subunit after cleavage of the p45 precursor. Caspases are mainly involved in mediating cell death (apoptosis) [(PUBMED:10578171), (PUBMED:10872455), (PUBMED:15077141)]. They have two main roles within the apoptosis cascade: as initiators that trigger the cell death process, and as effectors of the process itself. Caspase-mediated apoptosis follows two main pathways, one extrinsic and the other intrinsic or mitochondrial-mediated. The extrinsic pathway involves the stimulation of various TNF (tumour necrosis factor) cell surface receptors on cells targeted to die by various TNF cytokines that are produced by cells such as cytotoxic T cells. The activated receptor transmits the signal to the cytoplasm by recruiting FADD, which forms a death-inducing signalling complex (DISC) with caspase-8. The subsequent activation of caspase-8 initiates the apoptosis cascade involving caspases 3, 4, 6, 7, 9 and 10. The intrinsic pathway arises from signals that originate within the cell as a consequence of cellular stress or DNA damage. The stimulation or inhibition of different Bcl-2 family receptors results in the leakage of cytochrome c from the mitochondria, and the formation of an apoptosome composed of cytochrome c, Apaf1 and caspase-9. The subsequent activation of caspase-9 initiates the apoptosis cascade involving caspases 3 and 7, among others. At the end of the cascade, caspases act on a variety of signal transduction proteins, cytoskeletal and nuclear proteins, chromatin-modifying proteins, DNA repair proteins and endonucleases that destroy the cell by disintegrating its contents, including its DNA. The different caspases have different domain architectures depending upon where they fit into the apoptosis cascades, however they all carry the catalytic p10 and p20 subunits. Caspases can have roles other than in apoptosis, such as caspase-1 (interleukin-1 beta convertase) (EC 3.4.22.36), which is involved in the inflammatory process. The activation of apoptosis can sometimes lead to caspase-1 activation, providing a link between apoptosis and inflammation, such as during the targeting of infected cells. Caspases may also be involved in cell differentiation [(PUBMED:15066636)].
GO process:	apoptotic process (GO:0006915)
GO function:	cysteine-type peptidase activity (GO:0008234)
Family alignment:	View or

There are 712 CASc domains in 710 proteins in SMART's nrdb database.

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Evolution (species in which this domain is found)
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This tree shows only several representative species. The complete taxonomic breakdown of all proteins with CASc domain is also avaliable.

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Go to specific node: Anopheles gambiae, Caenorhabditis elegans, Drosophila melanogaster, Homo sapiens, Mus musculus, Rattus norvegicus, Takifugu rubripes
Literature (relevant references for this domain)
Primary literature is listed below; Automatically-derived, secondary literature is also avaliable.
- Liang H, Fesik SW
- Three-dimensional structures of proteins involved in programmed cell death.
- J Mol Biol. 1997; 274: 291-302
- Display abstract
- Programmed cell death (apoptosis) is a controlled process by which unwanted cells are selectively eliminated. Several families of proteins including the Bcl-2, tumor necrosis factor receptor 1, and caspase families play essential roles in the regulation, signaling, and execution of the genetic cell death program. The recently described three-dimensional structures of members of these families elucidate the structural basis of their functions and provide insights into the mechanisms by which these proteins regulate apoptosis.
- Miller DK, Myerson J, Becker JW
- The interleukin-1 beta converting enzyme family of cysteine proteases.
- J Cell Biochem. 1997; 64: 2-10
- Display abstract
- Interleukin-1 beta converting enzyme (ICE) is the first enzyme of a new family of cysteine endoproteinases to be isolated and characterized. An overview of the structure and activity of ICE is outlined together with highlights of salient features common to members of each of the family members.
- Villa P, Kaufmann SH, Earnshaw WC
- Caspases and caspase inhibitors.
- Trends Biochem Sci. 1997; 22: 388-93
- Display abstract
- Five years ago, little was known about mechanisms of apoptotic execution. Now, one class of cell-death gene, the cysteine and aspartases (caspases) has come under intensive study. This review discusses the two classes of caspases, the reasons why humans may have so many caspase genes, the growing list of caspase substrates, and viral and pharmacological caspase inhibitors.
- Komiyama T et al.
- Inhibition of interleukin-1 beta converting enzyme by the cowpox virus serpin CrmA. An example of cross-class inhibition.
- J Biol Chem. 1994; 269: 19331-7
- Display abstract
- We reported previously that human interleukin-1 beta converting enzyme (ICE) is regulated by the CrmA serpin encoded by cowpox virus. We now report the mechanism and kinetics of this unusual inhibition of a cysteine proteinase by a member of the serpin superfamily previously thought to inhibit serine proteinase only. CrmA possesses several characteristics typical of a number of inhibitory serpins. It is conformationally unstable, unfolding around 3 M urea, and stable to denaturation in 8 M urea upon complex formation with ICE. CrmA rapidly inhibits ICE with an association rate constant (kon) of 1.7 x 10(7) M-1 s-1, forming a tight complex with an equilibrium constant for inhibition (Ki) of less than 4 x 10(-12) M. These data indicate that CrmA is a potent inhibitor of ICE, consistent with the dramatic effects of CrmA on modifying host responses to virus infection. The inhibition of ICE by CrmA is an example of a "cross-class" interaction, in which a serpin inhibits a non-serine proteinase. Since CrmA possesses characteristics shared by inhibitors of serine proteinases, we presume that ICE, though it is a cysteine proteinase, has a substrate binding geometry strikingly close to that of serine proteinases. We reason that it is the substrate binding geometry, not the catalytic mechanism of a proteinase, that dictates its reactivity with protein inhibitors.
- Walker NP et al.
- Crystal structure of the cysteine protease interleukin-1 beta-converting enzyme: a (p20/p10)2 homodimer.
- Cell. 1994; 78: 343-52
- Display abstract
- Interleukin-1 beta-converting enzyme (ICE) proteolytically cleaves pro-IL-1 beta to its mature, active form. The crystal structure at 2.5 A resolution of a recombinant human ICE-tetrapeptide chloromethylketone complex reveals that the holoenzyme is a homodimer of catalytic domains, each of which contains a p20 and a p10 subunit. The spatial separation of the C-terminus of p20 and the N-terminus of p10 in each domain suggests two alternative pathways of assembly and activation in vivo. ICE is homologous to the C. elegans cell death gene product, CED-3, and these may represent a novel class of cytoplasmic cysteine proteases that are important in programmed cell death (apoptosis). Conservation among members of the ICE/CED-3 family of the amino acids that form the active site region of ICE supports the hypothesis that they share functional similarities.
- Wilson KP et al.
- Structure and mechanism of interleukin-1 beta converting enzyme.
- Nature. 1994; 370: 270-5
- Display abstract
- Interleukin-1 beta converting enzyme (ICE) processes an inactive precursor to the proinflammatory cytokine, interleukin-1 beta, and may regulate programmed cell death in neuronal cells. The high-resolution structure of human ICE in complex with an inhibitor has been determined by X-ray diffraction. The structure confirms the relationship between human ICE and cell-death proteins in other organisms. The active site spans both the 10 and 20K subunits, which associate to form a tetramer, suggesting a mechanism for ICE autoactivation.
- Miura M, Zhu H, Rotello R, Hartwieg EA, Yuan J
- Induction of apoptosis in fibroblasts by IL-1 beta-converting enzyme, a mammalian homolog of the C. elegans cell death gene ced-3.
- Cell. 1993; 75: 653-60
- Display abstract
- The mammalian interleukin-1 beta-converting enzyme (ICE) has sequence similarity to the C. elegans cell death gene ced-3. We show here that overexpression of the murine ICE (mICE) gene or of the C. elegans ced-3 gene causes Rat-1 cells to undergo programmed cell death. Point mutations in a region homologous between mICE and CED-3 eliminate the ability of mICE and ced-3 to cause cell death. The cell death caused by mICE can be suppressed by overexpression of the crmA gene, a specific inhibitor of ICE, as well as by bcl-2, a mammalian oncogene that can act to prevent programmed cell death. Our results suggest that ICE may function during mammalian development to cause programmed cell death.
- Yuan J, Shaham S, Ledoux S, Ellis HM, Horvitz HR
- The C. elegans cell death gene ced-3 encodes a protein similar to mammalian interleukin-1 beta-converting enzyme.
- Cell. 1993; 75: 641-52
- Display abstract
- We have cloned the C. elegans cell death gene ced-3. A ced-3 transcript is most abundant during embryogenesis, the stage during which most programmed cell deaths occur. The predicted CED-3 protein shows similarity to human and murine interleukin-1 beta-converting enzyme and to the product of the mouse nedd-2 gene, which is expressed in the embryonic brain. The sequences of 12 ced-3 mutations as well as the sequences of ced-3 genes from two related nematode species identify sites of potential functional importance. We propose that the CED-3 protein acts as a cysteine protease in the initiation of programmed cell death in C. elegans and that cysteine proteases also function in programmed cell death in mammals.
- Cerretti DP et al.
- Molecular cloning of the interleukin-1 beta converting enzyme.
- Science. 1992; 256: 97-100
- Display abstract
- Interleukin-1 beta (IL-1 beta) mediates a wide range of immune and inflammatory responses. The active cytokine is generated by proteolytic cleavage of an inactive precursor. A complementary DNA encoding a protease that carries out this cleavage has been cloned. Recombinant expression in COS-7 cells enabled the cells to process precursor IL-1 beta to the mature form. Sequence analysis indicated that the enzyme itself may undergo proteolytic processing. The gene encoding the protease was mapped to chromosomal band 11q23, a site frequently involved in rearrangement in human cancers.
- Thornberry NA et al.
- A novel heterodimeric cysteine protease is required for interleukin-1 beta processing in monocytes.
- Nature. 1992; 356: 768-74
- Display abstract
- Interleukin-1 beta (IL-1 beta)-converting enzyme cleaves the IL-1 beta precursor to mature IL-1 beta, an important mediator of inflammation. The identification of the enzyme as a unique cysteine protease and the design of potent peptide aldehyde inhibitors are described. Purification and cloning of the complementary DNA indicates that IL-1 beta-converting enzyme is composed of two nonidentical subunits that are derived from a single proenzyme, possibly by autoproteolysis. Selective inhibition of the enzyme in human blood monocytes blocks production of mature IL-1 beta, indicating that it is a potential therapeutic target.
Metabolism (metabolic pathways involving proteins which contain this domain)

Structure (3D structures containing this domain)

3D Structures of CASc domains in PDB

PDB code	Main view	Title
1bmq		Crystal structure of the complex of interleukin-1beta converting enzyme (ice) with a peptide based inhibitor, (3s )-n-methanesulfonyl-3-({1-[n-(2-naphtoyl)-l-valyl]-l- prolyl }amino)-4-oxobutanamide
1cp3		Crystal structure of the complex of apopain with the tetrapeptide inhibitor ace-dvad-fmc
1f1j		Crystal structure of caspase-7 in complex with acetyl-asp- glu-val-asp-cho
1f9e		Caspase-8 specificity probed at subsite s4: crystal structure of the caspase-8-z-devd-cho
1gfw		The 2.8 angstrom crystal structure of caspase-3 (apopain or cpp32)in complex with an isatin sulfonamide inhibitor.
1gqf		Crystal structure of human procaspase-7
1i3o		Crystal structure of the complex of xiap-bir2 and caspase 3
1i4e		Crystal structure of the caspase-8/p35 complex
1i4o		Crystal structure of the xiap/caspase-7 complex
1i51		Crystal structure of caspase-7 complexed with xiap
1ibc		Crystal structure of inhibited interleukin-1beta converting enzyme
1ice		Structure and mechanism of interleukin-1beta converting enzyme
1jxq		Structure of cleaved, card domain deleted caspase-9
1k86		Crystal structure of caspase-7
1k88		Crystal structure of procaspase-7
1kmc		Crystal structure of the caspase-7 / xiap-bir2 complex
1m72		Crystal structure of caspase-1 from spodoptera frugiperda
1nme		Structure of casp-3 with tethered salicylate
1nmq		Extendend tethering: in situ assembly of inhibitors
1nms		Caspase-3 tethered to irreversible inhibitor
1nw9		Structure of caspase-9 in an inhibitory complex with xiap- bir3
1pau		Crystal structure of the complex of apopain with the tetrapeptide aldehyde inhibitor ac-devd-cho
1pyo		Crystal structure of human caspase-2 in complex with acetyl- leu-asp-glu-ser-asp-cho
1qdu		Crystal structure of the complex of caspase-8 with the tripeptide ketone inhibitor zevd-dcbmk
1qtn		Crystal structure of the complex of caspase-8 with the tetrapeptide inhibitor ace-ietd-aldehyde
1qx3		Conformational restrictions in the active site of unliganded human caspase-3
1re1		Crystal structure of caspase-3 with a nicotinic acid aldehyde inhibitor
1rhj		Crystal structure of the complex of caspase-3 with a pryazinone inhibitor
1rhk		Crystal structure of the complex of caspase-3 with a phenyl- propyl-ketone inhibitor
1rhm		Crystal structure of the complex of caspase-3 with a nicotinic acid aldehyde inhibitor
1rhq		Crystal structure of the complex of caspase-3 with a bromomethoxyphenyl inhibitor
1rhr		Crystal structure of the complex of caspase-3 with a cinnamic acid methyl ester inhibitor
1rhu		Crystal structure of the complex of caspase-3 with a 5,6,7 tricyclic peptidomimetic inhibitor
1rwk		Crystal structure of human caspase-1 in complex with 3-(2- mercapto-acetylamino)-4-oxo-pentanoic acid
1rwm		Crystal structure of human caspase-1 in complex with 4-oxo- 3-[2-(5-{[4-(quinoxalin-2-ylamino)-benzoylamino]-methyl}- thiophen-2-yl)-acetylamino]-pentanoic acid
1rwn		Crystal structure of human caspase-1 in complex with 3-{2- ethyl-6-[4-(quinoxalin-2-ylamino)-benzoylamino]- hexanoylamino}-4-oxo-butyric acid
1rwo		Crystal structure of human caspase-1 in complex with 4-oxo- 3-{6-[4-(quinoxalin-2-ylamino)-benzoylamino]-2-thiophen-2- yl-hexanoylamino}-pentanoic acid
1rwp		Crystal structure of human caspase-1 in complex with 3-{6- [(8-hydroxy-quinoline-2-carbonyl)-amino]-2-thiophen-2-yl- hexanoylamino}-4-oxo-butyric acid
1rwv		Crystal structure of human caspase-1 in complex with 5-[5- (1-carboxymethyl-2-oxo-propylcarbamoyl)-5-phenyl- pentylsulfamoyl]-2-hydroxy-benzoic acid
1rww		Crystal structure of human caspase-1 in complex with 4-oxo- 3-[(6-{[4-(quinoxalin-2-ylamino)-benzoylamino]-methyl}- pyridine-3-carbonyl)-amino]-butyric acid
1rwx		Crystal structure of human caspase-1 in complex with 4-oxo- 3-{6-[4-(quinoxalin-2-yloxy)-benzoylamino]-2-thiophen-2-yl- hexanoylamino}-butyric acid
1sc1		Crystal structure of an active-site ligand-free form of the human caspase-1 c285a mutant
1sc3		Crystal structure of the human caspase-1 c285a mutant in complex with malonate
1sc4		Crystal structure of the human caspase-1 c285a mutant after removal of malonate
1shj		Caspase-7 in complex with dica allosteric inhibitor
1shl		Caspase-7 in complex with fica allosteric inhibitor
2ar9		Crystal structure of a dimeric caspase-9
2c1e		Crystal structures of caspase-3 in complex with aza-peptide michael acceptor inhibitors.
2c2k		Crystal structures of caspase-3 in complex with aza-peptide michael acceptor inhibitors.
2c2m		Crystal structures of caspase-3 in complex with aza-peptide michael acceptor inhibitors.
2c2o		Crystal structures of caspase-3 in complex with aza-peptide michael acceptor inhibitors.
2c2z		Crystal structure of caspase-8 in complex with aza-peptide michael acceptor inhibitor
2cdr		Crystal structures of caspase-3 in complex with aza-peptide epoxide inhibitors.
2cjx		Extended substrate recognition in caspase-3 revealed by high resolution x-ray structure analysis
2cjy		Extended substrate recognition in caspase-3 revealed by high resolution x-ray structure analysis
2cnk		Crystal structures of caspase-3 in complex with aza-peptide epoxide inhibitors.
2cnl		Crystal structures of caspase-3 in complex with aza-peptide epoxide inhibitors.
2cnn		Crystal structures of caspase-3 in complex with aza-peptide epoxide inhibitors.
2cno		Crystal structures of caspase-3 in complex with aza-peptide epoxide inhibitors.
2dko		Extended substrate recognition in caspase-3 revealed by high resolution x-ray structure analysis
2fp3		Crystal structure of the drosophila initiator caspase dronc
2fqq		Crystal structure of human caspase-1 (cys285->ala, cys362- >ala, cys364->ala, cys397->ala) in complex with 1-methyl-3- trifluoromethyl-1h-thieno[2,3-c]pyrazole-5-carboxylic acid (2-mercapto-ethyl)-amide
2fun		Alternative p35-caspase-8 complex
2h48		Crystal structure of human caspase-1 (cys362->ala, cys364- >ala, cys397->ala) in complex with 3-[2-(2- benzyloxycarbonylamino-3-methyl-butyrylamino)- propionylamino]-4-oxo-pentanoic acid (z-vad-fmk)
2h4w		Crystal structure of human caspase-1 (glu390->asp) in complex with 3-[2-(2-benzyloxycarbonylamino-3-methyl- butyrylamino)-propionylamino]-4-oxo-pentanoic acid (z-vad- fmk)
2h4y		Crystal structure of human caspase-1 (arg286->lys) in complex with 3-[2-(2-benzyloxycarbonylamino-3-methyl- butyrylamino)-propionylamino]-4-oxo-pentanoic acid (z-vad- fmk)
2h51		Crystal structure of human caspase-1 (glu390->asp and arg286->lys) in complex with 3-[2-(2- benzyloxycarbonylamino-3-methyl-butyrylamino)- propionylamino]-4-oxo-pentanoic acid (z-vad-fmk)
2h54		Crystal structure of human caspase-1 (thr388->ala) in complex with 3-[2-(2-benzyloxycarbonylamino-3-methyl- butyrylamino)-propionylamino]-4-oxo-pentanoic acid (z-vad- fmk)
2h5i		Crystal structure of caspase-3 with inhibitor ac-devd-cho
2h5j		Crystal strusture of caspase-3 with inhibitor ac-dmqd-cho
2h65		Crystal strusture of caspase-3 with inhibitor ac-vdvad-cho
2hbq		Crystal structure of wildtype human caspase-1 in complex with 3-[2-(2-benzyloxycarbonylamino-3-methyl-butyrylamino)- propionylamino]-4-oxo-pentanoic acid (z-vad-fmk)
2hbr		Crystal structure of human caspase-1 (arg286->ala) in complex with 3-[2-(2-benzyloxycarbonylamino-3-methyl- butyrylamino)-propionylamino]-4-oxo-pentanoic acid (z-vad- fmk)
2hby		Crystal structure of human caspase-1 (glu390->ala) in complex with 3-[2-(2-benzyloxycarbonylamino-3-methyl- butyrylamino)-propionylamino]-4-oxo-pentanoic acid (z-vad- fmk)
2hbz		Crystal structure of human caspase-1 (arg286->ala, glu390- >ala) in complex with 3-[2-(2-benzyloxycarbonylamino-3- methyl-butyrylamino)-propionylamino]-4-oxo-pentanoic acid (z-vad-fmk)
2j30		The role of loop bundle hydrogen bonds in the maturation and activity of (pro)caspase-3
2j31		The role of loop bundle hydrogen bonds in the maturation and activity of(pro)caspase-3
2j32		The role of loop bundle hydrogen bonds in the maturation and activity of(pro)caspase-3
2j33		The role of loop bundle hydrogen bonds in the maturation and activity of (pro)caspase-3
2k7z		Solution structure of the catalytic domain of procaspase-8
2nn3		Structure of pro-sf-caspase-1
2p2c		Inhibition of caspase-2 by a designed ankyrin repeat protein (darpin)
2ql5		Crystal structure of caspase-7 with inhibitor ac-dmqd-cho
2ql7		Crystal structure of caspase-7 with inhibitor ac-iepd-cho
2ql9		Crystal structure of caspase-7 with inhibitor ac-dqmd-cho
2qlb		Crystal structure of caspase-7 with inhibitor ac-esmd-cho
2qlf		Crystal structure of caspase-7 with inhibitor ac-dnld-cho
2qlj		Crystal structure of caspase-7 with inhibitor ac-wehd-cho
2wdp		Crystal structure of ligand free human caspase-6
3deh		Crystal structures of caspase-3 with bound isoquinoline-1,3, 4-trione derivative inhibitors
3dei		Crystal structures of caspase-3 with bound isoquinoline-1,3, 4-trione derivative inhibitors
3dej		Crystal structures of caspase-3 with bound isoquinoline-1,3, 4-trione derivative inhibitors
3dek		Crystal structures of caspase-3 with bound isoquinoline-1,3, 4-trione derivative inhibitors
3e4c		Procaspase-1 zymogen domain crystal strucutre
3edq		Crystal structure of caspase-3 with inhibitor ac-ldesd-cho
3edr		The crystal structure of caspase-7 in complex with acetyl- ldesd-cho
3gjq		Caspase-3 binds diverse p4 residues in peptides
3gjr		Caspase-3 binds diverse p4 residues in peptides
3gjs		Caspase-3 binds diverse p4 residues in peptides
3gjt		Caspase-3 binds diverse p4 residues in peptides
3h0e		3,4-dihydropyrimido(1,2-a)indol-10(2h)-ones as potent non- peptidic inhibitors of caspase-3
3h11		Zymogen caspase-8:c-flipl protease domain complex
3h13		C-flipl protease-like domain
3h1p		Mature caspase-7 i213a with devd-cho inhibitor bound to active site
3ibc		Crystal structure of caspase-7 incomplex with acetyl-yvad- cho
3ibf		Crystal structure of unliganded caspase-7

Links (links to other resources describing this domain)
BLOCKS ASPASE_HIS
INTERPRO IPR015917
PROSITE CASc_DOMAIN

BLOCKS	ASPASE_HIS
INTERPRO	IPR015917
PROSITE	CASc_DOMAIN