Biology:Caspase

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Short description: Family of cysteine proteases
Caspase domain
Caspase 1.png
Structure of caspase-1 (CASP1), originally called interleukin-1 beta-converting enzyme (ICE), the first human caspase to be identified.[1]
Identifiers
SymbolPeptidase_C14
PfamPF00656
Pfam clanCL0093
InterProIPR002398
PROSITEPS50208
MEROPSC14
SCOP21ice / SCOPe / SUPFAM

Caspases (cysteine-aspartic proteases, cysteine aspartases or cysteine-dependent aspartate-directed proteases) are a family of protease enzymes playing essential roles in programmed cell death. They are named caspases due to their specific cysteine protease activity – a cysteine in its active site nucleophilically attacks and cleaves a target protein only after an aspartic acid residue. As of 2009, there are 12 confirmed caspases in humans[note 1] and 10 in mice, carrying out a variety of cellular functions.

The role of these enzymes in programmed cell death was first identified in 1993, with their functions in apoptosis well characterised. This is a form of programmed cell death, occurring widely during development, and throughout life to maintain cell homeostasis. Activation of caspases ensures that the cellular components are degraded in a controlled manner, carrying out cell death with minimal effect on surrounding tissues.[3]

Caspases have other identified roles in programmed cell death such as pyroptosis, necroptosis and PANoptosis. These forms of cell death are important for protecting an organism from stress signals and pathogenic attack. Caspases also have a role in inflammation, whereby it directly processes pro-inflammatory cytokines such as pro-IL1β. These are signalling molecules that allow recruitment of immune cells to an infected cell or tissue. There are other identified roles of caspases such as cell proliferation, tumour suppression, cell differentiation, neural development and axon guidance and ageing.[4]

Caspase deficiency has been identified as a cause of tumour development. Tumour growth can occur by a combination of factors, including a mutation in a cell cycle gene which removes the restraints on cell growth, combined with mutations in apoptotic proteins such as caspases that would respond by inducing cell death in abnormally growing cells.[5] Conversely, over-activation of some caspases such as caspase-3 can lead to excessive programmed cell death. This is seen in several neurodegenerative diseases where neural cells are lost, such as Alzheimer's disease.[5] Caspases involved with processing inflammatory signals are also implicated in disease. Insufficient activation of these caspases can increase an organism's susceptibility to infection, as an appropriate immune response may not be activated.[5] The integral role caspases play in cell death and disease has led to research on using caspases as a drug target. For example, inflammatory caspase-1 has been implicated in causing autoimmune diseases; drugs blocking the activation of Caspase-1 have been used to improve the health of patients. Additionally, scientists have used caspases as cancer therapy to kill unwanted cells in tumours.[6]

Functional classification of caspases

Most caspases play a role in programmed cell death. These are summarized in the table below. The enzymes are sub classified into three types: Initiator, Executioner and Inflammatory.[7]

Programmed Cell Death Type of Caspase Enzyme Organism
Apoptosis Initiator Caspase 2 human and mouse
Caspase 8 human and mouse
Caspase 9 human and mouse
Caspase 10 human only [8]
Executioner Caspase 3 human and mouse
Caspase 6 human and mouse
Caspase 7 human and mouse
Pyroptosis Inflammatory Caspase 1 human and mouse
Caspase 4 human [note 2]
Caspase 5 human [note 2]
Caspase 11 mouse [note 2]
Caspase 12 mouse and some humans [note 1]
Caspase 13 cattle only [10]
Other roles Other Caspase 14 human and mouse

Note that in addition to apoptosis, caspase-8 is also required for the inhibition of another form of programmed cell death called necroptosis. Caspase-14 plays a role in epithelial cell keratinocyte differentiation and can form an epidermal barrier that protects against dehydration and UVB radiation.[11]

Activation of caspases

Caspases are synthesised as inactive zymogens (pro-caspases) that are only activated following an appropriate stimulus. This post-translational level of control allows rapid and tight regulation of the enzyme.

Activation involves dimerization and often oligomerisation of pro-caspases, followed by cleavage into a small subunit and large subunit. The large and small subunit associate with each other to form an active heterodimer caspase. The active enzyme often exists as a heterotetramer in the biological environment, where a pro-caspase dimer is cleaved together to form a heterotetramer.[12]

Dimerisation

The activation of initiator caspases and inflammatory caspases is initiated by dimerisation, which is facilitated by binding to adaptor proteins via protein–protein interaction motifs that are collectively referred to as death folds. The death folds are located in a structural domain of the caspases known as the pro-domain, which is larger in those caspases that contain death folds than in those that do not. The pro-domain of the intrinsic initiator caspases and the inflammatory caspases contains a single death fold known as caspase recruitment domain (CARD), while the pro-domain of the extrinsic initiator caspases contains two death folds known as death effector domains (DED).[13][14]

Multiprotein complexes often form during caspase activation.[12] Some activating multiprotein complexes includes:

Cleavage

Once appropriately dimerised, the Caspases cleave at inter domain linker regions, forming a large and small subunit. This cleavage allows the active-site loops to take up a conformation favourable for enzymatic activity.[15]

Cleavage of Initiator and Executioner caspases occur by different methods outlined in the table below.

  • Initiator caspases auto-proteolytically cleave whereas Executioner caspases are cleaved by initiator caspases. This hierarchy allows an amplifying chain reaction or cascade for degrading cellular components, during controlled cell death.
Initiator Caspase

Caspase-8

Inititator Pro-caspases have a prodomain that allows recruitment of other pro-caspases, which subsequently dimerise. Both pro-caspase molecules undergo cleavage by autocatalysis. This leads to removal of the prodomain and cleavage of the linker region between the large and small subunit. A heterotetramer is formed
PDB image of caspase 8 (3KJQ) in 'biological assembly'. Two shades of blue used to represent two small sunits, while two shades of purple represent two large subunits
Executioner

Caspase Caspase-3

Executioner caspase constitutively exist as homodimers. The red cuts represent regions where initiator caspases cleave the executioner caspases. The resulting small and large subunit of each Caspase-3 will associate, resulting in a heterotetramer.
[16]
PDB image of Caspase 3 (4QTX) in 'biological assembly'. Two shades of blue used to represent two small sunits, while two shades of purple represent two large subunits

Some roles of caspases

Apoptosis

Initiator caspases are activated by intrinsic and extrinsic apoptotic pathways. This leads to the activation of other caspases including executioner caspases that carry out apoptosis by cleaving cellular components.

Apoptosis is a form of programmed cell death where the cell undergoes morphological changes, to minimize its effect on surrounding cells to avoid inducing an immune response. The cell shrinks and condenses - the cytoskeleton will collapse, and the nuclear envelope disassembles the DNA fragments up. This results in the cell forming self-enclosed bodies called 'blebs', to avoid release of cellular components into the extracellular medium. Additionally, the cell membrane phospholipid content is altered, which makes the dying cell more susceptible to phagocytic attack and removal.[17]

Apoptotic caspases are subcategorised as:

  1. Initiator Caspases (Caspase 2, Caspase 8, Caspase 9, Caspase 10)
  2. Executioner Caspases (Caspase 3, Caspase 6 and Caspase 7)

Once initiator caspases are activated, they produce a chain reaction, activating several other executioner caspases. Executioner caspases degrade over 600 cellular components[18] in order to induce the morphological changes for apoptosis.

Examples of caspase cascade during apoptosis:

  1. Intrinsic apoptopic pathway: During times of cellular stress, mitochondrial cytochrome c is released into the cytosol. This molecule binds an adaptor protein (APAF-1), which recruits initiator Caspase-9 (via CARD-CARD interactions). This leads to the formation of a Caspase activating multiprotein complex called the Apoptosome. Once activated, initiator caspases such as Caspase 9 will cleave and activate other executioner caspases. This leads to degradation of cellular components for apoptosis.
  2. Extrinsic apoptopic pathway: The caspase cascade is also activated by extracellular ligands, via cell surface Death Receptors. This is done by the formation of a multiprotein Death Inducing Signalling Complex (DISC) that recruits and activates a pro-caspase. For example, the Fas Ligand binds the FasR receptor at the receptor's extracellular surface; this activates the death domains at the cytoplasmic tail of the receptor. The adaptor protein FADD will recruit (by a Death domain-Death domain interaction) pro-Caspase 8 via the DED domain. This FasR, FADD and pro-Caspase 8 form the Death Inducing Signalling Complex (DISC) where Caspase-8 is activated. This could lead to either downstream activation of the intrinsic pathway by inducing mitochondrial stress, or direct activation of Executioner Caspases (Caspase 3, Caspase 6 and Caspase 7) to degrade cellular components as shown in the adjacent diagram.[19]

Pyroptosis

Pyroptosis is a form of programmed cell death that inherently induces an immune response. It is morphologically distinct from other types of cell death – cells swell up, rupture and release pro-inflammatory cellular contents. This is done in response to a range of stimuli including microbial infections as well as heart attacks (myocardial infarctions).[20] Caspase-1, Caspase-4 and Caspase-5 in humans, and Caspase-1 and Caspase-11 in mice play important roles in inducing cell death by pyroptosis. This limits the life and proliferation time of intracellular and extracellular pathogens.[citation needed]

Pyroptosis by caspase-1

Caspase-1 activation is mediated by a repertoire of proteins, allowing detection of a range of pathogenic ligands. Some mediators of Caspase-1 activation are: NOD-like Leucine Rich Repeats (NLRs), AIM2-Like Receptors (ALRs), Pyrin and IFI16.[21]

These proteins allow caspase-1 activation by forming a multiprotein activating complex called Inflammasomes. For example, a NOD Like Leucine Rich Repeat NLRP3 will sense an efflux of potassium ions from the cell. This cellular ion imbalance leads to oligomerisation of NLRP3 molecules to form a multiprotein complex called the NLRP3 inflammasome. The pro-caspase-1 is brought into close proximity with other pro-caspase molecule in order to dimerise and undergo auto-proteolytic cleavage.[21]

Some pathogenic signals that lead to Pyroptosis by Caspase-1 are listed below:

  • DNA in the host cytosol binds to AIM2-Like Receptors inducing Pyroptosis
  • Type III secretion system apparatus from bacteria bind NOD Like Leucine Rich Repeats receptors called NAIP's (1 in humans and 4 in mice)

Pyroptosis by Caspase-4 and Caspase-5 in humans and Caspase-11 in mice

These caspases have the ability to induce direct pyroptosis when lipopolysaccharide (LPS) molecules (found in the cell wall of gram negative bacteria) are found in the cytoplasm of the host cell. For example, Caspase 4 acts as a receptor and is proteolytically activated, without the need of an inflammasome complex or Caspase-1 activation.[21]

A crucial downstream substrate for pyroptotic caspases is Gasdermin D (GSDMD)[22]

Role in inflammation

Inflammation is a protective attempt by an organism to restore a homeostatic state, following disruption from harmful stimulus, such as tissue damage or bacterial infection.[18]

Caspase-1, Caspase-4, Caspase-5 and Caspase-11 are considered 'Inflammatory Caspases'.[7]

  • Caspase-1 is key in activating pro-inflammatory cytokines; these act as signals to immune cells and make the environment favourable for immune cell recruitment to the site of damage. Caspase-1 therefore plays a fundamental role in the innate immune system. The enzyme is responsible for processing cytokines such as pro-ILβ and pro-IL18, as well as secreting them.[21]
  • Caspase-4 and -5 in humans, and Caspase-11 in mice have a unique role as a receptor, whereby it binds to LPS, a molecule abundant in gram negative bacteria. This can lead to the processing and secretion of IL-1β and IL-18 cytokines by activating Caspase-1; this downstream effect is the same as described above. It also leads to the secretion of another inflammatory cytokine that is not processed. This is called pro-IL1α.[21] There is also evidence of an inflammatory caspase, caspase-11 aiding cytokine secretion; this is done by inactivating a membrane channel that blocks IL-1β secretion[21]
  • Caspases can also induce an inflammatory response on a transcriptional level. There is evidence where it promotes transcription of nuclear factor-κB (NF-κB), a transcription factor that assists in transcribing inflammatory cytokines such as IFNs, TNF, IL-6 and IL-8. For example, Caspase-1 activates Caspase-7, which in turn cleaves the poly (ADP) ribose – this activates transcription of NF-κB controlled genes.[18]

Discovery of caspases

H. Robert Horvitz initially established the importance of caspases in apoptosis and found that the ced-3 gene is required for the cell death that took place during the development of the nematode C. elegans. Horvitz and his colleague Junying Yuan found in 1993 that the protein encoded by the ced-3 gene is cysteine protease with similar properties to the mammalian interleukin-1-beta converting enzyme (ICE) (now known as caspase 1). At the time, ICE was the only known caspase.[23] Other mammalian caspases were subsequently identified, in addition to caspases in organisms such as fruit fly Drosophila melanogaster.

Researchers decided upon the nomenclature of the caspase in 1996. In many instances, a particular caspase had been identified simultaneously by more than one laboratory; each would then give the protein a different name. For example, caspase 3 was variously known as CPP32, apopain and Yama. Caspases, therefore, were numbered in the order in which they were identified.[24] ICE was, therefore, renamed as caspase 1. ICE was the first mammalian caspase to be characterised because of its similarity to the nematode death gene ced-3, but it appears that the principal role of this enzyme is to mediate inflammation rather than cell death.

Evolution

In animals apoptosis is induced by caspases and in fungi and plants, apoptosis is induced by arginine and lysine-specific caspase like proteases called metacaspases. Homology searches revealed a close homology between caspases and the caspase-like proteins of Reticulomyxa (a unicellular organism). The phylogenetic study indicates that divergence of caspase and metacaspase sequences occurred before the divergence of eukaryotes.[25]

See also


Notes

  1. 1.0 1.1 Functional CASP12 is only expressed in some individuals of African descent, while individuals of Asian or Caucasian descent express only a non-functional truncated form.[2]
  2. 2.0 2.1 2.2 CASP4 and CASP5 are considered to be the human orthologues of CASP11, which was found in mice and rats but not in humans.[9]

References

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  2. Saleh, Maya; Vaillancourt, John P; Graham, Rona K; Huyck, Matthew; Srinivasula, Srinivasa M; Alnemri, Emad S; Steinberg, Martin H; Nolan, Vikki et al. (2004). "Differential modulation of endotoxin responsiveness by human caspase-12 polymorphisms". Nature 429 (6987): 75–9. doi:10.1038/nature02451. PMID 15129283. Bibcode2004Natur.429...75S. 
  3. Rathore, S.; Datta, G.; Kaur, I.; Malhotra, P.; Mohmmed, A. (2015-07-02). "Disruption of cellular homeostasis induces organelle stress and triggers apoptosis like cell-death pathways in malaria parasite" (in en). Cell Death & Disease 6 (7): e1803. doi:10.1038/cddis.2015.142. PMID 26136076. 
  4. Shalini, S.; Dorstyn, L.; Dawar, S.; Kumar, S. (2015-04-01). "Old, new and emerging functions of caspases" (in en). Cell Death & Differentiation 22 (4): 526–539. doi:10.1038/cdd.2014.216. ISSN 1350-9047. PMID 25526085. 
  5. 5.0 5.1 5.2 Goodsell, David S. (2000-10-01). "The Molecular Perspective: Caspases" (in en). The Oncologist 5 (5): 435–436. doi:10.1634/theoncologist.5-5-435. ISSN 1083-7159. PMID 11040280. 
  6. McIlwain, David R.; Berger, Thorsten; Mak, Tak W. (2013-04-01). "Caspase Functions in Cell Death and Disease" (in en). Cold Spring Harbor Perspectives in Biology 5 (4): a008656. doi:10.1101/cshperspect.a008656. ISSN 1943-0264. PMID 23545416. 
  7. 7.0 7.1 Galluzzi, Lorenzo; López-Soto, Alejandro; Kumar, Sharad; Kroemer, Guido (2016-02-16). "Caspases Connect Cell-Death Signaling to Organismal Homeostasis" (in en). Immunity 44 (2): 221–231. doi:10.1016/j.immuni.2016.01.020. ISSN 1074-7613. PMID 26885855. 
  8. Jänicke, Reiner U.; Sohn, Dennis; Totzke, Gudrun; Schulze-Osthoff, Klaus (June 2006). "Caspase-10 in Mouse or Not?". Science 312 (5782): 1874. doi:10.1126/science.312.5782.1874a. PMID 16809511. 
  9. Stowe, Irma; Lee, Bettina; Kayagaki, Nobuhiko (2015). "Caspase-11: arming the guards against bacterial infection". Immunological Reviews 265 (1): 75–84. doi:10.1111/imr.12292. PMID 25879285. 
  10. Koenig, Ulrich; Eckhart, Leopold; Tschachler, Erwin (2001). "Evidence That Caspase-13 Is Not a Human but a Bovine Gene". Biochemical and Biophysical Research Communications 285 (5): 1150–4. doi:10.1006/bbrc.2001.5315. PMID 11478774. 
  11. Denecker, Geertrui; Ovaere, Petra; Vandenabeele, Peter; Declercq, Wim (2008-02-11). "Caspase-14 reveals its secrets" (in en). The Journal of Cell Biology 180 (3): 451–458. doi:10.1083/jcb.200709098. ISSN 0021-9525. PMID 18250198. 
  12. 12.0 12.1 Shi, Yigong (2004-06-25). "Caspase Activation" (in en). Cell 117 (7): 855–858. doi:10.1016/j.cell.2004.06.007. ISSN 0092-8674. PMID 15210107. 
  13. Lahm, Armin; Paradisi, Andrea; Green, Douglas R; Melino, Gerry (2003). "Death fold domain interaction in apoptosis". Cell Death and Differentiation 10 (1): 10–2. doi:10.1038/sj.cdd.4401203. PMID 12655289. 
  14. Kumar, S (2006). "Caspase function in programmed cell death". Cell Death and Differentiation 14 (1): 32–43. doi:10.1038/sj.cdd.4402060. PMID 17082813. 
  15. Riedl, Stefan J.; Shi, Yigong (Nov 2004). "Molecular mechanisms of caspase regulation during apoptosis". Nature Reviews Molecular Cell Biology 5 (11): 897–907. doi:10.1038/nrm1496. PMID 15520809. 
  16. Lavrik, I.; Krueger, A.; Schmitz, I.; Baumann, S.; Weyd, H.; Krammer, P. H.; Kirchhoff, S. (2003-01-01). "The active caspase-8 heterotetramer is formed at the CD95 DISC" (in en). Cell Death & Differentiation 10 (1): 144–145. doi:10.1038/sj.cdd.4401156. ISSN 1350-9047. PMID 12655304. 
  17. Elmore, Susan (2007-06-01). "Apoptosis: A Review of Programmed Cell Death" (in en). Toxicologic Pathology 35 (4): 495–516. doi:10.1080/01926230701320337. ISSN 0192-6233. PMID 17562483. 
  18. 18.0 18.1 18.2 Sollberger, Gabriel; Strittmatter, Gerhard E.; Garstkiewicz, Martha; Sand, Jennifer; Beer, Hans-Dietmar (2014-02-01). "Caspase-1: The inflammasome and beyond" (in en). Innate Immunity 20 (2): 115–125. doi:10.1177/1753425913484374. ISSN 1753-4259. PMID 23676582. https://discovery.dundee.ac.uk/en/publications/d53bae44-552f-4d8f-810d-9b8338468e80. 
  19. Creagh, Emma M. (December 2014). "Caspase crosstalk: integration of apoptotic and innate immune signalling pathways". Trends in Immunology 35 (12): 631–640. doi:10.1016/j.it.2014.10.004. PMID 25457353. 
  20. Bergsbaken, Tessa; Fink, Susan L.; Cookson, Brad T. (2009). "Pyroptosis: host cell death and inflammation". Nature Reviews Microbiology 7 (2): 99–109. doi:10.1038/nrmicro2070. PMID 19148178. 
  21. 21.0 21.1 21.2 21.3 21.4 21.5 Eldridge, Matthew JG; Shenoy, Avinash R (2015). "Antimicrobial inflammasomes: unified signalling against diverse bacterial pathogens". Current Opinion in Microbiology 23: 32–41. doi:10.1016/j.mib.2014.10.008. PMID 25461570. 
  22. He, Wan-ting; Wan, Haoqiang; Hu, Lichen; Chen, Pengda; Wang, Xin; Huang, Zhe; Yang, Zhang-Hua; Zhong, Chuan-Qi et al. (2015-12-01). "Gasdermin D is an executor of pyroptosis and required for interleukin-1β secretion" (in en). Cell Research 25 (12): 1285–1298. doi:10.1038/cr.2015.139. ISSN 1001-0602. PMID 26611636. 
  23. Yuan, J (1993). "The C. elegans cell death gene ced-3 encodes a protein similar to mammalian interleukin-1 beta-converting enzyme". Cell 75 (4): 641–652. doi:10.1016/0092-8674(93)90485-9. PMID 8242740. 
  24. Alnemri ES, Emad S (1996). "Human ICE/CED-3 Protease Nomenclature". Cell 87 (2): 171. doi:10.1016/S0092-8674(00)81334-3. PMID 8861900. 
  25. Klim, Joanna; Gładki, Arkadiusz; Kucharczyk, Roza; Zielenkiewicz, Urszula; Kaczanowski, Szymon (2018-04-27). "Ancestral State Reconstruction of the Apoptosis Machinery in the Common Ancestor of Eukaryotes". G3: Genes, Genomes, Genetics 8 (6): 2121–2134. doi:10.1534/g3.118.200295. ISSN 2160-1836. PMID 29703784. 

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