Pyroptosis

The first known description of pyroptosis was made by Arturo Zychlinsky in 1991. After infection of macrophages with Shigella flexneri, Zychlinsky observed the macrophages rapidly died due to Caspase-1 activation. However, Zychlinsky identified this as a form of apoptosis, not as a unique death mechanism. The term pyroptosis was later coined in 2001 by Molly Brennan and Dr. Brad T. Cookson, an associate professor of microbiology and laboratory medicine at the University of Washington. The Greek pyro refers to fire and ptosis means falling. The compound term of pyroptosis may be understood as "fiery falling", which describes the bursting of pro-inflammatory chemical signals from the dying cell. Pyroptosis has a distinct morphology and mechanism compared to those of other forms of cell death. It has been suggested that microbial infection was the main evolutionary pressure for this pathway. Inflammasome formation was initially thought to be required for the induction of pyroptosis, but in 2013, the caspase-11 dependent noncanonical pathway was discovered, suggesting lipopolysaccharides (LPS) can trigger pyroptosis and subsequent inflammatory responses independent of toll-like receptor 4 (TLR4). In 2015, gasdermin D (GSDMD) was identified as the effector of pyroptosis that forms pores in the cell membrane. In 2021, the high-resolution structure of the GSDMD pore was solved by cryo-electron microscopy (cryo-EM). Also in 2021, an additional molecule, NINJ1, was found to be required for the plasma membrane rupture during pyroptosis. ==Morphological characteristics==

Pyroptosis, as a form of programmed cell death, has many morphological differences as compared to apoptosis. Both pyroptosis and apoptosis undergo chromatin condensation, but during apoptosis, the nucleus breaks into multiple chromatin bodies; in pyroptosis, the nucleus remains intact. In a cell that undergoes pyroptosis, gasdermin pores are formed on the plasma membrane, resulting in water influx. In terms of mechanism, pyroptosis is activated by inflammatory caspases, including caspase-1/4/5 in humans and caspase-11 in mice. Caspase-8 can act as an upstream regulator of inflammasome activation in context-dependent manners. Caspase-3 activation can take place in both apoptosis and pyroptosis. Also, necroptosis works in a caspase-independent fashion. It is proposed that both pyroptosis and necroptosis may act as defence systems against pathogens when apoptotic pathways are blocked. ==Mechanism==

The innate immune system, by using germ-line encoded pattern recognition receptors (PRRs), can recognize a wide range of pathogen-associated molecular patterns (PAMPs) and damage-associated molecular patterns (DAMPs) upon microbe infection. Classic examples of PRRs include toll-like receptors (TLRs) and NOD-like receptors (NLRs). Recognition of PAMPs and DAMPs triggers the formation of multi-protein complex inflammasomes, which then activates caspases to initiate pyroptosis. The inflammasome pathway may be canonical or noncanonical, with the former using caspase-1-activating inflammasomes and the latter using other caspases. The canonical inflammasome pathway In the canonical inflammasome pathway, PAMPs and DAMPs are recognised by certain endogenous PRRs. For example, NLR proteins NLRC4 can recognise flagellin and type III secretion system components. NLRP3 is activated by cellular events induced by different PAMPs and DAMPs stimuli. Some non-NLR proteins like absent in melanoma 2 (AIM2) and pyrin can also be activated and form inflammasomes. Canonical inflammasomes mostly contain three components: a sensor protein (PRRs), an adaptor (ASC) and an effector (caspase-1). Alternatively, NLRC4 can directly recruit pro-caspase-1, as it has a CARD instead of a PYD. In addition to their formation as a complex to induce pyroptosis, inflammasomes can also be integral components of larger cell death-inducing complexes called PANoptosomes to induce PANoptosis, another inflammatory form of cell death. Activated caspase-1 is responsible for cleavage of pro-IL-1β and pro-IL-18. These cytokines, once processed, will be in their biologically active form ready to be released from the host cells. In addition, caspase-1 also cleaves the cytosolic gasdermin D (GSDMD). GSDMD can be cleaved to produce an N-terminal domain (GSDMD-N) and a C-terminal domain (GSDMD-C). GSDMD-N can oligomerize and form transmembrane pores that have an inner diameter of 10-14 nm. The pores allow secretion of IL-1β and IL-18 and various cytosolic content to extracellular space, and they also disrupt the cellular ionic gradient. The resulting increase in osmotic pressure causes an influx of water followed by cell swelling and bursting. Notably, GSDMD-N is autoinhibited by GSDMD C-terminal domain before cleavage to prevent cell lysis in normal conditions. Also, GSDMD-N can only insert itself into the inner membrane with specific lipid compositions, which limits its damage to neighbour cells. Downstream of GSDMD, NINJ1 is now thought to be required for the plasma membrane rupture during pyroptosis. This positive feedback loop ensures that programmed cell death is carried forward. . GSDME can further be cleaved by granzyme B at the same site as caspase-3. Additionally, other members of the gasdermin family have been found to have pore-forming and pyroptotic activity, such as GSDMA, GSDMC, and GSDMB. The latter has been found to be activate by granzyme A. == Clinical relevance ==

Infection Pyroptosis acts as a defence mechanism against infection by inducing pathological inflammation. The formation of inflammasomes and the activity of caspase-1 determine the balance between pathogen resolution and disease. In a healthy cell, caspase-1 activation helps to fight infection caused by Salmonella and Shigella by introducing cell death to restrict pathogen growth. The cell activation results in an increase in cytokine levels, which will augment the consequences of inflammation and this, in turn, contributes to the development of the adaptive response as infection progresses. The ultimate resolution will clear pathogens. In contrast, persistent inflammation will produce excessive immune cells, which is detrimental. If the amplification cycles persist, metabolic disorder, autoinflammatory diseases and liver injury associated with chronic inflammation will occur. Cerebrovascular disease Recent studies show that pyroptosis plays a role in the pathophysiology of intracerebral hemorrhage, and mitigating pyroptosis could be an intervention strategy to inhibit the inflammatory response after intracerebral hemorrhage. Cancer Pyroptosis, as an inflammation-associated programmed cell death, has wide implications in various cancer types. Principally, pyroptosis can kill cancer cells and inhibit tumour development in the presence of endogenous DAMPs. In some cases, GSDMD can be used as a prognostic marker for cancers. However, prolonged production of inflammatory bodies may facilitate the formation of microenvironments that favour tumour growth. Understanding the mechanisms of pyroptosis and identifying pyroptosis-associated molecules can be useful in treating different cancers. In gastric cancer cells, presence of GSDMD can inhibit cyclin A2/CDK2 complexes, leading to cell cycle arrest and thus inhibit tumour development. Also, cellular concentration of GSDME increases when gastric cancer cells are treated with certain chemotherapy drugs. GSDME then activates caspase-3 and triggers pyroptotic cell death. Metabolic disorder The level of expression of NLRP3 inflammasome and caspase-1 has a direct relation to the severity of several metabolic syndromes, such as obesity and type II diabetic mellitus (T2DM). This is because the subsequent production level of IL-1β and IL-18, cytokines that impair the secretion of insulin, is affected by the activity of caspase-1. Glucose uptake level is then diminished, and the condition is known as insulin resistance. The condition is further accelerated by the IL-1β-induced destruction of pancreatic β cells. Cryopyrinopathies A mutation in the gene coding of inflammasomes leads to a group of autoinflammatory diseases called cryopyrinopathies. This group includes Muckle–Wells syndrome, cold autoinflammatory syndrome and chronic infantile neurologic cutaneous and articular syndrome, all showing symptoms of sudden fevers and localized inflammation. The mutated gene in such cases is the NLRP3, impeding the activation of inflammasome and resulting in an excessive production of IL-1β. This effect is known as "gain-of-function". HIV and AIDS Recent studies demonstrate that caspase-1-mediated pyroptosis drives CD4 T-cell depletion and inflammation by HIV, two signature events that propel HIV disease progression to AIDS. Although pyroptosis contributes to the host's ability to rapidly limit and clear infection by removing intracellular replication niches and enhancing defensive responses through the release of proinflammatory cytokines and endogenous danger signals, in pathogenic inflammation, such as that elicited by HIV-1, this beneficial response does not eradicate the primary stimulus. In fact, it appears to create a pathogenic vicious cycle in which dying CD4 T cells release inflammatory signals that attract more cells into the infected lymphoid tissues to die and to produce chronic inflammation and tissue injury. It may be possible to break this pathogenic cycle with safe and effective caspase-1 inhibitors. These agents could form a new and exciting 'anti-AIDS' therapy for HIV-infected subjects in which the treatment targets the host instead of the virus. Of note, Caspase-1 deficient mice develop normally, arguing that inhibition of this protein would produce beneficial rather than harmful therapeutic effects in HIV patients. == References ==