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Mitophagy

April 08, 2024

Mitophagy is the selective degradation of mitochondria by autophagy. It often occurs to defective mitochondria following damage or stress. The process of mitophagy was first described over a hundred years ago by Margaret Reed Lewis and Warren Harmon Lewis.[1] Ashford and Porter used electron microscopy to observe mitochondrial fragments in liver lysosomes by 1962,[2] and a 1977 report suggested that "mitochondria develop functional alterations which would activate autophagy."[3] The term "mitophagy" was in use by 1998.[4]

Mitophagy is key in keeping the cell healthy. It promotes turnover of mitochondria and prevents accumulation of dysfunctional mitochondria which can lead to cellular degeneration. It is mediated by Atg32 (in yeast) and NIX and its regulator BNIP3 in mammals. Mitophagy is regulated by PINK1 and parkin proteins. In addition to the selective removal of damaged mitochondria, mitophagy is also required to adjust mitochondrial numbers to changing cellular metabolic needs, for steady-state mitochondrial turnover, and during certain cellular developmental stages, such as during cellular differentiation of red blood cells.[5]

Role edit

Organelles and bits of cytoplasm are sequestered and targeted for degradation by the lysosome for hydrolytic digestion by a process known as autophagy. Mitochondria metabolism leads to the creation of by-products that lead to DNA damage and mutations. Therefore, a healthy population of mitochondria is critical for the well-being of cells. Previously it was thought that targeted degradation of mitochondria was a stochastic event, but accumulating evidence suggest that mitophagy is a selective process.[6]

Generation of ATP by oxidative phosphorylation leads to the production of various reactive oxygen species (ROS) in the mitochondria, and submitochondrial particles. Formation of ROS as a mitochondrial waste product will eventually lead to cytotoxicity and cell death. Because of their role in metabolism, mitochondria are very susceptible to ROS damage. Damaged mitochondria cause a depletion in ATP and a release of cytochrome c, which leads to activation of caspases and onset of apoptosis. Mitochondrial damage is not caused solely by oxidative stress or disease processes; normal mitochondria will eventually accumulate oxidative damage hallmarks overtime, which can be deleterious to mitochondria as well as to the cell. These faulty mitochondria can further deplete the cell of ATP, increase production of ROS, and release proapoptopic proteins such as caspases.

Because of the danger of having damaged mitochondria in the cell, the timely elimination of damaged and aged mitochondria is essential for maintaining the integrity of the cell. This turnover process consists of the sequestration and hydrolytic degradation by the lysosome, a process also known as mitophagy.

Mitochondrial depletion reduces a spectrum of senescence effectors and phenotypes while preserving ATP production via enhanced glycolysis.[7]

Pathways edit

In mammals edit

There are several pathways by which mitophagy is induced in mammalian cells. The PINK1 and Parkin pathway is, so far, the best characterized. This pathway starts by deciphering the difference between healthy mitochondria and damaged mitochondria. A 64-kDa protein, PTEN-induced kinase 1 (PINK1), has been implicated to detect mitochondrial quality. PINK1 contains a mitochondrial targeting sequence (MTS) and is recruited to the mitochondria. In healthy mitochondria, PINK1 is imported through the outer membrane via the TOM complex, and partially through the inner mitochondrial membrane via the TIM complex, so it then spans the inner mitochondrial membrane. The process of import into the inner membrane is associated with the cleavage of PINK1 from 64-kDa into a 60-kDa form. PINK1 is then cleaved by PARL into a 52-kDa form. This new form of PINK1 is degraded by proteases within the mitochondria. This keeps the concentration of PINK1 in check in healthy mitochondria.[8]

In unhealthy mitochondria, the inner mitochondrial membrane becomes depolarized. This membrane potential is necessary for the TIM-mediated protein import. In depolarized mitochondria, PINK1 is no longer imported into the inner membrane, is not cleaved by PARL and PINK1 concentration increases in the outer mitochondrial membrane. PINK1 can then recruit Parkin, a cytosolic E3 ubiquitin ligase.[9] It is thought that PINK1 phosphorylates Parkin ubiquitin ligase at S65 which initiates Parkin recruitment at the mitochondria.[10][11] The phosphorylation site of Parkin, at S65, is homologous to the site where ubiquitin is phosphorylated. This phosphorylation activates Parkin by inducing dimerization, an active state. [citation needed] This allows for Parkin-mediated ubiquitination on other proteins.[10]

Because of its PINK1-mediated recruitment to the mitochondrial surface, Parkin can ubiquitylate proteins in the outer mitochondrial membrane.[12] Some of these proteins include Mfn1/Mfn2 and mitoNEET.[11] The ubiquitylation of mitochondrial surface proteins brings in mitophagy initiating factors. Parkin promotes ubiquitin chain linkages on both K63 and K48. K48 ubiquitination initiates degradation of the proteins, and could allow for passive mitochondrial degradation. K63 ubiquitination is thought to recruit autophagy adaptors LC3/GABARAP which will then lead to mitophagy. It is still unclear which proteins are necessary and sufficient for mitophagy, and how these proteins, once ubiquitylated, initiate mitophagy.

Other pathways that can induce mitophagy includes mitophagy receptors on the outer mitochondrial membrane surface. These receptors include NIX1, BNIP3 and FUNDC1. All of these receptors contain LIR consensus sequences that bind LC3/GABARAP which can lead to the degradation of the mitochondria. In hypoxic conditions BNIP3 is upregulated by HIF1α. BNIP3 is then phosphorylated at its serine residues near the LIR sequence which promotes LC3 binding. FUNDCI is also hypoxia sensitive, although it is constitutively present at the outer mitochondrial membrane during normal conditions. [10] Mitophagy can also be artificially introduced by a series of synthetic autophagy receptors[13] that are composed of antibody fragments to recognize the mitochondrial outer membrane proteins.[14]

In neurons, mitochondria are distributed unequally throughout the cell to areas where energy demand is high, like at synapses and Nodes of Ranvier. This distribution is maintained largely by motor protein-mediated mitochondrial transport along the axon.[15] While neuronal mitophagy is thought to occur primarily in the cell body, it also occurs locally in the axon at sites distant from the cell body; in both the cell body and the axon, neuronal mitophagy occurs via the PINK1-Parkin pathway.[16] Mitophagy in the nervous system may also occur transcellularly, where damaged mitochondria in retinal ganglion cell axons can be passed to neighboring astrocytes for degradation.[17] This process is known as transmitophagy.

In yeast edit

Mitophagy in yeast was first presumed after the discovery of Yeast Mitochondrial Escape genes (yme), specifically yme1. Yme1 like other genes in the family showed increase escape of mtDNA, but was the only one that showed an increase in mitochondrial degradation. Through work on this gene which mediates the escape of mtDNA, researchers discovered that mitochondrial turnover is triggered by proteins.[18]

More was discovered about genetic control of mitophagy after studies on the protein UTH1. After performing a screen for genes that regulate longevity, it was found in ΔUTH1 strains that there was an inhibition of mitophagy, which occurred without affecting autophagy mechanisms. This study also showed that the Uth1p protein is necessary to move mitochondria to the vacuole. This suggested there is a specialized system for mitophagy. Other studies looked at AUP1, a mitochondrial phosphatase, and found Aup1 marks mitochondria for elimination.[18]

Another yeast protein associated with mitophagy is a mitochondrial inner membrane protein, Mdm38p/Mkh1p. This protein is part of the complex that exchanges K+/H+ ions across the inner membrane. Deletions in this protein causes swelling, a loss of membrane potential, and mitochondrial fragmentation.[18]

Recently, it has been shown that ATG32 (autophagy related gene 32) plays a crucial role in yeast mitophagy. It is localized to the mitochondria. Once mitophagy is initiated, Atg32 binds to Atg11 and the Atg32-associated mitochondria are transported to the vacuole. Atg32 silencing stops recruitment of autophagy machinery and mitochondrial degradation. Atg32 is not necessary for other forms of autophagy.[19][20]

All of these proteins likely play a role in maintaining healthy mitochondria, but mutations have shown that dysregulation can lead to a selective degradation of mitochondria. Whether these proteins work in concert, are main players in mitophagy, or members in a larger network to control autophagy still remains to be elucidated.

Role in the immune response edit

Mitochondria play an important role in the functioning of the immune system. Mitochondrial damage-associated molecular patterns (DAMPs) such as parts of damaged organelles or mtDNA are secreted by cells following sterile inflammation, dysregulations in cell metabolism, or infection. There is evidence that these DAMPs act as one of the key triggers of the innate immune response. Mitophagy provides the elimination of non-functioning mitochondria and maintains mitochondrial homeostasis. Due to that, it can be seen as an immunomodulatory tool to keep the immune response in check.[21]

Hematopoiesis edit

In addition to immunomodulatory functions, mitophagy can regulate the fate of hematopoietic stem cells (HSC). Mitophagy impaired due to the deletion of autophagy-related genes led to a loss of HSC function, more likely as a result of mitochondrial damage that stimulated excessive ROS production. On the contrary, mitophagy induction appeared to be protective for HSC and directed stem cell differentiation to the myeloid lineage.[22]

Macrophages edit

Immune cell activation and the change in phenotype are followed by metabolic reprogramming. Activated cells, including macrophages, favor glycolysis, which is also accompanied by mitochondrial clearance through mitophagy. On the contrary, macrophage regulatory phenotypes (M2) are associated with the induction of oxidative phosphorylation, which is dependent on mitochondrial biogenesis.[23] This highlights the important role of mitophagy in the determination of the macrophage phenotype.

It is also important to mention that mitophagy impairment in macrophages is quite common in the early stages of different pathological states. Macrophages play an important role in the innate immune response. However, conditions leading to immune paralysis, e.g. sepsis, make them incapable of efficient bactericidal clearance. Hence, some studies highlighted the role of mitophagy as a biomarker of different stages of sepsis, as it is inhibited in the early stage and induced later.[24] Other reports showed compromised mitophagy in experimental and human kidney fibrosis. Some mitophagy-associated molecules such as Mfn2 and Parkin are negatively regulated in this pathological state. Consequently, the frequency of regulatory profibrotic M2 macrophages was higher, confirming the role of mitophagy in the induction of the pro-inflammatory M1 phenotype.[24][25]

Inflammasome edit

Many studies demonstrate that the release of mtROS and mtDNA as DAMPs plays a crucial role in the activation of the inflammasome and following inflammation mediated by IL-1β. NF-κB, a protein complex that is important for immune cell signaling, but also plays an important role in mitophagy induction, has been reported to control the activation of the inflammasome by adopting the p62-mitophagy pathway.[26]

The importance of mitophagy was demonstrated by the deletion of Beclin 1 and LC3b autophagy-associated genes in bone marrow-derived macrophages (BMDM). Defective mitophagy and accumulation of damaged mitochondria led to enhanced mtROS production and the release of cytosolic mtDNA. As a result, activation of the NLRP3 inflammasome increased.[26] Recently, it was shown that Parkin deficiency also triggered NLRP3 activation in a mtROS-dependent manner and as a result promoted viral clearance.[21][27] Furthermore, Pink1 and Parkin deficiency in a model of polymicrobial sepsis induced inflammasome activation and appeared to be critical in host protection.[28] Consistent with these reports, there are also studies describing the loss of the autophagy protein Atg16L1 which induced the cleavage of IL-1β by caspases associated with NLRP3.[21] Many other proteins are known to modulate mitophagy. Some are cell-specific, for example, macrophages produce stress-induced proteins that are known to induce mitophagy followed by inhibition of NLRP3 inflammasome assembly.[21][29] In general, it can be said that many pathological inflammatory responses are the result of an imbalance in the crosstalk between the inflammasome and the mitophagy.

Viral immune response edit

It is known that some viruses can modulate mitophagy (directly or indirectly) using different mechanisms and, as a result, cause a disbalance in the innate immune response.[21] mtDNA that exits damaged mitochondria acts as one of the triggers of type I interferon (IFN I) production. Some viruses can induce mitophagy and therefore inhibit the production of these crucial antiviral cytokines. There are reports of viral proteins directly or indirectly interacting with autophagy and mitophagy-associated proteins such as LC3 or Pink1-Parkin and usurping them to trigger mitophagy and subsequently inhibit IFN I responses.[21][30]

Mitochondria is a dynamic structure regulating its morphology by context-dependent constant fission and fusion. Fission is crucial for mitophagy, as it cuts off a small mitochondrial part that can be further engulfed by the autophagosome.[31] The viruses Hepatitis B (HBV) and hepatitis C (HCV) take advantage of this mechanism by inducing mitochondrial fission and following mitophagy. HBV stimulates the phosphorylation of Drp1, a fission-promoting GTPase molecule, and the expression and recruitment of Parkin. HCV is known to promote mitophagy by inducing ROS production. Other viruses such as Human Parainfluenza (HPIV3) regulate host immune responses by clearing mitochondrial antiviral-signaling protein (MAVS) located in the outer mitochondrial membrane. There are specific proteins produced by HPIV3 that induce mitophagy in the infected cell, thus promoting MAVS degradation and the corresponding inhibition of IFN I production. The same strategy is used by the SARS-CoV-encoded protein ORF-9b, which triggers the degradation of several mitochondrial proteins, including MAVS.[32][33]

Relation to disease edit

Cancer edit

As of 2020, the role of mitophagy in cancer is not fully understood. Some models of mitophagy, such as PINK1 or BNIP3-mediated mitophagy, have been associated with tumor suppression in humans and mice. Mitophagy associated with NIX, in contrast, is associated with tumor promotion.[34] In 1920 Otto Warburg observed that certain cancerous tumors display a metabolic shift towards glycolysis. This is referred to as the "Warburg effect", in which cancer cells produce energy via the conversion of glucose into lactate, even in the presence of oxygen (aerobic glycolysis). Despite nearly a century since it was first described, a lot of questions remained unanswered regarding the Warburg effect. Initially, Warburg attributed this metabolic shift to mitochondrial dysfunction in cancer cells. Further studies in tumor biology have shown that the increased growth rate in cancer cells is due to an overdrive in glycolysis (glycolytic shift), which leads to a decrease in oxidative phosphorylation and mitochondrial density. As a consequence of the Warburg effect, cancer cells would produce large amounts of lactate. The excess lactate is then released to the extracellular environment which results in a decrease in extracellular pH. This micro-environment acidification can lead to cellular stress, which would lead to autophagy. Autophagy is activated in response to a range of stimuli, including nutrient depletion, hypoxia, and activated oncogenes. However, it appears that autophagy can help in cancer cell survival under conditions of metabolic stress and it may confer resistance to anti-cancer therapies such as radiation and chemotherapy. Additionally, in the microenvironment of cancer cells, there is an increase in hypoxia-inducible transcription factor 1-alpha (HIF1A), which promotes expression of BNIP3, an essential factor for mitophagy.[35]

Parkinson's disease edit

Parkinson's disease is a neurodegenerative disorder pathologically characterized by death of the dopamine-producing neurons in the substantia nigra. There are several genetic mutations implicated in Parkinson's disease, including loss of function PINK1 [36] and Parkin.[9] Loss of function in either of these genes results in the accumulation of damaged mitochondria, and aggregation of proteins or inclusion bodies – eventually leading to neuronal death.

Mitochondria dysfunction is thought to be involved in Parkinson's disease pathogenesis. In spontaneous, usually aging related Parkinson's disease (non-genetically linked), the disease is commonly caused by dysfunctional mitochondria, cellular oxidative stress, autophagic alterations and the aggregation of proteins. These can lead to mitochondrial swelling and depolarization. It is important to keep the dysfunctional mitochondria regulated, because all of these traits could be induced by mitochondrial dysfunction and can induce cell death.[37] Disorders in energy creation by mitochondria can cause cellular degeneration, like those seen in the substantia nigra.[31]

Tuberculosis edit

Tuberculosis is a contagious disease caused by infection with the airborne pathogen Mycobacterium tuberculosis. Recent investigation has shown that chronic infection by Mycobacterium tuberculosis in the lungs or ex-vivo infection by non-pathogenic mycobacteria (M.bovis) elicits activation of the receptor-mediated pathway for mitophagy. Here the receptor mediated mitophagy pathways are elicited through NIX that gets upregulated during M. tuberculosis infection. Elicited NIX/BNIP3L receptor recruitment of LC3 molecules mediating formation of phagophore that engulf defective mitochondria directly [38]

References edit

  1. ^ Lewis, Margaret; Lewis, Warren (1915). "Mitochondria (and other cytoplamic structures) in tissue cultures" (PDF). American Journal of Anatomy. 17 (3): 339–401. doi:10.1002/aja.1000170304.
  2. ^ Ashford, TP; Porter, KR (1962). "Cytoplasmic components of hepatic cell lysosomes". The Journal of Cell Biology. 12 (1): 198–202. doi:10.1083/jcb.12.1.198. PMC 2106008. PMID 13862833.
  3. ^ Beaulaton, J; Lockshin, KR (1977). "Ultrastructural study of the normal degeneration of the intersegmental muscles of Anthereae polyphemus and Manduca sexta (Insecta, Lepidoptera) with particular reference of cellular autophagy". Journal of Morphology. 154 (1): 39–57. doi:10.1002/jmor.1051540104. PMID 915948. S2CID 34266828.
  4. ^ Scott, SV; Klionsky, DJ (1988). "Delivery of Proteins and organelles to the vacuole from the cytoplasm". Current Opinion in Cell Biology. 10 (4): 523–529. doi:10.1016/S0955-0674(98)80068-9. PMID 9719874.
  5. ^ Youle, R; Narendra, D (2011). "Mechanisms of mitophagy". Nature Reviews Molecular Cell Biology. 12 (1): 9–14. doi:10.1038/nrm3028. PMC 4780047. PMID 21179058.
  6. ^ Kim, I; et al. (2007). "Selective degradation of mitochondria by mitophagy". Archives of Biochemistry and Biophysics. 462 (2): 245–256. doi:10.1016/j.abb.2007.03.034. PMC 2756107. PMID 17475204.
  7. ^ Correia-Melo C, Marques FD, Anderson R, Hewitt G, Hewitt R, Cole J, Carroll BM, Miwa S, Birch J, Merz A, Rushton MD, Charles M, Jurk D, Tait SW, Czapiewski R, Greaves L, Nelson G, Bohlooly-Y M, Rodriguez-Cuenca S, Vidal-Puig A, Mann D, Saretzki G, Quarato G, Green DR, Adams PD, von Zglinicki T, Korolchuk VI, Passos JF (2016). "Mitochondria are required for pro-ageing features of the senescent phenotype". The EMBO Journal. 35 (7): 724–42. doi:10.15252/embj.201592862. PMC 4818766. PMID 26848154. In multiple models of senescence, absence of mitochondria reduced a spectrum of senescence effectors and phenotypes while preserving ATP production via enhanced glycolysis.
  8. ^ Jin, SM; Youle, RJ (2012). "PINK1- and Parkin-mediated mitophagy at a glance". J Cell Sci. 125 (4): 795–9. doi:10.1242/jcs.093849. PMC 3656616. PMID 22448035.
  9. ^ a b Kitada, T; Asakawa, S; Hattori, N; et al. (1998). "Mutations in the parkin gene cause autosomal recessive juvenile parkinsonism". Nature. 392 (6676): 605–8. Bibcode:1998Natur.392..605K. doi:10.1038/33416. PMID 9560156. S2CID 4432261.
  10. ^ a b c Lazarou M. "Keeping the immune system in check: a role for mitophagy. Immunol Cell Biol. 2014;
  11. ^ a b Kane, LA; Lazarou, M; Fogel, AI; et al. (2014). "PINK1 phosphorylates ubiquitin to activate Parkin E3 ubiquitin ligase activity". J Cell Biol. 205 (2): 143–53. doi:10.1083/jcb.201402104. PMC 4003245. PMID 24751536.
  12. ^ Narendra, D; Tanaka, A; Suen, DF; Youle, RJ (2009). "Parkin-induced mitophagy in the pathogenesis of Parkinson disease". Autophagy. 5 (5): 706–8. doi:10.4161/auto.5.5.8505. PMID 19377297.
  13. ^ Jiang, Ziwen; Kuo, Yu-Hsuan; Arkin, Michelle R. (2023-11-07). "Synthetic autophagy receptor". Autophagy. doi:10.1080/15548627.2023.2278954. ISSN 1554-8627. PMID 37934826.
  14. ^ Jiang, Ziwen; Kuo, Yu-Hsuan; Arkin, Michelle R. (2023-11-08). "Autophagy Receptor-Inspired Antibody-Fusion Proteins for Targeted Intracellular Degradation". Journal of the American Chemical Society. 145 (44): 23939–23947. doi:10.1021/jacs.3c05199. ISSN 0002-7863. PMC 10636752. PMID 37748140.
  15. ^ Saxton, William M.; Hollenbeck, Peter J. (2012). "The axonal transport of mitochondria". Journal of Cell Science. 125 (9): 2095–2104. doi:10.1242/jcs.053850. PMC 1533994. PMID 16306220.
  16. ^ Ashrafi G, Schlehe JS, Lavoie MJ, Schwartz TL (2014). "Mitophagy of damaged mitochondria occurs locally in distal neuronal axons and requires PINK1 and Parkin". J Cell Biol. 206 (5): 655–70. doi:10.1083/jcb.201401070. PMC 4151150. PMID 25154397.
  17. ^ Davis CH, Kim KY, Bushong EA, Mills EA, Boassa D, Shih T, Kinebuchi M, Phan S, Zhou Y, Bihlmeyer NA, Nguyen JV, Jin Y, Ellisman MH, Marsh-Armstrong N (2014). "Transcellular degradation of axonal mitochondria". Proc Natl Acad Sci U S A. 111 (26): 9633–8. Bibcode:2014PNAS..111.9633D. doi:10.1073/pnas.1404651111. PMC 4084443. PMID 24979790.
  18. ^ a b c Tolkovsky, AM (2009). "Mitophagy". Biochimica et Biophysica Acta (BBA) - Molecular Cell Research. 1793 (9): 1508–15. doi:10.1016/j.bbamcr.2009.03.002. PMID 19289147.
  19. ^ Kanki, T; et al. (2009). "Atg32 is a mitochondrial protein that confers selectivity during mitophagy". Dev Cell. 17 (1): 98–109. doi:10.1016/j.devcel.2009.06.014. PMC 2746076. PMID 19619495.
  20. ^ Vives-Bauza, C; Przedborski, S (2011). "Mitophagy: the latest problem for Parkinson's disease". Trends Mol Med. 17 (3): 158–65. doi:10.1016/j.molmed.2010.11.002. PMID 21146459.
  21. ^ a b c d e f Song, Yinjuan; Zhou, Yang; Zhou, Xiangmei (2020-11-25). "The role of mitophagy in innate immune responses triggered by mitochondrial stress". Cell Communication and Signaling. 18 (1): 186. doi:10.1186/s12964-020-00659-x. ISSN 1478-811X. PMC 7687798. PMID 33239048.
  22. ^ Skendros, Panagiotis; Mitroulis, Ioannis; Ritis, Konstantinos (2018-09-04). "Autophagy in Neutrophils: From Granulopoiesis to Neutrophil Extracellular Traps". Frontiers in Cell and Developmental Biology. 6: 109. doi:10.3389/fcell.2018.00109. ISSN 2296-634X. PMC 6131573. PMID 30234114.
  23. ^ Hu, Chenchen; Xuan, Yuxin; Zhang, Xiyang; Liu, Yang; Yang, Shuya; Yang, Kun (October 2022). "Immune cell metabolism and metabolic reprogramming". Molecular Biology Reports. 49 (10): 9783–9795. doi:10.1007/s11033-022-07474-2. ISSN 1573-4978. PMC 9189272. PMID 35696048.
  24. ^ a b Gkikas, Ilias; Palikaras, Konstantinos; Tavernarakis, Nektarios (2018). "The Role of Mitophagy in Innate Immunity". Frontiers in Immunology. 9: 1283. doi:10.3389/fimmu.2018.01283. ISSN 1664-3224. PMC 6008576. PMID 29951054.
  25. ^ Bhatia, Divya; Chung, Kuei-Pin; Nakahira, Kiichi; Patino, Edwin; Rice, Michelle C.; Torres, Lisa K.; Muthukumar, Thangamani; Choi, Augustine Mk; Akchurin, Oleh M.; Choi, Mary E. (2019-12-05). "Mitophagy-dependent macrophage reprogramming protects against kidney fibrosis". JCI Insight. 4 (23): e132826, 132826. doi:10.1172/jci.insight.132826. ISSN 2379-3708. PMC 6962025. PMID 31639106.
  26. ^ a b Yuk, Jae-Min; Silwal, Prashanta; Jo, Eun-Kyeong (2020-07-01). "Inflammasome and Mitophagy Connection in Health and Disease". International Journal of Molecular Sciences. 21 (13): 4714. doi:10.3390/ijms21134714. ISSN 1422-0067. PMC 7370205. PMID 32630319.
  27. ^ Li, Jian; Ma, Chunmei; Long, Fei; Yang, Dongxue; Liu, Xue; Hu, Yingchao; Wu, Chunyan; Wang, Bingwei; Wang, Min; Chen, Yunzi; Liu, Genyan; Moynagh, Paul N.; Zhou, Jiawei; Peng, Tao; Yang, Shuo (2019-06-28). "Parkin Impairs Antiviral Immunity by Suppressing the Mitochondrial Reactive Oxygen Species-Nlrp3 Axis and Antiviral Inflammation". iScience. 16: 468–484. Bibcode:2019iSci...16..468L. doi:10.1016/j.isci.2019.06.008. ISSN 2589-0042. PMC 6593176. PMID 31229895.
  28. ^ Cho, Dong-Hyung; Kim, Jin Kyung; Jo, Eun-Kyeong (2020-01-31). "Mitophagy and Innate Immunity in Infection". Molecules and Cells. 43 (1): 10–22. doi:10.14348/molcells.2020.2329. PMC 6999710. PMID 31999918.
  29. ^ Lu, Chunfeng; Jiang, Yiming; Xu, Wenxuan; Bao, Xiaofeng (2023-02-25). "Sestrin2: multifaceted functions, molecular basis, and its implications in liver diseases". Cell Death & Disease. 14 (2): 160. doi:10.1038/s41419-023-05669-4. ISSN 2041-4889. PMC 9968343. PMID 36841824.
  30. ^ Ren, Zhihua; Zhang, Xiaojie; Ding, Ting; Zhong, Zhijun; Hu, Hui; Xu, Zhiwen; Deng, Junliang (2020). "Mitochondrial Dynamics Imbalance: A Strategy for Promoting Viral Infection". Frontiers in Microbiology. 11: 1992. doi:10.3389/fmicb.2020.01992. ISSN 1664-302X. PMC 7472841. PMID 32973718.
  31. ^ a b Arduíno, DM; Esteves, AR; Cardoso, SM (2011). "Mitochondrial fusion/fission, transport and autophagy in Parkinson's disease: when mitochondria get nasty". Parkinson's Disease. 2011: 767230. doi:10.4061/2011/767230. PMC 3043324. PMID 21403911.
  32. ^ Fu, Cheng; Cao, Nan; Liu, Wenjun; Zhang, Zilin; Yang, Zihui; Zhu, Wenhui; Fan, Shuangqi (2022-12-16). "Crosstalk between mitophagy and innate immunity in viral infection". Frontiers in Microbiology. 13. doi:10.3389/fmicb.2022.1064045. ISSN 1664-302X. PMC 9800879. PMID 36590405.
  33. ^ Wang, Hongna; Zheng, Yongfeng; Huang, Jieru; Li, Jin (2021). "Mitophagy in Antiviral Immunity". Frontiers in Cell and Developmental Biology. 9: 723108. doi:10.3389/fcell.2021.723108. ISSN 2296-634X. PMC 8446632. PMID 34540840.
  34. ^ MacLeod, Kay F. (2020). "Mitophagy and Mitochondrial Dysfunction in Cancer". Annual Review of Cancer Biology. 4 (1): 41–60. doi:10.1146/annurev-cancerbio-030419-033405.
  35. ^ Pavlides, S; et al. (2012). "Warburg Meets Autophagy: Cancer-Associated Fibroblasts Accelerate Tumor Growth and Metastasis via Oxidative Stress, Mitophagy, and Aerobic Glycolysis". Antioxidants & Redox Signaling. 16 (11): 1264–1284. doi:10.1089/ars.2011.4243. PMC 3324816. PMID 21883043.
  36. ^ Valente, EM; Abou-sleiman, PM; Caputo, V; et al. (2004). "Hereditary early-onset Parkinson's disease caused by mutations in PINK1" (PDF). Science. 304 (5674): 1158–60. Bibcode:2004Sci...304.1158V. doi:10.1126/science.1096284. PMID 15087508. S2CID 33630092.
  37. ^ Esteves, AR; Arduíno, DM; Silva, DF; Oliveira, CR; Cardoso, SM (2011). "Mitochondrial Dysfunction: The Road to Alpha-Synuclein Oligomerization in PD". Parkinson's Disease. 2011: 693761. doi:10.4061/2011/693761. PMC 3026982. PMID 21318163.
  38. ^ Mahla, RS; et al. (2021). "NIX-mediated mitophagy regulate metabolic reprogramming in phagocytic cells during mycobacterial infection". Lancet Infectious Diseases. 126: 102046. doi:10.1016/j.tube.2020.102046. PMID 33421909. S2CID 231437641.

April 08, 2024
mitophagy, selective, degradation, mitochondria, autophagy, often, occurs, defective, mitochondria, following, damage, stress, process, mitophagy, first, described, over, hundred, years, margaret, reed, lewis, warren, harmon, lewis, ashford, porter, used, elec. Mitophagy is the selective degradation of mitochondria by autophagy It often occurs to defective mitochondria following damage or stress The process of mitophagy was first described over a hundred years ago by Margaret Reed Lewis and Warren Harmon Lewis 1 Ashford and Porter used electron microscopy to observe mitochondrial fragments in liver lysosomes by 1962 2 and a 1977 report suggested that mitochondria develop functional alterations which would activate autophagy 3 The term mitophagy was in use by 1998 4 Mitophagy is key in keeping the cell healthy It promotes turnover of mitochondria and prevents accumulation of dysfunctional mitochondria which can lead to cellular degeneration It is mediated by Atg32 in yeast and NIX and its regulator BNIP3 in mammals Mitophagy is regulated by PINK1 and parkin proteins In addition to the selective removal of damaged mitochondria mitophagy is also required to adjust mitochondrial numbers to changing cellular metabolic needs for steady state mitochondrial turnover and during certain cellular developmental stages such as during cellular differentiation of red blood cells 5 Contents 1 Role 2 Pathways 2 1 In mammals 2 2 In yeast 3 Role in the immune response 3 1 Hematopoiesis 3 2 Macrophages 3 3 Inflammasome 3 4 Viral immune response 4 Relation to disease 4 1 Cancer 4 2 Parkinson s disease 4 3 Tuberculosis 5 ReferencesRole editOrganelles and bits of cytoplasm are sequestered and targeted for degradation by the lysosome for hydrolytic digestion by a process known as autophagy Mitochondria metabolism leads to the creation of by products that lead to DNA damage and mutations Therefore a healthy population of mitochondria is critical for the well being of cells Previously it was thought that targeted degradation of mitochondria was a stochastic event but accumulating evidence suggest that mitophagy is a selective process 6 Generation of ATP by oxidative phosphorylation leads to the production of various reactive oxygen species ROS in the mitochondria and submitochondrial particles Formation of ROS as a mitochondrial waste product will eventually lead to cytotoxicity and cell death Because of their role in metabolism mitochondria are very susceptible to ROS damage Damaged mitochondria cause a depletion in ATP and a release of cytochrome c which leads to activation of caspases and onset of apoptosis Mitochondrial damage is not caused solely by oxidative stress or disease processes normal mitochondria will eventually accumulate oxidative damage hallmarks overtime which can be deleterious to mitochondria as well as to the cell These faulty mitochondria can further deplete the cell of ATP increase production of ROS and release proapoptopic proteins such as caspases Because of the danger of having damaged mitochondria in the cell the timely elimination of damaged and aged mitochondria is essential for maintaining the integrity of the cell This turnover process consists of the sequestration and hydrolytic degradation by the lysosome a process also known as mitophagy Mitochondrial depletion reduces a spectrum of senescence effectors and phenotypes while preserving ATP production via enhanced glycolysis 7 Pathways editIn mammals edit There are several pathways by which mitophagy is induced in mammalian cells The PINK1 and Parkin pathway is so far the best characterized This pathway starts by deciphering the difference between healthy mitochondria and damaged mitochondria A 64 kDa protein PTEN induced kinase 1 PINK1 has been implicated to detect mitochondrial quality PINK1 contains a mitochondrial targeting sequence MTS and is recruited to the mitochondria In healthy mitochondria PINK1 is imported through the outer membrane via the TOM complex and partially through the inner mitochondrial membrane via the TIM complex so it then spans the inner mitochondrial membrane The process of import into the inner membrane is associated with the cleavage of PINK1 from 64 kDa into a 60 kDa form PINK1 is then cleaved by PARL into a 52 kDa form This new form of PINK1 is degraded by proteases within the mitochondria This keeps the concentration of PINK1 in check in healthy mitochondria 8 In unhealthy mitochondria the inner mitochondrial membrane becomes depolarized This membrane potential is necessary for the TIM mediated protein import In depolarized mitochondria PINK1 is no longer imported into the inner membrane is not cleaved by PARL and PINK1 concentration increases in the outer mitochondrial membrane PINK1 can then recruit Parkin a cytosolic E3 ubiquitin ligase 9 It is thought that PINK1 phosphorylates Parkin ubiquitin ligase at S65 which initiates Parkin recruitment at the mitochondria 10 11 The phosphorylation site of Parkin at S65 is homologous to the site where ubiquitin is phosphorylated This phosphorylation activates Parkin by inducing dimerization an active state citation needed This allows for Parkin mediated ubiquitination on other proteins 10 Because of its PINK1 mediated recruitment to the mitochondrial surface Parkin can ubiquitylate proteins in the outer mitochondrial membrane 12 Some of these proteins include Mfn1 Mfn2 and mitoNEET 11 The ubiquitylation of mitochondrial surface proteins brings in mitophagy initiating factors Parkin promotes ubiquitin chain linkages on both K63 and K48 K48 ubiquitination initiates degradation of the proteins and could allow for passive mitochondrial degradation K63 ubiquitination is thought to recruit autophagy adaptors LC3 GABARAP which will then lead to mitophagy It is still unclear which proteins are necessary and sufficient for mitophagy and how these proteins once ubiquitylated initiate mitophagy Other pathways that can induce mitophagy includes mitophagy receptors on the outer mitochondrial membrane surface These receptors include NIX1 BNIP3 and FUNDC1 All of these receptors contain LIR consensus sequences that bind LC3 GABARAP which can lead to the degradation of the mitochondria In hypoxic conditions BNIP3 is upregulated by HIF1a BNIP3 is then phosphorylated at its serine residues near the LIR sequence which promotes LC3 binding FUNDCI is also hypoxia sensitive although it is constitutively present at the outer mitochondrial membrane during normal conditions 10 Mitophagy can also be artificially introduced by a series of synthetic autophagy receptors 13 that are composed of antibody fragments to recognize the mitochondrial outer membrane proteins 14 In neurons mitochondria are distributed unequally throughout the cell to areas where energy demand is high like at synapses and Nodes of Ranvier This distribution is maintained largely by motor protein mediated mitochondrial transport along the axon 15 While neuronal mitophagy is thought to occur primarily in the cell body it also occurs locally in the axon at sites distant from the cell body in both the cell body and the axon neuronal mitophagy occurs via the PINK1 Parkin pathway 16 Mitophagy in the nervous system may also occur transcellularly where damaged mitochondria in retinal ganglion cell axons can be passed to neighboring astrocytes for degradation 17 This process is known as transmitophagy In yeast edit Mitophagy in yeast was first presumed after the discovery of Yeast Mitochondrial Escape genes yme specifically yme1 Yme1 like other genes in the family showed increase escape of mtDNA but was the only one that showed an increase in mitochondrial degradation Through work on this gene which mediates the escape of mtDNA researchers discovered that mitochondrial turnover is triggered by proteins 18 More was discovered about genetic control of mitophagy after studies on the protein UTH1 After performing a screen for genes that regulate longevity it was found in DUTH1 strains that there was an inhibition of mitophagy which occurred without affecting autophagy mechanisms This study also showed that the Uth1p protein is necessary to move mitochondria to the vacuole This suggested there is a specialized system for mitophagy Other studies looked at AUP1 a mitochondrial phosphatase and found Aup1 marks mitochondria for elimination 18 Another yeast protein associated with mitophagy is a mitochondrial inner membrane protein Mdm38p Mkh1p This protein is part of the complex that exchanges K H ions across the inner membrane Deletions in this protein causes swelling a loss of membrane potential and mitochondrial fragmentation 18 Recently it has been shown that ATG32 autophagy related gene 32 plays a crucial role in yeast mitophagy It is localized to the mitochondria Once mitophagy is initiated Atg32 binds to Atg11 and the Atg32 associated mitochondria are transported to the vacuole Atg32 silencing stops recruitment of autophagy machinery and mitochondrial degradation Atg32 is not necessary for other forms of autophagy 19 20 All of these proteins likely play a role in maintaining healthy mitochondria but mutations have shown that dysregulation can lead to a selective degradation of mitochondria Whether these proteins work in concert are main players in mitophagy or members in a larger network to control autophagy still remains to be elucidated Role in the immune response editMitochondria play an important role in the functioning of the immune system Mitochondrial damage associated molecular patterns DAMPs such as parts of damaged organelles or mtDNA are secreted by cells following sterile inflammation dysregulations in cell metabolism or infection There is evidence that these DAMPs act as one of the key triggers of the innate immune response Mitophagy provides the elimination of non functioning mitochondria and maintains mitochondrial homeostasis Due to that it can be seen as an immunomodulatory tool to keep the immune response in check 21 Hematopoiesis edit In addition to immunomodulatory functions mitophagy can regulate the fate of hematopoietic stem cells HSC Mitophagy impaired due to the deletion of autophagy related genes led to a loss of HSC function more likely as a result of mitochondrial damage that stimulated excessive ROS production On the contrary mitophagy induction appeared to be protective for HSC and directed stem cell differentiation to the myeloid lineage 22 Macrophages edit Immune cell activation and the change in phenotype are followed by metabolic reprogramming Activated cells including macrophages favor glycolysis which is also accompanied by mitochondrial clearance through mitophagy On the contrary macrophage regulatory phenotypes M2 are associated with the induction of oxidative phosphorylation which is dependent on mitochondrial biogenesis 23 This highlights the important role of mitophagy in the determination of the macrophage phenotype It is also important to mention that mitophagy impairment in macrophages is quite common in the early stages of different pathological states Macrophages play an important role in the innate immune response However conditions leading to immune paralysis e g sepsis make them incapable of efficient bactericidal clearance Hence some studies highlighted the role of mitophagy as a biomarker of different stages of sepsis as it is inhibited in the early stage and induced later 24 Other reports showed compromised mitophagy in experimental and human kidney fibrosis Some mitophagy associated molecules such as Mfn2 and Parkin are negatively regulated in this pathological state Consequently the frequency of regulatory profibrotic M2 macrophages was higher confirming the role of mitophagy in the induction of the pro inflammatory M1 phenotype 24 25 Inflammasome edit Many studies demonstrate that the release of mtROS and mtDNA as DAMPs plays a crucial role in the activation of the inflammasome and following inflammation mediated by IL 1b NF kB a protein complex that is important for immune cell signaling but also plays an important role in mitophagy induction has been reported to control the activation of the inflammasome by adopting the p62 mitophagy pathway 26 The importance of mitophagy was demonstrated by the deletion of Beclin 1 and LC3b autophagy associated genes in bone marrow derived macrophages BMDM Defective mitophagy and accumulation of damaged mitochondria led to enhanced mtROS production and the release of cytosolic mtDNA As a result activation of the NLRP3 inflammasome increased 26 Recently it was shown that Parkin deficiency also triggered NLRP3 activation in a mtROS dependent manner and as a result promoted viral clearance 21 27 Furthermore Pink1 and Parkin deficiency in a model of polymicrobial sepsis induced inflammasome activation and appeared to be critical in host protection 28 Consistent with these reports there are also studies describing the loss of the autophagy protein Atg16L1 which induced the cleavage of IL 1b by caspases associated with NLRP3 21 Many other proteins are known to modulate mitophagy Some are cell specific for example macrophages produce stress induced proteins that are known to induce mitophagy followed by inhibition of NLRP3 inflammasome assembly 21 29 In general it can be said that many pathological inflammatory responses are the result of an imbalance in the crosstalk between the inflammasome and the mitophagy Viral immune response edit It is known that some viruses can modulate mitophagy directly or indirectly using different mechanisms and as a result cause a disbalance in the innate immune response 21 mtDNA that exits damaged mitochondria acts as one of the triggers of type I interferon IFN I production Some viruses can induce mitophagy and therefore inhibit the production of these crucial antiviral cytokines There are reports of viral proteins directly or indirectly interacting with autophagy and mitophagy associated proteins such as LC3 or Pink1 Parkin and usurping them to trigger mitophagy and subsequently inhibit IFN I responses 21 30 Mitochondria is a dynamic structure regulating its morphology by context dependent constant fission and fusion Fission is crucial for mitophagy as it cuts off a small mitochondrial part that can be further engulfed by the autophagosome 31 The viruses Hepatitis B HBV and hepatitis C HCV take advantage of this mechanism by inducing mitochondrial fission and following mitophagy HBV stimulates the phosphorylation of Drp1 a fission promoting GTPase molecule and the expression and recruitment of Parkin HCV is known to promote mitophagy by inducing ROS production Other viruses such as Human Parainfluenza HPIV3 regulate host immune responses by clearing mitochondrial antiviral signaling protein MAVS located in the outer mitochondrial membrane There are specific proteins produced by HPIV3 that induce mitophagy in the infected cell thus promoting MAVS degradation and the corresponding inhibition of IFN I production The same strategy is used by the SARS CoV encoded protein ORF 9b which triggers the degradation of several mitochondrial proteins including MAVS 32 33 Relation to disease editCancer edit As of 2020 the role of mitophagy in cancer is not fully understood Some models of mitophagy such as PINK1 or BNIP3 mediated mitophagy have been associated with tumor suppression in humans and mice Mitophagy associated with NIX in contrast is associated with tumor promotion 34 In 1920 Otto Warburg observed that certain cancerous tumors display a metabolic shift towards glycolysis This is referred to as the Warburg effect in which cancer cells produce energy via the conversion of glucose into lactate even in the presence of oxygen aerobic glycolysis Despite nearly a century since it was first described a lot of questions remained unanswered regarding the Warburg effect Initially Warburg attributed this metabolic shift to mitochondrial dysfunction in cancer cells Further studies in tumor biology have shown that the increased growth rate in cancer cells is due to an overdrive in glycolysis glycolytic shift which leads to a decrease in oxidative phosphorylation and mitochondrial density As a consequence of the Warburg effect cancer cells would produce large amounts of lactate The excess lactate is then released to the extracellular environment which results in a decrease in extracellular pH This micro environment acidification can lead to cellular stress which would lead to autophagy Autophagy is activated in response to a range of stimuli including nutrient depletion hypoxia and activated oncogenes However it appears that autophagy can help in cancer cell survival under conditions of metabolic stress and it may confer resistance to anti cancer therapies such as radiation and chemotherapy Additionally in the microenvironment of cancer cells there is an increase in hypoxia inducible transcription factor 1 alpha HIF1A which promotes expression of BNIP3 an essential factor for mitophagy 35 Parkinson s disease edit Parkinson s disease is a neurodegenerative disorder pathologically characterized by death of the dopamine producing neurons in the substantia nigra There are several genetic mutations implicated in Parkinson s disease including loss of function PINK1 36 and Parkin 9 Loss of function in either of these genes results in the accumulation of damaged mitochondria and aggregation of proteins or inclusion bodies eventually leading to neuronal death Mitochondria dysfunction is thought to be involved in Parkinson s disease pathogenesis In spontaneous usually aging related Parkinson s disease non genetically linked the disease is commonly caused by dysfunctional mitochondria cellular oxidative stress autophagic alterations and the aggregation of proteins These can lead to mitochondrial swelling and depolarization It is important to keep the dysfunctional mitochondria regulated because all of these traits could be induced by mitochondrial dysfunction and can induce cell death 37 Disorders in energy creation by mitochondria can cause cellular degeneration like those seen in the substantia nigra 31 Tuberculosis edit Tuberculosis is a contagious disease caused by infection with the airborne pathogen Mycobacterium tuberculosis Recent investigation has shown that chronic infection by Mycobacterium tuberculosis in the lungs or ex vivo infection by non pathogenic mycobacteria M bovis elicits activation of the receptor mediated pathway for mitophagy Here the receptor mediated mitophagy pathways are elicited through NIX that gets upregulated during M tuberculosis infection Elicited NIX BNIP3L receptor recruitment of LC3 molecules mediating formation of phagophore that engulf defective mitochondria directly 38 References edit Lewis Margaret Lewis Warren 1915 Mitochondria and other cytoplamic structures in tissue cultures PDF American Journal of Anatomy 17 3 339 401 doi 10 1002 aja 1000170304 Ashford TP Porter KR 1962 Cytoplasmic components of hepatic cell lysosomes The Journal of Cell Biology 12 1 198 202 doi 10 1083 jcb 12 1 198 PMC 2106008 PMID 13862833 Beaulaton J Lockshin KR 1977 Ultrastructural study of the normal degeneration of the intersegmental muscles of Anthereae polyphemus and Manduca sexta Insecta Lepidoptera with particular reference of cellular autophagy Journal of Morphology 154 1 39 57 doi 10 1002 jmor 1051540104 PMID 915948 S2CID 34266828 Scott SV Klionsky DJ 1988 Delivery of Proteins and organelles to the vacuole from the cytoplasm Current Opinion in Cell Biology 10 4 523 529 doi 10 1016 S0955 0674 98 80068 9 PMID 9719874 Youle R Narendra D 2011 Mechanisms of mitophagy Nature Reviews Molecular Cell Biology 12 1 9 14 doi 10 1038 nrm3028 PMC 4780047 PMID 21179058 Kim I et al 2007 Selective degradation of mitochondria by mitophagy Archives of Biochemistry and Biophysics 462 2 245 256 doi 10 1016 j abb 2007 03 034 PMC 2756107 PMID 17475204 Correia Melo C Marques FD Anderson R Hewitt G Hewitt R Cole J Carroll BM Miwa S Birch J Merz A Rushton MD Charles M Jurk D Tait SW Czapiewski R Greaves L Nelson G Bohlooly Y M Rodriguez Cuenca S Vidal Puig A Mann D Saretzki G Quarato G Green DR Adams PD von Zglinicki T Korolchuk VI Passos JF 2016 Mitochondria are required for pro ageing features of the senescent phenotype The EMBO Journal 35 7 724 42 doi 10 15252 embj 201592862 PMC 4818766 PMID 26848154 In multiple models of senescence absence of mitochondria reduced a spectrum of senescence effectors and phenotypes while preserving ATP production via enhanced glycolysis Jin SM Youle RJ 2012 PINK1 and Parkin mediated mitophagy at a glance J Cell Sci 125 4 795 9 doi 10 1242 jcs 093849 PMC 3656616 PMID 22448035 a b Kitada T Asakawa S Hattori N et al 1998 Mutations in the parkin gene cause autosomal recessive juvenile parkinsonism Nature 392 6676 605 8 Bibcode 1998Natur 392 605K doi 10 1038 33416 PMID 9560156 S2CID 4432261 a b c Lazarou M Keeping the immune system in check a role for mitophagy Immunol Cell Biol 2014 a b Kane LA Lazarou M Fogel AI et al 2014 PINK1 phosphorylates ubiquitin to activate Parkin E3 ubiquitin ligase activity J Cell Biol 205 2 143 53 doi 10 1083 jcb 201402104 PMC 4003245 PMID 24751536 Narendra D Tanaka A Suen DF Youle RJ 2009 Parkin induced mitophagy in the pathogenesis of Parkinson disease Autophagy 5 5 706 8 doi 10 4161 auto 5 5 8505 PMID 19377297 Jiang Ziwen Kuo Yu Hsuan Arkin Michelle R 2023 11 07 Synthetic autophagy receptor Autophagy doi 10 1080 15548627 2023 2278954 ISSN 1554 8627 PMID 37934826 Jiang Ziwen Kuo Yu Hsuan Arkin Michelle R 2023 11 08 Autophagy Receptor Inspired Antibody Fusion Proteins for Targeted Intracellular Degradation Journal of the American Chemical Society 145 44 23939 23947 doi 10 1021 jacs 3c05199 ISSN 0002 7863 PMC 10636752 PMID 37748140 Saxton William M Hollenbeck Peter J 2012 The axonal transport of mitochondria Journal of Cell Science 125 9 2095 2104 doi 10 1242 jcs 053850 PMC 1533994 PMID 16306220 Ashrafi G Schlehe JS Lavoie MJ Schwartz TL 2014 Mitophagy of damaged mitochondria occurs locally in distal neuronal axons and requires PINK1 and Parkin J Cell Biol 206 5 655 70 doi 10 1083 jcb 201401070 PMC 4151150 PMID 25154397 Davis CH Kim KY Bushong EA Mills EA Boassa D Shih T Kinebuchi M Phan S Zhou Y Bihlmeyer NA Nguyen JV Jin Y Ellisman MH Marsh Armstrong N 2014 Transcellular degradation of axonal mitochondria Proc Natl Acad Sci U S A 111 26 9633 8 Bibcode 2014PNAS 111 9633D doi 10 1073 pnas 1404651111 PMC 4084443 PMID 24979790 a b c Tolkovsky AM 2009 Mitophagy Biochimica et Biophysica Acta BBA Molecular Cell Research 1793 9 1508 15 doi 10 1016 j bbamcr 2009 03 002 PMID 19289147 Kanki T et al 2009 Atg32 is a mitochondrial protein that confers selectivity during mitophagy Dev Cell 17 1 98 109 doi 10 1016 j devcel 2009 06 014 PMC 2746076 PMID 19619495 Vives Bauza C Przedborski S 2011 Mitophagy the latest problem for Parkinson s disease Trends Mol Med 17 3 158 65 doi 10 1016 j molmed 2010 11 002 PMID 21146459 a b c d e f Song Yinjuan Zhou Yang Zhou Xiangmei 2020 11 25 The role of mitophagy in innate immune responses triggered by mitochondrial stress Cell Communication and Signaling 18 1 186 doi 10 1186 s12964 020 00659 x ISSN 1478 811X PMC 7687798 PMID 33239048 Skendros Panagiotis Mitroulis Ioannis Ritis Konstantinos 2018 09 04 Autophagy in Neutrophils From Granulopoiesis to Neutrophil Extracellular Traps Frontiers in Cell and Developmental Biology 6 109 doi 10 3389 fcell 2018 00109 ISSN 2296 634X PMC 6131573 PMID 30234114 Hu Chenchen Xuan Yuxin Zhang Xiyang Liu Yang Yang Shuya Yang Kun October 2022 Immune cell metabolism and metabolic reprogramming Molecular Biology Reports 49 10 9783 9795 doi 10 1007 s11033 022 07474 2 ISSN 1573 4978 PMC 9189272 PMID 35696048 a b Gkikas Ilias Palikaras Konstantinos Tavernarakis Nektarios 2018 The Role of Mitophagy in Innate Immunity Frontiers in Immunology 9 1283 doi 10 3389 fimmu 2018 01283 ISSN 1664 3224 PMC 6008576 PMID 29951054 Bhatia Divya Chung Kuei Pin Nakahira Kiichi Patino Edwin Rice Michelle C Torres Lisa K Muthukumar Thangamani Choi Augustine Mk Akchurin Oleh M Choi Mary E 2019 12 05 Mitophagy dependent macrophage reprogramming protects against kidney fibrosis JCI Insight 4 23 e132826 132826 doi 10 1172 jci insight 132826 ISSN 2379 3708 PMC 6962025 PMID 31639106 a b Yuk Jae Min Silwal Prashanta Jo Eun Kyeong 2020 07 01 Inflammasome and Mitophagy Connection in Health and Disease International Journal of Molecular Sciences 21 13 4714 doi 10 3390 ijms21134714 ISSN 1422 0067 PMC 7370205 PMID 32630319 Li Jian Ma Chunmei Long Fei Yang Dongxue Liu Xue Hu Yingchao Wu Chunyan Wang Bingwei Wang Min Chen Yunzi Liu Genyan Moynagh Paul N Zhou Jiawei Peng Tao Yang Shuo 2019 06 28 Parkin Impairs Antiviral Immunity by Suppressing the Mitochondrial Reactive Oxygen Species Nlrp3 Axis and Antiviral Inflammation iScience 16 468 484 Bibcode 2019iSci 16 468L doi 10 1016 j isci 2019 06 008 ISSN 2589 0042 PMC 6593176 PMID 31229895 Cho Dong Hyung Kim Jin Kyung Jo Eun Kyeong 2020 01 31 Mitophagy and Innate Immunity in Infection Molecules and Cells 43 1 10 22 doi 10 14348 molcells 2020 2329 PMC 6999710 PMID 31999918 Lu Chunfeng Jiang Yiming Xu Wenxuan Bao Xiaofeng 2023 02 25 Sestrin2 multifaceted functions molecular basis and its implications in liver diseases Cell Death amp Disease 14 2 160 doi 10 1038 s41419 023 05669 4 ISSN 2041 4889 PMC 9968343 PMID 36841824 Ren Zhihua Zhang Xiaojie Ding Ting Zhong Zhijun Hu Hui Xu Zhiwen Deng Junliang 2020 Mitochondrial Dynamics Imbalance A Strategy for Promoting Viral Infection Frontiers in Microbiology 11 1992 doi 10 3389 fmicb 2020 01992 ISSN 1664 302X PMC 7472841 PMID 32973718 a b Arduino DM Esteves AR Cardoso SM 2011 Mitochondrial fusion fission transport and autophagy in Parkinson s disease when mitochondria get nasty Parkinson s Disease 2011 767230 doi 10 4061 2011 767230 PMC 3043324 PMID 21403911 Fu Cheng Cao Nan Liu Wenjun Zhang Zilin Yang Zihui Zhu Wenhui Fan Shuangqi 2022 12 16 Crosstalk between mitophagy and innate immunity in viral infection Frontiers in Microbiology 13 doi 10 3389 fmicb 2022 1064045 ISSN 1664 302X PMC 9800879 PMID 36590405 Wang Hongna Zheng Yongfeng Huang Jieru Li Jin 2021 Mitophagy in Antiviral Immunity Frontiers in Cell and Developmental Biology 9 723108 doi 10 3389 fcell 2021 723108 ISSN 2296 634X PMC 8446632 PMID 34540840 MacLeod Kay F 2020 Mitophagy and Mitochondrial Dysfunction in Cancer Annual Review of Cancer Biology 4 1 41 60 doi 10 1146 annurev cancerbio 030419 033405 Pavlides S et al 2012 Warburg Meets Autophagy Cancer Associated Fibroblasts Accelerate Tumor Growth and Metastasis via Oxidative Stress Mitophagy and Aerobic Glycolysis Antioxidants amp Redox Signaling 16 11 1264 1284 doi 10 1089 ars 2011 4243 PMC 3324816 PMID 21883043 Valente EM Abou sleiman PM Caputo V et al 2004 Hereditary early onset Parkinson s disease caused by mutations in PINK1 PDF Science 304 5674 1158 60 Bibcode 2004Sci 304 1158V doi 10 1126 science 1096284 PMID 15087508 S2CID 33630092 Esteves AR Arduino DM Silva DF Oliveira CR Cardoso SM 2011 Mitochondrial Dysfunction The Road to Alpha Synuclein Oligomerization in PD Parkinson s Disease 2011 693761 doi 10 4061 2011 693761 PMC 3026982 PMID 21318163 Mahla RS et al 2021 NIX mediated mitophagy regulate metabolic reprogramming in phagocytic cells during mycobacterial infection Lancet Infectious Diseases 126 102046 doi 10 1016 j tube 2020 102046 PMID 33421909 S2CID 231437641 Retrieved from https en wikipedia org w index php title Mitophagy amp oldid 1193393995, wikipedia, wiki, book, books, library,

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