Chaperone-assisted selective autophagy

Chaperone-assisted selective autophagy is a cellular process for the selective, ubiquitin-dependent degradation of chaperone-bound proteins in lysosomes.^[1][2][3][4]

Autophagy (Greek: ‘self-eating’) was initially identified as a catabolic process for the unselective degradation of cellular content in lysosomes under starvation conditions.^[5][6] However, autophagy also comprises selective degradation pathways, which depend on ubiquitin conjugation to initiate sorting to lysosomes.^[7] In the case of chaperone-assisted selective autophagy, dysfunctional, nonnative proteins are recognized by molecular chaperones and become ubiquitinated by chaperone-associated ubiquitin ligases. The ubiquitinated proteins are enclosed in autophagosomes, which eventually fuse with lysosomes, leading to the degradation of the dysfunctional proteins. Chaperone-assisted selective autophagy is a vital part of the cellular protein quality control system. It is essential for protein homeostasis (proteostasis) in neurons and in mechanically strained cells and tissues such as skeletal muscle, heart and lung.^[1][2][3][4]

Components and mechanism

The chaperone-assisted selective autophagy complex comprises the molecular chaperones HSPA8 and HSPB8, and the cochaperones BAG3 and STUB1.^[2] based on the interactions of co-chaperones and clients, "HSPAs cooperate with multiple degradative pathways: i) the ubiquitin-proteasome system (UPS), by forming a protein complex with STUB1 and BAG1, or by interacting with BAG2 for the ubiquitin-independent delivery of substrates to the proteasome". BAG3 facilitates the cooperation of HSPA8 and HSPB8 during the recognition of nonnative client proteins. STUB1 mediates the ubiquitination of the chaperone-bound client, which induces the recruitment of the autophagic ubiquitin adaptor SQSTM1. The adaptor simultaneously interacts with the ubiquitinated client and autophagosome membrane precursors, thereby inducing the autophagic engulfment of the client.^[7] Autophagosome formation during chaperone-assisted selective autophagy depends on an interaction of BAG3 with SYNPO2, which triggers the cooperation with a VPS18-containing protein complex that mediates the fusion of autophagosome membrane precursors.^[1] The formed autophagosomes finally fuse with lysosomes, resulting in client degradation.

Clients and physiological role

Proteins that are degraded by chaperone-assisted selective autophagy include pathogenic forms of the Huntingtin protein, which cause Huntington's disease.^[4] Furthermore, the expression of the cochaperone BAG3 is upregulated in aged neuronal cells, which correlates with an increased necessity to dispose oxidatively damaged proteins through autophagy.^[3] Chaperone-assisted selective autophagy is thus essential for proteostasis in neurons.

In mechanically strained cells and tissues, chaperone-assisted selective autophagy mediates the degradation of the actin-crosslinking protein filamin.^[1][2] Mechanical tension results in unfolding of filamin, leading to recognition by the chaperone complex and to the autophagic degradation of damaged filamin. This is a prerequisite for the maintenance of the actin cytoskeleton in mechanically strained cells and tissues. Impairment of chaperone-assisted selective autophagy in patients and animal models causes muscle dystrophy and cardiomyopathy.^[8][9][10]

References

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2. Arndt V, Dick N, Tawo R, Dreiseidler M, Wenzel D, Hesse M, Fürst DO, Saftig P, Saint R, Fleischmann BK, Hoch M, Höhfeld J (January 2010). "Chaperone-assisted selective autophagy is essential for muscle maintenance". Curr Biol. 20 (2): 143–8. doi:10.1016/j.cub.2009.11.022. PMID 20060297.
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4. Carra S, Seguin SJ, Landry J (January 2008). "HspB8 and Bag3: a new chaperone complex targeting misfolded proteins to macroautophagy". Autophagy. 4 (2): 237–9. doi:10.4161/auto.5407. PMID 18094623.
5. Reggiori F, Klionsky DJ (February 2002). "Autophagy in the eukaryotic cell". Eukaryotic Cell. 1 (1): 11–21. doi:10.1128/EC.01.1.11-21.2002. PMC 118053. PMID 12455967.
6. Levine B, Klionsky DJ (April 2004). "Development by self-digestion: molecular mechanisms and biological functions of autophagy". Dev. Cell. 6 (4): 463–77. doi:10.1016/S1534-5807(04)00099-1. PMID 15068787.
7. Shaid S, Brandts CH, Serve H, Dikic I (January 2013). "Ubiquitination and selective autophagy". Cell Death Differ. 20 (1): 21–30. doi:10.1038/cdd.2012.72. PMC 3524631. PMID 22722335.
8. Selcen D, Muntoni F, Burton BK, Pegoraro E, Sewry C, Bite AV, Engel AG (January 2009). "Mutation in BAG3 causes severe dominant childhood muscular dystrophy". Ann Neurol. 65 (1): 83–9. doi:10.1002/ana.21553. PMC 2639628. PMID 19085932.
9. Homma S, Iwasaki M, Shelton GD, Engvall E, Reed JC, Takayama S (September 2006). "BAG3 deficiency results in fulminant myopathy and early lethality". Am J Pathol. 169 (3): 761–73. doi:10.2353/ajpath.2006.060250. PMC 1698816. PMID 16936253.
10. Sarparanta J, Jonson PH, Golzio C, Sandell S, Luque H, Screen M, McDonald K, Stajich JM, Mahjneh I, Vihola A, Raheem O, Penttilä S, Lehtinen S, Huovinen S, Palmio J, Tasca G, Ricci E, Hackman P, Hauser M, Katsanis N, Udd B (February 2009). "Mutations affecting the cytoplasmic functions of the co-chaperone DNAJB6 cause limb-girdle muscular dystrophy". Nat Genet. 44 (4): 450–5. doi:10.1038/ng.1103. PMC 3315599. PMID 22366786.