p(HGNC:HSPD1)
The ATP-dependent chaperones are comprised of the 5 HSP90s, 17 HSP70s, 14 HSP60s, 6 ER-specific, and 8 MITO-specific Hsp100/AAA+ ATPases, respectively. PubMed:25437566
Ranked by decreasing median aging correlation, the induction of sHSPs and TPR genes consistently ranked high and the HSP60s, HSP40s, and HSP70s were consistently repressed. PubMed:25437566
HSP60 is essential for maturation and maintenance of the mitochondrial proteome and is therefore intimately linked to energy production. PubMed:25784053
Many studies based on model systems support a role for candidates from each of the major chaperome families; HSP100, HSP90, HSP70, HSP60, HSP40, sHSPs, and TPR-domain-containing proteins in proteostasis. PubMed:27491084
The HSP40, HSP60 and HSP70 families were amongst the most repressed chaperones, with HSP70s being the most repressed group overall. However, in contrast with the broad spectrum of repressed chaperone families, sHSPs and the TPR co-chaperone proteins were the only families that were significantly induced. PubMed:27491084
The ATP-dependent chaperones are comprised of the 5 HSP90s, 17 HSP70s, 14 HSP60s, 6 ER-specific, and 8 MITO-specific Hsp100/AAA+ ATPases, respectively. PubMed:25437566
HSP60 is essential for maturation and maintenance of the mitochondrial proteome and is therefore intimately linked to energy production. PubMed:25784053
HSP60 is essential for maturation and maintenance of the mitochondrial proteome and is therefore intimately linked to energy production. PubMed:25784053
Many studies based on model systems support a role for candidates from each of the major chaperome families; HSP100, HSP90, HSP70, HSP60, HSP40, sHSPs, and TPR-domain-containing proteins in proteostasis. PubMed:27491084
Binding to GroEL prevents aggregation of these flexible folding intermediates, and subsequent folding depends critically on the global encapsulation of the substrate in the chaperonin cavity by the cochaperone GroES (7, 132–135). PubMed:23746257
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If you find BEL Commons useful in your work, please consider citing: Hoyt, C. T., Domingo-Fernández, D., & Hofmann-Apitius, M. (2018). BEL Commons: an environment for exploration and analysis of networks encoded in Biological Expression Language. Database, 2018(3), 1–11.