The expanding number of members in the various human heat shock protein (HSP) families and the inconsistencies in their nomenclature have often led to confusion. Here, we propose new guidelines for the nomenclature of the human HSP families, HSPH (HSP110), HSPC (HSP90), HSPA (HSP70), DNAJ (HSP40), and HSPB (small HSP) as well as for the human chaperonin families HSPD/E (HSP60/HSP10) and CCT (TRiC). The nomenclature is based largely on the more consistent nomenclature assigned by the HUGO Gene Nomenclature Committee and used in the National Center of Biotechnology Information Entrez Gene database for the heat shock genes. In addition to this nomenclature, we provide a list of the human Entrez Gene IDs and the corresponding Entrez Gene IDs for the mouse orthologs.
Heat shock proteins (HSPs) were originally identified as stress-responsive proteins required to deal with proteotoxic stresses. Besides being stress-protective and possible targets for delaying progression of protein folding diseases, mutations in chaperones also have been shown to cause disease (chaperonopathies). The mechanism of action of the "classical", stress-inducible HSPs in serving as molecular chaperones preventing the irreversible aggregation of stress-unfolded or disease-related misfolded proteins is beginning to emerge. However, the human genome encodes several members for each of the various HSP families that are not stress-related but contain conserved domains. Here, we have reviewed the existing literature on the various members of the human HSPB (HSP27), HSPH (HSP110), HSPA (HSP70), and DNAJ (HSP40) families. Apart from structural and functional homologies, several diversities between members and families can be found that not only point to differences in client specificity but also seem to serve differential client handling and processing. How substrate specificity and client processing is determined is far from being understood.
A small number of heat-shock proteins have previously been shown to act protectively on aggregation of several proteins containing an extended polyglutamine (polyQ) stretch, which are linked to a variety of neurodegenerative diseases. A specific subfamily of heat-shock proteins is formed by the HSPB family of molecular chaperones, which comprises 10 members (HSPB1-10, also called small HSP). Several of them are known to act as anti-aggregation proteins in vitro. Whether they also act protectively in cells against polyQ aggregation has so far only been studied for few of them (e.g. HSPB1, HSPB5 and HSPB8). Here, we compared the 10 members of the human HSPB family for their ability to prevent aggregation of disease-associated proteins with an expanded polyQ stretch. HSPB7 was identified as the most active member within the HSPB family. It not only suppressed polyQ aggregation but also prevented polyQ-induced toxicity in cells and its expression reduces eye degeneration in a Drosophila polyQ model. Upon overexpression in cells, HSPB7 was not found in larger oligomeric species when expressed in cells and-unlike HSPB1-it did not improve the refolding of heat-denatured luciferase. The action of HSPB7 was also not dependent on the Hsp70 machine or on proteasomal activity, and HSPB7 overexpression alone did not increase autophagy. However, in ATG5-/- cells that are defective in macroautophagy, the anti-aggregation activity of HSPB7 was substantially reduced. Hence, HSPB7 prevents toxicity of polyQ proteins at an early stage of aggregate formation by a non-canonical mechanism that requires an active autophagy machinery.
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