Implicaciones de las proteínas de choque térmico pequeñas (sHsp/HSPB) en el desarrollo de enfermedades degenerativas / As proteínas pequenas de choque do calor (sHsp/HSPB) e sua implicação no desenvolvimento de doenças degenerative / Small heat shock proteins (sHsp/HSPB) and their implication in the development of degenerative diseases

Las proteínas de choque térmico pertenecen al grupo de proteínas de estrés y son moléculas presentes en todas las células, se unen a los péptidos nacientes para dirigir su plegamiento, garantizando su estructura tridimensional y con ello su funcionamiento correcto. Dentro de éste grupo de moléculas se encuentran las proteínas de choque térmico pequeñas (sHsp/HSPB), también, capaces de unirse a péptidos y proteínas dañadas por diversos tipos de agresiones, facilitando su reparación o degradación. En células expuestas a situaciones adversas produce un rápido aumento en las concentraciones de estas proteínas. Aunque inicialmente se asoció la expresión de las proteínas de estrés a aumentos bruscos de temperatura, hoy día es conocido que existen en condiciones fisiológicas normales y sus concentraciones aumentan en respuesta a un amplio espectro de agresiones ambientales como: infecciones virales, inflamaciones, cuadros febriles, exposición acompuestos citotóxicos, acidificación del pH, anoxia o shock térmico....

The small heat shock proteins (sHsp/HSPB) and their implication in the development of degenerative diseases. Stress proteins are present in all the cells and participate in the synthesis of proteins binding their selves to the newly formed peptides to direct their folding, thus ensuring their three-dimensional structure and appropriate functioning. Besides, stress proteins are able to bind to damaged peptides and proteins due to diverse types of aggressions, enabling their repair or degradation. When cells are exposed to adverse situations, a rapid increase in concentration of stress proteins occurs. Stress protein expression had been associated to heat shocks only, but nowadays we know that stress proteins are induced as a response to a wide array of physiological and environmental aggressions such as: viral infections,inflammations, febrile responses, cell exposure to cytotoxic compounds, pH acidification, anoxia, and heat shock. The production of this type of molecules is a defense mechanism that allows the cell to adapt to anomalous situations and increase its survival capacity. In our study we present a brief historical account on stress proteins, their association with some pathologies, and discuss the current state of knowledgeabout this type of molecules and the possible mechanisms involved in protein conformational disorders or proteopathies...

As proteínas pequenas de choque do calor (sHsp/HSPB) e sua implicação no desenvolvimento de doenças degenerative. As proteínas do estresse são moléculas presentes em todas as células e estão envolvidas no processo de síntese protéica, ligando-se aospeptídeos nascentes para dirigir o seu dobramento, o que garante sua estrutura tridimensional e, consequentemente, o seu bom funcionamento.Além disso, são capazes de se ligar a peptídeos e proteínas danificadas por diferentes tipos de agressão, facilitando a sua reparação ou degradação. Quando as células ficam expostas a situações adversas aumentam rapidamente as concentrações dessas proteínas. Embora no inicio associou-se a expressão das proteínas de estresse com uma mudança brusca de temperatura, atualmente é conhecido que elas são induzidas como resposta a um amplo espectro de agressões fisiológicas e ambientais, tais como: infecções virais, inflamações, febres, exposição das células a compostos citotóxicos, a acidificação do pH, anoxia ou choque térmico. A produção de tais células é um mecanismode defesa que permite à célula se adaptar a condições anormais e aumentar a sua capacidade de sobrevivência. Neste trabalho se apresenta um breve histórico das proteínas de estresse, a sua associação com certas doenças e se discute o estado atual do conhecimento sobre este tipo de moléculas e os possíveis mecanismos envolvidos nas doenças conformacionais ou proteinopatias....

Structural instability caused by a mutation at a conserved arginine in the alpha-crystallin domain of Chinese hamster heat shock protein 27.

Mutations in the alpha-crystallin domain of 4 of the small heat shock proteins (sHsp) (Hsp27/HspB1, alphaA-crystallin/ HspB4, alphaB-crystallin/HspB5, and HspB8) are responsible for dominant inherited diseases in humans. One such mutation at a highly conserved arginine residue was shown to cause major conformational defects and intracellular aggregation of alphaA- and alphaB-crystallins and HspB8. Here, we studied the effect of this Arg mutation on the structure and function of Hsp27. Chinese hamster Hsp27 with Arg148 replaced by Gly (Hsp27R148G) formed dimers in vitro and in vivo, which contrasted with the 12- or 24-subunit oligomers formed by the wild-type protein (Hsp27WT). Despite these alterations, Hsp27R148G had a chaperone activity almost as high as Hsp27WT. The dimers of Hsp27R148G did not further deoligomerize on phosphorylation and like the dimers formed by phosphorylated Hsp27WT were not affected by the deletion of the N-terminal WD/EPF (single letter amino acid code) motif, suggesting that mutation of Arg148, deletion of the N-terminal WD/EPF motif, and phosphorylation of Ser90 may produce similar structural perturbations. Nevertheless, the structure of Hsp27R148G appeared unstable, and the mutated protein accumulated as aggregates in many cells. Both a lower basal level of phosphorylation of Hsp27R148G and the coexpression of Hsp27WT could reduce the frequency of formation of these aggregates, suggesting possible mechanisms regulating the onset of the sHsp-mediated inherited diseases.

HspB8, a small heat shock protein mutated in human neuromuscular disorders, has in vivo chaperone activity in cultured cells.

The family of small heat shock proteins (sHsp) is composed of 10 members in mammals, four of which are found mutated in diseases associated with the accumulation of protein aggregates. Though many sHsp have demonstrated molecular chaperone activity in vitro in cell-free conditions, their activity in vivo in the normal cellular context remains unclear. In the present study, we investigated the capacity of the sHsp, HspB8/Hsp22, to prevent protein aggregation in the cells using the polyglutamine protein Htt43Q as a model. In control conditions, Htt43Q accumulated in perinuclear inclusions composed of SDS-insoluble aggregates. Co-transfected with Htt43Q, HspB8 became occasionally trapped within the inclusions; however, in most cells, HspB8 blocked inclusion formation. Biochemical analyses indicated that HspB8 inhibited the accumulation of SDS-insoluble Htt43Q as efficiently as Hsp40 which was taken as a positive control. Htt43Q then accumulated in the SDS-soluble fraction, provided that protein degradation was blocked by proteasome and autophagy inhibitors. In contrast, the other sHsp Hsp27/HspB1 and alphaB-crystallin/HspB5 had no effect. This suggested that HspB8 functions as a molecular chaperone, maintaining Htt43Q in a soluble state competent for rapid degradation. Analyses of Hsp27-HspB8 chimeric proteins indicated that the C-terminal domain of HspB8 contains the specific sequence necessary for chaperone activity. Missense mutations in this domain at lysine 141, which are found in human motor neuropathies, significantly reduced the chaperone activity of the protein. A decrease in the HspB8 chaperone activity may therefore contribute to the development of these diseases.

Essential role of the NH2-terminal WD/EPF motif in the phosphorylation-activated protective function of mammalian Hsp27.

Hsp27 is expressed at high levels after mild heat shock and contributes to making cells extremely resistant to subsequent treatments. The activity of the protein is regulated at the transcriptional level, but also by phosphorylation, which occurs rapidly during stress and is responsible for causing the dissociation of large 700-kDa Hsp27 oligomers into dimers. We investigated the mechanism by which phosphorylation and oligomerization modulate the protective activity of Chinese hamster Hsp27. In contrast to oligomer dissociation, which only required Ser90 phosphorylation, activation of Hsp27 thermoprotective activity required the phosphorylation of both Ser90 and Ser15. Replacement of Ser90 by Ala90, which prevented the dissociation of the oligomer upon stress, did cause a severe defect in the protective activity. Dissociation was, however, not a sufficient condition to activate the protein because replacement of Ser15 by Ala15, which caused little effect in the oligomeric organization of the protein, also yielded an inactive protein. Analyzes of mutants with short deletions in the NH2 terminus identified the Hsp27 WD/EPF or PF-rich domain as essential for protection, maintenance of the oligomeric structure, and in vitro chaperone activity of the protein. In light of a three-dimensional model of Hsp27 based on the crystallographic structure of wheat Hsp16.9, we propose that the conserved WD/EPF motif of mammalian Hsp27 mediates important intramolecular interactions with hydrophic surfaces of the alpha-crystallin domain of the protein. These interactions are destabilized by Ser90 phosphorylation, making the motif free to interact with heterologous molecular targets upon the additional phosphorylation of the nearby Ser15.

Distinct chaperone mechanisms can delay the formation of aggresomes by the myopathy-causing R120G alphaB-crystallin mutant.

A familial form of desmin-related myopathy (DRM) is associated with a missense mutation (R120G) in alphaB-crystallin (alphaB) and is characterized by intracellular desmin aggregation. Because alphaB is a molecular chaperone that participates in the assembly of desmin filaments, it has been suggested that the desmin aggregation might be due to the loss of alphaB function. We report here that alphaBR120G has indeed impaired in vivo function and structure as reflected by a highly reduced capacity to protect cells against heat shock and by an abnormal supramolecular organization even in cells not expressing desmin. In many cells, alphaBR120G accumulated in inclusion bodies that had characteristics of aggresomes concentrating around the centrosome following a microtubule-facilitated process. Three distinct chaperone mechanisms could reduce or even prevent the formation of the alphaBR120G aggresomes. Wild-type alphaB and Hsp27 prevented aggresome formation by co-oligomerizing with alphaBR120G. Hsp70 with its co-chaperone Hdj-1 or Chip-1 but not a mutant of Chip-1 lacking ubiquitin ligase activity, reduced the frequency of aggresome formation likely by targeting alphaBR120G for degradation. Finally, HspB8 interacted only transiently with alphaB but nonetheless rescued the alphaBR120G oligomeric organization, suggesting that it acted as a true chaperone assisting in the folding of the mutant protein. Hence, the formation of inclusion bodies in alphaBR120G-mediated DRM is probably due to the misfolding of alphaBR120G per se and can be delayed or prevented by expression of the wild type alphaB allele or other molecular chaperones, thereby explaining the adult onset of the disease.