The neuronal stress response: nuclear translocation of heat shock proteins as an indicator of hyperthermic stress

Two characteristic features of the heat shock response, (i) induction of hsp70 protein and (ii) nuclear translocation of constitutive hsc70 and stress-inducible hsp70 protein, were utilized as markers of cellular stress in the rabbit brain. Following a physiologically relevant increase in body temperature of 2.7 ± .3°C, nonneuronal cell types, such as ependymal cells and oligodendrocytes, undergo a stress response as assayed by the above criteria. In contrast, several neuronal cell populations required an increased degree of hyperthermic stress (3.4 ± .2°C) before exhibiting nuclear translocation of constitutive hsc70 protein. Induction of hsp70 protein was not observed in these neuronal cells at either temperature. The present results suggest that certain neurons in the rabbit brain are buffered against induction of the heat shock response, perhaps due to their high constitutive levels of hsc70 protein

Mutant SOD1 detoxification mechanisms in intact single cells.

International audienceMutant superoxide dismutase 1 (mtSOD1) causes dominantly inherited amyotrophic lateral sclerosis (ALS). The mechanism for mtSOD1 toxicity remains unknown. Two main hypotheses are the impairment of proteasomal function and chaperone depletion by misfolded mtSOD1. Here, we employed FRET/FLIM and biosensor imaging to quantitatively localize ubiquitination, as well as chaperone binding of mtSOD1, and to assess their effect on proteasomal and protein folding activities. We found large differences in ubiquitination and chaperone interaction levels for wild-type (wt) SOD1 versus mtSOD1 in intact single cells. Moreover, SOD1 ubiquitination levels differ between proteasomal structures and cytoplasmic material. Hsp70 binding and ubiquitination of wt and mtSOD1 species are highly correlated, demonstrating the coupled upregulation of both cellular detoxification mechanisms upon mtSOD1 expression. Biosensor imaging in single cells revealed that mtSOD1 expression alters cellular protein folding activity but not proteasomal function in the neuronal cell line examined. Our results provide the first cell-by-cell-analysis of SOD1 ubiquitination and chaperone interaction. Moreover, our study opens new methodological avenues for cell biological research on ALS.Cell Death and Differentiation (2008) 15, 312-321; doi:10.1038/sj.cdd.4402262; published online 9 November 2007