The consequences of expressing hsp70 in Drosophila cells at normal temperatures.

doi:10.1101/gad.6.8.1402

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GENES & DEVELOPMENT 6:1402-1413, 1992
ISSN 0890-9369

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The consequences of expressing hsp70 in Drosophila cells at normal temperatures.

J H Feder, J M Rossi, J Solomon, N Solomon, and S Lindquist

Howard Hughes Medical Institute, Department of Molecular Genetics and Cell Biology, University of Chicago, Illinois 60637.

Abstract

In Drosophila cells, regulatory mechanisms not only act to providerapid induction of hsp70 during heat shock but also to preventexpression at normal temperatures. To determine whether expressionof hsp70 is detrimental to cells growing at normal temperatures,we used heterologous promoters to force expression of the proteinin tissue culture cells and in larval salivary glands. Initially,constitutive expression of hsp70 substantially reduces the rateof cell growth. With continued expression, however, growth ratesrecover. At the same time, the intracellular distribution ofhsp70 changes. Immediately after induction, the protein is diffuselydistributed throughout the cell, but as growth resumes it coalescesinto discrete points of high concentration, which we term hsp70granules. hsp70 granules are also observed both in wild-typeDrosophila tissue culture cells and in salivary glands afterextended periods of recovery from heat shock. The protein inthese granules appears to be irreversibly inactivated. It cannotbe dispersed with a second heat shock, and cells containingthese granules do not show thermotolerance. Only partial overlapbetween hsp70 granules and lysosomes indicates that the granulesform independently of lysosomes. We conclude that expressionof hsp70 is detrimental to growth at normal temperatures. Wesuggest that the change in hsp70 distribution, from diffuseto granular, represents a mechanism for controlling the protein'sactivity by sequestration.

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