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Molecular and Cellular Biology, December 2001, p. 8575-8591, Vol. 21, No. 24
Institute of Molecular Medicine and Genetics,
Medical College of Georgia, Augusta, Georgia 30912
Received 11 May 2001/Returned for modification 21 July
2001/Accepted 21 September 2001
The murine hsp70 gene family includes the
evolutionarily conserved hsp70.1 and
hsp70.3 genes, which are the major
proteins induced by heat and other stress stimuli.
hsp70.1 and
hsp70.3 encode identical proteins which
protect cells and facilitate their recovery from stress-induced damage.
While the hsp70 gene family has been widely studied and
the roles of the proteins it encodes as molecular chaperones in a range
of human pathologies are appreciated, little is known about the
developmental regulation of hsp70.1 and
hsp70.3 expression and the in vivo
biological function of their products. To directly study the
physiological role of these proteins in vivo, we have generated mice
deficient in heat shock protein 70 (hsp70) by replacing the
hsp70.1 or
hsp70.3 gene with an in-frame
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.24.8575-8591.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Insights into Regulation and Function of the Major Stress-Induced
hsp70 Molecular Chaperone In Vivo: Analysis of Mice with Targeted
Gene Disruption of the hsp70.1 or
hsp70.3 Gene
-galactosidase sequence. We report here that the expression of
hsp70.1 and
hsp70.3 is developmentally regulated at
the transcriptional level, and an overlapping expression pattern for
both genes is observed during embryo development and in the tissues of
adult mice. hsp70.1
/ or
hsp70.3/ mice are viable
and fertile, with no obvious morphological abnormalities. In late
embryonic stage and adult mice, both genes are expressed constitutively
in tissues exposed directly to the environment (the epidermis and
cornea) and in certain internal organs (the epithelium of the tongue,
esophagus, and forestomach, and the kidney, bladder, and hippocampus).
Exposure of mice to thermal stress results in the rapid induction and
expression of hsp70, especially in organs not constitutively expressing
hsp70 (the liver, pancreas, heart, lung, adrenal cortex, and
intestine). Despite functional compensation in the
single-gene-deficient mice by the intact homologous gene (i.e.,
hsp70.3 in
hsp70.1/ mice and vice
versa), a marked reduction in hsp70 protein expression was observed in
tissues under both normal and heat stress conditions. At the cellular
level, inactivation of hsp70.1 or
hsp70.3 resulted in deficient maintenance
of acquired thermotolerance and increased sensitivity to heat
stress-induced apoptosis. The additive or synergistic effects exhibited
by coexpression of both hsp70 genes, and the
evolutionary significance of the presence of both hsp70 genes, is hence underlined.
*
Corresponding author. Mailing address: Institute of
Molecular Medicine and Genetics, Medical College of Georgia, 1120 15th St. CB-2803, Augusta, GA 30912-3175. Phone: (706) 721-8738. Fax: (706)
721-8732. E-mail: moskophidis{at}immag.mcg.edu.
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