Cold-induced heat shock protein expression in rat aorta and brown adipose tissue.

Recent reports indicate that Heat Shock Proteins (HSPs) are induced in mammalian tissues as part of a homeostatic response to environmental stressors. Administration of sympathomimetic drugs and neuroendocrine stress hormones has been shown to evoke an HSP response in unstressed animals indicating that cell signaling events exists that couple specific neurotransmitter/hormone-receptor interactions with HSP expression in mammalian tissues. Herein, we demonstrate that exposure of rats to a cold ambient temperature (6 degrees C) results in increased expression of constitutive and inducible members of the HSP70 gene family in association with increased expression of the mitochondrial uncoupling protein in brown adipose tissue (BAT). Increased HSP70 expression was not restricted to BAT because HSP70 was also induced in the aorta. This cold-induced HSP response is characterized by a transient increase in HSP70 protein and mRNA in both tissues during continued exposure. Ganglionic blockade prevented cold-induced HSP70 expression in BAT and aorta, indicating that sympathetic activity is requisite to this response. Administration of the alpha 1-adrenergic receptor antagonist, prazosin, also blocked expression, further delineating possible signaling mechanisms mediating this response. Apparently, cells in some mammalian tissues have adopted unique cellular regulatory mechanisms to support HSP induction that have been incorporated into the physiological response of the entire organism to an environmental stressor.

Adrenergic regulation of the heat shock response in brown adipose tissue.

One of several ways that cells respond to damage or stress is by the expression of a set of highly conserved proteins termed, heat shock proteins (HSP). Induction of the heat shock response has been positively correlated with adaptation or protection of cells and tissues from the destructive effects of various types of stressors. Although heat can induce a generalized HSP response in most cells, the selective induction of HSP in specific cell populations by pharmacological agents may prove therapeutically useful for the protection of organs or tissues at risk for damage. Results from our studies suggest that the HSP response is integrated with fundamental physiological stress responses and demonstrate that distinct regulatory events couple neurotransmitter/hormone-receptor interactions with HSP expression in mammalian tissues. We demonstrate that the adrenergic receptor agonist, phenylephrine, induces HSP expression in brown adipose tissue (BAT). Apparently, this response is mediated by alpha-adrenergic receptors in BAT because prazosin, but not propranolol, blocks HSP induction and hexamethonium is without effect. Based on the transcripts induced and the magnitude of heat shock element-binding activity, phenylephrine appears to induce HSP expression through unique transcriptional regulatory mechanisms. The phenylephrine-induced HSP response is not unique to BAT as we have found that HSP are induced in other tissues as well. In BAT, HSP may facilitate the thermogenic function of this tissue, however, their function in other tissues remains unclear. The results of this study characterize a model system where the heat shock response is differentially evoked by a specific pharmacological agent and may aide in the development of treatment strategies to selectively target HSP expression in vivo.

Thermoregulatory and heat-shock protein response deficits in cold-exposed diabetic mice.

Cold-induced expression of heat-shock proteins (HSPs) has been suggested to facilitate thermogenesis in brown adipose tissue (BAT). However, the regulation of this response and the mechanism supporting this facilitation have not been established. Because of the significant role of insulin in maintaining BAT thermogenesis, we employed a transgenic mouse model of diabetes to investigate the regulation and function of HSPs in BAT thermogenesis. These transgenic mice overexpress a calmodulin minigene regulated by the rat insulin II promotor, resulting in severe diabetes characterized by elevated blood glucose and glucagon that coincides with reduced serum and pancreatic insulin. Body temperature (Tb) of diabetic mice dropped significantly faster during a 3-h cold exposure (6 degrees C) than Tb of similarly treated control littermates. Cold exposure resulted in increased levels of constitutive and inducible HSP70 transcripts in control mice, but only constitutive HSP70 mRNA transcripts were induced in diabetic mice. Diabetes did not affect uncoupling protein induction, but cold-induced expression of members of other HSP families was reduced. Correspondingly, heat-shock regulatory factors were not activated in diabetic mice even though these factors were present. Phenylephrine induced HSP70 expression in control and diabetic animals, indicating that alpha-receptor-coupled HSP induction remained intact in BAT of diabetic mice. Insulin replacement restored the Tb response of diabetic mice as well as the HSP response. From these results it is clear that physiological signals that regulate cold-induced activation of BAT also regulate HSP expression in this tissue. This diabetic model provides a novel system in which the HSP response to cold has been selectively knocked out, making it a useful tool for the study of HSP regulation and function in BAT.

Characterization and regulation of cold-induced heat shock protein expression in mouse brown adipose tissue.

The accumulation of heat shock proteins (HSPs) after the exposure of cells or organisms to elevated temperatures is well established. It is also known that a variety of other environmental and cellular metabolic stressors can induce HSP synthesis. However, few studies have investigated the effect of cold temperature on HSP expression. Here we report that exposure of Institute of Cancer Research (ICR) mice to cold ambient temperatures results in a tissue-selective induction of HSPs in brown adipose tissue (BAT) coincident with the induction of mitochondrial uncoupling protein synthesis. Cold-induced HSP expression is associated with enhanced binding of heat shock transcription factors to DNA, similar to that which occurs after exposure of cells or tissues to heat and other metabolic stresses. Adrenergic receptor antagonists were found to block cold-induced HSP70 expression in BAT, whereas adrenergic agonists induced BAT HSP expression in the absence of cold exposure. These findings suggest that norepinephrine, released in response to cold exposure, induces HSP expression in BAT. Norepinephrine appears to initiate transcription of HSP genes after binding to BAT adrenergic receptors through, as yet, undetermined signal transduction pathways. Thermogenesis results from an increase in activity and synthesis of several metabolic enzymes in BAT of animals exposed to cold challenge. The concomitant increase in HSPs may function to facilitate the translocation and activity of the enzymes involved in this process.

Dietary copper deficiency reduces heat shock protein expression in cardiovascular tissues.

Dietary copper deficiency impairs cardiovascular function by depression of catecholamine metabolism, and alteration of the structure and function of cardiac mitochondria. Heat shock proteins (HSPs) are a group of cellular homeostatic proteins that are induced in vascular tissue by catecholaminergic transmission after exposure to stress. We investigated the effects of dietary copper deficiency on the induction and accumulation of HSPs in several cardiovascular tissues. Stress-induced levels of aortic HSP70 mRNA were reduced in copper-deficient (CuD) rats when compared with copper-adequate (CuA) controls. Cocaine-induced HSP70 mRNA accumulation was not different between CuA and CuD rats, suggesting that reduced HSP70 levels in restrained CuD animals may result from altered catecholaminergic neurotransmission. The level of HSP60 mRNA was specifically reduced in the atria of CuD rats, which may be associated with altered mitochondrial structure and function. These results describe a novel relationship between dietary copper deficiency and the expression of highly conserved cellular stress response proteins. Loss of these essential homeostatic proteins in vascular tissue may contribute to the impairment of cardiovascular function known to accompany copper deficiency.