The RNA-binding protein RBM3, a cold shock protein whose expression is elevated under hypothermic conditions, plays an important role in cell survival; however, little is known about the mechanism underlying the mild hypothermia-mediated regulation of RBM3 expression and apoptosis. Here we show that the transcription factor NF-κB p65 is phosphorylated at Ser276 and activates RBM3 gene transcription via binding to a particular element within the promoter region in response to induced hypothermia, elevating the protein expression, and suppressing apoptosis. Treatment with caffeic acid phenethyl ester (CAPE), a potent and specific inhibitor that suppresses the translocation of NF-κB p65 from the cytoplasm to the nucleus, resulted in decreased levels of RBM3 mRNA and protein and increased incidence of apoptosis despite cells were cultured under hypothermic conditions. Overexpression of RBM3 abolished the induction of apoptosis in cells treated with CAPE, indicating that NF-κB p65-upregulated RBM3 expression is necessary for the suppression of apoptosis. In addition, experiments with cells overexpressing RBM3 supported the finding demonstrating that the mild hypothermia-mediated higher expression of RBM3 suppressed the induction of apoptosis. Conversely, experiments with cells deficient in RBM3 supported the finding demonstrating that the CAPE-mediated loss of RBM3 induced apoptosis. These results suggest that NF-κB p65 is a critical mediator of mild hypothermia, to which cells are exposed as an extracellular environment, and a central inducer of RBM3 expression, which is responsible for preventing cells from apoptosis. Moreover, CAPE may have a potential for the application to a therapeutic agent for the treatment of cancers.
Background: Mild hypothermia, i.e. maintenance of organ temperature by up to 8°C lower than body temperature, is a critical strategy for exerting some functions of the cells and organs normally, and is an useful therapy for recovering properly from some diseases, including myocardial infarction, cardiac arrest, brain injury, and ischemic stroke. Nevertheless, there were no focusses so far on organ temperature and potential responses of gene expression to organ temperature in organs of homeothermic animals that survive under normal conditions. Objective: The present study aimed to assess organ temperature in homeothermic animals and evaluate the effect of their organ temperature on the expression of the cold shock protein RNA binding motif protein 3 (RBM3), and to gain insights into the organ temperature-mediated regulation of RBM3 gene transcription via Nuclear factor β-light-chain-enhancer of activated B cells (NF-κB) p65, which had been identified as a transcription factor that is activated by undergoing the Ser276 phosphorylation and promotes the RBM3 gene expression during mild hypothermia. Methods: We measured the temperature of several organs, where RBM3 expression was examined, in female and male mice. Next, in male mice, we tested NF-κB p65 expression and its Ser276 phosphorylation in organs that have their lower temperature than body temperature and compared them with those in organs that have their temperature near body temperature. Results: Organ temperature was around 32°C in the brain and reproductive organs, which is lower than the body temperature, and around 37°C in the heart, liver, and kidney, which is comparable to the body temperature. The expression of RBM3 was detected greatly in the brain and reproductive organs with their organ temperature of around 32°C, and poorly in the heart, liver, and kidney with their organ temperature of around 37°C. In accordance with the changes in the RBM3 expression, the NF-κB p65 Ser276 phosphorylation was detected more greatly in the testis and brain with their organ temperature of around 32°C, than in the heart, liver, and kidney with their organ temperature of around 37°C, although the NF-κB p65 expression was unchanged among all the organs tested. Discussion: Our data suggested that organ temperature lower than body temperature causes the expression of RBM3 in the brain and reproductive organs of mice, and that lower organ temperature causes the NF-κB p65 activation through the Ser276 phosphorylation, resulting in an increase in the RBM3 gene transcription, in the brain and reproductive organs of mice. Conclusion: The study may present the possibility that organ temperature-induced alterations in gene expression are organ specific in homeotherms and the possibility that organ temperature-induced alterations in gene expression are transcriptionally regulated in some organs of homeotherms.
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