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Abstract
Cold-inducible RNA-binding protein (CIRP) is a cold-shock protein which can be induced after exposure to a moderate cold-shock in different species ranging from amphibians to humans. Expression of CIRP can also be regulated by hypoxia, UV radiation, glucose deprivation, heat stress and H2O2, suggesting that CIRP is a general stress-response protein. In response to stress, CIRP can migrate from the nucleus to the cytoplasm and regulate mRNA stability through its binding site on the 3′-UTR of its targeted mRNAs. Through the regulation of its targets, CIRP has been implicated in multiple cellular process such as cell proliferation, cell survival, circadian modulation, telomere maintenance and tumor formation and progression. In addition, CIRP can also exert its functions by directly interacting with intracellular signaling proteins. Moreover, CIRP can be secreted out of cells. Extracellular CIRP functions as a damage-associated molecular pattern to promote inflammatory responses and plays an important role in both acute and chronic inflammatory diseases. Here, we summarize novel findings of CIRP investigation and hope to provide insights into the role of CIRP in cell biology and diseases.
Highlights
13 Pan Y, Cui Y, He H et al Developmental competence of mature yak vitrified-warmed oocytes is enhanced by IGF-I via modulation of Cold-inducible RNA-binding protein (CIRP) during in vitro maturation
CIRP is widely distributed across almost every cell in mammalian and is a stress responsive protein that is likely contributing to various stress responses differently through a combination of changes in protein levels and nucleocytoplasmic shuttling
Intracellular CIRP acts as an RNA chaperone, regulating mRNA stability through its binding sits on its targets, or transmit signals through interacting with other signaling proteins, regulating cell proliferation, cell survival, apoptosis and circadian rhythm, telomere maintenance and carcinoma progression
Summary
UV radiation Hypoxia Oxidative stress Osmotic shock Heat stress ER stress LPS stimulation. Cellular redox metabolism: thioredoxin Adhesion molecules: αE-β−catenin, C/E-cadherin Circadian mRNAs: Clock Reproduction-related genes in testis Telomerase components: TERT Response to hypoxia: HIF-1α
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