Intracellular clusterin inhibits mitochondrial apoptosis by suppressing p53-activating stress signals and stabilizing the cytosolic Ku70-bax protein complex

Purpose: Secretory clusterin (sCLU)/apolipoprotein J is an extracellular chaperone that has been functionally implicated in DNA repair, cell cycle regulation, apoptotic cell death, and tumori-genesis. It exerts a prosurvival function against most therapeutic treatments for cancer and is currently an antisense target in clinical trials for tumor therapy. However, the molecular mechanisms underlying its function remained largely unknown. Experimental Design: The molecular effects of small interfering RNA-mediated sCLU depletion in nonstressed human cancer cells were examined by focusing entirely on the endogenously expressed sCLU protein molecules and combining molecular, biochemical, and microscopic approaches. Results: We report here that sCLU depletion in nonstressed human cancer cells signals stress that induces p53-dependent growth retardation and high rates of endogenous apoptosis. We discovered that increased apoptosis in sCLU-depleted cells correlates to altered ratios of pro- apoptotic to antiapoptotic Bcl-2 protein family members, is amplified by p53, and is executed by mitochondrial dysfunction. sCLU depletion-related stress signals originate from several sites, because sCLU is an integral component of not only the secretory pathway but also the nucleocytosolic continuum and mitochondria. In the cytoplasm, sCLU depletion disrupts the Ku70-Bax complex and triggers Bax activation and relocation to mitochondria. We show that sCLU binds and thereby stabilizes the Ku70-Bax protein complex serving as a cytosol retention factor for Bax. Conclusions: We suggest that elevated sCLU levels may enhance tumorigenesis by interfering with Bax proapoptotic activities and contribute to one of the major characteristics of cancer cells, that is, resistance to apoptosis. ©2009 American Association for Cancer Research

Applying broadband dielectric spectroscopy (BDS) for the biophysical characterization of mammalian tissues under a variety of cellular stresses

The dielectric properties of biological tissues can contribute non-invasively to a better characterization and understanding of the structural properties and physiology of living organisms. The question we asked, is whether these induced changes are effected by an endogenous or exogenous cellular stress, and can they be detected non-invasively in the form of a dielectric response, e.g., an AC conductivity switch in the broadband frequency spectrum. This study constitutes the first methodological approach for the detection of environmental stress-induced damage in mammalian tissues by the means of broadband dielectric spectroscopy (BDS) at the frequencies of 1–106 Hz. Firstly, we used non-ionizing (NIR) and ionizing radiation (IR) as a typical environmental stress. Specifically, rats were exposed to either digital enhanced cordless telecommunication (DECT) radio frequency electromagnetic radiation or to γ-radiation, respectively. The other type of stress, characterized usually by high genomic instability, was the pathophysiological state of human cancer (lung and prostate). Analyzing the results of isothermal dielectric measurements provided information on the tissues’ water fraction. In most cases, our methodology proved sufficient in detecting structural changes, especially in the case of IR and malignancy. Useful specific dielectric response patterns are detected and correlated with each type of stress. Our results point towards the development of a dielectric-based methodology for better understanding and, in a relatively invasive way, the biological and structural changes effected by radiation and developing lung or prostate cancer often associated with genomic instability. © 2017 by the authors; licensee MDPI, Basel, Switzerland