Abstract
Simple SummaryCancer cells display among its hallmark genomic instability. This is a progressive tendency in accumulate genome alteration which contributes to the damage of genes regulating cell division and tumor suppression. Genomic instability favors the appearance of survival-promoting mutations, increasing the likelihood that those mutations will propagate into daughter cells and have a significant impact on cancer progression. Among the many factor influencing this phenomenon, mitochondrial physiology is emerging. Mitochondria are bound to genomic instability by responding to DNA alteration to trigger cell death programs and as a source for DNA damage. Mitochondrial alterations prototypical of cancer can desensitize the mitochondrial route of cell death, facilitating the survival of cell acquiring new mutations, or can stimulate mitochondrial mediated DNA damage, boosting the mutation rate and genomic instability itself.Mitochondria are well known to participate in multiple aspects of tumor formation and progression. They indeed can alter the susceptibility of cells to engage regulated cell death, regulate pro-survival signal transduction pathways and confer metabolic plasticity that adapts to specific tumor cell demands. Interestingly, a relatively poorly explored aspect of mitochondria in neoplastic disease is their contribution to the characteristic genomic instability that underlies the evolution of the disease. In this review, we summarize the known mechanisms by which mitochondrial alterations in cancer tolerate and support the accumulation of DNA mutations which leads to genomic instability. We describe recent studies elucidating mitochondrial responses to DNA damage as well as the direct contribution of mitochondria to favor the accumulation of DNA alterations.
Highlights
Introduction published maps and institutional affilMitochondria are highly dynamic organelles that are quintessential for eukaryotic cells since they mediate fundamental activities indispensable to cells’ health
As the center of oxidative metabolism, mitochondria are the powerhouse of the cells, they participate in calcium (Ca2+ ) homeostasis, they are the principal source of reactive oxygen species (ROS) production and are involved in regulated cell deaths (RCD) [1,2]
While the exact mechanism by which DNA damage response (DDR) activates Ca2+ transfer is still to be elucidated, these results indicate that mitochondrial Ca2+ uptake is an active mechanism in the control of DDR induced RCD
Summary
Cells are continuously subjected to a large variety of DNA lesions, which can be generated endogenously (e.g., by oxidative stress) or exogenously (such as ultraviolet light, ionizing irradiation or DNA damaging drugs). PML [50] and PTEN [51] and the proto-oncogene AKT These can localize to MAMs where exert their pro- or antiapoptotic activities by altering Ip3 dependent Ca2+ -transfer and RCD. It has been demonstrated that BRCA1-associated protein 1 (BAP1) binds and stabilizes Ip3R3, modulating Ca2+ release from the ER to mitochondria, promoting RCD. FBXL impairs Ip3R3 stability, and favoring its degradation Both mechanisms result in a lower Ca2+ transfer, while leaving ER Ca2+ content unchanged. This potentiates the Ca2+ accumulation to mitochondria, empowering mPTP opening. This results in favored Ca2+ transfer, mPTP opening and RCD
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