AI Article Synopsis
- Genetic mutations influence permanent changes in cell properties, while nongenetic mechanisms allow cells to quickly adapt to their environments through a process called 'cell-state transition.'
- Metals like copper and iron play crucial roles in these transitions by catalyzing important reactions in mitochondria and cell nuclei, which affect metabolism and epigenetics.
- The ability of cells to change identity without genetic alterations is vital in various biological processes, such as development, inflammation, aging, and cancer, highlighting the potential for using copper and iron in therapeutic applications.
Article Abstract
Whereas genetic mutations can alter cell properties, nongenetic mechanisms can drive rapid and reversible adaptations to changes in their physical environment, a phenomenon termed 'cell-state transition'. Metals, in particular copper and iron, have been shown to be rate-limiting catalysts of cell-state transitions controlling key chemical reactions in mitochondria and the cell nucleus, which govern metabolic and epigenetic changes underlying the acquisition of distinct cell phenotypes. Acquisition of a distinct cell identity, independently of genetic alterations, is an underlying phenomenon of various biological processes, including development, inflammation, erythropoiesis, aging, and cancer. Here, mechanisms that have been uncovered related to the role of these metals in the regulation of cell plasticity are described, illustrating how copper and iron can be exploited for therapeutic intervention.
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| http://dx.doi.org/10.1016/j.tcb.2024.07.005 | DOI Listing |
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