Individual Cell Longevity, 'Life's Timekeeper', and Metazoan Evolution

Current Aging Science
David Neill

Abstract

It is proposed that a primary and fundamental aspect of metazoan evolution is an ability to control and extend the longevity of individual cells. This was achieved through an intracellular oscillator, dubbed 'Life's Timekeeper', which evolved in the hypothetical ancestor of all metazoans. Slower oscillatory frequencies directed metazoan evolution towards extended longevity of individual cells, enabling generation of many specialised types of terminally differentiated cells. As the longevity of these cells was still relatively short in more primitive metazoans, stem cells, capable of differentiating into all specialised cell types, were retained in order to replace senescent cells. With increasing cell longevity, continual replacement of all senescent cells was no longer necessary. Cells such as neurons could be sustained throughout life, enabling the evolution of brains, hence, complex behaviour and intelligence. In multicellular metazoans the oscillator remains synchronised across all cells. It coordinates the timing of all cell-cell signalling systems, hence controls the timing of development and aging/senescence. In advanced metazoans, where senescent cells are not continually replaced, it controls lifespan. With regards to ...Continue Reading

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