AI Article Synopsis
- Tubular epithelial cells (TCs) are key components of the kidney that help maintain balance, with immature TCs able to replace damaged cells, while differentiated TCs cannot.
- To cope with frequent injuries, differentiated TCs can undergo polyploidization—gaining extra sets of chromosomes—which helps them enhance their function and survive stress.
- This article explores the phenomenon of TC polyploidy in various situations and aims to promote new insights and clinical applications in kidney health.
Article Abstract
Tubular epithelial cells (TCs) compose the majority of kidney parenchyma and play fundamental roles in maintaining homeostasis. Like other tissues, mostly immature TC with progenitor capabilities are able to replace TC lost during injury via clonal expansion and differentiation. In contrast, differentiated TC lack this capacity. However, as the kidney is frequently exposed to toxic injuries, evolution positively selected a response program that endows differentiated TC to maintain residual kidney function during kidney injury. Recently, we and others have described polyploidization of differentiated TC, a mechanism to augment the function of remnant TC after injury by rapid hypertrophy. Polyploidy is a condition characterized by >2 complete sets of chromosomes. Polyploid cells often display an increased functional capacity and are generally more resilient to stress as evidenced by being conserved across many plants and eukaryote species from flies to mammals. Here, we discuss the occurrence of TC polyploidy in different contexts and conditions and how this integrates into existing concepts of kidney cell responses to injury. Collectively, we aim at stimulating the acquisition of novel knowledge in the kidney field as well as accelerating the translation of this basic response mechanism to the clinical sphere.
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| http://dx.doi.org/10.1016/j.kint.2023.10.036 | DOI Listing |
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