[
Semin Cell Dev Biol,
2023]
The plasma membrane is crucial to the survival of animal cells, and damage to it can be lethal, often resulting in necrosis. However, cells possess multiple mechanisms for repairing the membrane, which allows them to maintain their integrity to some extent, and sometimes even survive. Interestingly, cells that survive a near-necrosis experience can recognize sub-lethal membrane damage and use it as a signal to secrete chemokines and cytokines, which activate the immune response. This review will present evidence of necrotic cell survival in both in vitro and in vivo systems, including in C. elegans, mouse models, and humans. We will also summarize the various membrane repair mechanisms cells use to maintain membrane integrity. Finally, we will propose a mathematical model to illustrate how near-death experiences can transform dying cells into innate immune modulators for their microenvironment. By utilizing their membrane repair activity, the biological effects of cell death can extend beyond the mere elimination of the cells.
[
Journal of Gerontology,
1998]
Vanfleteren and colleagues present an interesting example of environmental conditions altering the kinetics of survival. Most previous studies of survival in C. elegans have used abundant bacteria as a food source. Such studies have found that the Gompertz function (exponential growth in mortality rate with age) gives a relatively good fit to survival curves, but that there is some deceleration in the rate of growth of mortality later in the life span. Yulong Yang and I have completed dozens of studies of small populations of the wild-type strain, N2, as well as strains TJ401, TJ411, TJ412,and BA713 in the presence of abundant bacteria in liquid or on agar. Survival curves were better fit by Gompertz more often than by Weibull or logistic functions (unpublished observations).
[
RNA Biol,
2014]
Small RNA programmed Argonautes are sophisticated cellular effector platforms known to be involved in a diverse array of functions ranging from mRNA cleavage, translational inhibition, DNA elimination, epigenetic silencing, alternative splicing and even gene activation. First observed in human cells, small RNA-induced gene activation, also known as RNAa, involves the targeted recruitment of Argonaute proteins to specific promoter sequences followed by induction of stable epigenetic changes which promote transcription. The existence of RNAa remains contentious due to its elusive mechanism. A string of recent studies in C. elegans provides unequivocal evidence for RNAa's fundamental role in sculpting the epigenetic landscape and maintaining active transcription of endogenous genes and supports the presence of a functionally sophisticated network of small RNA-Argonaute pathways consisting of opposite yet complementary "yin and yang" regulatory elements. In this review, we summarize key findings from recent studies of endogenous RNAa in C. elegans, with an emphasis on the Argonaute protein CSR-1.