Abstract
The nonautonomous cell death by entosis was mediated by the so-called cell-in-cell structures, which were believed to kill the internalized cells by a mechanism dependent on acidified lysosomes. However, the precise values and roles of pH critical for the death of the internalized cells remained undetermined yet. We creatively employed keima, a fluorescent protein that displays different excitation spectra in responding to pH changes, to monitor the pH dynamics of the entotic vacuoles during cell-in-cell mediated death. We found that different cells varied in their basal intracellular pH, and the pH was relatively stable for entotic vacuoles containing live cells, but sharply dropped to a narrow range along with the inner cell death. In contrast, the lipidation of entotic vacuoles by LC3 displayed previously underappreciated complex patterns associated with entotic and apoptotic death, respectively. The pH decline seemed to play distinct roles in the two types of inner cell deaths, where apoptosis is preceded with moderate pH decline while a profound pH decline is likely to be determinate for entotic death. Whereas the cancer cells seemed to be lesser tolerant to acidified environments than noncancerous cells, manipulating vacuolar pH could effectively control inner cell fates and switch the ways whereby inner cell die. Together, this study demonstrated for the first time the pH dynamics of entotic vacuoles that dictate the fates of internalized cells, providing a rationale for tuning cellular pH as a potential way to treat cell-in-cell associated diseases such as cancer.
Highlights
Cell-in-cell structure (CICs) refers to a unique type of cellular structure characterized by the enclosure of one or more cells into the cytosolic vacuoles of another cell
It was proposed that entosis was a CICs-mediated type IV programmed death[26], which resulted in lysosomal entotic death as a predominant mechanism and apoptotic death as an Official journal of the Cell Death Differentiation Association
For accurate pH measurement based on keima excitation, we managed to make a correlation between the pH value and the ratio of keima excitations (550 nm/440 nm), and obtained pH titration curves for four entosis-proficient cell lines: MCF7, MCF10A, SW480 expressing E-cadherin (SW480/ E), and MDA-MB-231 expressing E-cadherin (MM231/E), respectively (Fig. 1B–E)
Summary
Cell-in-cell structure (CICs) refers to a unique type of cellular structure characterized by the enclosure of one or more cells into the cytosolic vacuoles of another cell. Recent studies implicated CICs in a wider range of biological processes, such as embryonic development[10], genome stability[11,12], virus infection[13,14], and Despite of the great progress made on the formation mechanisms for CICs, much less is known about the fate control of the internalized cell in CICs. It was proposed that entosis was a CICs-mediated type IV programmed death[26], which resulted in lysosomal entotic death as a predominant mechanism and apoptotic death as an Official journal of the Cell Death Differentiation Association. The dead inner cells were cleared by entotic vacuoles, as a huge lysosome through active fusion and fission processes[29,30]. Previous studies of the death mechanisms of the internalized cells had not dealt with the critical condition of lysosome acidification for cell death and degradation, and the determined turning point for the fates of internalized cells
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