A Novel Cell Death Mechanism Involving the Sphingosine‐to‐Glycerophospholipid Pathway

Abstract

Apoptosis is the most well‐studied form of cell death, but there exist other cell death pathways that also have roles in normal physiology and disease. It is unclear what other forms of cell death remain to be discovered and how these pathways could inform our understanding of cell and molecular biology. Caspase‐independent lethal 56 (CIL56) is a compound that kills cells via a novel cell death mechanism. We conducted a genome‐wide CRISPR screen to identify novel regulators of this death pathway. From the screen, we identified trans‐2‐enoyl‐CoA reductase (TECR) as a key regulator of CIL56‐induced death. TECR is localized to the endoplasmic reticulum and is required for very long‐chain fatty acid (VLCFA) synthesis. When the gene encoding TECR is disrupted, cells become resistant to CIL56‐induced death. We find that VLCFA synthesis is dispensable for CIL56‐induced death. On the contrary, TECR has a non‐canonical role in the conversion of sphingosine to palmitate in the sphingosine‐to‐glycerophospholipid pathway. Through chemical complementation analyses, we find that this pathway is important for death induction by CIL56. It remains unclear how this pathway could be acting to execute cell death. It is known that palmitate produced in the endoplasmic reticulum can be incorporated into ceramide species, which have long been associated with cell death. Preliminary lipidomic analyses reveal a dramatic increase in palmitoyl‐ceramide upon CIL56 treatment. We are investigating the role of this species in CIL56‐induced cell death to further characterize the mechanism of death and its importance.