An integrative approach to studying sphingolipid metabolism reveals p53 as a master regulator of the pathway
Botheina Ghandour, Saif Amin, Nihal Medatwal, Allen H. Lee, Gui-Qin Yu, Andrew E. Resnick, Sam B. Chiappone, Christopher J. Clarke, Daniel Canals, Yusuf A. Hannun, Chiara Luberto

TL;DR
This study shows that the tumor suppressor p53 plays a central role in regulating sphingolipid metabolism, especially in response to DNA damage.
Contribution
The study identifies p53 as a master regulator of sphingolipid metabolism through novel flux tracing and enzymatic assays.
Findings
Low-dose doxorubicin activates p53-dependent synthesis of specific dihydroceramide species.
p53 suppresses dihydroceramide desaturase activity at both low and high doxorubicin doses.
p53 influences sphingomyelin synthesis by affecting the Cer transport protein CERT1.
Abstract
Sphingolipids (SPLs) are bioactive lipids playing vital functions in cellular stress responses. The tumor suppressor p53 has been implicated in regulating a few specific SPL enzymes; however, a comprehensive understanding of p53’s overall impact on SPL metabolism is lacking. Here, we employed an integrative biochemical approach combining a novel flux tracing method (using d17dihydrosphingosine) with in situ enzymatic activity assays in the context of treatment with doxorubicin (Dox), a DNA-damaging agent causing well-established dose-dependent activation of p53. Furthermore, our previous studies established dose-specific modulation of SPLs by sublethal (low dose) versus lethal (high dose) Dox. Here, we exploited this model to focus on the role of p53, and found i) both low and high Dox enhanced the rate of synthesis of select dihydroceramide species, d17:0/16:0, d17:0/18:0, and…
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Taxonomy
TopicsSphingolipid Metabolism and Signaling · Pharmacological Receptor Mechanisms and Effects · Caveolin-1 and cellular processes
