Mitochondrial ceramide-rich macrodomains functionalize Bax upon irradiation.

BACKGROUND: Evidence indicates that Bax functions as a "lipidic" pore to regulate mitochondrial outer membrane permeabilization (MOMP), the apoptosis commitment step, through unknown membrane elements. Here we show mitochondrial ceramide elevation facilitates MOMP-mediated cytochrome c release in HeLa cells by generating a previously-unrecognized mitochondrial ceramide-rich macrodomain (MCRM), which we visualize and isolate, into which Bax integrates. METHODOLOGY/PRINCIPAL FINDINGS: MCRMs, virtually non-existent in resting cells, form upon irradiation coupled to ceramide synthase-mediated ceramide elevation, optimizing Bax insertion/oligomerization and MOMP. MCRMs are detected by confocal microscopy in intact HeLa cells and isolated biophysically as a light membrane fraction from HeLa cell lysates. Inhibiting ceramide generation using a well-defined natural ceramide synthase inhibitor, Fumonisin B1, prevented radiation-induced Bax insertion, oligomerization and MOMP. MCRM deconstruction using purified mouse hepatic mitochondria revealed ceramide alone is non-apoptogenic. Rather Bax integrates into MCRMs, oligomerizing therein, conferring 1-2 log enhanced cytochrome c release. Consistent with this mechanism, MCRM Bax isolates as high molecular weight "pore-forming" oligomers, while non-MCRM membrane contains exclusively MOMP-incompatible monomeric Bax. CONCLUSIONS/SIGNIFICANCE: Our recent studies in the C. elegans germline indicate that mitochondrial ceramide generation is obligate for radiation-induced apoptosis, although a mechanism for ceramide action was not delineated. Here we demonstrate that ceramide, generated in the mitochondrial outer membrane of mammalian cells upon irradiation, forms a platform into which Bax inserts, oligomerizes and functionalizes as a pore. We posit conceptualization of ceramide as a membrane-based stress calibrator, driving membrane macrodomain organization, which in mitochondria regulates intensity of Bax-induced MOMP, and is pharmacologically tractable in vitro and in vivo.

Insertional mutagenesis of the mouse acid ceramidase gene leads to early embryonic lethality in homozygotes and progressive lipid storage disease in heterozygotes.

Ceramide is an important cellular lipid involved in signal transduction and the biosynthesis of complex sphingolipids. It can be hydrolyzed into sphingosine, another important signaling lipid, by the activity of ceramidases. Point mutations in the gene (Asah1) encoding one ceramidase, acid ceramidase (AC), lead to the lysosomal storage disorder Farber disease (FD). To investigate the role of AC in mammalian development, we disrupted the mouse gene Asah1 in embryonic stem cells by homologous recombination mediated insertion of an AC targeting vector into the wild-type sequence. Genotype analysis of over 150 offspring or embryos from heterozygous intercrosses revealed an absence of Asah1(-/-) individuals at embryonic day (E) 8.5 or later, although the ratio of wild-type to Asah1(+/-) individuals from these intercrosses was 1:2. Northern blot analysis showed that AC expression was turned on early in development, by E7.0, and continued through at least E17. In contrast, expression of the related lipid hydrolase, acid sphingomyelinase, was shut down by E11. Asah1(+/-) mice survived and lived a normal lifespan, but developed a progressive lipid storage disease in several of their organs, particularly the liver. These histopathological findings in Asah1(+/-) animals correlated with an up to twofold increase in the ceramide content of these tissues and a reduction n AC activity, confirming that the gene insertion event disrupted AC activity and ceramide metabolism. These results provide direct in vivo evidence that normal ceramide metabolism, and AC activity in particular, is essential for mammalian development. The animals and embryos described here should be a valuable resource for investigators studying the role of ceramide in cell growth and development, as well as those interested in the pathogenesis of FD and other sphingolipid storage disorders.