👤 Y Hannun

The recent findings of sphingolipids as potential mediators of yeast heat stress responses led us to investigate their possible role in the heat-induced cell cycle arrest and subsequent recovery. The sphingolipid-deficient yeast strain 7R4 was found to lack the cell cycle arrest seen in the isogenic wild type. Furthermore, strain lcb1-100, which harbors a temperature-sensitive serine palmitoyltransferase, lacked increased de novo generated sphingoid bases upon heat stress. Importantly, this strain was found to lack the transient heat-induced G0/G1 arrest. These results indicate a role for sphingolipids and specifically those generated in the de novo pathway in the cell cycle arrest response to heat. To determine the bioactive sphingolipid regulating this response, an analysis of key mutants in the sphingolipid biosynthetic and degradation pathways was performed. Strains deleted in sphingoid base kinases, sphingoid phosphate phosphatase, lyase, or dihydrosphingosine hydroxylase were found to display the cell cycle arrest. Also, the knockout of a fatty acyl elongation enzyme, which severely attenuates ceramide production, displayed the arrest. These experiments suggested that the active species for cell cycle arrest were the sphingoid bases. In further support of these findings, exogenous phytosphingosine (10 microM) was found to induce transient arrest. Stearylamine did not induce an arrest, demonstrating chemical specificity, and L-erythro- was not as potent as D-erythro-dihydrosphingosine showing stereospecificity. To investigate a possible arrest mechanism, we studied the hyperstable Cln3 (Cln3-1) strain LDW6A that has been previously shown to be resistant to heat stress-induced cell cycle arrest. The strain containing Cln3-1 was found to be resistant to cell cycle arrest induced by exogenous phytosphingosine, indicating that Cln3 acts downstream of the sphingoid bases in this response. Interestingly, cell cycle recovery from the transient arrest was found to be dependent upon the sphingoid base kinases (LCB4, LCB5). Overall, this combination of genetic and pharmacologic results demonstrates a role for de novo sphingoid base biosynthesis by serine palmitoyltransferase in the transient G0/G1 arrest mediated through Cln3 via a novel mechanism. Show less

The late infantile and juvenile variants of Batten disease are genetically distinct neurodegenerative disorders. Hallmarks of Batten disease include cognitive and motor decline, seizures and blindness due to retinitis pigmentosa. Recently, the CLN3 gene responsible for the juvenile variant has been cloned. Also, apoptosis was proven to be the mechanism by which neurons and photoreceptors die. This paper provides mechanistic support for the occurrence of apoptosis in this disease: There was marked upregulation of Bcl-2 in brain from the late infantile and juvenile types at the protein and RNA levels both by immunocytochemistry and by Northern blot analysis; there were also a 42% to 197% increase in brain ceramide determinations in brains from three patients with the juvenile type and three patients with the late infantile type. Double immunolabeling of brain sections for apoptosis and Bcl-2 supported a protective role for Bcl-2 in the juvenile form of Batten disease. These results raise the possibility that the intact CLN3 gene is normally antiapoptotic, and that it could be an upstream regulator of ceramide. Show less