Loss of cyclin A and G1-cell cycle arrest are a prerequisite of ceramide-induced toxicity in human arterial endothelial cells.

BACKGROUND: Ceramide is an important messenger of TNF- and lipid-induced apoptosis. We previously demonstrated the adverse effect of TNF in the process of reendothelialization as well as the dependence of its effect on cell-cycle regulation. The current study was designed to investigate the linkage between ceramide induced toxicity and growth arrest in human endothelial cells. METHODS AND RESULTS: Cultured human arterial endothelial cells (HAEC) served as an in-vitro model to test the cellular effects of C2-ceramide (C2). C2-induced cell death in HAECs occurred time- and dose-dependently. The LD(50) in subconfluent cells was three times lower than in confluent cell layers (25 vs. 75 microM). C2 caused up to 70% inhibition of BrdU and [3H]thymidine incorporation at non-toxic concentrations as a result of G1 cell-cycle arrest. Downregulation of cyclin A and p21(Cip1/Waf1) protein expression was observed independently of C2-toxicity, while expression of other cell-cycle regulatory genes was not affected. Inhibition of cyclin A protein expression by sequence-specific antisense-oligonucleotides was paralleled by significant growth-inhibition. The protein phosphatase inhibitor okadaic acid induced endothelial cell proliferation, which was completely abrogated by C2. In contrast, aphidicolin-synchronized endothelial cells demonstrated elevated cyclin A levels along with 30% higher BrdU-incorporation and 70% less C2-toxicity. G1-arrested cells, however, showed significantly enhanced C2-toxicity, lack of cyclin A expression and induction of uncleaved caspase-3 (CPP32). CONCLUSIONS: Ceramide abrogates endothelial cell proliferation independently of apoptosis or necrosis at low concentrations (

Chromosomal localization of two genes underlying late-infantile neuronal ceroid lipofuscinosis.

Classical late-infantile neuronal ceroid lipofuscinosis (LINCL; CLN2) is an inherited neurodegenerative disorder of childhood characterized by seizures, loss of vision, and progressive motor and mental deterioration. The hallmark of this disease is the accumulation of enlarged, secondary lysosomes packed with curvilinear bodies in cells of affected individuals. The biochemical basis of LINCL remains unknown and there is no treatment effective in delaying the progression of this fatal disorder. During a genome-wide search using a set of highly polymorphic markers and 15 affected individuals from 7 multi-affected families, we obtained evidence for linkage of the LINCL gene CLN2 with markers on chromosome 11p15.5. We then genotyped patients and all available family members, including 8 single-affected families, for markers spanning 15 cM of 11p15.5. We obtained a maximum two-point LOD score of 6.16 at 0 = 0.00 at the marker locus D11S2362. Multipoint analysis yielded a maximum LOD score of 6.90 localized to the same marker. Using haplotype analysis, we localized CLN2 to a minimum candidate region of 11 cM flanked by marker loci D11S4046 on the telomeric side and D11S1996 on the centromeric side. Additionally, we present data suggesting that the gene underlying a variant LINCL subtype found in Costa Rica maps to the region defined by the CLN6 locus on chromosome 15q21-23. The mapping of these two LINCL loci provides a genetic basis for understanding the clinical heterogeneity observed in this group of diseases.