Reversible Nuclear-Lipid-Droplet Morphology Induced by Oleic Acid: A Link to Cellular-Lipid Metabolism.

Neutral lipids-involved in many cellular processes-are stored as lipid droplets (LD), those mainly cytosolic (cLD) along with a small nuclear population (nLD). nLD could be involved in nuclear-lipid homeostasis serving as an endonuclear buffering system that would provide or incorporate lipids and proteins involved in signalling pathways as transcription factors and as enzymes of lipid metabolism and nuclear processes. Our aim was to determine if nLD constituted a dynamic domain. Oleic-acid (OA) added to rat hepatocytes or HepG2 cells in culture produced cellular-phenotypic LD modifications: increases in TAG, CE, C, and PL content and in cLD and nLD numbers and sizes. LD increments were reversed on exclusion of OA and were prevented by inhibition of acyl-CoA synthetase (with Triacsin C) and thus lipid biosynthesis. Under all conditions, nLD corresponded to a small population (2-10%) of total cellular LD. The anabolism triggered by OA, involving morphologic and size changes within the cLD and nLD populations, was reversed by a net balance of catabolism, upon eliminating OA. These catabolic processes included lipolysis and the mobilization of hydrolyzed FA from the LD to cytosolic-oxidation sites. These results would imply that nLD are actively involved in nuclear processes that include lipids. In conclusion, nLD are a dynamic nuclear domain since they are modified by OA through a reversible mechanism in combination with cLD; this process involves acyl-CoA-synthetase activity; ongoing TAG, CE, and PL biosynthesis. Thus, liver nLD and cLD are both dynamic cellular organelles.

Partial prevention of hepatic lipid alterations in nude mice by neonatal thymulin gene therapy.

During adult life athymic (nude) male mice display not only a severe T-cell-related immunodeficiency but also endocrine imbalances and a moderate hyperglycemia. We studied the impact of congenital athymia on hepatic lipid composition and also assessed the ability of neonatal thymulin gene therapy to prevent the effects of athymia. We constructed a recombinant adenoviral vector, RAd-metFTS, expressing a synthetic DNA sequence encoding met-FTS, an analog of the thymic peptide facteur thymique sérique (FTS), whose Zn-bound biologically active form is known as thymulin. On postnatal day 1-2 homozygous (nu/nu) nude and heterozygous (nu/+) mice were injected with 10(8) pfu of RAd-metFTS or RAd-betagal (control vector) intramuscularly. The animals were processed at 52 d of age. Serum thymulin, glycemia, hepatic phospholipid FA composition and free and esterified cholesterol were determined. Adult homozygous male nudes were significantly (P < 0.01) hyperglycemic when compared with their heterozygous counterparts (2.04 vs. 1.40 g/L, respectively). The relative percentage of 16:0, 18:1 n-9, and 18:1n-7 FA was lower, whereas that of 18:0, 20:4n-6, and 22:6n-3 FA was higher, in hepatic phospholipid (PL) of nu/nu animals as compared with their nu/+ counterparts. Some of these alterations, such as that in the relative content of 22:6n-3 in liver PL and the unsaturation index, were completely or partially prevented by neonatal thymulin gene therapy. We conclude that the thymus influences lipid metabolism and that thymulin is involved in this modulatory activity.