Acetyl-L-carnitine flux to lipids in cells estimated using isotopomer spectral analysis.

Acetyl-L-carnitine is known as a reservoir of activated acetyl units and as a modulator of metabolic function. The objective of this study was to quantify the fate of the acetyl moiety of acetyl-L-carnitine in lipogenic pathways. Lipogenesis was studied in an adipocyte model, differentiated 3T3-L1 cells, and a hepatoma cell, HepG2 cells. Lipogenesis and ketogenesis were examined in rat hepatocytes. Both de novo synthesis and elongation of fatty acids were investigated using gas chromatography/mass spectrometry and [1,2-(13)C]acetyl-L-carnitine. Comparisons were performed with [13C]glucose and [13C]acetate. Isotopomer Spectral Analysis, a stable isotope method for differentiating between the enrichment of the precursor and the amount of synthesis was used to analyze the data. Acetyl-L-carnitine was generally less effective than acetate as a precursor for de novo lipogenesis. The effects of acetyl-L-carnitine were not identical to those of acetate plus carnitine as expected if acetyl-L-carnitine flux to acetyl CoA is controlled by carnitine acetyl transferase. Acetyl-L-carnitine (2 mM) contributed approximately 10% of the lipogenic acetyl-CoA used for synthesis and elongation as well as 6% of the ketogenic acetyl-CoA. No differences were found between the precursor enrichment for de novo lipogenesis and for elongation of saturated fatty acids. Flux of acetyl-L-carnitine to lipid was increased, not decreased, by the ATP citrate lyase inhibitor, -hydroxycitrate. In contrast, flux of glucose to lipid was dramatically decreased by this inhibitor. These results indicate that flux of acetyl-L-carnitine to lipid can bypass citrate and utilize cytosolic acetyl-CoA synthesis.

Phospholipid composition, phosphoinositide metabolism and metastatic capacity in murine melanoma B16 variants at different stages of growth.

Experimental efforts to identify characteristic features of metastatic subpopulations have led to the selection of strains of specialized cells with high and low metastatic potential in the hope that by studying their biochemical and biophysical properties we might start to clarify how tumour cells metastasize. We report data on the phospholipid composition of three variants of murine melanoma B16: F1, with low metastatic potential; F10, highly metastatic when injected i.v.; and BL6, highly metastatic, spontaneous metastases developing from a primary s.c. tumour. Cells were studied at different stages of growth: subconfluent cultures (40-70 x 10(3) cells/cm2) or dense cultures (140-170 x 10(3) cells/cm2). Total phospholipid content decreased as cell density increased in all variants; these changes can probably be related to the reduction in cell volume with increasing cell numbers in the well. As a consequence of this reduction, the amounts of individual phospholipids also decreased in dense cultures. Phosphatidylinositol behaved differently in the highly metastatic variants. In the F1 strain it was three times lower than would be expected from the total phospholipid reduction, while in F10 and BL6 levels increased when cell density increased. Differences in phosphatidylinositol level were also found between variants within each density, suggesting that phosphoinositide synthesis may be related to the metastatic potential of the variants. Incorporation of ([3H] myo)-inositol incorporation into phospholipids over a period of 4 h was greater in F1 cells than in F10 and BL6 at both cell densities.(ABSTRACT TRUNCATED AT 250 WORDS)