De novo synthesis and elongation of fatty acids by subcellar fractions of monkey aorta.

Subcellular fractions of aorta of squirrel monkey (Saimiri sciureus) were examined for their ability to synthesize and elongate fatty acids. High-speed supernate (HSS) incorporated substantial quantities of malonyl CoA into fatty acids while acetyl CoA was much less effectively utilized. Acetyl-CoA carboxylase activity exceeded the amount of acetyl CoA incorporated into fatty acids and thus does not account for the low incorporation of this substrate. Microsomes used malonyl CoA and acetyl CoA equally well; mitochondria incorporated either acetyl CoA or acetate. The amounts of substrate incorporated into fatty acids (m micro moles/mg of protein per hr) were 2.3 for HSS, 1.2 for microsomes, and 0.9 for mitochondria. The synthesized fatty acids were separated by gas-liquid chromatography, radioassayed, extracted from the scintillation fluid, and decarboxylated. HSS completely synthesized palmitic and stearic acids from malonyl CoA. Microsomes and mitochondria utilized acetyl CoA to elongate endogenous fatty acids and gave mainly palmitic, stearic, and C(18) and C(20) monoenoic acids, with lesser amounts of other saturated and unsaturated fatty acids. A significant quantity of malonyl CoA was utilized by microsomes to yield a fatty acid tentatively identified as docosapentaenoic. Radioactive fatty acids are incorporated into various lipid classes by the particulate preparations. These studies demonstrate that aortic tissue in a nonhuman primate is able to carry out several processes of fatty acid metabolism and that the aortic synthesis and elongation of fatty acids may play an important role in providing fatty acids for incorporation into aortic lipids.