(1-Pyrenebutyryl)carnitine and 1-pyrenebutyryl coenzyme A: fluorescent probes for lipid metabolite studies in artificial and natural membranes

Abstract

Membrane properties of fatty acyl CoA and acylcarnitine were studied with 1-pyrenebutyryl-CoA [PB-CoA] and (1-pyrenebutyryl)carnitine [PBC]. These molecules have the spectroscopic properties of pyrene and its derivatives and exhibit biological and chemical characteristics related to the acyl esters. PBC is more soluble in nonpolar solvents than PB-CoA and critical micelle concentrations of both compounds resemble the medium-chain fatty acyl esters. PB-CoA inhibits phosphorylating (ADP-stimulated) respiration in rat liver mitochondria noncompetitively (KI = 2 .mu.M) and carnitine palmitoyl-CoA and octanoyl-CoA transferases competitively (KI = 2.1 .mu.M and 15 .mu.M, respectively). PBC does not inhibit carnitine palmitoyl-CoA transferase or mitochondrial respiration when glutamate-malate or succinate (+rotenone) is used as the respiratory substrate. PBC is a potent inhibitor of phosphorylating respiration with either palmitoylcarnitine (I50 =1.4 .mu.M) or octanoylcarnitine (I50 = 40 nM) as the respiratory substrate. The mitochondrial carnitine-acylcarnitine translocase is competitively inhibited by PBC with a KI = 0.6 .mu.M for palmitoylcarnitine exchange and 23 nM for carnitine exchange. PBC and PB-CoA exhibit excimer and monomer fluorescence, the relative intensities of which are functions of their microscopic concentrations. PB-CoA is accessible only to the outer half of artificial lipid vesicles while PBC may cross lipid vesicle bilayers. PBC in the inner half of the bilayer appears trapped, i.e., not easily removed by exogenous bovine serum albumin, which binds PBC.