T. Haruna et al., Alteration of the membrane lipid environment by L-palmitoylcarnitine modulates K-ATP channels in guinea-pig ventricular myocytes, PFLUG ARCH, 441(2-3), 2000, pp. 200-207
Sarcolemmal adenosine 5'-triphosphate-sensitive K+ channels (K-ATP) are dra
matically up-regulated by a membrane phospholipid, phosphatidyl-inositol-4,
5-bisphosphate (PIP2). During ischaemia, L-palmitoylcarnitine (L-PC), a fat
ty acid metabolite, accumulates in the sarcolemma and deranges the membrane
lipid environment. We therefore investigated whether alteration of the mem
brane lipid environment by L-PC modulates the K-ATP channel activity in ins
ide-out patches from guineapig ventricular myocytes. L-PC (1 muM) inhibited
K-ATP channel activity, without affecting the single channel conductance,
through interaction with Kir6.2. L-PC simultaneously enhanced the ATP sensi
tivity of the channel [concentration for half-maximal inhibition (IC50) fel
l from 62.0+/-2.7 to 30.3+/-5.5 muM]. In contrast, PIP2 attenuated the ATP
sensitivity (IC50 343.6+/-54.3 muM) and restored Ca2+-induced inactivation
of K-ATP channels (94.1+/-13.7% of the control current immediately before t
he Ca2+-induced inactivation). Pretreatment of the patch membrane with 1 mu
M L-PC, however, reduced the magnitude of the PIP2-induced recovery to 22.7
+/-6.3% of the control (P<0.01 vs. 94.1+/-13.7% in the absence of L-PC). Co
nversely, after the PIP2-induced recovery, L-PC's inhibitory action was att
enuated, but L-PC partly reversed the PIP2-mediated decrease in the ATP sen
sitivity (IC50 fell from 310+/-19.2 to 93.1+/-9.8 <mu>M). Thus, interaction
between L-PC and PIP2 in the plasma membrane appears to regulate K-ATP cha
nnels.