Lysophosphatidylcholine (lysolecithins, referred to LPC) is oxidized from phosphatidylcholine by phospholipase A2. The physiological concentration of LPC in the blood is about 5-180 μM. LPC is accumulated during heart ischemia and contributes to arrhythmia and contractile dysfunction. However, the mechanism underlying LPC-induced damage remains unclear. We aimed to study the effects of LPC on cardiomyocyte gap junction. First, LPC did not affect cell survival. Although LPC did not alter the spontaneous contraction rates of cardiomyocytes, but arrhythmic beating was found. In functional study of scrape loading dye transfer assay, the distance of dye transfer decreased after LPC treatment, indicated that LPC impaired the gap junction intercellular communication (GJIC). We also found LPC treatment induced PKCalpha activation. This activation of PKCalpha increased the phosphorylation of connenix43-Ser368(P0-Cx43) and led to the decreased GJIC. Pre-treatment with the PKCalpha inhibitor (eV1-2) could restore the function of GJIC. In addition, we found that LPC increased intracellular calcium, induced activation of PKCalpha and CaMKII, and altered the distribution of Cx43 from the membrane to the cytoplasm. The calcium chelator (BAPTA-AM), PKCalpha inhibitor (Gö6976), and CaMKII inhibitor (KN93) could recover the function of GJIC. Gö6976 and KN93also recover the LPC-induced Cx43 redistribution. The expression of P2-Cx43 and P1-Cx43 also increased 1.3 folds after LPC treatment, but were not prevented by Gö6976 and KN93. Thus, LPC-induced phosphorylation of P2-Cx43 and P1-Cx43 might include other kinase. The hypothesis needs further studies to elucidate.