Fromenty B, Freneaux E, Labbe G, Deschamps D, Larrey D, Letteron P, Pessayre D
Unité de Recherches de Physiopathologie Hépatique (INSERM U-24), Hôpital Beaujon, Clichy, France.
Biochem Pharmacol. 1989 Nov 1;38(21):3743-51. doi: 10.1016/0006-2952(89)90580-7.
Tianeptine is a new tricyclic antidepressant which is metabolized mainly by beta-oxidation of its heptanoic side chain. We determined the effects of tianeptine on the mitochondrial oxidation of natural fatty acids in mice. In vitro, tianeptine (0.5 mM) inhibited by only 32% the formation of beta-oxidation products from [1-14C]palmitic acid by hepatic mitochondria, but inhibited by 71% that from [1-14C]octanoic acid and by 51% that from [1-14C]butyric acid. The activity of the tricarboxylic acid cycle, assessed as the in vitro formation of [14C]CO2 from [1-14C]acetylcoenzyme A was decreased by 51% in the presence of tianeptine (0.5 mM). The inhibition of both beta-oxidation and the tricarboxylic acid cycle appeared reversible in mitochondria from mice exposed to tianeptine in vivo but incubated in vitro without tianeptine. In vivo, administration of tianeptine (0.0625 mmol/kg i.p.), decreased by 53 and 58%, respectively, the formation of [14C]CO2 from [1-14C]octanoic acid and [1-14C]butyric acid, but did not significantly decrease that from [1-14C]palmitic acid. After administration of high doses of tianeptine, however, formation of [14C]CO2 from [1-14C]palmitic acid became inhibited as well, transiently after 0.25 mmol/kg and durably (greater than 24 hr) after 0.75 mmol/kg i.p. Hepatic triglycerides were increased 24 hr after administration of 0.75 mmol/kg i.p. of tianeptine, but not after 0.25 mmol/kg i.p. Microvesicular steatosis of the liver was observed in some mice after 0.75 mmol/kg i.p., but not after 0.5 mmol/kg i.p. We conclude that tianeptine inhibits the oxidation of medium- and short-chain fatty acids in mice. Microvesicular steatosis, however, requires very large doses in mice (0.75 mmol/kg i.p., i.e. 600-times the oral dose in humans), and is therefore unlikely to occur in humans.
噻奈普汀是一种新型三环类抗抑郁药,主要通过其庚酸侧链的β-氧化进行代谢。我们测定了噻奈普汀对小鼠体内天然脂肪酸线粒体氧化的影响。在体外,噻奈普汀(0.5 mM)仅抑制肝脏线粒体由[1-14C]棕榈酸生成β-氧化产物的32%,但抑制由[1-14C]辛酸生成产物的71%,以及由[1-14C]丁酸生成产物的51%。以体外由[1-14C]乙酰辅酶A生成[14C]CO2来评估,三羧酸循环的活性在有噻奈普汀(0.5 mM)存在时降低了51%。在体内接触过噻奈普汀但体外培养时未加噻奈普汀的小鼠线粒体中,β-氧化和三羧酸循环的抑制似乎都是可逆的。在体内,腹腔注射噻奈普汀(0.0625 mmol/kg)分别使由[1-14C]辛酸和[1-14C]丁酸生成[14C]CO2的量降低了53%和58%,但未显著降低由[1-14C]棕榈酸生成的量。然而,在给予高剂量噻奈普汀后,由[1-14C]棕榈酸生成[14C]CO2也受到抑制,腹腔注射0.25 mmol/kg后为短暂抑制,0.75 mmol/kg后则持久抑制(超过24小时)。腹腔注射0.75 mmol/kg噻奈普汀24小时后肝脏甘油三酯增加,但0.25 mmol/kg腹腔注射后未增加。腹腔注射0.75 mmol/kg后,部分小鼠出现肝脏微泡性脂肪变性,但0.5 mmol/kg腹腔注射后未出现。我们得出结论,噻奈普汀抑制小鼠中、短链脂肪酸的氧化。然而,小鼠出现微泡性脂肪变性需要非常大的剂量(腹腔注射0.75 mmol/kg,即人类口服剂量的600倍),因此在人类中不太可能发生。
