Department of Biology, University of Copenhagen, Denmark.
J Membr Biol. 2011 Jul;242(1):1-10. doi: 10.1007/s00232-011-9365-7. Epub 2011 Jun 18.
Na,K-ATPase activity, which is crucial for skeletal muscle function, undergoes acute and long-term regulation in response to muscle activity. The aim of the present study was to test the hypothesis that AMP kinase (AMPK) and the transcriptional coactivator PGC-1α are underlying factors in long-term regulation of Na,K-ATPase isoform (α,β and PLM) abundance and Na(+) affinity. Repeated treatment of mice with the AMPK activator AICAR decreased total PLM protein content but increased PLM phosphorylation, whereas the number of α- and β-subunits remained unchanged. The K(m) for Na(+) stimulation of Na,K-ATPase was reduced (higher affinity) after AICAR treatment. PLM abundance was increased in AMPK kinase-dead mice compared with control mice, but PLM phosphorylation and Na,K-ATPase Na(+) affinity remained unchanged. Na,K-ATPase activity and subunit distribution were also measured in mice with different degrees of PGC-1α expression. Protein abundances of α1 and α2 were reduced in PGC-1α +/- and -/- mice, and the β(1)/β(2) ratio was increased with PGC-1α overexpression (TG mice). PLM protein abundance was decreased in TG mice, but phosphorylation status was unchanged. Na,K-ATPase V (max) was decreased in PCG-1α TG and KO mice. Experimentally in vitro induced phosphorylation of PLM increased Na,K-ATPase Na(+) affinity, confirming that PLM phosphorylation is important for Na,K-ATPase function. In conclusion, both AMPK and PGC-1α regulate PLM abundance, AMPK regulates PLM phosphorylation and PGC-1α expression influences Na,K-ATPase α(1) and α(2) content and β(1)/β(2) isoform ratio. Phosphorylation of the Na,K-ATPase subunit PLM is an important regulatory mechanism.
钠钾-ATP 酶活性对骨骼肌功能至关重要,其会对肌肉活动做出急性和长期的调节。本研究旨在验证 AMP 激酶(AMPK)和转录共激活因子 PGC-1α 是否是影响钠钾-ATP 酶同工型(α、β和 PLM)丰度和 Na+亲和力的长期调节的潜在因素。反复用 AMPK 激活剂 AICAR 处理小鼠会降低总 PLM 蛋白含量,但增加 PLM 磷酸化,而 α 和 β 亚基数量保持不变。AICAR 处理后,Na+刺激钠钾-ATP 酶的 Km 值降低(亲和力增加)。与对照小鼠相比,AMPK 激酶失活小鼠的 PLM 丰度增加,但 PLM 磷酸化和 Na,K-ATP 酶 Na+亲和力保持不变。还在具有不同 PGC-1α 表达程度的小鼠中测量了钠钾-ATP 酶的活性和亚基分布。PGC-1α +/-和-/-小鼠的α1 和 α2 蛋白丰度降低,而 PGC-1α 过表达(TG 小鼠)时β(1)/β(2)比值增加。PLM 蛋白丰度在 TG 小鼠中降低,但磷酸化状态不变。PGC-1α TG 和 KO 小鼠的钠钾-ATP 酶 V(max)降低。体外实验诱导的 PLM 磷酸化增加了钠钾-ATP 酶的 Na+亲和力,证实了 PLM 磷酸化对钠钾-ATP 酶功能很重要。总之,AMPK 和 PGC-1α 均调节 PLM 丰度,AMPK 调节 PLM 磷酸化,而 PGC-1α 表达影响钠钾-ATP 酶α1 和α2 含量和β(1)/β(2)同工型比值。钠钾-ATP 酶亚基 PLM 的磷酸化是一个重要的调节机制。
