Department of Biophysics and Life Sciences, Graduate School of Arts and Sciences, The University of Tokyo Meguro, Japan.
Department of Biophysics and Life Sciences, Graduate School of Arts and Sciences, The University of Tokyo Meguro, Japan ; Bioinformatics Project (BIRD), Japan Science and Technology Agency, The University of Tokyo Meguro, Japan ; Core Research for Evolutional Science and Technology Project of Japan Science and Technology Agency, The University of Tokyo Meguro, Japan ; Department of Computer Science, School of Science and Technology, Meiji University Kawasaki, Japan.
Front Neural Circuits. 2014 Jun 2;8:56. doi: 10.3389/fncir.2014.00056. eCollection 2014.
Activin A is known as a neuroprotective factor produced upon acute excitotoxic injury of the hippocampus (in pathological states). We attempt to reveal the role of activin as a neuromodulator in the adult male hippocampus under physiological conditions (in healthy states), which remains largely unknown. We showed endogenous/basal expression of activin in the hippocampal neurons. Localization of activin receptors in dendritic spines (=postsynapses) was demonstrated by immunoelectron microscopy. The incubation of hippocampal acute slices with activin A (10 ng/mL, 0.4 nM) for 2 h altered the density and morphology of spines in CA1 pyramidal neurons. The total spine density increased by 1.2-fold upon activin treatments. Activin selectively increased the density of large-head spines, without affecting middle-head and small-head spines. Blocking Erk/MAPK, PKA, or PKC prevented the activin-induced spinogenesis by reducing the density of large-head spines, independent of Smad-induced gene transcription which usually takes more than several hours. Incubation of acute slices with activin for 2 h induced the moderate early long-term potentiation (moderate LTP) upon weak theta burst stimuli. This moderate LTP induction was blocked by follistatin, MAPK inhibitor (PD98059) and inhibitor of NR2B subunit of NMDA receptors (Ro25-6981). It should be noted that the weak theta burst stimuli alone cannot induce moderate LTP. These results suggest that MAPK-induced phosphorylation of NMDA receptors (including NR2B) may play an important role for activin-induced moderate LTP. Taken together, the current results reveal interesting physiological roles of endogenous activin as a rapid synaptic modulator in the adult hippocampus.
激活素 A 是一种已知的神经保护因子,在海马体的急性兴奋毒性损伤(在病理状态下)时产生。我们试图揭示激活素作为生理条件下(在健康状态下)成年雄性海马体中的神经调质的作用,这在很大程度上尚不清楚。我们显示了海马神经元中内源性/基础表达的激活素。通过免疫电子显微镜显示了激活素受体在树突棘(=突触后)中的定位。用激活素 A(10ng/ml,0.4nm)孵育海马体急性切片 2 小时会改变 CA1 锥体神经元中棘的密度和形态。激活素处理后,总棘密度增加了 1.2 倍。激活素选择性地增加大头棘的密度,而不影响中头棘和小头棘。阻断 Erk/MAPK、PKA 或 PKC 会通过减少大头棘的密度来阻止激活素诱导的棘形成,而不影响通常需要几个小时以上的 Smad 诱导的基因转录。用激活素孵育急性切片 2 小时,在弱θ爆发刺激下诱导适度的早期长时程增强(适度 LTP)。 follistatin、MAPK 抑制剂(PD98059)和 NMDA 受体 NR2B 亚基抑制剂(Ro25-6981)阻断了这种适度 LTP 的诱导。值得注意的是,单独的弱θ爆发刺激不能诱导适度 LTP。这些结果表明,MAPK 诱导的 NMDA 受体(包括 NR2B)磷酸化可能在激活素诱导的适度 LTP 中起重要作用。总之,目前的结果揭示了内源性激活素作为成年海马体中快速突触调节剂的有趣的生理作用。