Matsuda Naoto, Lu Hui, Fukata Yuko, Noritake Jun, Gao Hongfeng, Mukherjee Sujay, Nemoto Tomomi, Fukata Masaki, Poo Mu-Ming
Division of Neurobiology, Department of Molecular and Cell Biology, Helen Wills Neuroscience Institute, University of California, Berkeley, California 94720, USA.
J Neurosci. 2009 Nov 11;29(45):14185-98. doi: 10.1523/JNEUROSCI.1863-09.2009.
Brain-derived neurotrophic factor (BDNF) is essential for neuronal survival and differentiation during development and for synaptic function and plasticity in the mature brain. BDNF-containing vesicles are widely distributed and bidirectionally transported in neurons, and secreted BDNF can act on both presynaptic and postsynaptic cells. Activity-dependent BDNF secretion from neuronal cultures has been reported, but it remains unknown where the primary site of BDNF secretion is and whether neuronal activity can trigger BDNF secretion from axons and dendrites with equal efficacy. Using BDNF fused with pH-sensitive green fluorescent protein to visualize BDNF secretion, we found that BDNF-containing vesicles exhibited markedly different properties of activity-dependent exocytic fusion at the axon and dendrite of cultured hippocampal neurons. Brief spiking activity triggered a transient fusion pore opening, followed by immediate retrieval of vesicles without dilation of the fusion pore, resulting in very little BDNF secretion at the axon. On the contrary, the same brief spiking activity induced "full-collapse" vesicle fusion and substantial BDNF secretion at the dendrite. However, full vesicular fusion with BDNF secretion could occur at the axon when the neuron was stimulated by prolonged high-frequency activity, a condition neurons may encounter during epileptic discharge. Thus, activity-dependent axonal secretion of BDNF is highly restricted as a result of incomplete fusion of BDNF-containing vesicles, and normal neural activity induces BDNF secretion from dendrites, consistent with the BDNF function as a retrograde factor. Our study also revealed a novel mechanism by which differential exocytosis of BDNF-containing vesicles may regulate BDNF-TrkB signaling between connected neurons.
脑源性神经营养因子(BDNF)在发育过程中对神经元的存活和分化至关重要,在成熟大脑中对突触功能和可塑性也至关重要。含BDNF的囊泡在神经元中广泛分布并双向运输,分泌的BDNF可作用于突触前和突触后细胞。已有报道称神经元培养物中存在活动依赖性BDNF分泌,但BDNF分泌的主要部位在哪里,以及神经元活动是否能以相同效率触发轴突和树突分泌BDNF,仍不清楚。我们利用与pH敏感绿色荧光蛋白融合的BDNF来可视化BDNF分泌,发现培养的海马神经元轴突和树突中,含BDNF的囊泡在活动依赖性胞吐融合特性上存在显著差异。短暂的尖峰活动触发短暂的融合孔开放,随后囊泡立即回收,融合孔不扩张,导致轴突处BDNF分泌极少。相反,相同的短暂尖峰活动在树突处诱导“完全塌陷”的囊泡融合和大量BDNF分泌。然而,当神经元受到长时间高频活动刺激时,轴突处可发生与BDNF分泌相关的完全囊泡融合,癫痫放电期间神经元可能会遇到这种情况。因此,由于含BDNF囊泡的不完全融合,BDNF的活动依赖性轴突分泌受到高度限制,正常神经活动诱导BDNF从树突分泌,这与BDNF作为逆行因子的功能一致。我们的研究还揭示了一种新机制,即含BDNF囊泡的差异性胞吐作用可能调节相连神经元之间的BDNF-TrkB信号传导。