果蝇中一种将动机状态与记忆表达整合在一起的神经回路机制。
A neural circuit mechanism integrating motivational state with memory expression in Drosophila.
作者信息
Krashes Michael J, DasGupta Shamik, Vreede Andrew, White Benjamin, Armstrong J Douglas, Waddell Scott
机构信息
Department of Neurobiology, University of Massachusetts Medical School, 364 Plantation Street, Worcester, MA 01605, USA.
出版信息
Cell. 2009 Oct 16;139(2):416-27. doi: 10.1016/j.cell.2009.08.035.
Abstract
Behavioral expression of food-associated memory in fruit flies is constrained by satiety and promoted by hunger, suggesting an influence of motivational state. Here, we identify a neural mechanism that integrates the internal state of hunger and appetitive memory. We show that stimulation of neurons that express neuropeptide F (dNPF), an ortholog of mammalian NPY, mimics food deprivation and promotes memory performance in satiated flies. Robust appetitive memory performance requires the dNPF receptor in six dopaminergic neurons that innervate a distinct region of the mushroom bodies. Blocking these dopaminergic neurons releases memory performance in satiated flies, whereas stimulation suppresses memory performance in hungry flies. Therefore, dNPF and dopamine provide a motivational switch in the mushroom body that controls the output of appetitive memory.
摘要
果蝇中与食物相关记忆的行为表达受饱腹感限制,受饥饿促进,这表明动机状态存在影响。在此,我们确定了一种整合饥饿内部状态和食欲记忆的神经机制。我们发现,刺激表达神经肽F(dNPF,哺乳动物NPY的直系同源物)的神经元可模拟食物剥夺并提高饱腹果蝇的记忆表现。强大的食欲记忆表现需要六个多巴胺能神经元中的dNPF受体,这些神经元支配蘑菇体的一个特定区域。阻断这些多巴胺能神经元可释放饱腹果蝇的记忆表现,而刺激则会抑制饥饿果蝇的记忆表现。因此,dNPF和多巴胺在蘑菇体中提供了一个动机开关,控制着食欲记忆的输出。
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