20 Adult Neurogenesis in the Olfactory Bulb

P. Lledo
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引用次数: 4

Abstract

Most organisms rely on an olfactory system to detect and analyze chemical cues from the external world in the context of essential behavior. From worms to vertebrates, chemicals are detected by odorant receptors expressed by olfactory sensory neurons, which send an axon to the primary processing center—the olfactory bulb, in vertebrates. Within this relay, sensory neurons form excitatory synapses with projection neurons and with inhibitory interneurons. Thus, due to complex synaptic interactions in the olfactory bulb circuit, the output of a given projection neuron is determined not only by the sensory input, but also by the activity of local inhibitory interneurons that are concerned by adult neurogenesis throughout life. Recent studies have provided clues about how these new neurons incorporate into preexisting networks, how they survive or die once integrated into proper microcircuits, and how basic network functions are maintained despite the continual renewal of a large percentage of neurons. We know that external influences modulate the process of late neurogenesis at various stages. Thus, this process is probably flexible, allowing brain performance to be optimized for its environment. But optimized how? And why? This chapter describes the adaptation of new interneuron production to experience-induced plasticity. In particular, how the survival of newly generated neurons is highly sensitive not only to the level of sensory inputs, but also to the behavioral context is discussed. Also discussed is how neurogenesis may finely tune the functioning of the neural network, optimizing the processing of sensory information. Adult neurogenesis maintains continual turnover...
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嗅球中的成人神经发生
大多数生物依靠嗅觉系统来检测和分析来自外部世界的基本行为的化学线索。从蠕虫到脊椎动物,化学物质都是由嗅觉感觉神经元表达的气味受体检测到的,在脊椎动物中,嗅觉感觉神经元将轴突发送到初级处理中心——嗅球。在这个中继中,感觉神经元与投射神经元和抑制性中间神经元形成兴奋性突触。因此,由于嗅球回路中复杂的突触相互作用,给定的投射神经元的输出不仅取决于感觉输入,还取决于局部抑制性中间神经元的活动,这些神经元在整个生命过程中与成人神经发生有关。最近的研究提供了一些线索,包括这些新神经元是如何融入先前存在的网络的,它们在整合到适当的微电路后是如何生存或死亡的,以及尽管大量神经元不断更新,但基本的网络功能是如何维持的。我们知道,外部影响在不同阶段调节晚期神经发生的过程。因此,这个过程可能是灵活的,使大脑的表现能够根据环境进行优化。但是如何优化呢?,为什么?本章描述了新的中间神经元的产生对经验诱导的可塑性的适应。特别是,新生成的神经元的生存如何不仅对感觉输入的水平高度敏感,而且对行为环境也高度敏感。还讨论了神经发生如何精细地调节神经网络的功能,优化感觉信息的处理。成人神经发生保持持续的更新…
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