染色质可塑性预先决定了神经元形成记忆痕迹的资格。

IF 44.7 1区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Science Pub Date : 2024-07-26 DOI:10.1126/science.adg9982

Giulia Santoni, Simone Astori, Marion Leleu, Liliane Glauser, Simon A. Zamora, Myriam Schioppa, Isabella Tarulli, Carmen Sandi, Johannes Gräff

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引用次数: 0

摘要

记忆是由稀疏的神经元群编码的，但这种稀疏性是如何产生的在很大程度上仍是未知数。我们发现，神经元是否有资格被招募到记忆痕迹中取决于其在编码前的表观遗传状态。小鼠外侧杏仁核中的主神经元显示出内在染色质可塑性，当实验升高染色质可塑性时，它有利于神经元被分配到编码集合中。这种染色质可塑性发生在突触可塑性的基础基因组区域，并伴随着单个神经元兴奋性的实时提高。最后，对表观遗传改变的神经元进行光遗传沉默可以阻止记忆表达，从而揭示了染色质可塑性与记忆痕迹形成之间的细胞自主关系。这些结果表明，神经元的表观遗传状态是信息编码的关键因素。

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Chromatin plasticity predetermines neuronal eligibility for memory trace formation

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Chromatin plasticity predetermines neuronal eligibility for memory trace formation

Memories are encoded by sparse populations of neurons but how such sparsity arises remains largely unknown. We found that a neuron’s eligibility to be recruited into the memory trace depends on its epigenetic state prior to encoding. Principal neurons in the mouse lateral amygdala display intrinsic chromatin plasticity, which when experimentally elevated favors neuronal allocation into the encoding ensemble. Such chromatin plasticity occurred at genomic regions underlying synaptic plasticity and was accompanied by increased neuronal excitability in single neurons in real time. Lastly, optogenetic silencing of the epigenetically altered neurons prevented memory expression, revealing a cell-autonomous relationship between chromatin plasticity and memory trace formation. These results identify the epigenetic state of a neuron as a key factor enabling information encoding.

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来源期刊

Science 综合性期刊-综合性期刊

CiteScore

61.10

自引率

0.90%

发文量

审稿时长

2.1 months

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