Presynaptic RNA binding protein regulation of learning and memory in C. elegans

突触前 RNA 结合蛋白对秀丽隐杆线虫学习和记忆的调节

• 批准号: 10734771
• 负责人: Ashley Hayden
• 金额: $ 4.77万
• 依托单位: BAYLOR COLLEGE OF MEDICINE
• 依托单位国家: 美国
• 财政年份: 2022
• 资助国家: 美国
• 起止时间: 2022-07-01 至 2025-06-30
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10734771
• 关键词: Adult; Alzheimer' s Disease; Animals; Area; Binding; Biological Assay; Caenorhabditis elegans; Cognitive; Communities; Data; Disease; Drosophila genus; Ensure; Exhibits; Family; Fluorescent in Situ Hybridization; Food; Fragile X Syndrome; Functional disorder; Genes; Genetic; Health; Homologous Gene; Human; Immunoprecipitation; Impaired cognition; Investigation; Learning; Mammals; Measures; Memory; Messenger RNA; Modeling; Molecular; Mus; Nematoda; Nervous System; Neurons; Odors; Oogenesis; Organism; Pathway interactions; Phenotype; Play; Process; Protein Biosynthesis; RNA Interference; RNA-Binding Proteins; Rattus; Regulation; Research; Role; Synapses; Synaptic plasticity; Testing; Training; Transcript; Translations; autism spectrum disorder; cognitive function; crosslink; experimental study; insight; knock-down; long term memory; mRNA Expression; nervous system disorder; neuronal cell body; novel; pharmacologic; postsynaptic; presynaptic; single molecule; tool; transcriptome; vector control; virtual

PROJECT ABSTRACT Local protein synthesis in neuronal synapses is necessary for several aspects of learning and memory, including synaptic plasticity and consolidation of long-term memories. Studies of local protein synthesis have long suggested that translation occurs in presynaptic areas, but presynaptic protein synthesis has only been widely accepted by the scientific community in the last decade. As a result, virtually all studies looking at learning and memory have focused on post-synaptic protein synthesis. However, presynaptic protein synthesis also occurs during learning and memory across animal species, raising the question of how presynaptic protein synthesis is regulated and how this contributes to learning and memory. Thus, our lab set out to identify presynaptically localized transcripts and study their role in learning and memory. Subcellular sequencing of neuronal somas and synapses in the nematode worm Caenorhabditis elegans showed that presynaptic areas are enriched for mRNA transcripts encoding RNA binding proteins (RBPs). Studies in mammals have shown that RBPs are upregulated in presynapses following memory training in rats, and post-synaptic RBPs are key regulators of post-synaptic protein synthesis. Thus, RBPs may be key regulators of presynaptic protein synthesis during learning and memory, but further investigation is needed to test if this is the case. To this end, I propose aims to understand how presynaptic RBPs contribute to cognitive function and memory . I will use the nematode worm C. elegans for the proposed experiments because it is the only organism that has a well-defined presynaptic transcriptome, advanced genetic tools, and exhibits evolutionarily conserved memory. In Aim 1, I will test the hypothesis that loss of conserved, presynaptically enriched RBPs will modulate learning and memory. Specifically, I will knock down presynaptically enriched RBPs and test the effect of RNAi knockdown on positive olfactory associative memory in C. elegans. Preliminary data suggests that these tests will reveal presynaptic RBPs as novel memory regulators. In Aim 2, I will mechanistically study how RBPs can modulate learning and memory by identifying the mRNAs bound by a known memory-regulating RBP, PUF-8. I will then test the functional consequences of these mRNA targets on learning and memory. In Aim 2.1, I will perform eCLIP-seq on PUF-8 before and after memory training to identify mRNAs that are bound by PUF-8 in a memory- dependent manner, which are likely downstream memory-regulating genes. I will then validate my eCLIP findings by ensuring that these mRNA targets co-localize with PUF-8 in presynapses (Aim 2.2) and have functional consequences on learning and memory (Aim 2.3). Combined, the proposed studies will provide novel insight into the role of presynaptic transcripts in learning and memory. More specifically, because RBPs are understudied in terms of presynaptic translation, this proposal will address the mechanism of RBP control of downstream mRNAs during learning and memory.

项目摘要 神经元突触中的局部蛋白质合成对于学习和记忆的几个方面是必需的， 包括突触可塑性和长期记忆的巩固。局部蛋白质合成的研究 长期以来认为翻译发生在突触前区域，但突触前蛋白质的合成只发生在突触前区域。 在过去的十年里被科学界广泛接受。因此，几乎所有研究学习的 和记忆都集中在突触后蛋白质的合成上。然而，突触前蛋白质合成也 在动物物种的学习和记忆过程中发生，提出了一个问题， 合成是受调节的，以及这如何有助于学习和记忆。因此，我们的实验室开始鉴定 突触前定位的转录本，并研究其在学习和记忆中的作用。亚细胞测序 秀丽隐杆线虫的神经元胞体和突触显示突触前区域 富含编码RNA结合蛋白（RBP）的mRNA转录物。对哺乳动物的研究表明 RBP在大鼠记忆训练后的突触前上调，突触后RBP是关键， 突触后蛋白质合成的调节剂。因此，RBPs可能是突触前蛋白质合成的关键调节因子 在学习和记忆过程中，但需要进一步的研究来测试是否如此。为此，我建议 旨在了解突触前RBP如何有助于认知功能和记忆 .我会用线虫 沃姆角因为它是唯一具有明确定义的生物体， 突触前转录组，先进的遗传工具，并表现出进化保守的记忆。在目标1中， 将检验保守的、突触前富集的RBP的丢失将调节学习和 记忆具体来说，我将敲除突触前富集的RBP，并测试RNAi敲除的效果。 在C.优雅的初步数据显示，这些测试将揭示 突触前RBP作为新的记忆调节器。在目标2中，我将机械地研究RBP如何调节 通过识别已知的记忆调节RBP，PUF-8结合的mRNA来研究学习和记忆。然后我将 测试这些mRNA靶点对学习和记忆的功能影响。在目标2.1中，我将执行 在记忆训练之前和之后对PUF-8进行eCLIP-seq，以鉴定记忆中被PUF-8结合的mRNA。 依赖的方式，这可能是下游的记忆调节基因。然后，我将验证我的eCLIP结果 通过确保这些mRNA靶点与PUF-8在突触前共定位（Aim 2.2）， 对学习和记忆的影响（目标2.3）。结合起来，拟议的研究将提供新的见解， 突触前转录本在学习和记忆中的作用。更具体地说，由于限制性商业惯例在 就突触前翻译而言，该建议将解决RBP控制下游mRNA的机制 在学习和记忆过程中。