使用更新位置任务中的对象研究小鼠的记忆更新

Q2 Neuroscience Current Protocols in Neuroscience Pub Date : 2020-01-27 DOI:10.1002/cpns.87
Destiny S. Wright, Kasuni K. Bodinayake, Janine L. Kwapis
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引用次数: 10

摘要

在实验室里,记忆通常是作为一种从头开始的经历来研究的,在这种经历中,naïve动物暴露在一个与过去经历明显不同的离散学习事件中。然而,大多数现实世界的记忆都是对现有记忆的更新——修改或添加。这在老化的、经验丰富的大脑中尤其如此。为了更好地理解内存更新,我们开发了一种新的行为范式,称为更新位置中的对象(OUL)任务。OUL依赖于海马体依赖的空间学习,其优势在于能够在一次测试中同时测试原始记忆和更新的信息。此外,OUL依赖于偶然学习,避免了可能阻碍衰老动物表现的不必要的压力。在OUL中,动物首先在熟悉的环境中学习两个相同物体的位置。然后通过将一个对象移动到新的位置来更新该内存。最后,为了评估动物对原始信息和更新信息的记忆,所有动物都接受了一个测试,在这个测试中,它们暴露在物体的四个副本中:两个在原始训练地点,一个在更新的位置,一个在新的位置。通过比较对新位置和熟悉位置的探索,我们可以推断动物是否记得原始和更新的物体位置。OUL是一个简单但功能强大的任务,它可以为支持记忆更新的细胞、电路级和分子机制提供新的见解。©2020 by John Wiley &儿子,Inc。
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Investigating Memory Updating in Mice Using the Objects in Updated Locations Task

In the laboratory, memory is typically studied as a de novo experience, in which a naïve animal is exposed to a discrete learning event that is markedly different from its past experiences. Most real-world memories, however, are updates—modifications or additions—to existing memories. This is particularly true in the aging, experienced brain. To better understand memory updating, we have developed a new behavioral paradigm called the objects in updated locations (OUL) task. OUL relies on hippocampus-dependent spatial learning and has the advantage of being able to test both the original memory and the updated information in a single test session. Further, OUL relies on incidental learning that avoids unnecessary stress that might hinder the performance of aging animals. In OUL, animals first learn the location of two identical objects in a familiar context. This memory is then updated by moving one object to a new location. Finally, to assess the animals’ memory for the original and the updated information, all animals are given a test session in which they are exposed to four copies of the object: two in the original training locations, one in the updated location, and one in a novel location. By comparing exploration of the novel location to the familiar locations, we can infer whether the animal remembers the original and updated object locations. OUL is a simple but powerful task that could provide new insights into the cellular, circuit-level, and molecular mechanisms that support memory updating. © 2020 by John Wiley & Sons, Inc.

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Current Protocols in Neuroscience
Current Protocols in Neuroscience Neuroscience-Neuroscience (all)
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期刊介绍: Current Protocols in Neuroscience is a one-stop resource for finding and adapting the best models and methods for all types of neuroscience experiments. Updated every three months in all formats, CPNS is constantly evolving to keep pace with the very latest discoveries and developments. A year of these quarterly updates is included in the initial CPNS purchase price.
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