A whole-brain analysis of functional connectivity and immediate early gene expression reveals functional network shifts after operant learning

IF 4.7 2区 医学 Q1 NEUROIMAGING NeuroImage Pub Date : 2024-09-05 DOI:10.1016/j.neuroimage.2024.120840
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Abstract

Previous studies of operant learning have addressed neuronal activities and network changes in specific brain areas, such as the striatum, sensorimotor cortex, prefrontal/orbitofrontal cortices, and hippocampus. However, how changes in the whole-brain network are caused by cellular-level changes remains unclear. We, therefore, combined resting-state functional magnetic resonance imaging (rsfMRI) and whole-brain immunohistochemical analysis of early growth response 1 (EGR1), a marker of neural plasticity, to elucidate the temporal and spatial changes in functional networks and underlying cellular processes during operant learning. We used an 11.7-Tesla MRI scanner and whole-brain immunohistochemical analysis of EGR1 in mice during the early and late stages of operant learning. In the operant training, mice received a reward when they pressed left and right buttons alternately, and were punished with a bright light when they made a mistake. A group of mice (n = 22) underwent the first rsfMRI acquisition before behavioral sessions, the second acquisition after 3 training-session-days (early stage), and the third after 21 training-session-days (late stage). Another group of mice (n = 40) was subjected to histological analysis 15 min after the early or late stages of behavioral sessions. Functional connectivity increased between the limbic areas and thalamus or auditory cortex after the early stage of training, and between the motor cortex, sensory cortex, and striatum after the late stage of training. The density of EGR1-immunopositive cells in the motor and sensory cortices increased in both the early and late stages of training, whereas the density in the amygdala increased only in the early stage of training. The subcortical networks centered around the limbic areas that emerged in the early stage have been implicated in rewards, pleasures, and fears. The connectivities between the motor cortex, somatosensory cortex, and striatum that consolidated in the late stage have been implicated in motor learning. Our multimodal longitudinal study successfully revealed temporal shifts in brain regions involved in behavioral learning together with the underlying cellular-level plasticity between these regions. Our study represents a first step towards establishing a new experimental paradigm that combines rsfMRI and immunohistochemistry to link macroscopic and microscopic mechanisms involved in learning.

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对功能连接和即时早期基因表达的全脑分析揭示了操作学习后的功能网络转变。
以往对操作性学习的研究主要针对特定脑区的神经元活动和网络变化,如纹状体、感觉运动皮层、前额叶/或侧额叶皮层和海马。然而,细胞层面的变化如何引起整个大脑网络的变化仍不清楚。因此,我们结合静息态功能磁共振成像(rsfMRI)和神经可塑性标志物--早期生长反应1(EGR1)的全脑免疫组化分析,来阐明操作学习过程中功能网络和潜在细胞过程的时空变化。我们利用 11.7 特斯拉核磁共振成像扫描仪和全脑免疫组化分析技术对操作学习早期和晚期阶段的小鼠进行了 EGR1 分析。在操作训练中,小鼠交替按下左右按钮时会得到奖励,犯错时会受到强光惩罚。一组小鼠(n = 22)在行为训练前进行了第一次 rsfMRI 采集,3 个训练课日后进行了第二次采集(早期阶段),21 个训练课日后进行了第三次采集(晚期阶段)。另一组小鼠(n = 40)在行为训练早期或晚期阶段结束后 15 分钟接受组织学分析。训练早期,边缘区与丘脑或听觉皮层之间的功能连接增加;训练晚期,运动皮层、感觉皮层和纹状体之间的功能连接增加。运动皮层和感觉皮层中EGR1免疫阳性细胞的密度在训练早期和晚期都有所增加,而杏仁核的密度仅在训练早期有所增加。早期出现的以边缘区为中心的皮层下网络与奖赏、快乐和恐惧有关。运动皮层、躯体感觉皮层和纹状体之间的联系在后期得到巩固,这与运动学习有关。我们的多模态纵向研究成功揭示了参与行为学习的大脑区域的时间变化以及这些区域之间潜在的细胞级可塑性。我们的研究为建立一种新的实验范式迈出了第一步,这种范式结合了 rsfMRI 和免疫组化技术,将参与学习的宏观和微观机制联系起来。
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来源期刊
NeuroImage
NeuroImage 医学-核医学
CiteScore
11.30
自引率
10.50%
发文量
809
审稿时长
63 days
期刊介绍: NeuroImage, a Journal of Brain Function provides a vehicle for communicating important advances in acquiring, analyzing, and modelling neuroimaging data and in applying these techniques to the study of structure-function and brain-behavior relationships. Though the emphasis is on the macroscopic level of human brain organization, meso-and microscopic neuroimaging across all species will be considered if informative for understanding the aforementioned relationships.
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