围青春期是前额叶旁脑中间神经元活动影响成人认知灵活性的敏感期。

IF 2.3 4区 医学 Q2 DEVELOPMENTAL BIOLOGY
Gabriella M Sahyoun, Trang Dao Do, Amanda Anqueira-Gonzàlez, Ava Hornblass, Sarah E Canetta
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引用次数: 0

摘要

导言在发育过程中,一些经历会对大脑回路和行为产生持久的影响,这些经历被称为 "敏感期",反映了一种高度可塑性的状态。敏感期的典型例子来自对感觉系统(如视觉系统)的研究,在视觉系统中,初级视觉皮层的正常连接和正常的视觉功能需要早期的视觉经验。从机理上讲,失去视觉输入会导致代表受影响眼睛的丘脑皮层神经元活动减少,从而导致视觉皮层对这些输入的表征随活动而减少,并导致该眼睛失去视觉感知能力。虽然像内侧前额叶皮层(mPFC)这样的联想皮层区域并不接受直接的感觉输入,但最近的研究结果表明,该区域在早期发育的特定窗口期所经历的活动水平变化也可能导致前额叶皮层电路、网络功能和行为的长期变化。例如,我们最近证明,在围青春期(出生后第 P14 天)至青春期(第 P50 天)这段时间内,降低 mPFC 副发光素表达(PV)中间神经元的活动会导致其对锥体细胞的功能抑制长期下降,并导致认知灵活性受损。虽然操纵 mPFC PV 神经元间活动的影响对发育期而非成年期具有选择性,但这种操纵的敏感期的确切时间仍然未知:为了确定抑制 mPFC PV 细胞活动可对前额叶功能产生持续影响的敏感期,我们使用化学遗传学方法将 mPFC PV 活动的抑制限制在两个不同的窗口期:1)青春期(P14-P32)和2)青春早期(P33-P50)。然后,我们研究了 P90 之后的成人行为。与此同时,我们还对视觉皮层中与敏感期起始和偏移相关的分子标记进行了组织学分析,以确定 mPFC 中敏感期可塑性峰值的起始和偏移:我们发现,在青春期(P14-P32)而非青春期(P33-P50)抑制mPFC PV中间神经元会导致成年期的集合转换行为受损,表现为达到标准表现的试验次数和误差增加。与前脑功能区敏感期可塑性的青春期起始相一致,我们发现敏感期起始和偏移的组织学标记也分别以 P14 和 P35 为界。这些标志物在视觉皮层中的表达时间过程相似:结论:这两项研究都认为,围青春期(P14-32)是 mPFC 敏感期可塑性增强的时期。此外,我们对前额叶和视皮层敏感期可塑性标志物的直接比较表明,敏感期的表达具有相似的时间过程,这对敏感期分等级发生的观点提出了挑战。总之,这些发现扩展了我们对发育中 mPFC 敏感期可塑性的性质和时间的认识。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Peripuberty Is a Sensitive Period for Prefrontal Parvalbumin Interneuron Activity to Impact Adult Cognitive Flexibility.

Introduction: Developmental windows in which experiences can elicit long-lasting effects on brain circuitry and behavior are called "sensitive periods" and reflect a state of heightened plasticity. The classic example of a sensitive period comes from studies of sensory systems, like the visual system, where early visual experience is required for normal wiring of primary visual cortex and proper visual functioning. At a mechanistic level, loss of incoming visual input results in a decrease in activity in thalamocortical neurons representing the affected eye, resulting in an activity-dependent reduction in the representation of those inputs in the visual cortex and loss of visual perception in that eye. While associative cortical regions like the medial prefrontal cortex (mPFC) do not receive direct sensory input, recent findings demonstrate that changes in activity levels experienced by this region during defined windows in early development may also result in long-lasting changes in prefrontal cortical circuitry, network function, and behavior. For example, we recently demonstrated that decreasing the activity of mPFC parvalbumin-expressing (PV) interneurons during a period of time encompassing peripuberty (postnatal day P14) to adolescence (P50) led to a long-lasting decrease in their functional inhibition of pyramidal cells, as well as impairments in cognitive flexibility. While the effects of manipulating mPFC PV interneuron activity were selective to development, and not adulthood, the exact timing of the sensitive period for this manipulation remains unknown.

Methods: To refine the sensitive period in which inhibiting mPFC PV cell activity can lead to persistent effects on prefrontal functioning, we used a chemogenetic approach to restrict our inhibition of mPFC PV activity to two distinct windows: (1) peripuberty (P14-P32) and (2) early adolescence (P33-P50). We then investigated adult behavior after P90. In parallel, we performed histological analysis of molecular markers associated with sensitive period onset and offset in visual cortex, to define the onset and offset of peak-sensitive period plasticity in the mPFC.

Results: We found that inhibition of mPFC PV interneurons in peripuberty (P14-P32), but not adolescence (P33-P50), led to an impairment in set-shifting behavior in adulthood manifest as an increase in trials to reach criterion performance and errors. Consistent with a pubertal onset of sensitive period plasticity in the PFC, we found that histological markers of sensitive period onset and offset also demarcated P14 and P35, respectively. The time course of expression of these markers was similar in visual cortex.

Conclusion: Both lines of research converge on the peripubertal period (P14-P32) as one of heightened sensitive period plasticity in the mPFC. Further, our direct comparison of markers of sensitive period plasticity across the prefrontal and visual cortex suggests a similar time course of expression, challenging the notion that sensitive periods occur hierarchically. Together, these findings extend our knowledge about the nature and timing of sensitive period plasticity in the developing mPFC.

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来源期刊
Developmental Neuroscience
Developmental Neuroscience 医学-发育生物学
CiteScore
4.00
自引率
3.40%
发文量
49
审稿时长
>12 weeks
期刊介绍: ''Developmental Neuroscience'' is a multidisciplinary journal publishing papers covering all stages of invertebrate, vertebrate and human brain development. Emphasis is placed on publishing fundamental as well as translational studies that contribute to our understanding of mechanisms of normal development as well as genetic and environmental causes of abnormal brain development. The journal thus provides valuable information for both physicians and biologists. To meet the rapidly expanding information needs of its readers, the journal combines original papers that report on progress and advances in developmental neuroscience with concise mini-reviews that provide a timely overview of key topics, new insights and ongoing controversies. The editorial standards of ''Developmental Neuroscience'' are high. We are committed to publishing only high quality, complete papers that make significant contributions to the field.
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