Transposable Elements Are Dynamically Regulated in Medium Spiny Neurons and May Contribute to the Molecular and Behavioral Adaptations to Cocaine.

IF 9 1区医学 Q1 NEUROSCIENCES

Biological Psychiatry Pub Date : 2025-07-25 DOI:10.1016/j.biopsych.2025.07.014

Gabriella M Silva, Amber L Kaplan, Celeste R Park, Joseph A Picone, R Kijoon Kim, Natalie L Truby, Rachel L Neve, Xiaohong Cui, Peter J Hamilton

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引用次数: 0

Abstract

Background: Earlier work has established that Zfp189, which encodes a KZFP transcription factor (TF), differentially accumulates in nucleus accumbens (NAc) Drd1+ and Drd2+ medium spiny neurons (MSNs) and drives MSN functional and behavioral adaptations to cocaine. Here, we aimed to illuminate the cell type mechanisms through which this TF contributes to cocaine adaptations, with emphasis on investigating transposable elements (TEs).

Methods: First, we annotated TEs in existing single-nucleus RNA sequencing (snRNAseq) from rodents exposed to either acute or repeated cocaine. To directly test whether TE dysregulation participates in cocaine-related brain changes, we virally delivered synthetic ZFP189 TFs, capable of releasing (ZFP189^VPR) or repressing (ZFP189^WT) brain TEs. Following cocaine exposure, we performed both bulk and snRNAseq of manipulated NAc. Lastly, we conditionally delivered these synthetic TFs to either the Drd1+ or Drd2+ MSNs and performed behavioral and cell morphological experiments.

Results: We discovered that NAc TE transcript expression was dramatically increased by cocaine experience, and the most sensitive NAc cell types were Drd1+, followed by Drd2+ MSNs. Our snRNAseq revealed that ZFP189^VPR impeded gene expression across NAc cell types, including both MSN subtypes. Within either MSN subtype, ZFP189^WT promoted, and ZFP189^VPR restricted, primarily immune-related gene expression. We discovered that behavioral and cell morphological adaptations to cocaine are potentiated by ZFP189^VPR function in Drd1+ MSNs or ZFP189^WT in Drd2+ MSNs, revealing an MSN opponent process weighted by ZFP189 function.

Conclusions: This research points to TE transcript expression as dynamically regulated within NAc MSNs and possibly involved in producing the molecular and behavioral responses to cocaine.

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转座因子在中棘神经元中受到动态调控，并可能参与对可卡因的分子和行为适应。

背景：早期的研究已经证实，编码KZFP转录因子（TF）的Zfp189在伏隔核（NAc） Drd1+和Drd2+中棘神经元（MSN）中有差异地积累，并驱动MSN对可卡因的功能和行为适应。在这里，我们旨在阐明这种TF有助于可卡因适应的细胞类型机制，重点研究转座因子（te）。方法：首先，我们在暴露于急性或重复可卡因的啮齿动物的现有单核rna测序（snRNAseq）中注释TEs。为了直接测试TE失调是否参与可卡因相关的大脑变化，我们通过病毒传递合成的能够释放（ZFP189VPR）或抑制（ZFP189WT）脑TE的ZFP189 tf。在可卡因暴露后，我们对操纵NAc进行了大量和少量rna - naseq。最后，我们有条件地将这些合成的tf传递到Drd1+或Drd2+的msn上，并进行了行为和细胞形态学实验。结果：我们发现可卡因使NAc TE转录本的表达显著增加，其中最敏感的NAc细胞类型是Drd1+，其次是Drd2+ msn。我们的snRNAseq显示ZFP189VPR阻碍了NAc细胞类型的基因表达，包括两种MSN亚型。在两种MSN亚型中，ZFP189WT促进了主要与免疫相关的基因表达，而ZFP189VPR限制了这些基因的表达。我们发现Drd1+ MSNs中的ZFP189VPR功能或Drd2+ MSNs中的ZFP189WT功能增强了对可卡因的行为和细胞形态适应，揭示了一个由ZFP189功能加重的MSN对抗过程。结论：本研究指出TE转录本的表达在NAc msn内受到动态调控，可能参与产生对可卡因的分子和行为反应。

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来源期刊

Biological Psychiatry 医学-精神病学

CiteScore

18.80

自引率

2.80%

发文量

1398

审稿时长

33 days

期刊介绍： Biological Psychiatry is an official journal of the Society of Biological Psychiatry and was established in 1969. It is the first journal in the Biological Psychiatry family, which also includes Biological Psychiatry: Cognitive Neuroscience and Neuroimaging and Biological Psychiatry: Global Open Science. The Society's main goal is to promote excellence in scientific research and education in the fields related to the nature, causes, mechanisms, and treatments of disorders pertaining to thought, emotion, and behavior. To fulfill this mission, Biological Psychiatry publishes peer-reviewed, rapid-publication articles that present new findings from original basic, translational, and clinical mechanistic research, ultimately advancing our understanding of psychiatric disorders and their treatment. The journal also encourages the submission of reviews and commentaries on current research and topics of interest.