Dopamine Receptor 1 Specific CRISPRa Mice Exhibit Disrupted Behaviors and Striatal Baseline Cellular Activity.

IF 2.7 3区医学 Q3 NEUROSCIENCES

eNeuro Pub Date : 2025-08-18 Print Date: 2025-08-01 DOI:10.1523/ENEURO.0157-25.2025

Rianne R Campbell, Mikah Green, Eric Y Choi, Andreas B Wulff, Allison N Siclair, Smirti Khatri, Geralin Virata, Christina Barrett, Symphanie Key, Samir Patel, Mary Beth Rowell, Daniela Franco, Shanmugasundaram Ganapathy-Kanniappan, Brian N Mathur, Mary Kay Lobo

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Abstract

The two main cell types in the striatum, dopamine receptor 1 and adenosine receptor 2a spiny projection neurons (D1-SPNs and A2A-SPNs), have distinct roles in regulating motor- and reward-related behaviors. Cre-selective CRISPR-dCas9 systems allow for cell-type specific, epigenomic-based manipulation of gene expression with gene-specific single guide RNAs (sgRNAs) and have potential to elucidate molecular mechanisms underlying striatal subtype mediated behaviors. Conditional transgenic Rosa26:LSL-dCas9-p300 mice were recently generated to allow for robust expression of dCas9-p300 expression with Cre-driven cell-type specificity. This system utilizes p300, a histone acetyltransferase which regulates gene expression by unwinding chromatin and making that region of the genome more accessible for transcription. Rosa26-LSL-dCas9-p300 mice were paired with Drd1-Cre and Ador2a-Cre mice to generate Drd1-Cre:dCas9-p300 and Ador2a-Cre:dCas9-p300 mouse lines and underwent behavioral phenotyping when sgRNAs were not present. Both Drd1-Cre:dCas9-p300 and Ador2a-Cre:dCas9-p300 have cell-type-specific expression of spCas9 mRNA. Baseline behavioral assessments revealed that, under a sgRNA absent nontargeted state, Drd1-Cre:dCas9-p300 mice display repetitive spinning behavior, hyperlocomotion, and enhanced acquisition of reward learning in comparison with all genotypic littermates. In contrast, Ador2a-Cre:dCas9-p300 do not exhibit any changes in behavior in comparison with their littermates. Electrophysiological recordings of dorsal striatum D1-SPNs revealed that Drd1-Cre:dCas9-p300 mice have increased input resistance and increased spontaneous excitatory postsynaptic current amplitude, together suggesting greater excitatory drive of D1-SPNs. Overall, these data demonstrate the necessity to validate CRISPR-dCas9 lines for research investigations. Additionally, the Drd1-Cre:dCas9-p300 line has the potential to be used to study underlying mechanisms of stereotypy and reward learning.

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多巴胺受体1特异性CRISPRa小鼠表现出破坏行为和纹状体基线细胞活性。

纹状体中的两种主要细胞类型，多巴胺受体1和腺苷受体2a棘投射神经元（D1-SPNs和A2A-SPNs），在调节运动和奖励相关行为中具有不同的作用。基因选择性CRISPR-dCas9系统允许使用基因特异性单导rna （sgRNAs）对细胞类型特异性、基于表观基因组学的基因表达进行操作，并具有阐明纹状体亚型介导行为的分子机制的潜力。最近产生了条件转基因Rosa26:LSL-dCas9-p300小鼠，使dCas9-p300表达具有cred驱动的细胞类型特异性。该系统利用p300，一种组蛋白乙酰转移酶，通过解绕染色质来调节基因表达，并使基因组的该区域更容易转录。将Rosa26-LSL-dCas9-p300小鼠与Drd1-Cre和Ador2a-Cre小鼠配对，生成Drd1-Cre:dCas9-p300和Ador2a-Cre:dCas9-p300小鼠系，并在不存在sgRNAs的情况下进行行为表型分析。Drd1-Cre:dCas9-p300和Ador2a-Cre:dCas9-p300都有spCas9 mRNA的细胞型特异性表达。基线行为评估显示，在sgRNA缺失的非靶向状态下，与所有基因型的小鼠相比，Drd1-Cre:dCas9-p300小鼠表现出重复旋转行为、过度运动和获得奖励学习的增强。相比之下，Ador2a-Cre:dCas9-p300与它们的同伴相比，没有表现出任何行为变化。背侧纹状体D1-SPNs的电生理记录显示，Drd1-Cre:dCas9-p300小鼠的输入阻抗增加，自发兴奋性突触后电流幅值增加，表明D1-SPNs的兴奋性驱动更大。总的来说，这些数据证明了验证CRISPR-dCas9系用于研究调查的必要性。此外，Drd1-Cre:dCas9-p300系有可能用于研究刻板印象和奖励学习的潜在机制。使用基于crispr的工具来鉴定疾病和行为中细胞类型特异性表观基因组和转录机制在神经科学领域具有很高的实用性。以前在小鼠中实施crispr编辑系统的限制被认为是通过转基因小鼠系的产生来克服的，包括一种新的cre依赖性dCas9-p300小鼠系。然而，我们的数据显示，由Drd1-Cre小鼠与dCas9-p300小鼠杂交产生的Drd1-Cre:dCas9-p300小鼠在非靶向sgRNA缺失状态下存在细胞和行为破坏。总的来说，这些数据表明在研究调查中使用CRISPR-dCas9系统，特别是转基因小鼠系时要谨慎。

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来源期刊

eNeuro Neuroscience-General Neuroscience

CiteScore

5.00

自引率

2.90%

发文量

486

审稿时长

16 weeks

期刊介绍： An open-access journal from the Society for Neuroscience, eNeuro publishes high-quality, broad-based, peer-reviewed research focused solely on the field of neuroscience. eNeuro embodies an emerging scientific vision that offers a new experience for authors and readers, all in support of the Society’s mission to advance understanding of the brain and nervous system.