Sensory and Behavioural Neuroscience Unit, Okinawa Institute of Science and Technology Graduate University, Okinawa, Japan, 904-0495.
Laboratory Animal Resource Center, Tsukuba University, Ibaraki, Japan, 305-8577.
J Neurosci. 2021 Jul 28;41(30):6449-6467. doi: 10.1523/JNEUROSCI.3076-20.2021. Epub 2021 Jun 7.
In sensory systems of the brain, mechanisms exist to extract distinct features from stimuli to generate a variety of behavioral repertoires. These often correspond to different cell types at various stages in sensory processing. In the mammalian olfactory system, complex information processing starts in the olfactory bulb, whose output is conveyed by mitral cells (MCs) and tufted cells (TCs). Despite many differences between them, and despite the crucial position they occupy in the information hierarchy, Cre-driver lines that distinguish them do not yet exist. Here, we sought to identify genes that are differentially expressed between MCs and TCs of the mouse, with an ultimate goal to generate a cell type-specific Cre-driver line, starting from a transcriptome analysis using a large and publicly available single-cell RNA-seq dataset (Zeisel et al., 2018). Many genes were differentially expressed, but only a few showed consistent expressions in MCs and at the specificity required. After further validating these putative markers using ISH, two genes (i.e., and ) remained as promising candidates. Using CRISPR/Cas9-mediated gene editing, we generated Cre-driver lines and analyzed the resulting recombination patterns. This indicated that our new inducible Cre-driver line, , can be used to genetically label MCs in a tamoxifen dose-dependent manner, both in male and female mice, as assessed by soma locations, projection patterns, and sensory-evoked responses Hence, this is a promising tool for investigating cell type-specific contributions to olfactory processing and demonstrates the power of publicly accessible data in accelerating science. In the brain, distinct cell types play unique roles. It is therefore important to have tools for studying unique cell types specifically. For the sense of smell in mammals, information is processed first by circuits of the olfactory bulb, where two types of cells, mitral cells and tufted cells, output different information. We generated a transgenic mouse line that enables mitral cells to be specifically labeled or manipulated. This was achieved by looking for genes that are specific to mitral cells using a large and public gene expression dataset, and creating a transgenic mouse using the gene editing technique, CRISPR/Cas9. This will allow scientists to better investigate parallel information processing underlying the sense of smell.
在大脑的感觉系统中,存在从刺激中提取独特特征的机制,以产生各种行为反应。这些特征通常对应于感觉处理过程中不同阶段的不同细胞类型。在哺乳动物的嗅觉系统中,复杂的信息处理始于嗅球,其输出由僧帽细胞 (MCs) 和丛状细胞 (TCs) 传递。尽管它们之间存在许多差异,并且尽管它们在信息层次结构中占据至关重要的位置,但区分它们的 Cre 驱动线尚未存在。在这里,我们试图确定在小鼠的 MCs 和 TCs 之间表达差异的基因,最终目标是从使用大型公共单细胞 RNA-seq 数据集的转录组分析开始生成细胞类型特异性的 Cre 驱动线(Zeisel 等人,2018 年)。许多基因表达差异,但只有少数几个基因在 MCs 中表达一致,且具有所需的特异性。在用 ISH 进一步验证这些假定的标记物后,两个基因(即 和 )仍然是有前途的候选基因。使用 CRISPR/Cas9 介导的基因编辑,我们生成了 Cre 驱动线并分析了产生的重组模式。这表明,我们的新诱导型 Cre 驱动线 ,可以在雄性和雌性小鼠中以依赖于他莫昔芬剂量的方式遗传标记 MCs,这可以通过体定位、投射模式和感觉诱发反应来评估。因此,这是一种有前途的工具,可用于研究嗅觉处理中特定细胞类型的贡献,并展示了公开可用数据在加速科学研究方面的力量。在大脑中,不同的细胞类型发挥着独特的作用。因此,拥有专门研究特定细胞类型的工具非常重要。对于哺乳动物的嗅觉,信息首先由嗅球的回路处理,其中两种类型的细胞,即僧帽细胞和丛状细胞,输出不同的信息。我们使用一种大型公共基因表达数据集来寻找特定于僧帽细胞的基因,并使用基因编辑技术 CRISPR/Cas9 来创建一种转基因小鼠,从而生成了一种能够专门标记或操纵僧帽细胞的转基因小鼠。这将使科学家能够更好地研究嗅觉背后的平行信息处理。
