Probes for SLC17A7

The laminae of the neocortex are fundamental processing layers of the mammalian brain. Notably, such laminae are believed to be relatively stereotyped across short spatial scales such that shared laminae between nearby brain regions exhibit similar constituent cells. Here, we consider a potential exception to this rule by studying the retrosplenial cortex (RSC), a brain region known for sharp cytoarchitectonic differences across its granular-dysgranular border. Using a variety of transcriptomics techniques, we identify, spatially map, and interpret the excitatory cell-type landscape of the mouse RSC. In doing so, we uncover that RSC gene expression and cell types change sharply at the granular-dysgranular border. Additionally, supposedly homologous laminae between the RSC and the neocortex are effectively wholly distinct in their cell-type composition. In collection, the RSC exhibits a variety of intrinsic cell-type specializations and embodies an organizational principle wherein cell-type identities can vary sharply within and between brain regions.

The primate neocortex exerts high cognitive ability and strong information processing capacity. Here, we establish a single-cell RNA sequencing dataset of 133,454 macaque visual cortical cells. It covers major cortical cell classes including 25 excitatory neuron types, 37 inhibitory neuron types and all glial cell types. We identified layer-specific markers including HPCAL1 and NXPH4, and also identified two cell types, an NPY-expressing excitatory neuron type that expresses the dopamine receptor D3 gene; and a primate specific activity-dependent OSTN + sensory neuron type. Comparisons of our dataset with humans and mice show that the gene expression profiles differ between species in relation to genes that are implicated in the synaptic plasticity and neuromodulation of excitatory neurons. The comparisons also revealed that glutamatergic neurons may be more diverse across species than GABAergic neurons and non-neuronal cells. These findings pave the way for understanding how the primary cortex fulfills the high-cognitive functions.

The claustrum is a functionally and structurally complex brain region, whose very spatial extent remains debated. Histochemical-based approaches typically treat the claustrum as a relatively narrow anatomical region that primarily projects to the neocortex, whereas circuit-based approaches can suggest a broader claustrum region containing projections to the neocortex and other regions. Here, in the mouse, we took a bottom-up and cell-type-specific approach to complement and possibly unite these seemingly disparate conclusions. Using single-cell RNA-sequencing, we found that the claustrum comprises two excitatory neuron subtypes that are differentiable from the surrounding cortex. Multicolor retrograde tracing in conjunction with 12-channel multiplexed in situ hybridization revealed a core-shell spatial arrangement of these subtypes, as well as differential downstream targets. Thus, the claustrum comprises excitatory neuron subtypes with distinct molecular and projection properties, whose spatial patterns reflect the narrower and broader claustral extents debated in previous research. This subtype-specific heterogeneity likely shapes the functional complexity of the claustrum.

Background: The Psychiatric Ratings using Intermediate Stratified Markers (PRISM) project focuses on understanding the biological background behind social deficits, specifically social withdrawal irrespective of diagnosis. Reduced connectional integrity in fiber tracts such as Forceps minor has been indicated in low social individuals as a part of the PRISM 1 project. These fiber tracts are also involved in the Default Mode Network (DMN) and the Social network and they share a common region, the Orbitofrontal Cortex (OFC).This study aims to back-translate the clinical data to preclinical studies and associate social dysfunction in rodents with DMN and particularly OFC. Parvalbumin interneurons are targeted based on their fundamental role in maintaining Excitatory Inhibitory (E/I) balance in brain circuits. Numerous studies indicate behavioral impairment in rodents by increasing excitability of PV+ interneurons. Methods: As an initial step, we characterized the population of projection neurons within OFCs by combining Cholera Toxin subunit B (CTB) as a retrograde tracer and In situ hybridization (ISH) technique (RNAscope). We identified the expression of mRNAs marking glutamatergic (vesicular glutamate transporter [VGLUT]) and GABAergic (vesicular GABA transporter [VGAT]) by using Slc17a7 and Slc32a1 probes. CTB was injected unilaterally in the left OFC (AP=2.68, ML=-0.8, DV=2.2). after 10 days mice were perfused and RNAscope assay was performed using RNAscope™ Multiplex Fluorescent kit (ACDBio™).For inducing hypoactivation of OFC, we introduced an excitatory DREADD (designer receptors exclusively activated by designer drugs) to PV+ interneurons by using a PV-Cre mouse line. Mice were injected either AAV-hSyn-DIO-hM3D(Gq)-mCherry virus (n=12) or AAV-hSyn-DIO-mCherry (n=12) as control virus. As a novel behavioral tool, Radiofrequency identification (RFID)-assisted SocialScan combined with video tracking has been used, which provides a long-term observation of social behaviors. Monitoring the behavior in groups of four was performed for 7 days in total. After two pre-application days, Clozapine-N-oxide (CNO) was injected three times on consecutive days intraperitoneally (5mg/kg) as an activator of hM3D. application days were followed by two post-application days. Mice were perfused and RNAscope was performed to visualize c-fos mRNA expression as neuronal activity marker, and PV expression to validate our virus and mouse line efficacy. Results: ISH results indicated VGLUT1 has the highest expression within projection neurons (81%). 6% are VGAT+ and only 3% are both VGLUT1/VGAT positive neurons. Despite demonstrating the GABAergic projection neurons as a minority, their crucial role as local interneurons to moderate the excitatory neurons is indisputable.In in vivo study, CNO administration induced social dysregulation in DREAAD mice, demonstrated by a reduction in different social parameters (approach, fight, etc.) in terms of duration. During post-application days, DREAAD mice showed significantly higher social interaction in all definedparameters (Social Approach: p=0.0009, unpaired T-test) and locomotion as a non-social parameter (p= 0.0207).Results from ISH support our hypothesis that DREADD activation of PV+ interneurons is followed by high expression of neuronal activity markers in these targeted interneurons. Conclusion: This study indicates that manipulation of PV+ interneurons using artificially engineered activating protein receptors, generates in effect activation of these interneurons, and this manipulation particularly in OFC could cause social dysfunction in mice.