Litcius/Paper detail

Massive multiplexing of spatially resolved single neuron projections with axonal BARseq

Li Yuan, Xiaoyin Chen, Huiqing Zhan, Gilbert L. Henry, Anthony M. Zador

2024Nature Communications25 citationsDOIOpen Access PDF

Abstract

Neurons in the cortex are heterogeneous, sending diverse axonal projections to multiple brain regions. Unraveling the logic of these projections requires single-neuron resolution. Although a growing number of techniques have enabled high-throughput reconstruction, these techniques are typically limited to dozens or at most hundreds of neurons per brain, requiring that statistical analyses combine data from different specimens. Here we present axonal BARseq, a high-throughput approach based on reading out nucleic acid barcodes using in situ RNA sequencing, which enables analysis of even densely labeled neurons. As a proof of principle, we have mapped the long-range projections of >8000 primary auditory cortex neurons from a single male mouse. We identified major cell types based on projection targets and axonal trajectory. The large sample size enabled us to systematically quantify the projections of intratelencephalic (IT) neurons, and revealed that individual IT neurons project to different layers in an area-dependent fashion. Axonal BARseq is a powerful technique for studying the heterogeneity of single neuronal projections at high throughput within individual brains. High-throughput mapping of neural projections at the single-cell level remains challenging. Here, the authors have developed axonal BARseq, a new technique that allows for mapping projections from thousands of neurons within a single brain.

Topics & Concepts

NeuronNeuroscienceComputer scienceMultiplexingBiologyTelecommunicationsCell Image Analysis TechniquesAdvanced Fluorescence Microscopy TechniquesSingle-cell and spatial transcriptomics