Assessing the replicability of spatial gene expression using atlas data from the adult mouse brain

High-throughput, spatially resolved gene expression techniques are poised to be transformative across biology by overcoming a central limitation in single-cell biology: the lack of information on relationships that organize the cells into the functional groupings characteristic of tissues in complex multicellular organisms. Spatial expression is particularly interesting in the mammalian brain, which has a highly defined structure, strong spatial constraint in its organization, and detailed multimodal phenotypes for cells and ensembles of cells that can be linked to mesoscale properties such as projection patterns, and from there, to circuits generating behavior. However, as with any type of expression data, cross-dataset benchmarking of spatial data is a crucial first step. Here, we assess the replicability, with reference to canonical brain subdivisions, between the Allen Institute’s in situ hybridization data from the adult mouse brain (Allen Brain Atlas (ABA)) and a similar dataset collected using spatial transcriptomics (ST). With the advent of tractable spatial techniques, for the first time, we are able to benchmark the Allen Institute’s whole-brain, whole-transcriptome spatial expression dataset with a second independent dataset that similarly spans the whole brain and transcriptome. We use regularized linear regression (LASSO), linear regression, and correlation-based feature selection in a supervised learning framework to classify expression samples relative to their assayed location. We show that Allen Reference Atlas labels are classifiable using transcription in both data sets, but that performance is higher in the ABA than in ST. Furthermore, models trained in one dataset and tested in the opposite dataset do not reproduce classification performance bidirectionally. While an identifying expression profile can be found for a given brain area, it does not generalize to the opposite dataset. In general, we found that canonical brain area labels are classifiable in gene expression space within dataset and that our observed performance is not merely reflecting physical distance in the brain. However, we also show that cross-platform classification is not robust. Emerging spatial datasets from the mouse brain will allow further characterization of cross-dataset replicability ultimately providing a valuable reference set for understanding the cell biology of the brain.

Download Full-text

Replicability of spatial gene expression atlas data from the adult mouse brain

10.1101/2020.10.16.343210 ◽

2020 ◽

Author(s):

Shaina Lu ◽

Cantin Ortiz ◽

Daniel Fürth ◽

Stephan Fischer ◽

Konstantinos Meletis ◽

...

Keyword(s):

Gene Expression ◽

Mouse Brain ◽

Spatial Data ◽

Adult Mouse ◽

Brain Area ◽

Physical Distance ◽

Mammalian Brain ◽

Data Types ◽

Adult Mouse Brain ◽

Whole Brain

AbstractBackgroundSpatial gene expression is particularly interesting in the mammalian brain, with the potential to serve as a link between many data types. However, as with any type of expression data, cross-dataset benchmarking of spatial data is a crucial first step. Here, we assess the replicability, with reference to canonical brain sub-divisions, between the Allen Institute’s in situ hybridization data from the adult mouse brain (ABA) and a similar dataset collected using Spatial Transcriptomics (ST). With the advent of tractable spatial techniques, for the first time we are able to benchmark the Allen Institute’s whole-brain, whole-transcriptome spatial expression dataset with a second independent dataset that similarly spans the whole brain and transcriptome.ResultsWe use LASSO, linear regression, and correlation-based feature selection in a supervised learning framework to classify expression samples relative to their assayed location. We show that Allen reference atlas labels are classifiable using transcription, but that performance is higher in the ABA than ST. Further, models trained in one dataset and tested in the opposite dataset do not reproduce classification performance bi-directionally. Finally, while an identifying expression profile can be found for a given brain area, it does not generalize to the opposite dataset.ConclusionsIn general, we found that canonical brain area labels are classifiable in gene expression space within dataset and that our observed performance is not merely reflecting physical distance in the brain. However, we also show that cross-platform classification is not robust. Emerging spatial datasets from the mouse brain will allow further characterization of cross-dataset replicability.

Download Full-text

Molecular Atlas of the Adult Mouse Brain

10.1101/784181 ◽

2019 ◽

Cited By ~ 1

Author(s):

Cantin Ortiz ◽

Jose Fernandez Navarro ◽

Aleksandra Jurek ◽

Antje Märtin ◽

Joakim Lundeberg ◽

...

Keyword(s):

Gene Expression ◽

Mouse Brain ◽

Spatial Organization ◽

Adult Mouse ◽

Brain Regions ◽

Adult Brain ◽

Adult Mouse Brain ◽

Whole Brain ◽

Systematic Classification ◽

Molecular Code

AbstractBrain maps are essential for integrating information and interpreting the structure-function relationship of circuits and behavior. We aimed to generate a systematic classification of the adult mouse brain organization based on unbiased extraction of spatially-defining features. Applying whole-brain spatial transcriptomics, we captured the gene expression signatures to define the spatial organization of molecularly discrete subregions. We found that the molecular code contained sufficiently detailed information to directly deduce the complex spatial organization of the brain. This unsupervised molecular classification revealed new area- and layer-specific subregions, for example in isocortex and hippocampus, and a new division of striatum. The whole-brain molecular atlas further supports the identification of the spatial origin of single neurons using their gene expression profile, and forms the foundation to define a minimal gene set - a brain palette – that is sufficient to spatially annotate the adult brain. In summary, we have established a new molecular atlas to formally define the identity of brain regions, and a molecular code for mapping and targeting of discrete neuroanatomical domains.

Download Full-text

Faculty Opinions recommendation of Genome-wide atlas of gene expression in the adult mouse brain.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.1057954.521603 ◽

2007 ◽

Author(s):

Matteo Carandini

Keyword(s):

Gene Expression ◽

Mouse Brain ◽

Adult Mouse ◽

Adult Mouse Brain ◽

Genome Wide

Download Full-text

Correlated 5-Hydroxymethylcytosine (5hmC) and Gene Expression Profiles Underpin Gene and Organ-Specific Epigenetic Regulation in Adult Mouse Brain and Liver

PLoS ONE ◽

10.1371/journal.pone.0170779 ◽

2017 ◽

Vol 12 (1) ◽

pp. e0170779 ◽

Cited By ~ 30

Author(s):

I-Hsuan Lin ◽

Yi-Fan Chen ◽

Ming-Ta Hsu

Keyword(s):

Gene Expression ◽

Mouse Brain ◽

Epigenetic Regulation ◽

Adult Mouse ◽

Expression Profiles ◽

Gene Expression Profiles ◽

Adult Mouse Brain ◽

Organ Specific

Download Full-text

Purification of neuronal precursors from the adult mouse brain: comprehensive gene expression analysis provides new insights into the control of cell migration, differentiation, and homeostasis

Molecular and Cellular Neuroscience ◽

10.1016/j.mcn.2003.12.011 ◽

2004 ◽

Vol 25 (4) ◽

pp. 692-706 ◽

Cited By ~ 67

Author(s):

Sandra Pennartz ◽

Richard Belvindrah ◽

Stefan Tomiuk ◽

Céline Zimmer ◽

Kay Hofmann ◽

...

Keyword(s):

Gene Expression ◽

Cell Migration ◽

Mouse Brain ◽

Expression Analysis ◽

Gene Expression Analysis ◽

Adult Mouse ◽

Adult Mouse Brain ◽

Neuronal Precursors

Download Full-text

Majority of alpha2,6-sialylated glycans in the adult mouse brain exist in O-glycans: SALSA-MS analysis for knockout mice of alpha2,6-sialyltransferase genes

Glycobiology ◽

10.1093/glycob/cwaa105 ◽

2020 ◽

Author(s):

Yuhsuke Ohmi ◽

Takashi Nishikaze ◽

Yoko Kitaura ◽

Takako Ito ◽

Satoko Yamamoto ◽

...

Keyword(s):

Sialic Acid ◽

Mouse Brain ◽

Adult Mouse ◽

Expression Profiles ◽

T Antigen ◽

Mass Spectrometry Analysis ◽

Gene Products ◽

Adult Mouse Brain ◽

The Brain ◽

Brain Tissues

Abstract Sialic acids are unique sugars with negative charge and exert various biological functions such as regulation of immune systems, maintenance of nerve tissues and expression of malignant properties of cancers. Alpha 2,6 sialylated N-glycans, one of representative sialylation forms, are synthesized by St6gal1 or St6gal2 gene products in humans and mice. Previously, it has been reported that St6gal1 gene is ubiquitously expressed in almost all tissues. On the other hand, St6gal2 gene is expressed mainly in the embryonic and perinatal stages of brain tissues. However, roles of St6gal2 gene have not been clarified. Expression profiles of N-glycans with terminal α2,6 sialic acid generated by St6gal gene products in the brain have never been directly studied. Using conventional lectin blotting and novel sialic acid linkage-specific alkylamidationmass spectrometry method (SALSA-MS), we investigated the function and expression of St6gal genes and profiles of their products in the adult mouse brain by establishing KO mice lacking St6gal1 gene, St6gal2 gene, or both of them (double knockout). Consequently, α2,6-sialylated N-glycans were scarcely detected in adult mouse brain tissues, and a majority of α2,6-sialylated glycans found in the mouse brain were O-linked glycans. The majority of these α2,6-sialylated O-glycans were shown to be disialyl-T antigen and sialyl-(6)T antigen by mass spectrometry analysis. Moreover, it was revealed that a few α2,6-sialylated N-glycans were produced by the action of St6gal1 gene, despite both St6gal1 and St6gal2 genes being expressed in the adult mouse brain. In the future, where and how sialylated O-linked glycoproteins function in the brain tissue remains to be clarified.

Download Full-text