INSPIRE

We develop INSPIRE, a deep learning-based method for integrating and interpreting multiple spatial transcriptomics (ST) datasets from diverse sources. It integrates information across sections in a shared latent space, where meaningful biological variations from the input sections are preserved, while complex unwanted variations are eliminated. Utilizing this shared latent space, INSPIRE achieves an integrated NMF on gene expressions across sections, decomposing biological signals in different sections into consistent and interpretable spatial factors with associated gene programs. These inferred spatial factors often correspond to distinct cell populations and biological processes within the analyzed tissues.

INSPIRE takes gene expression count matrices and spatial coordinates from multiple ST sections as input, and generates three key outputs: latent representations of cells or spatial spots, non-negative spatial factors for cells or spatial spots, and non-negative gene loadings shared among datasets.

By integrating multiple ST datasets with INSPIRE, users can:

• Identify spatial trajectories and major spatial regions consistently across datasets using latent representations of cells or spatial spots.

• Reveal detailed tissue architectures, spatial distributions of cell types, and organizations of biological processes in tissues across sections using non-negative spatial factors for cells or spatial spots.

• Detect spatially variable genes, identify gene programs associated with specific spatial architectures in tissues, and conduct pathway enrichment analysis using non-negative gene loadings.

Quick Start and Usage Instructions

• Instructions
  • Using INSPIRE with graph attention networks (GATs)
  • Using INSPIRE with lightweight graph convolutional networks (LGCNs)

INSPIRE Tutorials

• Tutorials
  • Example 1: Analysis of human dorsolateral prefrontal cortex (DLPFC) dataset.
    • Run INSPIRE on the human DLPFC dataset
    • Calculate benchmarking scores
    • Perform spatial trajectory inference
    • Enrichment or depletion of spatial factors in cortical layers
    • Analysis of spatial factors and their associated gene signatures
    • Run INSPIRE on the human DLPFC dataset (12 sections)
  • Example 2: Analysis of mouse brain slices with complementary views.
    • Run INSPIRE on the mouse brain slices with different views
    • Analysis of spatial factors shared among slices and their gene signatures
    • Analysis of spatial factors specific to one slice and their associated gene signatures
  • Example 3: Analysis of mouse brain slices across distinct ST technologies.
    • Run INSPIRE on the brain datasets generated by Slide-seq V2 and MERFISH
    • Analysis of the Slide-seq V2 dataset only
    • Screen for cell-cell communication among the identified cortical layers
  • Example 4: Analysis of mouse whole-embryo slices across distinct ST technologies.
    • Run INSPIRE on the whole-embryo datasets generated by seqFISH and Stereo-seq
    • Analysis of spatial factors
    • Validate INSPIRE’s gene imputation capability
    • Impute gene expressions for seqFISH data from Stereo-seq data
    • Differentially expressed gene analysis based on measured and imputed genes
  • Example 5: Analysis of mouse whole-embryo slices across developmental stages.
    • Run INSPIRE on whole-embryo slices across multiple developmental stages
    • Changes in proportions of spots covered by the identified organs and tissues across stages
    • Analysis of the liver region identified by INSPIRE
    • Analysis of INSPIRE’s identified brain region III
    • Analysis of the spatial factor related to choroid plexus and its associated gene signature
    • Analysis of the spatial factor related to smooth muscle cells and its associated gene signature
  • Example 6: Spatial registration between two MERFISH hypothalamus sections.
    • Run INSPIRE on adjacent MERFISH slices from mouse hypothalamic preoptic region
    • Analysis of spatial factors
    • Spatially register the two MERFISH sections using rigid transformation with MNNs
  • Example 7: Spatial registration between two STARmap PLUS hippocampus sections.
    • Run INSPIRE on STARmap PLUS sections from mouse hippocampus
    • Spatially register the two STARmap PLUS sections using rigid transformation with MNNs
    • Spatially register the two STARmap PLUS sections using rigid transformation with the ICP algorithm
  • Example 8: 3D reconstruction of mouse embryo by integrating multiple 2D slices.
    • Run INSPIRE on multiple mouse embryo slices for 3D reconstruction
    • Reconstruct 3D model of the mouse embryo by spatially register adjacent 2D slices
    • 3D reconstructions of liver, heart, and a brain subregion that varies along the left-right axis
    • 3D spatially-resolved gene expression patterns
  • Example 9: Analysis of mouse skin data undergoing wound healing
    • Run INSPIRE on the mouse skin sections
    • Analysis of spatial factors
  • Example 10: Analysis of human breast cancer Xenium data, revealing microenvironment heterogeneity across tumor subtypes
    • Run INSPIRE on the human breast cancer Xenium sections
    • Spatial region identification in the human breast cancer data analysis
    • Analysis of spatial factors corresponding to myoepithelial subpopulations
    • Analysis of spatial factors corresponding to endothelial subpopulations

INSPIRE Installation

• Installation
  • Installation
  • Software dependencies