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A spatial omics data analysis tool that enables both unsupervised and supervised discovery of complex tissue cellular neighborhoods from cell phenotypes.

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Unsupervised and supervised discovery of tissue cellular neighborhoods from cell phenotypes with CytoCommunity

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Overview

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It remains poorly understood how different cells in a tissue organize and coordinate with each other to support tissue functions. To better understand the structure-function relationship of a tissue, the concept of tissue cellular neighborhoods (TCNs) or spatial domains as well as their identification tools have been proposed. However, we found several limitations as below.

(1) Most existing methods are originally designed for spatial transcriptomics data and thus use expression of hundreds or thousands of genes as features to infer TCNs. Such methods may not be applicable to spatial proteomics data that only have a few tens of protein expression features available.

(2) Using gene expression data as input cannot directly establish the relationship between cell types and TCNs in a tissue, making the interpretation of TCNs challenging.

(3) Given a cohort of tissue samples associated with different conditions (e.g., disease risk and patient prognosis), it is important to identify condition-specific TCNs with more biological and clinical relevance (e.g., tertiary lymphoid structure (TLS), which is typically present in low-risk but not in high-risk patients of many cancer types). Most existing methods are designed to detect TCNs in individual tissue samples by unsupervised learning and thus not applicable for the identification of condition-specific TCNs de novo.

We developed this tool, named CytoCommunity, for identifying TCNs that can be applied in either unsupervised or supervised fashion. We formulate TCN identification as a community detection problem on graphs and employ a graph neural network (GNN) model to identify TCNs. Several advantages include:

(1) CytoCommunity directly uses cell phenotypes as features to learn TCN partitions and thus facilitates the interpretation of TCN functions.

(2) CytoCommunity can not only infer TCNs for individual samples (unsupervised mode), but also identify condition-specific TCNs from a cohort of labeled tissue samples by leveraging differentiable graph pooling and sample labels (supervised mode), which is an effective strategy to address the difficulty of graph alignment across samples.

Highlights on the differences of TCNs identified by the two learning modes:

TCNs are identified per sample/image using the unsupervised mode and thus TCNs from different samples/images are NOT aligned.

TCNs are identified in all samples/images simultaneously using the supervised mode and thus TCNs from different samples/images are aligned.

In summary, CytoCommunity represents the first computational tool for end-to-end unsupervised and supervised analyses of single-cell spatial omics maps and enables discovery of conditional-specific cell-cell communication patterns across variable spatial scales.

This latest version (main branch) is CytoCommunity V1.1.0. Please refer to https://github.com/huBioinfo/CytoCommunity/releases for previous versions.

Installation

Hardware requirement

CPU: i7

Memory: 16G or more

Storage: 10GB or more

Software requirement

Conda version: 22.9.0

Python version: 3.10.6

R version: >= 4.0 suggested

Clone this repository and cd into it as below.

git clone https://github.com/huBioinfo/CytoCommunity.git
cd CytoCommunity

For Windows

Preparing the virtual environment

  1. Create a new conda environment using the environment.yml file or the requirements.txt file with one of the following commands:

    conda env create -f environment.yml
    # or
    conda create --name CytoCommunity --file requirements.txt

Note that the command should be executed in the directory containing the environment.yml or requirements.txt file. And if you use the .txt file, please convert it to the UTF-8 format.

Alternatively, the requirements can also be installed directly in a new conda environment:

conda create --name CytoCommunity pyhton=3.10.6
conda activate CytoCommunity
conda install --yes --file requirements.txt
  1. Install the diceR package (R has already been included in the requirements) with the following command:

    R.exe
    > install.packages("diceR")

For Linux

Preparing the virtual environment

  1. Create a new conda environment using the environment_linux.yml file and activate it:

    conda env create -f environment_linux.yml
    conda activate CytoCommunity
  2. Install R and the diceR package:

    conda install R
    R
    > install.packages("diceR")

The whole installation should take around 20 minutes.

Usage

The CytoCommunity algorithm for TCN indentification can be used in either an unsupervised or a supervised learning mode. You can reproduce TCN partitions shown in the published CytoCommunity paper using the commands below. The associated code scripts and example input data can be found under the directory "Tutorial/".

Unsupervised CytoCommunity

Prepare input data

The example input data to the unsupervised learning mode of CytoCommunity is derived from a mouse brain MERFISH dataset generated by Moffitt et al. (Science, 2018), including three types of files: (1) cell type label and (2) cell spatial coordinate files for each sample/image, as well as (3) an image name list file. These example input files can be found under the directory "Tutorial/Unsupervised/MERFISH-Brain_Input/".

Note that the naming fashion of the three types of files cannot be changed when using your own data. These files should be named as "[image name]_CellTypeLabel.txt", "[image name]_Coordinates.txt" and "ImageNameList.txt". Here, [image_name] should be consistent with your customized image names listed in the "ImageNameList.txt". The "[image name]_CellTypeLabel.txt" and "[image name]_Coordinates.txt" list cell type names and cell coordinates (tab-delimited x/y) of all cells in an image, respectively. The cell orders should be exactly the same across the two files.

Run the following steps in Windows Powershell or Linux Bash shell:

1. Use Step1 to construct KNN-based cellular spatial graghs and convert the input data to the standard format required by Torch.

This step generates a folder "Step1_Output" including constructed cellular spatial graphs of all samples/images in your input dataset folder (e.g., /MERFISH-Brain_Input/). No need to re-run this step for different images.

conda activate CytoCommunity
cd Tutorial/Unsupervised
python Step1_ConstructCellularSpatialGraphs.py

  Hyperparameters

  • InputFolderName: The folder name of your input dataset.
  • KNN_K: The K value used in the construction of the K nearest neighbor graph (cellular spatial graph) for each sample/image. This value can be empirically set to the integer closest to the square root of the average number of cells in the images in your dataset.

2. Use Step2 to perform soft TCN assignment learning in an unsupervised fashion.

This step generates a folder "Step2_Output_[specified image name]" including multiple runs (subfolders) of soft TCN assignment learning module. Each subfolder contains a cluster adjacent matrix, a cluster assignment matrix (soft TCN assignment matrix), a node mask file and a loss recording file. You need to re-run this step for different images by changing the hyperparameter "Image_Name".

python Step2_TCNLearning_Unsupervised.py

  Hyperparameters

  • InputFolderName: The folder name of your input dataset, consistent with Step1.
  • Image_Name: The name of the sample/image on which you want to identify TCNs.
  • Num_TCN: The maximum number of TCNs you expect to identify.
  • Num_Run: How many times to run the soft TCN assignment learning module in order to obtain robust results. [Default=20]
  • Num_Epoch: The number of training epochs. This value can be smaller than the default value [3000] for the large image (e.g., more than 10,000 cells).
  • Embedding_Dimension: The dimension of the embedding features for each cell. [Default=128]
  • Learning_Rate: This parameter determines the step size at each iteration while moving toward a minimum of a loss function. [Default=1E-4]
  • Loss_Cutoff: An empirical cutoff of the final loss to avoid underfitting. This value can be larger than the default value [-0.6] for the large image (e.g., more than 10,000 cells).

3. Use Step3 to perform TCN assignment ensemble.

The result of this step is saved in the "Step3_Output_[specified image name]/TCNLabel_MajorityVoting.csv" file. Make sure that the diceR package has been installed before Step3. You need to re-run this step for different images by changing the hyperparameter "Image_Name".

Rscript Step3_TCNEnsemble.R

  Hyperparameters

  • Image_Name: The name of the sample/image on which you want to identify TCNs, consistent with Step2.

4. Use Step4 to visualize single-cell spatial maps colored based on cell type annotations and final TCN partitions.

This step generates a folder "Step4_Output_[specified image name]" including two plots of this single-cell spatial map (in PNG and PDF formats) colored by input cell type annotations and identified TCNs, respectively. A "ResultTable_[specified image name].csv" file is also genereated to store the detailed information of this single-cell spatial map. You need to re-run this step for different images by changing the hyperparameter "Image_Name".

python Step4_ResultVisualization.py

  Hyperparameters

  • InputFolderName: The folder name of your input dataset, consistent with Step1.
  • Image_Name: The name of the sample/image on which you want to identify TCNs, consistent with Step2.

Supervised CytoCommunity

Prepare input data

The example input data to the supervised learning mode of CytoCommunity is derived from a triple-negative breast cancer (TNBC) MIBI-TOF dataset generated by Keren et al. (Cell, 2018), including four types of files: (1) cell type label and (2) cell spatial coordinate and (3) graph (sample) label files for each sample/image, as well as (4) an image name list file. These example input files can be found under the directory "Tutorial/Supervised/MIBI-TNBC_Input/".

Note that the naming fashion of the four types of files cannot be changed when using your own data. These files should be named as "[image name]_CellTypeLabel.txt", "[image name]_Coordinates.txt", "[image name]_GraphLabel.txt" and "ImageNameList.txt". Here, [image_name] should be consistent with your customized image names listed in the "ImageNameList.txt". The "[image name]_CellTypeLabel.txt" and "[image name]_Coordinates.txt" list cell type names and cell coordinates (tab-delimited x/y) of all cells in an image, respectively. The cell orders should be exactly the same across the two files. Different from unsupervised version, supervised CytoCommunity requires the "[image name]_GraphLabel.txt", where lists an integer (like "0", "1", "2", etc) to describe the graph/sample/image label.

Run the following steps in Windows Powershell or Linux Bash shell:

1. Use Step1 to construct KNN-based cellular spatial graghs and convert the input data to the standard format required by Torch.

This step generates a folder "Step1_Output" including constructed cellular spatial graphs of all samples/images in your input dataset folder (e.g., /MIBI-TNBC_Input/).

conda activate CytoCommunity
cd Tutorial/Supervised
python Step1_ConstructCellularSpatialGraphs.py

  Hyperparameters

  • InputFolderName: The folder name of your input dataset.
  • KNN_K: The K value used in the construction of the K nearest neighbor graph (cellular spatial graph) for each sample/image. This value can be empirically set to the integer closest to the square root of the average number of cells in the images in your dataset.

2. Use Step2 to perform soft TCN assignment learning in a supervised fashion.

This step generates a folder "Step2_Output", including results ("Time" folder) of running the soft TCN assignment learning module using the 10 times of 10-fold cross-validation fashion. Each "Time" folder contains results ("Fold" folder) of one time of 10-fold cross-validation. Each "Fold" folder contains cluster assignemnt matrix (soft TCN assignment matrix) files for all images.

python Step2_TCNLearning_Supervised.py

  Hyperparameters

  • Num_TCN: The maximum number of TCNs you expect to identify.
  • Num_Times: How many times to run the cross-vadlidation independently. [Default=10]
  • Num_Folds: The k value in the k-fold cross-validation. [Default=10]
  • Num_Epoch: The number of training epochs. [Default=100]
  • Embedding_Dimension: The dimension of the embedding features for each cell. [Default=512]
  • MiniBatchSize: This value is commonly set to be powers of 2 due to efficiency consideration. In the meantime, this value is suggested to be closest to half sizes of the training sets. [Default=16]
  • Learning_Rate: This parameter determines the step size at each iteration while moving toward a minimum of a loss function and should be increased with the mini-batch size increase. [Default=1E-4]
  • beta: A weight parameter to balance the MinCut loss used for graph partitioning and the cross-entropy loss used for graph classification. The default value is set to [0.9] due to emphasis on graph partitioning.

3. Use Step3 to perform TCN assignment ensemble.

The results of this step are saved under the "Step3_Output/ImageCollection/" directory. A "TCNLabel_MajorityVoting.csv" file will be generated for each image. Make sure that the diceR package has been installed before Step3.

Rscript Step3_TCNEnsemble.R

  Hyperparameters

  • InputFolderName: The folder name of your input dataset, consistent with Step1.

4. Use Step4 to visualize single-cell spatial maps colored based on cell type annotations and final TCN partitions.

This step generates a folder "Step4_Output" including three subfolders. The "CellType_Plot" subfolder stores single-cell spatial maps of all images (in PNG and PDF formats) colored by input cell type annotations. The "TCN_Plot" subfolder stores single-cell spatial maps of all images (in PNG and PDF formats) colored by identified TCNs. The "ResultTable_File" subfolder stores detailed information of single-cell spatial maps of all images in CSV format.

python Step4_ResultVisualization.py

  Hyperparameters

  • InputFolderName: The folder name of your input dataset, consistent with Step1.

Update Log

2024-01-08: The latest release “CytoCommunity_v1.1.0” makes the input data easier to prepare, compared to the original version v1.0.0.

Maintainers

Yuxuan Hu (huyuxuan@xidian.edu.cn)

Yafei Xu (22031212416@stu.xidian.edu.cn)

Kai Tan (tank1@chop.edu)

Citation

Yuxuan Hu, Jiazhen Rong, Yafei Xu, Runzhi Xie, Jacqueline Peng, Lin Gao, Kai Tan. Unsupervised and supervised discovery of tissue cellular neighborhoods from cell phenotypes. Nature Methods, 2024, https://doi.org/10.1038/s41592-023-02124-2.

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A spatial omics data analysis tool that enables both unsupervised and supervised discovery of complex tissue cellular neighborhoods from cell phenotypes.

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