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Snakemake workflow to benchmark scRNA-seq data simulators

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Snakemake workflow to benchmark
scRNA-seq data simulators


Setup

Dependencies

The current code was implemented using R v4.1.0, Bioconductor v3.13, Snakemake v5.5.0, and Python v3.6.8. All R dependencies (from GitHub, CRAN and Bioconductor) are listed under code/10-session_info.R and may be installed using the command contained therein.

Structure

  • config.yaml specifies the R library and version to use
  • code contains all R scripts used in the Snakemake workflow
  • data contains raw, filtered and simulated scRNA-seq datasets,
    as well as simulation parameter estimates
  • meta contains two .json files that specify simulation method (methods.json) and reference subset (subsets.json) configurations
  • outs contains all results from computations (typically data.frames) as .rds files
  • figs contains all visual outputs as .pdf files, and corresponding ggplot objects as .rds files (for subsequent arrangement into 'super'-figures)

Simulation methods are tagged with one or many of the following labels, according to which scenario(s) they can accommodate:

  • n for none: no clusters or batches
  • b for batch: multiple batches, no clusters
  • k for cluster: multiple clusters, no batches

Similarly, we tag subsets (see below) with exactly one of these labels. This allows running each method on subsets they are capable of simulating.


Workflow

Schematic of the computational workflow used to benchmark scRNA-seq simulators. (1) Methods are grouped according to which level of complexity they can accommodate: type n (`singular'), b (batches), k (clusters). (2) Raw datasets are retrieved reproducibly from a public source, filtered, and subsetted into various datasets that serve as reference for (3) parameter estimation and simulation. (4) Various gene-, cell-level and global summaries are computed from reference and simulated data, and (5) compared in a one- and two-dimensional setting using two statistics each. (6) Integration and clustering methods are applied to type b and k references and simulations, respectively, and relative performances compared between reference-simulation and simulation-simulation pairs.

Preprocessing

1. Data retrieval

Each code/00-get_data-<datset_id>.R script retrieves a publicly available scRNA-seq dataset through from which a SingleCellExperiment is constructed and written to data/00-raw/<datset_id>.rds

2. Filtering

code/01-fil_data.R is applied to each raw dataset as to

  • remove batches, cluster, or batch-cluster instances with fewer than 50 cells (depending on the dataset's complexity)
  • keep genes with a count of at least 1 in at least 10 cells, and remove cells with fewer than 100 detected genes

Filtered data are written to data/01-fil/<datset_id>.rds.

3. Subsetting

Because different methods can accommodate only some features (e.g. multiple batches or clusters, both or neither), code/02-sub_data.R creates specific subsets in data/02-sub/<datset_id>.<subset_id>,rds. We term these ref(erence)sets (i.e. <datset_id>.<subset_id> = <refset_id>), as they serve as the input reference data for simulation.

Simulation

1. Parameter estimation

Simulation parameters are estimated with code/03-est_pars.R, which in term sources a code/03-est_pars-<method_id>.R script that executes a method's parameter estimation function(s). In cases where no separate estimation takes place, this returns NULL. Parameter estimates for each combination of <refset_id.<method_id> = <simset_id> are written to data/04-est/<simset_id>.rds.

2. Data simulation

Data is simulated with code/04-sim_data.R, which in term sources a code/04-sim_data-<method_id>.R script that executes a method's simulation function. Simulations for each combination of <refset_id> and method_id are written to data/05-sim/<refset_id>,<method_id>.rds.

Summaries

Various quality control (QC) summaries are computed with code/05-calc_qc.R, which in term sources a set of code/05-calc_qc-<metric_id>.R scripts. QC results for reference and simulated data are written to outs/qc_ref-<refset_id>,<metric_id>.rds and outs/qc_sim-<simset_id>,<metric_id>.rds, respectively. At current, we consider:

1. Gene-level

  • frq: detection frequency (i.e., fraction of cells with non-zero counts)
  • avg/var: average/variance of logCPM
  • cv: coefficient of variation
  • cor: gene-to-gene correlation

2. Cell-level

  • frq: detection frequency (i.e., fraction of genes with non-zero counts)
  • lls: log-transformed library size (total counts)
  • cor: cell-to-cell correlation
  • pcd: cell-to-cell distance (in PCA space)
  • knn: number of KNN occurrences
  • ldf: local density factor

3. Global

  • sw: Silhouette width (using batch/cluster labels as classes)
  • cms: cell-specific mixing score (using batch/cluster labels as batches)
  • pve: percent variance explained (of gene expression = logCPM, by batch/cluster)

Noteworthily, we compute each summary for different groupings of cells (depending on the dataset's complexity):

  1. globally, i.e. across all cells
  2. at the batch-level, i.e. for each batch
  3. at the cluster-level, i.e. for each cluster

Global summaries are computed at the batch-/cluster-level only, as they require a grouping variable.

Statistics

We compare summaries between reference and simulated data in both one- (code/06-stat_1d.R) and two-dimensional settings (code/06-statl_2d.R). For the latter, every combination of gene- and cell-level metrics is considered, excluding correlations and global summaries. Furthermore, metrics are evaluated for each cell grouping, i.e. we perform a test globally, for each batch and cluster (again, depending on the dataset's complexity). Test results are written to outs/stat_1d,<refset_id>,<metric_id>,<stat1d_id>.rds for 1D, and outs/stat_2d,<refset_id>,<metric1_id>,<metric2_id>,<stat2d_id>.rds for 2D tests.

1. One-dimensional

  • Kolmogorov-Smirnov (KS) test
  • Wasserstein metric

2. Two-dimensional

  • two-dimensional KS test
  • Earth Mover's Distance (EMD)

Downstream

Integration

Each 05-calc_batch-x.R script wraps around an integration method that is applied in 05-calc_batch.R to the set of type b subsets. The output corrected assay data or integrated cell embeddings (depending on the method) are written to outs/batch_ref/sim-<ref/simset_id>,<batch_method>.rds for every reference and simulation, respectively. Results are evaluated by 06-eval_batch.R, which computes the following set of metrics:

  • cell-specific mixing score (CMS)
  • difference in local density factor ($\Delta$LDF)
  • batch correction score (BCS)

Clustering

Each 05-calc_clust-x.R script wraps around an integration method that is applied in 05-calc_clust.R to the set of type b subsets. The output cluster assignments are written to outs/clust_ref/sim-<ref/simset_id>,<clust_method>.rds for every reference and simulation, respectively. Results are evaluated by 06-eval_clust.R, which computes the following set of metrics:

  • precision (P) and recall (R)
  • F1 score (harmonic mean of P and R)

Visualization

Finally, results are collected across refset_ids and method_ids (jointly or separated by type), and visualized in various ways using as set of 07-plot_x.R scripts. Output figures are written to plts as .pdf files, along with the corresponding ggplot objects as .rds files. Lastly, 08-fig_x.R scripts are used to combined various ggplots into figures that are saved to figs as .pdf files.


Customization

Datasets

In principle, any dataset for which a code/00-get_data-<dataset_id>.R script exists will be accessible to the workflow. However, data will only be retrieved if the dataset appears in meta/subsets.json. Hence,

Removing

To exclude a dataset from the workflow, i) (re)move the corresponding code/00-get_data-<dataset_id>.R script; or, ii) remove or comment out any associated meta/subsets.json entries.

Adding

Similarly, a new dataset can be added by supplying an adequate code/00-get_data-<dataset_id>.R script, and adding an entry to the meta/subsets.json configuration that specifies the subset ID, the number of genes/cells to sample (NULL for all), which batch(es)/cluster(s) to retain, as well as the resulting subset's type (one of n,b,k,g).

Methods

The Snakemake will automatically include any simulation method for which a code/03-est_pars-<method_id>.R and code/04-sim_data-<method_id>.R script exists. Secondly, meta/methods.json will determine on which type(s) of dataset(s) each method should be run. Thus,

Removing

To exclude a method from the workflow, either i) set "<method_id>": "x" in the meta/methods.json file (or anything other than n,b,k,g); or, ii) (re)move the parameter estimation and/or simulation script from the code directory.

Adding

Analogous to the above, adding a method to the benchmark requires i) adding a code/03-est_pars-<method_id>.R and code/04-sim-data-<method_id>.R script; and, ii) adding an entry for the method_id to the meta/methods.json file. Importantly, the R script for parameter estimation should handle batches (colData column batch), clusters (colData column cluster), both or neither. And the method's type(s) should be specified accordingly (n for neither, b/k for batches/clusters, g for groups), e.g. "<method_id>": ["n", "k"] for a method that supports 'singular' datasets, as well as ones with multiple clusters.