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MiSDEED

Microbiome Synthetic Data Engine for Experimental Design

MiSDEED is a command-line tool and Python package for generating synthetic microbial abundance data. Its uses include power analysis and experimental design, creating simulations from verifiable ground truth for algorithm development, and generating synthetic data for model pretraining and transfer learning. Currently, MiSDEED supports the generation of multiple (possibly case-control) timecourses from an arbitrary number of interacting nodes. MiSDEED is distributed under the MIT license.

This project is run by Philippe Chlenski at Columbia University. A manuscript for MiSDEED is currently in peer review.

Diagram

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Installation

MiSDEED can easily be installed using pip as follows:

pip install misdeed

Dependencies

Dependencies are listed in requirements.txt and can be installed using

pip install -r requirements.txt

Misdeed command-line interface

Usage

MiSDEED is used as follows:

    ./misdeed [-h] node_sizes [-iNtDCPVRnevrTdciE] [--options]

Here the node_sizes positional parameter is a comma-separated list of integers. To see MiSDEED parameters, run the following command:

./misdeed -h

Example

git clone https://github.com/pchlenski/misdeed
cd misdeed

# install requirements
pip install -r requirements.txt

# generate a trajectory from the `example' directory to the `out' directory
./misdeed 4 --input_dir ./example --output_dir ./out

# modify generator parameters
./misdeed 10,15,20 --node_names mgx,mbx,mtx --time_points 50 --discard_first 50

# custom community matrix
./misdeed 10,15,20 --connectivity 0.4 --self_penalty 10 --variance 1.5 --correlation 0.5

# custom simulation parameters
./misdeed 10,15,20 --n_samples 10 --extinct_fraction 0.1 --noise_variance 0.001 --n_reads 2000 --time_step 0.05 --downsample 5

# custom case-control parameters
./misdeed 10,15,20 --n_samples 10 --case_fraction 0.5 --intervention_node n0 --effect_size 0.5

# generate and plot case-control trajectories
./misdeed 10,15,20 --n_samples 10 --case_fraction 0.5 --plot --pca

Inputs

If using the --input_dir parameter, MiSDEED will assume your input directory follows these conventions:

  • All files are in tsv (tab-separated values) format and end in ".tsv"
  • Node conventions:
    • Initial abundances are named [node_name]_x0.tsv
    • Growth rates are named [node_name]_g.tsv
    • Each node has a growth rate and a node name
    • Initial abundances and growth rates are equal to node dimensionality
  • Intervention conventions:
    • Intervention magnitudes are named [intervention_name]_[node_name]_u.tsv
    • Node responses are named [intervention_name]_[node_name]_b.tsv
    • Each intervention has a growth rate and a node name
    • Intervention magnitude dimensionality is equal to number of time points (set by --time_points parameter)
    • Node response dimensionality is equal to node dimensionality
  • Interaction conventions:
    • Interactions are named [outbound_node_name]->[inbound_node_name].tsv
    • At least one interaction is defined
    • Interaction matrix has shape (outbound node dimensionality) x (inbound node dimensionality)

The example directory in this repository contains a minimal example of these conventions.

Outputs

By default, MiSDEED will save results to the ./output directory as follows:

Single sample

output
`---[UUID]
    |---X
    |   |---[node_0_name].tsv
    |   |---[node_1_name].tsv
    |   `---...
    |---Y
    |   |---[node_0_name].tsv
    |   |---[node_1_name].tsv
    |   `---...
    |---Z
    |   |---[node_0_name].tsv
    |   |---[node_1_name].tsv
    |   `---...
    |---pca
    |   |---[node_0_name].png
    |   |---[node_1_name].png
    |   `---...
    `---plots
        |---[node_0_name].png
        |---[node_1_name].png
        `---...

Multiple samples

output
`---[UUID]
    |---X
    |   |---0
    |   |   |---[node_0_name].tsv
    |   |   |---[node_1_name].tsv
    |   |   `---...
    |   |---1
    |   |   |---[node_0_name].tsv
    |   |   |---[node_1_name].tsv
    |   |   `---...
    |   `---...
    |---Y
    |   |---0
    |   |   |---[node_0_name].tsv
    |   |   |---[node_1_name].tsv
    |   |   `---...
    |   |---1
    |   |   |---[node_0_name].tsv
    |   |   |---[node_1_name].tsv
    |   |   `---...
    |   `---...
    |---Z
    |   |---0
    |   |   |---[node_0_name].tsv
    |   |   |---[node_1_name].tsv
    |   |   `---...
    |   |---1
    |   |   |---[node_0_name].tsv
    |   |   |---[node_1_name].tsv
    |   |   `---...
    |   `---...
    |---pca
    |   |---[node_0_name].png
    |   |---[node_1_name].png
    |   `---...
    `---plots
        |---0_[node_0_name].png
        |---0_[node_1_name].png
        |---...
        |---1_[node_0_name].png
        |---1_[node_1_name].png
        `---...

Case-control

output
`---[UUID]
    |---case
    |   |---X
    |   |   |---0
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   |---1
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   `---...
    |   |---Y
    |   |   |---0
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   |---1
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   `---...
    |   |---Z
    |   |   |---0
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   |---1
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   `---...
    |   `---plots
    |       |---0_[node_0_name].png
    |       |---0_[node_1_name].png
    |       |---...
    |       |---1_[node_0_name].png
    |       |---1_[node_1_name].png
    |       `---...
    |---control
    |   |---X
    |   |   |---0
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   |---1
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   `---...
    |   |---Y
    |   |   |---0
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   |---1
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   `---...
    |   |---Z
    |   |   |---0
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   |---1
    |   |   |   |---[node_0_name].tsv
    |   |   |   |---[node_1_name].tsv
    |   |   |   `---...
    |   |   `---...
    |   `---plots
    |       |---0_[node_0_name].png
    |       |---0_[node_1_name].png
    |       |---...
    |       |---1_[node_0_name].png
    |       |---1_[node_1_name].png
    |       `---...
    `---pca
        |---[node_0_name].png
        |---[node_1_name].png
        `---...

OmicsGenerator Python package

The OmicsGenerator class has the following public methods:

  • add_node: Adds nodes to generator object.
  • add_interaction: Adds interactions to generator object.
  • add_intervention: Adds an intervention to generator.
  • set_initial_value: Sets a node value or growth rate.
  • get: Gets a (node/interaction/intervention) by name.
  • remove: Removes a node, intervention, or interaction from the generator by name.
  • generate: Generates a single timecourse of synthetic data.
  • generate_multiple: Generates several timecourses of synthetic data.
  • case_control: Generates synthetic case and control timecourses.
  • copy: Makes a deep copy of generator.
  • save: Saves generator outputs as plaintext files.

In addition, the package contains a number of utility functions:

  • inference.infer_glv_params: Infers community matrix, growth rates, and perturbation responses from absolute abundance data.
  • visualization.plot_timecourse: Plots timecourses of compositional data.
  • visualization.plot_pca: Plots PCA-transformed timecourses.

Examples

The corresponding Jupyter notebook can be found at notebooks/examples.ipynb.

Initialize generator

# initialize generator:
gen = OmicsGenerator(
    nodes=['mgx', 'mbx'],  # 2 nodes named 'mgx' and 'mbx'
    node_sizes=[15, 15],   # each node has 15 dimensions
    init_full=True         # set interaction matrices and growth rates randomly
)

# add intervention:
gen.add_intervention(
    'int1',                # intervention name
    'mgx',                 # apply to 'mgx' node
    10*np.random.rand(15), # set intervention response vector randomly
    start=50,              # start at t=50
    end=100                # go to end
)

Single timecourse

# run generator and plot:
z1, x1, y1 = gen.generate(dt=1e-2)
plot_timecourse(y1['mgx'])
plt.vlines(50, 0, 1)

Single timecourse

Multiple timecourses

# run multi-generator and plot:
z2, x2, y2 = gen.generate_multiple(20)
plot_pca([y2], 'mgx')

Multiple timecourses

Case-control

# run case-control and plot:
z3_control, x3_control, y3_control, z3_case, x3_case, y3_case = gen.case_control(100, .75, 'mgx', 1)
plot_pca([y3_control, y3_case], 'mgx', colors=['red', 'blue'], plot_trajectories=False)

Case-control

Using learned parameters

# run case-control and plot:
gen4 = OmicsGenerator(
    nodes=['mgx'],         # 1 node named 'mgx'
    node_sizes=[15],       # 'mgx' has 15 dimensions
    init_full=True         # set interaction matrices and growth rates randomly
)

# add intervention:
gen4.add_intervention(
    'int1',                # intervention name
    'mgx',                 # apply to 'mgx' node
    10*np.random.rand(15), # set intervention response vector randomly
    start=50,              # start at t=50
    end=100                # go to end
)

# generate training data
z4, x4, y4 = gen4.generate(dt=1e-2)

# infer params
M, u, E = infer_glv_params(
    z4['mgx'],             # use (latent) absolute abundances
    gen4.get('int1').U,    # assume intervention indicator is known
    interaction_reg=100,   # L1 penalty for interaction matrix
    growth_reg=0,          # L1 penalty for growth rates
    intervention_reg=0,    # L1 penalty for intervention responses
    dt=1e-2                # same time-step as generator
)

# build inferred generator
gen4_inferred = OmicsGenerator(nodes=['mgx'], node_sizes=[15])
gen4_inferred.add_interaction('M', 'mgx', 'mgx', M)
gen4_inferred.add_intervention('int1', 'mgx', E.reshape(-1), start=50, end=100)
gen4_inferred.set_initial_value('mgx', u.reshape(-1), growth_rate=True)
gen4_inferred.set_initial_value('mgx', gen4.get('mgx').initial_value) # same init. abundances as gen 1

z4_inferred, x4_inferred, y4_inferred = gen4_inferred.generate(dt=1e-2)

# plot both trajectories
colors = cm.get_cmap('magma', 20)(range(15))

for i in range(15):
    plt.plot(np.cumsum(z4_inferred['mgx'], axis=1)[:,i], alpha=0.5, c=colors[i])
    plt.plot(np.cumsum(z4['mgx'], axis=1)[:,i], alpha=0.5, c=colors[i])

Using learned parameters

MiSDEED paper and citation

The preprint for MiSDEED is available on bioRxiv. It can be cited as follows:

@article {chlenski2021misdeed,
    author = {Chlenski, Philippe and Hsu, Melody and Pe'er, Itsik},
    title = {MiSDEED: a synthetic multi-omics engine for microbiome power analysis and study design},
    year = {2021},
    doi = {10.1101/2021.08.09.455682},
    publisher = {Cold Spring Harbor Laboratory},
    journal = {bioRxiv}
}