pertpy.tools.LRClassifierSpace#
- class LRClassifierSpace[source]#
Fits a logistic regression model to the data and takes the feature space as embedding.
We fit one logistic regression model per perturbation. After training, the coefficients of the logistic regression model are used as the feature space. This results in one embedding per perturbation.
Methods table#
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Add perturbations linearly. |
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Fits a logistic regression model to the data and takes the coefficients of the logistic regression model as perturbation embedding. |
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Subtract mean of the control from the perturbation. |
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Quantify the effect size of each perturbation as a function of dose. |
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Score how well an additive model predicts combination perturbations. |
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Impute missing values in the specified column using KNN imputation in the space defined by use_rep. |
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Rank perturbations by their proximity to a query perturbation in a perturbation space. |
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Plot a clustered heatmap of pairwise distances between perturbations. |
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Subtract perturbations linearly. |
Methods#
- LRClassifierSpace.add(adata, *, perturbations, reference_key='control', ensure_consistency=True, target_col='perturbation')#
Add perturbations linearly. Assumes input of size n_perts x dimensionality.
- Parameters:
adata (
AnnData) – Anndata object of size n_perts x dim.reference_key (
str, default:'control') – perturbation source from which the perturbation summation starts.ensure_consistency (
bool, default:True) – If True, differentiate against control via compute_control_diff before combining so that “perturbation - perturbation == control” holds in the resulting space. Set False only if the input has already been differenced.target_col (
str, default:'perturbation') – .obs column name that stores the label of the perturbation applied to each cell.
- Return type:
- Returns:
Anndata object of size (n_perts+1) x dim, where the last row is the addition of the specified perturbations. If ensure_consistency is True, returns a tuple of (new_perturbation, adata) where adata is the AnnData object provided as input but updated using compute_control_diff.
Examples
Example usage with PseudobulkSpace:
>>> import pertpy as pt >>> mdata = pt.dt.papalexi_2021() >>> ps = pt.tl.PseudobulkSpace() >>> ps_adata = ps.compute(mdata["rna"], target_col="gene_target", groups_col="gene_target") >>> new_perturbation = ps.add(ps_adata, perturbations=["ATF2", "CD86"], reference_key="NT")
- LRClassifierSpace.compute(adata, target_col='perturbation', layer_key=None, embedding_key=None, test_split_size=0.2, max_iter=1000, random_state=0)[source]#
Fits a logistic regression model to the data and takes the coefficients of the logistic regression model as perturbation embedding.
- Parameters:
adata (
AnnData) – AnnData object of size cells x genestarget_col (
str, default:'perturbation') – .obs column that stores the label of the perturbation applied to each cell.layer_key (
str|None, default:None) – Layer in adata to use.embedding_key (
str|None, default:None) – Key of the embedding in obsm to be used as data for the logistic regression classifier. Can only be specified if layer_key is None.test_split_size (
float, default:0.2) – Fraction of data to put in the test set.max_iter (
int, default:1000) – Maximum number of iterations taken for the solvers to converge.random_state (
int|Generator|RandomState|None, default:0) – Random seed for the train/test split and the classifier.
- Return type:
- Returns:
AnnData object with one observation per perturbation, the logistic regression coefficients in .X and the perturbation labels in .obs[target_col].
Examples
>>> import pertpy as pt >>> adata = pt.dt.norman_2019() >>> rcs = pt.tl.LRClassifierSpace() >>> pert_embeddings = rcs.compute(adata, embedding_key="X_pca", target_col="perturbation_name")
- LRClassifierSpace.compute_control_diff(adata, *, target_col='perturbation', group_col=None, reference_key='control', layer_key=None, new_layer_key='control_diff', embedding_key=None, new_embedding_key='control_diff', all_data=False, copy=True)#
Subtract mean of the control from the perturbation.
- Parameters:
adata (
AnnData) – Anndata object of size cells x genes.target_col (
str, default:'perturbation') – .obs column name that stores the label of the perturbation applied to each cell.group_col (
str|None, default:None) – .obs column name that stores the label of the group of each cell. If None, ignore groups.reference_key (
str, default:'control') – The key of the control values.layer_key (
str|None, default:None) – Key of the AnnData layer to use for computation.new_layer_key (
str, default:'control_diff') – the results are stored in the given layer.embedding_key (
str|None, default:None) – obsm key of the AnnData embedding to use for computation.new_embedding_key (
str, default:'control_diff') – Results are stored in a new embedding in obsm with this key.all_data (
bool, default:False) – if True, do the computation in all data representations (X, all layers and all embeddings)copy (
bool, default:True) – If True returns a new AnnData; otherwise updates the input AnnData in place.
- Return type:
- Returns:
Updated AnnData object.
Examples
Example usage with PseudobulkSpace:
>>> import pertpy as pt >>> mdata = pt.dt.papalexi_2021() >>> ps = pt.tl.PseudobulkSpace() >>> diff_adata = ps.compute_control_diff(mdata["rna"], target_col="gene_target", reference_key="NT")
- LRClassifierSpace.dose_response(adata, *, target_col='perturbation', dose_col='dose', reference_key='control', metric='edistance', layer_key=None, embedding_key=None, **kwargs)#
Quantify the effect size of each perturbation as a function of dose.
For every (perturbation, dose) group the statistical distance to
reference_keyis computed in the chosen representation usingDistance. Operates on cell-level data, since distances are defined between groups of cells.- Parameters:
adata (
AnnData) – Cell-level AnnData.target_col (
str, default:'perturbation') – .obs column with the perturbation label.dose_col (
str, default:'dose') – .obs column with the (numeric) dose.reference_key (
str, default:'control') – Control perturbation all doses are compared against.metric (
Literal['edistance','euclidean','root_mean_squared_error','mse','mean_absolute_error','pearson_distance','spearman_distance','kendalltau_distance','cosine_distance','r2_distance','mean_pairwise','mmd','wasserstein','sym_kldiv','t_test','ks_test','nb_ll','classifier_proba','classifier_cp','mean_var_distribution','mahalanobis'], default:'edistance') – Distance metric passed toDistance.layer_key (
str|None, default:None) – Layer to compute distances from.embedding_key (
str|None, default:None) – .obsm embedding to compute distances from.kwargs – Passed to
onesided_distances().
- Return type:
- Returns:
Tidy DataFrame with
perturbation,doseanddistancecolumns, sorted by perturbation then dose.
Examples
>>> import pertpy as pt >>> adata = pt.dt.srivatsan_2020_sciplex2() >>> ps = pt.tl.PseudobulkSpace() >>> curves = ps.dose_response(adata, dose_col="dose_value", embedding_key="X_pca")
- LRClassifierSpace.evaluate_combinations(adata, *, combinations=None, target_col='perturbation', reference_key='control', metric='pearson', sep='+')#
Score how well an additive model predicts combination perturbations.
For every combination
"A+B"whose componentsAandBare each present as single perturbations, the additive predictioneffect(A) + effect(B)is compared against the measured combination effect, where effects are taken relative toreference_key. A small distance indicates additive, non-interacting perturbations, whereas a large deviation flags a genetic or pharmacological interaction.- Parameters:
adata (
AnnData) – Perturbation-level AnnData indexed by perturbation (one observation per perturbation).combinations (
Iterable[str] |None, default:None) – Combination names to evaluate. If None, everyobs_namecontainingsepwhose components are all present as singles is used.target_col (
str, default:'perturbation') – .obs column identifying each perturbation.reference_key (
str, default:'control') – Control perturbation subtracted to obtain effects. If absent, values are used as-is.metric (
Literal['pearson','cosine','euclidean'], default:'pearson') – Distance between predicted and measured combination effects.sep (
str, default:'+') – Separator between components in combination names.
- Return type:
- Returns:
DataFrame indexed by combination with
distance,predicted_magnitudeandmeasured_magnitudecolumns, sorted by ascending distance.
Examples
>>> import pertpy as pt >>> adata = pt.dt.norman_2019() >>> ps = pt.tl.PseudobulkSpace() >>> ps_adata = ps.compute(adata, target_col="perturbation_name") >>> scores = ps.evaluate_combinations(ps_adata, target_col="perturbation_name", reference_key="control")
- LRClassifierSpace.label_transfer(adata, *, target_column='perturbation', column_uncertainty_score_key='perturbation_transfer_uncertainty', target_val='unknown', neighbors_key='neighbors')#
Impute missing values in the specified column using KNN imputation in the space defined by use_rep.
Uncertainty is calculated as the entropy of the label distribution in the neighborhood of the target cell. In other words, a cell where all neighbors have the same set of labels will have an uncertainty of 0, whereas a cell where all neighbors have many different labels will have high uncertainty.
- Parameters:
adata (
AnnData) – The AnnData object containing single-cell data.target_column (
str, default:'perturbation') – The column name in adata.obs to perform imputation on.column_uncertainty_score_key (
str, default:'perturbation_transfer_uncertainty') – The column name in adata.obs to store the uncertainty score of the label transfer.target_val (
str, default:'unknown') – The target value to impute.neighbors_key (
str, default:'neighbors') – The key in adata.uns where the neighbors are stored.
- Return type:
Examples
>>> import pertpy as pt >>> import scanpy as sc >>> import numpy as np >>> adata = sc.datasets.pbmc68k_reduced() >>> # randomly dropout 10% of the data annotations >>> adata.obs["perturbation"] = adata.obs["louvain"].astype(str).copy() >>> random_cells = np.random.choice(adata.obs.index, int(adata.obs.shape[0] * 0.1), replace=False) >>> adata.obs.loc[random_cells, "perturbation"] = "unknown" >>> sc.pp.neighbors(adata) >>> sc.tl.umap(adata) >>> ps = pt.tl.PseudobulkSpace() >>> ps.label_transfer(adata)
- LRClassifierSpace.nearest_perturbations(adata, perturbation, *, target_col='perturbation', n_neighbors=10, layer_key=None, embedding_key=None, metric='euclidean')#
Rank perturbations by their proximity to a query perturbation in a perturbation space.
Operates on a perturbation-level AnnData (one observation per perturbation), i.e. the output of any
compute. Useful for discovering perturbations with a similar mechanism of action. Ifadata.obsp["distances"]is present (as produced byDistanceSpace) and no representation is requested explicitly, those precomputed distances are used directly.- Parameters:
adata (
AnnData) – Perturbation-level AnnData indexed by perturbation.perturbation (
str) – The query perturbation to find neighbors for.target_col (
str, default:'perturbation') – .obs column identifying each perturbation.n_neighbors (
int, default:10) – Number of nearest perturbations to return.layer_key (
str|None, default:None) – Layer to compute distances from.embedding_key (
str|None, default:None) – .obsm embedding to compute distances from.metric (
str, default:'euclidean') – Distance metric passed tosklearn.metrics.pairwise_distances().
- Return type:
- Returns:
DataFrame indexed by perturbation with a
distancecolumn, sorted ascending and excluding the query.
Examples
>>> import pertpy as pt >>> adata = pt.dt.norman_2019() >>> ps = pt.tl.PseudobulkSpace() >>> ps_adata = ps.compute(adata, target_col="perturbation_name") >>> neighbors = ps.nearest_perturbations(ps_adata, "CBL+CNN1", target_col="perturbation_name")
- LRClassifierSpace.plot_similarity(adata, *, target_col='perturbation', layer_key=None, embedding_key=None, metric='euclidean', cmap='viridis', **kwargs)#
Plot a clustered heatmap of pairwise distances between perturbations.
Uses
adata.obsp["distances"]when present (e.g. fromDistanceSpace) and otherwise computes pairwise distances in the chosen representation.- Parameters:
adata (
AnnData) – Perturbation-level AnnData indexed by perturbation.target_col (
str, default:'perturbation') – .obs column identifying each perturbation.layer_key (
str|None, default:None) – Layer to compute distances from.embedding_key (
str|None, default:None) – .obsm embedding to compute distances from.metric (
str, default:'euclidean') – Distance metric passed tosklearn.metrics.pairwise_distances().cmap (
str, default:'viridis') – Matplotlib colormap.kwargs – Passed to
seaborn.clustermap().
- Returns:
The grid returned by
seaborn.clustermap().
Examples
>>> import pertpy as pt >>> adata = pt.dt.norman_2019() >>> ds = pt.tl.DistanceSpace() >>> ds_adata = ds.compute(adata, target_col="perturbation_name", metric="edistance") >>> ds.plot_similarity(ds_adata, target_col="perturbation_name")
- LRClassifierSpace.subtract(adata, *, perturbations, reference_key='control', ensure_consistency=True, target_col='perturbation')#
Subtract perturbations linearly. Assumes input of size n_perts x dimensionality.
- Parameters:
adata (
AnnData) – Anndata object of size n_perts x dim.reference_key (
str, default:'control') – Perturbation source from which the perturbation subtraction starts.ensure_consistency (
bool, default:True) – If True, differentiate against control via compute_control_diff before combining so that “perturbation - perturbation == control” holds in the resulting space. Set False only if the input has already been differenced.target_col (
str, default:'perturbation') – .obs column name that stores the label of the perturbation applied to each cell.
- Return type:
- Returns:
Anndata object of size (n_perts+1) x dim, where the last row is the subtraction of the specified perturbations. If ensure_consistency is True, returns a tuple of (new_perturbation, adata) where adata is the AnnData object provided as input but updated using compute_control_diff.
Examples
Example usage with PseudobulkSpace:
>>> import pertpy as pt >>> mdata = pt.dt.papalexi_2021() >>> ps = pt.tl.PseudobulkSpace() >>> ps_adata = ps.compute(mdata["rna"], target_col="gene_target", groups_col="gene_target") >>> new_perturbation = ps.subtract(ps_adata, reference_key="ATF2", perturbations=["BRD4", "CUL3"])