Datasets
In the CC nomenclature, a dataset is determined by:
- One coordinate.
- One (typically) or multiple (eventually) sources having the same type of (mergeable) data.
- A processing procedure yielding signatures type 0.
Levels, coordinates and datasets
The CC is divided into five levels of increasing complexity:
Level | Name | Description |
---|---|---|
A |
Chemistry | Chemical properties of the compounds. |
B |
Targets | Chemical-protein interactions. |
C |
Networks | Higher-order effects of small molecules. |
D |
Cells | Readouts of compound cell-based assays. |
C |
Clinics | Clinical data of drugs and environmental chemicals. |
In turn, each level is divided into 5 sublevels or coordinates representing different aspects of the data. Each sublevel has an exemplary dataset, as described below:
Coordinate | Name | Description |
---|---|---|
A1 |
2D fingerprints | Binary representation of the 2D structure of a molecule. The neighbourhood of every atom is encoded using circular topology hashing. |
A2 |
3D fingerprints | Similar to A1 , the 3D structures of the three best conformers after energy minimization are hashed into a binary representation without the need for structural alignment. |
A3 |
Scaffolds | Largest molecular scaffold (usually a ring system) remaining after applying Murcko’s pruning rules. Additionally, we keep the corresponding framework, i.e. a version of the scaffold where all atoms are carbons and all bonds are single. The scaffold and the framework are encoded with path-based 1024-bit fingerprints, suitable for capturing substructures in similarity searches. |
A4 |
Structural keys | 166 functional groups and substructures widely accepted by medicinal chemists (MACCS keys). |
A5 |
Physicochemistry | Physicochemical properties such as molecular weight, logP, and refractivity. Number of hydrogen-bond donors and acceptors, rings, etc. Drug-likeness measurements e.g. number of structural alerts, Lipinski’s rule-of-5 violations or chemical beauty (QED). |
B1 |
Mechanism of action | Drug targets with known pharmacological action and modes (agonist, antagonist, etc.). |
B2 |
Metabolic genes | Drug metabolizing enzymes, transporters, and carriers. |
B3 |
Crystals | Small molecules co-crystalized with protein chains. Data is organized according to the structural families of the protein chains. |
B4 |
Binding | Compound--protein binding data available in major public chemogenomics databases. Data mainly comes from academic publications and patents. Only binding affinities below a class-specific threshold are kept (kinases ≤ 30 nM, GPCRs ≤ 100 nM, nuclear receptors ≤ 100 nM, ion channels ≤ 10 uM and others ≤ 1 uM). |
B5 |
HTS bioassays | Hits from screening campaigns against protein targets (mainly confirmatory functional assays below 10 uM). |
C1 |
Biological roles | Ontology terms associated with small molecules with recognized biological roles, such as known drugs, metabolites and other natural products. |
C2 |
Metabolic network | Curated reconstruction of human metabolism, containing metabolites and reactions. Data is represented as a network where nodes are metabolites and edges connect substrates and products of reactions. |
C3 |
Canonical pathways | Canonical pathways related to the known receptors of compounds (as recorded in B4 ). Pathways are assigned via a guilt-by-association approach, i.e. a molecule is related to a pathway if at least one of the molecule targets is a member of it. |
C4 |
Biological processes | Similar to C3 , biological processes from the gene ontology are associated with compounds via a guilt-by-association approach from B4 data. All parent terms are kept, from the leaves of the ontology to its root. |
C5 |
Interactomes | Neighborhoods of B4 targets are collected by inspecting several large protein-protein interaction networks. A random-walk algorithm is used to obtain a robust measure of 'proximity' in the network. |
D1 |
Gene expression | Transcriptional response of cell lines upon exposure to small molecules. A well-documented reference dataset of gene expression profiles is used to map all compound profiles using a two-sided gene set enrichment analysis. |
D2 |
Cancer cell lines | Small molecule sensitivity data (GI50) of a panel of 60 cancer cell lines. |
D3 |
Chemical genetics | Growth inhibition profiles in a panel of ~300 yeast mutants. Data are combined with yeast genetic interaction data so that compounds can be assimilated to genetic alterations when they have similar profiles. |
D4 |
Morphology | Changes in U-2 OS cell morphology measured after compound treatment using a multiplexed-cytological cell painting assay. 812 morphology features are recorded via automated microscopy and image analysis. |
D5 |
Cell bioassays | Small molecule cell bioassays reported in ChEMBL, mainly growth and proliferation measurements found in the literature. |
E1 |
Therapeutic areas | Anatomical Therapeutic Chemical (ATC) codes of drugs. All ATC levels are considered. |
E2 |
Indications | Indications of approved drugs and drugs in clinical trials. A controlled medical vocabulary is used. |
E3 |
Side effects | Side effects extracted from drug package inserts via text-mining techniques. |
E4 |
Disease phenotypes | Manually curated relationships between chemicals and diseases. Chemicals include drug molecules and environmental substances, among others. |
E5 |
Drug-drug interactions | Changes in the effect of a drug when it is taken together with a second drug. Drug-drug interactions may alter pharmacokinetics and/or cause side effects. |
Each of the coordinates can contain an arbitrary number of datasets. All datasets are fully described in the PostGreSQL database, and searchable at the CC web app (A1.001
).
Dataset characteristics
This is how we define a dataset:
Column | Values | Description |
---|---|---|
Code | e.g.A1.001
|
Identifier of the dataset. |
Level | e.g. A
|
The CC level. |
Coordinate | e.g.A1
|
Coordinates in the CC organization. |
Name | 2D fingerprints | Display, short-name of the dataset. |
Technical name | 1024-bit Morgan fingerprints | A more technical name for the dataset, suitable for chemo-/bio-informaticians. |
Description | 2D fingerprints are... | This field contains a long description of the dataset. It is important that the curator outlines here the importance of the dataset, why did he/she make the decision to include it, and what are the scenarios where this dataset may be useful. |
Unknowns |
True /False
|
Does the dataset contain known/unknown data? Binding data from chemogenomics datasets, for example, are positive-unlabeled, so they do contain unknowns. Conversely, chemical fingerprints or gene expression data do not contain unknowns. |
Discrete |
True /False
|
The type of data that ultimately expresses de dataset, after the pre-processing. Categorical variables are not allowed; they must be converted to one-hot encoding or binarized. Mixed variables are not allowed, either. |
Keys | e.g. CPD (we use @afernandez Bioteque nomenclature). Can be NULL . |
In the core CC database, most of the times this field will correspond to CPD , as the CC is centred on small molecules. It only makes sense to have keys of different types when we do connectivity attempts, that is, for example, when mapping disease gene expression signatures. |
Features | e.g. GEN (we use Bioteque nomenclature). Can be NULL . |
When features correspond to explicit knowledge, such as proteins, gene ontology processes, or indications, we express with this field the type of biological entities. It is not allowed to mix different feature types. Features can, however, have no type, typically when they come from a heavily-processed dataset, such as gene-expression data. Even if we use Bioteque nomenclature to the define the type of biological data, it is not mandatory that the vocabularies are the ones used by the Bioteque ; for example, I can use non-human UniProt ACs, if I deem it necessary. |
Exemplary |
True /False
|
Is the dataset exemplary of the coordinate. Only one exemplary dataset is valid for each coordinate. Exemplary datasets should have good coverage (both in keys space and feature space) and acceptable quality of the data. |
Public |
True /False
|
Some datasets are public, and some are not, especially those that come from collaborations with the pharma industry. |
See the PostgreSQL database for more information.
Dataset pre-processing
Every dataset has a particular processing protocol, always consisting of two consecutive steps:
- Fetching of data and conversion to a standard input file.
- It is very important that data are minimally transformed here.
- Data may be fetched from the downloaded files, from calculated properties, or from a file of interest of the user.
- From standard input to signature type 0
- When adding/updating a dataset, all procedures here must be encapsulated in a
fit()
method. - Accordingly, a
predict()
method must be available. - Acceptable standard inputs include:
.gmt
,.h5
and.tsv
. It is strongly recommended that input features are recognizable entities, e.g. those defined in theBioteque
.
It is of the utmost importance that step 2 is endowed with a predict()
method. Having the ability to convert any standard input to a signature type 0 (in an automated manner) will enable implementation of connectivity methods. This is a critical feature of the CC and I anticipate that most of our efforts will be put in this particular step.