KG2 is the second-generation knowledge graph for the
ARAX biomedical reasoning system. This Github
repository contains all of
the code for building KG2 as well as all of the documentation about how to
build, host, access, and use KG2. The KG2 build system produces knowledge graphs
in a Biolink model
standard-compliant JSON format and in a tab-separated value (TSV) format that
can be imported into a Neo4j graph database system. Through
additional scripts in the ARAX kg2c
subdirectory, the build system can
produce a "canonicalized" knowledge graph where synonym concepts (nodes) are
identified. Through additional scripts in the mediKanren
subdirectory, the
build system can produce an export of the KG2 knowledge graph that is suitable
for importing into the mediKanren
biomedical reasoning system.
The table of contents for this README is as follows:
- KG2: the second-generation RTX knowledge graph
- KG2 team contact information
- Is RTX-KG2 published?
- How to access RTX-KG2
- What data sources are used in KG2?
- How to build RTX-KG2 from its upstream sources
- General notes:
- Setup your computing environment
- The KG2 build system assumes there is no MySQL already installed
- AWS buckets
- AWS authentication
- Typical EC2 instance type used for building KG2
- Build instructions - What to do if a build fails - Note about versioning of KG2
- Possible failure modes for the KG2 build
- The output KG
- Updating the installed KG2 build system software
- Hosting KG2 in a Neo4j server on a new AWS instance
- Reloading KG2 into an existing Neo4j server
- Co-hosting the KG2 build system and Neo4j server?
- Post-setup tasks
- Schema of the JSON KG2
- Frequently asked questions
- Troubleshooting
- For Developers
- Shell coding standards for KG2 + File naming
- Credits
- Stephen Ramsey, Oregon State University ([email protected])
- Lili Acevedo, Oregon State University ([email protected])
- Amy Glen, Oregon State University ([email protected])
- E. C. Wood, Stanford University
Please use the GitHub issues page for this project.
Yes, please see:
Wood, E.C., Glen, A.K., Kvarfordt, L.G. et al. RTX-KG2: a system for building a semantically standardized knowledge graph for translational biomedicine. BMC Bioinformatics 23, 400 (2022). https://doi.org/10.1186/s12859-022-04932-3
The preprint can be found at: doi:10.1101/2021.10.17.464747.
(RTX-KG2 team members only: contact the KG2 maintainer for the endpoint, username, and password)
Information from many knowledge databases is combined in building KG2. The table below was compiled from the Snakemake diagram and ont-load-inventory.yaml.
Knowledge Source | Type | Redistribution license info | Home page |
---|---|---|---|
ChemBL | data | link | link |
DGIDB | data | link | link |
DisGeNET | data | link | link |
DrugBank | data | link | link |
DrugCentral | data | link | |
Ensembl | data | link | link |
GO_Annotations | data | link | |
Guide to Pharmacology | data | link | |
HMDB | data | link | |
IntAct | data | link | |
JensenLab | data | link | |
miRBase | data | link | link |
NCBIGene | data | link | |
PathWhiz | data | link | |
Reactome | data | link | link |
SemMedDB | data | link | link |
SMPDB | data | link | link |
Therapuetic Target Database | data | link | |
Unichem | data | link | |
UniprotKB | data | link | link |
Anatomical Therapeutic Chemical Classification System | ontology | link | |
Basic Formal Ontology | ontology | link | |
Biological Spatial Ontology | ontology | link | |
Cell Ontology | ontology | link | |
Chemical Entities of Biological Interest | ontology | link | |
CPT in HCPCS | ontology | link | |
Current Procedural Terminology | ontology | link | |
Dictyostelium discoideum anatomy | ontology | link | |
Disease Ontology | ontology | link | |
Experimental Factor Ontology | ontology | link | |
FOODON (Food Ontology) | ontology | link | |
Foundational Model of Anatomy | ontology | link | |
Gene Ontology | ontology | link | |
Gene Ontology | ontology | link | |
Genomic Epidemiology Ontology | ontology | link | |
Healthcare Common Procedure Coding System | ontology | link | |
HL7 Version 3.0 | ontology | link | |
HUGO Gene Nomenclature Committee | ontology | link | |
Human developmental anatomy, abstract | ontology | link | |
Human Phenotype Ontology | ontology | link | |
ICD-10 Procedure Coding System | ontology | link | |
Interaction Network Ontology | ontology | link | |
International Classification of Diseases, Ninth Revision, Clinical Modification | ontology | link | |
Medical Subject Headings | ontology | link | |
Medication Reference Terminology | ontology | link | |
MedlinePlus Health Topics | ontology | link | |
Metathesaurus Names | ontology | link | |
Molecular Interactions Controlled Vocabulary | ontology | link | |
MONDO Disease Ontology | ontology | link | |
National Drug Data File | ontology | link | |
National Drug File | ontology | link | |
National Drug File - Reference Terminology | ontology | link | |
NCBITaxon | ontology | link | |
NCI Thesaurus | ontology | link | |
Neuro Behavior Ontology | ontology | link | |
Online Mendelian Inheritance in Man | ontology | link | link |
ORPHANET Rare Disease Ontology | ontology | link | |
Phenotypic Quality Ontology | ontology | link | |
Physician Data Query | ontology | link | |
Protein Ontology | ontology | link | |
Psychological Index Terms | ontology | link | |
Relation Ontology | ontology | link | |
RXNORM | ontology | link | |
Uber-anatomy Ontology | ontology | link |
The KG2 build system is designed only to run in an Ubuntu 22.04 environment
(i.e., either (i)Â an Ubuntu 22.04 host OS or (ii)Â Ubuntu 22.04 running in a
Docker container) as a non-root user which must have passwordless sudo
enabled
and should have bash
as the default shell (the build commands in the
instructions in this README page assume a bash
shell). The build system will
also need (but will set up for itself, prompting the user for access keys at
setup time) a local configured installation of the Amazon Web Services (AWS)
command-line interface (CLI) software in order to be able to retrieve various
required files on-demand from a storage bucket in the AWS Simple Storage Service
(S3) system. Currently, KG2 is built using a set of bash
scripts that are
designed to run in Amazon's Elastic Compute Cloud (EC2), and thus,
configurability and/or coexisting with other installed software pipelines was
not a design consideration for the build system. The KG2 build system's bash
scripts create three subdirectories under the ${HOME}
directory of whatever
Linux user account you use to run the KG2 build software (if you run on an EC2
Ubuntu instance, this directory would by default be /home/ubuntu
):
~/kg2-build
, where various build artifacts are stored~/kg2-code
, which is a symbolic link to the git checkout directoryRTX-KG2/
~/kg2-venv
, which is the virtualenv for the KG2 build system
The various directories used by the KG2 build system are configured in the
bash
include file master-config.shinc
. Most of the KG2 build system code is
written in the Python3 programming language, and designed to run in python3.7
(and tested specifically in python 3.7.5).
Note about atomicity of file moving: The build software is designed to run with
the kg2-build
directory being in the same file system as the Python temporary
file directory (i.e., the directory name that is returned by the variable
tempfile.tempdir
in Python). If the KG2 software or installation is modified
so that kg2-build
is in a different file system from the file system in which
the directory tempfile.tempdir
(as referenced in the tempfile
python module)
resides, then the file moving operations that are performed by the KG2 build
software will not be atomic and interruption of build-kg2.sh
or its
subprocesses could then leave a source data file in a half-downloaded (i.e.,
broken) state.
Build Frequency: We are currently aiming to build KG2 approximately once per month, to keep it as current as feasible given the cost to build and validate KG2 from its upstream sources.
The computing environment where you will be running the KG2 build should be running Ubuntu 22.04. Your build environment should have the following minimum hardware specifications:
- 128 GiB of system memory
- 1,023 GiB of disk space in the root file system
- high-speed networking (20 Gb/s networking) and storage
- if you are on the RTX-KG2 team: ideally your build system should be in the AWS
region
us-west-2
since that is where the RTX KG2 S3 buckets are located
We use r5a.4xlarge
AWS instances for KG2 builds.
The target Ubuntu system in which you will run the KG2 build should not have
MySQL installed; if MySQL is already installed, you will need to delete it,
which you can do using the following bash
command, which requires curl
:
(WARNING! Please don't run this command without first making a backup image of
your system, such as an AMI):
source <(curl -s https://raw.githubusercontent.com/RTXteam/RTX-KG2/master/delete-mysql-ubuntu.sh)
The KG2 build system has been tested only under Ubuntu 18.04. If you want to build KG2 but don't have a native installation of Ubuntu 18.04 available, your best bet would be to use Docker (see Option 3 below).
In order to be able to build KG2, you'll need to have at least one AWS S3 bucket
set up (or use an existing bucket; for the KG2 creators, we use S3 three
buckets, s3://rtx-kg2
, s3://rtx-kg2-public
, and s3://rtx-kg2-versioned
,
which are in the us-west-2
AWS region) and you will need to have an AWS
authentication key pair that is configured to be able to read from (and write
to) the bucket(s), so that the build script can download a copy of the full
Unified Medical Language System (UMLS) distribution. The full UMLS distribution (umls-2023AA-metathesaurus.zip
); IANAL, but it appears
that the UMLS is encumbered by a license preventing redistribution so I have not
hosted them on a public server for download; but you can get it for free at the
UMLS website if you agree to the UMLS
license terms)), the DrugBank distribution (drugbank.xml.gz
), the SMPDB publications CSV file (obtained from the Wishart Lab), and the SemMedDB distriction will need to
be pre-placed in the S3 bucket and the local copy of master-config.shinc
will
need to be configured so that variables s3_bucket
, s3_bucket_public
, and
s3_bucket_versioned
point to the S3 bucket(s) and so that the shell variable
s3_region
identifies the AWS region in which the bucket(s) reside(s).
For the KG2 build system that we (the creators of KG2) have set up for use by
Team Expander Agent, the authentication key pair is associated with an IAM
account with username kg2-builder
; if you are setting up the KG2 build system
somewhere else, you will need to obtain your own AWS authentication key pair
that connects to an IAM account (or root AWS account, if you want to live
dangerously) that has S3 privileges to read from and write to the S3 buckets
that are configured in your local copy of master-config.shinc
. When you run
the KG2 setup script, you will be asked (by the AWS Command-line Interface, CLI)
to provide an authentication key pair. and it uploads the final output file
kg2-simplified.json.gz
to the buckets identified by the shell variables
s3_bucket
defined in master-config.shinc
(for the KG2 creators, that bucket
is s3://rtx-kg2
). Alternatively, you can set up your own S3 bucket to which to
copy the gzipped KG2 JSON file (which you would specify in the configuration
file master-config.shinc
), or in the file finish-snakemake.sh
, you can
comment out the line that copies the final gzipped JSON file to the S3
bucket. You will also need to edit (to fill in the correct Neo4j password) and
place a file RTXConfiguration-config.json
(template is in the KG2 source code
directory) into the S3 bucket identified by the shell variable s3_bucket
in
master-config.shinc
(for the KG2 creators, that bucket is s3://rtx-kg2/
);
As a minimal example of the data format for RTXConfiguration-config.json
, see the file
RTXConfiguration-config-EXAMPLE.json
in this repository code directory (note:
that config file can contain authentication information for additional server
types in the RTX system; those are not shown in the example file in this code
directory).
The KG2 build software has been tested with the following instance type:
- AMI: Ubuntu Server 22.04 LTS (HVM), SSD Volume Type -
ami-005bdb005fb00e791
(64-bit x86) - Instance type:
r5a.4xlarge
(128 GiB of memory) - Storage: 1,023 GiB, Elastic Block Storage
- Security Group: ingress TCP packets on port 22 (
ssh
) permitted
As of summer 2024, an on-demand r5a.4xlarge
instance in the us-west-2
AWS
region costs $0.904 per hour, so the cost to build KG2 (estimated to take 25
hours) would be approximately $23 (rough estimate, plus or minus
20%).
These instructions assume that you are logged into the target Ubuntu system, and
that the Ubuntu system has not previously had setup-kg2-build.sh
run (if it
has previously had setup-kg2-build.sh
run, you should first clear out the
instance by running clear-instance.sh
before proceeding, in order to ensure
that you are getting the exact python packages needed in the latest
requirements-kg2-build.txt
file in the KG2 codebase) and to ensure that
your build does not inadvertantly reuse artifacts from a previous RTX-KG2 build:
(1) Install the git
and screen
packages if they are not already installed (though
in an Ubuntu 22.04 instance created using the standard AWS AMI, they should already
be installed):
sudo apt-get update && sudo apt-get install -y screen git
(2) change to the home directory for user ubuntu
:
cd
(3) Clone the RTX software from GitHub:
git clone https://github.com/RTXteam/RTX-KG2.git
[An advantage to having the git clone
command separated out from the install script is
that it provides control over which branch you want to use for the KG2 build code.]
(4) Change branches to the KG2 buid code if necessary
cd ~/RTX-KG2/
git checkout [branch name]
(5) Setup the KG2 build system:
bash -x ~/RTX-KG2/setup-kg2-build.sh
Note that there is no need to redirect stdout
or stderr
to a log file, when
executing setup-kg2-build.sh
; this is because the script saves its own stdout
and
stderr
to a log file ~/kg2-build/setup-kg2-build.log
. This script takes just a
few minutes to complete. At some point, the script will print
fatal error: Unable to locate credentials
This is normal. The script will then prompt you to enter:
- your AWS Access Key ID
- your AWS Secret Access Key
- (both for an AWS account with access to the private S3 bucket that is configured in
master-config.shinc
)
- (both for an AWS account with access to the private S3 bucket that is configured in
- your default AWS region, which in our case is normally
us-west-2
- (you should enter the AWS region that hosts the private S3 bucket that you intend to use with the KG2 build system)
- When prompted
Default output format [None]
, just hit enter/return.
For KG2 builders on the RTX-KG2
team, just use the keypair for the kg2-builder
IAM user.
If all goes well, the setup script should end with the message:
upload: ../setup-kg2-build.log to s3://rtx-kg2-versioned/setup-kg2-build.log
printed to the console. The aforementioned message means that the logfile from
running the setup script has been archived in the rtx-kg2-versioned
S3 bucket.
(6) Look in the log file ~/kg2-build/setup-kg2-build.log
to see if the script
completed successfully; it should end with ======= script finished ======
.
In that case it is safe to proceed.
(7) [THIS STEP IS NORMALLY SKIPPED] If (and only if) you have made code changes to KG2 that will cause a change to the schema for KG2 (or added a major new upstream source database), you will want to increment the "major" release number for KG2. To do that, at this step of the build process, you would run this command:
touch ~/kg2-build/major-release
[MORE COMMON ALTERNATIVE] For regular releases, you want to increment the "minor" release number. This is for situations where changes to the code have been made and the build will likely be deployed. If you want to increment the "minor" release number for KG2, you would run this command:
touch ~/kg2-build/minor-release
If you don't increment the release number at all, you should not be planning to deploy the build. This is useful for cases where you are testing the build system, but not necessarily different code or bug fixes.
(8) Run a "dry-run" build:
bash -x ~/kg2-code/build/build-kg2-snakemake.sh all -F -n
and inspect the file ~/kg2-build/build-kg2-snakemake-KG2.{major version}.{minor version}-n.log
that will be created, to make sure that
all of the KG2 build tasks are included. Currently, the file should end with the following
count of tasks:
Job counts:
count jobs
1 ChEMBL
1 ChEMBL_Conversion
1 ClinicalTrialsKG
1 ClinicalTrialsKG_Conversion
1 DGIdb
1 DGIdb_Conversion
1 DisGeNET
1 DisGeNET_Conversion
1 DrugBank
1 DrugBank_Conversion
1 DrugCentral
1 DrugCentral_Conversion
1 Ensembl
1 Ensembl_Conversion
1 Finish
1 GO_Annotations
1 GO_Annotations_Conversion
1 HMDB
1 HMDB_Conversion
1 IntAct
1 IntAct_Conversion
1 JensenLab
1 JensenLab_Conversion
1 KEGG
1 KEGG_Conversion
1 Merge
1 NCBIGene
1 NCBIGene_Conversion
1 Ontologies
1 Ontologies_Conversion
1 Reactome
1 Reactome_Conversion
1 SMPDB
1 SMPDB_Conversion
1 SemMedDB
1 SemMedDB_Conversion
1 Simplify
1 Simplify_Stats
1 Slim
1 Stats
1 TSV
1 UMLS
1 UMLS_Conversion
1 UniChem
1 UniChem_Conversion
1 UniProtKB
1 UniProtKB_Conversion
1 ValidationTests
1 miRBase
1 miRBase_Conversion
50
This was a dry-run (flag -n). The order of jobs does not reflect the order of execution.
+ [[ '' != \t\e\s\t ]]
+ [[ -n != \-\n ]]
+ [[ '' != \t\e\s\t ]]
+ [[ -n != \-\n ]]
+ [[ '' != \t\e\s\t ]]
+ [[ -n != \-\n ]]
+ date
Mon Sep 9 02:17:09 UTC 2024
+ echo '================ script finished ============================'
================ script finished ============================
Assuming the log file looks correct, proceed.
(9) Initiate a screen
session to provide a stable pseudo-tty:
screen
(then hit return to get into the screen session).
(10) THIS STEP COMMENCES THE BUILD. Within the screen session, run:
bash -x ~/kg2-code/build/build-kg2-snakemake.sh all -F
You may exit out of the screen session using the ctrl-a d
key sequence. The
all
command line argument specifies that you would like to run a full build.
This is the best option if you are running on a new instance, or have added
upstream sources. Otherwise, consider the following options:
Partial Build of KG2
In some circumstances, if there are no updates to any of the upstream source
databases (like UMLS, ChEMBL, SemMedDB, etc.) that are extracted using
extract*.sh
scripts (as shown in the list of KG2 scripts), you can trigger
a "partial" build. This can be useful in cases where you are testing a change
to one of the YAML configuration files for KG2, for example. To do a partial
build, in Step (8) above, you would run
bash -x ~/kg2-code/build/build-kg2-snakemake.sh
(note the absence of the all
argument to build-kg2-snakemake.sh
). A partial build of KG2
may take about 12 hours. Note, you have to have previously run an all
build
of KG2, or else the partial build will not work. Note, when doing a partial build,
existing KG2 JSON files in the /home/ubuntu/kg2-build
directory from previous
builds will just get used and will not get updated; if you want any of those files
to get updated, you should delete them before running the partial build.
Test Build of KG2
For testing/debugging purposes, it is helpful to have a faster way to exercise the KG2 build code. For this, you may want to execute a "test" build. This build mode builds a smaller graph with a significantly reduced set of nodes and edges. Before you can do a test build, you must have previously done a full non-test build of KG2 at least once. To execute a full test build, in Step (8) above, you would run:
bash -x ~/kg2-code/build/build-kg2-snakemake.sh test
In the case of a test build, the intermediate JSON and TSV and log files created by the build system
will have -test
appended to the filename before the usual filename suffix
(.json
).
Note that there is no need to redirect stdout
or stderr
to a log file, when
executing build-kg2-snakemake.sh
; this is because the script saves its own
stdout
and stderr
to a log file ~/kg2-build/build-kg2-snakemake.log
. You
can watch the progress of your KG2 build by using this command:
tail -f ~/kg2-build/build-kg2-snakemake-KG2.{major version}.{minor version}.log
That file shows what has finished and what is still happening. If any line says
(exited with non-zero exit code)
the code has failed. However, since the code is
running in parallel, to minimize confusion, stdout
and stderr
for extraction and conversion scripts is piped into its own final based on the name of the script that runs. Log scripts are stored in ~/kg2-build/
At the end of the build process, you should inspect the logfile
~/kg2-build/filter_kg_and_remap_predicates.log
to see if there are warnings
like relation curie is missing from the YAML config file: CURIEPREFIX:some_predicate
where CURIEPREFIX
could be any CURIE prefix in
curies-to-urls-map.yaml
and some_predicate
is a snake-case predicate label
(or in the case of Relation Ontology, a numeric identifier). Any warnings of the
above format in filter_kg_and_remap_predicates.log
probably indicates that an
addition needs to be made to the file predicate-remap.yaml
, followed by a
partial rebuild starting with filter_kg_and_remap_predicates.py
(the Simplify
rule).
-
Let's suppose the build failed on the rule
UniChem
. In that case, you could fix the bug and then test your bugfix by running/home/ubuntu/kg2-venv/bin/snakemake --snakefile /home/ubuntu/kg2-code/build/Snakefile -R --until UniChem
which just runs that rule. Note, you should only use the above command after you have runbuild-kg2-snakemake.sh
(as in Step 8 above) at least once, otherwise you will get an error because the required Snakefile~/kg2-code/Snakefile
will not yet exist. Assuming that the above command is successful, you could then proceed. -
Restart the full build:
bash -x ~/kg2-code/build/build-kg2-snakemake.sh all
(Note, you only need the all
above if the rule is for an "extract-XXX.sh" script;
if it is for a rule that is downstream of the extract scripts, you can omit all
.
KG2 has semantic versioning with a graph/major/minor release system:
- The graph release number is always 2.
- The major release number is incremented when the schema for KG2 is changed (and the minor release is set to zero in that case)
- The minor release number is incremented for each non-test build for which the schema is not modified.
So an example version of KG2 would be "RTX KG 2.1.3" (graph release 2, major release 1, minor release 3). This build version is recorded in three places:
- the top-level
build
slot in the KG2 JSON file - in the
name
field of a node object withid
fieldRTX:KG2
(in both the JSON version of the KG and in the Neo4j version of the KG) - the file
s3://rtx-kg2-public/kg2-version.txt
in the S3 bucketrtx-kg2-public
.
By default, the KG2 build process (as outlined above) will automatically
increment the minor release number and update the file kg2-version.txt
in the
S3 bucket. If you are doing a build in which the KG2 schema has changed, you
should trigger the incrementing of the major release version by making sure to
do step (6) above. The build script (specifically, the script version.sh
)
will automatically delete the file ~/kg2-build/major-release
so that it will
not persist for the next build. Note: if the build system happens to terminate
unexpectedly while running version.sh
, or after the Simplify
rule,
you should check what state the files3://rtx-kg2-public/kg2-version.txt
was left in.
The version history for KG2 can be found here.
Occasionally a build will fail due to a connection error in attempting to cURL a file from one of the upstream sources (e.g., SMPDB, and less frequently, UniChem). As of KG2.10.1, several sources have hardcoded downloads from the S3 bucket - HMDB, DisGeNET, CHEBI, and ClinicalTrials KG. These hardcoded downloads should be backed out as the resolution improves. If KEGG's download fails, the conversion will fail and the extraction log will finish extremely fast. If KEGG's extraction finishes in less than 15 minutes, there is a connection issue.
Another failure mode is the versioning of ChemBL. Once ChemBL upgrades their dataset,
old datasets may become unavailable. This will result in failure when downloading. To
fix this, change the version number in extract-chembl.sh
.
The build-kg2-snakemake.sh
script creates
gzipped JSON Lines files and copies them to an S3 bucket
rtx-kg2
. You can access the gzipped JSON Lines files using the AWS command-line
interface (CLI) tool aws
with the command
aws s3 cp s3://rtx-kg2/kg2-simplified-KG2.{major version}.{minor version}-nodes.jsonl.gz .
aws s3 cp s3://rtx-kg2/kg2-simplified-KG2.{major version}.{minor version}-edges.jsonl.gz .
The TSV files for the knowledge graph can be accessed via HTTP as well,
aws s3 cp s3://rtx-kg2/kg2-tsv-KG2.{major version}.{minor version}.tar.gz .
You can access the various artifacts from the KG2 build (config file, log file,
etc.) at the AWS static website endpoint for the
rtx-kg2-public
S3 bucket: http://rtx-kg2-public.s3-website-us-west-2.amazonaws.com/
Each build of KG2 is labeled with a unique build date/timestamp. The build timestamp
can be found in the build
slot of the kg2-simplified.json
file and it can be
found in the node with ID RTX:KG2
in the Neo4j KG2 database.
We generally try to make the KG2 shell scripts idempotent, following best
practice for *nix shell scripting. However, changes to setup-kg2-build.sh
(or
setup-kg2-neo4j.sh
) that would bring in a new version of a major software
dependency (e.g., Python) of the KG2 build system are not usually tested for
whether they can also upgrade an existing installation of the build system;
this is especially an issue for software dependencies that are installed using
apt-get
. In the event that setup-kg2-build.sh
undergoes a major change that
would trigger such an upgrade (e.g., from Python3.7 to Python3.8), instead of
rerunning setup-kg2-build.sh
on your existing build system, we recommend that
you create a clean Ubuntu 18.04 instance and install using setup-kg2-build.sh
.
We host our production KG2 graph database in Neo4j version 3.5.13 with APOC
3.5.0.4, on an Ubuntu 18.04 EC2 instance with 64 GiB of RAM and 8 vCPUs
(r5a.2xlarge
) in the us-east-2
AWS region.
Installation: in a newly initialized Ubuntu 18.04 AWS
instance, as user ubuntu
, run the following commands:
(1) Make sure you are in your home directory:
cd
(2) Clone the RTX software from GitHub:
git clone https://github.com/RTXteam/RTX-KG2.git
(3) Change branches to the KG2 buid code if necessary
cd ~/RTX-KG2/
git checkout [branch name]
(4) Install and configure Neo4j, with APOC:
bash -x ~/RTX-KG2/neo4j/setup-kg2-neo4j.sh
This script takes just a few minutes to complete. At some point, the script will print
fatal error: Unable to locate credentials
This is normal. The script will then prompt you to enter your AWS Access Key ID
and AWS Secret Access Key, for an AWS account with access to the private S3
bucket that is configured in master-config.shinc
. It will also ask you to
enter your default AWS region; you should enter the AWS region that hosts the
private S3 bucket that you intend to use with the KG2 build system, which in our
case would be us-west-2
. When prompted Default output format [None]
, just
hit enter/return. Also, the setup script will print a warning
WARNING: Max 1024 open files allowed, minimum of 40000 recommended. See the Neo4j manual.
but this, too, can be ignored [The /lib/systemd/service/neo4j.service
file
that is installed (indirectly) by the setup script actually sets the limit to 60000,
for when the Neo4j database system is run via systemd (but when running neo4j-admin
at the CLI to set the password, Neo4j doesn't know this and it reports a limit warning).]
(5) Look in the log file ${HOME}/setup-kg2-neo4j.log
to see if the script
completed successfully; it should end with ======= script finished ======
.
(6) Start up a screen
session, and within that screen session, load KG2 into Neo4j:
bash -x ~/RTX-KG2/neo4j/tsv-to-neo4j.sh > ~/kg2-build/tsv-to-neo4j.log 2>&1
This script takes over three hours to complete.
(6) Look in the log file ~/kg2-build/tsv-to-neo4j.log
to see if the script
completed successfully; it should end with ======= script finished ======
.
Once you have loaded KG2 into Neo4j as described above, if you want to reload
KG2, just run (as user ubuntu
):
bash -x ~/RTX-KG2/tsv-to-neo4j.sh > ~/kg2-build/tsv-to-neo4j.log 2>&1
In theory, it should be possible to install Neo4j and load KG2 into it on the same Ubuntu instance where KG2 was built; but this workflow is usually not tested since in our setup, we nearly always perform the KG2 build and Neo4j hosting on separate AWS instances. This is because the system requirements to build KG2 are much greater than the system requirements to host KG2 in Neo4j.
-
We typically define a DNS
CNAME
record for the KG2 Neo4j server hostname, of the formkg2endpoint-kg2-X-Y.rtx.ai
, whereX
is the major version number andY
is the minor version number. -
Before you release a new build of KG2, please update the version history markdown file with the new build version and the numbers of the GitHub issues that are addressed/implemented in the new KG2 version.
-
After a build has successfully completed and verified, add a new release with the KG2 version number to GitHub. Include the
kg2-versions.md
entry for the version in the release text. -
Wherever possible we try to document the name of the build host (EC2 instance) used for the KG2 build in
kg2-versions.md
and we try to preserve thekg2-build
directory and its contents on that host, until a new build has superseded the build. Having the build directory available on the actual build host is very useful for tracking down the source of an unexpected relationship or node property. Any new data sources in the build or major updates (e.g., DrugBank, UMLS, or ChEMBL) should also be noted in thekg2-versions.md
file. -
One of the key build artifacts that should be inspected in order to assess the build quality is the JSON report
kg-simplified-report-KG2.{major version}.{minor version}.json
. This file should be inspected as a part of the post-build quality assessment process.
The files kg2-merged-KG2.{major version}.{minor version}-edges.jsonl
and kg2-merged-KG2.{major version}.{minor version}-nodes.jsonl
are intermediate files probably only of use to KG2
developers. The files kg2-simplified-KG2.{major version}.{minor version}-edges.jsonl
and kg2-simplified-KG2.{major version}.{minor version}-nodes.jsonl
are key artifacts of the build
process that feed into several downstream artifacts and may be of direct use to
application developers. Newlines, carriage returns, linefeed characters, or hard
tabs are not allowed in any string property or in any string scalar within a
list property in KG2. The JSON LInes data structure is a
name-value pair object (i.e., dictionary) with the following keys:
The top-level build
slot contains a dictionary whose keys are:
version
: a string containing the version identifier for the KG2 build, likeRTX KG2.2.3
. For a "test" build, the version identifier will have-TEST
appended to it.timestamp_utc
: a string containing the ISO 8601 date/timestamp (in UTC) for the build, like this:2020-08-11 21:51
.
The top-level nodes
slot contains a list of node objects. Each node object has
the following keys:
category
: a string containing a CURIE ID for the semantic type of the node, as a category in the Biolink model. Example:biolink:Gene
.category_label
: asnake_case
representation of thecategory
field, without thebiolink:
CURIE prefix.creation_date
: a string identifier of the date in which this node object was first created in the upstream source database; it has (at present) no consistent format, unfortunately (usual value isnull
).deprecated
: a Boolean field indicating whether or not this node has been deprecated by the upstream source database (usual value isfalse
).description
: a narrative description field for the node, in prose textfull_name
: a longer name for the node (often is identical to thename
field)id
: a CURIE ID for the node; this CURIE ID will be unique across nodes in KG2 (that constraint is enforced in the build process)iri
: a URI where the user can get more information about this node (we try to make these resolvable wherever possible)name
: a display name for the nodeprovided_by
: A CURIE ID list (which corresponds to an actual node in KG2) for the upstream information resource that is the definitive source for information about this node.publications
: a list of CURIE IDs of publications (e.g.,PMID
orISBN
orDOI
identifiers) that contain information about this nodereplaced_by
: a CURIE ID for the node that replaces this node, for cases when this node has been deprecated (usually it isnull
).synonym
: a list of strings with synonyms for the node; if the node is a gene, the first entry in the list should be the official gene symbol; other types of information can for certain node types be found in this list, such as protein sequence information for UniProt protein nodes. The entries in the node synonym property (which is of type list) are not guaranteed to beid
fields of actual nodes in KG2. Also, they are not comprehensive; if node Y is related to node X by abiolink:same_as
relation type, there is no guarantee that Y will be in the synonym property list for X (in most cases, it won't be).update date
: a string identifier of the date in which the information for this node object was last updated in the upstream source database; it has (at present) no consitent format, unfortunately; it is usually notnull
.has_biological_sequence
: a string of sequence information for nodes from DrugBank (SMILES), ChemBL (Canonical SMILES), HMDB (SMILES), miRBase ("sequence" - appears to be amino acids), and UniprotKB ("sequence" - also appears to be amino acids). For nodes from other sources, this property isnull
.
edges
: a list of edge objects. Each edge object has the following keys:relation_label
: asnake_case
representation of the plain English label for the original predicate for the edge provided by the upstream source database (see therelation
field)negated
: a Boolean field indicating whether or not the edge relationship is "negated"; usuallyfalse
, in the normal build process for KG2object
: the CURIE ID (id
) for the KG2 node that is the object of the edgeprimary_knowledge_source
: A list containing CURIE IDs (each of which corresponds to an actual node in KG2) for the upstream information resources that reported this edge's specific combination of subject/predicate/object (in the case of multiple providers for an edge, the other fields likepublications
are merged from the information from the multiple sources).publications
: a list of CURIE IDs of publications supporting this edge (e.g.,PMID
orISBN
orDOI
identifiers)publications_info
: a dictionary whose keys are CURIE IDs from the list in thepublications
field, and whose values are described in the next subsection ("publication_info")predicate_label
: asnake_case
representation of the plain English label for the simplified predicate (see thepredicate
field); in most cases this is a predicate type from the Biolink model.predicate
: a CURIE ID for the simplified relationsubject
: the CURIE ID (id
) for the KG2 node that is the subject of the edgeupdate_date
: a string identifier of the date in which the information for this node object was last updated in the upstream source database; it has (at present) no consitent format, unfortunately; it is usually notnull
.id
: a concatenated string of other edge attributes that uniquely identifies the edgesource_predicate
: a CURIE ID for the relation as reported by the upstream database source.qualified_predicate
qualified_object_aspect
qualified_object_direction
If it is not null
, the publications_info
object's values are objects containing
the following name/value pairs:
publication date
: string representation of the date of the publication, in ISO 8601 format (%Y-%m-%d %H:%i:%S
)sentence
: a string containing the natural language sentence from which the edge was inferred (this is only notnull
for SemMedDB edges, at present)subject score
: a string containing a confidence score; for SemMedDB edges, this score corresponds to a confidence with which the subject of the triple was correctly identified; for other edges (like ChEMBL drug to target predictions), the score corresponds to a confidence in a computational prediction of the ligand-to-target binding relationship; NOTE: there at present no unified scale for this field, unfortunatelyobject score
: for SemMedDB edges, this score corresponds to a confidence with which the subject of the triple was correctly identified; otherwisenull
KG2 aims to comply with the Biolink knowledge graph format.
Dump files of RTX-KG2pre and RTX-KG2c are available for download in the github:ncats/translator-lfs-artifacts project area.
It's complicated. The KG2 build software is provided free-of-charge via the MIT license. All documentation for KG2 and any downloadable build artifacts hosted on GitHub or S3 are provided free-of-charge via the (CC-BY license)[https://creativecommons.org/licenses/by/4.0/]. If you are using KG2 in your work, we ask that you attribute credit to the KG2 team as follows: RTX KG2 development team, github.com/RTXteam. Our assertion of the CC-BY license covers only creative product our team (documentation, reports, and knowledge graph formatting); the actual content of the KG2 knowledge graph is encumbered by various licenses (e.g., UMLS) that prevent its redistribution.
We emphasize knowledge souces that
- Are available in a flat-file download (e.g., TSV, XML, JSON, DAT, or SQL dump)
- Are being maintained and updated periodically
- Provide content/knowledge that complements (does not duplicate) what is already in KG2.
- Connect concept identifiers that are already in KG2.
- Ideally, provide knowledge based on human curation (favored over computational text-mining).
- In the case where Snakemake is forcibly quit due to a loss of power or other reason, it may result in the code directory becoming locked. To resolve, run:
/home/ubuntu/kg2-venv/bin/snakemake --snakefile /home/ubuntu/kg2-code/build/Snakefile --unlock
Sometimes, when hosting KG2 in a Neo4j server on a new AWS instance, the initial password does not get set correctly, which will lead to an Authentication Error in tsv-to-neo4j.sh
. To fix this, do the following:
- Start up Neo4 (sudo service neo4j start)
- Wait one minute, then confirm Neo4j is running (sudo service neo4j status)
- Use a browser to connect to Neo4j via HTTP on port 7474. You should see a username/password authentication form.
- Fill in "neo4j" and "neo4j" for username and password, respectively, and submit the form. You should be immediately prompted to set a new password. At that time, type in our "usual" Neo4j password (you'll have to enter it twice).
- When you submit the form, Neo4j should be running and it should now have the correct password set.
Occasionally, when a database needs to be re-extracted, the error ERROR: role "jjyang" already exists
occurs.
If the following is not in the extraction script, add it to the line above where the role is created.
sudo -u postgres psql -c "DROP ROLE IF EXISTS ${role}"
This section has some guidelines for the development team for the KG2 build system.
- Hard tabs are not permitted in source files such as python or bash (use spaces).
- Only python3 is allowed.
- Please follow PEP8 formatting standards, except we allow line length to go to 160.
- Please use type hints wherever possible.
- Use lower-case for variable names except for environment variables.
- The flags
nounset
,pipefail
, anderrexit
should be set.
- For config files and shell scripts, use
kabob-case
- For python modules, use
snake_case
.
Thank you to the many people who have contributed to the development of RTX KG2:
Stephen Ramsey, E. C. Wood, Amy Glen, Lindsey Kvarfordt, Finn Womack, Liliana Acevedo, Veronica Flores, and Deqing Qu.
David Koslicki, Eric Deutsch, Yao Yao, Jared Roach, Chris Mungall, Tom Conlin, Matt Brush,
Chunlei Wu, Harold Solbrig, Will Byrd, Michael Patton, Jim Balhoff, Chunyu Ma, Chris Bizon,
Deepak Unni, Richard Bruskiewich, and Jeff Henrikson.
National Center for Advancing Translational Sciences (award number OT2TR002520).