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Manual
Kraken is a taxonomic sequence classifier that assigns taxonomic
labels to DNA sequences. Kraken examines the
The first version of Kraken used a large indexed and sorted list of
Kraken 2 differs from Kraken 1 in several important ways:
- Only minimizers of the
$k$ -mers in the query sequences are used as database queries. Similarly, only minimizers of the$k$ -mers in the reference sequences in the database's genomic library are stored in the database. We will also refer to the minimizers as$\ell$ -mers, where$\ell \leq k$ . All$k$ -mers are considered to have the same LCA as their minimizer's database LCA value. - Kraken 2 uses a compact hash table that is a probabilistic data structure. This means that occasionally, database queries will fail by either returning the wrong LCA, or by not resulting in a search failure when a queried minimizer was never actually stored in the database. By incurring the risk of these false positives in the data structure, Kraken 2 is able to achieve faster speeds and lower memory requirements. Users should be aware that database false positive errors occur in less than 1% of queries, and can be compensated for by use of confidence scoring thresholds.
- Kraken 2 has the ability to build a database from amino acid sequences and perform a translated search of the query sequences against that database.
- Kraken 2 utilizes spaced seeds in the storage and querying of minimizers to improve classification accuracy.
- Kraken 2 provides support for "special" databases that are not based on NCBI's taxonomy. These are currently limited to three popular 16S databases.
Because Kraken 2 only stores minimizers in its hash table, and
If you use Kraken 2 in your own work, please cite either the Kraken 2 paper and/or the original Kraken paper as appropriate. Thank you!
-
Disk space: Construction of a Kraken 2 standard database requires approximately 100 GB of disk space. A test on 01 Jan 2018 of the default installation showed 42 GB of disk space was used to store the genomic library files, 26 GB was used to store the taxonomy information from NCBI, and 29 GB was used to store the Kraken 2 compact hash table.
Like in Kraken 1, we strongly suggest against using NFS storage to store the Kraken 2 database if at all possible.
-
Memory: To run efficiently, Kraken 2 requires enough free memory to hold the database (primarily the hash table) in RAM. While this can be accomplished with a ramdisk, Kraken 2 will by default load the database into process-local RAM; the
--memory-mapping
switch tokraken2
will avoid doing so. The default database size is 29 GB (as of Jan. 2018), and you will need slightly more than that in RAM if you want to build the default database. -
Dependencies: Kraken 2 currently makes extensive use of Linux utilities such as sed, find, and wget. Many scripts are written using the Bash shell, and the main scripts are written using Perl. Core programs needed to build the database and run the classifier are written in C++11, and need to be compiled using a somewhat recent version of g++ that will support C++11. Multithreading is handled using OpenMP. Downloads of NCBI data are performed by wget and rsync. Most Linux systems will have all of the above listed programs and development libraries available either by default or via package download.
Unlike Kraken 1, Kraken 2 does not use an external
$k$ -mer counter. However, by default, Kraken 2 will attempt to use thedustmasker
orsegmasker
programs provided as part of NCBI's BLAST suite to mask low-complexity regions (see [Masking of Low-complexity Sequences]).MacOS NOTE: MacOS and other non-Linux operating systems are not explicitly supported by the developers, and MacOS users should refer to the Kraken-users group for support in installing the appropriate utilities to allow for full operation of Kraken 2. We will attempt to use MacOS-compliant code when possible, but development and testing time is at a premium and we cannot guarantee that Kraken 2 will install and work to its full potential on a default installation of MacOS.
In particular, we note that the default MacOS X installation of GCC does not have support for OpenMP. Without OpenMP, Kraken 2 is limited to single-threaded operation, resulting in slower build and classification runtimes.
-
Network connectivity: Kraken 2's standard database build and download commands expect unfettered FTP and rsync access to the NCBI FTP server. If you're working behind a proxy, you may need to set certain environment variables (such as
ftp_proxy
orRSYNC_PROXY
) in order to get these commands to work properly.Kraken 2's scripts default to using rsync for most downloads; however, you may find that your network situation prevents use of rsync. In such cases, you can try the
--use-ftp
option tokraken2-build
to force the downloads to occur via FTP. -
MiniKraken: At present, users with low-memory computing environments can replicate the "MiniKraken" functionality of Kraken 1 in two ways: first, by increasing the value of
$k$ with respect to$\ell$ (using the--kmer-len
and--minimizer-len
options tokraken2-build
); and secondly, through downsampling of minimizers (from both the database and query sequences) using a hash function. This second option is performed if the--max-db-size
option tokraken2-build
is used; however, the two options are not mutually exclusive. In a difference from Kraken 1, Kraken 2 does not require building a full database and then shrinking it to obtain a reduced database.
To begin using Kraken 2, you will first need to install it, and then either download or create a database.
Kraken 2 consists of two main scripts (kraken2
and kraken2-build
),
along with several programs and smaller scripts. As part of the installation
process, all scripts and programs are installed in the same directory.
After installation, you can move the main scripts elsewhere, but moving
the other scripts and programs requires editing the scripts and changing
the $KRAKEN2_DIR
variables in the main scripts.
Once an install directory is selected, you need to run the following command in the directory where you extracted the Kraken 2 source:
./install_kraken2.sh $KRAKEN2_DIR
(Replace $KRAKEN2_DIR
above with the directory where you want to install
Kraken 2's programs/scripts.)
The install_kraken2.sh
script should compile all of Kraken 2's code
and setup your Kraken 2 program directory. Installation is successful if
you see the message "Kraken 2 installation complete.
"
Once installation is complete, you may want to copy the main Kraken 2
scripts into a directory found in your PATH
variable (e.g., "$HOME/bin
"):
cp $KRAKEN2_DIR/kraken2{,-build,-inspect} $HOME/bin
After installation, you're ready to either create or download a database.
A Kraken 2 database is a directory containing at least 3 files:
-
hash.k2d
: Contains the minimizer to taxon mappings -
opts.k2d
: Contains information about the options used to build the database -
taxo.k2d
: Contains taxonomy information used to build the database
None of these three files are in a human-readable format. Other files may also be present as part of the database build process, and can, if desired, be removed after a successful build of the database.
In interacting with Kraken 2, you should not have to directly reference any of these files, but rather simply provide the name of the directory in which they are stored. Kraken 2 allows both the use of a standard database as well as custom databases; these are described in the sections [Standard Kraken 2 Database] and [Custom Databases] below, respectively.
To create the standard Kraken 2 database, you can use the following command:
kraken2-build --standard --db $DBNAME
(Replace "$DBNAME
" above with your preferred database name/location.
Please note that the database will use approximately 100 GB of
disk space during creation, with the majority of that being reference
sequences or taxonomy mapping information that can be removed after the
build.)
This will download NCBI taxonomic information, as well as the complete genomes in RefSeq for the bacterial, archaeal, and viral domains, along with the human genome and a collection of known vectors (UniVec_Core). After downloading all this data, the build process begins; this can be the most time-consuming step. If you have multiple processing cores, you can run this process with multiple threads, e.g.:
kraken2-build --standard --threads 24 --db $DBNAME
Using 32 threads on an AWS EC2 r4.8xlarge instance with 16 dual-core hyperthreaded 2.30 GHz CPUs and 244 GB of RAM, the build process took approximately 35 minutes in Jan. 2018.
The build process itself has two main steps, each of which requires passing over the contents of the reference library:
-
Estimation of the capacity needed in the Kraken 2 compact hash table.
This uses a low-memory method to reliably estimate the number of
minimizers present in the reference library given the selected parameters
$k$ and$\ell$ . - Population of the hash table (and conversion of the taxonomy to an internal format). This step is a second pass over the reference library to find minimizers and then place them in the database.
(There is one other preliminary step where sequence IDs are mapped to taxonomy IDs, but this is usually a rather quick process and is mostly handled during library downloading.)
Unlike Kraken 1's build process, Kraken 2 does not perform checkpointing
after the estimation step. This is because the estimation step is dependent
on the selected
To classify a set of sequences, use the kraken2
command:
kraken2 --db $DBNAME seqs.fa
Output will be sent to standard output by default. The files
containing the sequences to be classified should be specified
on the command line. Sequences can also be provided through
standard input using the special filename /dev/fd/0
.
The kraken2
program allows several different options:
-
Multithreading: Use the
--threads NUM
switch to use multiple threads. -
Quick operation: Rather than searching all
$\ell$ -mers in a sequence, stop classification after the first database hit; use--quick
to enable this mode. -
Hit group threshold: The option
--minimum-hit-groups
will allow you to require multiple hit groups (a group of overlapping k-mers that share a common minimizer that is found in the hash table) be found before declaring a sequence classified, which can be especially useful with custom databases when testing to see if sequences either do or do not belong to a particular genome. -
Sequence filtering: Classified or unclassified sequences can be sent to a file for later processing, using the
--classified-out
and--unclassified-out
switches, respectively. -
Output redirection: Output can be directed using standard shell redirection (
|
or>
), or using the--output
switch. -
Compressed input: Kraken 2 can handle gzip and bzip2 compressed files as input by specifying the proper switch of
--gzip-compressed
or--bzip2-compressed
. -
Input format auto-detection: If regular files (i.e., not pipes or device files) are specified on the command line as input, Kraken 2 will attempt to determine the format of your input prior to classification. You can disable this by explicitly specifying
--gzip-compressed
or--bzip2-compressed
as appropriate. Note that use of the character device file/dev/fd/0
to read from standard input (akastdin
) will not allow auto-detection. -
Paired reads: Kraken 2 provides an enhancement over Kraken 1 in its handling of paired read data. Rather than needing to concatenate the pairs together with an
N
character between the reads, Kraken 2 is able to process the mates individually while still recognizing the pairing information. Using the--paired
option tokraken2
will indicate tokraken2
that the input files provided are paired read data, and data will be read from the pairs of files concurrently.Usage of
--paired
also affects the--classified-out
and--unclassified-out
options; users should provide a#
character in the filenames provided to those options, which will be replaced bykraken2
with "_1
" and "_2
" with mates spread across the two files appropriately. For example:kraken2 --paired --classified-out cseqs#.fq seqs_1.fq seqs_2.fq
will put the first reads from classified pairs in
cseqs_1.fq
, and the second reads from those pairs incseqs_2.fq
.
To get a full list of options, use kraken2 --help
.
Each sequence (or sequence pair, in the case of paired reads) classified by Kraken 2 results in a single line of output. Kraken 2's output lines contain five tab-delimited fields; from left to right, they are:
-
"C"/"U": a one letter code indicating that the sequence was either classified or unclassified.
-
The sequence ID, obtained from the FASTA/FASTQ header.
-
The taxonomy ID Kraken 2 used to label the sequence; this is 0 if the sequence is unclassified.
-
The length of the sequence in bp. In the case of paired read data, this will be a string containing the lengths of the two sequences in bp, separated by a pipe character, e.g. "98|94".
-
A space-delimited list indicating the LCA mapping of each
$k$ -mer in the sequence(s). For example, "562:13 561:4 A:31 0:1 562:3" would indicate that:- the first 13
$k$ -mers mapped to taxonomy ID #562 - the next 4
$k$ -mers mapped to taxonomy ID #561 - the next 31
$k$ -mers contained an ambiguous nucleotide - the next
$k$ -mer was not in the database - the last 3
$k$ -mers mapped to taxonomy ID #562
Note that paired read data will contain a "
|:|
" token in this list to indicate the end of one read and the beginning of another.When Kraken 2 is run against a protein database (see [Translated Search]), the LCA hitlist will contain the results of querying all six frames of each sequence. Reading frame data is separated by a "
-:-
" token. - the first 13
Kraken 1 offered a kraken-translate
and kraken-report
script to change
the output into different formats. Through the use of kraken2 --use-names
,
Kraken 2 will replace the taxonomy ID column with the scientific name and
the taxonomy ID in parenthesis (e.g., "Bacteria (taxid 2)" instead of "2"),
yielding similar functionality to Kraken 1's kraken-translate
script.
The sample report functionality now exists as part of the kraken2
script,
with the use of the --report
option; the sample report formats are
described below.
Like Kraken 1, Kraken 2 offers two formats of sample-wide results. Kraken 2's standard sample report format is tab-delimited with one line per taxon. The fields of the output, from left-to-right, are as follows:
- Percentage of fragments covered by the clade rooted at this taxon
- Number of fragments covered by the clade rooted at this taxon
- Number of fragments assigned directly to this taxon
- A rank code, indicating (U)nclassified, (R)oot, (D)omain, (K)ingdom, (P)hylum, (C)lass, (O)rder, (F)amily, (G)enus, or (S)pecies. Taxa that are not at any of these 10 ranks have a rank code that is formed by using the rank code of the closest ancestor rank with a number indicating the distance from that rank. E.g., "G2" is a rank code indicating a taxon is between genus and species and the grandparent taxon is at the genus rank.
- NCBI taxonomic ID number
- Indented scientific name
The scientific names are indented using space, according to the tree structure specified by the taxonomy.
By default, taxa with no reads assigned to (or under) them will not have
any output produced. However, if you wish to have all taxa displayed, you
can use the --report-zero-counts
switch to do so. This can be useful if
you are looking to do further downstream analysis of the reports, and want
to compare samples. Sorting by the taxonomy ID (using sort -k5,5n
) can
provide a consistent line ordering between reports.
In addition, we also provide the option --use-mpa-style
that can be used
in conjunction with --report
. This option provides output in a format
similar to MetaPhlAn's output. The output with this option provides one
taxon per line, with a lowercase version of the rank codes in Kraken 2's
standard sample report format (except for 'U' and 'R'), two underscores,
and the scientific name of the taxon (e.g., "d__Viruses"). The full
taxonomy of each taxon (at the eight ranks considered) is given, with each
rank's name separated by a pipe character (e.g., "d__Viruses|o_Caudovirales").
Following this version of the taxon's scientific name is a tab and the
number of fragments assigned to the clade rooted at that taxon.
Kraken 2 allows users to perform a six-frame translated search, similar to the well-known BLASTX program. To do this, Kraken 2 uses a reduced 15 amino acid alphabet and stores amino acid minimizers in its database. LCA results from all 6 frames are combined to yield a set of LCA hits, which is then resolved in the same manner as in Kraken's normal operation.
To build a protein database, the --protein
option should be given to
kraken2-build
(either along with --standard
, or with all steps if
building a custom database).
We realize the standard database may not suit everyone's needs. Kraken 2 also allows creation of customized databases.
To build a custom database:
-
Install a taxonomy. Usually, you will just use the NCBI taxonomy, which you can easily download using:
kraken2-build --download-taxonomy --db $DBNAME
This will download the accession number to taxon maps, as well as the taxonomic name and tree information from NCBI. These files can be found in
$DBNAME/taxonomy/
. If you need to modify the taxonomy, edits can be made to thenames.dmp
andnodes.dmp
files in this directory; you may also need to modify the*.accession2taxid
files appropriately.Some of the standard sets of genomic libraries have taxonomic information associated with them, and don't need the accession number to taxon maps to build the database successfully. These libraries include all those available through the
--download-library
option (see next point), except for theplasmid
and non-redundant databases. If you are not using custom sequences (see the--add-to-library
option) and are not using one of theplasmid
or non-redundant database libraries, you may want to skip downloading of the accession number to taxon maps. This can be done by passing--skip-maps
to thekraken2-build --download-taxonomy
command. -
Install one or more reference libraries. Several sets of standard genomes/proteins are made easily available through
kraken2-build
:-
archaea
: RefSeq complete archaeal genomes/proteins -
bacteria
: RefSeq complete bacterial genomes/proteins -
plasmid
: RefSeq plasmid nucleotide/protein sequences -
viral
: RefSeq complete viral genomes/proteins -
human
: GRCh38 human genome/proteins -
fungi
: RefSeq complete fungal genomes/proteins -
plant
: RefSeq complete plant genomes/proteins -
protozoa
: RefSeq complete protozoan genomes/proteins -
nr
: NCBI non-redundant protein database -
nt
: NCBI non-redundant nucleotide database -
env_nr
: NCBI non-redundant protein database with sequences from large environmental sequencing projects -
env_nt
: NCBI non-redundant nucleotide database with sequences from large environmental sequencing projects -
UniVec
: NCBI-supplied database of vector, adapter, linker, and primer sequences that may be contaminating sequencing projects and/or assemblies -
UniVec_Core
: A subset of UniVec chosen to minimize false positive hits to the vector database
To download and install any one of these, use the
--download-library
switch, e.g.:kraken2-build --download-library bacteria --db $DBNAME
Multiple libraries can be downloaded into a database prior to building by issuing multiple
kraken2-build --download-library
commands, e.g.:kraken2-build --download-library archaea --db $DBNAME kraken2-build --download-library viral --db $DBNAME
The above commands would prepare a database that would contain archaeal and viral genomes; the
--build
option (see below) will still need to be used after downloading these libraries to actually build the database, however.(Note that downloading
nr
orenv_nr
require use of the--protein
option, and thatUniVec
andUniVec_Core
are incompatible with the--protein
option.)Other genomes can also be added, but such genomes must meet certain requirements:
- Sequences must be in a FASTA file (multi-FASTA is allowed)
- Each sequence's ID (the string between the
>
and the first whitespace character on the header line) must contain either an NCBI accession number to allow Kraken 2 to lookup the correct taxa, or an explicit assignment of the taxonomy ID usingkraken:taxid
(see below).
Sequences not downloaded from NCBI may need their taxonomy information assigned explicitly. This can be done using the string
kraken:taxid|XXX
in the sequence ID, withXXX
replaced by the desired taxon ID. For example, to put a known adapter sequence in taxon 32630 ("synthetic construct"), you could use the following:>sequence16|kraken:taxid|32630 Adapter sequence CAAGCAGAAGACGGCATACGAGATCTTCGAGTGACTGGAGTTCCTTGGCACCCGAGAATTCCA
The
kraken:taxid
string must begin the sequence ID or be immediately preceded by a pipe character (|
). Explicit assignment of taxonomy IDs in this manner will override the accession number mapping provided by NCBI.If your genomes meet the requirements above, then you can add each sequence to your database's genomic library using the
--add-to-library
switch, e.g.:kraken2-build --add-to-library chr1.fa --db $DBNAME kraken2-build --add-to-library chr2.fa --db $DBNAME
Note that if you have a list of files to add, you can do something like this in
bash
:for file in chr*.fa do kraken2-build --add-to-library $file --db $DBNAME done
Or even add all
*.fa
files found in the directorygenomes
:find genomes/ -name '*.fa' -print0 | xargs -0 -I{} -n1 kraken2-build --add-to-library {} --db $DBNAME
(You may also find the
-P
option toxargs
useful to add many files in parallel if you have multiple processors.) -
-
Once your library is finalized, you need to build the database. This can be done with the command:
kraken2-build --build --db $DBNAME
The
--threads
option is also helpful here to reduce build time.By default, the values of
$k$ and$\ell$ are 35 and 31, respectively (or 15 and 12 for protein databases). These values can be explicitly set with the--kmer-len
andminimizer-len
options, however. Note that the minimizer length must be no more than 31 for nucleotide databases, and 15 for protein databases. Additionally, the minimizer length$\ell$ must be no more than the$k$ -mer length. There is no upper bound on the value of$k$ , but sequences less than$k$ bp in length cannot be classified.Kraken 2 also utilizes a simple spaced seed approach to increase accuracy. A number
$s$ <$\ell$ /4 can be chosen, and$s$ positions in the minimizer will be masked out during all comparisons. Masked positions are chosen to alternate from the second-to-last position in the minimizer; e.g.,$s$ = 5 and$\ell$ = 31 will result in masking out the 0 positions shown here:111 1111 1111 1111 1111 1101 0101 0101
By default,
$s$ = 7 for nucleotide databases, and$s$ = 0 for protein databases. This can be changed using the--minimizer-spaces
option along with the--build
task ofkraken2-build
.
A full list of options for kraken2-build
can be obtained using
kraken2-build --help
.
After building a database, if you want to reduce the disk usage of
the database, you can use the --clean
option for kraken2-build
to remove intermediate files from the database directory.
Low-complexity sequences, e.g. "ACACACACACACACACACACACACAC", are known to occur in many different organisms and are typically less informative for use in alignments; the BLAST programs often mask these sequences by default. Using this masking can help prevent false positives in Kraken 2's results, and so we have added this functionality as a default option to Kraken 2's library download/addition process.
Kraken 2 uses two programs to perform low-complexity sequence masking,
both available from NCBI: dustmasker
, for nucleotide sequences, and
segmasker
, for amino acid sequences. These programs are available
as part of the NCBI BLAST+ suite. If these programs are not installed
on the local system and in the user's PATH when trying to use
kraken2-build
, the database build will fail. Users who do not wish to
install these programs can use the --no-masking
option to kraken2-build
in conjunction with any of the --download-library
, --add-to-library
, or
--standard
options; use of the --no-masking
option will skip masking of
low-complexity sequences during the build of the Kraken 2 database.
To support some common use cases, we provide the ability to build Kraken 2 databases using data from various external databases. These external databases may not follow the NCBI taxonomy, and so we've provided mechanisms to automatically create a taxonomy that will work with Kraken 2 (although such taxonomies may not be identical to NCBI's).
To build one of these "special" Kraken 2 databases, use the following command:
kraken2-build --db $DBNAME --special TYPE
where the TYPE
string is one of the database names listed below.
At present, the "special" Kraken 2 database support we provide is limited to pre-packaged solutions for some public 16S sequence databases, but this may grow in the future.
For targeted 16S sequencing projects, a normal Kraken 2 database using whole genome data may use more resources than necessary. A Kraken 2 database created from a well-curated genomic library of just 16S data can provide both a more efficient solution as well as a more accurate set of predictions for such projects. We provide support for building Kraken 2 databases from three publicly available 16S databases:
-
Greengenes (Kraken 2 database name:
greengenes
), using all available 16S data. -
RDP (Kraken 2 database name:
rdp
), using the bacterial and archaeal 16S data. -
SILVA (Kraken 2 database name:
silva
), using the Small subunit NR99 sequence set.
Note that these databases may have licensing restrictions regarding their data,
and it is your responsibility to ensure you are in compliance with those
restrictions; please visit the databases' websites for further details. The
kraken2-build
script only uses publicly available URLs to download data and
then converts that data into a form compatible for use with Kraken 2.
Furthermore, if you use one of these databases in your research, please visit the corresponding database's website to determine the appropriate and up-to-date citation.
At present, we have not yet developed a confidence score with a
probabilistic interpretation for Kraken 2. However, we have developed a
simple scoring scheme that has yielded good results for us, and we've
made that available in Kraken 2 through use of the --confidence
option
to kraken2
. The approach we use allows a user to specify a threshold
score in the [0,1] interval; the classifier then will adjust labels up
the tree until the label's score (described below) meets or exceeds that
threshold. If a label at the root of the taxonomic tree would not have
a score exceeding the threshold, the sequence is called unclassified by
Kraken 2 when this threshold is applied.
A sequence label's score is a fraction
"562:13 561:4 A:31 0:1 562:3" would indicate that:
- the first 13
$k$ -mers mapped to taxonomy ID #562 - the next 4
$k$ -mers mapped to taxonomy ID #561 - the next 31
$k$ -mers contained an ambiguous nucleotide - the next
$k$ -mer was not in the database - the last 3
$k$ -mers mapped to taxonomy ID #562
In this case, ID #561 is the parent node of #562. Here, a label of #562
for this sequence would have a score of --confidence
threshold over 16/21, the classifier
would adjust the original label from #562 to #561; if the threshold was
greater than 20/21, the sequence would become unclassified.
The kraken2-inspect
script allows users to gain information about the content
of a Kraken 2 database. The output format of kraken2-inspect
is identical to the reports generated with the --report
option to kraken2
.
Instead of reporting how many reads in input data classified to a given taxon
or clade, as kraken2
's --report
option would, the kraken2-inspect
script
will report the number of minimizers in the database that are mapped to the
various taxa/clades. For example, the first five lines of kraken2-inspect
's
output on an example database might look like this:
$ kraken2-inspect --db EXAMPLE_DB | head -5
100.00% 1770368409 1581179 R 1 root
96.50% 1708407622 58003 R1 131567 cellular organisms
91.28% 1615910070 985309 D 2 Bacteria
43.89% 777062062 1312736 P 1224 Proteobacteria
18.62% 329590216 555667 C 1236 Gammaproteobacteria
This output indicates that 555667 of the minimizers in the database map
directly to the Gammaproteobacteria class (taxid #1236), and 329590216 (18.62%)
of the database's minimizers map to a taxon in the clade rooted at
Gammaproteobacteria. For more information on kraken2-inspect
's options,
use its --help
option.
The kraken2
and kraken2-inpsect
scripts supports the use of some
environment variables to help in reducing command line lengths:
-
KRAKEN2_NUM_THREADS
: if the--threads
option is not supplied tokraken2
, then the value of this variable (if it is set) will be used as the number of threads to runkraken2
. (This variable does not affectkraken2-inspect
.) -
KRAKEN2_DB_PATH
: much like thePATH
variable is used for executables by your shell,KRAKEN2_DB_PATH
is a colon-separated list of directories that will be searched for the database you name if the named database does not have a slash (/
) character. By default, Kraken 2 assumes the value of this variable is ".
" (i.e., the current working directory). This variable can be used to create one (or more) central repositories of Kraken databases in a multi-user system. Example usage in bash:export KRAKEN2_DB_PATH="/home/user/my_kraken2_dbs:/data/kraken2_dbs:"
This will cause three directories to be searched, in this order:
/home/user/my_kraken2_dbs
/data/kraken2_dbs
- the current working directory (caused by the empty string as
the third colon-separated field in the
KRAKEN2_DB_PATH
string)
The search for a database will stop when a name match is found; if two directories in the
KRAKEN2_DB_PATH
have databases with the same name, the directory of the two that is searched first will have its database selected.If the above variable and value are used, and the databases
/data/kraken2_dbs/mainDB
and./mainDB
are present, thenkraken2 --db mainDB sequences.fa
will classify
sequences.fa
using/data/kraken_dbs/mainDB
; if instead you wanted to use themainDB
present in the current directory, you would need to specify a directory path to that database in order to circumvent searching, e.g.:kraken2 --db ./mainDB sequences.fa
Note that the
KRAKEN2_DB_PATH
directory list can be skipped by the use of any absolute (beginning with/
) or relative pathname (including at least one/
) as the database name. -
KRAKEN2_DEFAULT_DB
: if no database is supplied with the--db
option, the database named in this variable will be used instead. Using this variable, you can avoid using--db
if you only have a single database that you usually use, e.g. in bash:export KRAKEN2_DEFAULT_DB="/home/user/kraken2db" kraken2 sequences.fa > kraken2.output
This will classify
sequences.fa
using the/home/user/kraken2db
database.Note that the value of
KRAKEN2_DEFAULT_DB
will also be interpreted in the context of the value ofKRAKEN2_DB_PATH
if you don't setKRAKEN2_DEFAULT_DB
to an absolute or relative pathname. Given the earlier example in this section, the following:export KRAKEN2_DEFAULT_DB="mainDB" kraken2 sequences.fa
will use
/data/kraken_dbs/mainDB
to classifysequences.fa
.