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a simple python script for "grafting" on novel sequences to a custom Kraken2 database

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KrakenGrafter

a simple python3 script for "grafting" on novel sequences to a custom Kraken2 database

the purpose of this script is to append on the contents of a .fasta file to the nodes.dmp and names.dmp used by Kraken2 - in effect "grafting" on a new branch to the tree of life inside the nodes.dmp and names.dmp files. this allows the user to then use the kraken2-build --add-to-library functionality during database building thereby making sure their own custom sequences are included

this is an extension to simply using kraken2-build --add-to-library because it allows the user to create new nodes that did not previously exist in the taxonomic system - see kraken2's custom database section.

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two example usecases:

  • say you've identified a new set of members of a genus and want to count their prevalance in sequencing datasets - they are hitherto unknown to the NCBI, and so wont have their own nodes in the taxonomy - you'd use the "A)" approach here
  • say you've indetified a completely new set of sequences - not only does the NCBI doesn't have a node, but maybe they don't even fit the tree of life! - you could append these sequences to "synthetic construct" under a new genus-species pair - you'd use the "B)" approach here
  • more detail in the tutorial

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installation

download the KrakenGrafter.py file and place it somewhere in your PATH - make sure you are using python3 with argparse installed

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the script takes in three input files:

  • nodes.dmp to modify
  • names.dmp to modify
  • .fasta of sequences to graft

NOTE: the seqIDs need to contain no whitespace and no pipe characters ("|")

the entire seqID will be grafted into the nodes.dmp and names.dmp files so maybe keep it concise

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the script then generates three output files:

  • new_nodes.dmp (or specified name) of the modified nodes.dmp
  • new_names.dmp (or specified name) of the modified names.dmp
  • K2.fasta (or specified name) of the modified .fasta file

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the script can be used in two different ways - in both cases, brand new taxon IDs are generated that have not been seen in the nodes.dmp and names.dmp files:

A) a given .fasta file's sequence(s) is/are inserted directly beneath (taxonomically speaking) a specified "root" node

example:

python KrakenGrafter.py -i_nodes nodes.dmp -i_names names.dmp -i_fasta input.fasta -root 32630

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B) the user declares a brand new "parent" node that is inserted beneath the "root" node (at a user-specified taxonomic depth) and then the given .fasta sequence(s) is/are inserted directly beneath this new "parent" node this functionality is enabled by declaring both -parent_taxon and -parent_rank

example:

python KrakenGrafter.py -i_nodes nodes.dmp -i_names names.dmp -i_fasta input.fasta -root 32630 -parent_taxon new_genus -parent_rank genus

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NOTE: i_nodes, i_names, root, o_nodes, o_names, o_fasta, and debug are all optional variables to declare.

the default "root" node is 32630 - which is the NCBI's "synthetic construct" node - a safe habour for new sequences.

To find a more specific node, one can either go on the NCBI taxonomy browser or use grep 'taxon_string' names.dmp to try and work out what taxon ID to use for "root"

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tutorial

regardless of how you use KrakenGrafter.py, you need to start the same way by downloading the NCBI taxonomy:

  1. kraken2-build --download-taxonomy --db $DB_name

    then, optionally, you can download any number of the prexisting kraken2 databases e.g.:

    kraken2-build --download-library viral --db $DB_name

    kraken2-build --download-library plant --db $DB_name

    if you are having issues with the FTP path when running kraken2-build --download-library then this is a likely fix (in rsync_from_ncbi.pl replace if (! ($full_path =~ s#^ftp://${qm_server}${qm_server_path}/##)) { with if (! ($full_path =~ s#^https://${qm_server}${qm_server_path}/##)) {)

  2. now that you have the databases of interest (please see this bioRxiv for an assessment of how to choose your database and classification settings), navigate to:

    cd $DB_name/taxonomy

    here you will find the nodes.dmp and names.dmp files needed for KrakenGrafter.py

    I suggest you copy and re-name these original nodes.dmp and names.dmp files and keep them in $DB_name/taxonomy - that way you can just revert their names and use them as intended if something goes wrong.

  3. you also need to identify the taxon ID (taxID) under which the grafting will be performed, e.g.:

    grep 'Enterobacterales' names.dmp (the first column will contain the taxID - an integer - be sure to manually inspect)

  4. lastly in the prep, you need to have ready a .fasta file. The file can contain any number of sequences, the only thing to look out for are the seqIDs (the ">" names of the sequences) - your .fasta file seqIDs need to have no whitespaces (space / tab) and no pipe characters ("|")

    your .fasta file must contain sequences that will all be insterted under the same taxonomic node - e.g. if you want to graft on both say a new bacterium and a new protist, you would run KrakenGrafter.py twice, once for the bacterium and once for the protist (any order) - each with their own .fasta file - but the input nodes.dmp and names.dmp files of the second 'round' of KrakenGrafter.py will be the output from the first

  5. I'd now take your copies of the nodes.dmp and names.dmp files and your .fasta file(s) and put them in the same directory (this isn't necessary but I find it easier than writing out long paths)

A) grafting on new sets of sequences to pre-existing nodes

let's say I want to graft on species1.fasta under genus_taxID and genus2.fasta under family_taxID - this would be done in two steps:

  1. python KrakenGrafter.py -i_nodes nodes.dmp -i_names names.dmp -i_fasta species1.fasta -root genus_taxID -o_nodes nodes.dmp -o_names names.dmp -o_fasta K2_species1.fasta

    this overwrites the input nodes.dmp and names.dmp files

  2. python KrakenGrafter.py -i_nodes nodes.dmp -i_names names.dmp -i_fasta genus2.fasta -root family_taxID -o_nodes nodes.dmp -o_names names.dmp -o_fasta K2_genus2.fasta

    note how in this set-up, the output nodes.dmp and names.dmp files of 1) are used in 2) - that way all the sequences are added to same nodes.dmp and names.dmp files

  3. now make sure to move the edited nodes.dmp and names.dmp files (with those exact names) back to $DB_name/taxonomy

  4. now we need to use the in-built features of Kraken2 to actually add these sequences to the database (we can do this in one step by catting the KrakenGrafter.py output .fasta files) and build the database:

    cat K2_species1.fasta K2_genus2.fasta > K2_seqs_to_graft.fasta

    kraken2-build --add-to-library K2_seqs_to_graft.fasta --db $DB_name

    kraken2-build --build --db $DB_name --threads 32

B) grafting on new sets of sequences to new nodes

let's say I want to graft on species3.fasta to a new node under a given family_taxID in a new genus (named new_genus) - in addition to the setup above, you will also need to decide on a name for the new parent taxon (e.g. new_genus) as well as a taxonomic rank for this taxon (in this case genus). The 'root' under which this parent taxon is inserted can be any taxonomic depth above the parent taxon (e.g. you could instert a new bacterial species in simply the bacterial kingtom taxID as the 'root' - 2 - but then create a brand new genus - new_genus). Because the new parent taxon (in this case new_genus) doesn't yet exist in the taxomony, a new taxID will be automatically generated for it as well as for the actual sequences being added below it:

  1. python KrakenGrafter.py -i_nodes nodes.dmp -i_names names.dmp -i_fasta species3.fasta -root family_taxID -parent_taxon new_genus -parent_rank genus -o_nodes nodes.dmp -o_names names.dmp -o_fasta K2_species3.fasta

  2. now make sure to move the edited nodes.dmp and names.dmp files (with those exact names) back to $DB_name/taxonomy

  3. now we need to use the in-built features of Kraken2 to actually add these sequences to the database and build the database:

kraken2-build --add-to-library K2_species3.fasta --db $DB_name

kraken2-build --build --db $DB_name --threads 32

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written by INZ - 04/21/22, Stanford Unversity, provided with no acceptance of liability or promise of functionality, version 0.1.0

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a simple python script for "grafting" on novel sequences to a custom Kraken2 database

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