Difference between revisions of "Pfam"
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− | For the PDB information to be useful to Pfam we need to map between PDB residues and UniProt sequence residues. This is not a trivial task! This mapping information is provided by the MSD database. See here for more details. The <code>msd_data</code> table contains this residue by residue mapping. | + | For the PDB information to be useful to Pfam we need to map between PDB residues and UniProt sequence residues. This is not a trivial task! This mapping information is provided by the MSD database. See [http://www.ebi.ac.uk/msd-srv/docs/sifts/ here] for more details. The <code>msd_data</code> table contains this residue by residue mapping. |
The following statement gets the first 10 residue mappings for the structure <code>2ABL</code>. | The following statement gets the first 10 residue mappings for the structure <code>2ABL</code>. | ||
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==See also== | ==See also== | ||
*[http://www.ebi.ac.uk/integr8/EBI-Integr8-HomePage.do Integr8] — Access to complete genomes and proteomes | *[http://www.ebi.ac.uk/integr8/EBI-Integr8-HomePage.do Integr8] — Access to complete genomes and proteomes | ||
− | *[[TrEMBL]] Database performing an automated protein sequence annotation | + | *[[TrEMBL]] — Database performing an automated protein sequence annotation |
− | *[[InterPro]] Integration of protein domain and protein family databases | + | *[[InterPro]] — Integration of protein domain and protein family databases |
==References== | ==References== |
Latest revision as of 08:23, 8 September 2007
The Pfam database contains information about protein domains and families. Pfam-A is the manually curated portion of the database that contains over 8,000 entries. For each entry a protein sequence alignment and a hidden Markov model is stored. These hidden Markov models can be used to search sequence databases with the HMMer package written by Sean Eddy. Because the entries in Pfam-A do not cover all known proteins an automatically generated supplement is provided called Pfam-B. Pfam-B is derived from the PRODOM database.
The database iPfam builds on the domain description of Pfam. It investigates if different proteins described together in the protein structure database PDB are close enough to potentially interact.
Pfam MySQL database documentation
Note: This is taken directly from the Pfam website. It is archived here in case they take it offline.
See: Installation documentation here: MySQL.
Database structure
The table structures are in the '.sql
' files found in .sql files.
Table data
The table data is in the form: "THE_TABLE_NAME".sql.gz
(i.e., pfamA table data is in pfamA.sql.gz
)
The files can be downloaded from ftp://ftp.sanger.ac.uk/pub/databases/Pfam/database_files/
- Upload files
- gunzip files
- Load into MySQL using:
mysql> load data infile 'FULL_PATH_DIR/pfamA.sql' into table pfamA;
Table queries
Query domains by architecture and protein ID/ACC
- View proteins by Architecture
QUERY: Give me all the architectures and protein sequences for B12-binding family.
The architecture information is in 3 tables:
architecture pfamA_architecture pfamseq_architecture
SELECT architecture, pfamseq_id FROM pfamA,architecture, pfamA_architecture, pfamseq_architecture, pfamseq WHERE pfamA_id = "B12-binding" AND pfamA.auto_pfamA = pfamA_architecture.auto_pfamA AND pfamA_architecture.auto_architecture = architecture.auto_architecture AND architecture.auto_architecture = pfamseq_architecture.auto_architecture AND pfamseq_architecture.auto_pfamseq = pfamseq.auto_pfamseq;
- View proteins by protein id/accession
QUERY: Give me all the domains for protein "PLCG1_BOVIN
"
SEED ALIGNMENT:
SELECT pfamA_acc, pfamA_id, seq_start, seq_end FROM pfamseq, pfamA, pfamA_reg_seed WHERE pfamseq_id = "pig1_bovin" AND pfamseq.auto_pfamseq = pfamA_reg_seed.auto_pfamseq AND pfamA_reg_seed.auto_pfamA = pfamA.auto_pfamA; +-----------+----------+-----------+---------+ | pfamA_acc | pfamA_id | seq_start | seq_end | +-----------+----------+-----------+---------+ | PF00168 | C2 | 1090 | 1177 | | PF00388 | PI-PLC-X | 321 | 465 | | PF00018 | SH3_1 | 794 | 849 | +-----------+----------+-----------+---------+ 3 rows in set (0.03 sec)
FULL ALIGNMENT: This table is different from pfamA_reg_seed
as it has the "in_full
" column. You have to set the in_full = "1"
if you want ONLY the domains that are in the full alignment and are significant. Otherwise it will include the insignificant matches and return thousands of rows!
SELECT pfamA_acc, pfamA_id, seq_start, seq_end FROM pfamseq, pfamA, pfamA_reg_full WHERE pfamseq_id = "PLCG1_BOVIN" AND pfamseq.auto_pfamseq = pfamA_reg_full.auto_pfamseq AND pfamA_reg_full.auto_pfamA = pfamA.auto_pfamA AND in_full = "1"; +-----------+----------+-----------+---------+ | pfamA_acc | pfamA_id | seq_start | seq_end | +-----------+----------+-----------+---------+ | PF00168 | C2 | 1090 | 1177 | | PF00017 | SH2 | 550 | 639 | | PF00017 | SH2 | 668 | 741 | | PF00388 | PI-PLC-X | 321 | 465 | | PF00018 | SH3_1 | 794 | 849 | | PF00169 | PH | 33 | 142 | | PF00387 | PI-PLC-Y | 952 | 1070 | +-----------+----------+-----------+---------+ 7 rows in set (0.00 sec)
- View other regions by protein id/accession
pfam-B regions
SELECT distinct seq_start, seq_end, pfamB.pfamB_acc, pfamB_id FROM pfamB_reg, pfamB, pfamseq WHERE pfamseq_id = 'PLCG1_BOVIN' AND pfamB_reg.auto_pfamseq = pfamseq.auto_pfamseq AND pfamB_reg.auto_pfamB = pfamB.auto_pfamB;
- Other regions - transmembrane, signal-peptide, coiled-coils, and low-complexity
SELECT seq_start, seq_end, type_id, source_id, score FROM other_reg, pfamseq WHERE pfamseq.pfamseq_id = 'PLCG1_BOVIN' AND other_reg.auto_pfamseq = pfamseq.auto_pfamseq;
- Context regions
SELECT seq_start, seq_end, domain_score, pfamA.pfamA_acc, pfamA_id, pfamA.description FROM context_pfam_regions, pfamseq, pfamA WHERE pfamseq.pfamseq_id = 'PLCG1_BOVIN' AND context_pfam_regions.auto_pfamseq = pfamseq.auto_pfamseq AND pfamA.auto_pfamA = context_pfam_regions.auto_pfamA;
- Smart regions
SELECT seq_start, seq_end, smart_id; FROM smart_regions, pfamseq, smart WHERE pfamseq.pfamseq_id = 'PLCG1_BOVIN' AND smart_regions.auto_pfamseq = pfamseq.auto_pfamseq AND smart.auto_smart = smart_regions.auto_smart;
Query domain by family ID/ACC
- All domains for a family (FULL alignment)
SELECT pfamseq_id, seq_start, seq_end, pfamA_id FROM pfamA, pfamseq, pfamA_reg_full WHERE pfamA_id = "B12D" AND pfamA.auto_pfamA = pfamA_reg_full.auto_pfamA AND pfamA_reg_full.auto_pfamseq = pfamseq.auto_pfamseq AND in_full = "1"; +------------+-----------+---------+----------+ | pfamseq_id | seq_start | seq_end | pfamA_id | +------------+-----------+---------+----------+ | Q42338 | 2 | 88 | B12D | | Q9LJ47 | 1 | 87 | B12D | | Q9XHD5 | 3 | 89 | B12D | | O22414 | 3 | 89 | B12D | | Q940E1 | 29 | 116 | B12D | | Q40019 | 2 | 87 | B12D | | Q84MX3 | 87 | 173 | B12D | +------------+-----------+---------+----------+ 7 rows in set (0.02 sec)
- All domains for a family (SEED alignment)
SELECT pfamseq_id, seq_start, seq_end, pfamA_id FROM pfamA, pfamseq, pfamA_reg_seed WHERE pfamA_id = "B12D" AND pfamA.auto_pfamA = pfamA_reg_seed.auto_pfamA AND pfamA_reg_seed.auto_pfamseq = pfamseq.auto_pfamseq; +------------+-----------+---------+----------+ | pfamseq_id | seq_start | seq_end | pfamA_id | +------------+-----------+---------+----------+ | Q42338 | 2 | 88 | B12D | | O22414 | 3 | 89 | B12D | | Q9XHD5 | 3 | 89 | B12D | | Q940E1 | 29 | 116 | B12D | | Q9LJ47 | 1 | 87 | B12D | +------------+-----------+---------+----------+ 5 rows in set (0.00 sec)
Annotation: Information displayed on family page
- Pfam annotation
SELECT * FROM pfamA, pfamA_web WHERE pfamA_id = "CBS" AND pfamA.auto_pfamA = pfamA_web.auto_pfamA;
- Interpro annotation
SELECT interpro_id, abstract FROM interpro AS i, pfamA AS p WHERE p.auto_pfamA = i.auto_pfamA AND pfamA_id = "CBS";
- Gene Ontology (GO) annotation
SELECT go_id, term, category FROM gene_ontology AS go, pfamA AS p WHERE go.auto_pfamA = p.auto_pfamA AND pfamA_acc = "PF00067";
- Literature references
SELECT pfamA_literature_references.comment, order_added, medline, title, literature_references.author, journal FROM pfamA, pfamA_literature_references, literature_references WHERE pfamA_id = "CBS" AND pfamA.auto_pfamA = pfamA_literature_references.auto_pfamA AND pfamA_literature_references.auto_lit = literature_references.auto_lit;
- Database References
SELECT db_id, pfamA_database_links.comment, db_link, other_params FROM pfamA, pfamA_database_links WHERE pfamA_id = "CBS" AND pfamA.auto_pfamA = pfamA_database_links.auto_pfamA;
Structures and domain interactions (iPfam)
- Tables containing PDB information
There are two tables containing information primary about PDB structures: pdb
and msd_data
. The pdb
table contains a list of PDB identifiers, the header and the title records from that PDB file.
SELECT pdb_id, header, title FROM pdb WHERE pdb_id="2abl"; +--------+--------------+-----------------------------------------------------------+ | pdb_id | header | title | +--------+--------------+-----------------------------------------------------------+ | 2abl | Transferase | Sh3-sh2 domain fragment of human bcr-abl tyrosine kinase | +--------+--------------+-----------------------------------------------------------+ 1 row in set (0.00 sec)
For the PDB information to be useful to Pfam we need to map between PDB residues and UniProt sequence residues. This is not a trivial task! This mapping information is provided by the MSD database. See here for more details. The msd_data
table contains this residue by residue mapping.
The following statement gets the first 10 residue mappings for the structure 2ABL
.
SELECT pdb_id, pdb_res, pdb_seq_number, pfamseq_acc, pfamseq_res, pfamseq_seq_number FROM msd_data, pdb, pfamseq WHERE pdb.auto_pdb=msd_data.auto_pdb AND pfamseq.auto_pfamseq=msd_data.auto_pfamseq AND pdb_id="2abl" LIMIT 10; +--------+---------+----------------+-------------+-------------+--------------------+ | pdb_id | pdb_res | pdb_seq_number | pfamseq_acc | pfamseq_res | pfamseq_seq_number | +--------+---------+----------------+-------------+-------------+--------------------+ | 2abl | MET | 75 | P00519 | A | 56 | | 2abl | GLY | 76 | P00519 | G | 57 | | 2abl | PRO | 77 | P00519 | P | 58 | | 2abl | SER | 78 | P00519 | S | 59 | | 2abl | GLU | 79 | P00519 | E | 60 | | 2abl | ASN | 80 | P00519 | N | 61 | | 2abl | ASP | 81 | P00519 | D | 62 | | 2abl | PRO | 82 | P00519 | P | 63 | | 2abl | ASN | 83 | P00519 | N | 64 | | 2abl | LEU | 84 | P00519 | L | 65 | +--------+---------+----------------+-------------+-------------+--------------------+ 10 rows in set (0.00 sec)
Using a similar query to the previous one, we generate a mapping for each Pfam domain with a known structure. This information is stored in the pdbmap
table.
SELECT pdb_id, chain, pdb_start_res, pdb_end_res FROM pdb, pdbmap, pfamA WHERE pfamA_id = 'CBS' AND pfamA.auto_pfamA = pdbmap.auto_pfam AND pfam_region = '1' AND pdbmap.auto_pdb = pdb.auto_pdb;
- Tables Containing Domain Interaction Information (i.e., iPfam)
iPfam is a database within a database. iPfam contains information about domain-domain interactions.
The main table for iPfam is the interaction table. This is a large denormalised table that contains all of the interaction information to the residue-residue level. The interaction table can be joined onto the following tables: pdb, pfamA, pfamseq, int_atom, int_pfamAs
SELECT distinct interaction.auto_pfamA_A, interaction.pfamA_id_A, interaction.auto_pfamA_B, interaction.pfamA_id_B FROM interaction, pdb WHERE pdb_id="2abl" AND interaction.auto_pdb=pdb.auto_pdb;
There are three other tables that are part of the iPfam specific tables. The int_atom
contains the in atom numbers that are forming the interaction. The int_bond
table contains the actual bond that is formed between the interaction.
SELECT pdb_id, interaction.pdb_seq_number_A, pfamseq_seq_number_B, int_atom.pdb_atom, int_atom.partner_pdb_atom FROM interaction, pdb, int_atom WHERE pdb_id="2abl" AND int_atom.auto_atom_int=interaction.auto_atom_int AND interaction.auto_pdb=pdb.auto_pdb LIMIT 10;
Finally, the int_pfamAs
table gives the listing of the Domain-Domain interactions found in iPfam.
Genomes
Note: ncbi_code 1423
is for species: Bacillus subtilis. This information if found in the ncbi_taxonomy
table.
- Return all the species and basic Pfam information for a Kingdom:
SELECT ncbi_code, species, num_distinct_regions, num_total_regions, num_proteins, sequence_coverage, residue_coverage, total_genome_proteins FROM genome_species WHERE grouping like '%Bacteria%' ORDER BY species;
- Return all the Pfam-A domains for a species (using ncbi codes)
SELECT genome_seqs.auto_pfamA, pfamA_acc, pfamA_id, description, sum(count) FROM genome_seqs, pfamA WHERE genome_seqs.ncbi_code = '1423' AND genome_seqs.auto_pfamA = pfamA.auto_pfamA GROUP BY genome_seqs.auto_pfamA;
- Return the protein sequences for a species
SELECT pfamseq.pfamseq_id FROM pfamseq, genome_seqs WHERE ncbi_code = '1423' AND genome_seqs.auto_pfamseq = pfamseq.auto_pfamseq;
- Return all the protein sequences for a species and a specific Pfam-A domain
SELECT pfamseq.pfamseq_id FROM pfamseq, genome_seqs, pfamA WHERE ncbi_code = '1423' AND genome_seqs.auto_pfamseq = pfamseq.auto_pfamseq AND genome_seqs.auto_pfamA = pfamA.auto_pfamA AND pfamA_acc = 'PF00106';
See also
- Integr8 — Access to complete genomes and proteomes
- TrEMBL — Database performing an automated protein sequence annotation
- InterPro — Integration of protein domain and protein family databases
References
- Finn RD, Mistry J, Schuster-Bockler B, Griffiths-Jones S, Hollich V, Lassmann T, Moxon S, Marshall M, Khanna A, Durbin R, Eddy SR, Sonnhammer EL, Bateman A (2006). "Pfam: clans, web tools and services". Nucleic Acids Res, 34:D247-D251; PMID 16381856.
- Finn RD, Marshall M, Bateman A (2005). "iPfam: visualization of protein-protein interactions in PDB at domain and amino acid resolutions". Bioinformatics, 21:410-412; PMID 15353450.
- Bateman A, Coin L, Durbin R, Finn RD, Hollich V, Griffiths-Jones S, Khanna A, Marshall M, Moxon S, Sonnhammer EL, Studholme DJ, Yeats C, Eddy SR (2004). "The Pfam protein families database". Nucleic Acids Res, 32(Database issue):D138-D141; PMID 14681378.
External links
- Pfam - Protein family database at Sanger Institute, UK
- Pfam - Protein family database at Janelia Farm Research Campus, USA
- Pfam - Protein family database at Center for Genomics and Bioinformatics, Sweden
- iPfam - Interactions of Pfam domains in PDB
- Pfam database files (ftp)
- Pfam MySQL database documentation