| URL: | http://daisy.nagahama-i-bio.ac.jp/Famsbase/ |
| Full name: | Full Automatic Modeling System database |
| Description: | The latest update of FAMSBASE which is based on the protein three-dimensional (3D) structures released by November 2003, contains modeled 3D structures for 368,724 open reading frames (ORFs) derived from genomes of 276 species, namely 17 archaebacterial, 130 eubacterial, 18 eukaryotic and 111 phage genomes. |
| Year founded: | 2004 |
| Last update: | |
| Version: | |
| Accessibility: |
Accessible
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| Country/Region: | Japan |
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| University/Institution: | Japan Atomic Energy Agency |
| Address: | Quantum Bioinformatics Team, Center for Computational Science and Engineering, Japan Atomic Energy Agency, 8-1 Umemidai, Kizu-cho, Souraku-gun, Kyoto, 619-0215 Japan |
| City: | Kyoto |
| Province/State: | |
| Country/Region: | Japan |
| Contact name (PI/Team): | Kei Yura |
| Contact email (PI/Helpdesk): | pj.og.aeaj@iek.aruy |
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Coverage of whole proteome by structural genomics observed through protein homology modeling database. [PMID: 17146617]
We have been developing FAMSBASE, a protein homology-modeling database of whole ORFs predicted from genome sequences. The latest update of FAMSBASE ( http://daisy.nagahama-i-bio.ac.jp/Famsbase/ ), which is based on the protein three-dimensional (3D) structures released by November 2003, contains modeled 3D structures for 368,724 open reading frames (ORFs) derived from genomes of 276 species, namely 17 archaebacterial, 130 eubacterial, 18 eukaryotic and 111 phage genomes. Those 276 genomes are predicted to have 734,193 ORFs in total and the current FAMSBASE contains protein 3D structure of approximately 50% of the ORF products. However, cases that a modeled 3D structure covers the whole part of an ORF product are rare. When portion of an ORF with 3D structure is compared in three kingdoms of life, in archaebacteria and eubacteria, approximately 60% of the ORFs have modeled 3D structures covering almost the entire amino acid sequences, however, the percentage falls to about 30% in eukaryotes. When annual differences in the number of ORFs with modeled 3D structure are calculated, the fraction of modeled 3D structures of soluble protein for archaebacteria is increased by 5%, and that for eubacteria by 7% in the last 3 years. Assuming that this rate would be maintained and that determination of 3D structures for predicted disordered regions is unattainable, whole soluble protein model structures of prokaryotes without the putative disordered regions will be in hand within 15 years. For eukaryotic proteins, they will be in hand within 25 years. The 3D structures we will have at those times are not the 3D structure of the entire proteins encoded in single ORFs, but the 3D structures of separate structural domains. Measuring or predicting spatial arrangements of structural domains in an ORF will then be a coming issue of structural genomics. |
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FAMS and FAMSBASE for protein structure. [PMID: 18428727]
The computer program FAMS (Full Automatic Modeling System) performs homology modeling of protein structures by means of an algorithm consisting of database searches and simulated annealing. FAMS produces a model in which the torsion angles of the backbone and sidechains are highly accurate. The operations of the FAMS algorithm are fully automated, and, therefore, special knowledge, techniques or experience are not required in order to obtain a biologically worthwhile protein structure. |