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I-TASSER QUARK LOMETS COACH COFACTOR MetaGO MUSTER CEthreader SEGMER FG-MD ModRefiner REMO DEMO SPRING COTH BSpred ANGLOR EDock BSP-SLIM SAXSTER FUpred ThreaDom ThreaDomEx EvoDesign GPCR-I-TASSER MAGELLAN BindProf BindProfX SSIPe ResQ IonCom STRUM DAMpred

TM-score TM-align MM-align RNA-align NW-align LS-align EDTSurf MVP MVP-Fit SPICKER HAAD PSSpred 3DRobot MR-REX I-TASSER-MR SVMSEQ NeBcon ResPRE WDL-RF ATPbind DockRMSD DeepMSA FASPR

BioLiP E. coli GLASS GPCR-HGmod GPCR-RD GPCR-EXP Tara-3D TM-fold DECOYS POTENTIAL RW/RWplus EvoEF HPSF THE-DB CASP7 CASP8 CASP9 CASP10 CASP11 CASP12 CASP13

This page contains 3D structural models (Version 3, built on Aug 2014) of 1,026 putative G protein-coupled receptors (GPCRs) in the human genome generated by the GPCR-I-TASSER pipeline. The most recent (Version 4, built on June 2018) is now available as part of the GPCR-EXP database.

In GPCR-I-TASSER, the GPCR sequences are first threaded through the GPCR template library to identify muliple structure templates by the LOMETS programs. When close homolgous templates are identified, full-length models will be constructed by the I-TASSER based fragment assembly simulations, assisted by a GPCR and membrane specific force field and spatial restraints collected from mutagenesis experiments in GPCR-RD. In case that homologous templates are not available, an ab initio folding procedure is used to assemble the 7-TM-helix bundle from scratch, followed by the GPCR-I-TASSER fragment reassembly simulations. For multiple domain GPCRs, structural models are built by GPCR-I-TASSER for each domain separately which are then reassembly by the I-TASSER approach. All the models are finally subjected to FG-MD for fragment-guided molecular dynamic simulation refinements.

Note:

  • For each entry, the GPCR-HGmod data include top-five full-length models, LOMETS template and alignments, secondary structure prediction, solvent accessibility prediction, and residue-specific error and B-factor predictions.
  • The GPCR-I-TASSER models have generally higher resolution in the transmembrane regions; users should bear cautions on using the loop and tail regions of the models which have usually a relatively lower resolution. Users are encouraged to check the attached residue-specific quality (ResQ) prediction to assess the local structure errors.
  • All the models were constructed from the GPCR sequence alone. An attachment of addition ligand molecules may change the conformation of the structures.
  • Experimentally solved GPCR structures can be found at GPCR-EXP Database.
Other GPCR-related resources
GPCR resources from other laboratories



[ GPCR-HGmod Version 1: Human GPCR structure models generated in Jun 2013 ]
[ GPCR-HGmod Version 2: Human GPCR structure models generated in Mar 2014 ]
[ GPCR-HGmod Version 3: Human GPCR structure models generated in Aug 2014 ]
[ GPCR-HGmod Version 4: Human GPCR structure models generated in Jun 2018 ]

Download the tarball set of all GPCR results

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Structure Models of GPCRs in the Human Genome
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HG ID UniProt ID Length C-score Estimated
TM-score
Estimated
RMSD
Top 5 models
HG0140 P25106 362 -0.48 0.65 ± 0.13 7.60 ± 4.30
HG0141 Q8TDT9 306 1.59 0.94 ± 0.05 3.00 ± 2.20
HG0142 A5JUU5 370 -0.01 0.71 ± 0.11 6.70 ± 4.00
HG0143 Q15617 311 0.08 0.72 ± 0.11 6.10 ± 3.80
HG0144 P30988 490 -2.34 0.44 ± 0.14 9.99 ± 4.20
HG0145 Q7Z602 305 1.09 0.86 ± 0.07 4.00 ± 2.70
HG0146 Q8NGR9 330 -0.81 0.61 ± 0.14 8.20 ± 4.50
HG0147 Q86SQ3 457 -2.30 0.44 ± 0.14 9.99 ± 4.30
HG0148 Q6NWR6 365 -1.44 0.54 ± 0.15 9.90 ± 4.60
HG0149 P35372 400 -0.78 0.61 ± 0.14 8.60 ± 4.50
HG0150 Q502V2 469 -1.95 0.48 ± 0.15 9.99 ± 4.50


References:

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