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I-TASSER results for job id Rv3346c

[Click on result.tar.bz2 to download the tarball file including all modelling results listed on this page]

 Input Sequence in FASTA format
 Predicted Secondary Structure
 Predicted Solvent Accessibility
 Predicted Normalized B-facotr
 Top 10 threading templates used by I-TASSER
 Top 5 final models predicted by I-TASSER

(For each target, I-TASSER simulations generate a large ensemble of structural conformations, called decoys. To select the final models, I-TASSER uses the SPICKER program to cluster all the decoys based on the pair-wise structure similarity, and reports up to five models which corresponds to the five largest structure clusters. The confidence of each model is quantitatively measured by C-score that is calculated based on the significance of threading template alignments and the convergence parameters of the structure assembly simulations. C-score is typically in the range of [-5, 2], where a C-score of higher value signifies a model with a high confidence and vice-versa. TM-score and RMSD are estimated based on C-score and protein length following the correlation observed between these qualities. Since the top 5 models are ranked by the cluster size, it is possible that the lower-rank models have a higher C-score in rare cases. Although the first model has a better quality in most cases, it is also possible that the lower-rank models have a better quality than the higher-rank models as seen in our benchmark tests. If the I-TASSER simulations converge, it is possible to have less than 5 clusters generated. This is usually an indication that the models have a good quality because of the converged simulations.)
 Proteins structureally close to the target in PDB (as identified by TM-align

(After the structure assembly simulation, I-TASSER uses the TM-align structural alignment program to match the first I-TASSER model to all structures in the PDB library. This section reports the top 10 proteins from the PDB that have the closest structural similarity, i.e. the highest TM-score, to the predicted I-TASSER model. Due to the structural similarity, these proteins often have similar function to the target. However, users are encouraged to use the data in the next section 'Predicted function using COACH' to infer the function of the target protein, since COACH has been extensively trained to derive biological functions from multi-source of sequence and structure features which has on average a higher accuracy than the function annotations derived only from the global structure comparison.)


 Predicted function using COACH

(This section reports biological annotations of the target protein by COACH based on the I-TASSER structure prediction. COACH is a meta-server approach that combines multiple function annotation results from the COFACTOR, TM-SITE and S-SITE programs.)


  Ligand binding sites

Rank C-score Cluster
size
PDB
Hit
Lig
Name
Download
Complex
Ligand Binding Site Residues
10.10 4 1y6oA PO4 Rep, Mult 8,27,28,29,30
20.07 3 1hn4A MJI Rep, Mult 6,8,25,37,38,41,74
30.05 2 1jb0L CLA Rep, Mult 45,75,76
40.05 2 2onhA MN Rep, Mult 58,61,65
50.02 1 1l8sB LPE Rep, Mult 7,8,11,28,52
60.02 1 3mgrH RB Rep, Mult 42,43,45
70.02 1 3d1lB MPR Rep, Mult 66,84,85
80.02 1 1fxfB MJI Rep, Mult 23,26,27,31,71,74,75
90.02 1 2bo6B MN Rep, Mult 57,61
100.02 1 2o012 CLA Rep, Mult 38,42
110.02 1 2wse1 CLA Rep, Mult 19,27
120.02 1 4il4B LSM Rep, Mult 66,70,73
130.02 1 1y6pA CA Rep, Mult 32,34,35,36,38

Download the all possible binding ligands and detailed prediction summary.
Download the templates clustering results.
(a)C-score is the confidence score of the prediction. C-score ranges [0-1], where a higher score indicates a more reliable prediction.
(b)Cluster size is the total number of templates in a cluster.
(c)Lig Name is name of possible binding ligand. Click the name to view its information in the BioLiP database.
(d)Rep is a single complex structure with the most representative ligand in the cluster, i.e., the one listed in the Lig Name column.
Mult is the complex structures with all potential binding ligands in the cluster.

  Enzyme Commission (EC) numbers and active sites

RankCscoreECPDB
Hit
TM-scoreRMSDaIDENaCovEC NumberActive Site Residues
10.0602wyeB0.5753.560.1000.9293.5.1.9724,51
20.0602hcsA0.4504.070.0650.7062.7.7.48,3.4.21.91NA
30.0601bvuC0.5643.610.0480.8941.4.1.368
40.0601cjyA0.5533.710.0730.9183.1.1.4,3.1.1.5NA
50.0601f1hL0.5533.210.0540.8246.3.1.241
60.0601b4wA0.5553.240.0830.8473.1.1.434
70.0601gtmA0.5593.750.0360.9061.4.1.358
80.0601v9lA0.5663.440.0240.8821.4.1.280
90.0603k92A0.5633.560.0600.8821.4.1.26,27,36,68
100.0601p7oA0.5463.460.1140.8943.1.1.4NA
110.0601pp2R0.5453.400.0680.8593.1.1.4NA
120.0601bvuA0.5643.450.0480.8821.4.1.380
130.0603f5mB0.5503.410.1150.8592.7.1.1156
140.0601f1hA0.5533.210.0540.8246.3.1.2NA
150.0602lgsA0.4653.910.0280.7416.3.1.2NA
160.0602oqdB0.5453.300.0380.8713.1.1.440
170.0601bk9A0.5433.540.0950.8713.1.1.432
180.0601htoA0.5533.240.0410.8246.3.1.2NA
190.0601vapA0.5393.610.0800.8823.1.1.432

(a)CscoreEC is the confidence score for the EC number prediction. CscoreEC values range in between [0-1];
where a higher score indicates a more reliable EC number prediction.
(b)TM-score is a measure of global structural similarity between query and template protein.
(c)RMSDa is the RMSD between residues that are structurally aligned by TM-align.
(d)IDENa is the percentage sequence identity in the structurally aligned region.
(e)Cov represents the coverage of global structural alignment and is equal to the number of structurally aligned residues divided
by length of the query protein.

  Gene Ontology (GO) terms

Homologous GO templates in PDB 
RankCscoreGOTM-scoreRMSDaIDENaCovPDB HitAssociated GO Terms
00.130.5433.540.100.871bk9A GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0046872
10.070.5243.550.040.911u73A GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0008217 GO:0016042 GO:0016787 GO:0042742 GO:0046872
20.070.6033.150.100.912qfzA GO:0005096 GO:0005622 GO:0006886 GO:0012505 GO:0017137 GO:0031338 GO:0042803 GO:0071889 GO:0090630 GO:1902017
30.070.5553.240.080.851b4wA GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0046872
40.070.5123.660.050.913dihA GO:0004623 GO:0005509 GO:0005576 GO:0016042 GO:0072556
50.070.5113.710.050.921vipA GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0046872
60.070.5353.610.050.914rfpA GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0042802 GO:0046872
70.070.5053.690.040.911aypA GO:0004623 GO:0005509 GO:0005543 GO:0005576 GO:0005615 GO:0005783 GO:0005789 GO:0006629 GO:0006644 GO:0006654 GO:0010744 GO:0016020 GO:0016042 GO:0016787 GO:0030141 GO:0034374 GO:0036148 GO:0036149 GO:0036150 GO:0036151 GO:0036152 GO:0046473 GO:0046872 GO:0047498 GO:0048471 GO:0050729 GO:0050830 GO:0070062 GO:0070374
80.070.5493.430.070.861pp2L GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0046872
90.070.5393.610.080.881vapA GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0046872
100.070.5063.620.010.911aokA GO:0004623 GO:0005509 GO:0005576 GO:0016042 GO:0035792
110.070.5243.510.030.891m8tA GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0046872
120.070.5653.150.090.844ntwC GO:0004623 GO:0005509 GO:0005576 GO:0016042
130.070.5193.460.030.871mh2B GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0046872
140.070.5533.190.080.861oqsB GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0046872 GO:0072556
150.070.5773.630.080.913dzxA GO:0005096 GO:0005622 GO:0006886 GO:0012505 GO:0017137 GO:0031338 GO:0071889 GO:0090630 GO:1902017
160.070.5883.640.080.963eloA GO:0000187 GO:0002227 GO:0002446 GO:0004623 GO:0005102 GO:0005509 GO:0005576 GO:0005615 GO:0006629 GO:0006633 GO:0006644 GO:0006654 GO:0007015 GO:0007165 GO:0009986 GO:0010524 GO:0015758 GO:0016042 GO:0016787 GO:0019370 GO:0019731 GO:0030141 GO:0030593 GO:0032052 GO:0032431 GO:0032637 GO:0032869 GO:0035556 GO:0036148 GO:0036149 GO:0036150 GO:0036151 GO:0036152 GO:0044240 GO:0045740 GO:0045944 GO:0046470 GO:0046872 GO:0047498 GO:0048146 GO:0050482 GO:0050714 GO:0050778 GO:0050830 GO:0051092
170.070.5323.400.010.883g8gA GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0030430 GO:0044164 GO:0046872 GO:0072556
180.070.5183.710.050.891a3dA GO:0004623 GO:0005509 GO:0005576 GO:0006629 GO:0016042 GO:0016787 GO:0046872


Consensus prediction of GO terms
 
Molecular Function GO:0052689 GO:0046872 GO:0004620
GO-Score 0.59 0.59 0.59
Biological Processes GO:0006629 GO:0044712 GO:1901575
GO-Score 0.59 0.59 0.59
Cellular Component GO:0005576 GO:0012505 GO:0005622 GO:0072556
GO-Score 0.30 0.07 0.07 0.07

(a)CscoreGO is a combined measure for evaluating global and local similarity between query and template protein. It's range is [0-1] and higher values indicate more confident predictions.
(b)TM-score is a measure of global structural similarity between query and template protein.
(c)RMSDa is the RMSD between residues that are structurally aligned by TM-align.
(d)IDENa is the percentage sequence identity in the structurally aligned region.
(e)Cov represents the coverage of global structural alignment and is equal to the number of structurally aligned residues divided by length of the query protein.
(f)The second table shows a consensus GO terms amongst the top scoring templates. The GO-Score associated with each prediction is defined as the average weight of the GO term, where the weights are assigned based on CscoreGO of the template.

[Click on result.tar.bz2 to download the tarball file including all modelling results listed on this page]



Please cite the following articles when you use the I-TASSER server:
1. J Yang, R Yan, A Roy, D Xu, J Poisson, Y Zhang. The I-TASSER Suite: Protein structure and function prediction. Nature Methods, 12: 7-8, 2015.
2. J Yang, Y Zhang. I-TASSER server: new development for protein structure and function predictions, Nucleic Acids Research, 43: W174-W181, 2015.
3.A Roy, A Kucukural, Y Zhang. I-TASSER: a unified platform for automated protein structure and function prediction. Nature Protocols, 5: 725-738, 2010.
4.Y Zhang. I-TASSER server for protein 3D structure prediction. BMC Bioinformatics, 9: 40, 2008.