ECOD: An Evolutionary Classification of Protein Domains

Cheng, Hua; Schaeffer, R. Dustin; Liao, Yuxing; Kinch, Lisa N.; Pei, Jimin; Shi, Shuoyong; Kim, Bong Hyun; Grishin, Nick V.

doi:10.1371/journal.pcbi.1003926

Cited by 355 publications

(453 citation statements)

References 60 publications

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“…CATH [35], SCOP [33] and ECOD [37]). PhyloFacts [20] also provides domain families in its resources which are sub-classified using SCI-PHY, as for the whole protein families.…”

Section: Protein Domain Familiesmentioning

confidence: 99%

Protein function annotation using protein domain family resources

Das

Orengo

2016

Methods

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As a result of the genome sequencing and structural genomics initiatives, we have a wealth of protein sequence and structural data. However, only about 1% of these proteins have experimental functional annotations. As a result, computational approaches that can predict protein functions are essential in bridging this widening annotation gap. This article reviews the current approaches of protein function prediction using structure and sequence based classification of protein domain family resources with a special focus on functional families in the CATH-Gene3D resource.

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“…CATH [35], SCOP [33] and ECOD [37]). PhyloFacts [20] also provides domain families in its resources which are sub-classified using SCI-PHY, as for the whole protein families.…”

Section: Protein Domain Familiesmentioning

confidence: 99%

Protein function annotation using protein domain family resources

Das

Orengo

2016

Methods

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“…For proteins and domains without known structure, we considered putative structural templates detected by HHpred, 45 iTASSER 46,47 and known structures for proteins of similar function from other families of RNA virus in PDB and ECOD databases. 48 Once a candidate structural template was detected, we further validated its relationship to the Ebolavirus protein by similarity in function, compatibility between the predicted secondary structure 49 of the Ebolavirus protein and the 3D structure of the template, conservation of residues in the Ebolavirus protein that were aligned to the active sites of the template, and the consistency among multiple structural templates. Sequences of the structural templates and the ZEBOV protein were aligned by Promals3D 50,51 and the alignments were manually adjusted to ensure that the corresponding secondary structure elements in different templates were aligned together.…”

Section: Sequence Analysis Of Ebolavirus Proteinsmentioning

confidence: 99%

“…In addition, a scan of PDB sequences with the conserved pattern C-x (8)-C-x(4)-C-x(3)-H using ScanProsite 74 reveals exactly the same motif in CCCH zinc fingers (PDB id: 2d9n). All the CCCH zinc fingers belongs to one homologous group in the ECOD database, 48 and this family contains the N-terminal domain of the transcription antiterminator M2-1 from another Mononegavirales, Pneumovirus (4C3B 75 and 4CS7, 76 alignment shown in Fig. S1).…”

Section: The Zinc-finger Domain Of Vp30mentioning

confidence: 99%

Predictive and comparative analysis of Ebolavirus proteins

2015

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Ebolavirus is the pathogen for Ebola Hemorrhagic Fever (EHF). This disease exhibits a high fatality rate and has recently reached a historically epidemic proportion in West Africa. Out of the 5 known Ebolavirus species, only Reston ebolavirus has lost human pathogenicity, while retaining the ability to cause EHF in long-tailed macaque. Significant efforts have been spent to determine the three-dimensional (3D) structures of Ebolavirus proteins, to study their interaction with host proteins, and to identify the functional motifs in these viral proteins. Here, in light of these experimental results, we apply computational analysis to predict the 3D structures and functional sites for Ebolavirus protein domains with unknown structure, including a zinc-finger domain of VP30, the RNA-dependent RNA polymerase catalytic domain and a methyltransferase domain of protein L. In addition, we compare sequences of proteins that interact with Ebolavirus proteins from RESTV-resistant primates with those from RESTV-susceptible monkeys. The host proteins that interact with GP and VP35 show an elevated level of sequence divergence between the RESTV-resistant and RESTV-susceptible species, suggesting that they may be responsible for host specificity. Meanwhile, we detect variable positions in protein sequences that are likely associated with the loss of human pathogenicity in RESTV, map them onto the 3D structures and compare their positions to known functional sites. VP35 and VP30 are significantly enriched in these potential pathogenicity determinants and the clustering of such positions on the surfaces of VP35 and GP suggests possible uncharacterized interaction sites with host proteins that contribute to the virulence of Ebolavirus.

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“…Target-specific pages show evaluation results at three levels of target /model structural organization: quaternary structure ( Multimers tab), tertiary structure ( Monomers tab) and constituting domains (Cheng et al, 2014), if applicable ( Domains tab). For each of the structural organization levels, a user can browse the results by checking tabs corresponding to different assessment tracks.…”

Section: Presentation Of the Evaluation Resultsmentioning

confidence: 99%

“…Targets are split into domains by consulting the DomainParser (Guo et al, 2003), DDomain2 (Zhou et al, 2007) programs, and the ECOD (Cheng et al, 2014) database of structural domains. Organization of the web resource for the Domains evaluation is similar to that for the Monomers .…”

Section: Presentation Of the Evaluation Resultsmentioning

confidence: 99%

Evaluation system and web infrastructure for the second cryo-EM model challenge

Kryshtafovych

Adams

Lawson

et al. 2018

Journal of Structural Biology

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An evaluation system and a web infrastructure were developed for the second cryo-EM model challenge. The evaluation system includes tools to validate stereo-chemical plausibility of submitted models, check their fit to the corresponding density maps, estimate their overall and per-residue accuracy, and assess their similarity to reference cryo-EM or X-ray structures as well as other models submitted in this challenge. The web infrastructure provides a convenient interface for analyzing models at different levels of detail. It includes interactively sortable tables of evaluation scores for different subsets of models and different sublevels of structure organization, and a suite of visualization tools facilitating model analysis. The results are publicly accessible at http://model-compare.emdatabank.org.

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ECOD: An Evolutionary Classification of Protein Domains

Cited by 355 publications

References 60 publications

Protein function annotation using protein domain family resources

Protein function annotation using protein domain family resources

Predictive and comparative analysis of Ebolavirus proteins

Evaluation system and web infrastructure for the second cryo-EM model challenge

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