key: cord-0941010-61m5e0pd
authors: Meldal, Birgit H M; Perfetto, Livia; Combe, Colin; Lubiana, Tiago; Ferreira Cavalcante, João Vitor; Bye-A-Jee, Hema; Waagmeester, Andra; del-Toro, Noemi; Shrivastava, Anjali; Barrera, Elisabeth; Wong, Edith; Mlecnik, Bernhard; Bindea, Gabriela; Panneerselvam, Kalpana; Willighagen, Egon; Rappsilber, Juri; Porras, Pablo; Hermjakob, Henning; Orchard, Sandra
title: Complex Portal 2022: new curation frontiers
date: 2021-10-29
journal: Nucleic Acids Res
DOI: 10.1093/nar/gkab991
sha: 91595656c8bc2ccbd7885cff6e1a88e68fd2370e
doc_id: 941010
cord_uid: 61m5e0pd

The Complex Portal (www.ebi.ac.uk/complexportal) is a manually curated, encyclopaedic database of macromolecular complexes with known function from a range of model organisms. It summarizes complex composition, topology and function along with links to a large range of domain-specific resources (i.e. wwPDB, EMDB and Reactome). Since the last update in 2019, we have produced a first draft complexome for Escherichia coli, maintained and updated that of Saccharomyces cerevisiae, added over 40 coronavirus complexes and increased the human complexome to over 1100 complexes that include approximately 200 complexes that act as targets for viral proteins or are part of the immune system. The display of protein features in ComplexViewer has been improved and the participant table is now colour-coordinated with the nodes in ComplexViewer. Community collaboration has expanded, for example by contributing to an analysis of putative transcription cofactors and providing data accessible to semantic web tools through Wikidata which is now populated with manually curated Complex Portal content through a new bot. Our data license is now CC0 to encourage data reuse. Users are encouraged to get in touch, provide us with feedback and send curation requests through the ‘Support’ link.

Protein complexes, stable functional assemblies consisting of two or more associated polypeptide chains, are responsible for driving and regulating many cellular processes. Multi-chain assemblies perform many functions, including (a) positioning molecules involved in the same process in close proximity (b) bringing structure to disordered regions of proteins and (c) creating novel substrate binding sites at subunit interfaces. These assemblies can contain additional molecules, such as nucleic acids and small molecules. In budding yeast (1), around one in three proteins have a function in stable heteromeric complexes and in bacteria around one in five (see below).

Although the existence of many well-studied protein complexes has been recognized for decades, existing manually curated, species-specific catalogues were either not regularly maintained, e.g. CYGD (2) for yeast, or entries were curated based on individual papers rather than amalgamated knowledge, e.g. CORUM (3) for mammalian species. The Complex Portal (www.ebi.ac.uk/complexportal) was created to meet this unmet need: It is a manually curated, encyclopaedic resource that provides stable identifiers and summarizes compositional, topological and functional aspects of stable macromolecular complexes from a selection of model organisms and organisms of special interest. It enables protein complex identification in large-scale data analyses, contributing to the study of complex evolution and increasing our understanding of cell biology (4) (5) (6) (7) (8) .

Since the last update (9) , the coverage of model organism complexomes, the compendium of known complexes for a given species, has increased significantly, with that of Saccharomyces cerevisiae being maintained and added to as more experimental data leads to the identification of new assemblies (1) and the completion of a first draft of the Escherichia coli complexome. Work is now focused on annotating human complexes, wherever possible in collaboration with other data resources or scientific groups. We have also responded to the ongoing SARS-CoV-2 pandemic by creating the complexome of this organism and also of related viruses, in order to contribute to global efforts to respond to this threat.

We have improved ComplexViewer so that it can display multiple features simultaneously and show links between participants of sub-complexes and other complex participants. We updated the participant table so that all participants are now colour-coordinated between ComplexViewer and the table (Figure 1 ). We have made updates to the Com-plexTab format, adding a 'UniProt ID-only' column that lists the UniProt accession numbers (and their stoichiometry) for the protein participants of complexes, including those that are part of subcomplexes and molecule sets.

We have expanded our community collaboration by contributing to a large-scale transcription cofactor analysis, by working with Wikidata contributors who have written a bot that populates Wikidata with Complex Portal content for semantic web reuse and by collaborating with the Cytoscape ClueGO App developers to incorporate Complex Portal entries as a new ontology for complex enrichment analyses. Finally, we changed our content license to CC0 to improve data accessibility and re-use.

A protein complex is a functional, biological entity that contains two or more macromolecules (proteins, nucleic acids or small molecules) for which there is experimental or inferred evidence that these molecules stably interact with each other. As of release 241 (18 October 2021), 3572 complexes from 26 species have been curated and released. Each entry is species-specific, describing the complex composition, topology and function and linking out to external databases that provide further domain-specific information, such as structural details from wwPDB (10) or EMDB (11) or the role of the complex in metabolic reactions or signalling pathways in Reactome (12) . Complex components are linked to primary reference resources; UniProt (13, 14) for proteins, ChEBI (14) for small molecules and RNAcentral (15) for noncoding RNAs. Complexes that are also participants of larger complexes are linked to their own Complex Portal entries. In principle, we create separate entries for each compositional variant of a complex. How-ever, some complexes, mainly the ribosomes, contain many participants that are potentially coded by two alternative, paralogous genes. In these cases, we create molecule sets, identified by identifiers of type EBI-{1-9}, containing the UniProt IDs of each of the paralogous proteins. On the website they appear as unlinked concatenations of gene symbols and species names, e.g. 'rps4a rps4b yeast'.

Since our last update three years ago, we have focused on a number of curation priorities:

Escherichia coli complexome. In December 2019, we released the first version of the E. coli K12 (NCBI reference taxon: 83333) complexome currently consisting of 321 complexes. This work was based on extensive literature mining and subsequent comparison with existing resources, in this case primarily UniProt KB and EcoCyc (16) . This systematically annotated set of E. coli complexes includes, at the time of writing, 786 unique proteins (18% of the proteome). 95% (305) of complexes contain 5 or fewer proteins (median = 3) ( Figure 2 ). 87% unique proteins (681/786) are found in only one complex and 9% protein (74/786) in two complexes with the remaining 31 proteins found in more than two complexes. This distribution is similar to what we saw for yeast (1) except that fewer proteins in general were found in heteromeric complexes (18% versus 32%).

As with the recently completed S. cerevisiae complexome, a watchlist of additional potential candidate complexes exists and these are being added to the dataset on an ongoing basis, if and when they are experimentally verified. Also, it must be recognised that E. coli K12 is a nonpathogenic laboratory strain and many proteins are cryptic or have been engineered out of the strain. Complexes containing such proteins are therefore absent from this model organism. For example, E. coli K12 does not express the PhnE permease due to the presence of an 8 bp insertion in phnE (17) , therefore the phosphonate ABC transporter complex is not formed. To capture complexes that contain proteins not present in the K12 strain but that are essential for fully understanding the life-cycle of wild-type strains of these Gram-negative bacteria, the complex and its protein components are mapped to the species level for E. coli, NCBI taxon ID:562. Examples include the phosphonate ABC transporter complex (CPX-4382) and heat-labile enterotoxin IIB complex (CPX-2304).

Coronavirus complexes. In response to the COVID-19 pandemic we have curated coronavirus complexes as well as human targets of viral proteins (18) . To date, we have released 21 SARS-CoV-2 complexes (taxon ID: 2697049), 16 SARS-CoV complexes (taxon ID: 694009) and 17 MERs-CoV complexes (taxon IDs: 1263720 and 1235996 [no reference proteome available]). They include mixed-species complexes of the viral Spike proteins with their host receptors ACE2 ( Figure 1 ) and DPP4, respectively. As new experimental evidence emerges frequently for these complexes we have made use of our versioning protocol and updated complex components, stoichiometry and function. For example, new evidence from crystal and SAXS analyses led to an update of the stoichiometry of the nsp7-nsp8 primase (CPX-5690) from 8:8 to 2:2 while the function of the nsp10-nsp14 complex (CPX-5692) was updated from a guanine-N7 methyltransferase to a 3 -5 exoribonuclease (GO:0000175). We continue to add new interaction evidence from IntAct (19) and structural evidence from ww-PDB (20) and EMDB (21) at each release. These complexes are already used as cross-references by several external databases such as the IMEx resources (22) , Gene Ontology (23, 24) , MatrixDB (25), Reactome, SIGNOR (26), UniProtKB and WikiPathways (27) thus allowing for a more integratable set of coronavirus-related information to be freely available to the research community.

Human complexes. Efforts are now focused on expanding the collection of manually curated human complexes. Exactly how many assemblies comprise the human complexome is a question still very much open to debate. We anticipate that most, but not all, of the intracellular complexes we have identified in S. cerevisiae are conserved in multicellular organisms, but human complexes often contain additional protein components or the existence of paralogous proteins lead to increased numbers of complex variants. One simple example of the latter case is the replication protein A complex, a single heterotrimer in yeast (CPX-21), but in humans one protein (P15927/Q13156) has been duplicated resulting in two heterotrimeric complex variants (CPX-1878/CPX-1879). Additionally, there will be an appreciable number of transmembrane and extra-cellular complexes with a role in the immune response, inter-and intracellular communication and signalling. A data mining exercise, undertaken in collaboration with the UniProt group, of information embedded in UniProtKB records has suggested that there may be at least 4000 different assemblies in the human complexome. To date, we have released 1255 human complexes including almost 200 that are either targets of viral proteins or play a role in the immune system, including the B-cell and T-cell receptor complexes, the interferon-receptor family of complexes and the complete complement cascade of the innate immune system. We are also focusing on dimeric transcription factor complexes, complementing a recent revision of the human transcription factor proteins undertaken by members of the Gene Ontology and Gene Regulation Consortia (28) .

Linking chemistry to biology: enhancing enzyme annotation. Many enzymes are found in multi-chain complexes, which may serve to bring together multiple enzymes associated with a specific metabolic pathway, bring regulatory subunits in close proximity to the catalytic chain, enable the coordination of ligand binding, or create new binding sites in subunit interfaces. In order to improve our annotation of these assemblies, we are now adding cross-references to the Rhea knowledgebase of biochemical reactions (29) where it has been demonstrated that the enzyme has this activity in the context of a given complex. Rhea uses the chemical ontology ChEBI to describe reaction participants, their chemical structures and chemical transformations and enables a more granular description of the enzyme/substrate interaction. For example, human serine palmitoyltransferase exists as four variant complexes (CPX-6663, CPX-6664, CPX-6665, CPX-6681) which share a common E.C. number (2.3.1.50). However, the substrate specificities of these complexes vary, due to the positioning of side chain residues of differing amino acids in the alternate complex components, and this can be fully described by the addition of the appropriate Rhea cross-references. Rhea cross-references are currently available in download files, and will be visualised on the website in the near future.

Enzymes are not the only complex components which bind small molecules. Rhea encompasses transporter activity within its concept of a reaction, and cross-references are increasingly being added to complexes involved in trans-portation. The ligands that are bound by receptors are also systematically captured as a 'ligand' annotation topic and are described by both a recommended, human-readable protein, peptide or small molecule name and a UniProtKB or ChEBI accession number, as appropriate.

Defining curation practice for obsoleting complexes and versioning. When the research community's understanding of a complex's existence changes to the extent that we need to delete an existing entry, or we decide to merge a sub-complex into a larger assembly, the original entries remain available in previous release files accessible via our ftp repository (http://ftp.ebi.ac.uk/pub/databases/ intact/complex/). If a complex has been merged into an existing entry, the accession number of the obsoleted complex is added to the complex it has been merged into as a secondary identifier, allowing an external user to still retrieve an entry. Secondary identifiers are available in all download files, while the website currently only displays the primary accession number (e.g. CPX-3042 is now part of CPX-2161). This enables us to adhere to the FAIR principle of data Findability. More minor updates, for example the identification of an additional participant, are indicated by entry versioning, as previously described (1, 9) .

We have made a number of improvements to the Com-plexViewer (3) (Figure 1 Additionally, the participant table is now colourcoordinated, matching the node colours of proteins or background colours of complexes as participants.

We have refreshed and updated the Home, About and Documentation pages, including adding more information about our curation practices, handling of edge cases and documentation about our file formats. These new pages are also linked to our GitHub repository which allows us to make any updates easier and quicker.

Complexes may contain molecules other than proteins, such as nucleic acids or small molecules, but some users, for example mass spectrometry proteomics scientists, are only interested in the protein components. Protein complexes can be subcomponents of larger assemblies, and users previously needed to parse the files separately to retrieve the participant of these subcomplexes. In response to requests from this user community, we have added a new column to the tab-delimited format, ComplexTab, that contains a list of UniProt accession numbers (including isoform or postprocesses chain extensions) in pipe-separated style with stoichiometry in parentheses.

To ensure our data is available for reuse by all interested parties, and in line with EMBL-EBI policy, our licence has been updated to Creative Commons Public Domain (CC0) License (https://creativecommons.org/ publicdomain/zero/1.0/). This applies to all Complex Portal data, i.e. PSI-MI XML3.0 (30), MI-JSON and Com-plexTab files (9) , as well as data directly accessed via web pages/services.

The GREEKc collaboration was an EC-funded COST action aimed at integrating data and knowledge pertaining to gene regulation, of which the Complex Portal was an active participant throughout. As part of this effort, Velthuijs et al. (31) have used the Complex Portal as a verification dataset in their analysis of potential transcription cofactors. By combining inferred complexes from hu.MAP 2.0 (32), curated complexes from CORUM (33) and curated physical interaction data from IntAct [this volume NAR paper] and BioGrid (34) with a selected set of transcription-related Gene Ontology terms we have identified more than 1500 putative transcription cofactors. 415 of these are already participants of complexes in Complex Portal, and the remaining proteins will be curated into Complex Portal if they are identified as components of complexes.

Wikidata (https://www.wikidata.org/) is part of the infrastructure provided by the Wikimedia Foundation and a sister project of Wikipedia; it initially provided a semantic web infrastructure for encyclopedic knowledge to be used in Wikipedia (35) , but has since gained traction as a generic linked open resource; over the past years a number of life sciences resources have been aligned to Wikidata, including subsets of UniProt, the Gene Ontology and ChEBI.

After we released the first eleven SARS-CoV-2 complexes in April 2020 we joined the COVID19 Virtual Elixir BioHackathon 2020 (https://github.com/ virtual-biohackathons/covid-19-bh20/wiki).

During this hackathon we added Wikidata entities for these eleven complexes using a semi-automated curation pipeline using OpenRefine (https://openrefine.org/) and the Wikidata Integrator Python module (36) . Through this integration into Wikidata, Complex Portal identifiers (https://www.wikidata.org/wiki/Property:P7718) for SARS-CoV-2 complexes as well as selected human complexes, which had already been manually added to Wikidata, were immediately used in the WikiPathways COVID-19 Pathways Collection (http://covid.wikipathways.org/) (36) which is part of the COVID-19 Disease Map project (https://covid19map.elixir-luxembourg.org/minerva/) (37) that also includes the Reactome COVID-19 project. As an extension to this initial SARS-CoV-2-focused collaboration we have subsequently developed a Wikidata Complex Bot, reconciling the entries in Complex Portal to Wikidata. The Complex Bot parses the Complex Portal releases and enriches the Wikidata environment, connecting proteins by their common presence in complexes, linking the new entries to existing entries and matching GO complexes with their Wikidata IDs. As a result, Complex Portal data is now available on the semantic web and updated regularly in line with our regular data releases and integrated with related UniProt, GO and ChEBI data in semantic web format ( Figure 3 ). This enables rapid integration with other linked-data sources using Wikidata as a proxy. To be able to run bots on Wikidata a bot-flag was requested (https://www.wikidata.org/wiki/Wikidata: Requests for permissions/Bot/ComplexPortalBot) and approved after an online vetting process, where the rationale and the software was assessed. The open source code of the bot can be found at https://github.com/lubianat/complex bot.

Currently, the bot runs manually; after each Complex Portal update a request is sent to the bot developer to run the bot on the recent update. We are working towards an automatic integration of the two processes, similar to the continuous integration applied elsewhere (36) . Another use of the Complex Portal data in Wikidata is the visualisation of complex information with Scholia (38) . For example, https://scholia.toolforge.org/complex/Q104836061 shows information for the SARS-CoV-2 polymerase complex (CPX-5742). Similarly, protein pages show in which complexes they participate (e.g. https://scholia.toolforge.org/protein/Q90038963 for SARS-CoV-2 NSP7).

Complex Portal identifiers are already being used as the preferred identifiers for complex entities in, among others, IMEx, Gene Ontology, Saccharomyces Genome Database (39) and SIGNOR curation efforts and more recently for causal interaction curation efforts based on MI2CAST curation guidelines (40) , WikiPathways (27) annotations (via the BridgeDb (41) mapping service) and the COVID-19 Disease Map project (37) . The use of Complex Portal identifiers in WikiPathways was enabled by manually creating complex entities in Wikidata with cross-references to Complex Portal, an effort that preceded and initiated our Wikidata bot development. An ongoing collaboration with the UniProt team will drive further work on the human complexome and an enhanced import of data from the Complex Portal into UniProt records is under active discussion.

Complex Portal data, together with molecular interaction data from IntAct, Reactome and SIGNOR, is integrated into the Open Targets (42) partnership that uses human genetics and genomics data for systematic drug target identification and prioritisation, via our bespoke graph database. Additionally, we provide a JSON file from the same graph database, containing protein-to-complex mappings.

The ClueGO App (43) is a powerful platform for functional enrichment analysis within Cytoscape (44) . Bespoke Complex Portal ontology files have been created for a selected number of species with the Complex Portal complexes being leaf nodes of the Gene Ontology Cellular Component class. These new ontology files are available starting with ClueGO version 2.5.8 and allow users to conduct enrichment analyses for complex composition, see Figure 4 . We will further collaborate with the ClueGO team to extend the Complex Portal Ontology, and to create new visualizations for Complex Portal data.

With the completion of the draft complexomes for S. cerevisiae and E. coli we are now fully focusing on completing a first draft of the human complexome. We are looking to extend our collaborations with other resources to increase our coverage of other model organisms, a paradigm successfully initiated with Saccharomyces cerevisiae (39) . We are currently focusing on immune system complexes through collaborations with WikiPathways, the COVID-19 Disease Map project and the Cellxgene initiative (45) .

We are developing an import pipeline for heteromeric structures from PDBe which will speed up the manual part of the curation process by populating all standardized, structured fields directly from the PDB files. We are also working with the group of Colin Logie (https://molbio. science.ru.nl/about/molecular-biology/colin-logie/) who is studying the relation between chromatin structure and transcription and is providing extensive lists of important curation targets. The group is developing a pipeline to identify additional potential protein complexes with a role in cotranscription which will be further evaluated by manual curation in the Complex Portal.

We actively encourage curation requests and user feedback which will improve our databases and services. Please contact the Molecular Interaction Team via our support page at https://www.ebi.ac.uk/support/complexportal. Information about curation is provided at https://www.ebi.ac. uk/complexportal/documentation. Extensive training material on how to best use our resource is available at https: //bit.ly/Complex-Portal-training.

The Complex Portal is a community project. Developers can contribute to the code at https://github.com/Complex-Portal/complex-portal-view.

Data can be accessed either via our ftp site (ftp.ebi.ac.uk/ pub/databases/intact/complex/current/) or our REST API (https://www.ebi.ac.uk/intact/complex-ws/).

Lists of putative complexes on our 'watch lists' are available on request (https://www.ebi.ac.uk/support/ complexportal).

Wikidata Integrator python module: https://github.com/ SuLab/WikidataIntegrator. Wikidata bot: https://github.com/lubianat/complex bot.

Analysing the yeast complexome-the complex portal rising to the challenge

CYGD: the comprehensive yeast genome database

ComplexViewer: visualization of curated macromolecular complexes

Lessons from equilibrium statistical physics regarding the assembly of protein complexes

The genetic landscape of a cell

Ancestral reconstruction of protein interaction networks

Production of protein-complex components is stoichiometric and lacks general feedback regulation in eukaryotes

ComplexBrowser: a tool for identification and quantification of protein complexes in large-scale proteomics datasets

Complex Portal 2018: extended content and enhanced visualization tools for macromolecular complexes

The Protein Data Bank Archive

EMDB Web Resources

The reactome pathway knowledgebase

UniProt: the universal protein knowledgebase in 2021

ChEBI in 2016: Improved services and an expanding collection of metabolites

RNAcentral 2021: secondary structure integration, improved sequence search and new member databases

The EcoCyc Database in 2021

Phosphate uptake by the phosphonate transport system PhnCDE

The IMEx coronavirus interactome: an evolving map of Coronaviridae-host molecular interactions

The MIntAct project-IntAct as a common curation platform for 11 molecular interaction databases

2021) wwPDB biocuration: on the front line of structural biology

Evolution of standardization and dissemination of cryo-EM structures and data jointly by the community, PDB, and EMDB

Towards a unified open access dataset of molecular interactions

Gene ontology: tool for the unification of biology. The Gene Ontology Consortium

The Gene Ontology resource: enriching a GOld mine

Building protein-protein and protein-glycosaminoglycan interaction networks using MatrixDB, the extracellular matrix interaction database

2020) SIGNOR 2.0, the SIGnaling Network Open Resource 2.0: 2019 update

WikiPathways: connecting communities

A GO catalogue of human DNA-binding transcription factors

Updates in Rhea: SPARQLing biochemical reaction data

Encompassing new use cases -level 3.0 of the HUPO-PSI format for molecular interactions

Integration of transcription coregulator complexes with sequence-specific DNA-binding factor interactomes

2021) hu.MAP 2.0: integration of over 15,000 proteomic experiments builds a global compendium of human multiprotein assemblies

CORUM: the comprehensive resource of mammalian protein complexes-2019

The BioGRID database: a comprehensive biomedical resource of curated protein, genetic, and chemical interactions

Wikidata: a free collaborative knowledgebase

Wikidata as a knowledge graph for the life sciences

COVID-19 Disease Map, building a computational repository of SARS-CoV-2 virus-host interaction mechanisms

The Semantic Web: ESWC 2017 Satellite Events

Integration of macromolecular complex data into the Saccharomyces Genome Database

The minimum information about a Molecular Interaction CAusal STatement (MI2CAST)

The BridgeDb framework: standardized access to gene, protein and metabolite identifier mapping services

Open Targets Platform: supporting systematic drug-target identification and prioritisation

ClueGO: a Cytoscape plug-in to decipher functionally grouped gene ontology and pathway annotation networks

Cytoscape: a software environment for integrated models of biomolecular interaction networks

Cellxgene: A performant, scalable exploration platform for high dimensional sparse matrices

We would like to acknowledge Andrew Su for providing virtual workspace and staff for collaboration, Sabah Ul-Hasan for proofreading and improving the manuscript and Eliot Ragueneau for advising on aspects of the improvements to ComplexViewer.