{"status":"ok","message-type":"work","message-version":"1.0.0","message":{"indexed":{"date-parts":[[2026,3,17]],"date-time":"2026-03-17T21:42:05Z","timestamp":1773783725601,"version":"3.50.1"},"reference-count":67,"publisher":"Springer Science and Business Media LLC","issue":"1","license":[{"start":{"date-parts":[[2023,8,2]],"date-time":"2023-08-02T00:00:00Z","timestamp":1690934400000},"content-version":"tdm","delay-in-days":0,"URL":"https:\/\/creativecommons.org\/licenses\/by\/4.0"},{"start":{"date-parts":[[2023,8,2]],"date-time":"2023-08-02T00:00:00Z","timestamp":1690934400000},"content-version":"vor","delay-in-days":0,"URL":"https:\/\/creativecommons.org\/licenses\/by\/4.0"}],"content-domain":{"domain":["link.springer.com"],"crossmark-restriction":false},"short-container-title":["BMC Bioinformatics"],"abstract":"Abstract<\/jats:title>\n \n Background<\/jats:title>\n \n Proteins often assemble into higher-order complexes to perform their biological functions. Such protein\u2013protein interactions (PPI) are often experimentally measured for pairs of proteins and summarized in a weighted PPI network, to which community detection algorithms can be applied to define the various higher-order protein complexes. Current methods include unsupervised and supervised approaches, often assuming that protein complexes manifest only as dense subgraphs. Utilizing supervised approaches, the focus is not on\n how<\/jats:italic>\n to find them in a network, but only on learning\n which<\/jats:italic>\n subgraphs correspond to complexes, currently solved using heuristics. However, learning to walk trajectories on a network to identify protein complexes leads naturally to a reinforcement learning (RL) approach, a strategy not extensively explored for community detection. Here, we develop and evaluate a reinforcement learning pipeline for community detection on weighted protein\u2013protein interaction networks to detect new protein complexes. The algorithm is trained to calculate the value of different subgraphs encountered while walking on the network to reconstruct known complexes. A distributed prediction algorithm then scales the RL pipeline to search for novel protein complexes on large PPI networks.\n <\/jats:p>\n <\/jats:sec>\n \n Results<\/jats:title>\n The reinforcement learning pipeline is applied to a human PPI network consisting of 8k proteins and 60k PPI, which results in 1,157 protein complexes. The method demonstrated competitive accuracy with improved speed compared to previous algorithms. We highlight protein complexes such as C4orf19, C18orf21, and KIAA1522 which are currently minimally characterized. Additionally, the results suggest TMC04 be a putative additional subunit of the KICSTOR complex and confirm the involvement of C15orf41 in a higher-order complex with HIRA, CDAN1, ASF1A, and by 3D structural modeling.<\/jats:p>\n <\/jats:sec>\n \n Conclusions<\/jats:title>\n Reinforcement learning offers several distinct advantages for community detection, including scalability and knowledge of the walk trajectories defining those communities. Applied to currently available human protein interaction networks, this method had comparable accuracy with other algorithms and notable savings in computational time, and in turn, led to clear predictions of protein function and interactions for several uncharacterized human proteins.<\/jats:p>\n <\/jats:sec>","DOI":"10.1186\/s12859-023-05425-7","type":"journal-article","created":{"date-parts":[[2023,8,2]],"date-time":"2023-08-02T05:02:28Z","timestamp":1690952548000},"update-policy":"https:\/\/doi.org\/10.1007\/springer_crossmark_policy","source":"Crossref","is-referenced-by-count":20,"title":["Molecular complex detection in protein interaction networks through reinforcement learning"],"prefix":"10.1186","volume":"24","author":[{"ORCID":"https:\/\/orcid.org\/0000-0002-6529-6127","authenticated-orcid":false,"given":"Meghana V.","family":"Palukuri","sequence":"first","affiliation":[]},{"ORCID":"https:\/\/orcid.org\/0000-0002-8367-4144","authenticated-orcid":false,"given":"Ridhi S.","family":"Patil","sequence":"additional","affiliation":[]},{"ORCID":"https:\/\/orcid.org\/0000-0001-8808-180X","authenticated-orcid":false,"given":"Edward M.","family":"Marcotte","sequence":"additional","affiliation":[]}],"member":"297","published-online":{"date-parts":[[2023,8,2]]},"reference":[{"issue":"1","key":"5425_CR1","doi-asserted-by":"publisher","first-page":"e8792","DOI":"10.15252\/msb.20188792","volume":"17","author":"AL Richards","year":"2021","unstructured":"Richards AL, Eckhardt M, Krogan NJ. Mass spectrometry-based protein\u2013protein interaction networks for the study of human diseases. Mol Syst Biol. 2021;17(1):e8792. https:\/\/doi.org\/10.15252\/msb.20188792.","journal-title":"Mol Syst Biol"},{"issue":"1","key":"5425_CR2","doi-asserted-by":"publisher","first-page":"79","DOI":"10.1002\/mas.21574","volume":"38","author":"K Titeca","year":"2019","unstructured":"Titeca K, Lemmens I, Tavernier J, Eyckerman S. Discovering cellular protein\u2013protein interactions: technological strategies and opportunities. Mass Spectrom Rev. 2019;38(1):79\u2013111. https:\/\/doi.org\/10.1002\/mas.21574.","journal-title":"Mass Spectrom Rev"},{"issue":"10","key":"5425_CR3","doi-asserted-by":"publisher","first-page":"825","DOI":"10.1016\/j.tibtech.2016.02.014","volume":"34","author":"AH Smits","year":"2016","unstructured":"Smits AH, Vermeulen M. Characterizing protein\u2013protein interactions using mass spectrometry: challenges and opportunities. Trends Biotechnol. 2016;34(10):825\u201334. https:\/\/doi.org\/10.1016\/j.tibtech.2016.02.014.","journal-title":"Trends Biotechnol"},{"issue":"12","key":"5425_CR4","doi-asserted-by":"publisher","first-page":"848","DOI":"10.15252\/msb.20156351","volume":"11","author":"J Snider","year":"2015","unstructured":"Snider J, Kotlyar M, Saraon P, Yao Z, Jurisica I, Stagljar I. Fundamentals of protein interaction network mapping. Mol Syst Biol. 2015;11(12):848. https:\/\/doi.org\/10.15252\/msb.20156351.","journal-title":"Mol Syst Biol"},{"key":"5425_CR5","doi-asserted-by":"publisher","first-page":"201","DOI":"10.1016\/j.sbi.2017.05.003","volume":"44","author":"TM Cafarelli","year":"2017","unstructured":"Cafarelli TM, Desbuleux A, Wang Y, Choi SG, De Ridder D, Vidal M. Mapping, modeling, and characterization of protein\u2013protein interactions on a proteomic scale. Curr Opin Struct Biol. 2017;44:201\u201310. https:\/\/doi.org\/10.1016\/j.sbi.2017.05.003.","journal-title":"Curr Opin Struct Biol"},{"issue":"6","key":"5425_CR6","doi-asserted-by":"publisher","first-page":"932","DOI":"10.15252\/msb.20167490","volume":"13","author":"K Drew","year":"2017","unstructured":"Drew K, et al. Integration of over 9000 mass spectrometry experiments builds a global map of human protein complexes. Mol Syst Biol. 2017;13(6):932. https:\/\/doi.org\/10.15252\/msb.20167490.","journal-title":"Mol Syst Biol"},{"issue":"5","key":"5425_CR7","doi-asserted-by":"publisher","first-page":"e10016","DOI":"10.15252\/msb.202010016","volume":"17","author":"K Drew","year":"2021","unstructured":"Drew K, Wallingford JB, Marcotte EM. huMAP 2.0: integration of over 15,000 proteomic experiments builds a global compendium of human multiprotein assemblies. Mol Syst Biol. 2021;17(5):e10016. https:\/\/doi.org\/10.15252\/msb.202010016.","journal-title":"Mol Syst Biol"},{"issue":"5","key":"5425_CR8","doi-asserted-by":"publisher","first-page":"787","DOI":"10.1016\/j.cell.2011.05.006","volume":"145","author":"A Malovannaya","year":"2011","unstructured":"Malovannaya A, et al. Analysis of the human endogenous coregulator complexome. Cell. 2011;145(5):787\u201399. https:\/\/doi.org\/10.1016\/j.cell.2011.05.006.","journal-title":"Cell"},{"issue":"3","key":"5425_CR9","doi-asserted-by":"publisher","first-page":"712","DOI":"10.1016\/j.cell.2015.09.053","volume":"163","author":"MY Hein","year":"2015","unstructured":"Hein MY, et al. A human interactome in three quantitative dimensions organized by stoichiometries and abundances. Cell. 2015;163(3):712\u201323. https:\/\/doi.org\/10.1016\/j.cell.2015.09.053.","journal-title":"Cell"},{"issue":"2","key":"5425_CR10","doi-asserted-by":"publisher","first-page":"425","DOI":"10.1016\/j.cell.2015.06.043","volume":"162","author":"EL Huttlin","year":"2015","unstructured":"Huttlin EL, et al. The BioPlex network: a systematic exploration of the human interactome. Cell. 2015;162(2):425\u201340. https:\/\/doi.org\/10.1016\/j.cell.2015.06.043.","journal-title":"Cell"},{"issue":"7655","key":"5425_CR11","doi-asserted-by":"publisher","first-page":"7655","DOI":"10.1038\/nature22366","volume":"545","author":"EL Huttlin","year":"2017","unstructured":"Huttlin EL, et al. Architecture of the human interactome defines protein communities and disease networks. Nature. 2017;545(7655):7655. https:\/\/doi.org\/10.1038\/nature22366.","journal-title":"Nature"},{"issue":"7569","key":"5425_CR12","doi-asserted-by":"publisher","first-page":"7569","DOI":"10.1038\/nature14877","volume":"525","author":"C Wan","year":"2015","unstructured":"Wan C, et al. Panorama of ancient metazoan macromolecular complexes. Nature. 2015;525(7569):7569. https:\/\/doi.org\/10.1038\/nature14877.","journal-title":"Nature"},{"issue":"12","key":"5425_CR13","doi-asserted-by":"publisher","first-page":"3851","DOI":"10.1074\/mcp.M113.032367","volume":"12","author":"KJ Kirkwood","year":"2013","unstructured":"Kirkwood KJ, Ahmad Y, Larance M, Lamond AI. Characterization of native protein complexes and protein isoform variation using size-fractionation-based quantitative proteomics. Mol Cell Proteom MCP. 2013;12(12):3851\u201373. https:\/\/doi.org\/10.1074\/mcp.M113.032367.","journal-title":"Mol Cell Proteom MCP"},{"issue":"9","key":"5425_CR14","doi-asserted-by":"publisher","first-page":"907","DOI":"10.1038\/nmeth.2131","volume":"9","author":"AR Kristensen","year":"2012","unstructured":"Kristensen AR, Gsponer J, Foster LJ. A high-throughput approach for measuring temporal changes in the interactome. Nat Methods. 2012;9(9):907\u20139. https:\/\/doi.org\/10.1038\/nmeth.2131.","journal-title":"Nat Methods"},{"issue":"5","key":"5425_CR15","doi-asserted-by":"publisher","first-page":"1068","DOI":"10.1016\/j.cell.2012.08.011","volume":"150","author":"PC Havugimana","year":"2012","unstructured":"Havugimana PC, et al. A census of human soluble protein complexes. Cell. 2012;150(5):1068\u201381. https:\/\/doi.org\/10.1016\/j.cell.2012.08.011.","journal-title":"Cell"},{"key":"5425_CR16","doi-asserted-by":"publisher","first-page":"87","DOI":"10.1016\/j.jnca.2018.02.011","volume":"108","author":"MA Javed","year":"2018","unstructured":"Javed MA, Younis MS, Latif S, Qadir J, Baig A. Community detection in networks: a multidisciplinary review. J Netw Comput Appl. 2018;108:87\u2013111. https:\/\/doi.org\/10.1016\/j.jnca.2018.02.011.","journal-title":"J Netw Comput Appl"},{"issue":"1","key":"5425_CR17","doi-asserted-by":"publisher","first-page":"2","DOI":"10.1186\/1471-2105-4-2","volume":"4","author":"GD Bader","year":"2003","unstructured":"Bader GD, Hogue CW. An automated method for finding molecular complexes in large protein interaction networks. BMC Bioinform. 2003;4(1):2. https:\/\/doi.org\/10.1186\/1471-2105-4-2.","journal-title":"BMC Bioinform"},{"issue":"15","key":"5425_CR18","doi-asserted-by":"publisher","first-page":"1891","DOI":"10.1093\/bioinformatics\/btp311","volume":"25","author":"G Liu","year":"2009","unstructured":"Liu G, Wong L, Chua HN. Complex discovery from weighted PPI networks. Bioinformatics. 2009;25(15):1891\u20137. https:\/\/doi.org\/10.1093\/bioinformatics\/btp311.","journal-title":"Bioinformatics"},{"issue":"1","key":"5425_CR19","doi-asserted-by":"publisher","first-page":"169","DOI":"10.1186\/1471-2105-10-169","volume":"10","author":"M Wu","year":"2009","unstructured":"Wu M, Li X, Kwoh C-K, Ng S-K. A core-attachment based method to detect protein complexes in PPI networks. BMC Bioinform. 2009;10(1):169. https:\/\/doi.org\/10.1186\/1471-2105-10-169.","journal-title":"BMC Bioinform"},{"issue":"5","key":"5425_CR20","doi-asserted-by":"publisher","first-page":"5","DOI":"10.1038\/nmeth.1938","volume":"9","author":"T Nepusz","year":"2012","unstructured":"Nepusz T, Yu H, Paccanaro A. Detecting overlapping protein complexes in protein-protein interaction networks. Nat Methods. 2012;9(5):5. https:\/\/doi.org\/10.1038\/nmeth.1938.","journal-title":"Nat Methods"},{"key":"5425_CR21","doi-asserted-by":"publisher","unstructured":"Lee C, Reid F, McDaid A, Hurley N. Detecting highly overlapping community structure by greedy clique expansion. 2010. arXiv: arXiv:1002.1827, https:\/\/doi.org\/10.48550\/arXiv.1002.1827.","DOI":"10.48550\/arXiv.1002.1827"},{"key":"5425_CR22","doi-asserted-by":"publisher","DOI":"10.1109\/TFUZZ.2023.3259726","author":"L Hu","year":"2023","unstructured":"Hu L, Yang Y, Tang Z, He Y, Luo X. FCAN-MOPSO: an improved fuzzy-based graph clustering algorithm for complex networks with multi-objective particle swarm optimization. IEEE Trans Fuzzy Syst. 2023. https:\/\/doi.org\/10.1109\/TFUZZ.2023.3259726.","journal-title":"IEEE Trans Fuzzy Syst"},{"issue":"6","key":"5425_CR23","doi-asserted-by":"publisher","first-page":"1922","DOI":"10.1109\/TCBB.2018.2844256","volume":"16","author":"L Hu","year":"2019","unstructured":"Hu L, Yuan X, Liu X, Xiong S, Luo X. Efficiently detecting protein complexes from protein interaction networks via alternating direction method of multipliers. IEEE\/ACM Trans Comput Biol Bioinform. 2019;16(6):1922\u201335. https:\/\/doi.org\/10.1109\/TCBB.2018.2844256.","journal-title":"IEEE\/ACM Trans Comput Biol Bioinform"},{"issue":"4","key":"5425_CR24","doi-asserted-by":"publisher","first-page":"542","DOI":"10.1093\/bioinformatics\/btaa775","volume":"37","author":"L Hu","year":"2021","unstructured":"Hu L, Zhang J, Pan X, Yan H, You Z-H. HiSCF: leveraging higher-order structures for clustering analysis in biological networks. Bioinformatics. 2021;37(4):542\u201350. https:\/\/doi.org\/10.1093\/bioinformatics\/btaa775.","journal-title":"Bioinformatics"},{"issue":"1","key":"5425_CR25","doi-asserted-by":"publisher","first-page":"73","DOI":"10.1093\/bioinformatics\/btaa1089","volume":"37","author":"S Omranian","year":"2021","unstructured":"Omranian S, Angeleska A, Nikoloski Z. PC2P: parameter-free network-based prediction of protein complexes. Bioinformatics. 2021;37(1):73\u201381. https:\/\/doi.org\/10.1093\/bioinformatics\/btaa1089.","journal-title":"Bioinformatics"},{"key":"5425_CR26","doi-asserted-by":"publisher","first-page":"414","DOI":"10.1186\/s12859-022-04923-4","volume":"23","author":"R Wang","year":"2022","unstructured":"Wang R, Wang C, Ma H. Detecting protein complexes with multiple properties by an adaptive harmony search algorithm. BMC Bioinform. 2022;23:414. https:\/\/doi.org\/10.1186\/s12859-022-04923-4.","journal-title":"BMC Bioinform"},{"issue":"3","key":"5425_CR27","doi-asserted-by":"publisher","first-page":"1592","DOI":"10.1109\/TCBB.2021.3050102","volume":"19","author":"X Meng","year":"2022","unstructured":"Meng X, Xiang J, Zheng R, Wu F-X, Li M. DPCMNE: detecting protein complexes from protein-protein interaction networks via multi-level network embedding. IEEE ACM Trans Comput Biol Bioinform. 2022;19(3):1592\u2013602. https:\/\/doi.org\/10.1109\/TCBB.2021.3050102.","journal-title":"IEEE ACM Trans Comput Biol Bioinform"},{"issue":"13","key":"5425_CR28","doi-asserted-by":"publisher","first-page":"i250","DOI":"10.1093\/bioinformatics\/btn164","volume":"24","author":"Y Qi","year":"2008","unstructured":"Qi Y, Balem F, Faloutsos C, Klein-Seetharaman J, Bar-Joseph Z. Protein complex identification by supervised graph local clustering. Bioinformatics. 2008;24(13):i250\u201368. https:\/\/doi.org\/10.1093\/bioinformatics\/btn164.","journal-title":"Bioinformatics"},{"issue":"3","key":"5425_CR29","doi-asserted-by":"publisher","first-page":"e0194124","DOI":"10.1371\/journal.pone.0194124","volume":"13","author":"Y Dong","year":"2018","unstructured":"Dong Y, Sun Y, Qin C. Predicting protein complexes using a supervised learning method combined with local structural information. PLoS ONE. 2018;13(3):e0194124. https:\/\/doi.org\/10.1371\/journal.pone.0194124.","journal-title":"PLoS ONE"},{"issue":"12","key":"5425_CR30","doi-asserted-by":"publisher","first-page":"e0262056","DOI":"10.1371\/journal.pone.0262056","volume":"16","author":"MV Palukuri","year":"2021","unstructured":"Palukuri MV, Marcotte EM. Super.Complex: a supervised machine learning pipeline for molecular complex detection in protein-interaction networks. PLoS ONE. 2021;16(12):e0262056. https:\/\/doi.org\/10.1371\/journal.pone.0262056.","journal-title":"PLoS ONE"},{"key":"5425_CR31","doi-asserted-by":"publisher","unstructured":"Paim EC, Bazzan ALC, Chira C. Detecting communities in networks: a decentralized approach based on multiagent reinforcement learning. In 2020 IEEE symposium series on computational intelligence (SSCI); 2020. pp. 2225\u20132232. doi: https:\/\/doi.org\/10.1109\/SSCI47803.2020.9308197.","DOI":"10.1109\/SSCI47803.2020.9308197"},{"issue":"1","key":"5425_CR32","doi-asserted-by":"publisher","first-page":"1","DOI":"10.1038\/s41467-022-33729-4","volume":"13","author":"P Bryant","year":"2022","unstructured":"Bryant P, Pozzati G, Zhu W, Shenoy A, Kundrotas P, Elofsson A. Predicting the structure of large protein complexes using AlphaFold and Monte Carlo tree search. Nat Commun. 2022;13(1):1. https:\/\/doi.org\/10.1038\/s41467-022-33729-4.","journal-title":"Nat Commun"},{"issue":"2","key":"5425_CR33","doi-asserted-by":"publisher","first-page":"2","DOI":"10.1038\/s41594-022-00910-8","volume":"30","author":"DF Burke","year":"2023","unstructured":"Burke DF, et al. Towards a structurally resolved human protein interaction network. Nat Struct Mol Biol. 2023;30(2):2. https:\/\/doi.org\/10.1038\/s41594-022-00910-8.","journal-title":"Nat Struct Mol Biol"},{"issue":"D1","key":"5425_CR34","doi-asserted-by":"publisher","first-page":"D559","DOI":"10.1093\/nar\/gky973","volume":"47","author":"M Giurgiu","year":"2019","unstructured":"Giurgiu M, et al. CORUM: the comprehensive resource of mammalian protein complexes\u20142019. Nucleic Acids Res. 2019;47(D1):D559\u201363. https:\/\/doi.org\/10.1093\/nar\/gky973.","journal-title":"Nucleic Acids Res"},{"issue":"6","key":"5425_CR35","doi-asserted-by":"publisher","first-page":"875","DOI":"10.1016\/j.cmet.2016.08.017","volume":"24","author":"JD Arroyo","year":"2016","unstructured":"Arroyo JD, et al. A genome-wide CRISPR death screen identifies genes essential for oxidative phosphorylation. Cell Metab. 2016;24(6):875\u201385. https:\/\/doi.org\/10.1016\/j.cmet.2016.08.017.","journal-title":"Cell Metab"},{"issue":"7645","key":"5425_CR36","doi-asserted-by":"publisher","first-page":"438","DOI":"10.1038\/nature21423","volume":"543","author":"RL Wolfson","year":"2017","unstructured":"Wolfson RL, et al. KICSTOR recruits GATOR1 to the lysosome and is necessary for nutrients to regulate mTORC1. Nature. 2017;543(7645):438\u201342. https:\/\/doi.org\/10.1038\/nature21423.","journal-title":"Nature"},{"issue":"1","key":"5425_CR37","doi-asserted-by":"publisher","first-page":"296","DOI":"10.1006\/bbrc.1999.0894","volume":"260","author":"S Suetsugu","year":"1999","unstructured":"Suetsugu S, Miki H, Takenawa T. Identification of two human WAVE\/SCAR homologues as general actin regulatory molecules which associate with the Arp2\/3 complex. Biochem Biophys Res Commun. 1999;260(1):296\u2013302. https:\/\/doi.org\/10.1006\/bbrc.1999.0894.","journal-title":"Biochem Biophys Res Commun"},{"issue":"2","key":"5425_CR38","doi-asserted-by":"publisher","first-page":"e38","DOI":"10.1371\/journal.pbio.0040038","volume":"4","author":"OD Weiner","year":"2006","unstructured":"Weiner OD, et al. Hem-1 complexes are essential for Rac activation, actin polymerization, and myosin regulation during neutrophil chemotaxis. PLoS Biol. 2006;4(2):e38. https:\/\/doi.org\/10.1371\/journal.pbio.0040038.","journal-title":"PLoS Biol"},{"issue":"6585","key":"5425_CR39","doi-asserted-by":"publisher","first-page":"eabi6983","DOI":"10.1126\/science.abi6983","volume":"375","author":"NH Cho","year":"2022","unstructured":"Cho NH, et al. OpenCell: endogenous tagging for the cartography of human cellular organization. Science. 2022;375(6585):eabi6983. https:\/\/doi.org\/10.1126\/science.abi6983.","journal-title":"Science"},{"issue":"7","key":"5425_CR40","doi-asserted-by":"publisher","first-page":"774","DOI":"10.1038\/s41592-022-01454-x","volume":"19","author":"G Kustatscher","year":"2022","unstructured":"Kustatscher G, et al. Understudied proteins: opportunities and challenges for functional proteomics. Nat Methods. 2022;19(7):774\u20139. https:\/\/doi.org\/10.1038\/s41592-022-01454-x.","journal-title":"Nat Methods"},{"issue":"D1","key":"5425_CR41","doi-asserted-by":"publisher","first-page":"D480","DOI":"10.1093\/nar\/gkaa1100","volume":"49","author":"UniProt Consortium","year":"2021","unstructured":"UniProt Consortium. UniProt: the universal protein knowledgebase in 2021. Nucleic Acids Res. 2021;49(D1):D480\u20139. https:\/\/doi.org\/10.1093\/nar\/gkaa1100.","journal-title":"Nucleic Acids Res"},{"key":"5425_CR42","unstructured":"\u201cC4orf19 expression in human.\u201d https:\/\/bgee.org\/gene\/ENSG00000154274. Accessed 20 May 2022."},{"issue":"6340","key":"5425_CR43","doi-asserted-by":"publisher","first-page":"l3321","DOI":"10.1126\/science.aal3321","volume":"356","author":"PJ Thul","year":"2017","unstructured":"Thul PJ, et al. A subcellular map of the human proteome. Science. 2017;356(6340):l3321. https:\/\/doi.org\/10.1126\/science.aal3321.","journal-title":"Science"},{"key":"5425_CR44","unstructured":"\u201cTissue expression of C4orf19-Summary-The Human Protein Atlas.\u201d https:\/\/www.proteinatlas.org\/ENSG00000154274-C4orf19\/tissue. Accessed 16 June 2022."},{"issue":"4","key":"5425_CR45","doi-asserted-by":"publisher","first-page":"1145","DOI":"10.7150\/jca.63635","volume":"13","author":"W Wang","year":"2022","unstructured":"Wang W, et al. Down-regulated C4orf19 confers poor prognosis in colon adenocarcinoma identified by gene co-expression network. J Cancer. 2022;13(4):1145\u201359. https:\/\/doi.org\/10.7150\/jca.63635.","journal-title":"J Cancer"},{"issue":"8","key":"5425_CR46","doi-asserted-by":"publisher","first-page":"2795","DOI":"10.1172\/JCI39679","volume":"120","author":"X Zheng","year":"2010","unstructured":"Zheng X, et al. CCM3 signaling through sterile 20-like kinases plays an essential role during zebrafish cardiovascular development and cerebral cavernous malformations. J Clin Invest. 2010;120(8):2795\u2013804. https:\/\/doi.org\/10.1172\/JCI39679.","journal-title":"J Clin Invest"},{"issue":"1","key":"5425_CR47","doi-asserted-by":"publisher","first-page":"157","DOI":"10.1074\/mcp.M800266-MCP200","volume":"8","author":"M Goudreault","year":"2009","unstructured":"Goudreault M, et al. A PP2A phosphatase high density interaction network identifies a novel striatin-interacting phosphatase and kinase complex linked to the cerebral cavernous malformation 3 (CCM3) protein. Mol Cell Proteom MCP. 2009;8(1):157\u201371. https:\/\/doi.org\/10.1074\/mcp.M800266-MCP200.","journal-title":"Mol Cell Proteom MCP"},{"issue":"12","key":"5425_CR48","doi-asserted-by":"publisher","first-page":"e142838","DOI":"10.1172\/jci.insight.142838","volume":"6","author":"R Wang","year":"2021","unstructured":"Wang R, et al. Pdcd10-Stk24\/25 complex controls kidney water reabsorption by regulating Aqp2 membrane targeting. JCI Insight. 2021;6(12):e142838. https:\/\/doi.org\/10.1172\/jci.insight.142838.","journal-title":"JCI Insight"},{"issue":"24","key":"5425_CR49","doi-asserted-by":"publisher","first-page":"11905","DOI":"10.18632\/aging.102505","volume":"11","author":"M Xiong","year":"2019","unstructured":"Xiong M, et al. KIF20A promotes cellular malignant behavior and enhances resistance to chemotherapy in colorectal cancer through regulation of the JAK\/STAT3 signaling pathway. Aging. 2019;11(24):11905\u201321. https:\/\/doi.org\/10.18632\/aging.102505.","journal-title":"Aging"},{"issue":"1","key":"5425_CR50","doi-asserted-by":"publisher","first-page":"91","DOI":"10.1016\/j.jss.2015.03.070","volume":"197","author":"D Stangel","year":"2015","unstructured":"Stangel D, et al. Kif20a inhibition reduces migration and invasion of pancreatic cancer cells. J Surg Res. 2015;197(1):91\u2013100. https:\/\/doi.org\/10.1016\/j.jss.2015.03.070.","journal-title":"J Surg Res"},{"key":"5425_CR51","unstructured":"\u201cPDCD10 programmed cell death 10 [Homo sapiens (human)]-Gene-NCBI.\u201d https:\/\/www.ncbi.nlm.nih.gov\/gene\/11235. Accessed 31 May 2022."},{"issue":"1","key":"5425_CR52","doi-asserted-by":"publisher","first-page":"213","DOI":"10.7150\/jca.35821","volume":"11","author":"H-P Hsu","year":"2020","unstructured":"Hsu H-P, Wang C-Y, Hsieh P-Y, Fang J-H, Chen Y-L. Knockdown of serine\/threonine-protein kinase 24 promotes tumorigenesis and myeloid-derived suppressor cell expansion in an orthotopic immunocompetent gastric cancer animal model. J Cancer. 2020;11(1):213\u201328. https:\/\/doi.org\/10.7150\/jca.35821.","journal-title":"J Cancer"},{"issue":"1","key":"5425_CR53","doi-asserted-by":"publisher","first-page":"225","DOI":"10.1186\/s12859-019-2800-y","volume":"20","author":"L Liang","year":"2019","unstructured":"Liang L, Chen V, Zhu K, Fan X, Lu X, Lu S. Integrating data and knowledge to identify functional modules of genes: a multilayer approach. BMC Bioinform. 2019;20(1):225. https:\/\/doi.org\/10.1186\/s12859-019-2800-y.","journal-title":"BMC Bioinform"},{"issue":"10","key":"5425_CR54","doi-asserted-by":"publisher","first-page":"1893","DOI":"10.1042\/BCJ20190944","volume":"477","author":"M Shroff","year":"2020","unstructured":"Shroff M, Knebel A, Toth R, Rouse J. A complex comprising C15ORF41 and Codanin-1: the products of two genes mutated in congenital dyserythropoietic anaemia type I (CDA-I). Biochem J. 2020;477(10):1893\u2013905. https:\/\/doi.org\/10.1042\/BCJ20190944.","journal-title":"Biochem J"},{"key":"5425_CR55","doi-asserted-by":"publisher","DOI":"10.3389\/fphys.2019.00621","author":"R Russo","year":"2019","unstructured":"Russo R, et al. Characterization of two cases of congenital dyserythropoietic anemia type I shed light on the uncharacterized C15orf41 protein. Front Physiol. 2019. https:\/\/doi.org\/10.3389\/fphys.2019.00621.","journal-title":"Front Physiol"},{"issue":"10","key":"5425_CR56","doi-asserted-by":"publisher","first-page":"921","DOI":"10.1038\/nsmb1147","volume":"13","author":"Y Tang","year":"2006","unstructured":"Tang Y, et al. Structure of a human ASF1a\/HIRA complex and insights into specificity of histone chaperone complex assembly. Nat Struct Mol Biol. 2006;13(10):921\u20139. https:\/\/doi.org\/10.1038\/nsmb1147.","journal-title":"Nat Struct Mol Biol"},{"issue":"19","key":"5425_CR57","doi-asserted-by":"publisher","first-page":"4107","DOI":"10.1128\/MCB.05546-11","volume":"31","author":"TS Rai","year":"2011","unstructured":"Rai TS, et al. Human CABIN1 Is a functional member of the human HIRA\/UBN1\/ASF1a histone H3.3 chaperone complex. Mol Cell Biol. 2011;31(19):4107\u201318. https:\/\/doi.org\/10.1128\/MCB.05546-11.","journal-title":"Mol Cell Biol"},{"issue":"1","key":"5425_CR58","doi-asserted-by":"publisher","first-page":"18","DOI":"10.1186\/s12860-020-00258-1","volume":"21","author":"G Swickley","year":"2020","unstructured":"Swickley G, et al. Characterization of the interactions between Codanin-1 and C15Orf41, two proteins implicated in congenital dyserythropoietic anemia type I disease. BMC Mol Cell Biol. 2020;21(1):18. https:\/\/doi.org\/10.1186\/s12860-020-00258-1.","journal-title":"BMC Mol Cell Biol"},{"key":"5425_CR59","doi-asserted-by":"publisher","DOI":"10.1101\/2021.10.04.463034","author":"R Evans","year":"2021","unstructured":"Evans R, et al. Protein complex prediction with AlphaFold-Multimer. bioRxiv. 2021. https:\/\/doi.org\/10.1101\/2021.10.04.463034.","journal-title":"bioRxiv"},{"issue":"6","key":"5425_CR60","doi-asserted-by":"publisher","first-page":"679","DOI":"10.1038\/s41592-022-01488-1","volume":"19","author":"M Mirdita","year":"2022","unstructured":"Mirdita M, Sch\u00fctze K, Moriwaki Y, Heo L, Ovchinnikov S, Steinegger M. ColabFold: making protein folding accessible to all. Nat Methods. 2022;19(6):679\u201382. https:\/\/doi.org\/10.1038\/s41592-022-01488-1.","journal-title":"Nat Methods"},{"issue":"1","key":"5425_CR61","doi-asserted-by":"publisher","first-page":"110","DOI":"10.1016\/j.devcel.2009.04.016","volume":"17","author":"T Wassmer","year":"2009","unstructured":"Wassmer T, et al. The retromer coat complex coordinates endosomal sorting and dynein-mediated transport, with carrier recognition by the trans-Golgi network. Dev Cell. 2009;17(1):110\u201322. https:\/\/doi.org\/10.1016\/j.devcel.2009.04.016.","journal-title":"Dev Cell"},{"key":"5425_CR62","unstructured":"\u201cSubcellular-C11orf42-The Human Protein Atlas.\u201d https:\/\/www.proteinatlas.org\/ENSG00000180878-C11orf42\/subcellular. Accessed 16 June 2022."},{"key":"5425_CR63","unstructured":"\u201cSubcellular-SNX5-The Human Protein Atlas.\u201d https:\/\/www.proteinatlas.org\/ENSG00000089006-SNX5\/subcellular. Accessed 16 June 2022."},{"key":"5425_CR64","unstructured":"\u201cSubcellular-VPS29-The Human Protein Atlas.\u201d https:\/\/www.proteinatlas.org\/ENSG00000111237-VPS29\/subcellular. Accessed 16 June 2022."},{"key":"5425_CR65","unstructured":"\u201cSubcellular-SNX2-The Human Protein Atlas.\u201d https:\/\/www.proteinatlas.org\/ENSG00000205302-SNX2\/subcellular. Accessed 16 June 2022."},{"key":"5425_CR66","unstructured":"\u201cSubcellular-SNX1-The Human Protein Atlas.\u201d https:\/\/www.proteinatlas.org\/ENSG00000028528-SNX1\/subcellular. Accessed 16 June 2022."},{"issue":"7816","key":"5425_CR67","doi-asserted-by":"publisher","first-page":"459","DOI":"10.1038\/s41586-020-2286-9","volume":"583","author":"DE Gordon","year":"2020","unstructured":"Gordon DE, et al. A SARS-CoV-2 protein interaction map reveals targets for drug repurposing. Nature. 2020;583(7816):459\u201368. https:\/\/doi.org\/10.1038\/s41586-020-2286-9.","journal-title":"Nature"}],"container-title":["BMC Bioinformatics"],"original-title":[],"language":"en","link":[{"URL":"https:\/\/link.springer.com\/content\/pdf\/10.1186\/s12859-023-05425-7.pdf","content-type":"application\/pdf","content-version":"vor","intended-application":"text-mining"},{"URL":"https:\/\/link.springer.com\/article\/10.1186\/s12859-023-05425-7\/fulltext.html","content-type":"text\/html","content-version":"vor","intended-application":"text-mining"},{"URL":"https:\/\/link.springer.com\/content\/pdf\/10.1186\/s12859-023-05425-7.pdf","content-type":"application\/pdf","content-version":"vor","intended-application":"similarity-checking"}],"deposited":{"date-parts":[[2023,8,2]],"date-time":"2023-08-02T05:03:22Z","timestamp":1690952602000},"score":1,"resource":{"primary":{"URL":"https:\/\/bmcbioinformatics.biomedcentral.com\/articles\/10.1186\/s12859-023-05425-7"}},"subtitle":[],"short-title":[],"issued":{"date-parts":[[2023,8,2]]},"references-count":67,"journal-issue":{"issue":"1","published-online":{"date-parts":[[2023,12]]}},"alternative-id":["5425"],"URL":"https:\/\/doi.org\/10.1186\/s12859-023-05425-7","relation":{"has-preprint":[{"id-type":"doi","id":"10.1101\/2022.06.20.496772","asserted-by":"object"}]},"ISSN":["1471-2105"],"issn-type":[{"value":"1471-2105","type":"electronic"}],"subject":[],"published":{"date-parts":[[2023,8,2]]},"assertion":[{"value":"5 February 2023","order":1,"name":"received","label":"Received","group":{"name":"ArticleHistory","label":"Article History"}},{"value":"20 July 2023","order":2,"name":"accepted","label":"Accepted","group":{"name":"ArticleHistory","label":"Article History"}},{"value":"2 August 2023","order":3,"name":"first_online","label":"First Online","group":{"name":"ArticleHistory","label":"Article History"}},{"order":1,"name":"Ethics","group":{"name":"EthicsHeading","label":"Declarations"}},{"value":"Not applicable.","order":2,"name":"Ethics","group":{"name":"EthicsHeading","label":"Ethics approval and consent to participate"}},{"value":"Not applicable.","order":3,"name":"Ethics","group":{"name":"EthicsHeading","label":"Consent for publication"}},{"value":"The authors declare no competing of interest.","order":4,"name":"Ethics","group":{"name":"EthicsHeading","label":"Competing interests"}}],"article-number":"306"}}