Keyword search (4,164 papers available)

"Butler G" Authored Publications:

Title Authors PubMed ID
1 Ion channel classification through machine learning and protein language model embeddings Ghazikhani H; Butler G; 39572876
ENCS
2 SPOT: A machine learning model that predicts specific substrates for transport proteins Kroll A; Niebuhr N; Butler G; Lercher MJ; 39325691
ENCS
3 Comparative genomic analysis of thermophilic fungi reveals convergent evolutionary adaptations and gene losses Steindorff AS; Aguilar-Pontes MV; Robinson AJ; Andreopoulos B; LaButti K; Kuo A; Mondo S; Riley R; Otillar R; Haridas S; Lipzen A; Grimwood J; Schmutz J; Clum A; Reid ID; Moisan MC; Butler G; Nguyen TTM; Dewar K; Conant G; Drula E; Henrissat B; Hansel C; Singer S; Hutchinson MI; de Vries RP; Natvig DO; Powell AJ; Tsang A; Grigoriev IV; 39266695
CSFG
4 Exploiting protein language models for the precise classification of ion channels and ion transporters Ghazikhani H; Butler G; 38656743
CSFG
5 Enhanced identification of membrane transport proteins: a hybrid approach combining ProtBERT-BFD and convolutional neural networks Ghazikhani H; Butler G; 37497772
ENCS
6 Integrative approach for detecting membrane proteins. Alballa M, Butler G 33349234
CSFG
7 BENIN: Biologically enhanced network inference. Wonkap SK, Butler G 32698722
ENCS
8 TooT-T: discrimination of transport proteins from non-transport proteins. Alballa M, Butler G 32321420
CSFG
9 TranCEP: Predicting the substrate class of transmembrane transport proteins using compositional, evolutionary, and positional information. Alballa M, Aplop F, Butler G 31935244
CSFG
10 Analytical and computational approaches to define the Aspergillus niger secretome. Tsang A, Butler G, Powlowski J, Panisko EA, Baker SE 19618504
BIOLOGY
11 SnowyOwl: accurate prediction of fungal genes by using RNA-Seq and homology information to select among ab initio models. Reid I, O'Toole N, Zabaneh O, Nourzadeh R, Dahdouli M, Abdellateef M, Gordon PM, Soh J, Butler G, Sensen CW, Tsang A 24980894
CSFG
12 Machine learning for biomedical literature triage. Almeida H, Meurs MJ, Kosseim L, Butler G, Tsang A 25551575
CSFG
13 mycoCLAP, the database for characterized lignocellulose-active proteins of fungal origin: resource and text mining curation support. Strasser K, McDonnell E, Nyaga C, Wu M, Wu S, Almeida H, Meurs MJ, Kosseim L, Powlowski J, Butler G, Tsang A 25754864
CSFG
14 An Adaptive Defect Weighted Sampling Algorithm to Design Pseudoknotted RNA Secondary Structures. Zandi K, Butler G, Kharma N 27499762
CSFG

 

Title:TooT-T: discrimination of transport proteins from non-transport proteins.
Authors:Alballa MButler G
Link:https://www.ncbi.nlm.nih.gov/pubmed/32321420?dopt=Abstract
DOI:10.1186/s12859-019-3311-6
Publication:BMC bioinformatics
Keywords:Amino acid compositionEnsemble learningTransporter prediction
PMID:32321420 Category:BMC Bioinformatics Date Added:2020-04-24
Dept Affiliation: CSFG
1 Department of Computer Science and Software Engineering, Concordia University, Montréal, Québec, Canada. m_alball@encs.concordia.ca.
2 Department of Computer Science and Software Engineering, Concordia University, Montréal, Québec, Canada.
3 Centre for Structural and Functional Genomics, Concordia University, Montréal, Québec, 24105, Canada.

Description:

TooT-T: discrimination of transport proteins from non-transport proteins.

BMC Bioinformatics. 2020 Apr 23;21(Suppl 3):25

Authors: Alballa M, Butler G

Abstract

BACKGROUND: Membrane transport proteins (transporters) play an essential role in every living cell by transporting hydrophilic molecules across the hydrophobic membranes. While the sequences of many membrane proteins are known, their structure and function is still not well characterized and understood, owing to the immense effort needed to characterize them. Therefore, there is a need for advanced computational techniques takes sequence information alone to distinguish membrane transporter proteins; this can then be used to direct new experiments and give a hint about the function of a protein.

RESULTS: This work proposes an ensemble classifier TooT-T that is trained to optimally combine the predictions from homology annotation transfer and machine-learning methods to determine the final prediction. Experimental results obtained by cross-validation and independent testing show that combining the two approaches is more beneficial than employing only one.

CONCLUSION: The proposed model outperforms all of the state-of-the-art methods that rely on the protein sequence alone, with respect to accuracy and MCC. TooT-T achieved an overall accuracy of 90.07% and 92.22% and an MCC 0.80 and 0.82 with the training and independent datasets, respectively.

PMID: 32321420 [PubMed - in process]




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