Journal of Jilin University(Engineering and Technology Edition) ›› 2022, Vol. 52 ›› Issue (1): 187-194.doi: 10.13229/j.cnki.jdxbgxb20200723

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Prediction of protein-ATP binding site based on deep learning

Gui-xia LIU1,2(),Zhi-yao PEI1,2,Jia-zhi SONG1,2   

  1. 1.College of Computer Science and Technology,Jilin University,Changchun 130012,China
    2.Key Laboratory of Symbol Computation and Knowledge Engineering of Ministry Education,Jilin University,Changchun 130012,China
  • Received:2020-12-16 Online:2022-01-01 Published:2022-01-14

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Abstract:

Accurately identifying protein-ATP binding site is important for the research of protein function and the disease drug design. In order to improve the prediction accuracy of identifying protein-ATP binding site, first, a deep neural network model, Inceptiobase, based on inception architecture was proposed. Then, the network model and training strategy were optimized and improved through large number of experimental tests, and an upgraded deep neural network model, Inception_evolution, was proposed. Through two sets of data sets tested on the model, the AUCs are 0.885 and 0.918, respectively, which are better than other comparative machine learning methods. The experimental results show that the deep learning method can be applied to the protein-ATP binding site prediction problem, and the model Inception_evolution can predict the protein-ATP binding site more accurately.

Key words: bioinformatics, protein-ATP binding site prediction, feature extraction, deep learning, Inception neural network model

CLC Number: 

  • TP399

Table 1

Definition of parameters in formula"

实际情况预测结果
10

1

0

TPFN
FPTN

Fig.1

Inception module"

Fig.2

Inception_base module"

Fig.3

Inception_base network mode"

Table 2

Inc_base performance on ATP-227"

方 法ACCSESPMCCAUC
CT0.9670.1890.9950.324-
ATPint0.6550.5120.6600.0660.606
ATPsite0.9690.3670.9910.4510.868
NsitePred0.9670.4600.9850.4760.875
TATPsite0.9720.4580.9910.5300.882
TATP0.9690.4890.9890.5420.912
TNUCs0.9750.5160.9920.584-
Inc_base0.9680.6250.9790.5480.906

Table 3

Inc_base performance on ATP-388"

方 法ACCSESPMCCAUC
CT0.9640.2390.9980.451-
NsitePred0.9540.4670.9770.4560.852
TATPsite0.9680.4130.9950.5590.853
TNUCs0.9720.4690.9970.6270.856
ATPseq0.9720.5450.9930.6390.878
Inc_base0.9760.4320.9890.5770.882

Fig. 4

Inception_evo1 module"

Fig.5

Inception_evo2 module"

Fig. 6

Inception_evo1 network model"

Table 4

Inc_evo performance on ATP-227"

方 法ACCSESPMCCAUC
CT0.9670.1890.9950.324-
ATPint0.6550.5120.6600.0660.606
ATPsite0.9690.3670.9910.4510.868
NsitePred0.9670.4600.9850.4760.875
TATPsite0.9720.4580.9910.5300.882
TATP0.9690.4890.9890.5420.912
TNUCs0.9750.5160.9920.584-
Inc_evo0.9810.5360.9890.5690.918

Table 5

Inc_evo performance on ATP-388"

方 法ACCSESPMCCAUC
CT0.9640.2390.9980.451-
NsitePred0.9540.4670.9770.4560.852
TATPsite0.9680.4130.9950.5590.853
TNUCs0.9720.4690.9970.6270.856
ATPseq0.9720.5450.9930.6390.878
Inc_evo0.9840.4520.9950.5880.885
1 Bain F E, Fischer L A, Chen R, et al. Chapter seventeen-single-molecule analysis of replication protein A⁃DNA interactions[J]. Methods in Enzymology, 2018, 600: 439-461.
2 Raphael T, Timo M, Schroda M, et al. ATP-dependent molecular chaperones in plastids — more complex than expected[J]. Biochimica et Biophysica Acta Bioenergetics, 2015, 1847(9):872-888.
3 Gerwert K, Freier E, Wolf S. The role of protein-bound water molecules in microbial rhodopsins[J]. Biochimica Et Biophysica Acta, 2014, 1837(5): 606-613.
4 Qi W, Zhen L P, Yang Z, et al. COACH-D: improved protein⁃ligand binding sites prediction with refined ligand-binding poses through molecular docking[J]. Nuclc Acids Research,2018,46(W1):438-442.
5 Baldassi C, Zamparo M, Feinauer C, et al. Fast and accurate multivariate gaussian modeling of protein families: predicting residue contacts and protein-interaction partners[J]. PLoS ONE, 2014, 9(3): No. e92721.
6 冉军舰. 赵瑞香 . 梁新红 ,等.基于蛋白互作网络解析甘薯渣中去氢表雄酮的生物作用机制[J]. 扬州大学学报:农业与生命科学版,2019, 40(5): 33-38.
Ran Jun-jian, Zhao Rui-xiang, Liang Xin-hong, et al. Biological mechanism analysis of DHEA from sweet potato residue based on protein-protein interaction network[J]. Journal of Yangzhou University: Agricultural and Life Science Edition, 2019, 40(5): 33-38.
7 Carrano A, Snkhchyan H, Kooij G, et al. ATP-binding cassette transporters P-glycoprotein and breast cancer related protein are reduced in capillary cerebral amyloid angiopathy[J]. Neurobiology of Aging, 2014, 35(3): 565-575.
8 Christian S, Christoph W, Walter M. ATP- and ADP-dnaA protein, a molecular switch in gene regulation[J]. Embo Journal, 1999, 18(21): 6169-6176.
9 Chauhan J S, Mishra N K, Raghava G P. Identification of ATP binding residues of a protein from its primary sequence[J]. BMC Bioinformatics, 2009, 10(1): 434.
10 Chen K, Mizianty M J, Kurgan L. ATPsite: sequence-based prediction of ATP-binding residues[J]. Proteome Science, 2011, 9(S1):235-242.
11 Kurgan L, Chen K, Mizianty M J. Prediction and analysis of nucleotide binding residues using sequence and sequence-derived structural descriptors[J]. Bioinformatics, 2011, 28(3):331-341.
12 Yu Dong-Jun, Hu jun, Tang Zhen-min, et al. Improving protein-ATP binding residues prediction by boosting SVMs with random under-sampling[J]. Neurocomputing, 2013, 104: 180-190.
13 Yu Dong-jun, Hu Jun, Huang Yan, et al. TargetATPsite: a template‐free method for ATP‐binding sites prediction with residue evolution image sparse representation and classifier ensemble[J]. Journal of Computational Chemistry, 2013, 34(11): 974-985.
14 Fang C, Noguchi T, Yamana H. Simplified sequence-based method for ATP-binding prediction using contextual local evolutionary conservation[J]. Algorithms for Molecular Biology, 2014, 9(1): 7.
15 Andrews B J, Hu J. TSC_ATP: a two-stage classifier for predicting protein-ATP binding sites from protein sequence[C]∥ Computational Intelligence in Bioinformatics & Computational Biology, Niagara Falls, ON, Canada, 2015: 1-5.
16 Hu Jun, Li Yang, Zhang Yang,et al. ATPbind: accurate protein⁃ATP binding site prediction by combining sequence-profiling and structure-based comparisons[J]. Journal of Chemical Information & Modeling, 2018,58:501-510.
17 Zhou J, Lu Q, Xu R, et al. CNNsite: prediction of DNA-binding residues in proteins using convolutional neural network with sequence features[C]∥IEEE International Conference on Bioinformatics and Biomedicine (BIBM), Shenzhen, China, 2016: 78-85.
18 Pan Xiao-yong, Peter R, Yan Jun-chi, et al. Prediction of RNA-protein sequence and structure binding preferences using deep convolutional and recurrent neural networks[J]. BMC Genomics, 2018, 19(1):511.
19 Zhang Yu, Yu Dong-jun. Protein-ATP binding site prediction based on 1D-convolutional neural network[J]. Journal of Computer Applications, 2019, 39(11): 3146-3150.
20 Mcguffin L J, Kevin B, Jones D T. The PSIPRED protein structure prediction server[J]. Bioinformatics, 2000,16(4): 2.
21 Faraggi E, Zhou Yao-qi, Kloczkowski A. Accurate single-sequence prediction of solvent accessible surface area using local and global features[J]. Protns Structure Function & Bioinformatics, 2015, 82(11): 3170-3176.
22 Szegedy C, Liu W, Jia Y, et al. Going Deeper with Convolutions[C]∥ IEEE Conference on Computer Vision and Pattern Recognition (CVPR), Las Vegas, NV, USA, 2015:1-9.
23 Szegedy C, Ioffe S, Vanhoucke V, et al. Rethinking the inception architecture for computer vision[C]∥IEEE Conference on Computer Vision and Pattern Recognition (CVPR), Las Vegas, NV, USA, 2016:2818-2826.
24 Lin T Y, Goyal P, Girshick R, et al. Focal loss for dense object detection[J]. IEEE Transactions on Pattern Analysis & Machine Intelligence, 2017,42(2): 318-327.
25 Szegedy C, Ioffe S, Vanhoucke V, et al. Inception-v4, inception-resnet and the impact of residual connections on learning[J]. Computer Vision and Pattern Recognition,2016: arXiv:.
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