Abstract
Biological network proteins are key operational particles that substantially and operationally cooperate to bring out cellular progressions. Protein links with some other biological network proteins to accomplish their purposes. Physical collaborations are commonly referred to by the relationships of domain-level. The interaction among proteins and biological network reconstruction can be predicted based on various methods such as social theory, similarity, and topological features. Operational particles of proteins collaboration can be indirect among proteins based on mutual fields, subsequently particles of proteins involved in an identical biological progression be likely to harbor similar fields. To reconstruct the real-world network of proteins particles, some methods need only the notations of proteins domain, and then, it can be utilized to multiple species. A novel method we have introduced will analyze and reconstruct the real-world network of protein particles. The proposed technique works based on protein closeness, algebraic connectivity, and mutual proteins. Our proposed method was practically tested over different data sets and reported the results. Experimental results clearly show that the proposed technique worked best as compared to other state-of-the-art algorithms.
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References
Finn RD, Attwood TK, Babbitt PC, Bateman A, Bork P, Bridge AJ, Chang H-Y, Oszt´anyi Z, El-Gebali S, Fraser M et al (2017) Interpro in 2017—beyond protein family and domain annotations. Nucleic Acids Res 45:D190–D199
Runge J (2018) Causal network reconstruction from time series: from theoreticalassumptions to practical estimation. Chaos: An Interdisciplinary J Nonlinear Sci 28:075310
Brugere I, Gallagher B, Berger-Wolf TY (2018) Network structure infer- ence, a survey: Motivations, methods, and applications. ACM Comput Surveys (CSUR) 51:1–39
Gul H, Amin A, Adnan A, Huang K (2021) A systematic analysis of link prediction in complex network. IEEE Access 9:20531–20541
Gul H, Amin A, Nasir F, Ahmad S, Wasim M (2021) Link prediction using double degree equation with mutual and popular nodes, pp 328–337
Molina D, Poyatos J, Del Ser J, Garc´ıa S, Hussain A, Herrera F, (2020) Comprehensive taxonomies of nature-and bio-inspired optimization: inspiration versus algorithmic behavior, critical analysis recommendations. Cognitive Comput 12:897–939
Scardapane S, Scarpiniti M, Baccarelli E, Uncini A (2020) Why should we add early exits to neural networks? Cogn Comput 12:954–966
Jiang X, Yan T, Zhu J, He B, Li W, Du H, Sun S (2020) Densely connected deep extreme learning machine algorithm. Cogn Comput 12:979–990
Leicht EA, Holme P, Newman ME (2006) Vertex similarity in networks. Phys Rev E 73:026120
Adamic LA, Adar E (2003) Friends and neighbors on the web. Social networks 25:211–230
Newman ME (2001) Clustering and preferential attachment in growing networks. Phys Rev E 64:025102
Ravasz E, Somera AL, Mongru DA, Oltvai ZN, Barab´asi A-L (2002) Hierarchical organization of modularity in metabolic networks. Science 297:1551–1555
Rossi RA, Ahmed NK (2015) The network data repository with interactive graph analytics and visualization, in: AAAI,. URL: http://networkrepository.com
Hanley JA, McNeil BJ (1982) The meaning and use of the area under a receiver operating characteristic (roc) curve. Radiology 143:29–36
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Gul, H., Al-Obeidat, F., Moreira, F., Tahir, M., Amin, A. (2022). Real-World Protein Particle Network Reconstruction Based on Advanced Hybrid Features. In: Ullah, A., Anwar, S., Rocha, Á., Gill, S. (eds) Proceedings of International Conference on Information Technology and Applications. Lecture Notes in Networks and Systems, vol 350. Springer, Singapore. https://doi.org/10.1007/978-981-16-7618-5_2
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DOI: https://doi.org/10.1007/978-981-16-7618-5_2
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