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Current Genomics


ISSN (Print): 1389-2029
ISSN (Online): 1875-5488

Research Article

iHyd-PseAAC (EPSV): Identifying Hydroxylation Sites in Proteins by Extracting Enhanced Position and Sequence Variant Feature via Chou's 5- Step Rule and General Pseudo Amino Acid Composition

Author(s): Asma Ehsan*, Muhammad K. Mahmood, Yaser D. Khan, Omar M. Barukab, Sher A. Khan and Kuo-Chen Chou

Volume 20, Issue 2, 2019

Page: [124 - 133] Pages: 10

DOI: 10.2174/1389202920666190325162307

Price: $65


Background: In various biological processes and cell functions, Post Translational Modifications (PTMs) bear critical significance. Hydroxylation of proline residue is one kind of PTM, which occurs following protein synthesis. The experimental determination of hydroxyproline sites in an uncharacterized protein sequence requires extensive, time-consuming and expensive tests.

Methods: With the torrential slide of protein sequences produced in the post-genomic age, certain remarkable computational strategies are desired to overwhelm the issue. Keeping in view the composition and sequence order effect within polypeptide chains, an innovative in-silico predictor via a mathematical model is proposed.

Results: Later, it was stringently verified using self-consistency, cross-validation and jackknife tests on benchmark datasets. It was established after a rigorous jackknife test that the new predictor values are superior to the values predicted by previous methodologies.

Conclusion: This new mathematical technique is the most appropriate and encouraging as compared with the existing models.

Keywords: PseAAC, Hydroxylation of proline, Post Translational Modifications (PTMs), Sequence-coupling model, Mammalian proteins, Hydroxyproline.

Graphical Abstract
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