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  4. The Significant and Profound Impacts of Pseudo K-Tuple Nucleotide Composition

The Significant and Profound Impacts of Pseudo K-Tuple Nucleotide Composition


DOI: 10.31038/AMM.2020111

 

The “pseudo K-tuple nucleotide composition” or “PseKNC” [1], is an extended version of “pseudo amino acid composition” [2] or “PseAAC” [3].

Both PseAAC and PseKNC are of vector descriptor, but the former represents protein or peptide sequences while the latter represents DNA or RNA sequences.

Just like “PseAAC” (see, e.g., [4-35]) or “Pseudo amino acid composition” being very successful (see, e.g., [36-127]), it is indeed both significant and profound.

References

  1. Chen W, Lei TY, Jin DC, Lin H, Chou KC, PseKNC, et al. (2014) a flexible web-server for generating pseudo K-tuple nucleotide composition. Anal Biochem 456: 53-60.[crossref]
  2. Chou (2001) Prediction of protein cellular attributes using pseudo amino acid composition, PROTEINS : Structure, Function, and Genetics (Erratum: ibid., Vol.44, 60), 43: 246-255. [crossref]
  3. Chou KC (2005) Using amphiphilic pseudo amino acid composition to predict enzyme subfamily classes. Bioinformatics 21: 10-19. [crossref]
  4. Hayat M, Khan A (2012) Discriminating Outer Membrane Proteins with Fuzzy K-Nearest Neighbor Algorithms Based on the General Form of Chou’s PseAAC. Protein & Peptide Letters 19: 411-421. [crossref]
  5. Liao B, Xiang Q, Li D (2012) Incorporating Secondary Features into the General form of Chou’s PseAAC for Predicting Protein Structural Class. Protein & Peptide Letters 19: 1133-1138.
  6. Mei S (2012) Multi-kernel transfer learning based on Chou’s PseAAC formulation for protein submitochondria localization. J Theor Biol 293: 121-130.
  7. Mei S (2012) Predicting plant protein subcellular multi-localization by Chou’s PseAAC formulation based multi-label homolog knowledge transfer learning. J Theor Biol 310: 80-87.
  8. Qin YF, Wang CH, Yu XQ, Zhu J, Liu TG, Zheng XQ, et al. (2012) Predicting Protein Structural Class by Incorporating Patterns of Over-Represented k-mers into the General form of Chou’s PseAAC. Protein & Peptide Letters 19: 388-397. [crossref]
  9. Sun XY, Shi SP, Qiu JD, Suo SB, Huang SY, Liang RP, et al. (2012) Identifying protein quaternary structural attributes by incorporating physicochemical properties into the general form of Chou’s PseAAC via discrete wavelet transform. Molecular BioSystems 8: 3178-3184. [crossref]
  10. Cao DS, Xu QS, Liang YZ, propy (2013) a tool to generate various modes of Chou’s PseAAC. Bioinformatics 29: 960-962. [crossref]
  11. Chang TH, Wu LC, Lee TY, Chen SP, Huang HD, Horng JT, EuLoc, et al. (2013) a web-server for accurately predict protein subcellular localization in eukaryotes by incorporating various features of sequence segments into the general form of Chou’s PseAAC. Journal of Computer-Aided Molecular Design 27: 91-103. [crossref]
  12. Fan GL, Q.-Z. Li, Y.-C. Zuo (2013) Predicting acidic and alkaline enzymes by incorporating the average chemical shift and gene ontology informations into the general form of Chou’s PseAAC. Pocess Biochemistry 48: 1048-1053. [crossref]
  13. Pacharawongsakda E, Theeramunkong T (2013) Predict Subcellular Locations of Singleplex and Multiplex Proteins by Semi-Supervised Learning and Dimension-Reducing General Mode of Chou’s PseAAC. IEEE Transactions on Nanobioscience 12: 311-320.
  14. Xie HL, Fu L, Nie XD (2013) Using ensemble SVM to identify human GPCRs N-linked glycosylation sites based on the general form of Chou’s PseAAC. Protein Eng Des Sel 26: 735-742. [crossref]
  15. Han GS, Yu ZG, Anh V (2014) A two-stage SVM method to predict membrane protein types by incorporating amino acid classifications and physicochemical properties into a general form of Chou’s PseAAC. J Theor Biol 344: 31-39. [crossref]
  16. Li L, Yu S, Xiao W, Li Y, Li M, Huang L, Zheng X, Zhou S, Yang H, et al. (2014) Prediction of bacterial protein subcellular localization by incorporating various features into Chou’s PseAAC and a backward feature selection approach. Biochimie 104: 100-107. [crossref]
  17. Zhang J, Zhao X, Sun P, Ma Z (2014) PSNO: Predicting Cysteine S-Nitrosylation Sites by Incorporating Various Sequence-Derived Features into the General Form of Chou’s PseAAC. Int J Mol Sci 15: 11204-11219. [crossref]
  18. Liu B, Xu J, Fan S, Xu R, Jiyun J Zhou, Wang X (2015) PseDNA-Pro: DNA-binding protein identification by combining Chou’s PseAAC and physicochemical distance transformation. Molecular Informatics 34: 8-17. [crossref]
  19. Mandal M, Mukhopadhyay A, Maulik U (2015) Prediction of protein subcellular localization by incorporating multiobjective PSO-based feature subset selection into the general form of Chou’s PseAAC. Medical & Biological Engineering & Computing53: 331-344. [crossref]
  20. Sanchez V, Peinado AM, Perez-Cordoba JL, Gomez AM (2015) A new signal characterization and signal-based Chou’s PseAAC representation of protein sequences. Journal of Bioinformatics and Computational Biology 13 1550024.
  21. Kabir M, Hayat M (2016) iRSpot-GAEnsC: identifing recombination spots via ensemble classifier and extending the concept of Chou’s PseAAC to formulate DNA samples. Molecular Genetics and Genomics 291: 285-296. [crossref]
  22. Tahir M, Hayat M (2016) iNuc-STNC: a sequence-based predictor for identification of nucleosome positioning in genomes by extending the concept of SAAC and Chou’s PseAAC. Mol Biosyst 12: 2587-2593. [crossref]
  23. Ju Z, He JJ (2017) Prediction of lysine propionylation sites using biased SVM and incorporating four different sequence features into Chou’s PseAAC. J Mol Graph Model 76: 356-363. [crossref]
  24. Yu B, Li S, Qiu WY, Chen C, Chen RX, Wang L, Wang MH, Zhang Y, et al. (2017) Accurate prediction of subcellular location of apoptosis proteins combining Chou’s PseAAC and PsePSSM based on wavelet denoising. Oncotarget 8: 107640-107665. [crossref]
  25. Ahmad J, Hayat M (2018) MFSC: Multi-voting based Feature Selection for Classification of Golgi Proteins by Adopting the General form of Chou’s PseAAC components. J Theor Biol 463: 99-109. [crossref]
  26. Akbar S, Hayat M (2018) iMethyl-STTNC: Identification of N(6)-methyladenosine sites by extending the Idea of SAAC into Chou’s PseAAC to formulate RNA sequences. J Theor Biol 455: 205-211. [crossref]
  27. Contreras-Torres E (2018) Predicting structural classes of proteins by incorporating their global and local physicochemical and conformational properties into general Chou’s PseAAC. J Theor Biol 454: 139-145. [crossref]
  28. Fu X, Zhu W, Liso B, Cai L, Peng L, Yang J, et al. (2018) Improved DNA-binding protein identification by incorporating evolutionary information into the Chou’s PseAAC. IEEE Access 18: 43-66. [crossref]
  29. Javed F, Hayat M (2018) Predicting subcellular localizations of multi-label proteins by incorporating the sequence features into Chou’s PseAAC. Genomics 17: 793-821. [crossref]
  30. Mousavizadegan M, Mohabatkar H (2018) Computational prediction of antifungal peptides via Chou’s PseAAC and SVM. Journal of Bioinformatics and Computational Biology [crossref]
  31. Zhang S, Liang Y (2018) Predicting apoptosis protein subcellular localization by integrating auto-crosscorrelation and PSSM into Chou’s PseAAC. J Theor Biol 457: 163-169. [crossref]
  32. Ahmad J, Hayat M (2019) MFSC: Multi-voting based feature selection for classification of Golgi proteins by adopting the general form of Chou’s PseAAC components. J Theor Biol 463: 99-109. [crossref]
  33. Butt AH, Rasool N, Khan YD (2019) Prediction of antioxidant proteins by incorporating statistical moments based features into Chou’s PseAAC. J Theor Biol 473: 1-8.
  34. Javed F, Hayat M (2019) Predicting subcellular localization of multi-label proteins by incorporating the sequence features into Chou’s PseAAC. Genomics 111: 1325-1332. [crossref]
  35. Tahir M, Hayat M, Khan SA (2019) iNuc-ext-PseTNC: an efficient ensemble model for identification of nucleosome positioning by extending the concept of Chou’s PseAAC to pseudo-tri-nucleotide composition. Molecular Genetics and Genomics: MGG 294: 199-210. [crossref]
  36. Ding YS, Zhang TL (2008) Using Chou’s pseudo amino acid composition to predict subcellular localization of apoptosis proteins: an approach with immune genetic algorithm-based ensemble classifier. Pattern Recognition Letters 29: 1887-1892. [crossref]
  37. Fang Y, Guo Y, Feng Y, Li M (2008) Predicting DNA-binding proteins: approached from Chou’s pseudo amino acid composition and other specific sequence features. Amino Acids 34: 103-109. [crossref]
  38. Jiang X, Wei R, Zhang TL, Gu Q (2008) Using the concept of Chou’s pseudo amino acid composition to predict apoptosis proteins subcellular location: an approach by approximate entropy. Protein & Peptide Letters 15: 392-396. [crossref]
  39. Jiang X, Wei R, Zhao Y, Zhang T (2008) Using Chou’s pseudo amino acid composition based on approximate entropy and an ensemble of AdaBoost classifiers to predict protein subnuclear location. Amino Acids 34: 669-675. [crossref]
  40. Li FM, Li QZ (2008) Predicting protein subcellular location using Chou’s pseudo amino acid composition and improved hybrid approach. Protein & Peptide Letters 15: 612-616. [crossref]
  41. Lin H (2008) The modified Mahalanobis discriminant for predicting outer membrane proteins by using Chou’s pseudo amino acid composition. J Theor Biol 252: 350-356. [crossref]
  42. Lin H, Ding H, Guo FB, Zhang AY, Huang J (2008) Predicting subcellular localization of mycobacterial proteins by using Chou’s pseudo amino acid composition. Protein & Peptide Letters 15: 739-744. [crossref]
  43. Nanni L, Lumini A (2008) Genetic programming for creating Chou’s pseudo amino acid based features for submitochondria localization. Amino Acids 34: 653-660. [crossref]
  44. Zhang GY, Li HC, Gao JQ, Fang BS (2008) Predicting lipase types by improved Chou’s pseudo amino acid composition. Protein & Peptide Letters 15: 1132-1137. [crossref]
  45. Zhang SW, Chen W, Yang F, Pan Q (2008) Using Chou’s pseudo amino acid composition to predict protein quaternary structure: a sequence-segmented PseAAC approach, Amino Acids 35: 591-598. [crossref]
  46. Zhang SW, Zhang YL, Yang HF, Zhao CH, Pan Q (2008) Using the concept of Chou’s pseudo amino acid composition to predict protein subcellular localization: an approach by incorporating evolutionary information and von Neumann entropies. Amino Acids 34: 565-572. [crossref]
  47. Chen C, Chen L, Zou X, Cai P (2009) Prediction of protein secondary structure content by using the concept of Chou’s pseudo amino acid composition and support vector machine. Protein & Peptide Letters 16: 27-31. [crossref]
  48. Georgiou DN, Karakasidis TE, Nieto JJ, Torres A (2009) Use of fuzzy clustering technique and matrices to classify amino acids and its impact to Chou’s pseudo amino acid composition. J Theor Biol 257: 17-26. [crossref]
  49. Li ZC, Zhou XB, Dai Z, Zou XY (2009) Prediction of protein structural classes by Chou’s pseudo amino acid composition: approached using continuous wavelet transform and principal component analysis. Amino Acids 37: 415-425. [crossref]
  50. Lin H, Wang H, Ding H, Chen YL, Li QZ (2009) Prediction of Subcellular Localization of Apoptosis Protein Using Chou’s Pseudo Amino Acid Composition. Acta Biotheoretica 57 321-330. [crossref]
  51. Qiu JD, Huang JH, Liang RP, Lu XQ (2009) Prediction of G-protein-coupled receptor classes based on the concept of Chou’s pseudo amino acid composition: an approach from discrete wavelet transform. Anal Biochem 390: 68-73. [crossref]
  52. Zeng YH, Guo YZ, Xiao RQ, Yang L, Yu LZ, Li ML, et al. (2009) Using the augmented Chou’s pseudo amino acid composition for predicting protein submitochondria locations based on auto covariance approach. J Theor Biol 259: 366–372.
  53. Esmaeili M, Mohabatkar H, Mohsenzadeh S (2010) Using the concept of Chou’s pseudo amino acid composition for risk type prediction of human papillomaviruses. J Theor Biol 263: 203-209. [crossref]
  54. Gu Q, Ding YS, Zhang TL (2010) Prediction of G-Protein-Coupled Receptor Classes in Low Homology Using Chou’s Pseudo Amino Acid Composition with Approximate Entropy and Hydrophobicity Patterns. Protein & Peptide Letters 17: 559-567. [crossref]
  55. Mohabatkar H (2010) Prediction of cyclin proteins using Chou’s pseudo amino acid composition. Protein & Peptide Letters 17: 1207-1214. [crossref]
  56. Qiu JD, Huang JH, Shi SP, Liang RP (2010) Using the concept of Chou’s pseudo amino acid composition to predict enzyme family classes: an approach with support vector machine based on discrete wavelet transform. Protein : Peptide Letters 17: 715-722. [crossref]
  57. Sahu SS, Panda G (2010) A novel feature representation method based on Chou’s pseudo amino acid composition for protein structural class prediction. Computational Biology and Chemistry 34: 320-327.
  58. Yu L, Guo Y, Li Y, Li G, Li M, Luo J, Xiong W, Qin W, et al. (2010) SecretP: Identifying bacterial secreted proteins by fusing new features into Chou’s pseudo amino acid composition. J Theor Biol 267: 1-6. [crossref]
  59. Guo J, Rao N, Liu G, Yang Y, Wang G (2011) Predicting protein folding rates using the concept of Chou’s pseudo amino acid composition. Journal of: Computational Chemistry 32: 1612-1617. [crossref]
  60. Lin J, Wang Y (2011) Using a novel AdaBoost algorithm and Chou’s pseudo amino acid composition for predicting protein subcellular localization. Protein & Peptide Letters 18: 1219-1225.
  61. Lin J, Wang Y, Xu X (2011) A novel ensemble and composite approach for classifying proteins based on Chou’s pseudo amino acid composition. African Journal of Biotechnology 10: 16963-16968.
  62. Mohabatkar H, Mohammad Beigi, Esmaeili A (2011) Prediction of GABA(A) receptor proteins using the concept of Chou’s pseudo amino acid composition and support vector machine. J Theor Biol 281: 18-23. [crossref]
  63. Mohammad BM, Behjati M, Mohabatkar H (2011) Prediction of metalloproteinase family based on the concept of Chou’s pseudo amino acid composition using a machine learning approach. Journal of Structural and Functional Genomics 12: 191-197. [crossref]
  64. Qiu JD, Suo SB, Sun XY, Shi SP, Liang RP (2011) OligoPred: A web-server for predicting homo-oligomeric proteins by incorporating discrete wavelet transform into Chou’s pseudo amino acid composition. Journal of Molecular Graphics & Modelling 30: 129-134. [crossref]
  65. Zou D, He Z, He J, Xia Y (2011) Supersecondary structure prediction using Chou’s pseudo amino acid composition. J Comput Chem 32: 271-278. [crossref]
  66. Cao JZ, Liu WQ, Gu H (2012) Predicting Viral Protein Subcellular Localization with Chou’s Pseudo Amino Acid Composition and Imbalance-Weighted Multi-Label K-Nearest Neighbor Algorithm. Protein and Peptide Letters 19: 1163-1169. [crossref]
  67. Chen C, Shen ZB, Zou XY (2012) Dual-Layer Wavelet SVM for Predicting Protein Structural Class Via the General Form of Chou’s Pseudo Amino Acid Composition. Protein & Peptide Letters 19: 422-429. [crossref]
  68. Du P, Wang X, Xu C, Gao Y (2012) PseAAC-Builder: A cross-platform stand-alone program for generating various special Chou’s pseudo amino acid compositions. Anal Biochem 425: 117-119. [crossref]
  69. Fan GL, Li QZ (2012) Predict mycobacterial proteins subcellular locations by incorporating pseudo-average chemical shift into the general form of Chou’s pseudo amino acid composition. J Theor Biol 304: 88-95. [crossref]
  70. Fan GL, Li QZ (2012) Predicting protein submitochondria locations by combining different descriptors into the general form of Chou’s pseudo amino acid composition. Amino Acids 43: 545-555. [crossref]
  71. Li LQ, Zhang Y, Zou LY, Zhou Y, Zheng XQ (2012) Prediction of Protein Subcellular Multi-Localization Based on the General form of Chou’s Pseudo Amino Acid Composition. Protein & Peptide Letters 19: 375-387.
  72. Liu L, Hu XZ, Liu XX, Wang Y, Li SB (2012) Predicting Protein Fold Types by the General Form of Chou’s Pseudo Amino Acid Composition: Approached from Optimal Feature Extractions. Protein & Peptide Letters 19: 439-449. [crossref]
  73. Nanni L, Brahnam S, Lumini A (2012) Wavelet images and Chou’s pseudo amino acid composition for protein classification. Amino Acids 43: 657-665. [crossref]
  74. Nanni L, Lumini A, Gupta D, Garg A (2012) Identifying bacterial virulent proteins by fusing a set of classifiers based on variants of Chou’s pseudo amino acid composition and on evolutionary information. IEEE-ACM Transaction on Computational Biolology and Bioinformatics 9: 467-475. [crossref]
  75. Niu XH, Hu XH, Shi F, Xia JB (2012) Predicting Protein Solubility by the General Form of Chou’s Pseudo Amino Acid Composition: Approached from Chaos Game Representation and Fractal Dimension. Protein & Peptide Letters 19: 940-948. [crossref]
  76. Ren LY, Zhang YS, Gutman I (2012) Predicting the Classification of Transcription Factors by Incorporating their Binding Site Properties into a Novel Mode of Chou’s Pseudo Amino Acid Composition. Protein & Peptide Letters 19: 1170-1176. [crossref]
  77. Zhao XW, Ma ZQ, Yin MH (2012) Predicting protein-protein interactions by combing various sequence- derived features into the general form of Chou’s Pseudo amino acid composition. Protein & Peptide Letters 19: 492-500.
  78. Zia-ur-Rehman, Khan A (2012) Identifying GPCRs and their Types with Chou’s Pseudo Amino Acid Composition: An Approach from Multi-scale Energy Representation and Position Specific Scoring Matrix. Protein & Peptide Letters 19: 890-903. [crossref]
  79. Chen YK, Li KB (2013) Predicting membrane protein types by incorporating protein topology, domains, signal peptides, and physicochemical properties into the general form of Chou’s pseudo amino acid composition. J Theor Biol 318: 1-12. [crossref]
  80. Fan GL, Li QZ (2013) Discriminating bioluminescent proteins by incorporating average chemical shift and evolutionary information into the general form of Chou’s pseudo amino acid composition. J Theor Biol 334: 45-51. [crossref]
  81. Georgiou DN, Karakasidis TE, Megaritis AC (2013) A short survey on genetic sequences, Chou’s pseudo amino acid composition and its combination with fuzzy set theory. The Open Bioinformatics Journal 7: 41-48. [crossref]
  82. Gupta MK, Niyogi R, Misra M (2013) An alignment-free method to find similarity among protein sequences via the general form of Chou’s pseudo amino acid composition. SAR QSAR Environ Res 24: 597-609. [crossref]
  83. Huang C, Yuan J (2013) Using radial basis function on the general form of Chou’s pseudo amino acid composition and PSSM to predict subcellular locations of proteins with both single and multiple sites. Biosystems 113: 50-57. [crossref]
  84. Huang C, Yuan JQ (2013) A multilabel model based on Chou’s pseudo amino acid composition for identifying membrane proteins with both single and multiple functional types. J Membr Biol 246: 327-334. [crossref]
  85. Huang C, Yuan JQ (2013) Predicting protein subchloroplast locations with both single and multiple sites via three different modes of Chou’s pseudo amino acid compositions. J Theor Biol 335: 205-212.
  86. Khosravian M, Faramarzi FK, Beigi MM, Behbahani M, Mohabatkar H, et al. (2013) Predicting Antibacterial Peptides by the Concept of Chou’s Pseudo amino Acid Composition and Machine Learning Methods. Protein & Peptide Letters 20: 180-186. [crossref]
  87. Lin H, Ding C, L.-F. Yuan, Chen W, Ding H, Z.-Q. Li, F.-B. Guo, Huang J, N.-N. Rao, et al. (2013) Predicting subchloroplast locations of proteins based on the general form of Chou’s pseudo amino acid composition: Approached from optimal tripeptide composition. International Journal of Biomethmatics 6: 1350003.
  88. Liu B, Wang X, Zou Q, Dong Q, Chen Q (2013) Protein remote homology detection by combining Chou’s pseudo amino acid composition and profile-based protein representation. Molecular Informatics 32: 775-782. [crossref]
  89. Mohabatkar H, Beigi MM, Abdolahi K, Mohsenzadeh S (2013) Prediction of Allergenic Proteins by Means of the Concept of Chou’s Pseudo Amino Acid Composition and a Machine Learning Approach. Medicinal Chemistry 9: 133-137. [crossref]
  90. Qin YF, Zheng L, Huang J (2013) Locating apoptosis proteins by incorporating the signal peptide cleavage sites into the general form of Chou’s Pseudo amino acid composition. Int J Quantum Chem 113: 1660-1667.
  91. Sarangi AN, Lohani M, Aggarwal R (2013) Prediction of Essential Proteins in Prokaryotes by Incorporating Various Physico-chemical Features into the General form of Chou’s Pseudo Amino Acid Composition. Protein Pept Lett 20: 781-795. [crossref]
  92. Wan S, Mak MW, Kung SY (2013) GOASVM: A subcellular location predictor by incorporating term-frequency gene ontology into the general form of Chou’s pseudo amino acid composition. J Theor Biol 323: 40-48. [crossref]
  93. Wang X, Li GZ, Lu WC (2013) Virus-ECC-mPLoc: a multi-label predictor for predicting the subcellular localization of virus proteins with both single and multiple sites based on a general form of Chou’s pseudo amino acid composition. Protein & Peptide Letters 20: 309-317. [crossref]
  94. Xiaohui N, Nana L, Jingbo X, Dingyan C, Yuehua P, Yang X, Weiquan W, Dongming W, Zengzhen W, et al. (2013) Using the concept of Chou’s pseudo amino acid composition to predict protein solubility: An approach with entropies in information theory. J Theor Biol 332: 211-217. [crossref]
  95. Du P, Gu S, Jiao Y (2014) PseAAC-General: Fast building various modes of general form of Chou’s pseudo amino acid composition for large-scale protein datasets. International Journal of Molecular Sciences 15: 3495-3506. [crossref]
  96. Hajisharifi Z, Piryaiee M, Mohammad M Beigi, Behbahani M, Mohabatkar H (2014) Predicting anticancer peptides with Chou’s pseudo amino acid composition and investigating their mutagenicity via Ames test. J Theor Biol 341: 34-40. [crossref]
  97. Jia C, Lin X, Wang Z (2014) Prediction of Protein S-Nitrosylation Sites Based on Adapted Normal Distribution Bi-Profile Bayes and Chou’s Pseudo Amino Acid Composition. Int J Mol Sci 15: 10410-10423. [crossref]
  98. Kong L, Zhang L, Lv J (2014) Accurate prediction of protein structural classes by incorporating predicted secondary structure information into the general form of Chou’s pseudo amino acid composition. J Theor Biol 344: 12-18. [crossref]
  99. Nanni L, Brahnam S, Lumini A (2014) Prediction of protein structure classes by incorporating different protein descriptors into general Chou’s pseudo amino acid composition. J Theor Biol 360: 109-116. [crossref]
  100. Zhang J, Sun P, Zhao X, Ma Z (2014) PECM: Prediction of extracellular matrix proteins using the concept of Chou’s pseudo amino acid composition. J Theor Biol 363: 412-418. [crossref]
  101. Zhang L, Zhao X, Kong L (2014) Predict protein structural class for low-similarity sequences by evolutionary difference information into the general form of Chou’s pseudo amino acid composition. J Theor Biol 355: 105-110. [crossref]
  102. Zuo YC, Peng Y, Liu L, Chen W, Yang L, Fan GL (2014) Predicting peroxidase subcellular location by hybridizing different descriptors of Chou’s pseudo amino acid patterns. Anal Biochem 458: 14-19. [crossref]
  103. Ali F, Hayat M (2015) Classification of membrane protein types using Voting Feature Interval in combination with Chou’s Pseudo Amino Acid Composition. J Theor Biol 384: 78-83. [crossref]
  104. Fan GL, Zhang XY, Liu YL, Nang Y, Wang H (2015) DSPMP: Discriminating secretory proteins of malaria parasite by hybridizing different descriptors of Chou’s pseudo amino acid patterns. J Comput Chem 36: 2317-2327. [crossref]
  105. Huang C, Yuan JQ (2015) Simultaneously Identify Three Different Attributes of Proteins by Fusing their Three Different Modes of Chou’s Pseudo Amino Acid Compositions. Protein Pept Lett 22: 547-556.
  106. Khan ZU, Hayat M, Khan MA (2015) Discrimination of acidic and alkaline enzyme using Chou’s pseudo amino acid composition in conjunction with probabilistic neural network model. J Theor Biol 365: 197-203. [crossref]
  107. Kumar R, Srivastava A, Kumari B, Kumar M (2015) Prediction of beta-lactamase and its class by Chou’s pseudo amino acid composition and support vector machine. J Theor Biol 365: 96-103. [crossref]
  108. Wang X, Zhang W, Zhang Q, Li GZ (2015) MultiP-SChlo: multi-label protein subchloroplast localization prediction with Chou’s pseudo amino acid composition and a novel multi-label classifier. Bioinformatics 31: 2639-2645. [crossref]
  109. Jiao YS, Du PF (2016) Prediction of Golgi-resident protein types using general form of Chou’s pseudo amino acid compositions: Approaches with minimal redundancy maximal relevance feature selection. J Theor Biol 402: 38-44. [crossref]
  110. Tang H, Chen W, Lin H (2016) Identification of immunoglobulins using Chou’s pseudo amino acid composition with feature selection technique. Mol Biosyst 12: 1269-1275. [crossref]
  111. Zou HL, Xiao X (2016) Predicting the Functional Types of Singleplex and Multiplex Eukaryotic Membrane Proteins via Different Models of Chou’s Pseudo Amino Acid Compositions. J Membr Biol 249: 23-29.
  112. Huo H, Li T, Wang S, Lv Y, Zuo Y, Yang L (2017) Prediction of presynaptic and postsynaptic neurotoxins by combining various Chou’s pseudo components. Sci Rep 7: 5827.
  113. Rahimi M, Bakhtiarizadeh MR, Mohammadi A -Sangcheshmeh (2017) OOgenesis_Pred: A sequence-based method for predicting oogenesis proteins by six different modes of Chou’s pseudo amino acid composition. J Theor Biol 414: 128-136. [crossref]
  114. Tripathi P, Pandey PN (2017) A novel alignment-free method to classify protein folding types by combining spectral graph clustering with Chou’s pseudo amino acid composition. J Theor Biol 424: 49-54. [crossref]
  115. Yu B, Lou L, Li S, Zhang Y, Qiu W, Wu X, Wang M, Tian B, et al. (2017) Prediction of protein structural class for low-similarity sequences using Chou’s pseudo amino acid composition and wavelet denoising. J Mol Graph Model 76: 260-273. [crossref]
  116. Al Maruf MA, Shatabda S (2018) iRSpot-SF: Prediction of recombination hotspots by incorporating sequence based features into Chou’s Pseudo components. Genomics 18: 63-82. [crossref]
  117. Arif M, Hayat M, Jan Z (2018) iMem-2LSAAC: A two-level model for discrimination of membrane proteins and their types by extending the notion of SAAC into Chou’s pseudo amino acid composition. J Theor Biol 442: 11-21. [crossref]
  118. Cui X, Yu Z, Yu B, Wang M, Tian B, Ma Q (2018) UbiSitePred: A novel method for improving the accuracy of ubiquitination sites prediction by using LASSO to select the optimal Chou’s pseudo components. Chemometrics and Intelligent Laboratory Systems (CHEMOLAB) 17: 512-538. [crossref]
  119. Mei J, Zhao J (2018) Prediction of HIV-1 and HIV-2 proteins by using Chou’s pseudo amino acid compositions and different classifiers. Sci Rep 8: 2359.
  120. Zhang L, Kong L (2018) iRSpot-ADPM: Identify recombination spots by incorporating the associated dinucleotide product model into Chou’s pseudo components. J Theor Biol 441: 1-8. [crossref]
  121. Zhang S, Yang K, Lei Y, Song K (2018) iRSpot-DTS: Predict recombination spots by incorporating the dinucleotide-based spare-crosscovariance information into Chou’s pseudo components. Genomics 11: 457-464. [crossref]
  122. Al Maruf MA, Shatabda S (2019) iRSpot-SF: Prediction of recombination hotspots by incorporating sequence based features into Chou’s Pseudo components. Genomics 111: 966-972. [crossref]
  123. Nosrati M, Mohabatkar H, Behbahani M (2019) Introducing of an integrated artificial neural network and Chou’s pseudo amino acid composition approach for computational epitope-mapping of Crimean-Congo haemorrhagic fever virus antigens. International Immunopharmacology 78: 106020. [crossref]
  124. Pan Y, Wang S, Zhang Q, Lu Q, Su D, Zuo Y, Yang L, et al. (2019) Analysis and prediction of animal toxins by various Chou’s pseudo components and reduced amino acid compositions. J Theor Biol 462: 221-229. [crossref]
  125. Tahir M, Tayara H, Chong KT (2019) iRNA-PseKNC(2methyl): Identify RNA 2′-O-methylation sites by convolution neural network and Chou’s pseudo components. J Theor Biol 465: 1-6.
  126. Tian B, Wu X, Chen C, Qiu W, Ma Q, Yu B (2019) Predicting protein-protein interactions by fusing various Chou’s pseudo components and using wavelet denoising approach. J Theor Biol 462: 329-346. [crossref]
  127. Zhang L, Kong L (2019) iRSpot-PDI: Identification of recombination spots by incorporating dinucleotide property diversity information into Chou’s pseudo components. Genomics 111: 457-464. [crossref]

Article Type

Short Communication

Publication history

Received: November 03, 2020
Accepted: November 05, 2020
Published: November 10, 2020

Citation

Kuo-Chen Chou (2020) The Significant and Profound Impacts of Pseudo K-Tuple Nucleotide Composition. Arch Mol Med J Volume 1(1): 1–4. DOI: 10.31038/AMM.2020111

Corresponding author

Kuo-Chen Chou
Gordon Life Science Institute,
Boston,
Massachusetts 02478,
USA

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