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1. zhang gy, li hc, fang bs. predicting the cofactors of oxidoreductases based on amino acid composition distribution and chou¡¯s amphiphilic pseudo amino acid composition, journal of theoretical biology, 2008, 253: 310-315. £¨ÒýÓôÎÊý£º132£©
2. zhang gy, li hc, fang bs. predicting lipase types by improved pseudo-amino acid composition, protein & peptide letters, 2008, 15: 1132-1137. £¨ÒýÓôÎÊý£º95£©
3. zhang gy, fang bs. logitboost classifier for discriminating thermophilic and mesophilic proteins, journal of biotechnology, 2007, 127(3): 417-424. £¨ÒýÓôÎÊý£º22£©
4. wang jd, wang yl, wang xz, zhang dd, wu sy & zhang gy. enhanced thermal stability of lichenase from bacillus subtilis 168 by spytag/spycatcher-mediated spontaneous cyclization, biotechnology for biofuels, 2016, 9(1): 79. £¨ÒýÓôÎÊý£º21£©
5. zhang gy, fang bs. application of amino acid distribution along the sequence for discriminating mesophilic and thermophilic proteins, process biochemistry, 2006, 41 (8): 1792-1798. £¨ÒýÓôÎÊý£º19£©
6. zhang gy, ge hh. support vector machine with a pearson vii function kernel for discriminating halophilic and non-halophilic proteins. computational biology and chemistry, 2013, 46:16-22. £¨ÒýÓôÎÊý£º16£©
7. zhang gy, fang bs. discrimination of thermophilic and mesophilic proteins via pattern recognition methods, process biochemistry, 2006, 41 (3): 552-556. £¨ÒýÓôÎÊý£º16£©
8. zhang gy, li hc, fang bs. discriminating acidic and alkaline enzymes using a random forest model with secondary structure amino acid composition, process biochemistry, 2009, 44(6): 654-660. £¨ÒýÓôÎÊý£º12£©
9. zhang gy, ge hh, lin y. stability of halophilic proteins: from dipeptide attributes to discrimination classifier. international journal of biological macromolecules, 2013, 53:1-6. £¨ÒýÓôÎÊý£º12£©
10. zhang gy, fang bs. support vector machine for discrimination of thermophilic and mesophilic proteins based on amino acid composition, protein & peptide letters, 2006, 13(10): 965-970. £¨ÒýÓôÎÊý£º11£©
11. zhang gy, ge hh. protein hypersaline adaptation: insight from amino acids with machine learning algorithms. the protein journal, 2013, 32(4):239-245. £¨ÒýÓôÎÊý£º9£©
12. li cc, zhang gy. the fusions of elastin-like polypeptides and xylanase self-assembled into insoluble active xylanase particles, journal of biotechnology, 2014, 177: 60-66. £¨ÒýÓôÎÊý£º9£©
13. cai zw, ge hh, yi zw, zeng ry & zhang gy. characterization of a novel psychrophilic and halophilic ¦Â-1, 3-xylanase from deep-sea bacterium, flammeovirga pacifica strain wpaga1, international journal of biological macromolecules, 2018, 118: 2176-2184. £¨ÒýÓôÎÊý£º7£©
14. lin yq, qiu y, cai lx, & zhang gy*. investigation of the elp-mediated silicification-based protein self-immobilization using an acidic target enzyme. industrial & engineering chemistry research, 2020, 59: 19829-19837. (·âÃæÂÛÎÄ)
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