Nanomaterials as matrices for enzyme immobilization

Artificial Cells, Blood Substitutes, and Biotechnology

Volumn 39, Issue 2, 2011, Pages 98-109

  Gupta, Munishwar N ^a   Kaloti, Mandeep ^a   Kapoor, Manali ^a   Solanki, Kusum ^a  

^a INDIAN INSTITUTE OF TECHNOLOGY DELHI   (India)

Author keywords

carbon nanotubes; enantioselective biocatalysis; enzyme catalysis in low water media; enzyme immobilization; mesoporous materials; protein refolding; quantum dots; superparamagnetic nanoparticles

Indexed keywords

ENANTIOSELECTIVE; ENZYME CATALYSIS IN LOW WATER MEDIA; MESOPOROUS; PROTEIN REFOLDING; QUANTUM DOTS; SUPERPARAMAGNETIC NANOPARTICLES;

BROWNIAN MOVEMENT; CARBON NANOTUBES; CATALYSIS; CATALYSTS; ENZYME IMMOBILIZATION; ENZYMES; NANOPARTICLES; NANOSTRUCTURED MATERIALS; SEMICONDUCTOR QUANTUM DOTS; SUPERPARAMAGNETISM;

MESOPOROUS MATERIALS;

CARBON; NANOMATERIAL; NANOTUBE; QUANTUM DOT;

ARTICLE; BIOCATALYSIS; BIOREACTOR; BIOSENSOR; ENANTIOSELECTIVITY; ENZYME IMMOBILIZATION; NANOFABRICATION; PROTEIN FOLDING;

BIOCATALYSIS; ENZYME STABILITY; ENZYMES, IMMOBILIZED; EQUIPMENT REUSE; HYDROGEN-ION CONCENTRATION; NANOPARTICLES; NANOSTRUCTURES; NANOTECHNOLOGY; NANOTUBES, CARBON; PROTEIN BINDING; PROTEIN REFOLDING; QUANTUM DOTS; TITANIUM;

EID: 79952386806     PISSN: 10731199     EISSN: 15324184     Source Type: Journal    
DOI: 10.3109/10731199.2010.516259     Document Type: Article

References (95)

1. Gupta, M.N. (1992). Enzyme function in organic solvents. Eur J Biochem, 203: 25-32.
2. Gupta, M.N. (ed.) (2000). Methods in Non-aqueous Enzymology . Switzerland: Birkhauser Verlag.
3. Khmelnitsky, Y.L., Levashov, A.V., Klyachko, N.L. and Martinek, K. (1988). Engineering biocatalytic systems in organic media with low water content. Enzyme Microb Technol , 10 :710-724. (Pubitemid 19016156)
4. Mattiasson, B. and Holst, O. (ed.) (1991). E xtractive Bioconversions . New York: Marcel Dekker Inc.
5. Dandavate, V., Keharia, H. and Madamwar, D. (2009). Ethyl isovalerate synthesis using Candida rugosa lipase immobilized on silica nanoparticles prepared in nonionic reverse micelles. Process Biochem , 44: 349-152.
6. Shah, S. and Gupta, M. N. (2007). Kinetic resolution of (-)-1-phenylethanol in [Bmim][PF 6 ] using high activity preparations of lipases. Bioorg Med Chem Lett , 17 :921-924. (Pubitemid 46177625)
7. Lamare, S. and Legoy, M.D. (1993). Biocatalysis in the gas phase. Trends Biotechnol , 11 :413-418. (Pubitemid 23311184)
8. Halling, P.J. (2006). Understanding enzyme action at solid surfaces. Biochem Soc Trans , 34 :309-311.
9. Schloss, P. D. and Handelsman, J. (2003). Biotechnological prospects from metagenomics. Curr Opin Biotechnol , 14 :303-310. (Pubitemid 36782660)
10. Marco, D. (ed.) (2010) . Metagenomics: Theory, Methods and Applications . Caister Academic Press.
11. Bornscheuer, U. T. and Kazlauskas, R. J. (2004). Catalytic promiscuity in biocatalysis: Using old enzymes to form new bonds and follow new pathways. Angew Chem Int Ed , 43 :6032-6040. (Pubitemid 39611872)
12. Khersonsky, O. and Tawfi k, D.S. (2010). Enzyme promiscuity: A mechanistic and evolutionary perspective. Annu Rev Biochem , 79 :11.1-11.35.
13. Gupta, M.N. and Mattiasson, B. (1992). Unique applications of immobilized proteins in bioanalytical systems. In:Bioanalytical Applications of Enzymes . Suelter, C.H. and Kricka, L. (eds). New York: John Wiley & Sons Inc., 36 :1-34.
14. Gusain, M.J. (ed.) (2006). I mmobilization of Enzymes and Cells. New York: Humana Press Inc.
15. Broun, G. B. (1976). Chemically aggregated enzymes. Methods Enzymol , 44 :263-280.
16. Cao, L., Langen, L.V. and Sheldon, R.A. (2003). Immobilized enzymes: carrier-bound or carrier-free? Curr Opin Biotechnol , 14 :387-394.
17. Sheldon, R.A Schoevaart, R. and Van Langen, L.M. (2005). Cross-linked enzyme aggregates (CLEAs). Biocatal Biotransform, 23 : 141-147.
18. Schoevaart, R., Wolbers, M. W., Golubovic, M., Ottens, M., Kieboom, A.P.G., Rantwijk, F.V., van der Wielen, L. A. and Sheldon, R. A. (2004). Preparation, optimization, and structures of cross-linked enzyme aggregates (CLEAs). Biotechnol Bioeng , 87 :754-762. (Pubitemid 39264644)
19. Sowdhamini, R. and Balaram, P. (1993). Protein structure and stability. In:Thermostability of Enzymes. Gupta, M.N. (ed). Berlin: Springer-Verlag, 2-21.
20. Wold, F. (1972). Bifunctional reagents. M ethods Enzymol , 25 :623-651.
21. Gupta, M.N. (1993). Applications of crosslinking techniques to enzyme/protein stabilization and bioconjugate preparation. In : Biocatalyst Design for Stability and Specifi city . Himmel, M.E. and Georgiou, G. (eds). Washington, DC: ACS Symposium Series Am. Chem. Soc., 307-324.
22. Tyagi, R. and Gupta, M. N. (1998) Chemical modifi cation and chemical crosslinking for protein/enzyme stabilization. Biochemistry (Mosc) , 63 :334-344. (Pubitemid 128588271)
23. Tischer, W. and Kasche V. (1999). Immobilized enzymes: crystals or carriers? Trends Biotechnol , 17 :326-335.
24. Roy, I., Sharma, S. and Gupta, M. N. (2004) Smart biocatalysts: design and applications. In:Advances in Biochemical Engineering and Biotechnology , Scheper, T. (ed). Berlin: Springer-Verlag, 86 :159-189.
25. Roy, I. and Gupta, M.N. (2006) Design of smart biocatalysts: Immobilization of enzymes on smart polymers. In:Immobilization of Enzymes & Cells , Guisan, J.M. (ed).: Humana Press Inc., New York, 22: 87-95.
26. Raghava, S., Mondal, K., Pareek, P., Kuckling, D. and Gupta. M.N. (2006). Preparation and properties of thermo sensitive bioconjugates of trypsin. Artif Cells Blood Substit Immobil Biotechnol , 34 :323-336. (Pubitemid 43995277)
27. Raghava, S. and Gupta, M.N. (2009). Stimuli-responsive polymers in biotechnology, In:Advances in Fermentation Technology: Current Topics on Bioprocesses in Food Industry. Pandey, A., Larroche, C., Soccol, C.R., Dussap, C.G. (eds). Delhi: Asiatech New Publishers Inc., 14-26.
28. Teotia, S. and Gupta, M. N. (2001). Purifi cation of á - amylase using magnetic alginate beads. Appl Biochem Biotechnol , 90 :211-220. (Pubitemid 32295759)
29. Teotia, S. and Gupta, M. N. (2002). Magnetite-alginate beads for purifi cation of some starch-degrading enzymes. Mol Biotechnol , 20 :231-237. (Pubitemid 34252634)
30. Safarikova, M., Roy, I., Gupta, M. N. and Safarik, I. (2003). Magnetic alginate microparticles for purifi cation of á - amylases. J Biotechnol , 105 :255-260. (Pubitemid 37315767)
31. Safarik, I. and Safarikova, M. (2009). Magnetic nano and microparticles in biotechnology. Chem Papers , 63 :497-505.
32. Roy, I. and Gupta, M.N. (2006) Use of immobilized biocatalysts in fl uidized bed format. In:Immobilization of Enzymes & Cells, Guisan, J.M. (ed).: Humana Press Inc., New York, 311-320.
33. Engasser, J.M. and Horvath, C. (1976). Diffusion and kinetics with immobilized enzymes. In:Applied Biochemistry and Bioengineering. Wingard, L.B., Katzir, E.K. and Goldstein, L. (eds). London: Academic Press, 1 :127-220.
34. Bommarius, A.S. and Riebel, B.R. (2004). Enzyme reaction engineering. In: Biocatalysis . Verlag: Wiley- VCH, 91-131.
35. Halling, P. J. (2002). Enzymatic conversions in organic and other low water media. In:Enzyme Catalysis in Organic Synthesis. Drauz, K. and Waldman, H. (eds). Weinheim: Wiley-VCH, 259-285.
36. Chang, T.M.S. (2007). A rtifi cial Cells - Biotechnology, Nanomedicine, Regenerative Medicine, Blood Substitutes, Bioencapsulation and Cell/Stem Cell Therapy . Singapore: World Scientifi c Publishing Co. Pte. Ltd.
37. Wang, P. (2006). Nanoscale biocatalyst systems. Curr Opin Biotechnol, 17 :574-579. (Pubitemid 44791914)
38. Bosley, J.A., Peilow, A.D. (2000). Immobilization of lipases for use in non-aqueous reaction systems. In:Methods in Nonaqueous Enzymology . Gupta, M.N. (ed). Switzerland: Birkhauser Verlag, 52-69.
39. Chiang, C.L. and Sung, C.S. (2006). Purifi cation of transfection-grade plasmid DNA from bacterial cells with superparamagnetic nanoparticles. J Magn Magn Mater , 302 :7-13.
40. Mikhaylova, M., Kim, D.K, Berry, C.C., Zagorodni, A., Toprak, M., Curtis, A.S.G. and Muhammed, M. (2004). BSA immobilization on amine-functionalized superparamagnetic iron oxide nanoparticles. Chem Mater , 16 :2344-2354.
41. Kim, D.K., Mikhaylova, M., Zhang, Y. and Muhammed, M. (2003). Protective coating of superparamagnetic iron oxide nanoparticles. Chem Mater , 15 :1617-1627.
42. Gao, X., Yu, K.M.K., Tam, K.Y. and Tsang, S.C. (2003). Colloidal stable silica encapsulated nano-magnetic composite as a novel bio-catalyst carrier. Chem Commun, 2998-2999. (Pubitemid 38019242)
43. Dyal, A., Loos, K., Noto, M., Chang, S.W., Spagnoli, C., Shafi , K.V.P.M., Ulman, A., Cowman, M. and Gross, R.A. (2003). Activity of Candida rugosa lipase immobilized on ã -Fe 2 O 3 magnetic nanoparticles. J Am Chem Soc , 125 :1684-1685. (Pubitemid 36232549)
44. Gardimalla, H.M.R., Mandal, D., Stevens, P.D., Yenb, M. and Gao, Y. (2005). Superparamagnetic nanoparticlesupported enzymatic resolution of racemic carboxylates. Chem Commun, 35 :4432-4434. (Pubitemid 41375027)
45. Zhang, Y., Li, J., Han, D., Zhang, H., Liu, P. and Li, C. (2008). An effi cient resolution of racemic secondary alcohols on magnetically separable biocatalyst. Biochem Biophys Res Commun , 365 : 609-613. (Pubitemid 350234836)
46. Wang, W., Xu, Y., Wang, D.I.C. and Li, Z. (2009). Recyclable nanobiocatalyst for enantioselective sulfoxidation: Facile fabrication and high performance of chloroperoxidase coated magnetic nanoparticles with iron oxide core and polymer shell. J Am Chem Soc , 139 :12892-12893.
47. Lee, J., Lee, Y., Youn, J.K., Na, H.B., Yu, T., Kim, H., Lee, S.M., Koo, Y.M., Kwak, J.H., Park, H.G., Chang, H.N., Hwang, M., Park, J.G., Kim, J. and Hyeon, T. (2008). Simple synthesis of functionalized superparamagnetic magnetite/silica core/shell nanoparticles and their application as magnetically separable high-performance biocatalysts. Small , 4 :143-52. (Pubitemid 351205748)
48. Netto, C.G.C.M., Andrade, L.H. and Toma, H.E. (2009). Enantioselective transesterifi cation catalysis by Candida antarctica lipase immobilized on superparamagnetic nanoparticles. Tetrahedron: Asymmetry , 20 :2299-2304.
49. Dussan, K.J., Giraldo, O. H., and Cardona, C. A. (2007). Application of magnetic nanostructures in biotechnological processes: Biodiesel production using lipase immobilized on magnetic carriers. Proceedings of European Congress of Chemical Engineering (ECCE-6).
50. Weber, H. K. and Faber, K. (1997). Stabilization of lipases against deactivation by acetaldehyde formed in acyl transfer reactions. Meth Enzymol , 206 :509-518. (Pubitemid 27408208)
51. Weber, H.K., Zuegg, J., Faber, K. and Pleissb, J. (1997). Molecular reasons for lipase sensitivity against acetaldehyde. J Mol Catal B Enzy , 3 :131-138. (Pubitemid 27276900)
52. Johnson, A. K., Zawadzka, A.M., Deobald, L.A., Crawford, R.L. and Paszczynski, A.J. (2008). Novel method for immobilization of enzymes to magnetic nanoparticles. J Nanopart Res , 10 :1009-1025.
53. Kim, J., Lee, J., Na, H. B., Kim, B. C., Youn, J. K., Kwak, J. H., Moon, K., Lee, E., Kim, J., Park, J., Dohnalkova, A., Park, H. G., Gu, M. B., Chang, H. N., Grate, J. W. and Hyeon, T. (2005). A magnetically separable, highly stable enzyme system based on nanocomposites of enzymes and magnetic nanoparticles shipped in hierarchically ordered, mesocellular, mesoporous silica. Small , 1 :1203-1207. (Pubitemid 43951832)
54. Kim, J. and Grate, J.W. (2003). Single-enzyme nanoparticles armored by a nanometer-scale organic/inorganic network. Nano Lett, 3 :1219-1222. (Pubitemid 37206066)
55. Wang, Y. and Caruso, F. (2004). Enzyme encapsulation in nanoporous silica spheres. Chem Commun , 1528-1529. (Pubitemid 38969085)
56. Wang, P., Dai, S., Waezsada, S.D., Tsao, A., Davison, B.H. (2001). Enzyme stabilization by covalent binding in nonporous sol-gel glass for nonaqueous biocatalysis. Biotechnol Bioeng , 74: 249-255. (Pubitemid 32685696)
57. Klibanov, A.M. (1979). Enzyme stabilization by immobilization. Anal Biochem , 93 :1-25. (Pubitemid 9151664)
58. Mozhaev, V. V. and Martinek, K., (1990). Structurestability relationships in proteins: a guide to approaches to stabilizing enzymes. Adv Drug Deliv Rev , 4 :387-419. (Pubitemid 20201078)
59. Kula, M. R. and Kragl, U. (2000). Dehydrogenases in the synthesis of chiral compounds. In:Stereoselective Biocatalysis , Patel, R. N. (ed). New York: Marcel Dekker, 839-866.
60. Asuri, P., Karajanagi, S.S., Sellitto, E., Kim, D.Y., Kane, R.S. and Dordick, J.S. (2006). Water-soluble carbon nanotube-enzyme conjugates as functional biocatalytic formulations. Biotechnol Bioeng , 95 :804-811. (Pubitemid 44863199)
61. Shah, S., Solanki, K. and Gupta, M.N. (2007). Enhancement of lipase activity in non-aqueous media upon immobilization on multi-walled carbon nanotubes. Chem Cent J, 1: 30.
62. Shah, S. and Gupta, M.N. (2008). Simultaneous refolding, purifi cation and immobilization of xylanase with multi-walled carbon nanotubes. Biochim Biophys Acta, 1784 :363-367.
63. Asuri, P., Bale, S.S., Karajanagi, S.S. and Kane, R.S. (2006). The protein - nanomaterial interface. Curr Opin Biotechnol , 17 :562-568.
64. Huang, W., Lin, Y., Taylor, S., Gaillard, J., Rao, A.M. and Sun, Y.P. (2002). Sonication-assisted functionalization and solubilization of carbon nanotubes. Nano Lett , 2 :231-234. (Pubitemid 135706298)
65. Shim, M., Kam, N.W.S., Chem, R.J., Li, Y. and Dai, H. (2002). Functionalization of carbon nanotubes for biocompatibility and biomolecular recognition. Nano Lett , 2 :285-288. (Pubitemid 135706308)
66. Chen, R.J., Bangsaruntip, S., Drouvalakais, K.A., Kam, N.W.S., Shim, M., Li, Y., Kim, W., Utz, P.J. and Dai, H. (2003). Noncovalent functionalization of carbon nanotubes for highly specifi c electronic biosensors. Proc Natl Acad Sci , 100 :4984-4989. (Pubitemid 36542645)
67. Azamian, B.R., Cavis, J.J., Coleman, K.S., Bagshaw, C.B. and Green, M.L.H. (2002). Biochemical single walled carbon nanotubes. J Am Chem Soc , 124 :12664-12665. (Pubitemid 35215982)
68. Karajanagi, S.S., Vertegel, A.A., Kane, R.S. and Dordick, J.S. (2004). Structures and functions of enzymes adsorbed onto single walled carbon nanotubes. Langmuir , 20 : 11594-11599. (Pubitemid 40049633)
69. Jia, H., Zhu, G. and Wang, P. (2003). Catalytic behaviors of enzymes attached to nanoparticles: the effect of particle mobility. Biotechnol Bioeng, 84 :406-414. (Pubitemid 37280210)
70. Chen, Y.Z., Yang, C.T., Ching, C.B. and Xu, R. (2008). Immobilization of lipases on hydrophobilized zirconia nanoparticles: Highly enantioselective and reusable biocatalysts. Langmuir , 24 :8877-8884.
71. Raghava, S., Singh, P.K., Rao, A.R., Dutta, V. and Gupta, M.N. (2009). Nanoparticles of unmodifi ed titanium dioxide facilitate protein refolding. Mater Chem , 19 :2830-2834.
72. Vertegel, A.A., Siegel, R.W. and Dordick, J.S. (2004). Silica nanoparticle size infl uences the structure and enzymatic activity of adsorbed lysozyme. Langmuir , 20 :6800-6807.
73. Herricks, T.E., Kim, S.H., Kim, J., Li, D., Kwak, J.H., Grate, J.W., Kim, S.H. and Xia, Y. (2005). Direct fabrication of enzyme-carrying polymer nanofi bers by electrospinning. J Mater Chem, 14: 3241-3245. (Pubitemid 41204110)
74. Hutten, A., Sudfeld, D., Ennen, I., Reiss, G., Hachmann, W., Heinzmann, U., Wojczykowski, K., Jutzi, P., Saikaly, W. and Thomas, G. (2004). New magnetic nanoparticles for biotechnology. J Biotechnol , 112 :47-63. (Pubitemid 39037386)
75. Medintz, I.L., Uyeda, H.T., Goldman, E.R. and Mattoussi, H. (2005). Quantum dot bioconjugates for imaging, labelling and sensing. Nat Mater, 4 :435-446. (Pubitemid 40774047)
76. Hotz, C.Z. (2005). Applications of quantum dots in biology. In:Nanobiotechnology Protocols. Rosenthal, S.J. and Wright, D.W. (eds). New York: Humana Press Inc.
77. Cleland, J.L., Hedgepeth, C. and Wang, D.I. (1992). Polyethylene glycol enhanced refolding of bovine carbonic anhydrase B. Reaction stoichiometry and refolding model. J. Biol Chem, 267 : 13327-13334 .
78. Mondal, K., Bohidar, H.B., Roy, R.P. and Gupta, M.N. (2006). Alginate-chaperoned facile refolding of Chromobacterium viscosum lipase. Biochim Biophys Acta (Proteins and Proteomics) , 1764 :877-886.
79. De, M. and Rotello, M.V. (2008). Synthetic chaperones : nanoparticle-mediated refolding of thermally denatured proteins. Chem Commun , 3504-3506.
80. O'Shannessy, D.J. and Hoffman, W.L. (1987). Site-directed immobilization of glycoproteins on hydrazide-containing supports, Biotech Appl Biochem, 9 :488-496.
81. Sardar, M. and Gupta M.N. (2005). Immobilization of tomato pectinase on Con A-Seralose 4B by bioaffi nity layering. Enzyme Microb Technol , 37 :355-359. (Pubitemid 40933523)
82. Dalal, S. and Gupta, M.N. (2007). Treatment of phenolic wastewater by horseradish peroxidase immobilized by bioaffi nity layering. Chemosphere, 67 :741-747. (Pubitemid 46107612)
83. Wu, L.Q. and Payne, G.F. (2004). Biofabrication: using biological materials and biocatalysts to construct nanostructured assemblies. T rends Biotechnol , 2 2 :593-599. (Pubitemid 39371141)
84. Kim, J., Grate, J.W. and Wang, P. (2008). Nanobiocatalysis and its potential applications. Trends Biotechnol , 26 :639-646.
85. Sharma, S., Teotia, S. and Gupta, M. N. (2003). Bioconversionin an aqueous two phase system using a smart biocatalyst: Casein hydrolysis by alpha chymotrypsin. Enzyme Microb Technol, 32 :337-339. (Pubitemid 36050909)
86. Zhu, G. and Wang, P. (2004). Polymer-enzyme conjugates can self-assemble at oil/water interfaces and effect interfacial biotransformations. J Am Chem Soc , 126 :11132-11133. (Pubitemid 39223169)
87. Sheldon, R.A. (2007). Enzyme immobilization: The quest for optimum performance. Adv Synth Catal , 349 : 1289-1307.
88. Miyazaki, M. and Maeda, H. (2006). Microchannel enzyme reactors and their applications for processing. Trends Biotechnol, 24 :463-470. (Pubitemid 44374781)
89. Honda,T., Miyazaki, M., Nakamura, H. and Maeda, H. (2005). Facile preparation of an enzyme-immobilized microreactor using a cross-linking enzyme membrane on a microchannel. Adv Synth Catal , 348 :2163-2171. (Pubitemid 44662644)
90. Li, H., Liu, S., Dai, Z., Bao, J., and Yang, X. (2009). Applications of nanomaterials in electrochemical enzyme biosensors. Sensors, 9 :8547-8561.
91. Yun, Y.H., Eteshola, E., Bhattacharya, A., Dong, Z., Shim, J.S., Conforti, L., Kim, D., Schulz, M.J., Ahn, C.H. and Watts, N. (2009). Tiny medicine: nanomaterial-based biosensors. Sensors, 9 :9275-9299.
92. Somorjai, G.A., Frei, H. and Park, J.Y. (2009). Advancing the frontiers in nanocatalysis, biointerfaces, and renewable energy conversion by innovations of surface techniques. J Am Chem Soc , 131 :16589-16605.
93. Xiao, Y., Patolsky, F., Kate, E., Hainfeld, J.F. and Willner I. (2003). Plugging into enzymes : nanowiring of redox enzymes by a gold nanoparticles. S cience , 2 99 :1877-1881. (Pubitemid 36356654)
94. Grunes, J., Zhu, J. and Somorjai, G.A. (2003). Catalysis and nanoscience. Chem Commun , 2257-2260. (Pubitemid 37163931)
95. Lynch, I. and Dawson, K.A. (2008). Protein-nanoparticle interactions. Nano Today , 3 :40-47. (Pubitemid 351298587)