Frontiers of Chemical Science and Engineering >
Cell surface protein engineering for high-performance whole-cell catalysts
Received date: 11 Aug 2016
Accepted date: 09 Oct 2016
Published date: 17 Mar 2017
Copyright
Cell surface protein engineering facilitated by accumulation of information on genome and protein structure involves heterologous production and modification of cell surface proteins using genetic engineering, and is important for the development of high-performance whole-cell catalysts. In this field, cell surface display is a major technology by exposing target proteins, such as enzymes, on the cell surface using a carrier protein. The target proteins are fused to the carrier proteins that transport and tether them to the cell surface, as well as to a secretion signal. This paper reviews cell surface display systems for prokaryotic and eukaryotic cells from the perspective of carrier proteins, which determine the number of displayed molecules, and the localization, size, and direction (N- or C-terminal anchoring) of the passengers. We also discuss advanced methods for displaying multiple enzymes and a new method for the immobilization of whole-cell catalysts using adhesive surface proteins.
Hajime Nakatani , Katsutoshi Hori . Cell surface protein engineering for high-performance whole-cell catalysts[J]. Frontiers of Chemical Science and Engineering, 2017 , 11(1) : 46 -57 . DOI: 10.1007/s11705-017-1609-3
| 1 |
Liljeqvist S, Samuelson P, Hansson M, Nguyen T N, Binz H, Stahl S. Surface display of the cholera toxin B subunit on Staphylococcus xylosus and Staphylococcus carnosus. Applied and Environmental Microbiology, 1997, 63(7): 2481–2488
|
| 2 |
Lee J S, Shin K S, Pan J G, Kim C J. Surface-displayed viral antigens on Salmonella carrier vaccine. Nature Biotechnology, 2000, 18(6): 645–648
|
| 3 |
Martineau P, Charbit A, Leclerc C, Werts C, O’Callaghan D, Hofnung M. A genetic system to elicit and monitor antipeptide antibodies without peptide synthesis. Bio/Technology, 1991, 9(2): 170–172
|
| 4 |
Westerlund-Wikstrom B, Tanskanen J, Virkola R, Hacker J, Lindberg M, Skurnik M, Korhonen T K. Functional expression of adhesive peptides as fusions to Escherichia coli flagellin. Protein Engineering, 1997, 10(11): 1319–1326
|
| 5 |
Boder E T, Wittrup K D. Yeast surface display for screening combinatorial polypeptide libraries. Nature Biotechnology, 1997, 15(6): 553–557
|
| 6 |
Xu Z, Lee S Y. Display of polyhistidine peptides on the Escherichia coli cell surface by using outer membrane protein C as an anchoring motif. Applied and Environmental Microbiology, 1999, 65(11): 5142–5147
|
| 7 |
Sousa C, Kotrba P, Ruml T, Cebolla A, De Lorenzo V. Metalloadsorption by Escherichia coli cells displaying yeast and mammalian metallothioneins anchored to the outer membrane protein LamB. Journal of Bacteriology, 1998, 180(9): 2280–2284
|
| 8 |
Bae W, Mulchandani A, Chen W. Cell surface display of synthetic phytochelatins using ice nucleation protein for enhanced heavy metal bioaccumulation. Journal of Inorganic Biochemistry, 2002, 88(2): 223–227
|
| 9 |
Liu C, Yang B, Gan J, Zhang Y, Liang M, Shu X, Shu J. Heterogeneous reactions of suspended parathion, malathion, and fenthion particles with NO(3) radicals. Chemosphere, 2012, 87(5): 470–476
|
| 10 |
Smith G P. Filamentous fusion phage: Novel expression vectors that display cloned antigens on the virion surface. Science, 1985, 228(4705): 1315–1317
|
| 11 |
Li M. Applications of display technology in protein analysis. Nature Biotechnology, 2000, 18(12): 1251–1256
|
| 12 |
Freudl R, MacIntyre S, Degen M, Henning U. Cell surface exposure of the outer membrane protein OmpA of Escherichia coli K-12. Journal of Molecular Biology, 1986, 188(3): 491–494
|
| 13 |
Ishikawa M, Shigemori K, Hori K. Application of the adhesive bacterionanofiber AtaA to a novel microbial immobilization method for the production of indigo as a model chemical. Biotechnology and Bioengineering, 2014, 111(1): 16–24
|
| 14 |
Hori K, Ohara Y, Ishikawa M, Nakatani H. Effectiveness of direct immobilization of bacterial cells onto material surfaces using the bacterionanofiber protein AtaA. Applied Microbiology and Biotechnology, 2015, 99(12): 5025–5032
|
| 15 |
Xu X, Gao C, Zhang X, Che B, Ma C, Qiu J, Tao F, Xu P. Production of N-acetyl-D-neuraminic acid by use of an efficient spore surface display system. Applied and Environmental Microbiology, 2011, 77(10): 3197–3201
|
| 16 |
Smith M R, Khera E, Wen F. Engineering novel and improved biocatalysts by cell surface display. Industrial & Engineering Chemistry Research, 2015, 54(16): 4021–4032
|
| 17 |
Beerli R R, Bauer M, Buser R B, Gwerder M, Muntwiler S, Maurer P, Saudan P, Bachmann M F. Isolation of human monoclonal antibodies by mammalian cell display. Proceedings of the National Academy of Sciences of the United States of America, 2008, 105(38): 14336–14341
|
| 18 |
Ernst W, Grabherr R, Wegner D, Borth N, Grassauer A, Katinger H. Baculovirus surface display: Construction and screening of a eukaryotic epitope library. Nucleic Acids Research, 1998, 26(7): 1718–1723
|
| 19 |
Schneewind O, Missiakas D M. Protein secretion and surface display in Gram-positive bacteria. Philosophical Transactions of the Royal Society of London. Series B: Biological Sciences, 2012, 367(1592): 1123–1139
|
| 20 |
van Bloois E, Winter R T, Kolmar H, Fraaije M W. Decorating microbes: Surface display of proteins on Escherichia coli. Trends in Biotechnology, 2011, 29(2): 79–86
|
| 21 |
Levin A M, Weiss G A. Optimizing the affinity and specificity of proteins with molecular display. Molecular BioSystems, 2006, 2(1): 49–57
|
| 22 |
Francisco J A, Earhart C F, Georgiou G. Transport and anchoring of beta-lactamase to the external surface of Escherichia coli. Proceedings of the National Academy of Sciences of the United States of America, 1992, 89(7): 2713–2717
|
| 23 |
Francisco J A, Campbell R, Iverson B L, Georgiou G. Production and fluorescence-activated cell sorting of Escherichia coli expressing a functional antibody fragment on the external surface. Proceedings of the National Academy of Sciences of the United States of America, 1993, 90(22): 10444–10448
|
| 24 |
Francisco J A, Stathopoulos C, Warren R A, Kilburn D G, Georgiou G. Specific adhesion and hydrolysis of cellulose by intact Escherichia coli expressing surface anchored cellulase or cellulose binding domains. Bio/Technology, 1993, 11(4): 491–495
|
| 25 |
Wei W, Liu X, Sun P, Wang X, Zhu H, Hong M, Mao Z W, Zhao J. Simple whole-cell biodetection and bioremediation of heavy metals based on an engineered lead-specific operon. Environmental Science & Technology, 2014, 48(6): 3363–3371
|
| 26 |
Yang C, Zhao Q, Liu Z, Li Q, Qiao C, Mulchandani A, Chen W. Cell surface display of functional macromolecule fusions on Escherichia coli for development of an autofluorescent whole-cell biocatalyst. Environmental Science & Technology, 2008, 42(16): 6105–6110
|
| 27 |
Qu W, Xue Y, Ding Q. Display of fungi xylanase on Escherichia coli cell surface and use of the enzyme in xylan biodegradation. Current Microbiology, 2015, 70(6): 779–785
|
| 28 |
Richins R D, Kaneva I, Mulchandani A, Chen W. Biodegradation of organophosphorus pesticides by surface-expressed organophosphorus hydrolase. Nature Biotechnology, 1997, 15(10): 984–987
|
| 29 |
Jung H C, Lebeault J M, Pan J G. Surface display of Zymomonas mobilis levansucrase by using the ice-nucleation protein of Pseudomonas syringae. Nature Biotechnology, 1998, 16(6): 576–580
|
| 30 |
Maurer J, Jose J, Meyer T F. Autodisplay: One-component system for efficient surface display and release of soluble recombinant proteins from Escherichia coli. Journal of Bacteriology, 1997, 179(3): 794–804
|
| 31 |
Karami A, Latifi A M, Khodi S. Comparison of the organophosphorus hydrolase surface display using InaVN and Lpp-OmpA systems in Escherichia coli. Journal of Microbiology and Biotechnology, 2014, 24(3): 379–385
|
| 32 |
Kawahara H. The structures and functions of ice crystal-controlling proteins from bacteria. Journal of Bioscience and Bioengineering, 2002, 94(6): 492–496
|
| 33 |
Jung H C, Park J H, Park S H, Lebeault J M, Pan J G. Expression of carboxymethylcellulase on the surface of Escherichia coli using Pseudomonas syringae ice nucleation protein. Enzyme and Microbial Technology, 1998, 22(5): 348–354
|
| 34 |
van Bloois E, Winter R T, Janssen D B, Fraaije M W. Export of functional Streptomyces coelicolor alditol oxidase to the periplasm or cell surface of Escherichia coli and its application in whole-cell biocatalysis. Applied Microbiology and Biotechnology, 2009, 83(4): 679–687
|
| 35 |
Yim S K, Jung H C, Pan J G, Kang H S, Ahn T, Yun C H. Functional expression of mammalian NADPH-cytochrome P450 oxidoreductase on the cell surface of Escherichia coli. Protein Expression and Purification, 2006, 49(2): 292–298
|
| 36 |
Yim S K, Kim D H, Jung H C, Pan J G, Kang H S, Ahn T, Yun C H. Surface display of heme- and diflavin-containing cytochrome P450 BM3 in Escherichia coli: A whole cell biocatalyst for oxidation. Journal of Microbiology and Biotechnology, 2010, 20(4): 712–717
|
| 37 |
Benz I, Schmidt M A. Structures and functions of autotransporter proteins in microbial pathogens. International Journal of Medical Microbiology, 2011, 301(6): 461–468
|
| 38 |
Leo J C, Grin I, Linke D.Type V secretion: Mechanism(s) of autotransport through the bacterial outer membrane. Philosophical Transactions of the Royal Society of London. Series B: Biological Sciences, 2012, 367(1592): 1088–1101
|
| 39 |
Nicolay T, Vanderleyden J, Spaepen S. Autotransporter-based cell surface display in Gram-negative bacteria. Critical Reviews in Microbiology, 2013, 41(1): 109–123
|
| 40 |
Jose J, Meyer T F. The autodisplay story, from discovery to biotechnical and biomedical applications. Microbiology and Molecular Biology Reviews, 2007, 71(4): 600–619
|
| 41 |
Detzel C, Maas R, Tubeleviciute A, Jose J. Autodisplay of nitrilase from Klebsiella pneumoniae and whole-cell degradation of oxynil herbicides and related compounds. Applied Microbiology and Biotechnology, 2013, 97(11): 4887–4896
|
| 42 |
Jose J, von Schwichow S. Autodisplay of active sorbitol dehydrogenase (SDH) yields a whole cell biocatalyst for the synthesis of rare sugars. ChemBioChem, 2004, 5(4): 491–499
|
| 43 |
Lattemann C T, Maurer J, Gerland E, Meyer T F. Autodisplay: Functional display of active beta-lactamase on the surface of Escherichia coli by the AIDA-I autotransporter. Journal of Bacteriology, 2000, 182(13): 3726–3733
|
| 44 |
Schultheiss E, Weiss S, Winterer E, Maas R, Heinzle E, Jose J. Esterase autodisplay: Enzyme engineering and whole-cell activity determination in microplates with pH sensors. Applied and Environmental Microbiology, 2008, 74(15): 4782–4791
|
| 45 |
Li C, Zhu Y, Benz I, Schmidt M A, Chen W, Mulchandani A, Qiao C. Presentation of functional organophosphorus hydrolase fusions on the surface of Escherichia coli by the AIDA-I autotransporter pathway. Biotechnology and Bioengineering, 2008, 99(2): 485–490
|
| 46 |
Becker S, Theile S, Heppeler N, Michalczyk A, Wentzel A, Wilhelm S, Jaeger K E, Kolmar H. A generic system for the Escherichia coli cell-surface display of lipolytic enzymes. FEBS Letters, 2005, 579(5): 1177–1182
|
| 47 |
Shanna S, Iasson E P, Tozakidis M, Teese J J. Maximized autotransporter-mediated expression (MATE) for surface display and secretion of recombinant proteins in Escherichia coli. Food Technology and Biotechnology, 2015, 50(3): 251–260
|
| 48 |
Tozakidis I E, Brossette T, Lenz F, Maas R M, Jose J. Proof of concept for the simplified breakdown of cellulose by combining Pseudomonas putida strains with surface displayed thermophilic endocellulase, exocellulase and beta-glucosidase. Microbial Cell Factories, 2016, 15(1): 103
|
| 49 |
Crampton M, Berger E, Reid S, Louw M. The development of a flagellin surface display expression system in a moderate thermophile, Bacillus halodurans Alk36. Applied Microbiology and Biotechnology, 2007, 75(3): 599–607
|
| 50 |
Pallesen L, Poulsen L K, Christiansen G, Klemm P. Chimeric FimH adhesin of type 1 fimbriae: A bacterial surface display system for heterologous sequences. Microbiology, 1995, 141(11): 2839–2848
|
| 51 |
Ishikawa M, Nakatani H, Hori K. AtaA, a new member of the trimeric autotransporter adhesins from Acinetobacter sp. Tol 5 mediating high adhesiveness to various abiotic surfaces. PLoS One, 2012, 7(11): e48830
|
| 52 |
Nummelin H, Merckel M C, Leo J C, Lankinen H, Skurnik M, Goldman A. The Yersinia adhesin YadA collagen-binding domain structure is a novel left-handed parallel beta-roll. EMBO Journal, 2004, 23(4): 701–711
|
| 53 |
O’Rourke F, Schmidgen T, Kaiser P O, Linke D, Kempf V A. Adhesins of Bartonella spp. Advances in Experimental Medicine and Biology, 2011, 715: 51–70
|
| 54 |
Yoshimoto S, Nakatani H, Iwasaki K, Hori K. An Acinetobacter trimeric autotransporter adhesin reaped from cells exhibits its nonspecific stickiness via a highly stable 3D structure. Scientific Reports, 2016, 6: 28020
|
| 55 |
Schneewind O, Mihaylova-Petkov D, Model P. Cell wall sorting signals in surface proteins of gram-positive bacteria. EMBO Journal, 1993, 12(12): 4803–4811
|
| 56 |
Lee S Y, Choi J H, Xu Z. Microbial cell-surface display. Trends in Biotechnology, 2003, 21(1): 45–52
|
| 57 |
Schreuder M P, Brekelmans S, van den Ende H, Klis F M. Targeting of a heterologous protein to the cell wall of Saccharomyces cerevisiae. Yeast (Chichester, England), 1993, 9(4): 399–409
|
| 58 |
Pepper L R, Cho Y K, Boder E T, Shusta E V. A decade of yeast surface display technology: Where are we now? Combinatorial Chemistry & High Throughput Screening, 2008, 11(2): 127–134
|
| 59 |
Kuroda K, Ueda M. Arming technology in yeast-novel strategy for whole-cell biocatalyst and protein engineering. Biomolecules, 2013, 3(3): 632–650
|
| 60 |
Blazic M, Kovacevic G, Prodanovic O, Ostafe R, Gavrovic-Jankulovic M, Fischer R, Prodanovic R. Yeast surface display for the expression, purification and characterization of wild-type and B11 mutant glucose oxidases. Protein Expression and Purification, 2013, 89(2): 175–180
|
| 61 |
Gera N, Hussain M, Rao B M. Protein selection using yeast surface display. Methods (San Diego, Calif.), 2013, 60(1): 15–26
|
| 62 |
Tanaka T, Yamada R, Ogino C, Kondo A. Recent developments in yeast cell surface display toward extended applications in biotechnology. Applied Microbiology and Biotechnology, 2012, 95(3): 577–591
|
| 63 |
Wen F, Sethi D K, Wucherpfennig K W, Zhao H. Cell surface display of functional human MHC class II proteins: Yeast display versus insect cell display. Protein Engineering, Design & Selection, 2011, 24(9): 701–709
|
| 64 |
Yeasmin S, Kim C H, Park H J, Sheikh M I, Lee J Y, Kim J W, Back K K, Kim S H. Cell surface display of cellulase activity-free xylanase enzyme on Saccharomyces cerevisiae EBY100. Applied Biochemistry and Biotechnology, 2011, 164(3): 294–304
|
| 65 |
Ueda M, Tanaka A. Cell surface engineering of yeast: Construction of arming yeast with biocatalyst. Journal of Bioscience and Bioengineering, 2000, 90(2): 125–136
|
| 66 |
Kondo A, Shigechi H, Abe M, Uyama K, Matsumoto T, Takahashi S, Ueda M, Tanaka A, Kishimoto M, Fukuda H. High-level ethanol production from starch by a flocculent Saccharomyces cerevisiae strain displaying cell-surface glucoamylase. Applied Microbiology and Biotechnology, 2002, 58(3): 291–296
|
| 67 |
Chen Y, Stemple B, Kumar M, Wei N. Cell surface display fungal laccase as a renewable biocatalyst for degradation of persistent micropollutants bisphenol A and sulfamethoxazole. Environmental Science & Technology, 2016, 50(16): 8799–8808
|
| 68 |
He X, Shang J, Li F, Liu H. Yeast cell surface display of linoleic acid isomerase from Propionibacterium acnes and its application for the production of trans-10, cis-12 conjugated linoleic acid. Biotechnology and Applied Biochemistry, 2014, 62(1): 1–8
|
| 69 |
Bony M, Thines-Sempoux D, Barre P, Blondin B. Localization and cell surface anchoring of the Saccharomyces cerevisiae flocculation protein Flo1p. Journal of Bacteriology, 1997, 179(15): 4929–4936
|
| 70 |
Matsumoto T, Fukuda H, Ueda M, Tanaka A, Kondo A. Construction of yeast strains with high cell surface lipase activity by using novel display systems based on the Flo1p flocculation functional domain. Applied and Environmental Microbiology, 2002, 68(9): 4517–4522
|
| 71 |
Han Z L, Han S Y, Zheng S P, Lin Y. Enhancing thermostability of a Rhizomucor miehei lipase by engineering a disulfide bond and displaying on the yeast cell surface. Applied Microbiology and Biotechnology, 2009, 85(1): 117–126
|
| 72 |
Jiang Z B, Song H T, Gupta N, Ma L X, Wu Z B. Cell surface display of functionally active lipases from Yarrowia lipolytica in Pichia pastoris. Protein Expression and Purification, 2007, 56(1): 35–39
|
| 73 |
Moura M V, da Silva G P, Machado A C, Torres F A, Freire D M, Almeida R V. Displaying lipase B from Candida antarctica in Pichia pastoris using the yeast surface display approach: Prospection of a new anchor and characterization of the whole cell biocatalyst. PLoS One, 2015, 10(10): e0141454
|
| 74 |
Kondo A, Ueda M. Yeast cell-surface display—applications of molecular display. Applied Microbiology and Biotechnology, 2004, 64(1): 28–40
|
| 75 |
Bauer F F, Govender P, Bester M C. Yeast flocculation and its biotechnological relevance. Applied Microbiology and Biotechnology, 2010, 88(1): 31–39
|
| 76 |
Vallejo J A, Sanchez-Perez A, Martinez J P, Villa T G. Cell aggregations in yeasts and their applications. Applied Microbiology and Biotechnology, 2013, 97(6): 2305–2318
|
| 77 |
Abe H, Ohba M, Shimma Y, Jigami Y. Yeast cells harboring human alpha-1,3-fucosyltransferase at the cell surface engineered using Pir, a cell wall-anchored protein. FEMS Yeast Research, 2004, 4(4-5): 417–425
|
| 78 |
Abe H, Shimma Y, Jigami Y. In vitro oligosaccharide synthesis using intact yeast cells that display glycosyltransferases at the cell surface through cell wall-anchored protein Pir. Glycobiology, 2003, 13(2): 87–95
|
| 79 |
Andres I, Gallardo O, Parascandola P, Javier Pastor F I, Zueco J. Use of the cell wall protein Pir4 as a fusion partner for the expression of Bacillus sp. BP-7 xylanase A in Saccharomyces cerevisiae. Biotechnology and Bioengineering, 2005, 89(6): 690–697
|
| 80 |
Shimma Y, Saito F, Oosawa F, Jigami Y. Construction of a library of human glycosyltransferases immobilized in the cell wall of Saccharomyces cerevisiae. Applied and Environmental Microbiology, 2006, 72(11): 7003–7012
|
| 81 |
Shi B, Ke X, Yu H, Xie J, Jia Y, Guo R. Novel properties for endoglucanase acquired by cell-surface display technique. Journal of Microbiology and Biotechnology, 2015, 25(11): 1856–1862
|
| 82 |
Yuzbasheva E Y, Yuzbashev T V, Perkovskaya N I, Mostova E B, Vybornaya T V, Sukhozhenko A V, Toropygin I Y, Sineoky S P. Cell surface display of Yarrowia lipolytica lipase Lip2p using the cell wall protein YlPir1p, its characterization, and application as a whole-cell biocatalyst. Applied Biochemistry and Biotechnology, 2015, 175(8): 3888–3900
|
| 83 |
Castillo L, Martinez A I, Garcera A, Elorza M V, Valentin E, Sentandreu R. Functional analysis of the cysteine residues and the repetitive sequence of Saccharomyces cerevisiae Pir4/Cis3: The repetitive sequence is needed for binding to the cell wall beta-1,3-glucan. Yeast (Chichester, England), 2003, 20(11): 973–983
|
| 84 |
Ecker M, Deutzmann R, Lehle L, Mrsa V, Tanner W. Pir proteins of Saccharomyces cerevisiae are attached to beta-1,3-glucan by a new protein-carbohydrate linkage. Journal of Biological Chemistry, 2006, 281(17): 11523–11529
|
| 85 |
Starwalt S E, Masteller E L, Bluestone J A, Kranz D M. Directed evolution of a single-chain class II MHC product by yeast display. Protein Engineering, 2003, 16(2): 147–156
|
| 86 |
Yang N, Yu Z, Jia D, Xie Z, Zhang K, Xia Z, Lei L, Qiao M. The contribution of Pir protein family to yeast cell surface display. Applied Microbiology and Biotechnology, 2014, 98(7): 2897–2905
|
| 87 |
Liu R, Yang C, Xu Y, Xu P, Jiang H, Qiao C. Development of a whole-cell biocatalyst/biosensor by display of multiple heterologous proteins on the Escherichia coli cell surface for the detoxification and detection of organophosphates. Journal of Agricultural and Food Chemistry, 2013, 61(32): 7810–7816
|
| 88 |
Tang X, Liang B, Yi T, Manco G, Palchetti I, Liu A. Cell surface display of organophosphorus hydrolase for sensitive spectrophotometric detection of p-nitrophenol substituted organophosphates. Enzyme and Microbial Technology, 2014, 55: 107–112
|
| 89 |
Yang J, Liu R, Jiang H, Yang Y, Qiao C. Selection of a whole-cell biocatalyst for methyl parathion biodegradation. Applied Microbiology and Biotechnology, 2012, 95(6): 1625–1632
|
| 90 |
Chen X A, Ishida N, Todaka N, Nakamura R, Maruyama J, Takahashi H, Kitamoto K. Promotion of efficient saccharification of crystalline cellulose by Aspergillus fumigatus Swo1. Applied and Environmental Microbiology, 2010, 76(8): 2556–2561
|
| 91 |
Arantes V, Saddler J N. Access to cellulose limits the efficiency of enzymatic hydrolysis: The role of amorphogenesis. Biotechnology for Biofuels, 2010, 3(1): 4
|
| 92 |
Nakatani Y, Yamada R, Ogino C, Kondo A. Synergetic effect of yeast cell-surface expression of cellulase and expansin-like protein on direct ethanol production from cellulose. Microbial Cell Factories, 2013, 12(1): 66
|
| 93 |
Hyeon J E, Jeon S D, Han S O. Cellulosome-based, Clostridium-derived multi-functional enzyme complexes for advanced biotechnology tool development: Advances and applications. Biotechnology Advances, 2013, 31(6): 936–944
|
| 94 |
Schwarz W H. The cellulosome and cellulose degradation by anaerobic bacteria. Applied Microbiology and Biotechnology, 2001, 56(5-6): 634–649
|
| 95 |
Wen F, Sun J, Zhao H. Yeast surface display of trifunctional minicellulosomes for simultaneous saccharification and fermentation of cellulose to ethanol. Applied and Environmental Microbiology, 2010, 76(4): 1251–1260
|
| 96 |
Tsai S L, Oh J, Singh S, Chen R, Chen W. Functional assembly of minicellulosomes on the Saccharomyces cerevisiae cell surface for cellulose hydrolysis and ethanol production. Applied and Environmental Microbiology, 2009, 75(19): 6087–6093
|
| 97 |
Liang Y, Si T, Ang E L, Zhao H. Engineered pentafunctional minicellulosome for simultaneous saccharification and ethanol fermentation in Saccharomyces cerevisiae. Applied and Environmental Microbiology, 2014, 80(21): 6677–6684
|
| 98 |
You C, Zhang X Z, Sathitsuksanoh N, Lynd L R, Zhang Y H. Enhanced microbial utilization of recalcitrant cellulose by an ex vivo cellulosome-microbe complex. Applied and Environmental Microbiology, 2012, 78(5): 1437–1444
|
| 99 |
Lin Y, Tanaka S. Ethanol fermentation from biomass resources: Current state and prospects. Applied Microbiology and Biotechnology, 2006, 69(6): 627–642
|
| 100 |
Dervakos G A, Webb C. On the merits of viable-cell immobilisation. Biotechnology Advances, 1991, 9(4): 559–612
|
| 101 |
Junter G A, Jouenne T. Immobilized viable microbial cells: From the process to the proteome em leader or the cart before the horse. Biotechnology Advances, 2004, 22(8): 633–658
|
| 102 |
Carballeira J D, Quezada M A, Hoyos P, Simeo Y, Hernaiz M J, Alcantara A R, Sinisterra J V. Microbial cells as catalysts for stereoselective red-ox reactions. Biotechnology Advances, 2009, 27(6): 686–714
|
| 103 |
Cassidy M B, Lee H, Trevors J T. Environmental applications of immobilized microbial cells: A review. Journal of Industrial Microbiology, 1996, 16(2): 79–101
|
| 104 |
Schaeffer C R, Woods K M, Longo G M, Kiedrowski M R, Paharik A E, Buttner H, Christner M, Boissy R J, Horswill A R, Rohde H, Fey P D. Accumulation-associated protein enhances Staphylococcus epidermidis biofilm formation under dynamic conditions and is required for infection in a rat catheter model. Infection and Immunity, 2015, 83(1): 214–226
|
| 105 |
Cotter S E, Surana N K, St Geme J W 3rd. Trimeric autotransporters: A distinct subfamily of autotransporter proteins. Trends in Microbiology, 2005, 13(5): 199–205
|
| 106 |
Hobley L, Harkins C, MacPhee C E, Stanley-Wall N R. Giving structure to the biofilm matrix: An overview of individual strategies and emerging common themes. FEMS Microbiology Reviews, 2015, 39(5): 649–669
|
| 107 |
Ishikawa M, Shigemori K, Suzuki A, Hori K. Evaluation of adhesiveness of Acinetobacter sp. Tol 5 to abiotic surfaces. Journal of Bioscience and Bioengineering, 2012, 113(6): 719–725
|
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