. Acessado em: 07/2012.
CHAHAL, D. S. (1991) Production of Trichoderma reesei system with high
hydrolytic potential by solid-state fermentation. In: LEATHAM, G. F.,
HIMMEL, M. E., ed. Enzymes in biomass conversion. ACS symposium
series, 460. American Chemical Society, Washington, DC, p. 111-122.
CHANG C. L.; GONG C. S.; CHEN L. F., TSAO G. T. D-Xylulose Fermentation
to Ethanol by Saccharomyces cerevisiae. Appl. Environ. Microbiol., v. 42, p.
284
–
289, 1981.
CHAUDHARY, P.; KUMAR, N. N.; DEOBAGKAR, D. N. The Glucanases of
Cellulomonas. Biotechnology Advances, v. 15, n. 2, p. 315-331, 1997.
CHEN, F.; SRINIVASA, R. M. S.; TEMPLE, S.; JACKSON, L.; SHADLE, G.;
DIXON, R. A. Multi-site genetic modulation of monolignol biosynthesis
suggests new routes for formation of of syringyl lignin and wall-bound ferulic
acid in alfalfa (Medicago sativa L.). Plant Journal, v. 48, p. 113- 124, 2006.
CAPÍTULO 8: Referências Bibliográficas
182
Danielle da Silveira dos Santos
CHEN, R. R.; WANG, Y.; SHIN, H-D.; AGRAWAL, M.; MAO, Z. Strains of
Zymomonas mobilis for fermentation of biomass-Us patent 20090269797,
2009.
CHEN, T.; ZHANG, J.; LIANG, L.; YANG, R.; LIN, Z. An in vivo, label-free quick
assay for xylose transport in Escherichia coli. Analytical Biochemistry,
v.390, p. 63-67, 2009.
CHEN, W.; LIN, T.; GUO, G.; HUANG, W. Ethanol production from rice straw
hydrolysates by Pichia stipites. Energy Procedia, v. 14, p. 1261
–
1266,
2012.
CHEN, Y. C. B. Initial investigation of xylose fermentation for
lignocellulosicbioethanol production. Tese de Doutorado. Auburn
University, AL, 2009.
CHENG, K. K.;CAI, B. Y.; ZHANG, J. A.; LING, H. Z.; ZHOU, Y. J.; GE, J. P.; et
al. Sugarcane bagasse hemicelluloses hydrolysate for ethanol production
by acid recovery process.Biochemical Engineering Journal, v. 38, p. 105
–
109, 2008.
CHOU, Y.C.; HOWE, W.; EVANS, K.; ZHANG, M. Construction of xylose
utilizing Zymomonas mobilis integrants based on strain ATCC31821, in:
23TH SYMPOSIUM ON BIOTECHNOLOGYFUELS. Chemical Abstracts,
Colorado Springs, 2002.
CHOU, Y-C.; ZHANG, M.; MOHAGHEGHI, A.; EVANS, K.; FINKELSTEIN, M.
Construction andevaluation of a xylose/arabinose fermenting strain of
Zymomonas mobilis. In:Abstracts in 19th symposium on biotechnology for
fuels and chemicals. 1997.
CNI (2007) Matriz energética e emissão de gases do efeito estufa. Disponível
em: . Acessado em: 06/2009.
CONAB,
Companhia
Nacional de
Abastecimento
(2011)
Disponível
em:. Acessado em: 09/2012.
CONWAY, T.; BYUN, M. O-K.; INGRAM, L. O. Expression Vector for
Zymomonas mobilis. Applied and Environmental Microbiology, p. 235-241,
1987.
CONWAY, T.; SEWELL, G. W.; INGRAM, L. 0.Glyceraldehyde-3-Phosphate
Dehydrogenase Gene from Zymomonas mobilis: Cloning, Sequencing, and
CAPÍTULO 8: Referências Bibliográficas
183
Danielle da Silveira dos Santos
Identification of Promoter Region. Journal of Bacteriology, v. 169, n. 12, p.
5653-5662, 1987.
COSTA, F. H. N.; BUZATO, J. B.; CELLIGOI M. A. P. C. ; TANO, M. S.
Fermentação contínua por Zymomonas mobilis ATCC 29191 em
concentrações elevadas de sacarose. Revista de Ciências Exatas e
Naturais, v. 3, n. 2, p. 201-207, 2001.
COUGHLANM, P. & LJUNGDAHLL, G. (1988) Comparative biochemistry of
fungal and bacterial cellulolytic enzyme systems. In : Biochemistry and
Genetics of Cellulose Degradation, FEMS Symposium n. 43, p. 11-30.
Edited by J. P. Aubert, P. Btguin & J. Millet. London & San Diego: Academic
Press.
CRESPO, F.; BADSHAH, M.; ALVAREZ, M. T.; MATTIASSON, B. Ethanol
production by continuous fermentation of D-(+)-cellobiose, D-(+)-xylose and
sugarcane bagasse hydrolysate using the thermoanaerobe Caloramator
boliviensis. Bioresource Technology, v.103, p.186
–
191, 2012.
DAMASO, M. C. T. ; DE CASTRO, A. M. ; CASTRO, R. M. ; ANDRADE, C. M.
M. C. ; PEREIRA JR., N. (2004) Application of Xylanase from
Thermomyces lanuginosus IOC-4145 for Enzymatic Hydrolysis of Corncob
and Sugarcane Bagasse. Appl. Biochem. Biotechnol., v. 113, p.1003
–
1012.
DANIELS, J. & ROACH, B. T. (1987) Taxonomy and evolution in sugarcane. In:
Sugarcane improvement through breeding-Heinz DJ, ed. Amsterdam:
Elsevier Press, p. 7-84.
DAUGULIS, A. J.; McLELLAN, P. J.; LI, J. Experimental investigation and
modeling of oscillatory behavior in the continuous culture of Zymomonas
mobilis. Biotechnology and Bioengineering, v. 56, p. 99
–
105, 1997.
DAVIS, L.; JEON, Y.; SVENSON, C.; ROGERS, P.; PEARCE, J.; PEIRISA, P.
Evaluation of wheat stillage for ethanol production by recombinant
Zymomonas mobilis. Biomass and Bioenergy, v. 29, p. 49
–
59, 2005.
DAVIS, L.; ROGERS, P.; PEARCE, J.; PEIRIS P. Evaluation of Zymomonas-
based ethanol production from a hydrolysed waste starch stream. Biomass
and Bioenergy, v. 30, p. 809
–
814, 2006.
DAVIS, L.; ROGERS, P.; PEARCE, J.; PEIRIS, P. Evaluation of Zymomonas-
based ethanol production from a hydrolysed waste starch stream.
Biomassand Bioenergy, v. 30, p. 809-814, 2006.
CAPÍTULO 8: Referências Bibliográficas
184
Danielle da Silveira dos Santos
DEGRAAF, A. A.; STRIEGEL, K.; WITTIG, R. M.; LAUFER, B.; SCHMITZ, G.;
WIECHERT, W.; SPRENGER, G. A.; SAHM, H. Metabolic state of
Zymomonas mobilis in glucose, fructose, and xylose-fed continuous
cultures as analyzed by C-13- and P-31-NMR spectroscopy.Archives of
Microbiology, v. 171, n. 6, p. 371
–
385,1999.
DEANDA, K.; ZHANG, M.; EDDY, C.; PICATAGGIO, S. Development of an
arabinose fermenting Zymomonas mobilis strain by metabolic pathway
engineering.Applied and Environmental Microbiology, v. 62, p. 4465-4470,
1996.
DELGADO, O. D.; ABATE, C. M.; SINERIZ, F.Construction of an integrative
shuttle vector for Zymomonas mobilis. FEMS Microbiology Letters, v. 132,
p. 23
–
26,1995.
DELGENES, J. P.; MOLETTA, R.; NAVARRO, J. M. Effects of lignocelluloses
degradation products on ethanol fermentation of glucose and xylose by
Saccharomyces cerevisiae, Pichia stipitis, and Candida shehatae. Enzyme
and Microbial Technology, v.19, p. 220
–
225, 1996.
DEMIRBAS, A. Energy and environmental issues relating to greenhouse gas
emissions in Turkey. Energy Convers Manage, v. 44, p. 201
–
213, 2003.
DEUTSCHER, J.; FRANCKE, C.; POSTMA, P. W. How phosphotransferase
system-related protein phosphorylation regulates carbohydrate metabolism
in bacteria. Microbiology and Molecular Biology Reviews, v. 70, p. 939-
1031, 2006.
DIEN, B. S.; COTTA, M. A.; JEFFERIES, T. W. Bacteria engineered for fuel
ethanol production: current status. Applied Microbiology and Biotechnology,
v. 3, p. 258-266, 2003.
DIEN, B. S.; NICHOLS, N. N.; O’BRYAN, P. J.; BOTHAST, R. J. Development
of new ethanologenic Escherichia coli strains for fermentation of
lignocellulosic biomass. Applied Biochemical and Biotechnology, v. 84, p.
181
–
96, 2000.
DILLON, A. (2004) Celulases. In: SAID, S.; PIETRO, R. C. L. Enzimas como
agentes biotecnológicos. Ribeirão Preto, Legis Summa, p. 243-270.
DiMARCO, A. A.; ROMANO, A. H. D-Glucose transport system in Zymomonas
mobilis. Applied and Environmental Microbiology, v. 49, p. 151
–
157, 1985.
CAPÍTULO 8: Referências Bibliográficas
185
Danielle da Silveira dos Santos
DOELLE H. W.; McGREGOR A. N. The effect of high ethanol and C0
2
concentrations on the ultrastructure of Zymomonas mobilis. European
Journal of Applied Microbiology and Biotechnology, v. 17, p. 44-48, 1983.
DOELLE, H. W. & KIRK, L. CRITTENDEN, R.; TOH, H.; DOELLE, M. B.
Zymomonas mobilis
–
science and industrial application. Critical Reviews in
Biotechnology, Boca Raton, v. 13, n. 1, p. 57-98, 1993.
DOELLE, M. B.; MILLICHIP, R. J.; DOELLE, H. W. Production of ethanol from
corn using inoculum cascading of Zymomonas mobilis. Journal Process
Biochemistry, v. 24, n. 4, p. 137-140, 1989.
DOIMBEK, K. M.; INGRAM, L. O. Magnesium limitation and its role in the
apparent toxicity of ethanol during yeast fermentation. Applied and
Environmental Microbiology, v. 52, p. 975-981, 1986.
DUFF, S. J. B.; MURRAY, W. D. Bioconversion of forest products industry
waste cellulosics to fuel ethanol: a review. Bioresource Technology, v. 55,
p. 1- 33, 1996.
DWIDAR M. et al. The production of biofuels from carbonated beverages.
Applied Energy http://dx.doi.org/10.1016/j.apenergy.2012.02.054, 2012.
EKLUND, R. & ZACCHI, G. Simultaneous Saccharification and fermentation of
steam-pretreated willow. Enzyme Microb. Technol., v. 17, p. 255-259, 1995.
ELIASSON, A.; CHRISTENSSON, C.; WAHLBOM, C. F.; HAHN-HAGERDAL,
B. Anaerobic xylose fermentation by recombinant Saccharomyces
cerevisiaecarrying XYL1, XYL2, and XKS1 in mineral medium chemostat
cultures. Applied and Environmental Microbiology, v. 66, p. 3381
–
3386,
2000.
ELNASHAINE, S. S. E. H.; CHEN, Z.; GARHYAN, P.; PRASAD, P.; MAHECA,
B. A. (2006) Practical implications of bifurcation chaos in chemical and
biological reaction engineering. International Journal of Chemical Reactor
Engineering. Disponível em: < http://www.bepress.com/ijcre/vol4/R1>.
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de
Pesquisa
de
Energética
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