CONVERSION OF MIXED WASTE OFFICE PAPER TO ETHANOL BY GENETICALLY-ENGINEERED KLEBSIELLA-OXYTOCA STRAIN P2

被引：33

作者：

BROOKS, TA ^{[1
]}

INGRAM, LO ^{[1
]}

机构：

[1] UNIV FLORIDA,DEPT MICROBIOL & CELL SCI,GAINESVILLE,FL 32611

来源：

BIOTECHNOLOGY PROGRESS | 1995年 / 11卷 / 06期

关键词：

D O I：

10.1021/bp00036a003

中图分类号：

Q81 [生物工程学（生物技术）]; Q93 [微生物学];

学科分类号：

071005 ; 0836 ; 090102 ; 100705 ;

摘要：

Unsorted, mixed waste office paper (MWOP) is an excellent substrate for conversion into fuel ethanol using a recombinant strain of Klebsiella oxytoca which ferments cellobiose and cellotriose to ethanol at near theoretical yields, eliminating the need for supplemental beta-glucosidase. This organism was tested with commercial fungal cellulase in optimized simultaneous saccharification and fermentation experiments (SSF) using MWOP as a substrate (pH 5-5.2, 35 degrees C). Similar rates and yields were obtained with dilute acid-pulped (hydrolysis of hemicellulose) and water-pulped MWOP on a dry weight basis although viscosity was reduced by the acid pretreatment. In simple batch fermentations, 40 g/L ethanol was produced after 48-72 h with 100 g/L MWOP and 1000 filter paper units (FPU) of cellulase/L, a yield of 550 L of ethanol metric ton. Cellulase usage was further reduced by recycling SSF residues containing bound enzymes in multistage fermentations. This approach reduced the requirement for fungal cellulase while retaining rapid ethanol production and high ethanol yield. In our optimal design, broths containing an average of 39.6 g/L ethanol were produced in three successive stages with an average fermentation time of 80 h (567 FPU of fungal cellulase/L; 6.1 FPU/g of substrate). This represents a yield of 0.426 g of ethanol/g of substrate, 539 L/metric ton, 129 gal/U.S. ton. MWOP contains approximately 90% carbohydrate. Thus the combined efficiency for saccharification and fermentation to ethanol was 83.3% of the theoretical maximum.

引用

页码：619 / 625

页数：7

共 42 条

[1] BADAR TA, 1993, PROG PAPER RECYCL, V2, P42
[2] ETHANOL-PRODUCTION FROM LIGNOCELLULOSICS - LARGE-SCALE EXPERIMENTATION AND ECONOMICS
BALLERINI, D
DESMARQUEST, JP
POURQUIE, J
NATIVEL, F
REBELLER, M
[J]. BIORESOURCE TECHNOLOGY, 1994, 50 (01) : 17 - 23
[3] BARBOSA MDS, 1992, APPL ENVIRON MICROB, V58, P1182
[4] BARNETT JA, 1976, ADV CARBOHYD CHEM BI, V32, P123
[5] GENETIC-ENGINEERING OF SOFT-ROT BACTERIA FOR ETHANOL-PRODUCTION FROM LIGNOCELLULOSE
BEALL, DS
INGRAM, LO
[J]. JOURNAL OF INDUSTRIAL MICROBIOLOGY, 1993, 11 (03): : 151 - 155
[6] BEALL DS, 1992, BIOTECHNOL LETT, V14, P857, DOI 10.1007/BF01029153
[7] PARAMETRIC STUDIES OF ETHANOL-PRODUCTION FROM XYLOSE AND OTHER SUGARS BY RECOMBINANT ESCHERICHIA-COLI
BEALL, DS
OHTA, K
INGRAM, LO
[J]. BIOTECHNOLOGY AND BIOENGINEERING, 1991, 38 (03) : 296 - 303
[8] CONVERSION OF XYLAN TO ETHANOL BY ETHANOLOGENIC STRAINS OF ESCHERICHIA-COLI AND KLEBSIELLA-OXYTOCA
BURCHHARDT, G
INGRAM, LO
[J]. APPLIED AND ENVIRONMENTAL MICROBIOLOGY, 1992, 58 (04) : 1128 - 1133
[9] PRETREATMENT OF WASTE PAPER FOR INCREASED ETHANOL YIELDS
CAPEKMENARD, E
JOLLEZ, P
CHORNET, E
WAYMAN, M
DOAN, K
[J]. BIOTECHNOLOGY LETTERS, 1992, 14 (10) : 985 - 988
[10] FERMENTATION OF CRYSTALLINE CELLULOSE TO ETHANOL BY KLEBSIELLA-OXYTOCA CONTAINING CHROMOSOMALLY INTEGRATED ZYMOMONAS-MOBILIS GENES
DORAN, JB
INGRAM, LO
[J]. BIOTECHNOLOGY PROGRESS, 1993, 9 (05) : 533 - 538

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