酵母发酵蔗渣半纤维素水解物生产木糖酶

采用二次正交旋转组合设计研究了蔗渣半纤维素水解过程中硫酸浓度与液 固比对木糖收率的影响。回归分析表明 ,这两个因素与木糖的收率之间存在显著的回归关系。通过回归方程优化水解条件 ,当硫酸浓度 2 .4g L ,液 固 =6 .2 ,在蒸汽压力 2 .5× 10 4Pa的条件下水解 2 .5h ,10 0g蔗渣可水解生成木糖约 2 4g。大孔树脂吸附层析处理蔗渣半纤维素水解物 ,能有效地减少其中的酵母生长抑制物含量 ,显著改善水解物的发酵性能。用大孔树脂在pH 2条件下处理过的蔗渣半纤维素水解物作基质 ,含木糖 2 0 0g L ,产木糖醇酵母菌株CandidatropicalisAS2 .1776发酵 110h耗完基质中的木糖 ,生成木糖醇 12 7g L ,产物转化率 0 .6 4(木糖醇g 木糖g) ,产物生成速率 1.15g L·h .     

An improvement in Pichia stipitis fermentation of acid-hydrolysed hemicellulose achieved by overliming (calcium hydroxide treatment) and strain adaptation

The fermentability of a corn cob, acid-hydrolysed hemicellulose by Pichia stipitis was considerably improved by pre-treatment with Ca(OH)₂. The total sugars utilized and ethanol yield for the untreated hydrolysate were 18% and 0.21 g/g, respectively, compared with 82% and 0.32 g/g respectively for the treated material. Adaptation of the yeast to the hydrolysate resulted in a significantly higher fermentation rate with over 90% of the initial total sugars being utilized and an ethanol yield and maximum ethanol concentration of 0.41 g/g and 13.3 g/l, respectively.The authors are with the USDA Forest Products Laboratory. One Gifford Pinchot Drive. Madison, WI, 53705 USA     

Influence of xylan on the enzymatic hydrolysis of steam‐pretreated corn stover and hybrid poplar

The focus of this study was to alter the xylan content of corn stover and poplar using SO₂‐catalyzed steam pretreatment to determine the effect on subsequent hydrolysis by commercial cellulase preparations supplemented with or without xylanases. Steam pretreated solids with xylan contents ranging from ～1 to 19% (w/w) were produced. Higher xylan contents and improved hemicellulose recoveries were obtained with solids pretreated at lower severities or without SO₂‐addition prior to pretreatment. The pretreated solids with low xylan content (<4% (w/w)) were characterized by fast and complete cellulose to glucose conversion when utilizing cellulases. Commercial cellulases required xylanase supplementation for effective hydrolysis of pretreated substrates containing higher amounts of xylan. It was apparent that the xylan content influenced both the enzyme requirements for hydrolysis and the recovery of sugars during the pretreatment process. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Bacteroides xylanolyticus sp. nov., a xylanolytic bacterium from methane producing cattle manure

As part of a study of the biogas production from cattle waste, xylanolytic bacteria were isolated from enrichments of fermenting cattle manure. From 34 isolates, mostly Gram-negative rods, a typical strain was investigated in more detail. It was an anaerobic non-sporeforming, Gramnegative rod, which was motile with peritrichous flagella. This organism fermented xylan and many soluble sugars (glucose, cellobiose, mannose, xylose, arabinose). Other hemicelluloses such as gum xanthan, laminaran, locust bean gum, and gum arabic were not utilized. It also could not use cellulose. Fermentation products were carbon dioxide, hydrogen, acetate and ethanol. The bacterium produced carboxymethylcellulase and xylanase, especially when growing on xylan. Growth was optimal between 25°C and 40°C and between pH 6.5 and 7.5. The guanine plus cytosine content of the DNA was 34.8±0.8%. The isolate was identified as a member of the genus Bacteroides, and a new species is proposed: Bacteroides xylanolyticus (xylan dissolving). The type strain of B. xylanolyticus is strain X5-1 (DSM 3808).     

一株产木聚糖酶的蜡样芽孢杆菌对雪茄烟叶成分及发酵产物的影响

雪茄烟叶中的半纤维素在叶脉及叶片韧性等特性中发挥重要作用,烟叶叶脉较粗,半纤维素含量过高,导致雪茄烟叶韧性较差,可用性变差.本实验室前期筛选到一株产木聚糖酶的蜡样芽孢杆菌,该菌株对烟碱有较好的耐受性,利用液态发酵方法研究菌株以雪茄烟叶为营养源产木聚糖酶的最佳发酵条件,并对最佳发酵条件下菌株降解烟叶中半纤维素的效果进行测...     

木质纤维生物质资源高效利用分子技术的开发

木质纤维生物质是地球上最丰富的可再生生物质资源,可为造纸、化工、纺织和生物能源等工业提供重要的原材料。木质纤维生物质主要包括木质素、纤维素和半纤维素三种生物多聚物成分。如何利用分子手段改造这些生物聚合物,提高它们的工业利用率是目前高度关注的问题。综述了近年来木质纤维多聚物在生物合成与改造方面的研究进展,展望了利用分子技术改造植物木质纤维生物质实现其高效利用的前景。     

Comparative Histochemical Analysis of Cell Wall Polysaccharides by Enzymatic and Chemical Extractions of Two Fruits

A protocol for extracting polysaccharides from cell walls has been modified and used to analyze histochemically two fruits with opposite characteristics. Grapes are nonclimacteric fruits and are harvested at full maturity. In contrast, kiwi fruits are climacteric and are harvested and consumed before they are physiologically mature. The two fruits were analyzed histochemically using two protocols. One method is defined as chemical, and is based on subsequential extractions of pectins by chemical agents. The other is defined as enzymatic because it removes pectins using pectinase followed by hot ammonium oxalate. In both protocols, two types of hemicellulosic polymers are removed by 1 M and 4 M/KOH leaving a cellulosic residue on the slide. Both protocols remove the same amount of pectins, thus confirming their precision. The sum of hemicellulose and the cellulosic insoluble residue are equivalent using the two methods, but the relative amounts of the cellulose and hemicellulosic polymers were dependent upon the method of extraction. When the enzyme was used to extract the pectins, there was less cellulose and more hemicellulose. The removal of polysaccharides by ammonium oxalate and by guanidinethio-cyanate in the enzymatic and the chemical protocols, respectively, yielded approximately the same amount of removed material.

Similar results were obtained from both fruits. Grape, being softer than kiwi fruit, was relatively richer in pectic substances and less rich in hemicellulose and cellulose polymers. No difference in cell wall material could be ascribed to the different ripening habits.     

β-Galactosidase, polygalacturonase and pectinesterase in differential softening and cell wall modification during papaya fruit ripening

Papaya ( Carica papaya L. cv. Eksotika) fruit softens differentially in relation to position of the tissue. The inner mesocarp tissue is softer, and its firmness decreases more rapidly during ripening than that of the outer mesocarp tissue. As the fruit ripens, pectin solubility and depolymerisation increase. Hemicellulose, too, appears to be depolymerised but, unlike pectins, this apparent degradation of hemicellulose is associated with an increase rather than a decrease in its level. Pectin and hemicellulose depolymerisation began in the inner mesocarp tissue at about the same time as β-galactosidase (EC 3.2,1.23) activity started to increase and tissue firmness began to decrease more rapidly. In contrast, pectin solubilisation in both outer and inner mesocarp tissues occurred steadily throughout ripening at a comparable rate and paralleled closely the increase of polygalacturonase (PG; EC 3.2.1.67) and pectinesterase (EC 3.1.1.11). In general, irrespective of enzyme distribution, tissue softening during ripening was more closely related to changes in β-galactosidase activity than to PG or pectinesterase activity. Papaya, β-galactosidase appears to be an important wall degrading enzyme and may contribute significantly to differential softening, perhaps by complementing the action of polygalacturonase. Polygalacturonase activity increased with increasing depth of the mesocarp tissue, as did softening of the fruit.     

Isolation, characterization and significance of papaya β‐galactanases to cell wall modification and fruit softening during ripening

β‐Galactosidases (EC 3.2.1.23) from ripe papaya ( Carica papaya L. cv. Eksotika) fruits having galactanase activities were fractionated by a combination of cation exchange and gel‐filtration chromatography into three isoforms, viz., β‐galactosidase I, II and III. The native proteins of the respective isoforms have apparent molecular masses of 67, 67 and 55 kDa, each showing one predominant polypeptide upon SDS‐PAGE of about 31 and 33 kDa for β‐galactosidases I and III, respectively, and of 67 kDa for β‐galactosidase II. The β‐galactosidase I protein, which was undetectable in immature fruits, appeared to be specifically accumulated during ripening. The β‐galactosidase II protein was present in developing fruits, but its level seemed to decrease with ripening. β‐Galactosidase I seemed to be an important softening enzyme; its activity increased dramatically (4‐ to 8‐fold) to a peak early during ripening and correlated closely with differential softening as related to position in the fruit tissue. The inner mesocarp tissue was softer, and its wall pectins were modified earlier and firmness decreased more rapidly during ripening compared to the outer mesocarp tissue. β‐Galactosidase II also may contribute significantly to softening because of its ability to catalyse increased solubility and depolymerization of pectins as well as through its ability to modify the alkali‐soluble hemicellulose fraction of the cell wall. The physiological significance of both β‐galactosidase isoforms may partly be attributed to their functional capacity as β‐(1,4)‐galactanases.     

A hemicellulosic β-glucan from the hypocotyls of Phaseolus aureus

A glucan of $\text{DP}$_nca 80 has been isolated from the hypocotyls of mung bean plants (Phaseolus aureus). Methylation analysis and periodate oxidation studies showed that the glucan has (1 → 3) and (1 → 4) linked d-glucopyranosyl residues in the molar ratio 1·0:1·7. Oligosaccharides containing both β(1 → 3) and β(1 → 4) linked residues were isolated from partial hydrolysates.