可同化阿拉伯糖的木糖还原酿酒酵母菌株构建

[目的] 以秸秆等木质纤维素类生物质为原料生产液体生物燃料乙醇,目前生产成本高,大规模工业化生产尚有较大难度。构建能同化阿拉伯糖进行木糖还原生产木糖醇的重组酿酒酵母菌株,以实现原料中全糖利用、生产高附加值产品,实现产品多元化。[方法] 首先,利用CRISPR/Cas9基因编辑技术依次向出发菌株中导入阿拉伯糖代谢途径和木糖还原酶基因,使菌株获得代谢阿拉伯糖和将木糖转化为木糖醇的能力;其次,通过适应性驯化的进化工程手段,提高重组菌株对阿拉伯糖的利用效率;最后,通过混合糖发酵验证重组菌株利用阿拉伯糖和还原木糖产木糖醇的能力。[结果] 通过导入植物乳杆菌的阿拉伯糖代谢途径,酿酒酵母菌株获得了较好的利用阿拉伯糖生长繁殖的能力;进一步导入假丝酵母的木糖还原酶基因后,重组菌株在葡萄糖作为辅助碳源条件下可高效还原木糖产木糖醇,但阿拉伯糖的利用能力下降。利用以阿拉伯糖为唯一碳源的培养基进行反复批次驯化,阿拉伯糖的利用能力得以恢复和提升,得到表型较好的重组菌株KAX3-2。该菌株在木糖（50 g/L）和阿拉伯糖（20 g/L）混合糖发酵条件下发酵72 h时,对阿拉伯糖和木糖利用率分别达到42.1%和65.9%,木糖醇的收率为64%。[结论] 本研究成功构建了一株能有效利用阿拉伯糖并能将木糖转化为木糖醇的重组酿酒酵母菌株KAX3-2,为后续构建、获得阿拉伯糖代谢能力更强、木糖醇积累效率更高菌株的工作奠定了基础。     

酸性土壤中高效半纤维素降解菌的筛选与鉴定

【目的】筛选能够适应南方酸性土壤的高效半纤维素降解菌株,并进行鉴定,确定菌株的安全性。【方法】采用半纤维素平板水解圈法和胞外酶测定法进行菌株筛选,通过拮抗实验构建复合微生物菌系。利用培养特征、形态学、生理生化特征和分子生物学方法进行菌株鉴定。【结果】筛选出效果稳定,互不拮抗的高效半纤维素降解放线菌4株(NA9、NA10、NA12和NA13),半纤维素酶活分别为:217.6、229.8、221.1和211.8 U/mL。真菌2株NF1和NF7,半纤维素酶活为217.7和244.2 U/mL。复合微生物菌系半纤维素酶活可达299.0 U/mL。经鉴定菌株NA9、NA10、NA12和NA13为链霉菌中的哥斯达黎加链霉菌(Streptomyces costaricanus)。菌株NF1为亮白曲霉(Aspergillus candidus),菌株NF7为黄蓝状菌(Tarlaromyces flavus)。     

产D-乳酸重组大肠杆菌ptsG基因的敲除及其混合糖同步发酵

为构建能够同时高效利用五碳糖和六碳糖发酵产D-乳酸的重组大肠杆菌工程菌,以能高效利用五碳糖发酵产D-乳酸的大肠杆菌工程菌E.coli JH13为出发菌株,通过Red同源重组技术敲除葡萄糖跨膜转运基因pts G。实验结果表明,pts G缺陷菌株E.coli JH15在10%混合糖(5%葡萄糖和5%木糖)培养基中发酵,可同时利用五碳糖和六碳糖以完成发酵;而对照菌葡萄糖消耗完才利用木糖,发酵结束还有18 g/L木糖残留;JH15乳酸产量为83.04 g/L,相比于对照菌株提高了25.86%;在稻草秸秆水解液中发酵,JH15同时利用葡萄糖、木糖和L-阿拉伯糖,乳酸产量为25.15 g/L,转化率为86.42%。JH15作为能利用混合糖同步发酵产D-乳酸的大肠杆菌工程菌,它的成功构建为利用廉价的木质纤维素水解物为原料发酵生产D-乳酸提供参考依据。     

利用木糖-葡萄糖为原料产乙醇酵母的筛选、鉴定及发酵试验

建立筛选利用木糖为碳源产乙醇酵母模型,获得一株适合利用木质纤维素为原料产乙醇的酵母菌株。样品经麦芽汁培养基培养后,以木糖为唯一碳源的筛选培养基初筛,再以重铬酸钾显色法复筛。通过生理生化和26D1/D2区对筛选得到的菌株进行分析和鉴定,该菌初步鉴定为Pichia caribbica。经过筛选得到的菌株Y2-3以木糖（40g/L）为唯一碳源发酵时：生物量为23.5g/L,木糖利用率为94.7 %,乙醇终产量为4.57 g/L;以混合糖（葡萄糖40 g/L,木糖20 g/L）发酵时：生物量为28.6 g/L,木糖利用率为94.2 %,葡萄糖利用率为95.6%,乙醇终产量为20.6 g/L。Pichia caribbica是可以转化木糖及木糖-葡萄糖混合糖为乙醇的酵母菌株,为利用木质纤维素发酵乙醇的进一步研究奠定了基础。     

产木聚糖酶的沿海红树林真菌筛选及其培养与酶活测定条件优化

从香港海岸红树林分离到的 77株真菌中有 34株可产生木聚糖酶 ,从中选出CY2 80 9(Staganosporasp .)、CY4 786和CY5 0 4 0等 3菌株与已知陆生产酶菌株HU5 0 4 8(Aspergillusawamori)进行产木聚糖酶的比较研究。根据培养液中菌丝生物量、木聚糖酶活力和木糖等价还原糖含量等指标的测定 ,菌株CY4 786在起始pH 7 8的木聚糖 酵母膏 海盐液体培养基中 2 5℃下震荡 (10 0r min)培养 7d产酶最佳 ;粗酶液在 5 0℃和pH 4 6的优化条件下进行测定 ,木聚糖酶活力达到 1 0 7× 10 4 U mL。结果表明 ,红树林真菌起着半纤维素降解者的作用 ,沿海红树林环境中存在着可资利用的木聚糖酶产生菌。作者讨论了利用发酵液中木糖等价还原糖含量的动态变化作为快速筛选产木聚糖酶菌株的指标的可能性     

青霉菌胞外半纤维素酶的纯化及其性质研究

半纤维素是由己糖和戊糖组成的异质多糖,约占陆生植物干重的15％～30％,微生物产生的半纤维素酶（hendcellulas）可降解半纤维素生成木糖及其它单糖。研究半纤维素生物转化具有重要意义,如在造纸工业的生物制浆和废水处理;转化半纤维素为单糖。酒精等化工产品等。在国外已有不少有关真菌和细菌降解半纤维素的研究［‘·‘］,国内有关真菌降解半纤维素的研究工作已开始逐步展开【｝‘」,但有关青霉菌胞外半纤维素酶的产酶条件及其性质尚未见报道。本研究在优化青霉菌胞外半纤维素酶发酵条件的基础上,对粗酶液进行f初步纯化,并对其讲…     

丙酸杆菌属中的一个新种

从沼气发酵液中,分离出几株丙酸菌。该菌为革兰氏阳性、不形成芽孢的兼性厌氧菌。厌氧培养在BPYL培养基上细胞为球形;在BPY培养基上细胞则为杆状。能利用20多种糖和醇产酸,产生丙酸和乙酸。水解七叶苷,还原硝酸盐,过氧化氢酶阳性,不液化明胶,不产生吲哚。不利用D-阿拉伯糖和木糖产酸。该菌株属于丙酸杆菌属中的一个新种,定名为北京丙酸杆菌 Propionibacterium beijingense sp nov。     

一株耐冷玫红假裸囊菌HD1031的鉴定及其所产纤维素酶的研究

[目的]以纤维素为唯一碳源,从四川省阿坝自治州黄龙沟的高山低温环境中分离筛选产纤维素酶的耐冷菌,并研究菌株的产酶特征.[方法]根据菌株的ITS序列分析及形态特征,对菌株进行鉴定.利用DNS法测定纤维素酶酶活性.[结果]从四川省阿坝自治州黄龙沟的高山腐殖土中筛选出一株产纤维素酶的耐冷菌HD1031,经鉴定该菌为玫红假裸囊菌(Pseudogymnoascus roseus).该菌可在4℃-25℃生长,最适生长温度为16℃-17℃.该菌在以微晶纤维素和玉米芯粉为碳源、硫酸铵和Tryptone为氮源的培养基中,17℃、160 r/min摇瓶发酵8d后产生纤维素酶,其中内切葡聚糖酶酶活为366.67 U/mL,滤纸酶酶活87.6 U/mL,β-葡萄糖苷酶酶活90.8 U/mL,酶最适反应pH为6.0,最适反应温度为50℃.[结论]筛选获得一株产纤维素酶的耐冷菌HD1031,此菌株所产纤维素酶在20℃-40℃下活性较高,对热敏感,具有低温纤维素酶的特点.     

一株产纤维素酶菌株的分离、鉴定及产酶特性

【目的】筛选并鉴定一株产纤维素酶的菌株,初步探究该菌的产酶特性,为综合利用纤维素筛选菌源。【方法】在常温条件下,采用滤纸培养基对菌种富集,采用CMC-Na初筛纤维素降解菌,采用LB培养基分离纯化菌株,经形态学、生理生化特征试验、16S r RNA基因序列测定等分析筛选菌株的系统分类地位。单因素试验确定培养时间、培养温度、初始p H及Na Cl浓度对筛选菌株产酶活力的影响。【结果】从腐烂的玉米秸秆中分离出一株在常温下产纤维素酶细菌KZ-2,根据菌落形态特征、生理生化特征鉴定以及16S r RNA基因序列分析,初步鉴定KZ-2为肠杆菌(Enterobacter sp.),为潜在新种。产酶条件实验显示:该菌使用产酶发酵培养基120 h产酶量达到最大值,在25–35°C、初始p H 4.5–5.5、Na Cl浓度1.0%–2.0%范围内为最佳产酶条件,在最适条件下酶活可达80.93 U/m L。该菌株所产纤维素酶最适反应p H为7.0,最适反应温度为50°C。【结论】KZ-2是一株具有降解纤维素能力的细菌,在常温下即可分泌纤维素酶,并且该菌株为潜在新种,具有潜在的开发价值。     

生物垃圾好氧处理中的纤维素降解菌生长规律研究

目的:研究了蔬菜垃圾好氧处理过程中,纤维素降解菌和半纤维素降解菌(细菌和真菌),纤维素酶活和半纤维素酶活,和有机物降解之间的变化规律。方法:用添加纤维素和半纤维素的牛肉膏蛋白胨培养基和查式培养基,分别培养计数纤维素降解细菌、真菌和半纤维素降解细菌、真菌;马福炉灼烧测有机物含量。结果:好氧处理的初始阶段中,前4d有机物日均降解率5.2%,后3d日均降解率2.2%。结论:半纤维素降解菌的数量比纤维素降解菌的多,半纤维素酶活力,也高于纤维素酶活力;微生物的变化情况为前6d产两种酶的微生物主要有细菌和真菌;从第6d开始真菌快速生长;至第7d真菌纤维素酶和半纤维素酶活力显著升高。     

Production of xylooligosaccharides from enzymatic hydrolysis of xylan by the white-rot fungi Pleurotus

The white-rot fungi basidiomycetes Pleurotus sp. BCCB068 and Pleurotus tailandia were used to degrade oat-spelt xylan under submerged fermentation over a period of 40 days. Activities of endo-1,4-β-xylanase and β-xylosidase and xylan degradation products were determined. Xylan degradation by Pleurotus sp. BCCB068 and P. tailandia reached 75.1% and 73.4%, respectively. The formation of xylooligosaccharides and the simple sugars xylose, arabinose, cellobiose, mannose, and maltose were observed for both strains. The xylan degradation exhibited by these Pleurotus strains indicates they have potential for use in biotechnological processes related to degradation of hemicellulose sources.     

Interactions between rumen bacterial strains during the degradation and utilization of the monosaccharides of barley straw cell-walls

Pure cultures and pair-combinations of strains representative of the rumen cellulolytic species Ruminococcus flavefaciens, Fibrobacter succinogenes and Butyrivibrio fibrisovens were grown on cell-wall materials from barley straw. Of the pure cultures, R. flavefaciens solubilized straw most rapidly. The presence of B. fibrisolvens , which was unable to degrade straw extensively in pure culture, increased the solubilization of dry matter by R. flavefaciens and the solubilization of cell-wall carbohydrates by both R. flavefaciens and F. succinogenes. During fermentation, both R. flavefaciens and F. succinogenes released bound glucose and free and bound arabinose and xylose into solution. The accumulation of these sugars, especially arabinose and xylose, was greatly reduced in co-cultures containing B. fibrisolvens , suggesting that significant interspecies cross feeding of the products of hemicellulose hydrolysis (particularly soluble bound xylose released by F. succinogenes ) occurs during straw degradation by mixed cultures containing this species.     

Studies on the Carbohydrates of Horse Radish,Cochlearis Armoracia L

In the root of horse radish, sucrose, fructose, glucose and two unknown fructose-oligosac-charides were found in the form of free sugars, in the decreasing order just given, and large amounts of starch, hot 50% methanol-soluble polysaccharide, water-soluble polysaccharide, pectin, hemicellulose, cellulose and a small amount of lignin were found as polysaccharides. As the constructive sugar of these polysaccharides, the following, i.e., glucose, fructose, galactose, arabinose, galacturonic acid and xylose were detected.     

Pentose transport by the ruminal bacterium Butyrivibrio fibrisolvens

Abstract Butyrivibrio fibrisolvens is a fibrolytic ruminal bacterium that degrades hemicellulose and ferments the resulting pentose sugars. Washed cells of strain D1 accumulated radiolabelled xylose ( K _m= 1.5 μ M) and arabinose ( K _m= 0.2 μ M) when the organism was grown on xylose, arabinose, or glucose, but cultures grown on sucrose or cellobiose had little capacity to transport pentose. Glucose and xylose inhibited transport of each other non-competitively. Both sugars were utilized preferentially over arabinose, but since they did not inhibit transport of arabinose, it appeared that the preference was related to an internal metabolic step. Although the protonmotive force was completely abolished by ionophores, cells retained some ability to transport pentose. In contrast, the metabolic inhibitors iodoacetate, arsenate, and fluoride had little effect on protonmotive force but caused a large decrease in intracellular ATP and xylose and arabinose uptake. These results suggested that high-affinity, ATP-dependent mechanisms were responsible for pentose transport and hexose sugars affected the utilization of xylose and arabinose.     

Conversion of corn milling fibrous co-products into ethanol by recombinant Escherichia coli strains K011 and SL40

Corn hulls and corn germ meal were both evaluated as feedstocks for production of ethanol for biofuel. Currently, these fibrous co-products are combined with corn steep liquor and the fermentation bottoms (if available) and marketed as cattle feed. Samples were obtained from wet and dry corn mills. The corn hulls and germ meal were evaluated for starch and hemicellulose compositions. Starch contents were 12 to 32% w/w and hemicellulose (arabinoxylans) contents were 23 to 64% w/w. Corn fibrous samples were hydrolysed, using dilute sulphuric acid, into mixed sugar streams containing arabinose, glucose and xylose. Total sugar concentrations in the hydrolysate varied from 8.4 to 10.8% w/v. The hydrolysates were fermented to ethanol using recombinant E. coli strains K011 and SL40. Ethanol yields were 0.38 to 0.41g ethanol produced/g total sugars consumed and fermentations were completed in 60h or less. However, residual xylose was detected for each hydrolysate fermentation and was especially significant for fermentations using strain SL40. Strain K011 was a superior ethanologenic strain compared with strain SL40 in terms of both ethanol yield and maximum productivity.     

Production of citric acid from sugars present in wood hemicellulose usingAspergillus niger andSaccharomycopsis lipolytica

Summary One strain each of the fungus,Aspergillus niger, and the yeast,Saccharomycopsis lipolytica, were investigated for their ability to produce citric acid from the sugars present in hemicellulose hydrolysates.S. lipolytica produced citric acid as efficiently from mannose as from glucose, but failed to assimilate xylose, arabinose or galactose.A. niger readily assimilated mannose, xylose and arabinose, and produced citric acid from these sugars although the yields were lower than from glucose. A possible inhibitory effect of arabinose on citric acid production from other sugars was observed usingA. niger.     

Metabolic engineering applications to renewable resource utilization

Lignocellulosic materials containing cellulose, hemicellulose, and lignin are the most abundant renewable organic resource on earth. The utilization of renewable resources for energy and chemicals is expected to increase in the near future. The conversion of both cellulose (glucose) and hemicellulose (hexose and pentose) for the production of fuel ethanol is being studied intensively, with a view to developing a technically and economically viable bioprocess. Whereas the fermentation of glucose can be carried out efficiently, the bioconversion of the pentose fraction (xylose and arabinose, the main pentose sugars obtained on hydrolysis of hemicellulose), presents a challenge. A lot of attention has therefore been focused on genetically engineering strains that can efficiently utilize both glucose and pentoses, and convert them to useful compounds, such as ethanol. Metabolic strategies seek to generate efficient biocatalysts (bacteria and yeast) for the bioconversion of most hemicellulosic sugars to products that can be derived from the primary metabolism, such as ethanol. The metabolic engineering objectives so far have focused on higher yields, productivities and expanding the substrate and product spectra.     

Hydrolysis of xylan and fermentation of xylose to ethanol

The focus in the development of pulping processes has usually been exclusively on cellulose. However, hemicellulose could serve as a valuable source of hexose and pentose sugars. Consequently, it should not be destroyed in a process designed for very high cellulose fibre yields. Novel procedures developed for production of ethanol by the fermentation of pentoses as well as hexoses provide new possibilities of hemicellulose utilization.

Many fungi produce extracellular hemicellulases. In the present work the production of xylanase and β-xylosidase with strains of Aspergillus and Trichoderma was studied. The enzymes were used for the hydrolysis of xylan. Xylose was fermented to ethanol by the mold Fusarium oxysporum.     

Use of catabolite repression mutants for fermentation of sugar mixtures to ethanol

Use of agricultural biomass, other than corn-starch, to produce fuel ethanol requires a microorganism that can ferment the mixture of sugars derived from hemicellulose. Escherichia coli metabolizes a wide range of substrates and has been engineered to produce ethanol in high yield from sugar mixtures. E. coli metabolizes glucose in preference to other sugars and, as a result, utilization of the pentoses in hemicellulose-derived sugar mixtures is delayed and may be incomplete. Residual sugar lowers the ethanol yield and is problematic for downstream processing of fermentation products. Therefore, a catabolite repression mutant that simultaneously utilizes glucose and pentoses would be useful for fermentation of complex substrate mixtures. We constructed ethanologenic E. coli strains with a glucose phosphotransferase (ptsG) mutation and used the mutants to ferment glucose, arabinose, and xylose, singly and in mixtures, to ethanol. Yields were 87-94% of theoretical for both the wild type and mutants, but the mutants had an altered pattern of mixed sugar utilization. Phosphotransferase mutants metabolized the pentoses simultaneously with glucose, rather than sequentially. Based upon fermentations of sugar mixtures, a catabolite-repression mutant of ethanologenic E. coli is expected to provide more efficient fermentation of hemicellulose hydrolysates by allowing direct utilization of pentoses.     

Isolation and Identification of Native Auxins in Marine Algae

Endosperm cell walls were isolated from rice grains and their chemical composition was analyzed. The cell walls were composed of cellulose microfibrils and matrix phase which consisted of hemicellulose and pectic substances. Hemicellulose mainly comprised arabinoxylan, accompanied by a small amount of glucose-containing polysaccharide. Pectic substances contained polygalacturonides, some of which had side chains containing neutral sugars such as galactose and arabinose. Amino acid analysis of these fractions suggested that hydroxyproline-containing glycoproteins were contained in these cell walls and firmly bound to cellulose microfibrils.