连续温度变化对β-1,3-葡聚糖酶酶解酵母β-葡聚糖的影响

为了探索反应温度对产物组分的影响,利用自制连续变化的温度梯度实验装置,研究了22 ℃~60 ℃ (±0.1 ℃) 区间内温度对一内切β-1,3-葡聚糖酶酶解酵母β-葡聚糖的影响,获得了酶解过程多点温度特性数据。分析表明：该酶酶解酵母β-葡聚糖的活化能为84.17 kJ/mol;以产物积累表示的最适酶解温度随时间延长呈指数下降;酶解产物组分受温度的影响,低温较高温获得的寡糖链长,高温区大于46 ℃可以获得以昆布二糖、昆布三糖为主的组分,而低温区小于30 ℃可以获得昆布五糖及更大分子量的产物。研究结果可为寡糖     

青稞中β-1,3-葡聚糖酶的纯化及其抗血清的制备

萌发的青稞种子经醋酸钠缓冲液抽提,50％～85％硫酸铵分级沉淀,DEAE—Cellulose52、CM—SepharoseFastFlow离子交换层析和SephadexG-75分子筛层析,得到具活性的β-1,3-葡聚糖酶。SDS—PAGE检测显示分子量27kDa左右的主带（95％）。将纯化的β-1,3．葡聚糖酶对新西兰兔进行免疫制备抗血清,双向免疫扩散测定效价为1：64。免疫印迹分析表明纯化的β—1,3-葡聚糖酶免疫杂交带亦在27kDa处。     

解淀粉芽孢杆菌β-1,3-1,4-葡聚糖酶的高效表达

目的:克隆解淀粉芽孢杆菌β-1,3-1,4-葡聚糖酶基因(bglA)使其在解淀粉芽孢杆菌CICIM B4081中高效表达,并对重组酶进行酶学性质研究.方法:以解淀粉芽孢杆菌(CICIM B4801)染色体DNA为模板,经过PCR扩增得到了大小约为0.8kb的β-1,3-1,4-葡聚糖酶基因(bglA),构建了重组表达质粒pQ-bglA,通过电转化的方法将其转化人解淀粉芽孢杆菌(CICIM B4801)中.结果:得到了能高效表达β-1,3-1,4-葡聚糖酶的重组解淀粉芽孢杆菌.在250mL摇瓶条件下,重组菌分解地衣多糖的胞外最高酶活达到了1515.7U/mL,重组酶的最适作用温度为55℃,最适反应pH值为6.5.结论:重组菌的β-1,3-1,4-葡聚糖酶的酶活为原始菌株的11.84倍,实现了bglA基因在解淀粉芽孢杆菌中的高效表达.     

枯草芽孢杆菌产β-1,3-1,4-葡聚糖酶的响应面优化

【目的】采用响应面法(RSM)优化枯草芽孢杆菌5 L发酵罐产β-1,3-1,4-葡聚糖酶的发酵条件。【方法】利用Box-Behnken设计和方差分析。【结果】获得最佳发酵条件为:转速、通气量和培养基pH分别为500 r/min、1.05 vvm和5.08,发酵时间仅为22 h产β-1,3-1,4-葡聚糖酶活力达2 294.4 U/mL。【结论】实验结果表明响应面法优化5 L发酵罐发酵产β-1,3-1,4-葡聚糖酶的条件合理可行。     

绿色木霉LTR-2 β-1, 3-葡聚糖酶基因的克隆及其在 毕赤酵母中的表达

根据从GenBank中检索到的木霉菌β-1,3-葡聚糖酶基因序列设计引物,以高产β-1,3-葡聚糖酶菌株--绿色木霉LTR-2的cDNA为模板,采用PCR方法扩增得到内切β-1,3-葡聚糖酶基因(glu).将glu克隆至载体pMD18-T上,进行了全序列测定.序列分析表明该基因由2289个核苷酸残基组成,含有一个开放阅读框架,可以编码762个氨基酸,与报道基本相同.翻译后的氨基酸序列含有两个β-1,3-葡聚糖酶的保守区RVVYIPPGTY和AASQNKVAYF.基因与已发表的木霉β-1,3-葡聚糖酶基因有较高的同源性,其中和哈茨木霉bgn3.1和绿木霉bgn13.1的同源性达到93%.序列已经提交GenBank,登录号为EF176582.将glu基因插入到巴斯德毕赤酵母(Pichia pastoris)穿梭载体pPIC9K中,获得重组质粒pGLU14,经线性化后转化毕赤酵母菌株KM71.经大量平板筛选,获得能有效分泌表达β-1,3-葡聚糖酶的毕赤酵母工程菌株KGLU14,菌落PCR扩增证实了glu基因已经整合到酵母基因组中.SDS电泳结果表明其β-1,3-葡聚糖酶的分子量大约为80kDa,和理论推测值大致相同.摇瓶发酵结果表明,培养基中β-1,3-葡聚糖酶的活力可达889U/mL.     

小麦叶片β-1,3-葡聚糖酶的诱导、纯化与抗菌活性

三个小麦品种331、抗倒680和鲁麦23经氯化汞、水杨酸或核黄素处理后,叶片中的β-1,3-葡聚糖酶活性均有不同程度的升高.氯化汞处理24h对品种331该酶活性的诱导作用最强.因此取用氯化汞处理24 h的331小麦叶片研磨得到粗酶液.将粗酶液经硫酸铵分级沉淀、Phenyl-Sepharose Fast Flow疏水层析、DEAE-Sepharose Fast Flow阴离子交换层析和Sephacryl S-100分子筛层析,得到了SDS-PAGE凝胶电泳谱带单一的β-1,3-葡聚糖酶样品.经SDS-PAGE(12%)和凝胶过滤层析,测得其分子量约为52.0～53.6 kD.抗菌试验测定显示,纯化的β-1,3-葡聚糖酶对供试的4种病原真菌的生长、孢子萌发或芽管伸长都有一定程度的抑制作用.     

酵母葡聚糖对丹参毛状根过氧化物酶和苯丙氨酸解氨酶的影响

为利用转化的丹参毛状根生产丹参中的药理活性物质,从啤酒酵母细胞壁中应用碱处理方法制备β-1,3-葡聚糖。利用全酵母细胞壁和酵母葡聚糖的水解产物分别诱导悬浮培养的丹参毛状根,比较它们对丹参毛状根的形态和根组织过氧化物酶、苯丙氨酸解氨酶的影响。结果表明,酵母葡聚糖比全酵母细胞壁水解产物更显著促进丹参毛状根组织的过氧化物酶和苯丙氨酸解氨酶的总活性,酵母葡聚糖的诱导效应具有浓度依赖性和时效性。酵母葡聚糖显著促进丹参毛状根的生长和根端膨大。葡聚糖是有潜力的丹参生长和次生代谢调节剂。     

β-1,3-1,4葡聚糖酶基因克隆表达及其抗菌活性与机理研究进展

β-1,3．1,4-葡聚糖酶是一类能水解β-1,3．糖苷键和β-1,4-糖苷键的酶,因其主要分解大麦中的β-1,3-1,4-葡聚糖和细菌地衣多糖,所以又称地衣多糖酶。综述了β-1,3．1,4-葡聚糖酶基因的克隆表达及其抗菌活性与机理最新研究进展。     

乙醇-酶体系预处理结合水提法提取灵芝中β-葡聚糖的研究

采用乙醇-酶预处理体系,结合水提法较系统地研究了灵芝子实体中β-葡聚糖的提取技术。结果表明,乙醇-酶体系预处理的关键参数为:乙醇质量分数60%(V/V),加酶量1.5%(M/V,g/m L)、酶解温度45℃、酶解p H8.0;在乙醇-酶体系预处理的基础上,进一步采用单因素试验和Box-Benhnken试验设计与响应面分析法对灵芝子实体中β-葡聚糖的热水提取工艺进行了优化。结果显示水提温度、提取时间、水料比3个因素及水提温度与水料比二者的交互作用对β-葡聚糖的提取有显著影响。经优化后获得3个核心因素的最佳水平为:提取温度80℃、提取时间2.5h、水料比35:1。在乙醇-酶预处理结合水提取条件下,灵芝子实体中β-葡聚糖的提取得率可达0.412mg/g,是传统无水乙醇回流预处理结合水提法提取β-葡聚糖得率的2.1倍。本研究为灵芝β-葡聚糖的进一步提取放大试验奠定了技术基础。     

细菌编码β-1,3-1,4-葡聚糖酶催化活性优化方法

β-1,3-1,4-葡聚糖酶是一类专一降解β-葡聚糖的内切水解酶。高效β-葡聚糖酶在啤酒酿造工业上具有十分重要的应用价值。目前,研究较多的β-1,3-1,4-葡聚糖酶主要来源于细菌。文中概述了细菌编码β-1,3-1,4-葡聚糖酶的分子生物学性质,并且从蛋白分子改造、表达调控和发酵条件优化三方面阐述了其催化活性提高的方法和成果。     

食药用菌功能性β-葡聚糖荧光法测定研究

以酵母功能性β-1,3/1,6-葡聚糖为对照品,利用苯胺蓝和β-1,3/1,6-葡聚糖特异结合荧光特性,研究了葡聚糖荧光法测定时的各影响因素,建立了荧光法测定食药用菌功能性β-葡聚糖的方法。pH9.6缓冲液,80℃条件下避光反应15min,室温30min冷却后,398nm激发波长,508nm发射波长,20℃下进行荧光测定。在测定浓度2-20μg/mL范围内,荧光强度与浓度具有良好的线性关系(R2=0.9977),其中检出限为45μg/L,测定精密度和加样回收率良好,相对标准偏差(RSD)分别为1.86%和3.40%,并与酶法进行了比对验证,一致性良好,且荧光法更为节约时间和成本,并对灰树花菌、巴氏蘑菇、香菇和鲍氏针层孔菌四种食药用菌β-葡聚糖提取样品进行了葡聚糖纯度和提取率测定。     

Absence of fks1p in lager brewing yeast results in aberrant cell wall composition and improved beer flavor stability

The flavor stability during storage is very important to the freshness and shelf life of beer. However, beer fermented with a yeast strain which is prone to autolyze will significantly affect the flavor of product. In this study, the gene encoding β-1,3-glucan synthetase catalytic subunit (fks1) of the lager yeast was destroyed via self-clone strategy. β-1,3-glucan is the principle cell wall component, so fks1 disruption caused a decrease in β-1,3-glucan level and increase in chitin level in cell wall, resulting in the increased cell wall thickness. Comparing with wild-type strain, the mutant strain had 39.9 and 63.41 % less leakage of octanoic acid and decanoic acid which would significantly affect the flavor of beer during storage. Moreover, the results of European Brewery Convention tube fermentation test showed that the genetic manipulation to the industrial brewing yeast helped with the anti-staling ability, rather than affecting the fermentation ability. The thiobarbituric acid value reduced by 65.59 %, and the resistant staling value increased by 26.56 %. Moreover, the anti-staling index of the beer fermented with mutant strain increased by 2.64-fold than that from wild-type strain respectively. China has the most production and consumption of beer around the world, so the quality of beer has a significant impact on Chinese beer industry. The result of this study could help with the improvement of the quality of beer in China as well as around the world.     

The scale-up cultivation of Candida utilis in waste potato juice water with glycerol affects biomass and β(1,3)/(1,6)-glucan characteristic and yield

New ideas on production of yeast origin β-glucan preparations for industrial application are attracting interest considering market development of that high-value functional polysaccharide. Sellecting an efficient yeast producer and designing culture conditions are a prerequisite for obtaining high yield of β-glucan. The aim of this study was to describe at the first time the influence of the mode of cultivation (shake-flasks and batch fermentation) and time of culture on characteristic and yield of biomass and β(1,3)/(1,6)-glucan preparations of Candida utilis ATCC 9950 after cultivation in medium based on waste potato juice water supplemented with 10% of glycerol. After shake-flask culture, the biomass was characterized by higher protein content (app. 26.5%) compared to 19% after batch fermentation while the cultivation on a biofermentor scale promoted polysaccharides biosynthesis. The highest output of purified β(1,3)/(1,6)-glucan preparation (5.3 g_d.w./L), containing app. 85% of that polysaccharide, was found after 48 h cultivation in biofermentor. Batch fermentation promoted biosynthesis of alkali-insoluble β(1,3)/(1,6)-glucan fraction, decreasing the content of β(1,6)-glucan. The yield of β(1,3)/(1,6)-glucan synthesis was 0.063 (g/g glycerol), while the productivity of that polysaccharide reached 0.094 (g/L/h). Longer batch fermentation (72 h) resulted in reduction of production efficiency of β-glucan preparation under studied conditions. The results of the study provide a new efficient biotechnological solution to produce high-value β-glucan preparations of C. utilis origin based on valorization of agro-waste potato juice water with glycerol.

     

Digestion of Yeasts and Beta-1,3-Glucanases in Mosquito Larvae: Physiological and Biochemical Considerations

Aedes aegypti larvae ingest several kinds of microorganisms. In spite of studies regarding mosquito digestion, little is known about the nutritional utilization of ingested cells by larvae. We investigated the effects of using yeasts as the sole nutrient source for A. aegypti larvae. We also assessed the role of beta-1,3-glucanases in digestion of live yeast cells. Beta-1,3-glucanases are enzymes which hydrolyze the cell wall beta-1,3-glucan polyssacharide. Larvae were fed with cat food (controls), live or autoclaved Saccharomyces cerevisiae cells and larval weight, time for pupation and adult emergence, larval and pupal mortality were measured. The presence of S. cerevisiae cells inside the larval gut was demonstrated by light microscopy. Beta-1,3-glucanase was measured in dissected larval samples. Viability assays were performed with live yeast cells and larval gut homogenates, with or without addition of competing beta-1,3-glucan. A. aegypti larvae fed with yeast cells were heavier at the 4^th instar and showed complete development with normal mortality rates. Yeast cells were efficiently ingested by larvae and quickly killed (10% death in 2h, 100% in 48h). Larvae showed beta-1,3-glucanase in head, gut and rest of body. Gut beta-1,3-glucanase was not derived from ingested yeast cells. Gut and rest of body activity was not affected by the yeast diet, but head homogenates showed a lower activity in animals fed with autoclaved S. cerevisiae cells. The enzymatic lysis of live S. cerevisiae cells was demonstrated using gut homogenates, and this activity was abolished when excess beta-1,3-glucan was added to assays. These results show that live yeast cells are efficiently ingested and hydrolyzed by A. aegypti larvae, which are able to fully-develop on a diet based exclusively on these organisms. Beta-1,3-glucanase seems to be essential for yeast lytic activity of A. aegypti larvae, which possess significant amounts of these enzyme in all parts investigated.     

两步法硫酸水解热凝胶生产β-1,3-葡寡糖

对硫酸水解热凝胶制备β-1,3-葡寡糖进行了研究。首先建立了葡寡糖的分析方法,采用半制备HPLC分离热凝胶水解液得到β-1,3-葡寡糖,利用ESI-MS和TLC技术对分离组分进行了成分鉴定。考察了反应温度和反应时间对热凝胶寡糖收率的影响,结果表明,两步法硫酸水解获取低聚合度β-1,3-热凝胶寡糖(DP 2~6)的较优水解条件为:1.0 mol/L硫酸于70℃水解1%热凝胶6h,回收水解残留物后于80℃继续水解3 h;对于较高聚合度寡糖(DP 7~10)两步水解时间分别为4 h和1 h较为合适。     

The yeast-phase virulence requirement for α-glucan synthase differs among Histoplasma capsulatum chemotypes

Histoplasma capsulatum strains can be classified into two chemotypes based on cell wall composition. The cell wall of chemotype II yeast contains a layer of α-(1,3)-glucan that masks immunostimulatory β-(1,3)-glucans from detection by the Dectin-1 receptor on host phagocytes. This α-(1,3)-glucan cell wall component is essential for chemotype II Histoplasma virulence. In contrast, chemotype I yeast cells lack α-(1,3)-glucan in vitro, yet they remain fully virulent in vivo. Analysis of the chemotype I α-glucan synthase (AGS1) locus revealed a 2.7-kb insertion in the promoter region that diminishes AGS1 expression. Nonetheless, AGS1 mRNA can be detected during respiratory infection with chemotype I yeast, suggesting that α-(1,3)-glucan could be produced during in vivo growth despite its absence in vitro. To directly test whether AGS1 contributes to chemotype I strain virulence, we prevented AGS1 function by RNA interference and by insertional mutation. Loss of AGS1 function in chemotype I does not impair the cytotoxicity of ags1(-) mutant yeast to cultured macrophages, nor does it affect the intracellular growth of yeast. In a murine model of histoplasmosis, the ags1(-) chemotype I mutant strains show no defect in lung infection or in extrapulmonary dissemination. Together, these studies demonstrate that AGS1 expression is dispensable for chemotype I yeast virulence, in contrast to the case for chemotype II yeast. Despite the absence of cell wall α-(1,3)-glucan, chemotype I yeast can avoid detection by Dectin-1 in a growth stage-dependent manner. This suggests the production of a unique Histoplasma chemotype I factor that, at least partially, circumvents the α-(1,3)-glucan requirement for yeast virulence.     

Mechanism by which orally administered beta-1,3-glucans enhance the tumoricidal activity of antitumor monoclonal antibodies in murine tumor models

Antitumor mAb bind to tumors and activate complement, coating tumors with iC3b. Intravenously administered yeast beta-1,3;1,6-glucan functions as an adjuvant for antitumor mAb by priming the inactivated C3b (iC3b) receptors (CR3; CD11b/CD18) of circulating granulocytes, enabling CR3 to trigger cytotoxicity of iC3b-coated tumors. Recent data indicated that barley beta-1,3;1,4-glucan given orally similarly potentiated the activity of antitumor mAb, leading to enhanced tumor regression and survival. This investigation showed that orally administered yeast beta-1,3;1,6-glucan functioned similarly to barley beta-1,3;1,4-glucan with antitumor mAb. With both oral beta-1,3-glucans, a requirement for iC3b on tumors and CR3 on granulocytes was confirmed by demonstrating therapeutic failures in mice deficient in C3 or CR3. Barley and yeast beta-1,3-glucan were labeled with fluorescein to track their oral uptake and processing in vivo. Orally administered beta-1,3-glucans were taken up by macrophages that transported them to spleen, lymph nodes, and bone marrow. Within the bone marrow, the macrophages degraded the large beta-1,3-glucans into smaller soluble beta-1,3-glucan fragments that were taken up by the CR3 of marginated granulocytes. These granulocytes with CR3-bound beta-1,3-glucan-fluorescein were shown to kill iC3b-opsonized tumor cells following their recruitment to a site of complement activation resembling a tumor coated with mAb.     

Altered extent of cross-linking of beta1,6-glucosylated mannoproteins to chitin in Saccharomyces cerevisiae mutants with reduced cell wall beta1,3-glucan content.

The yeast cell wall contains beta1,3-glucanase-extractable and beta1,3-glucanase-resistant mannoproteins. The beta1,3-glucanase-extractable proteins are retained in the cell wall by attachment to a beta1,6-glucan moiety, which in its turn is linked to beta1,3-glucan (J. C. Kapteyn, R. C. Montijn, E. Vink, J. De La Cruz, A. Llobell, J. E. Douwes, H. Shimoi, P. N. Lipke, and F. M. Klis, Glycobiology 6:337-345, 1996). The beta1,3-glucanase-resistant protein fraction could be largely released by exochitinase treatment and contained the same set of beta1,6-glucosylated proteins, including Cwp1p, as the B1,3-glucanase-extractable fraction. Chitin was linked to the proteins in the beta1,3-glucanase-resistant fraction through a beta1,6-glucan moiety. In wild-type cell walls, the beta1,3-glucanase-resistant protein fraction represented only 1 to 2% of the covalently linked cell wall proteins, whereas in cell walls of fks1 and gas1 deletion strains, which contain much less beta1,3-glucan but more chitin, beta1,3-glucanase-resistant proteins represented about 40% of the total. We propose that the increased cross-linking of cell wall proteins via beta1,6-glucan to chitin represents a cell wall repair mechanism in yeast, which is activated in response to cell wall weakening.     

Chemical and ultrastructural studies on the cell walls of the yeastlike and mycelial forms of Histoplasma farciminosum

The cell wall of the yeast form of Histoplasma farciminosum contains 13.2% beta-1,3-glucan, 1.0% galactomannan, and 25.8% chitin, whereas the cell wall of mycelial form has 21.8, 4.5, and 40%, respectively, for the same polymers. Also, the cell wall of the yeast form contains alpha-1,3-glucan (13.5%) and an unidentified polymer (21.5%). Chitin, one of the structural polymers of both yeast and mycelial cell walls, is identified as thin isolated fibers (4 nm wide) or in thick bundles (50 nm wide) of fibers. beta-(1-3)-Glucan is also found as thin isolated fibers indistinguishable from isolated fibers of chitin. Fibers 14 nm wide and resembling alpha-(1-3)-glucan fibers of other fungi are found in the yeast form. The results reported here do not give support to the proposal for a different taxonomic classification.     

Purification and characterization of beta-1,6-glucanase of Streptomyces rochei application in the study of yeast cell wall proteins

A beta-1,6-glucanase was purified to apparent homogeneity from a commercial yeast digestive enzyme prepared from Streptomyces rochei by a series of column chromatographies. The molecular mass of the purified enzyme was 60 kDa by SDS-PAGE. The purified enzyme had an optimum pH range from 4.0 to 6.0 and was stable in the same pH range. The enzyme was stable under 50 degrees C but lost almost all activity at 60 degrees C. The enzyme was specific to beta-1,6-glucan and had little activity towards beta-1,3-glucan and beta-1,4-glucan. When the beta-1,6-glucan was hydrolyzed with the purified enzyme for 5 h, the reaction products contained 20% glucose, 36% gentiobiose, and 44% other oligosaccharides, suggesting that the enzyme is an endo-type glucanase. When the purified enzyme was used for the digestion of the cell wall of Saccharomyces cerevisiae, cell-wall proteins covalently bound to the cell-wall glucan were recovered as soluble forms, suggesting that this enzyme is useful for analysis of yeast-cell wall proteins.