里氏木霉纤维素酶的分离纯化及酶学性质

通过(NH4)2SO4分级沉淀、HiPrep 26/10 Desalting凝胶色谱脱盐、Source 15 Q阴离子交换色谱技术,里氏木霉(Rut C-30)纤维素酶主要组分得以初步分开,再经过Source 15 S阳离子交换色谱、HiPrep Sephacryl S-100 HR凝胶过滤色谱、Superdex 75 PrepGrade凝胶过滤色谱进一步分离纯化,得到2个纯化的内切葡聚糖酶组分EGⅡ、EGⅠ和一个外切葡聚糖酶组分CBHⅠ;经过SDS-PAGE电泳鉴定为电泳纯,测得相对分子质量分别为5.22×104,5.62×104和6.90×104。EGⅡ的最适反应pH是5.6,最适反应温度为65℃;EGⅠ的最适反应pH是4.4,最适反应温度为55℃;以羧甲基纤维素(CMC)为底物时,EGⅠ、EGⅡ的米氏常数(Km)分别为2.20 mg/mL、3.38 mg/mL。CBHⅠ的最适反应pH是5.8,最适反应温度为60℃,以对硝基苯基-β-D-纤维二糖苷(PNPC)为底物时,米氏常数(Km)为0.12 mg/mL。     

Association of Phosphatidylcholine with Soybean 11S Globulin

To address the multiplicity of aromatic ring hydroxylation dioxygenases, we used PCR amplification and denaturing gradient gel electrophoresis (DGGE). The amplified DNA fragments separated into five bands, A to E. Southern hybridization analysis of RHA1 total DNA using the probes for each band showed that band C originated from a couple of homologous genes. The nucleotide sequences of the bands showed that bands A, C, and E would be parts of new dioxygenase genes in RHA1. That of band B agreed with the bphA1 gene, which was characterized previously. That of band D did not correspond to any known gene sequences. The regions including the entire open reading frames (ORFs) were cloned and sequenced. The nucleotide sequences of ORFs suggested that the genes of bands A,C, and E may respectively encode benzoate, biphenyl, and polyhydrocarbon dioxygenases. Northern hybridization indicated the induction of the gene of band A by benzoate and biphenyl, and that of the gene of band C by biphenyl and ethylbenzene, supporting the above notions. The gene of band E was not induced by any of these substrates. Thus the combination of DGGE and Southern hybridization enable us to address the multiplicity of the ring hydroxylation dioxygenase genes and to isolate some of them.     

Pretreatment Of Hardwood (Eucalyptus Regnans) Sawdust By Autohydrolysis Explosion And Its Saccharification By Trichodermal Cellulases

Autohydrolysis explosion pretreatment of hardwood (Eucalyptus regnans) sawdust at 200°C and 6.9 MPa gas pressure (steam + nitrogen) for 5 min solubilized 85% of the total hemicellulose components and produced a pulp that was highly accessible to attack by cellulases from Trichoderma reesei C-30 and by a commercial preparation, Meicelase. The autohydrolysis liquor, representing 15% of the original weight of the sawdust on a solids basis, consisted mainly of xylose, xylose oligomers and minor amounts of galactose, mannose, arabinose, glucose and uronic acids. Enzymic hydrolysis of pretreated E. regnans pulps using Trichodermal cellulases resulted in saccharification yields of <50% within 24 h from 10% (w/v) substrate slurries and 20 cellulase (FPU) units per g of pretreated pulp. The cellulose-to-glucose conversions were lower and this was attributable to the production of a compound(s) during enzymic hydrolysis that was inhibitory to the β-glucosidase component, but not the cellulases, in the Trichodermal cellulase preparations. Enzymic digests supplemented with Novozym 188 β-glucosidase showed >70% cellulose-to-glucose conversion within 24 h under similar conditions of hydrolysis. The inhibitor compound was not inhibitory to the Novozym 188 β-glucosidases. Alkali-extracted autohydrolysis-exploded pulps were less susceptible to hydrolysis than unextracted pulps. Factors that influenced the extent of cellulose conversion into glucose such as enzyme-substrate and cellulase-to-β-glucosidase ratios are also discussed.     

Subunit Structure of Soybean 11S Globulin

The acidic and the basic subunits were shown to be present in equimolar amounts in the 11S globulin molecule by the densitometric scanning of the SDS gel and the molecular weight consideration. The four acidic subunits (A₁, A₂, A₃ and A₄) were found to be present in the approximate molar ratio of 1:1:2:2. Four basic subunits separated and designated as B₁, B₂, B₃ and B₄ based on the relative mobilities in the acidic gel in 7 m urea were found to be present in the approximate molar ratio of 1:1:2:2. The four basic subunits were fractionated in approximately same amounts into three different peaks, peak I (B₁ and B₂), peak II (B₃) and peak III (B₄) by CM-Sephadex C–50 column chromatography in the presence of 6 m urea. Three kinds of intermediary subunits of 11S globulin were fractionated with DEAE-Sephadex A–50 in the absence of reducing agents in 6 m urea, and disulfide bonds appeared to participate in the binding between the acidic and the basic subunits in the molar ratio of 1: 1 with the following combinations; A₁ and A₂ combined with B₃, A₃ with B₁ and B₂, and A₄ with B₄. In view of the above results and molecular weight consideration, a new model of subunit structure was proposed for 11S globulin.     

2种纤维素酶水解效果比较及酶蛋白组分分析

比较了自产纤维素酶和商品纤维素酶的水解效果,并采用超滤、层析、SDS-PAGE相结合的方法分析2种纤维素酶蛋白组分的差异。里氏木霉以纸浆为C源合成的自产纤维素酶的水解得率高于商品纤维素酶,自产纤维素酶水解48h的得率为66.24%,商品纤维素酶的得率为52.19%。自产纤维素酶中存在着Cel6A酶组分和XYNⅡ酶组分,而商品纤维素酶中没有检测到这2种酶组分。自产纤维素酶和商品纤维素酶的Cel1A酶组分和Cel7A酶组分间存在着分布和含量上的差异。自产纤维素酶在相对分子质量(2.5～3.5)×104范围内存在着几条蛋白条带,而商品纤维素酶则是在相对分子质量3.5×104附近存在着几条蛋白条带。     

同步分泌高效纤维素酶和木聚糖酶菌株YB的鉴定及其酶学性质研究

筛选和鉴定可降解木质纤维素的真菌,并研究其产酶特征。采用刚果红平板涂布法,从荔枝腐叶中筛选具有木质纤维素降解能力的真菌,结合ITS-rDNA序列分析进行鉴定,初步测定其产酶条件,然后采用DEAE Sepharose Fast Flow阴离子交换层析与Sephadex G-100凝胶层析对硫酸铵沉淀的粗酶液进行分离纯化,对其开展酶学性质研究。结果显示,筛选出一株可降解木质纤维素降解的菌株YB,鉴定为绿木霉(Trichoderma virens)。在发酵过程中,纤维素酶和木聚糖酶的最大活力分别为313.53±26.78 U/mL和18 120.87±500.37 U/mL。分离纯化得到纤维素酶(CMC酶)Ⅰb、Ⅳ和木聚糖酶Ⅰa;通过SDS-PAGE检测,其分子量分别为58.5 kD、22.8 kD和44.5 kD。3种酶的最适酶促反应条件均为:50℃,pH 5.0。其中,木聚糖酶能有效降解玉米芯木聚糖为木糖和多种木寡糖。菌株Trichoderma virens YB可分泌高效木质纤维素降解酶,具有应用于木聚糖酶和木寡糖生产的潜力。     

Polymerization of Soybean 11S Globulin Due to Reactions with Peroxidizing Linoleic Acid

Soybean 11S globulin was polymerized by incubating with peroxidizing linoleic acid. The molar ratio of the acidic subunits to the basic subunits of 11S globulin decreased with the elapse of the incubation time. The acidic subunits were lost faster and formed polymers more easily than the basic subunits. The acidic and basic subunits in 11S globulin were fractionated by DEAE-Sephadex gel chromatography. Each of the acidic and basic subunits was allowed to react with peroxidizing linoleic acid individually. The results also showed that the acidic subunits formed polymers faster than the basic subunits. Both succinylated and acetylated 11S globulins were also submitted to the incubation with peroxidizing linoleic acid. The polymerization of the modified protein was suppressed by masking ε-amino groups.     

Reevaluation of the Subunit Molecular Weights of Soybean 11S Globulin

The acidic and basic subunits are the main constituents of soybean 11S globulin. Each of these two subunits consists of three major polypeptides of similar size. The molecular weights of the acidic and basic subunits have been previously estimated to be 37,000 and 22,000, respectively, by SDS-polyacrylamide gel electrophoresis (Catsimpoolas et al, J. Set Food. Agric., 22, 448 (1971)). Reevaluation of the molecular weights by 6 m guanidine gel chromatography gave the values of 28,000 and 18,000, respectively. These are supported by results of equilibrium sedimentation in the same solvent. The previously reported values seem to have been overestimated, especially for the acidic subunits. The overestimations seem to be related to the high percentage of acidic amino acids, which causes the conformation of the SDS-protein polypeptide complexes of these subunits to deviate from those of proteins usually employed as standards for molecular weight estimations.     

用Blue Sepharose CL-6B快速纯化天花粉蛋白

差光谱显示染料cibacron blue F3GA与天花粉蛋白(TCS)有特异性结合,复合物在可见光部分的最大吸收波长在690 nm,摩尔消光系数ε=2.6×10^-3(mol/L)^-1·cm^-1,解离常数K_d=1.8 μmol/L,0.5 mol/L NaCl可使复合物解离.根据这一特点,用Blue-Sepharose CL-6B凝胶从栝篓块茎中亲和纯化了TCS.此法快速、简便、高效,易于大量制备.     

里氏木霉与米根霉混合固态发酵产纤维素酶

以里氏木霉及米根霉单菌固态发酵为对象,考察不同混合发酵形式对里氏木霉与米根霉混合固态发酵产纤维素酶的影响。结果表明:同时接种里氏木霉与米根霉,试验考察的两菌种接种量比1∶1(以孢子个数计)及5∶1条件下,两菌未产生明显协同产酶作用。米根霉延时(24 h)接种且菌种量比5∶1以及米根霉延时(48 h)接种且菌种量比1∶1,2种发酵形式产酶情况类似,滤纸酶活(FPA)及羧甲基纤维素酶(CMCase)酶活相对米根霉单菌发酵有所提高,而β-葡萄糖苷酶(β-GA)酶活相对里氏木霉单菌固态发酵结束时分别增加4.66及4.40倍,可以发现两菌产生一定协同作用。在米根霉延时(48 h)接种且菌种量比5∶1的发酵形式下,FPA及CMCase在发酵第7天酶活分别达到44.04 IU/g、627.14 U/g(以1 g干曲计),分别是里氏木霉固态单菌发酵产酶达到稳定期时酶活的1.36和1.63倍,两菌产生了有效的协同作用。     

Localisation of β-glucosidase in Trichoderma reesei cell walls with immunoelectron microscopy

Abstract Using ferritin-conjugated antibodies as an electron microscopic marker, β-glucosidase was localized within the cell walls of the imperfect fungus Trichoderma reesei QM9414. With different states of cell wall degradation obtained with a cell wall-lysing culture filtrate of Micromonospora chalcea , β-glucosidase was mainly detected within the outer, fibrous exopolysaccharide layer and the outer face of the plasma membrane.     

根癌农杆菌介导的VHb异源表达及其对里氏木霉的影响

里氏木霉是生产纤维素酶的重要菌株,在其浸没式发酵过程中,氧传递是重要影响因素。为了减轻溶氧的限制,本研究借助根癌农杆菌将透明颤菌血红蛋白基因vgb引入里氏木霉。qPCR结果表明,pki及gpd启动子均可以有效启动vgb在里氏木霉中的表达。进一步实验结果表明,在摇瓶培养中,供氧充足情况下野生菌和转化株的生长无明显差异,但是在静止培养条件下,氧气供应受限,转化菌株的干重是野生菌的17.8~25.5倍。     

用琼脂糖亲和层析一步纯化蓖麻毒蛋白

本文报道了一种单用琼脂糖(Sepharose4B)来纯化蓖麻毒蛋白的快速简便的方法。我们发现在pH5的条件下,蓖麻毒蛋白和与其密切相关的蓖麻凝集素对琼脂糖的结合能力有很大的差别。在有0.2mol/LD-半乳糖存在下可将蓖麻毒蛋白从Sepharose上洗下,同样条件下蓖麻凝集素仍牢固地结合在柱上。从而经一步柱层析便可得到电泳纯的蓖麻毒蛋白。此法不需另行合成亲和胶,适合于蓖麻毒蛋白的大规模纯化。     

丝状真菌纤维素酶合成诱导及转录调控

利用廉价可再生木质纤维素资源水解产生的可发酵糖生产生物能源和生物基化学品是近年来国内外研究的热点。纤维素酶酶解是木质纤维素原料生物降解的重要手段,但目前纤维素酶生产成本过高,限制了纤维素生物转化和生物炼制的工业化应用。对丝状真菌纤维素酶基因表达和调控进行研究,有利于进一步选育纤维素酶高产菌株,降低纤维素酶生产成本。随着高通量测序及丝状真菌遗传操作等技术的进步,对丝状真菌纤维素酶诱导和基因表达调控机理有了更深入的认识。本文综述了近年来丝状真菌纤维素酶诱导和纤维素酶基因表达调控的最新进展,重点论述糖转运蛋白、转录因子和染色质重塑对纤维素酶表达调控的影响,并对利用人工锌指蛋白进行丝状真菌纤维素酶诱导调控研究进行了展望。     

黑曲霉与里氏木霉固态混合发酵产β-葡萄糖苷酶

对黑曲霉NL02与里氏木霉RUT-C30固态混合发酵产β-葡萄糖苷酶的发酵培养基进行优化,研究培养基含水率、C源、N源、接种量、温度和2种菌种不同延长接种时间与接种比例对β-葡萄糖苷酶活力的影响。研究表明：麸皮17.5 g、玉米芯7.5 g、（NH4）2SO4 0.40 g、尿素0.37 g、黑曲霉孢子接入量为107个接种到250 mL三角瓶中,温度30 ℃、摇床转速100 r/min时,里氏木霉以105个孢子与黑曲霉同时接入,每克干曲所得β-葡萄糖苷酶的活力为132.45 IU,较黑曲霉单独培养时的104.35 IU提高了26.94%。     

Adsorption and synergism of cellobiohydrolase I and II of Trichoderma reesei during hydrolysis of microcrystalline cellulose

Hydrolysis of microcrystalline cellulose (Avicel) by cellobiohydrolase I and II (CBH I and II) from Trichoderma reesei has been studied. Adsorption and synergism of the enzymes were investigated. Experiments were performed at different temperatures and enzyme/substrate ratios using CBH I and CBH II alone and in reconstituted equimolar mixtures. Fast protein liquid chromatography (FPLC) analysis was found to be an accurate and reproducible method to follow the enzyme adsorption. A linear correlation was found between the conversion and the amount of adsorbed enzyme when Avicel was hydrolyzed by increasing amounts of CBH I and/or CBH II. CBH I had lower specific activity compared to CBH II although, over a wide concentration range, more CBH I was adsorbed than CBH II. Synergism between the cellobiohy-drolases during hydrolysis of the amorphous fraction of Avicel showed a maximum as a function of total enzyme concentration. Synergism measured as a function of bound enzyme showed a continuous increase, which indicates that by decreasing the distance between the two enzymes the synergism is enhanced. The adsorption process for both enzymes was slow. Depending on the enzyme/substrate ratio it took 30-90 min to reach 95% of the equilibrium binding. The amount of bound enzyme decreased with increasing temperature. The two enzymes compete for the adsorption sites but also bind to specific sites. Stronger competition for adsorption sites was shown by CBH I. (c) 1994 John Wiley & Sons, Inc.     

Isolation and Some Physico-chemical Properties of the Acidic Subunits of Soybean 11S Globulin

Four kinds of acidic subunits and three kinds of basic subunits of 11S globulin were separated by polyacryl amide gel electrophoresis in the urea system. The four acidic subunits designated as A₁, A₂, A₃ and A₄ (R_m=0.35, 0.40, 0.46 and 0.56 respectively) were isolated by stepwise elution followed by repeating gradient elution with DEAE-Sephadex A-50 in the presence of 6 m urea at 5°C.

Subsequently, some physico-chemical properties of the subunits were determined. For example, N-terminal amino acids were determined as phenylalanine for both A₁ and A₂ and as leucine (or isoleucine) for both A₃ and A₄ by the DNP-amino acid method. The molecular weights of A₁, A₂ and A₃ were shown as 37,000 and 45,000 for A₄ by SDS-gel electrophoresis. The amino acid compositions of the acidic subunits were roughly similar to each other, but some remarkable differences were observed in the content of basic amino acids (lysine, histidine and arginine), serine and proline.     

Inhibition of enzymatic hydrolysis by residual lignins from softwood--study of enzyme binding and inactivation on lignin-rich surface

Lignin-derived inhibition is a major obstacle restricting the enzymatic hydrolysis of cell wall polysaccharides especially with softwood lignocellulosics. Enzyme adsorption on lignin is suggested to contribute to the inhibitory effect of lignin. The interaction of cellulases with softwood lignin was studied in the present work with commercial Trichoderma reesei cellulases (Celluclast) and lignin-rich residues isolated from steam pretreated softwood (SPS) by enzymatic and acid hydrolysis. Both lignin preparations inhibited the hydrolysis of microcrystalline cellulose (Avicel) and adsorbed the major cellulases present in the commercial cellulase mixture. The adsorption phenomenon was studied at low temperature (4°C) and at the typical hydrolysis temperature (45°C) by following activities of free and lignin-bound enzymes. Severe inactivation of the lignin-bound enzymes was observed at 45°C, however at 4°C the enzymes retained well their activity. Furthermore, SDS-PAGE analysis of the lignin-bound enzymes indicated that very strong interactions form between the residue and the enzymes at 45°C, because the enzymes were not released from the residue in the electrophoresis. These results suggest that heat-induced denaturation may take place on the surface of softwood lignin at the hydrolysis temperature.     

Hydrodynamic and kinetic study of cellulase production by Trichoderma reesei with pellet morphology

Numerical simulations and experimental validation were performed to understand the effects of hydrodynamics on pellet formation and cellulase production by filamentous T. reesei. The constructed model combined a steady-state multiple reference frame (MRF) approach describing mechanical mixing, oxygen mass transfer, and non-Newtonian flow field with a transient sliding mesh approach and kinetics of oxygen consumption, pellet formation, and enzyme production. The model was experimentally validated at various agitation speeds in a two-impeller Rushton turbine fermentor. Results from simulation and experimentation showed that higher agitation speeds led to increases in the pellet diameter and the proportion of pelletized (vs. filamentous) forms of the biomass. It also led to increase in dissolved oxygen mass transfer rate in shear-thinning fluid and cellulase productivity. The extent of these increases varied considerably among agitation speeds. Pellet formation and morphology were presumably affected within a viscosity-dependent shear-rate range. Cellulase activity and cell viability were shown to be sensitive to impeller shear. A maximum cellulase activity of 3.5 IU/mL was obtained at 400 rpm, representing a twofold increase over that at 100 rpm.