麦长管蚜唾液中几种酶的鉴定、活力测定与功能分析

用Parafilm膜夹营养液法,以两种食料介质饲喂麦长管蚜Macrosiphum avenae 3龄若蚜并收集其唾液,对唾液中的酶类进行了鉴定、活力测定和功能分析。结果表明,在20%蔗糖介质提取液中,鉴定有果胶酶、多酚氧化酶和纤维素酶; 在水介质提取液中鉴定有纤维素酶; 两种介质提取液中都未鉴定出过氧化物酶。酶活力测定结果表明, 在20%蔗糖介质提取液中, 每30头蚜虫分泌的果胶酶、多酚氧化酶和纤维素酶的酶活力分别为2.59×10^-3 U/g、7×10^-3 U/g和7.89×10^-3 U/g; 在水介质提取液中,纤维素酶活力为3.68×10^-3 U/g。行为反应试验结果表明,果胶酶处理麦苗的挥发物组分能引起麦长管蚜寄生性天敌燕麦蚜茧蜂Aphidius avenae和捕食性天敌七星瓢虫Coccinella septempunctata 的嗅觉偏好反应,因此,果胶酶在麦长管蚜取食诱导小麦植株的间接防御反应中具有重要作用。     

极端耐热纤维素酶Cel74的表达、纯化与特性

从海栖热袍菌中克隆出编码热稳定性的纤维素酶基因,以热激载体pHsh为表达质粒,构建重组质粒phsh—Ceff4,并转化至大肠杆菌中进行表达。基因表达产物通过热处理和离子交换层析,重组酶纯度达电泳纯。对纯化的重组酶酶学性质研究表明,最适反应温度85℃,最适反应pH4．6,pH4．5—6．0之间酶的相对酶活在80％以上。Co^2＋对酶活性有促进作用,Ca^2＋、Mg^2＋、Zn^2＋不影响酶活性,而Cu^2＋、Ni^2＋、Mn^2＋对酶活性有抑制作用。     

Access of cellulase to cellulose and lignin for poplar solids produced by leading pretreatment technologies

Adsorption of cellulase on solids resulting from pretreatment of poplar wood by ammonia fiber expansion (AFEX), ammonia recycled percolation (ARP), controlled pH, dilute acid (DA), flowthrough (FT), lime, and sulfur dioxide (SO₂) and pure Avicel glucan was measured at 4°C, as were adsorption and desorption of cellulase and adsorption of β‐glucosidase for lignin left after enzymatic digestion of the solids from these pretreatments. From this, Langmuir adsorption parameters, cellulose accessibility to cellulase, and the effectiveness of cellulase adsorbed on poplar solids were estimated, and the effect of delignification on cellulase effectiveness was determined. Furthermore, Avicel hydrolysis inhibition by enzymatic and acid lignin of poplar solids was studied. Flowthrough pretreated solids showed the highest maximum cellulase adsorption capacity (σ_solids = 195 mg/g solid) followed by dilute acid (σ_solids = 170.0 mg/g solid) and lime pretreated solids (σ_solids = 150.8 mg/g solid), whereas controlled pH pretreated solids had the lowest (σ_solids = 56 mg/g solid). Lime pretreated solids also had the highest cellulose accessibility (σ_cellulose = 241 mg/g cellulose) followed by FT and DA. AFEX lignin had the lowest cellulase adsorption capacity (σ_lignin = 57 mg/g lignin) followed by dilute acid lignin (σ_lignin = 74 mg/g lignin). AFEX lignin also had the lowest β‐glucosidase capacity (σ_lignin = 66.6 mg/g lignin), while lignin from SO₂ (σ_lignin = 320 mg/g lignin) followed by dilute acid had the highest (301 mg/g lignin). Furthermore, SO₂ followed by dilute acid pretreated solids gave the highest cellulase effectiveness, but delignification enhanced cellulase effectiveness more for high pH than low pH pretreatments, suggesting that lignin impedes access of enzymes to xylan more than to glucan, which in turn affects glucan accessibility. In addition, lignin from enzymatic digestion of AFEX and dilute acid pretreated solids inhibited Avicel hydrolysis less than ARP and flowthrough lignin, whereas acid lignin from unpretreated poplar inhibited enzymes the most. Irreversible binding of cellulase to lignin varied with pretreatment type and desorption method. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Hydrolysis of cellulose derived from steam exploded bagasse by Penicillium cellulases: Comparison with commercial cellulase

A complete cellulase from Penicillium pinophilum was evaluated for the hydrolysis of α-cellulose derived from steam exploded sugarcane bagasse and other cellulosic substrates. α-Cellulose at 1% substrate concentration was completely hydrolyzed by Penicillium cellulase within 3 h wherein at 10% the hydrolysis was 100% within 24 h with an enzyme loading of 10 FPU/g. The hydrolysate yielded glucose as major end product as analyzed by HPLC. Under similar conditions, hydrolysis of Sigmacell (microcrystalline cellulose), CP-123 (pulverized cellulose powder) and ball milled Solka Floc were 42%, 56% and 52%, respectively. Further the hydrolysis performance of Penicillium sp. cellulase is compared with Trichoderma reesei cellulase (Accellerase^TM 1000) from Genencore. The kinetics of hydrolysis with respect to enzyme and substrate concentration will be presented.     

Expression of multi-functional cellulase gene mfc in Coprinus cinereus under control of different basidiomycete promoters

Multi-functional cellulase gene mfc was expressed in Coprinus cinereus under naturally non-inductive conditions using three heterologous promoters. Endo-β-1,4-glucanase expression was achieved in solid and liquid media with promoter sequences from the Lentinula edodesgpd gene, the Flammulina velutipes gpd gene and the Volvariella volvaceagpd gene. As measured by enzyme activity in liquid cultures, a 613-bp gpd promoter fragment from L. edodes was most efficient, followed by a 752-bp gpd fragment from F. velutipes. The V. volvacea gpd promoter sequence was less active, in comparison. Irrespective of the promoter used, enzymatic activities increase 34-fold for highly active transformants and 29-fold for less active one by using cellulase-inducing medium. The highest activities of endo-β-1,4-glucanase (34.234 U/ml) and endo-β-1,4-xylanase (263.695 U/ml) were reached by using the L. edodesgpd promoter.     

根霉TC1653产纤维素酶提纯及酶学性质研究

对根霉所产纤维素酶酶系进行了分析并研究了部分酶学性质。实验选择超滤和凝胶柱分离相结合的方式提纯纤维素酶,结果显示根霉TC1653纤维素酶系是一个完全酶系,具有一个较为明显的内切葡聚糖酶组分。β-葡萄糖苷酶组分的最适反应温度为70℃,温度高于70℃时,活性迅速下降,但在这种高温下具有最高反应活性的酶很少见,很可能又是一种新的β-葡萄糖苷酶。     

Fast identification of thermostable beta‐glucosidase mutants on cellobiose by a novel combinatorial selection/screening approach

Engineering costly cellulases on natural cellulosic substrates is of importance for emerging biomass‐based biorefineries. Directed enzyme evolution is becoming a popular tool, but identification of desired mutants from a large mutant library remains challenging sometimes. In this work, we demonstrated a novel combinatorial selection/screening strategy for finding thermostable beta‐glucosidase on its natural substrate—cellobiose. First, selection was conducted through complementation of beta‐glucosidase for non‐cellobiose‐utilizing Escherichia coli so that only the cells expressing active beta‐glucosidase can grow on a M9 synthetic medium with cellobiose as the sole carbon source (selection plate). Second, the clones on the selection plates were duplicated by using nylon membranes. After heat treatment, the nylon membranes were overlaid on M9/cellobiose screening plates so that remaining activities of thermostable beta‐glucosidase mutants hydrolyzed cellobiose on the screening plates to glucose. Third, the growth of an indicator E. coli strain that can utilize glucose but not cellobiose on the screening plates helped detect the thermostable beta‐glucosidase mutants on the selection plates. Several thermostable mutants were identified from a random mutant library of the Paenibacillus polymyxa beta‐glucosidase. The most thermostable mutant A17S had an 11‐fold increase in the half‐life of thermoinactivation at 50°C. Biotechnol. Bioeng. 2009;103: 1087–1094. © 2009 Wiley Periodicals, Inc.     

Mechanism of cellulase reaction on pure cellulosic substrates

Cellulase reaction mechanism was investigated with the use of following pure cellulosic substrates: Microcrystalline cellulose (Avicel), α‐cellulose (Sigma), filter paper, cotton, and non‐crystalline cellulose (NCC). NCC is amorphous cellulose prepared in our laboratory by treatment with concentrated sulfuric acid. When hydrolyzed with cellulase, NCC produces significant amount of cello‐oligosaccharides (COS) as reaction intermediates along with glucose and cellobiose. The COS produced by cellulase were categorized into two different moieties based upon their degree of polymerization (DP): low DP (less than 7) COS (LD‐COS) and high DP COS (HD‐COS). Endo‐glucanase (Endo‐G) reacts rapidly on the NCC reducing its DP to 30–60, after which the Endo‐G reaction with NCC ceases. HD‐COS is produced from NCC by the action of Endo‐G, whereas LD‐COS is produced by exo‐glucanase (Exo‐G). β‐Glucosidase (β‐G) hydrolyzes LD‐COS to produce cellobiose, but it does not hydrolyze HD‐COS. DP of NCC affects the action of Exo‐G in such a way that the overall yield is high for high DP NCC. This is in line with previous findings that substrate‐recognition by Exo‐G requires binding on β‐glucan chain with DP of 10 for the hydrolysis to take place. The individual cellulose chain residues within solid having DP less than 10 therefore remain unreacted. The percentage of the unreacted portion would be lower for high DP NCC, which results high overall conversion. The surface area and the number of reactive sites on the substrate facilitate adsorption of enzyme therefore the initial rate of the hydrolysis. The overall extent of conversion of cellulose, however, is controlled primarily by its inherent characteristics such as DP and crystallinity. Biotechnol. Bioeng. 2009;102: 1570–1581. © 2008 Wiley Periodicals, Inc.     

一组纤维素分解菌的分离、筛选及其产酶条件的研究

从堆肥中筛选得到两株分解纤维素的菌株,一株为高温单孢菌Q-0,另一株为芽孢杆菌Q-3,对Q-0、Q-3及这两株菌组成的混合菌产纤维素酶条件进行了研究。结果表明,混合菌分解棉花和滤纸纤维素的分解率均比单一菌株高,其分解率分别为69％和62％。混合菌产酶最适温度为50℃,pH7．5。在以棉花纤维为惟一碳源时,混合菌产生的纤维素酶可达101个酶活单位,比菌Q-0高近40个酶活单位。Q-0、Q-3和混合菌利用有机氮源优于无机氮源。