角质酶的研究进展

角质酶(EC3.1.1.74)是一种可以降解角质并产生大量脂肪酸单体的水解酶。角质酶是一种多功能酶,可水解可溶性酯、不溶性甘油三酯和各种聚酯,同时还能催化酸与醇的酯化、脂肪酸盐与醇的转酯化反应,因此在食品工业、化工工业等诸多领域都具有广泛的应用。近年来研究发现,角质酶可实现棉纤维的生物精练和合成纤维的生物改性,是推动纺织工业清洁生产的关键酶制剂。     

角质酶在生物可降解聚酯聚己二酸/对苯二甲酸丁二醇酯降解中的应用

随着废弃塑料带来的环境污染越来越严重,生物可降解聚酯已成为大众关注的焦点。聚己二酸/对苯二甲酸丁二醇酯[poly(butylene adipate-co-terephthalate),PBAT]是脂肪族和芳香族共聚形成的生物可降解聚酯,兼具两者的优异性能。针对PBAT在自然条件下对降解环境要求严格且降解周期长的不足之处,本研究探究了角质酶在PBAT降解中的应用和对苯二甲酸-丁二醇酯(butylene terephthalate,BT)含量对PBAT生物降解性的影响,以实现对PBAT降解速率的提升。选取5种不同来源的聚酯降解酶对PBAT进行降解应用并比较出降解效果最优的酶,并测定了含有不同BT含量的PBAT聚酯的降解效率。结果表明,角质酶ICCG为降解效果最好的酶,且BT含量越高PBAT的降解率越低。此外,还确定了角质酶ICCG对高BT含量的PBAT(H)降解的最适温度、最适缓冲液类型、最适pH、最适E/S(enzyme to substrate)和最适底物浓度比分别为75℃、Tris-HCl、9.0、0.4%和1.0%。本研究结果可为角质酶在PBAT降解中的应用提供一定的理论依据和实验...     

重组角质酶的发酵制备及其对涤纶纤维的表面改性

对大肠杆菌表达嗜热子囊菌Thermobifida fusca角质酶的摇瓶诱导条件及3 L发酵罐扩大培养进行了研究,并探讨了角质酶对涤纶纤维的改性作用。结果表明,在摇瓶培养中,采用工业级TB培养基,用2 g/L乳糖诱导,菌体培养至对数生长前期添加0.5％甘氨酸,角质酶产量可达到128 U/mL。在3 L发酵罐扩大培养中,补料培养生物量 (OD600) 最大达到35,角质酶酶活最高达506 U/mL,是迄今国内外报道细菌来源角质酶的最高水平。紫外分光光度法分析初步表明涤纶纤维经角质酶水解产生了对苯二甲酸类物质     

植物角质膜及其渗透性与抗旱性研究进展

角质膜覆盖于陆生植物的地上部分,是植物与外部环境之间的第一道屏障,保护植物免遭各种生物和非生物胁迫。本文就植物角质膜的结构、成分、生物合成的途径及机理、渗透性及温度、湿度、活性剂对角质膜渗透性的影响,角质膜与植物抗旱性关系的研究进展做系统综述,并对植物角质膜研究中存在的问题进行了探讨。     

Thermobifida fusca角质酶突变体D204C/E253C高效可溶表达及其应用

Thermobifida fusca角质酶突变体D204C/E253C是通过在野生型角质酶中引入二硫键获得的热稳定性突变体.由于二硫键的引入,导致突变体D204C/E253C在表达过程中,易错误折叠形成大量包涵体,可溶表达比率极低.这极大地限制了其发酵制备以及在PET纤维改性中的应用.为了加强突变体D204C/E253...     

核盘菌角质酶的克隆、表达及活性分析

角质酶可降解脂肪族或芳香族聚酯,对聚对苯二甲酸乙二醇酯也具有较好的降解作用,但目前市面上角质酶产品非常稀缺,因此寻求一种高效表达的角质酶用于工程酶的开发非常有必要.本研究从核盘菌中克隆得到8个角质酶基因,利用PCR结合RT-PCR技术筛选出主效基因SsCut-52,利用大肠杆菌Escherichia coli BL21...     

胰酶对皮肤角质细胞分离和传代的影响

考察不同的胰酶浓度及其作用时间对角质细胞分离和传代的影响。实验发现在胰酶浓度 0.25%时作用5min可获得的总活细胞量和有克隆形成能力的细胞量均优于其它培养条件 ;而在胰酶浓度0.05%时作用 5min可获得最大的原代角质细胞贴壁率。随着胰酶浓度的提高 ,传代角质细胞的贴壁率和贴壁速率常数以及克隆形成率均随之增加 ,因此在传代培养时使用 0.25%胰酶浓度进行消化较为适宜.     

嗜热子囊菌利用短链有机酸生产角质酶

以嗜热子囊菌(Thermobifida fusca WSH03-11)发酵生产角质酶为模型,研究微生物利用市政污泥厌氧酸化所产短链有机酸为碳源发酵生产高附加值产品的可能。发现：(1)以丁酸、丙酸和乙酸为碳源时,有机酸和氮元素浓度分别为8.0 g/L和1.5 g/L有利于角质酶的生产;而以乳酸为碳源时,最适有机酸和氮源浓度分别为3.0 g/L和1.0 g/L;(2)改变诱导物角质的浓度,以丁酸、丙酸、乙酸和乳酸为碳源,分别比优化前提高了31.0%、13.3%、43.8%和73.2%;(3)在四种有机酸中,T. fusca WSH03-11利用乙酸的速率最快,平均比消耗速率是丙酸的1.3倍,丁酸的2.0倍及乳酸的2.2倍;以丁酸为碳源时的酶活(52.4 U/mL)是乳酸的1.7倍、乙酸的2.5倍和丙酸的3.2倍;角质酶对乳酸的得率(12.70 u/mg)分别是丁酸的1.4倍、丙酸的3.0倍和乙酸的3.8倍;(4)以混合酸为碳源生产角质酶,T. fusca WSH03-11优先利用乙酸,而对丁酸的利用受到抑制。进一步研究发现,混合酸中0.5 g/L的乙酸将导致丁酸的消耗量降低66.7%。这是首次利用混合酸作碳源发酵生产角质酶的研究报道。这一研究结果进一步确证了利用市政污泥厌氧酸化所产有机酸为碳源发酵生产高附加值产品的可行性,为以廉价碳源生产角质酶奠定了良好的基础。     

嗜热子囊菌利用短链有机酸生产角质酶

以嗜热子囊菌(Thermobifida fusca WSH03-11)发酵生产角质酶为模型,研究微生物利用市政污泥厌氧酸化所产短链有机酸为碳源发酵生产高附加值产品的可能。发现：(1)以丁酸、丙酸和乙酸为碳源时,有机酸和氮元素浓度分别为8.0 g/L和1.5 g/L有利于角质酶的生产;而以乳酸为碳源时,最适有机酸和氮源浓度分别为3.0 g/L和1.0 g/L;(2)改变诱导物角质的浓度,以丁酸、丙酸、乙酸和乳酸为碳源,分别比优化前提高了31.0%、13.3%、43.8%和73.2%;(3)在四种有机酸中,T. fusca WSH03-11利用乙酸的速率最快,平均比消耗速率是丙酸的1.3倍,丁酸的2.0倍及乳酸的2.2倍;以丁酸为碳源时的酶活(52.4 U/mL)是乳酸的1.7倍、乙酸的2.5倍和丙酸的3.2倍;角质酶对乳酸的得率(12.70 u/mg)分别是丁酸的1.4倍、丙酸的3.0倍和乙酸的3.8倍;(4)以混合酸为碳源生产角质酶,T. fusca WSH03-11优先利用乙酸,而对丁酸的利用受到抑制。进一步研究发现,混合酸中0.5 g/L的乙酸将导致丁酸的消耗量降低66.7%。这是首次利用混合酸作碳源发酵生产角质酶的研究报道。这一研究结果进一步确证了利用市政污泥厌氧酸化所产有机酸为碳源发酵生产高附加值产品的可行性,为以廉价碳源生产角质酶奠定了良好的基础。     

抗氧化剂对皮肤角质细胞体外寿命的影响

考察了抗氧化剂对鼠角质细胞体外培养寿命的影响。实验发现在角质细胞的体外培养过程中添加抗氧化剂有利于延长细胞的寿命,其中效果最好的是巯基乙醇,其次为过氧化氢酶和SOD,但在体外培养过程中,角质细胞生长速率仍然逐渐下降。实验还发现,添加抗氧化剂可在一定程度上提高角质细胞的克隆形成率,减缓细胞衰老速率。同时,通过考察鼠表皮角质细胞衰老动力学,获得了对应于不同抗氧化剂的细胞衰老动力学常数。      

Research and application of biotechnology in textile industries in China

Textile industry is a conventional and pillar industry in China, which possesses a considerable proportion of the national economy. In recent years, special attention has been paid to the application of biotechnology in textile industries in China. As an interdiscipline between natural science and engineering science, textile biotechnology has much effect on China's textile industry. This paper summarizes current developments and highlights those areas where biotechnology might play an increasingly important role in China's textile industry as follows:

(1) Development of new types of textile fibers and polymers, such as Bt cotton naturally colored cotton, colored silk and silk gene-sequence, spider silk non-wovens, chitin fiber and chitosan derivatives, etc.

(2) Application of enzyme technology in textile wet processing, such as alkaline pectinase, PVA-degrading enzyme, cutinase and catalase used for cotton preparation, neutral cellulase for denim washing, transglutaminase for wool modification, protease for silk degumming as well as pectinase and hemicellulases for retting of bast fibers.

(3) Treatment of textile effluents with biotechnology.

Effect of silent mutations in Translational Initial Region on the production of recombinant cutinase in Escherichia coli

Translational Initial Region (TIR) is the threshold of an intracellular translation process, and tiny alterations in this region are reported to intensely influence the downstream expression. Such property provides a potential utilization in extracellular production of recombinant enzyme. As an esterase, cutinase is an essential catalyst in the process of textile scouring, and has a potential application in food and chemical industry. In the present study, a bacterial cutinase (Tfu_0883) from Thermobifida fusca was expressed in Escherichia coli with pelB as its signal peptide using trc as its promoter. A subsequent TIR degeneracy mutagenesis was then carried out in the initial sequence of pelB. A fast screening method for these mutants was developed and a series of strains with different expression strengths were accordingly obtained. Among these mutants, a high cutinase production level of 38.0 U/ml was achieved, which is three times that of the control group. This study explored the potential utilization of TIR degeneracy mutagenesis in the production of industrial enzymes.     

Extracellular overexpression of recombinant <Emphasis Type="Italic">Thermobifida fusca</Emphasis> cutinase by alpha-hemolysin secretion system in <Emphasis Type="Italic">E. coli</Emphasis> BL21(DE3)

Background  

Extracellular expression of proteins has an absolute advantage in a large-scale industrial production. In our previous study, Thermobifida fusca cutinase, an enzyme mainly utilized in textile industry, was expressed via type II secretory system in Escherichia coli BL21(DE3), and it was found that parts of the expressed protein was accumulated in the periplasmic space. Due to the fact that alpha-hemolysin secretion system can export target proteins directly from cytoplasm across both cell membrane of E. coli to the culture medium, thus in the present study we investigated the expression of cutinase using this alpha-hemolysin secretion system.     

Enzymatic surface modification of poly(ethylene terephthalate)

This study unambiguously confirms hydrolysis using cutinase of the persistent synthetic polymer poly(ethylene terephthalate), the most important synthetic fiber in the textile industry by direct measurement and identification of the different hydrolysis products. In this aqueous heterogeneous system, dissolved cutinase from Fusarium solani pisi acts on different solid poly(ethylene terephthalate) substrates. The extent of hydrolysis was detected by measuring the amount of (soluble) degradation products in solution using reversed-phase HPLC. Crystallinity greatly affects the capability of the enzyme to hydrolyze the ester bonds, displaying relatively high activity towards an amorphous polyester film and little activity on a highly crystalline substrate. The enzyme is sufficiently stable, hydrolysis rate on the amorphous substrate maintained at sufficient high level over a long period of time of at least five days. From an industrial point of view it is highly recommended to increase the hydrolysis rates.     

Enhanced degradation and toxicity reduction of dihexyl phthalate by Fusarium oxysporum f. sp. pisi cutinase

AIMS: This research aims to investigate the efficiency of two lipolytic enzymes--fungal cutinase and yeast esterase--upon the biodegradation of dihexyl phthalate (DHP). METHOD AND RESULTS: During the enzymatic degradation of DHP dissolved in methanol, several degradation products were detected and their time-course changes were monitored using GC/MS. The DHP-degradation rate of cutinase was surprisingly high; i.e. almost 70% of the initial DHP (500 mg l(-1)) was decomposed within 4.5 h. Although the same amount of esterase was employed, more than 85% of the DHP remained after 3 days. Almost all the DHP was converted by cutinase into 1,3-isobenzofurandione (IBF), whereas hexyl methyl phthalate and IBF were abundantly produced by esterase. In addition, the toxicities of the DHP-degraded products by esterase were evaluated using various recombinant bioluminescent bacteria, which caused oxidative and protein damage, whereas the hydrolysis products from cutinase never caused any cellular damage in the methanol-containing reaction system. CONCLUSIONS: Cutinase starts to act as a DHP-degrader much earlier and faster than esterase, with high stability in ester-hydrolytic activity, therefore a plausible approach to the practical application of cutinase for DHP degradation in the DHP-contaminated environments may be possible. SIGNIFICANCE AND IMPACT OF THE STUDY: This study describes the enhanced degradation and detoxification of DHP using Fusarium oxysporum f. sp. pisi cutinase.     

角质酶/角蛋白酶一浴法处理对羊毛性能的影响

采用T.fusca产角质酶以及Bacillus subtilis产角蛋白酶一浴法的方式处理羊毛,通过毡缩率、断裂强力、碱溶解度、上染速率、K/S值和接触角等指标考察了该处理对羊毛的改性效果,并运用XPS、氨基酸分析和SEM考察了其对羊毛结构与性质的影响。实验结果表明：经一浴法处理后,羊毛织物的毡缩率下降明显,达到机可洗要求;断裂强力下降较少,碱溶解度增加较少,上染速率提高,K/S值增加;XPS分析表明,经处理后羊毛纤维表面的元素含量变化较大;氨基酸分析表明,经处理后羊毛纤维中的胱氨酸质量分数有所降低;SEM显示,羊毛鳞片层大部分被剥除,综上可以说明角质酶/角蛋白酶的一浴法处理对羊毛具有明显的改性作用。     

DSC studies of Fusarium solani pisi cutinase: consequences for stability in the presence of surfactants

The application of cutinase from Fusarium solani pisi as a fat-stain removing ingredient in laundry washing is hampered by its lack of stability in the presence of anionic surfactants. We postulate that the stability of cutinase towards anionics can be improved by mutations increasing its temperature stability. Thermal unfolding as measured with DSC, appears to be irreversible, though the thermograms are more symmetric than predicted by a simple irreversible model. In the presence of taurodeoxycholate (TDOC), the unfolding temperature is lower and the unfolding is reversible. We conclude that an early reversible unfolding intermediate exists in which a number of additional hydrophobic patches are exposed to the solvent, or preferentially are covered with TDOC. Improvement of the stability of cutinase with respect to both surfactants and thermal denaturation, should thus be directed toward the prevention of exposure of hydrophobic patches in the early intermediate.     

Hydrolysis of plant cuticle by plant pathogens. Purification, amino acid composition, and molecular weight of two isozymes of cutinase and a nonspecific esterase from Fusarium solani f. pisi.

The extracellular fluid of the plant pathogen, Fusarium solani f. pisi, grown on the plant cuticular polymer, cutin, was shown to contain cutinase and p-nitrophenyl palmitate hydrolase activities (R.E. Purdy and P.E. Kolattukudy (1973), Arch. Biochem. Biophys. 159, 61). From this extracellular fluid two isozymes of cutinase and a nonspecific esterase (p-nitrophenyl palmitate hydrolase) were isolated using Sephedex G-100 gel filtration, QAE-Sephadex chromatography, and SE-Sephedex chromatography. Phenolics contained in the extracellular fluid were found to be associated with the cutinase but not with the nonspecific esterase, and the phenolic materials were removed from cutinase at the QAE-Sephedex step. A 34-fold purification of the nonspecific esterase and a 6.5-fold purification of cutinase were achieved by the procedure described. The two isozymes of cutinase (I and II) and the nonspecific esterase were homogeneous as judged by polyacrylamide disc gel electrophoresis and sedimentation equilibrium centrifugation. Molecular weights of cutinase I, cutinase II, and the nonspecific esterase were determined by Sephedex G-100 gel filtration, sedimentation equilibrium centrifugation, amino acid composition, and sodium dodecyl sulfate polyacrylamide disc gel electrophoresis. The values obtained with these techniques agreed with each other and were about 22,000 for both cutinases and 52,000 for the nonspecific esterase. The dodecyl sulfate gel electrophoresis indicated that a small portion of cutinase II contained proteolylic clips, near the middle of the polypeptide chain, and that the nonspecific esterase might also have undergone some proteolylic modification. The amino acid composition of cutinase I was similar to that of cutinase II except for the presence of a larger number of tryptophan residues in the latter, while the amino acid composition of the nonspecific esterase showed more differences from that of either cutinase.     

Dynamic light scattering of cutinase in AOT reverse micelles

The fungal lipolytic enzyme cutinase, incorporated into sodium bis-(2ethylhexyl) sulfosuccinate reversed micelles has been investigated using dynamic light scattering. The reversed micelles form spontaneously when water is added to a solution of sodium bis-(2ethylhexyl) sulfosuccinate in isooctane. When an enzyme is previously dissolved in the water before its addition to the organic phase, the enzyme will be incorporated into the micelles. Enzyme encapsulation in reversed micelles can be advantageous namely to the conversion of water insoluble substrates and to carry out synthesis reactions. However protein unfolding occurs in several systems as for cutinase in sodium bis-(2ethylhexyl) sulfosuccinate reversed micelles. Dynamic light scattering measurements of sodium bis-(2ethylhexyl) sulfosuccinate reversed micelles with and without cutinase were taken at different water to surfactant ratios. The results indicate that cutinase was attached to the micellar wall and that might cause cutinase unfolding. The interactions between cutinase and the bis-(2ethylhexyl) sulfosuccinate interface are probably the driving force for cutinase unfolding at room temperature. Twenty-four hours after encapsulation, when cutinase is unfolded, a bimodal distribution was clearly observed. The radii of reversed micelles with unfolded cutinase were determined and found to be considerable larger than the radii of the empty reversed micelles. The majority of the reversed micelles were empty (90-96% of mass) and the remainder (4-10%) containing unfolded cutinase were larger by 26-89 A.     

Synthesis and characterization of a new cutinase substrate, 4-nitrophenyl (16-methyl sulfone ester) hexadecanoate

Phytopathogenic fungi penetrate plants by breaking down the cuticular barrier with cutinase. Cutinases are extracellular hydrolytic enzymes that degrade cutin, a polyester composed of hydroxy and epoxy fatty acids. Until now, cutinase has been recognized by its ability to release labeled cutin monomers or by a non-specific esterase assay based on the hydrolysis of p-nitrophenyl esters of short fatty acids. In this work, an insoluble p-nitrophenyl derivative was synthesized and purified, and its structure was determined to be 4-nitrophenyl (16-methyl sulfone ester) hexadecanoate (pNMSEH) by nuclear magnetic resonance (H+ NMR) analysis. pNMSEH was tested as a new cutinase substrate with Pseudomonas mandocino cutinase and porcine liver esterase. While a linear release over time of p-nitrophenol (pNP) was recorded in the presence of cutinase, no response was obtained with the esterase. The calculated kinetic parameters of pNMSEH hydrolysis by cutinase revealed a high specificity (Km=1.8mM), albeit a low catalytic rate (Vmax=10.5 micromol min(-l)l(-1)). This new synthetic substrate may be helpful for detecting and assaying cutinase activity in mixed solutions, such as crude fungal extracellular extracts.