人参细胞生物合成熊果苷转化体系的建立

以人参(Panax ginseng C. A. Mey.)培养细胞为生物反应体系,利用外源氢醌为底物,对熊果苷的生物合成进行了研究.TLC鉴别表明,人参细胞可以将外源的氢醌转化为熊果苷;以熊果苷含量和氢醌的转化率为指标,对人参细胞生物合成熊果苷的基本条件(氢醌浓度、转化持续时间、细胞培养阶段)进行了探讨, 结果表明,MS固体培养基上培养32 d的人参细胞,在含有2 mmol·L-1氢醌的生物合成培养基中转化24 h后,合成的熊果苷含量占细胞干重的7.176%,氢醌转化率也达到79.15%.     

生物合成聚3-羟基丙酸酯的研究进展

聚3-羟基丙酸酯(P3HP)作为聚羟基脂肪酸酯家族(PHAs)中的新型热塑性塑料,具有生物降解性和生物相容性等优点。目前,未见野生微生物可以合成P3HP的报道,生产途径主要为化学法和生物法。其中,通过化学法或添加3-HP单体及其结构类似物作为前体的P3HP合成效率低、成本高且不具环保性;而通过构建和改造工程菌的生物代谢途径,能够利用廉价、可再生的碳源,已经逐渐成为研究热点。文中综述了国内外P3HP生物合成研究进展,并对甘油途径、丙二酸单酰辅酶A(Malonyl-Co A)途径和β-丙氨酸途径等合成方法进行了优缺点分析,为生物合成P3HP的深入研究奠定理论基础。     

重组大肠杆菌合成聚（3-巯基丙酸）和聚（3-羟基丁酸-3-巯基丙酸）的研究

利用Clostridium acetobutylicum的丁酸激酶基因 (buk) 和磷酸转丁酰基酶基因(ptb),以及Thiocapsa pfennigii的PHA合成酶基因,设计了一条能够合成多种聚羟基烷酸的代谢途径,用构建的质粒转化大肠杆菌,获得了重组大肠杆菌菌株。前期的研究表明,在合适的前体物条件下,该重组大肠杆菌能够合成包括聚羟基丁酸、聚（羟基丁酸戊酸）等多种生物聚酯［Liu and Steinbüchel, Appl. Environ. Microbiol. 66:739743］。利用该重组大肠杆菌,通过生物催化作用合成了3巯基丙酸的同型共聚酯,同时利用该重组大肠杆菌还获得了含3-巯基丙酸单体的多种异型共聚物。实验首先研究了3巯基丙酸对大肠杆菌生长的影响,在此基础上优化了培养过程中添加3-巯基丙酸的时机和浓度,结果表明,在实验的条件下,细胞合成聚（3-巯基丙酸）可达6.7%(占细胞干重),合成聚（3-羟基丁酸—3-巯基丙酸）（分子中3-巯基丙酸:3-羟基丁酸=3:1）可达24.3%。实验进一步研究了同时或分别表达以上3个基因的重组大肠杆菌合成聚合物的能力,结果表明只有当3个基因同时表达时才能合成聚合物,说明3个基因对合成过程是必须的,从而表明了合成途径是按照设计的路线进行的。还通过GC/MS、GPC、IR等手段对合成的化合物进行了定性的研究。聚（3-巯基丙酸）或聚（3-羟基丁酸-3-巯基丙酸）等聚酯属于一类新型生物聚合物,它在分子骨架中含有硫酯键,不同于聚羟基烷酸酯的氧酯键,从而具有显著不同的物理、化学、光学等性质和具有重要的潜在应用价值。     

重组大肠杆菌合成聚(3-巯基丙酸)和聚(3-羟基丁酸-3-巯基丙酸)的研究

利用Clostridium acetobutylicum的丁酸激酶基因 (buk) 和磷酸转丁酰基酶基因(ptb),以及Thiocapsa pfennigii的PHA合成酶基因,设计了一条能够合成多种聚羟基烷酸的代谢途径,用构建的质粒转化大肠杆菌,获得了重组大肠杆菌菌株.前期的研究表明,在合适的前体物条件下,该重组大肠杆菌能够合成包括聚羟基丁酸、聚(羟基丁酸-戊酸)等多种生物聚酯[Liu and Steinbüchel, Appl. Environ. Microbiol. 66739-743].利用该重组大肠杆菌,通过生物催化作用合成了3-巯基丙酸的同型共聚酯,同时利用该重组大肠杆菌还获得了含3-巯基丙酸单体的多种异型共聚物.实验首先研究了3-巯基丙酸对大肠杆菌生长的影响,在此基础上优化了培养过程中添加3-巯基丙酸的时机和浓度,结果表明,在实验的条件下,细胞合成聚(3-巯基丙酸)可达6.7%(占细胞干重),合成聚(3-羟基丁酸-3-巯基丙酸)(分子中3-巯基丙酸3-羟基丁酸=31)可达24.3%.实验进一步研究了同时或分别表达以上3个基因的重组大肠杆菌合成聚合物的能力,结果表明只有当3个基因同时表达时才能合成聚合物,说明3个基因对合成过程是必须的,从而表明了合成途径是按照设计的路线进行的.还通过GC/MS、GPC、IR等手段对合成的化合物进行了定性的研究.聚(3-巯基丙酸)或聚(3-羟基丁酸-3-巯基丙酸)等聚酯属于一类新型生物聚合物,它在分子骨架中含有硫酯键,不同于聚羟基烷酸酯的氧酯键,从而具有显著不同的物理、化学、光学等性质和具有重要的潜在应用价值.     

脲酶抑制剂氢醌的环境效应评价

本文根据用标记和非标记氢醌进行的模拟、盆栽和田间定位试验,结合国内外文献有关氢醌的环境常数,论述了氢醌在土壤-植物系统的去向和代谢途径、对土壤酶活性的影响及其环境效应。得出的结论是:作为脲酶抑制剂使用的微量氢醌(0.3—0.4％,与尿素重量比),不会从土壤中淋失和挥发,在土壤和植物中没有累积,对与碳、氮和磷转化有关的土壤酶活性很少影响。在土壤中,它将通过氧化、臭氧化和生物学降解,经由环断裂生成二元酸或参与腐殖物质的合成。在植物体内,主要通过糖苷化得到同化和利用。因此,氢醌作为脲酶抑制剂在农业生产中应用是安全的。     

热稳定酯酰辅酶A合成酶的异源表达及酶学特性

【目的】为寻找能合成丙酰辅酶A和丁酰辅酶A等聚酮合成前体的生物催化剂,用体外酶学实验对一个酯酰辅酶A合成酶进行了表征。【方法】利用丙二酰辅酶A合成酶作为输入序列,通过BLAST程序在Caldicellulosiruptor owensensis OL的基因组中找到1个酯酰辅酶A合成酶基因。在大肠杆菌中进行了异源表达,并通过亲和层析进行纯化。底物谱、最适反应条件、稳定性和动力学参数通过体外酶学实验进行表征,而定点突变则用于活性中心的氨基酸残基的分析。【结果】该酶具有较好的底物宽泛性,可识别丙酸、丁酸、2-甲基丙酸、戊酸、3-甲基丁酸、2-甲基丁酸以及环己甲酸等一系列单酸。反应最适温度为30°C,最适p H为7.0。70°C保温8 h后仍有45%的活性残留,表明该酶相对比较稳定。通过活性中心3个位点的定点突变可以改变酶的底物特异性。【结论】C.owensensis OL来源的酯酰辅酶A合成酶是潜在的生物催化剂,可以用于聚酮前体的合成。     

低成本绿色循环工艺发酵生产丙酸联产维生素B12

对提取维生素B12后的费氏丙酸杆菌废菌体进行水解处理,考察以菌体水解液作为N源用于丙酸发酵的可行性.利用正交设计得到了提取维生素B12后的废菌体水解优化条件.基于此,构建利用植物纤维床反应器固定化生产丙酸联产维生素B12的低成本绿色循环工艺.结果表明:在4.5L的发酵体系中,单批次总糖质量浓度为200 g/L,发酵进行了5批次共1192h,丙酸生成总量为2 328.75 g,单批次丙酸质量浓度103.50 g/L,丙酸生产效率达0.43 g/(L·h),干菌质量浓度达到19.52 g/L.将菌体注入微好氧发酵罐中发酵获得112.8 mg/L维生素B12.     

程序降温法固相酶催化棕榈油甘油解的研究

单脂肪酸甘油酯(单甘酯)的酶法合成工艺中最具有工业化前景的当属固体相油脂甘油解。彭立风、谭天伟[1～2]以猪胰脂肪酶固相催化牛油、棕榈油甘油解合成单甘酯,甘油与油脂摩尔比为2～4∶1,最佳反应温度下反应24ｈ后单甘酯含量最高分别达1951%和2417%,将反应物于更低温度下…     

南海深海微生物酯酶EST12-7在制备(R)-2-氯丙酸乙酯中的应用研究

利用来源南海深海的微生物酯酶EST12-7不对称水解反应拆分制备（R）-2-氯丙酸乙酯。并探寻了温度、pH、底物浓度、有机溶剂和反应时间等因素对酯酶EST12-7催化制备（R）-2-氯丙酸乙酯的影响。结果表明,深海微生物酯酶EST12-7催化制备（R）-2-氯丙酸乙酯的最佳反应条件为：13.8 μg/ml酯酶EST12-7,50 mmol/L（±）-2-氯丙酸乙酯,2%正癸醇,pH8.5,30℃,0.05mol/L Tris-HCl,反应60 min。在最佳反应条件下,（±）-2-氯丙酸乙酯的转化率可达49%,所制备的（R）-2-氯丙酸乙酯的光学纯度为98%。通过对酯酶EST12-7拆分制备（R）-2-氯丙酸甲酯和（R）-2-氯丙酸乙酯进行比较,2-氯丙酸酯中的链长对酯酶EST12-7拆分反应有极大的影响。     

3-羟基丙酸分批发酵过程中的pH控制策略研究

本文利用重组大肠杆菌以甘油为底物发酵合成3．羟基丙酸,考察了不同pH对3．羟基丙酸产量及菌体生长的影响,发现在pH6．5条件下,细胞比生长速率达到最大值,延迟期也相对较短;而pH7．0有利于3-羟基丙酸的合成,控制pH7．0可以使3-羟基丙酸产量达到7．39g／L。基于不同pH条件下对细胞比生长速率和3-羟基丙酸比生成速率的分析,提出3．羟基丙酸分批发酵过程中的pH控制策略,即在发酵过程前5h将pH控制在6．5,5h～15h控制pH为7．0,此时有利于细胞生长;而后在15h-25h控制pH为7．5,25h后控制pH为7．0,从而使细胞具有较高的3．羟基丙酸比合成速率。在此控制策略下经过34h发酵3-羟基丙酸的终产量达到8．76g／L,比pH7．0条件下的3-羟基丙酸产量提高了18．54％。     

Hydroxylation of Phenol to Hydroquinone Catalyzed by A Human Myeloperoxidase-Superoxide Complex: Possible Implications In Benzene-Induced Myelotoxicity

Benzene, a known human rnyelotoxin and leukemogen is metabolized by liver cytochrome P-450 mono-oxygenase to phenol. Further hydroxylation of phenol by cytochrome P-450 monooxygenase results in the formation of mainly hydroquinone, which accumulates in the bone marrow. Bone marrow contains high levels of myeloperoxidase. Here we report that phenol hydroxylation to hydroquinone is also catalyzed by human myeloperoxidase in the presence of a superoxide anion radical generating system, hypoxanthine and xanthine oxidase. No hydroquinone formation was detected in the absence of myeloperoxidase. At low concentrations superoxide disniutase stimulated, but at high concentrations inhibited, the conversion of phenol to hydroquinone. The inhibitory effect at high superoxide dismutase concentrations indicates that the active hydroxylating species of myeloperoxidase is not derived from its interaction with hydrogen peroxide. Furthermore, catalase a hydrogen peroxide scavenger, was found to have no significant effect on hydroxylation of phenol to hydroquinone, supporting the lack of hydrogen peroxide involvement. Mannitol (a hydroxyl radical scavenger) was found to have no inhibitory effect, but histidine (a singlet oxygen scavenger) inhibited hydroquinone formation. Based on these results we postulate that a myeloperoxidase-superoxide complex spontaneously rearranges to generate singlet oxygen and that this singlet oxygen is responsible for phenol hydroxylation to hydroquinone. These results also suggest that myeloperoxidase dependent hydroquinone formation could play a role in the production and accumulation of hydroquinone in bone marrow, the target organ of benzene-induced myelotoxicity.     

Hydroxylation of Phenol to Hydroquinone Catalyzed by A Human Myeloperoxidase-Superoxide Complex: Possible Implications In Benzene-Induced Myelotoxicity

Benzene, a known human rnyelotoxin and leukemogen is metabolized by liver cytochrome P-450 mono-oxygenase to phenol. Further hydroxylation of phenol by cytochrome P-450 monooxygenase results in the formation of mainly hydroquinone, which accumulates in the bone marrow. Bone marrow contains high levels of myeloperoxidase. Here we report that phenol hydroxylation to hydroquinone is also catalyzed by human myeloperoxidase in the presence of a superoxide anion radical generating system, hypoxanthine and xanthine oxidase. No hydroquinone formation was detected in the absence of myeloperoxidase. At low concentrations superoxide disniutase stimulated, but at high concentrations inhibited, the conversion of phenol to hydroquinone. The inhibitory effect at high superoxide dismutase concentrations indicates that the active hydroxylating species of myeloperoxidase is not derived from its interaction with hydrogen peroxide. Furthermore, catalase a hydrogen peroxide scavenger, was found to have no significant effect on hydroxylation of phenol to hydroquinone, supporting the lack of hydrogen peroxide involvement. Mannitol (a hydroxyl radical scavenger) was found to have no inhibitory effect, but histidine (a singlet oxygen scavenger) inhibited hydroquinone formation. Based on these results we postulate that a myeloperoxidase-superoxide complex spontaneously rearranges to generate singlet oxygen and that this singlet oxygen is responsible for phenol hydroxylation to hydroquinone. These results also suggest that myeloperoxidase dependent hydroquinone formation could play a role in the production and accumulation of hydroquinone in bone marrow, the target organ of benzene-induced myelotoxicity.     

Chitosan‐templated bio‐coloration of cotton fabrics via laccase‐catalyzed polymerization of hydroquinone

There is an increasing interest in the development of enzymatic coloration of textile fabrics as an alternative to conventional textile dyeing processes, which is successful for dyeing protein fibers. However, unmodified cotton fabrics are difficult to be dyed through enzyme catalysis due to the lack of affinity of biosynthesized dyes to cotton fibers. In order to improve the enzyme‐catalyzed dyeability of cotton fibers, chitosan was used to coat cotton fabrics as template. A novel and facile bio‐coloration technique using laccase catalysis of hydroquinone was developed to dye chitosan‐templated cotton fabrics. The polymerization of hydroquinone with the template of chitosan under the laccase catalysis was monitored by ultraviolet‐vis spectrophotometer on the absorbance of reaction solution. A significant peak of UV‐vis spectrum at 246 nm corresponding to large conjugated structures appeared and increased with increasing the duration of enzymatic catalysis. The effect of different treatment conditions on the laccase‐catalyzed dyeing of cotton fabric was investigated to determine their optimal parameters of laccase‐catalyzed coloration. Fourier‐transform infrared spectroscopy spectra demonstrated the formation of H‐bond and Schiff base reaction between chitosan and polymerized hydroquinone. Scanning electron microscopy indicated that the surface of dyed cotton fiber was much rougher than that of the control sample. Moreover, X‐ray photoelectron spectroscopy also revealed the existence of the chitosan/polymerized hydroquinone complex and polymerized hydroquinone on the dyed cotton fibers. This chitosan‐templated approach offers possibility for biological dyeing coloration of cotton fabrics and other cellulosic materials.     

Mimicking the photosynthetic system with strong hydrogen bonds to promote proton electron concerted reactions

A Copper(2+) complex with a Cu^II–C bond containing sp³ configuration was used to investigate the role of strong hydrogen bonds in proton coupled electron transfer (PCET) reactions. The only example of a Cu^II–C system realized so far is that using tris-(pyridylthio)methyl (tptm) as a tetradentate tripodal ligand. Using this ligand, [CuF(tptm)] and [Cu(tptm)(OH)] have been prepared. The former complex forms supra-molecular arrays of layers of the complex between which hydroquinone is intercalated in the crystalline phase. This hydroquinone intercalation crystal was prepared via the photochemical conversion of quinone during the crystallization process. This conversion reaction probably involves a proton coupled electron transfer process. The nuclear magnetic resonance spectroscopic analysis of the reaction mixture shows the presence of Cu(III) during the conversion reaction. These results strongly suggest the presence of the molecular aggregate of the [CuF(tptm)] complex, water and quinone in the solution phase during the quinone to hydroquinone conversion. The presence of this type of aggregate requires a strong hydrogen bond between the [CuF(tptm)] complex and water. The presence of this particular hydrogen bond is a unique character of such a complex that has the Cu^II–C bond. This complex is used as a model for photosynthetic water splitting since the photoconversion of quinone to hydroquinone also involves the production of oxygen from water.     

A chemiluminescence method to detect hydroquinone with water‐soluble sulphonato‐(salen)manganese(III) complex as catalyst

A water‐soluble sulphonato‐(salen)manganese(III) complex with excellent catalytic properties was synthesized and demonstrated to greatly enhance the chemiluminescence signal of the hydrogen peroxide ? luminol reaction. Coupled with flow‐injection technique, a simple and sensitive chemiluminescence method was first developed to detect hydroquinone based on the chemiluminescence system of the hydrogen peroxide–luminol–sulphonato‐(salen)manganese(III) complex. Under optimal conditions, the assay exhibited a wide linear range from 0.1 to 10 ng mL^–1 with a detection limit of 0.05 ng mL^–1 for hydroquinone. The method was applied successfully to detect hydroquinone in tap‐water and mineral‐water, with a sampling frequency of 120 times per hour. The relative standard deviation for determination of hydroquinone was less than 5.6%, and the recoveries ranged from 96.8 to 103.0%. The ultraviolet spectra, chemiluminescence spectra, and the reaction kinetics for the peroxide–luminol–sulphonato‐(salen)manganese(III) complex system were employed to study the possible chemiluminescence mechanism. The proposed chemiluminescence analysis technique is rapid and sensitive, with low cost, and could be easily extended and applied to other compounds. Copyright © 2015 John Wiley & Sons, Ltd.     

人参毛状根生物合成熊果苷的分离与鉴定

熊果苷(arbutin),化学名称为对-羟基苯-β-D-吡喃葡萄糖苷,能够竞争性抑制酪氨酸酶的活性从而抑制黑色素的形成,被国际公认为高效祛斑美白剂,是化妆品中理想的添加成分.人参(Panax ginseng C. A. Mey.)自古以来就是名贵药材,由于人参在栽培过程中存在着栽培困难、周期过长、地域限制等难题,人参的组织培养受到了广泛的重视.本实验室已建立了人参细胞大量培养体系[1]和人参毛状根培养体系[2],并把熊果苷与人参细胞配伍应用到化妆品生产中,产品深受广大消费者青睐.用植物培养物对外源底物进行生物转化,从而对其结构进行修饰,以获得更有意义的产物的研究报道很多[3～9],也是当今研究的热点.本实验室已对人参生物转化熊果苷的基本条件进行了初步探讨[10],本文在此基础上,对转化产物进行了分离鉴定.     

Reassessment of antioxidant activity of arbutin: Multifaceted evaluation using five antioxidant assay systems

Abstract

Arbutin, a practically used skin-lightening agent, has been reported to possess a weak antioxidant activity compared to that of its precursor, hydroquinone. However, its antioxidant activity has not been systematically evaluated. Hence, this study reassessed its activity using five assay systems. Assays were first performed using model radicals, DPPH radical and ABTS^?+. Arbutin showed weak DPPH radical-scavenging activity compared to that of hydroquinone, but showed strong ABTS^?+-scavenging activity. Its activity by ORAC assay was then evaluated using a physiologically relevant peroxyl radical. Arbutin exerted weak but long-lasting radical-scavenging activity and showed totally the same antioxidant activity as that of hydroquinone. Finally, it was shown that, in two cell-based antioxidant assays using erythrocytes and skin fibroblasts, arbutin exerted strong antioxidant activity comparable or even superior to that of hydroquinone. These findings indicate that the antioxidant activity of arbutin may have been under-estimated and suggest that it acts as a potent antioxidant in the skin.     

The impact of hydroquinone on acetylcholine esterase and certain human carbonic anhydrase isoenzymes (hCA I,II, IX,and XII)

Abstract

Carbonic anhydrases (CAs) are widespread and the most studied members of a great family of metalloenzymes in higher vertebrates including humans. CAs were investigated for their inhibition of all of the catalytically active mammalian isozymes of the Zn²⁺-containing CA, (CA, EC 4.2.1.1). On the other hand, acetylcholinesterase (AChE. EC 3.1.1.7), a serine protease, is responsible for ACh hydrolysis and plays a fundamental role in impulse transmission by terminating the action of the neurotransmitter ACh at the cholinergic synapses and neuromuscular junction. In the present study, the inhibition effect of the hydroquinone (benzene-1,4-diol) on AChE activity was evaluated and effectively inhibited AChE with K_i of 1.22?nM. Also, hydroquinone strongly inhibited some human cytosolic CA isoenzymes (hCA I and II) and tumour-associated transmembrane isoforms (hCA IX, and XII), with K_is in the range between micromolar (415.81?μM) and nanomolar (706.79?nM). The best inhibition was observed in cytosolic CA II.