环氧角鲨烯环化酶在三萜化合物生物合成中的进展

三萜类化合物是植物代谢产物中最具多样性的化合物之一,具有广泛的生理活性和重要的经济价值.环氧角鲨烯环化酶(oxidosqualene cyclases,OSCs)催化2,3-氧化鲨烯环化生成不同类型的甾醇和植物三萜化合物,对天然产物的结构多样性具有重要意义.然而,目前对于OSCs酶催化2,3-氧化鲨烯发生环化多样性的机...     

甾醇生物合成中的关键酶-环氧角鲨烯环化酶的分子生物学研究

植物体中环氧角鲨烯环化酶催化2,3-环氧角鲨烯形成一系列三萜烯,为甾醇和三萜化合物的生物合成提供前体。这一催化反应被认为是甾醇和三萜化合物生物合成分支形成的关键位点．综述了甾醇和三萜化合物生物合成中的关键酶——环氧角鲨烯环化酶（OSCs）家族的生物学功能,基因克隆与属性,酶的细胞定位与酶活的表达调控等分子生物学研究进展．     

产角鲨烯细胞工厂的构建及关键基因的筛选、克隆与表达

角鲨烯因具有很强的抗氧化、抗菌和抗肿瘤活性,被普遍应用于医药、保健品和化妆品等领域。文中在实验室构建的高效合成萜类化合物底盘菌株工作的基础上,以角鲨烯为目标产物,通过过表达法尼基焦磷酸合酶基因ispA得到高效合成三萜化合物的底盘菌株;然后对原核生物来源的角鲨烯合酶进行系统发育分析、筛选、克隆和表达,得到两株高效合成角鲨烯的大肠杆菌Escherichia coli工程菌株。其中,导入来源于嗜热蓝细菌Thermosynechococcus elongatus和深蓝聚球蓝细菌Synechococcus lividus的角鲨烯合酶的工程菌株,角鲨烯产量分别达到 (16.5±1.4) mg/g (细胞干重含量,后同) 和 (12.0±1.9) mg/g,发酵液浓度达到 (167.1±14.3) mg/L和(121.8±19.5) mg/L。相比于当前普遍使用的人源角鲨烯合酶及初代菌株,来源于T. elongatus和S. lividus的角鲨烯合酶分别使角鲨烯产量大幅提升了3.3倍和2.4倍,为原核细胞异源合成角鲨烯打下坚实的基础。     

白念珠菌角鲨烯环氧化酶基因开放读框的克隆及其在大肠杆菌中的表达

根据白念珠菌角鲨烯环氧化酶基因的开放读框中编码^1MSSVKY^6的序列和编码^492NEIVR^496的序列分别设计上,下游引物,以白念珠菌ATCC11006的基因组DNA为模板进行PCR扩增;将PCR产物克隆并做序列分析后,在大肠杆菌中进行表达。结果PCR获得大小约为1.5kb的产物,测序分析表明克隆的产物大小为1491bp。正是白念珠菌角鲨烯环氧化酶基因的开放读框,表达得到约为80kDa大小的蛋白,与理论计算一致。本研究为开展特比萘芬与其作用靶酶关系的研究奠定了基础。     

罗汉果种仁中角鲨烯的提取及其结构表征

以石油醚为溶剂采用索氏提取法提取罗汉果种仁油脂,采用HPLC检测,初步确定罗汉果种仁中含有角鲨烯,含量为12.5%。经柱层析、HPLC制备后得纯度为98.5%的化合物单体,经IR、1H-NMR、13C-NMR、MS检测,确认罗汉果种仁油中含有角鲨烯。     

沙打旺的化学成分

从沙打旺分离到１５个化合物,经光谱分析,理化实验及与已知化合物比较,鉴定了１１个化合物,其中两个为四环三萜类化合物,分别鉴定为（２０Ｒ,２４Ｓ）－３．１６－二羰基－６α,２５－二羟基－２０,２４－环氧－９．１９－环羊甾酮（９）和（２０Ｒ,２４Ｓ）－３,１６－二羰基－６α,２５－二羟基－２０,２４－环氧－９,１９－环－２３氧－羊毛甾酮（１０）。     

大肠杆菌角鲨烯合成途径的构建与调控

角鲨烯因其具有良好的抗氧化功能而被广泛应用于食品、医药、化妆品、工业应用等领域。本实验在大肠杆菌中构建角鲨烯合成途径,通过对其合成途径中关键限速酶(1-脱氧-D-木酮糖-5-磷酸合酶和异戊烯基二磷酸异构酶)过表达的方法进行初步调控,使角鲨烯的产量提升了近三倍。之后采用单因素试验对其发酵培养基和培养条件进行优化,以此来提高角鲨烯的产量。优化发酵条件后,使用最优发酵培养基——TB培养基,在最佳发酵条件:37℃,220r/min培养至OD600约为1.2时加入终浓度为0.1mmol/L的IPTG诱导剂,25℃条件下诱导48h,角鲨烯产量可达73.88mg/L。     

生物活性产品角鲨烯的特性及其开发应用

角鲨烯是几类常见甾醇的前体物质,具有重要的生物活性和广泛的食药价值。由于对海洋野生动物及渔业资源的保护,角鲨烯的商业化生产受到了极大限制。寻找新的可持续来源的角鲨烯资源十分重要。本文主要阐述了角鲨烯的生物活性、来源及其应用,分析了不同生物来源角鲨烯的生物合成途径与常见的提取工艺,提出了利用微生物,尤其是微藻进行高价值角鲨烯绿色生产的经济可行性。文章以期为角鲨烯的工业化生产与应用提供理论基础。     

基于转录组测序对油茶角鲨烯合酶基因的克隆及分析

油茶是中国重要的木本油料树种,而角鲨烯在茶籽油中含量多少是茶油品质的重要指标,为提高油茶角鲨烯含量,以油茶种子转录组测序为基础,根据Unigene设计SQS基因RACE引物,克隆出基因全长共1 490 bp,开放阅读框1 266 bp,编码422个氨基酸,将氨基酸序列与其他植物SQS进行比对,构建进化树,分析物种间进化关系,进行蛋白质的生物信息学分析,包括蛋白质结构特点、理化性质、氨基酸组成及稳定性分析; 跨膜区域分析; 信号肽识别位点; 磷酸化位点; 二级结构及功能; 结构域分析。通过转录组测序和荧光实时定量分析了SQS基因在油茶种子发育各时期表达量变化规律,并提取各时期油脂,测定角鲨烯含量,发现两种基因表达量分析方法的结果有一致的变化趋势,且与各月份间角鲨烯含量有相同的变化规律。证明了转录组测序的有效性,并推测油茶角鲨烯合酶基因的表达量变化与角鲨烯含量的多少有直接关系,为后续从分子手段提高茶籽油中角鲨烯含量提供了理论基础。     

外源因子对桦褐孔菌发酵产桦褐孔菌醇的影响

食药用真菌因其丰富的天然活性物质成为具有开发潜力的药物来源。桦褐孔菌Inonotus obliquus作为一种珍稀的药用真菌,因其对糖尿病、消化系统疾病、心血管疾病、肝病和癌症等疾病有良好的治疗效果而受到广泛关注。桦褐孔菌醇（inotodiol）是桦褐孔菌特有的一种羊毛甾烷型三萜类化合物,具有多种抗癌活性。本文的主要目的是研究外源因子的添加对桦褐孔菌液态发酵产桦褐孔菌醇的影响,以及对桦褐孔菌醇合成途径中酶活的影响。结果表明：最佳外源因子是香叶醇,最佳添加浓度和添加时间分别为0.02%（V/V）和第144小时。发酵结束时（240h）桦褐孔菌醇的产量为27.89mg/L是对照组（9.23mg/L）的3.02倍。通过对比添加香叶醇后桦褐孔菌醇的产量变化以及合成途径中4种酶（法尼基焦磷酸合酶、角鲨烯合酶、角鲨烯环氧化酶和羊毛甾醇合酶）的活性变化,对香叶醇的作用机制进行了初步探究。研究结果表明添加香叶醇后,4种酶活性均较对照组有显著的提高,与此对应的桦褐孔菌醇产量也显著增加,说明这4种酶在桦褐孔菌醇合成途径中起到了积极的作用。     

Identification of the Arabidopsis dry2/sqe1‐5 mutant reveals a central role for sterols in drought tolerance and regulation of reactive oxygen species

Squalene epoxidase enzymes catalyse the conversion of squalene into 2,3‐oxidosqualene, the precursor of cyclic triterpenoids. Here we report that the Arabidopsis drought hypersensitive/squalene epoxidase 1‐5 (dry2/sqe1‐5) mutant, identified by its extreme hypersensitivity to drought stress, has altered stomatal responses and root defects because of a point mutation in the SQUALENE EPOXIDASE 1 (SQE1) gene. GC‐MS analysis indicated that the dry2/sqe1‐5 mutant has altered sterol composition in roots but wild‐type sterol composition in shoots, indicating an essential role for SQE1 in root sterol biosynthesis. Importantly, the stomatal and root defects of the dry2/sqe1‐5 mutant are associated with altered production of reactive oxygen species. As RHD2 NADPH oxidase is de‐localized in dry2/sqe1‐5 root hairs, we propose that sterols play an essential role in the localization of NADPH oxidases required for regulation of reactive oxygen species, stomatal responses and drought tolerance.     

浙贝母角鲨烯合酶全长cDNA的克隆及功能分析

鲨烯是甾醇和其他三萜类化合物的关键代谢中间体,其生物合成由鲨烯合酶（squalene synthase,SQS）催化,该酶将2分子法呢基焦磷酸转化为鲨烯。浙贝母异甾体生物碱的生物合成途径与三萜类化合物类似。在本研究中,基于cDNA末端的快速扩增（RACE）技术克隆了浙贝母鲨烯合酶 (FtSQS）基因的全长cDNA,GenBank登录号为KF551097.2。通过生物信息学方法对FtSQS进行详细表征,包括保守区检测、序列同源分析、二级和三级结构预测及系统发育树分析。结果表明,其开放阅读框（ORF）为1 230 bp,编码409个氨基酸,FtSQS氨基酸序列与印度甘松、截形苜蓿、紫衫、马铃薯、柴胡、金铁锁和拟南芥的SQS氨基酸同源性分别达到73.84%、73.23%、72.24%、70.66%、70.66%、69.44%和68.14%。启动子分析表明,FtSQS的5′上游区域具有与生理和环境因素相关的各种潜在因素。为了获得可溶性FtSQS表达,从羧基末端截断24个疏水氨基酸,构建了原核表达载体pGEX-2T-FtSQSΔTM,并在大肠杆菌BL21(DE3)中表达。SDS-PAGE检测到约66 kD的重组FtSQSΔTM蛋白。体外酶促反应证明,FtSQS可以催化FPP转化成鲨烯。qRT-PCR分析FtSQS mRNA在叶中的表达量最高,茎、根次之,而在鳞茎中表达水平最低。这提示,叶子是浙贝母碱生物合成的主要活性器官。FtSQS的鉴定及功能研究为浙贝母次生代谢产物的研究提供了重要依据。     

Role of Organotellurium Species in Tellurium Neuropathy

Exposure of weanling rats to a diet containing 1% elemental tellurium causes segmental demyelination of peripheral nerve, and an inhibition of squalene epoxidase. This inhibition is thought to be the mechanism of action leading to demyelination. Tellurite appears to be the active inhibitory species in a cell-free system but the active species in vivo is unknown. We examined potassium tellurite (K₂TeO₃) and three organotellurium compounds for their ability to inhibit squalene epoxidase in Schwann cell cultures and to induce demyelination in weanling rats. K₂TeO₃ had no effect on squalene epoxidase activity in cultured Schwann cells and caused no demyelination in vivo. All three organotellurium compounds caused inhibition of squalene epoxidase in vitro and caused demyelination in vivo. (CH₃)₂TeCl₂ was the most potent of these compounds and its neuropathy most resembled that caused by elemental tellurium. These data are consistent with the hypothesis that tellurium-induced demyelination is a result of squalene epoxidase inhibition and suggest that a dimethyltelluronium compound may be the neurotoxic species presented to Schwann cells in vivo.     

Arabidopsis thaliana squalene epoxidase 1 is essential for root and seed development

Squalene epoxidase converts squalene into oxidosqualene, the precursor of all known angiosperm cyclic triterpenoids, which include membrane sterols, brassinosteroid phytohormones, and non-steroidal triterpenoids. In this work, we have identified six putative Arabidopsis squalene epoxidase (SQE) enzymes and used heterologous expression in yeast to demonstrate that three of these enzymes, SQE1, SQE2, and SQE3, can epoxidize squalene. We isolated and characterized Arabidopsis sqe1 mutants and discovered severe developmental defects, including reduced root and hypocotyl elongation. Adult sqe1-3 and sqe1-4 plants have diminished stature and produce inviable seeds. The sqe1-3 mutant accumulates squalene, consistent with a block in the triterpenoid biosynthetic pathway. Therefore, SQE1 function is necessary for normal plant development, and the five SQE-like genes remaining in this mutant are not fully redundant with SQE1.     

Sterol biosynthesis by a prokaryote: first in vitro identification of the genes encoding squalene epoxidase and lanosterol synthase from Methylococcus capsulatus

Sterol biosynthesis by prokaryotic organisms is very rare. Squalene epoxidase and lanosterol synthase are prerequisite to cyclic sterol biosynthesis. These two enzymes, from the methanotrophic bacterium Methylococcus capsulatus, were functionally expressed in Escherichia coli. Structural analyses of the enzymatic products indicated that the reactions proceeded in a complete regio- and stereospecific fashion to afford (3S)-2,3-oxidosqualene from squalene and lanosterol from (3S)-2,3-oxidosqualene, in full accordance with those of eukaryotes. However, our result obtained with the putative lanosterol synthase was inconsistent with a previous report that the prokaryote accepts both (3R)- and (3S)-2,3-oxidosqualenes to afford 3-epi-lanosterol and lanosterol, respectively. This is the first report demonstrating the existence of the genes encoding squalene epoxidase and lanosterol synthase in prokaryotes by establishing the enzyme activities. The evolutionary aspect of prokaryotic squalene epoxidase and lanosterol synthase is discussed.     

Dual Localization of Squalene Epoxidase, Erg1p, in Yeast Reflects a Relationship between the Endoplasmic Reticulum and Lipid Particles

Squalene epoxidase, encoded by the ERG1 gene in yeast, is a key enzyme of sterol biosynthesis. Analysis of subcellular fractions revealed that squalene epoxidase was present in the microsomal fraction (30,000 × g) and also cofractionated with lipid particles. A dual localization of Erg1p was confirmed by immunofluorescence microscopy. On the basis of the distribution of marker proteins, 62% of cellular Erg1p could be assigned to the endoplasmic reticulum and 38% to lipid particles in late logarithmic-phase cells. In contrast, sterol Δ²⁴-methyltransferase (Erg6p), an enzyme catalyzing a late step in sterol biosynthesis, was found mainly in lipid particles cofractionating with triacylglycerols and steryl esters. The relative distribution of Erg1p between the endoplasmic reticulum and lipid particles changes during growth. Squalene epoxidase (Erg1p) was absent in an erg1 disruptant strain and was induced fivefold in lipid particles and in the endoplasmic reticulum when the ERG1 gene was overexpressed from a multicopy plasmid. The amount of squalene epoxidase in both compartments was also induced approximately fivefold by treatment of yeast cells with terbinafine, an inhibitor of the fungal squalene epoxidase. In contrast to the distribution of the protein, enzymatic activity of squalene epoxidase was only detectable in the endoplasmic reticulum but was absent from isolated lipid particles. When lipid particles of the wild-type strain and microsomes of an erg1 disruptant were mixed, squalene epoxidase activity was partially restored. These findings suggest that factor(s) present in the endoplasmic reticulum are required for squalene epoxidase activity. Close contact between lipid particles and endoplasmic reticulum may be necessary for a concerted action of these two compartments in sterol biosynthesis.     

脱乙酰壳多糖处理增加人参细胞皂苷的累积和皂苷合成关键酶基因的转录

脱乙酰壳多糖处理可以诱导人参细胞产生H2 O2 ,增加人参皂苷的累积 ,提高鲨烯合酶 (squalenesynthase,GSS)与鲨烯环氧酶 (squaleneepoxidase,GSE)基因的转录水平。质膜NADPH氧化酶的抑制剂DPI,H2 O2 的淬灭剂DMTU与DHC可以抑制脱乙酰壳多糖的这些效应 ,暗示脱乙酰壳多糖可以活化质膜NADPH氧化酶而产生H2 O2 ,H2 O2 进而作为第二信使诱导gss与gse基因转录以及皂苷的合成。质膜钙通道抑制剂LaCl3与内质网钙通道抑制剂RR ,以及蛋白激酶抑制剂K2 5 2a都能削弱脱乙酰壳多糖促进皂苷积累和gss、gse转录的效应 ,说明胞内Ca2 浓度的升高与蛋白质磷酸化都参与了脱乙酰壳多糖诱导的gss、gse的转录以及皂苷的合成     

Biosynthesis of sterols and triterpenes in cell suspension cultures of Uncaria tomentosa

Pectin administered to Uncaria tomentosa cell suspension cultures, was found to increase the production of triterpene acids (ursolic and oleanolic acid), however, neither growth nor sterol accumulation were affected. Cell cultures showed that pectin treatment caused a rapid threefold increase in the activities of enzymes involved in the biosynthesis of C(5) and C(30 )isoprenoid, such as isopentenyl diphosphate isomerase and squalene synthase. The activity of a farnesyl diphosphatase, which could divert the flux of farnesyl diphosphate to farnesol, was two times lower in elicited than in control cells. Elicited cells also transformed more rapidly a higher percentage of [5-(3)H]mevalonic acid into triterpene acids. Interestingly, addition of terbinafine, an inhibitor of squalene epoxidase, to elicited cell cultures inhibited sterol accumulation while triterpene production was not inhibited. These results suggest that in U. tomentosa cells, both the previously mentioned enzymes and those involved in squalene 2,3-oxide formation play an important regulatory role in the biosynthesis of sterols and triterpenes.