长春花悬浮培养细胞对天麻素的生物转化

应用长春花 (Catharanthusroseus (L .)G .Don)悬浮细胞培养体系对天麻素进行了生物转化反应研究。经过8d培养形成一个转化产物 ,应用光谱方法鉴定转化产物的结构为对羟基苯甲醇 ,为天麻素水解后形成的甙元。     

内生真菌和诱导子对长春花悬浮细胞及生物碱合成的影响

目的:探讨内生真茵和诱导子对长春花悬浮细胞生长及生物碱合成的影响.方法:接种内生真茵与悬浮细胞的共同培养,添加诱导子到细胞培养液中对长春花悬浮细胞进行诱导处理,检测实验处理后长春花悬浮细胞各项生化指标.结果:培养液pH值上升,悬浮细胞MDA舍量增加,细胞抗氧化酶(POD、CAT)和生物碱合成的关键性酶(PAL、TDC)活性升高.生物碱产量得到提高,诱导组悬浮细胞生物碱产量达到770.36μg/gFW,共培养组生物碱产量为693.76 μg/gFW,分别比对照组提高了48%和32%.结论:真菌及其诱导子能改变长春花悬浮培养细胞的态势,导致细胞代谢结构的改变,使生物碱的产量提高.     

长春花悬浮培养细胞对天麻素的生物转化

应用长春花(Catharanthus roseus (L.) G. Don)悬浮细胞培养体系对天麻素进行了生物转化反应研究.经过8 d培养形成一个转化产物,应用光谱方法鉴定转化产物的结构为对羟基苯甲醇,为天麻素水解后形成的甙元.     

光照强度对曼陀罗和紫花曼陀罗生长发育的影响

以曼陀罗(Datura stramonium)及其变种紫花曼陀罗(Datura stramonium var. tatual)为研究材料, 采用光照培养箱对盆栽苗进行5个光照强度的处理, 研究其生长发育、叶片解剖结构、叶片及茎色素含量对不同光照强度的响应。结果表明: (1)在试验设置的光照强度范围内, 增强光照强度有利于曼陀罗和紫花曼陀罗的发育及茎、叶生物量的积累; 13 000和18 000 lx两个光照强度下两供试曼陀罗长势最好; 同等光照强度下紫花曼陀罗的株高、基茎粗、叶片数目、茎叶生物量大于曼陀罗, 但差异性不显著。(2)两供试曼陀罗叶片厚度、栅栏组织厚度、海绵组织厚度及气孔密度、气孔指数均随着试验光照强度的增强而增加; 紫花曼陀罗气孔密度及气孔指数明显高于曼陀罗。(3)两供试曼陀罗叶片中叶绿素含量均随试验设置光照强度的增强呈先升后降的趋势; 随试验设置光照强度的增强, 两供试曼陀罗茎中叶绿素a、b及类胡萝卜素含量变化趋势不一致; 茎中花色素苷、类黄酮及总酚含量的变化情况是: 两供试曼陀罗均与光照强度呈正相关, 但紫花曼陀罗比曼陀罗含量高, 这也是紫花曼陀罗花、茎等器官呈紫色的物质基础, 加上气孔密度和气孔指数较大等特性, 使紫花曼陀罗较曼陀罗适应性更强。     

紫花曼陀罗幼苗中紫色异细胞分布特征及其形态建成影响条件的初步研究

应用植物显微技术观察了幼苗期紫花曼陀罗（Datura stramonium L.var.tatula Torrey）中紫色异细胞的分布及不同温度与光照下培养的紫花曼陀罗幼苗茎中紫色异细胞的形态和分布差异。结果：（1）紫花曼陀罗中紫色异细胞分布在茎与叶地上器官中,根中则不存在。（2）强光和高温下培养的紫花曼陀罗幼苗茎中紫色异细胞的颜色明显加深、透明度下降,细胞间隙减小;而弱光和低温下其形态特征表现与上述相反。（3）强光处理下紫色异细胞横切面积、纵切长度以及数量均显著增加（P<0.05）;弱光下该异细胞横切面积、纵切长度均显著减少（P<0.05）,但数量显著增加（P<0.05）。（4）高温处理下紫色异细胞横切面积、纵切长度以及数量均显著增加（P<0.05）;低温下该异细胞仅数量显著增加（P<0.05）,其横切面积、纵切长度虽减小但变化差异性不显著（P<0.05）。结论：紫花曼陀罗中紫色异细胞的形态建成受光照和温度影响,曼陀罗（Datura stramonium L.）变种紫花曼陀罗（D.stramonium L.var.tatula Torrey）各营养器官中进化出紫色异细胞对其更好地适应光照和温度等生态环境变化有积极作用。     

转基因何首乌毛状根对8种活性成分的生物转化研究

目的：利用转基因何首乌毛状根悬浮培养体系对青蒿素等8种活性化合物进行生物转化研究。方法：分别向预培养9 d的何首乌毛状根培养体系中加入底物,共培养7 d后终止转化,通过TLC和/或HPLC检测转化产物,使用柱色谱法分离纯化产物。结果：化合物呋喃橐吾酮（6）发生了生物转化,并分离得到两个转化产物;对苯二酚（7）被转化,分离并鉴定出1个转化产物;青蒿素（8）发生了转化,分离得到两个转化产物。结论：转基因何首乌毛状根悬浮体系中存在多种生物酶系统,可对外源底物进行糖基化、氧化、还原和羟基化修饰。     

人参毛状根生物合成天麻素转化体系的建立

以对羟基苯甲醇转化率和天麻素含量为指标,探索适宜于人参毛状根生物合成天麻素的培养条件如底物浓度、转化持续时间和培养阶段.结果表明,B5液体培养基培养22d的人参毛状根,在含有1.000mmol·L-1对羟基苯甲醇的生物合成培养基中转化24h,合成的天麻素含量占干重的6.65%,对羟基苯甲醇转化率达到84.8%,说明以人参毛状根为反应器可以合成人参所不具有的天麻素.     

雷公藤悬浮细胞原生质体的制备及瞬时转化体系的建立

为探索药用植物雷公藤(Tripterygium wilfordii)悬浮细胞原生质体提取的最优条件,并建立雷公藤原生质体瞬时转化体系,以雷公藤悬浮细胞为材料,对酶解液配比、酶解时间、甘露醇浓度及处理转速进行考察。用PEG介导的瞬时转化法将外源基因转化到雷公藤原生质体中。结果表明,以雷公藤悬浮细胞为材料提取原生质体的最佳条件是酶液配比为2.0%纤维素酶+0.5%果胶酶+0.5%离析酶,甘露醇浓度为0.6 mol·L–1,酶解10小时,处理转速为67×g;用PEG介导法将含有编码GFP的植物表达载体转化雷公藤悬浮细胞原生质体,激光共聚焦扫描显微镜下细胞显示绿色荧光。通过实验筛选得到雷公藤悬浮细胞原生质体的最佳提取条件,建立了雷公藤悬浮细胞原生质体的瞬时转化体系,为进一步开展雷公藤功能基因及合成生物学研究奠定了基础。     

Ce(NH4)2(NO3)6对蔓茎堇菜悬浮细胞凋亡和总黄酮含量的影响

用DNA Laddering和DAPI荧光检测法对Ce(NH4)2(NO3)6诱导的蔓茎堇菜(Viola diffusa Ging.)悬浮细胞的凋亡情况进行研究,同时还测定了诱导过程中悬浮细胞的生长量和总黄酮含量。结果表明,Ce(NH4)2(NO3)6可诱导蔓茎堇菜悬浮细胞发生凋亡,1.0 mmol.L-1Ce(NH4)2(NO3)6胁迫诱导培养8 d时,细胞凋亡率最高(55.7%);总黄酮含量显著增加,达2.820%。表明Ce(NH4)2(NO3)6在诱导蔓茎堇菜悬浮细胞凋亡并抑制其生长的同时,还能促进黄酮类化合物的合成。     

水稻悬浮细胞再生及根癌农杆菌介导转化的影响因素

已经成功报道的农杆菌介导的水稻遗传转化多以活力较高的胚性愈伤为材料,很少以水稻悬浮细胞作为受体．另外,利用农杆菌转化多数都是通过浸泡的方式进行侵染．本实验利用滴加浸染法进行农杆菌介导转化水稻悬浮细胞,探讨影响 DNA 转化效率的因素．研究显示,在转化前,将水稻悬浮细胞在愈伤诱导培养基上培养1～2周,诱导产生直径为2～3 mm的微小愈伤组织对转化非常重要.微小愈伤组织大小不应小于 2 mm;对悬浮细胞短时间培养不但会缩短植株再生时间,而且会提高转化效率．此外,侵染农杆菌的浓度、侵染时间和不同侵染方法也影响 T-DNA 插入基因组的效率．用 1 ml Ａ600值为 0.5 浓度的农杆菌悬液滴加在水稻悬浮细胞诱导的愈伤,培养3 d或直到可见农杆菌菌落,此方法可以得到较高转化效率．将再生的潮霉素抗性的转化植株在含有 50 mg/L 潮霉素的分化和生根培养基中筛选得到,并对转化植株 gus 基因的表达进行 PCR 检测.结果显示,用 Ａ600值为 0.5 浓度的农杆菌浸泡侵染 20 min和滴加浸染法,分别得到PCR阳性植株率为 70% 和92%.     

Production of Gastrodin Through Biotransformation of p-hydroxybenzaldehyde Using Cell Suspension Cultures of Datura tatula L.

The conversion of exogenous p-hydroxybenzaldehyde into p-hydroxy-methyl-phenol-β-D-glucoside (gastrodin) was studied using cell suspension cultures of Datura tatula L. The chemical structure of the synthesized gastrodin was identified on the basis of spectral analysis and chemical evidence. The procedure of conversion of p-hydroxybenzaldehyde into gastrodin by D. tatula L. cell suspension cultures was established. The synthesized gastrodin (II) was isolated from the ferment liquor and identified by spectral analysis. Simultaneously, the p-hydroxybenzyl alcohol (I) that was converted through biotransformation of p-hydroxybenzaldehyde by cell suspension cultures of D. tatula L. was also isolated and identified. The efficiency of glucosylation of p-hydroxybenzaldehyde was remarkably enhanced by the addition of salicylic acid (0.1 mg/L) and the maintenance of low pressure (0.001 MPa) in a 25-L airlift loop bioreactor. The biotransformation of exogenous p-hydroxybenzaldehyde to gastrodin using cell suspension cultures of D. tatula L. is a promising approach.     

Biotransformation of 18 beta-glycyrrhetinic acid by cell suspension cultures of Glycyrrhiza glabra.

Two biotransformation products formed from 18 beta-glycyrrhetinic acid by cell suspension cultures of Glycyrrhiza glabra were isolated and their structures determined by chemical and spectral data as 3-O-[alhpa-L-arabinopyranosyl-(1----2)-beta-D-Glucuronopy ranosyl]-24- hydroxy-18 beta-glycyrrhetinic acid and 30-O-beta-D-glycopyrano-syl-18 beta-glycyrrhetinic acid. The formation of glycyrrhizin, the main triterpene glucuronide of the licorice root, was not detected among the biotransformation products. This is the first report of the glucuronylation of an exogenous triterpene in plant cell cultures.     

Biotransformation of withanolides by cell suspension cultures of Withania somnifera (Dunal)

The biotransformation potential of cell suspension cultures generated from Withania somnifera leaf was investigated, using withanolides, i.e. withanolide A, withaferin A, and withanone as precursor substrates. Interestingly, the cell suspension cultures showed inter-conversion of withanolides, as well converted to some unknown compounds, released to the culture media. The bio-catalyzed withanolide was detected and quantified by TLC and HPLC, respectively. There is noticeable conversion of withanolide A to withanone, and vice versa though at a lower level. The type of reaction of this biotransformation appears to be substitution of 20-OH group to 17-OH in withanolide A. In this paper, we present for the first time the possibility of biotransformation by inter-conversion of withanolides of pharmacological importance through cell suspension culture of W. somnifera. The possible role of putative cytochrome P₄₅₀ hydroxylases is implicated in the conversion.     

Novel biotransformation processes of dihydroartemisinic acid and artemisinic acid to their hydroxylated derivatives by two plant cell culture systems

Novel biotransformation processes of dihydroartemisinic acid (1) and artemisinic acid (2) to their hydroxylated derivatives were investigated using the cell suspension cultures of Catharanthus roseus and Panax quinquefolium crown galls as two biocatalyst systems. Five biotransformation products, 3-α-hydroxydihydroartemisinic acid (3), 3-β-hydroxydihydroartemisinic acid (4), 15-hydroxy-cadin-4-en-12-oic acid (5), 3-α-hydroxyartemisinic acid (6) and 3-β-hydroxyartemisinic acid (7), were isolated by chromatograph methods and identified by the analysis of ¹H NMR, ¹³C NMR, and ESI-MS spectra. Compounds 3–5 were obtained for the first time by biotransformation process. It was also the first time to transform artemisinic acid to yield epimeric 3-hydroxy artemisinic acids in plant cell culture system. The biocatalyst system of C. roseus cell cultures showed a great capacity of regio- and stereo-selective hydroxylation in allyl group of the exogenous substrates. The results also showed that the biocatalyst system of P. quinquefolium crown galls possessed the ability to hydroxylate propenyl group of exogenous substrates in a regio- and substrate-selective manner. Furthermore, the in vitro antitumor activity of the hydroxyl products was evaluated by MTT assay. The result indicated that α-hydroxyl products possessed stronger antitumor activity than β-hydroxyl products against the HepG2 and GLC-82 cell lines.     

Biotransformation of 2-(4-methoxybenzyl)-l-cyclohexanone by cell cultures ofSolatium aviculare

During the search for compounds with insect juvenile hormone activity, the biotransformation of 2-(4-methoxybenzyl)-l-cyclohexanone, of 2-(4-methoxybenzyl)-l-cyclohexanone ethylene acetal and of both isomers of 2-(4-methoxybenzyl)-l-cyclohexanol by plant cells was examined. The compounds were metabolized by cell suspension culture of Solatium aviculare Forst. The reaction conditions were optimized and the metabolic products isolated and identified. A scheme of biotransformation pathway has been proposed.     

Monoclonal antibody against a cell wall marker protein for embryogenic potential of <Emphasis Type="Italic">Dactylis glomerata</Emphasis> L. suspension cultures

We identified and isolated a monoclonal antibody (MAb 3G2) raised against extracellular proteins from microcluster cells of orchard grass (Dactylis glomerata L.) embryogenic suspension culture. MAb 3G2 recognized with high specificity an antigen ionically bound within the primary cell wall and in the culture medium of microcluster cells. Two-dimensional polyacrylamide gel analysis and blotting of proteins on PVDF membrane showed that MAb 3G2 detected a single polypeptide of apparent molecular mass of 48 kDa and an isoelectric point (pI) of 5.2, designated EP48. A transient expression during somatic embryogenesis was observed for EP48. Indirect immunofluorescence showed that this protein highly accumulated in the cell walls of some single cells, microclusters and partly in proembryogenic masses (PEMs), but not in globular embryos of the embryogenic cell line and microclusters from the non-embryogenic cell line. Signal intensity varied between individual cells of the same population and in successive stages of somatic embryo development. Screening of several D. glomerata L. embryogenic and non-embryogenic cell lines with MAb 3G2 indicated the presence of ECP48 in only embryogenic suspension cultures at early stages of embryo development long before morphological changes have taken place and thus it could serve as an early marker for embryogenic potential in D. glomerata L. suspension cultures.     

Biotransformation studies using hairy root cultures - A review

Agrobacterium rhizogenes induced hairy root cultures are entering into a new juncture of functional research in generating pharmaceutical lead compounds by bringing about chemical transformations aided through its inherent enzyme resources. Rational utilization of hairy root cultures as highly effective biotransformation systems has come into existence in the last twenty years involving a wide range of plant systems as well as exogenous substrates and diverse chemical reactions. To date, hairy root cultures are preferred over plant cell/callus and suspension cultures as biocatalyst due to their genetic/biochemical stability, hormone-autotrophy, multi-enzyme biosynthetic potential mimicking that of the parent plants and relatively low-cost cultural requirements. The resultant biotransformed molecules, that are difficult to make by synthetic organic chemistry, can unearth notable practical efficacies by acquiring improved physico-chemical properties, bioavailability, lower toxicity and broader therapeutic properties. The present review summarizes the overall reported advances made in the area of hairy root mediated biotransformation of exogenous substrates with regard to their reaction types, plant systems associated, bacterial strains/molecules involved and final product recovery.     

Oxidation of 8'-hydroxy abscisic acid in Black Mexican Sweet maize cell suspension cultures

In a biotransformation study to prepare deuterium labelled phaseic acid (PA) from deuterated abscisic acid (ABA), the product contained fewer deuterium atoms than expected. Thus, spectroscopic data of isolated deuterated PA prepared from biotransformation of (+)-5,8',8',8'-d4-ABA in maize (Zea mays L. cv. Black Mexican Sweet) cell suspension cultures showed 83% deuterium incorporation at the 8'-exo position. Also, metabolism studies of (+)-4,5-d2-ABA in maize resulted in the isolation of deuterium labelled ABA derivatives, namely PA, dihydrophaseic acid (DPA), 4'-O-beta-D-glucopyranosylDPA, 8'-hydroxyPA, 8'-hydroxyDPA and 8'-oxoDPA, as deduced from spectroscopic methods. These combined results suggested the presence of an aldehyde intermediate which is either: (a) reduced to 8'-hydroxyABA and cyclized to PA, or (b) is hydrated and cyclized to 8'-hydroxyPA or (c) is further oxidized to the acid and cyclized to 8'-oxoPA. The chemical synthesis of this intermediate, as well as its biotransformation in maize cell cultures is presented.     

Biotransformation of 3b-Hydroxyandrost-5-en-17-one by Cell Suspension Cultures of Catharanthus roseus

Catharanthus roseus (L.) G. Don cell suspension cultures were used to transform 3b-hydroxyandrost-5-en-17-one, the products were isolated by chromatographic methods. Their structures were established by means of NMR and MS spectral analyses. Nine metabolites were respectively elucidated as: androst-4-ene-3,17-dione (Ⅰ), 6a-hydroxyandrost-4-ene-3,17-dione (Ⅱ), 6a,17b-dihydroxyandrost-4-en-3-one (Ⅲ), 6b-hydroxyandrost-4-ene-3,17-dione (Ⅳ), 17b-hydroxyandrost-4-en-3-one (Ⅴ), 15a,17b-dihydroxyandrost-4-en-3-one (Ⅵ), 15b,17b-dihydroxyandrost-4-en-3-one (Ⅶ), 14a-hydroxyandrost-4-ene-3,17-dione (Ⅷ), 17b-hydroxyandrost-4-ene-3,16-dione (Ⅸ). It is the first time to obtain the above compounds by biotransformation with Catharanthus roseus cell cultures.     

Evidence of a new biotransformation pathway of p-coumaric acid into p-hydroxybenzaldehyde in Pycnoporus cinnabarinus

Pycnoporus cinnabarinus MUCL39533 was shown to be able to convert p-coumaric acid into p-hydroxybenzaldehyde, a component of high organoleptic note present in natural vanilla aroma. Use of phospholipid-enriched medium led to high-density cultures of P. cinnabarinus, since dry mycelial biomass was increased three-fold as compared to glucose medium. In the presence of phospholipids, 155 mg l(-1) p-hydroxybenzaldehyde was produced as the major compound on culture day 13 with a molar yield of 26%. The degradation pathways of p-coumaric acid were investigated. Based on the different metabolites identified, an oxidative side-chain degradation pathway of p-coumaric acid conversion to p-hydroxybenzoic acid was suggested. This acid was further reduced to p-hydroxybenzaldehyde and p-hydroxybenzyl alcohol, or hydroxylated and reduced to protocatechyl derivatives. Additionally, a reductive pathway of p-coumaric acid with 3-(4-hydroxyphenyl)-propanol as the terminal product occurred.