长春花次生代谢转录调控的分子机制

本文就长春花体内生物碱生物合成途径中受转录因子调控、外界因素对其诱导和调控以及作用机制的研究进展作介绍。     

植物萜类次生代谢及其调控

植物次生代谢在植物生长发育、环境适应、抵御病虫害等方面发挥着重要作用,这些天然产物组成地球上最丰富的有机化合物的宝库．萜类是植物代谢产物中种类最多的一类,具有重要的生理和生态功能,一些成分还有应用价值．近十几年来,人们在萜类化合物的分离、鉴定、应用、生物合成、相关基因与基因族、酶蛋白结构和功能、代谢调控以及代谢工程等各方面取得了重大进展．本文概述了植物萜类化合物代谢及其调控领域的研究进展与发展趋势．     

长春花细胞培养与吲哚生物碱的生产

本文简要介绍长春花细胞培养与吲哚生物碱生产的研究概况,包括培养方法、培养系统、分析方法、培养条件的影响、高产细胞系的筛选和保存、生物碱的生物合成等方面。以求对我国的细胞培养工业化生产药用成分的研究有所借鉴。     

长春花萜类吲哚生物碱的生物合成途径

药用植物长春花含有130余种萜类吲哚生物碱,该文对近年来国内外有关长春花生物碱合成的上游和下游阶段及其相关研究进行详细的归纳总结。长春花上游合成途径中在相应的酶促作用下由吲哚途径产生的色胺和由类萜途径产生的裂环马钱子苷在异胡豆苷合成酶的催化作用下形成了所有长春花TIAs的共同前体物质3α-异胡豆苷,3α-异胡豆苷再由下游途径的各种酶促作用下生成种类各异的长春花TIAs。通过对长春花TIAs合成途径的阐述,为萜类吲哚生物碱合成及其代谢调控的相关研究提供参考。     

药用植物长春花WRKY转录因子的鉴定及表达谱分析

WRKY是调控植物生长发育和逆境胁迫反应等生命活动的一个转录因子大家族.然而,有关药用植物长春花CrWRKY转录因子的种类和功能却知之甚少.从26 009个长春花蛋白中鉴定出47个CrWRKY转录因子.依据WRKY结构域和系统进化,将CrWRKY分为G1、G2和G3三大类群.表达谱数据分析表明,长春花CrWRKY基因的表达具有器官特异性.47个CrWRKY基因的表达谱可分为3种表达模式:第1类型主要在花、甲基茉莉酸甲酯(MeJA)或酵母提取物(YE)处理的原生质体中高表达;第2类型主要在茎和毛状根中高表达;第3类型在根、茎、叶、幼苗和MeJA处理的毛状根中高表达.进一步用实时定量PCR检测了16个代表性CrWRKY基因在不同器官、MeJA处理原生质体和毛状根中的表达模式,检测结果与上述数字基因表达谱数据基本一致.约1/3以上CrWRKY基因的表达受MeJA和YE的调控,暗示它们可能参与萜类吲哚生物碱的合成和逆境胁迫反应.为进一步解析长春花WRKY转录因子的功能和萜类吲哚生物碱合成调控的网络奠定了基础.     

长春花生物碱生物合成途径和相关酶及其基因调控的研究进展

从长春质碱、文多灵、蛇根碱和阿吗碱及长春碱、长春新碱等的生物合成途径和催化酶及其基因的表达调控等方面概述了长春花生物碱的生物合成途径和代谢调控的研究进展,并对已经被分离和纯化或克隆的催化酶及其基因作了简要介绍。     

参与植物次生代谢调控的转录因子及其在植物次生代谢遗传改良中的应用

转录因子与结构基因的结合,激活合成基因的表达是次生代谢物合成途径启动前的重要分子事件,对植物次生代谢起着十分重要的调节作用。转录因了可激活次牛代谢物合成途径中多个基因协同表达,从而有效启动次生代谢途径。因此,转录因子为揭示植物次生代谢调控机制提供重要工具,转录因子的基因工程可为植物次生代谢的遗传改良提供有效的手段。     

植物MEP途径的代谢调控机制

萜类代谢途径是植物中最重要的次生代谢途径之一,对其有效的调控决定着植物的生长发育、抗性及品质等各个方面。植物中类萜合成的前体物在质体中是由2-C-甲基-D-赤藓糖醇-4-磷酸(2-C-Methyl-D-Erythritol-4-Phosphate,MEP)途径合成的,MEP途径中的许多基因除了受到多基因编码和转录水平的调节外,还受到转录后调节机制的调节,而转录后调节是一种新发现的调节方式,其机制还不是很清楚。该文重点对近年来国内外有关植物MEP途径的多种调节方式,尤其是转录后调节的调节机制及其可能参与的信号分子方面的研究进展进行综述,为植物的MEP途径的代谢调控提供参考。     

bZIP转录因子调控植物次生代谢产物生物合成的研究进展

植物次生代谢产物是通过次生代谢产生的一类小分子有机化合物,是植物适应环境的表现,次生代谢产物也是重要药物和化工原料的来源。bZIP转录因子是普遍存在于真核生物中的一类多基因家族,可有效调控植物次生代谢产物的生物合成。本文概述了植物bZIP转录因子的结构和类型,重点阐述了bZIP转录因子调控萜类、黄酮类和生物碱等植物次生代谢产物生物合成的研究进展,并对研究前景进行了展望。深入探讨bZIP转录因子的调控机制,有助于利用基因工程技术优化植物次生代谢途径,提高次生代谢产物的含量,在新药创制、工农业生产等方面具有广泛的应用前景。     

Terpenoid indole alkaloid production by Catharanthus roseus hairy roots induced by Agrobacterium tumefaciens harboring rol ABC genes

We have established Catharanthus roseus hairy root cultures transgenic for the rol ABC genes from T(L)-DNA of the agropine-type Agrobacterium rhizogenes strain A4. The rol ABC hairy root lines exhibit a wild-type hairy root syndrome in terms of growth and morphology on solid medium. However, they differ from wild-type hairy root lines in that they more frequently have excellent adaptability to liquid medium and do not appear to form calli during cultivation. Moreover, they do not produce detectable levels of mannopine and agropine which, in contrast, are often synthesized abundantly in wild-type hairy root lines. The absence of these opines does not appear to cause the rol ABC lines to have higher levels of terpenoid indole alkaloids than wild-type hairy root lines. Unlike wild-type lines, rol ABC lines produce very similar levels of total alkaloids despite wide variations in individual alkaloid contents. This work demonstrates that the three genes rol ABC are sufficient to induce high-quality hairy roots in Catharanthus roseus.     

Expression of a feedback-resistant anthranilate synthase in Catharanthus roseus hairy roots provides evidence for tight regulation of terpenoid indole alkaloid levels

Different plant species produce a variety of terpenoid indole alkaloids, which are of interest as plant defensive secondary metabolites and as valuable pharmaceuticals. Although significant progress has been made, the mechanisms regulating the levels of this important class of compounds require continued elucidation. Previous precursor feeding studies have indicated that alkaloid accumulation can be improved during the exponential growth phase of hairy root cultures through enhanced tryptophan availability. To test this relationship, transgenic hairy root cultures of Catharanthus roseus were established with a glucocorticoid-inducible promoter controlling the expression of an Arabidopsis feedback-resistant anthranilate synthase alpha subunit. Enzyme assays demonstrated that the Arabidopsis alpha subunit is compatible with the native beta subunit and that anthranilate synthase activity is more resistant to tryptophan inhibition in induced than in uninduced extracts. The metabolic effects of expressing the feedback-resistant anthranilate synthase alpha subunit were also dramatic. Over a 6-day induction period during the late exponential growth phase, tryptophan and tryptamine specific yields increased from almost undetectable levels to 2.5 mg/g dry weight and from 25 microg/g to 267 microg/g dry weight, respectively. The greater than 300-fold increase in tryptophan levels observed in these studies under certain induction conditions compares favorably with the fold increases obtained in previous constitutive expression studies. Despite the large increases in tryptophan and tryptamine, the levels of most terpenoid indole alkaloids were not significantly altered, with the exception of lochnericine, which increased 81% after a 3-day induction period. These results suggest that terpenoid indole alkaloid levels are tightly controlled.