植物异戊烯基转移酶研究进展

次生代谢产物的生物学作用被认为是高等植物生存和进化的关键.类异戊二烯(Isoprenoids)化合物作为植物中极为丰富的一类次生代谢物,在植物信号转导、适应气候、繁殖及防御等方面具有多种生理功能.此外,植物类异戊二烯化合物还广泛应用于制药、天然乳胶、香料及有机合成等工业领域,具有重要的经济价值.异戊烯基转移酶(Pren...     

植物中的异戊烯基转移酶

介绍了近年来植物中异戊烯基转移酶(又称异戊烯基二磷酸合酶,IPPS)的研究进展,着重讨论IPPS的链长决定机制,同时分析了有待解决的问题.     

茎瘤芥异戊烯基转移酶家族基因全基因组鉴定及表达分析北大核心CSCD

该研究以茎瘤芥栽培品种‘永安小叶’为实验材料,在全基因组水平对茎瘤芥基因组中异戊烯基转移酶(IPT)家族基因成员进行鉴定;通过荧光定量PCR检测各基因在不同组织、盐胁迫和根肿菌胁迫条件下的表达模式。结果显示:(1)在茎瘤芥基因组中共鉴定到27个IPT家族基因,分布在14条染色体上,它们在系统进化树中可聚类为7个分支。(2)大部分IPT家族基因主要在茎瘤芥的根和茎中表达,在叶片、花和种荚中表达量相对较低。BjuB006281在茎中的表达水平最高,BjuA027211、BjuB010173、BjuB010174和BjuA001839在根中的表达水平较高。(3)大部分的IPT基因表达受盐胁迫抑制,BjuB006281、BjuA036403、BjuB010173、BjuB026254在盐胁迫12~48 h显著下调表达;BjuB022918和BjuB007352则在盐胁迫24~48 h显著下调表达。(4)大部分茎瘤芥IPT基因在12 h受到根肿菌侵染的显著诱导,其中BjuB006281、BjuA014415、BjuB022918在侵染后12 h的表达水平为0 h对照的15倍以上。该研究鉴定出多个响应盐胁迫和根肿菌胁迫的IPT基因,为进一步研究他们的基因功能奠定了基础。     

补骨脂中异戊烯基黄酮类化合物及其药理作用研究进展

综述补骨脂(Psoralea corylifolia)中的异戊烯基黄酮类化合物及其药理作用的研究进展.     

异戊烯基化吲哚类生物碱的化学酶合成

异戊烯基化吲哚类生物碱广泛存在于麦角菌、青霉菌和曲霉菌中,具有一定的药理学活性,与未异戊烯基化的前体在生物活性方面具有明显的差异.曲霉菌中的某些异戊烯基化吲哚类生物碱具有抗癌活性,如烟曲霉毒素C（fumitremorgin C）、tryprostatin B,但其天然产量低且不易分离,利用化学酶合成法可很容易地将前体转化为异戊烯基化吲哚类生物碱.异戊烯基转移酶FtmPT1对二甲丙烯基二磷酸（dimethylallyl diphosphate,DMAPP）具有专一性,但可以接受不同的芳香族底物.早期研究发现,FtmPT1能接受含色氨酸的不同环二肽为底物,但以cyclo-L-Trp-L-Tyr和cyclo-L-Trp-L-Phe为底物时,酶的相对活性很低,其产物量少,无法用于合成产物.本实验通过优化酶反应条件来提高其产量.将已构建的含ftmPT1的质粒在大肠杆菌中诱导表达,经Ni-NTA亲和柱纯化后用于酶反应.实验结果表明,通过增加酶量（终浓度2.8 μmol/L）、延长培养时间（37 ℃,24 h）,以cyclo-L-Trp-L-Tyr和cyclo-L-Trp-L-Phe为底物的酶反应产率分别达到49.3%和21.3%,产物经¹H^-NMR、¹H-¹H-COSY和ESI-MS鉴定,其结果与预期吻合.据检索,这2个化合物均为新化合物,分别命名为cyclo-C2-1′-DMA-L-Trp-L-Tyr和cyclo-C2-1′-DMA-L-Trp-L-Phe.     

微生物异戊烯基转移酶研究进展

类异戊二烯(isoprenoids)是最具化学多样性的一种天然分子家族,参与微生物中类胡萝卜素、甾醇等次生代谢物的合成,这类物质在工业大规模生产中具有广阔的商业前景。异戊烯基转移酶是类异戊二烯合成途径中的关键酶,其活性及编码基因的转录水平参与调节次生代谢物产量,在类异戊二烯化合物生物合成途径中发挥重要作用。本文重点归纳了微生物中异戊烯基转移酶的发现与鉴定,分析其结构特点与链长决定机制,讨论异戊烯基转移酶家族之间的复杂进化,概述酶基因表达调控的应用以及生物合成研究现状,为深入研究异戊烯基转移酶作用机理及各领域中的应用提供思路。     

苦参异戊烯基黄酮类化合物的化学,活性及其生物合成研究进展

综述苦参(Sophora flavecens Aiton.)异戊烯基黄酮类化合物的化学,活性及其生物合成研究进展。     

巴西橡胶树顺式异戊烯基转移酶基因cDNA克隆及其序列特征分析

以巴西橡胶树(Hevea brasiliensis)胶乳的RNA为Tester;叶片RNA为Driver,利用抑制消减杂交法(suppressive subtractive hybridization,SSH)构建了一个胶乳特异表达基因差减文库.通过反式Northern点杂交(reverse Northern dot blots)筛选到一个与顺式异戊烯基转移酶基因(橡胶生物合成的关键酶基因)高度同源的阳性克隆R363.采用RACE方法获得该克隆的全长cDNA(GenBank登陆号:AY461414).序列分析表明,该基因长1156 bp,含有873 bp的阅读框,编码290个氨基酸,分子量约为32.9 kD,等电点为7.2,含有N-端跨膜螺旋区.同源性分析表明R363编码的蛋白质具有异戊烯基转移酶家族的特征,含有cis-异戊烯基链转移酶的5个高度保守区,推测R363可能是一种新的顺式-异戊烯基转移酶基因.Northern blot分析显示,R363在胶乳中高度表达,在叶中不表达.乙烯处理前后表达强度一致,表明该基因表达不为乙烯所诱导.     

无花果亚属植物异戊烯基类黄酮及其生物活性研究进展北大核心CSCD

无花果亚属隶属于桑科,既是重要的水果资源,也是优良的中药资源,广泛种植于热带、亚热带地区,因含有丰富的生物活性成分和保健功效,经济价值突出。无花果亚属植物中异戊烯基类黄酮含量丰富,结构多样,已报道有37种异黄酮、2种黄烷酮、7种黄酮和1种查尔酮。无花果异戊烯基类黄酮具有突出的抗氧化活性,能够缓解更年期症状,保护骨骼、预防炎症、预防癌症等。从化学结构和生物活性两方面对无花果亚属植物的异戊烯基黄酮类化合物的研究概况进行总结,以期为该属植物的开发和利用提供参考。     

泡桐丛枝植原体tRNA异戊烯基焦磷酸转移酶基因克隆、原核表达及功能分析

【目的】为了鉴定植原体tRNA异戊烯基焦磷酸转移酶基因(tRNA-ipt)的表达及蛋白功能,探索植原体致病机理。【方法】对泡桐丛枝、桑萎缩、长春花绿变及苦楝丛枝植原体tRNA-ipt基因完整序列进行PCR扩增和生物信息学分析。对泡桐丛枝植原体tRNA-ipt基因进行原核表达并制备抗体。利用Western blot和FITC间接免疫荧光显微镜检测其在植原体中的表达。使用分光光度计分析该基因对大肠杆菌生长的影响,用ELISA测定转化菌株细胞分裂素含量。【结果】首次发现泡桐丛枝、桑萎缩、长春花绿变及苦楝丛枝植原体中完整tRNA-ipt基因,大小为876 bp,编码291个氨基酸,且N端均含有ATP/GTP结合位点保守序列(GPTASGKT)。4种植原体tRNA-IPT之间的氨基酸序列相似率为99.1%-99.5%,与同组植原体同源性在95.4%-99.3%,与其他组植原体同源性低于70%。SDS-PAGE结果显示tRNA-IPT蛋白在大肠杆菌中得到表达。首次获得泡桐丛枝植原体tRNA-IPT抗体并检测到该蛋白在泡桐发病组织中的特异表达。经过对转化菌株生长曲线及玉米素含量的测定,发现该基因能促进大肠杆菌后期生长和玉米素核苷的积累。【结论】4种植原体tRNA-ipt基因编码相同特性的功能蛋白,泡桐丛枝植原体tRNA-IPT蛋白能够在植原体中表达,根据该基因对异源菌株生长速率和激素合成的影响推断该蛋白可能参与植原体的细胞分裂素合成,在致病过程中起到重要作用。     

额济纳绿洲胡杨（Populus euphratica）酚类物质含量和分布及其与土壤水分的关系

采用分光光度法测定了额济纳绿洲胡杨(Populus euphratica)的披针形叶、卵圆形叶、嫩枝、枝(D《5 mm)、枝(5～10 mm)、主干树皮、根(D《2 mm)、根(2～5 mm)和根(5～10 mm)9类器官中的总酚、黄酮和缩合单宁含量.结果表明,总酚含量较高的器官为皮(27.93 mg/s),叶、根、枝中总酚含量分别为17.64 mg/g(两类叶均值)、16.72mg/g(三类根均值)、12.19 mg/g(三类枝均值);黄酮含量较高的器官为皮(51.30 mg/g),叶、根、枝中黄酮含量分别为28.45 mg/g(两类叶均值)、39.99 mg/g(三类根均值)、23.67 mg/g(三类枝均值);根中缩合单宁含量较高,三类根均值为22.10 mg/g,皮、叶、枝中缩合单宁含量分别为8.41 mg/g、4.03 mg/g(两类叶均值)、4.47 mg/g(三类枝均值).披针形叶和卵圆形叶中酚类物质含量没有显著性差异(P》0.05);随着枝不断成熟,嫩枝、枝(D《5mm)、枝(5～10mm)中酚类物质逐渐减少;随着根直径减少,根中缩合单宁逐渐增加,细根(D《2mm)中的缩合单宁含量最高(25.95 mg/g).分析胡杨各器官中酚类物质含量与土壤水分的关系,结果表明卵圆形叶中酚类物质含量与土壤水分含量成显著负相关关系(P《0.05,总酚:r=-0.949;黄酮:r=-0.923;缩合单宁:r=-0.944).研究揭示了极端干旱地区胡杨各器官中酚类物质的变化规律,及其与环境因子的相互作用关系.     

The role of phenolic compounds in disease resistance in geranium

The present study was conducted in the hill station of G B Pant University of Agriculture and Technology, Ranichauri, Uttarakhand, which is known for its diversity in medicinal and aromatic plants. The plant geranium, also known as rose or lemon geranium is highly valued for its essential oil which is used in the cosmetic and preferring industries. The plant suffers due to stem and root rot both during summer and winter seasons. In the present study, geranium plants showed maximum stem rot incidence (60.55%) and plant mortality (17.20%) during the winter season, whereas in summer the crops showed maximum root rot and wilt complex incidence (38.33%) with plant mortality up to (12.22%). The average stem rot mortality was comparatively low (16–20%) in summer but increased to 18–26% in winter crop. Several phenolic acids such as as tannic, gallic, caffeic, ferulic and benzoic were detected by using high performance liquid chromatography (HPLC) in variable amounts in these plants. The disease intensity varied from 97.77 to 92.46% from season to season. The significance of the phenolic compounds is discussed in relation to disease prevalence.     

Comparative evaluation of an electrochemical bioreporter for detecting phenolic compounds

In this study, we constructed an Escherichia coli-based electrochemical bioreporter (EB) harboring pLZCapR, which encodes the CapR regulatory protein (for phenol degradation) along with β-galactosidase, and examined its ability to detect phenolic compounds as compared with previously reported optical bioreporters (OBs) controlled by CapR and detected using a luminometer (OB-lum) or spectrophotometer (OB-spec). The recombinant E. coli bioreporter cells were immobilized in polyvinyl alcohol (PVA); p-aminophenyl-β-D-galactopyranoside (PAPG) was used as the enzymatic substrate; and electrochemical measurements were taken. The peak current obtained on cyclic voltammetry (CV) was used to measure the redox response of PAPG degradation. Our results revealed that the EB system showed a detection range of 10 nM to 10 mM phenol with a good lower detection limit (30 nM phenol). Furthermore, the detection time was dramatically lower for the EB system (15–20 min) compared to the OBs (～6 hr). These responses were reliably repeatable with an acceptable standard deviation (±2.7%; n = 6), and the system showed good stability without loss of activity over 7 hr of operation or following 2 weeks of cold storage. Together, these results show that the EB system is faster and has a lower detection limit than the existing optical techniques.     

Antibacterial activity of wine phenolic compounds and oenological extracts against potential respiratory pathogens

Aims: To investigate the effect of seven wine phenolic compounds and six oenological phenolic extracts on the growth of pathogenic bacteria associated with respiratory diseases (Pseudomonas aeruginosa, Staphylococcus aureus, Moraxella catarrhalis, Enterococcus faecalis, Streptococcus sp Group F, Streptococcus agalactiae and Streptococcus pneumoniae). Methods and Results: Antimicrobial activity was determined using a microdilution method and quantified as IC₅₀. Mor. catarrhalis was the most susceptible specie to phenolic compounds and extracts. Gallic acid and ethyl gallate were the compounds that showed the greatest antimicrobial activity. Regarding phenolic extracts, GSE (grape seed extract) and GSE‐O (oligomeric‐rich fraction from GSE) were the ones that displayed the strongest antimicrobial effects. Conclusions: Results highlight the antimicrobial properties of wine phenolic compounds and oenological extracts against potential respiratory pathogens. The antimicrobial activity of wine phenolic compounds was influenced by the type of phenolic compounds. Gram‐negative bacteria were more susceptible than Gram‐positive bacteria to the action of phenolic compounds and extracts; however, the effect was species‐dependent. Significance and Impact of Study: The ability to inhibit the growth of respiratory pathogenic bacteria as shown by several wine phenolic compounds and oenological extracts warrants further investigations to explore the use of grape and wine preparations in oral hygiene.     

Biotransformation and bioconversion of phenolic compounds obtainment: an overview

Phenolic compounds have recently been recognized for their influence on human metabolism, acting in the prevention of some chronic diseases as well as proving to be important antioxidants in food. Nevertheless, the extraction and concentration processes are usually carried out by organic solvent extraction from natural sources and can generate some drawbacks like phenolic compound degradation, lengthy process times and low yields. As a solution, some eco-friendly technologies, including solid-state fermentation (SSF) or enzymatic-assisted reaction, have been proposed as alternative processes. This article reviews the extraction of phenolic compounds from agro-industrial co-products by solid-state fermentation, even as friendly enzyme-assisted extractions. It also discusses the characteristics of each bioprocess system and the variables that affect product formation, as well as the range of substrates, microorganisms and enzymes that can be useful for the production of bioactive phenolic compounds.     

The effect of quinoid and phenolic compounds on urease and dehydrogenase activity and nitrification in soil

Summary 1,4-Naphthoquinone; 2-methyl-1,4-napthoquinone; 2,3-dichlorohydroquinone; 4,6-di-tert.butyl-o-benzoquinone; 4,6-di-tert.butylpyrocatechol and 4-tert.butylpyrocatechol at concentrations of 10 and 20 ppm inhibit mineralization of urea N by reducing urease activity and/or nitrification in soils. Coating of urea with these chemicals was more effective than direct application to the soil. There was no adverse effect of any of the chemicals either on germination or on the growth of wheat plants at concentrations of 20 and 50 ppm added to soil.     

生物质催化转化制备呋喃基化学品和酚类化合物

生物质转化制备精细化学品是解决石油能源危机的重要途径之一。其中,纤维素及半纤维素转化合成呋喃基化学品与木质素转化制酚类化合物是主要的反应路线,特别是借助催化技术加速生物质转化更是当今化学领域的研究重点;依据催化反应体系的不同,对近年来用于生物质催化转化的反应媒介以及催化剂研究进展进行了综述,并对未来生物质催化转化研究方向的发展前景进行了展望。     

Scavenging effects of phenolic compounds on reactive oxygen species

Phenolic compounds are widely present in plants and they have received considerable attention due to their antioxidant property. In this article we report the results of a study of the reactivity of 10 selected phenolics (sesamol, three phenolic acids, three flavonols, one flavone, and two flavanones) with superoxide anion radical (O(2) (*)), hydroxyl radical (HO(*)) and singlet oxygen ((1)O(2)). The following generators of reactive oxygen species were used: 18-crown-6/KO(2)/dimethylsulfoxide (DMSO) or hypoxanthine/xanthine oxidase as sources of O(2) (*), the Fenton reaction carried out in a sodium trifluoroacetate (pH 6.15) for HO(*), and a mixture of alkaline aqueous H(2)O(2) and cobalt ions for (1)O(2). We have employed chemiluminescence, electron spin resonance spin trapping, and spectrophotometry techniques to examine an antioxidative property. All tested compounds acted as scavengers of various reactive oxygen species. The reactivity indexes (beta) for the reaction of the phenolic compounds with HO(*) were calculated.     

胁迫条件对一土生青霉菌总酚积累及其清除自由基能力的影响

旨在阐明胁迫条件对一土生青霉菌总酚积累及其抗氧化活性的影响。采用固体培养基培养青霉菌,以紫外线辐射、添加H2O2水溶液和降低培养基营养物质含量作为胁迫手段,检测受到胁迫后,菌体总酚的积累及酚类清除自由基的能力。菌丝体总酚含量以Folin-Ciocalteu法测定,自由基清除率以分光光度法测定。结果表明,在胁迫条件下,各实验组菌丝体的总酚含量较对照组均有显著提高,添加H2O2组的总酚含量最高达63.86mg/g,紫外线辐射组的总酚含量最高达58.4mg/g,营养胁迫组的总酚含量最高达43.19mg/g。各实验组酚类提取物对羟自由基的清除率最高,其中添加1mmol/LH2O2组为35.28%,紫外线辐射40s组为69.97%,75%营养胁迫组为50.83%。因此,胁迫条件可增加该青霉合成酚类化合物及提高其抵抗胁迫的能力。     

紫锥菊提取物及酚酸化合物体外抗血小板聚集活性研究

为探究紫锥菊提取物及酚酸化合物体外抗血小板聚集活性,体外抗血小板聚集实验采用Born比浊法,以聚集抑制率和半数抑制浓度为指标评价。同时采用分子对接方法,选择凝血因子V(F5)、凝血因子VIII(F8)及凝血因子XI(F11)与酚酸类化合物进行虚拟对接,研究其抗血小板聚集的分子作用靶点。结果表明化合物S-1～S-10及其提取物对体外ADP诱导的血小板聚集有抑制作用,抑制率呈浓度依赖性,S-6与靶点的结合位点更多,选择性更强。紫锥菊中酚酸类化合物及其提取物在体外均显现出抗ADP诱导的血小板聚集活性,为紫锥菊体内研究提供依据。