合成8二甲基异戊烯基柚皮素的人工酿酒酵母菌株构建

8二甲基异戊烯基柚皮素(8DN)作为生产黄酮类药物淫羊藿苷的重要前体,在医药合成领域具有重大应用潜力。由于其合成路径及相关基因的复杂性,目前主要通过饲喂8DN的直接前体(柚皮素、异黄腐酚等)的方式合成8DN,而在生物体内全合成8DN的研究工作还未见报道。为了实现8DN在酿酒酵母体内的生物全合成,通过组合筛选8DN前体物柚皮素合成所需的多种外源基因(TAL、4CL、CHS、CHI),获得30株柚皮素生产菌,发现不同来源的基因组合使柚皮素产量的具有明显差异(0.37~22.33mg/L)。并且利用Delta位点将较优的基因组合整合至酵母基因组,实现了稳定的柚皮素高产菌株(Sy BE_Sc02050031)构建。在此基础上进一步导入带有苦参来源的异戊烯基转移酶基因(N8DT)多拷贝质粒,实现8DN合成的完整反应过程,8DN的摇瓶发酵产量达到36.7μg/L。另外,通过关键限速酶N8DT的序列优化策略,发现截断定位信号肽序列的N8DT明显提高了从柚皮素到8DN这一关键反应的催化效果,8DN的产量提高到52.6μg/L(144.2%)。首次在酿酒酵母中成功构建高产8DN的生物全合成路径,为在微生物体内合成其他黄酮类天然产物提供了参考,具有重要的指导意义。     

银杏查尔酮合成酶基因表达的时间进程

查尔酮合成酶是银杏叶黄酮合成途径中的第一个关键酶。利用RACE技术克隆到银杏的一个查尔酮合成酶基因,命名为GbCHS2,其cDNA全长1608bp,包括长1173bp的读码框,编码391个氨基酸。GbCHS2蛋白与已从银杏克隆到的GbCHS1蛋白具有很高的同源性,并包含其所有相同的活性位点。用半定量RT-PCR方法研究了银杏叶生长过程中chs基因的转录水平的变化,并对CHS活性变化和黄酮含量的变化曲线进行了线性回归分析。结果显示,在整个银杏叶生长过程中,CHS活性与黄酮含量呈极显著线性相关,表明CHS是银杏叶黄酮合成途径中的一个关键限速酶;chs基因的转录水平的变化与黄酮的积累是同步的,chs基因的这种表达模式表明chs基因的转录水平可能决定了银杏叶黄酮的积累。     

不同施氮水平对烟草叶片黄酮类化合物含量及其代谢途径的调控

本研究以生长在3个不同施氮水平(60 kg/hm~2,90 kg/hm~2和120 kg/hm~2)下的"云烟87"为材料,运用超高效液相色谱法、分光光度法和荧光定量PCR法,分别研究了不同施氮水平对烟叶生长发育过程中黄酮类化合物芸香苷、山奈酚-3-O-芸香苷和总黄酮含量、代谢相关酶活性及相关基因表达的影响。结果表明:随着生长发育的进行,黄酮类化合物代谢相关基因PAL、C4H、4CL、CHS、CHI、F3H、F3'H、FLS、A3RT的基因表达总体上呈逐渐降低的趋势,从而调控了山奈酚-3-O-芸香苷和总黄酮含量呈逐渐降低的趋势,芸香苷含量呈先略有升高后降低的趋势。不同施氮水平下比较,处理前期(50 d和83 d),较低施氮水平(60 kg/hm~2)上调了烟草叶片黄酮类化合物代谢相关基因PAL、C4H、4CL、CHS、CHI、F3H、F3'H、FLS、A3RT和ANS的基因表达,提高了黄酮类化合物代谢关键酶PAL、CHI的活性,促进了黄酮类化合物芸香苷、山奈酚-3-O-芸香苷和总黄酮含量的积累(p0.05);处理后期(106 d),较高施氮水平(120 kg/hm~2)上调了烟草叶片黄酮类化合物代谢相关基因PAL、C4H、4CL、CHS、CHI、F3H、F3'H、A3RT和ANS基因的表达,提高了黄酮类化合物代谢关键酶PAL、CHI的活性,促进了黄酮类化合物芸香苷、山奈酚-3-O-芸香苷和总黄酮含量的积累(p0.05)。     

石榴果色合成相关基因CHS和CHI的表达特性分析

花色苷是类黄酮家族中重要的一类次生代谢产物,对果实呈色起重要作用。CHS (查尔酮合成酶)和CHI (查尔酮异构酶)为花色苷合成提供了前体物质,是花色苷合成所不可或缺的。利用RT-PCR和RACE方法,本研究从石榴果皮中克隆了与花色苷合成相关的CHS基因和CHI基因的cDNA全长,同时采用qRT-PCR研究了这两个基因在三个不同色泽石榴品种‘红宝石’、‘水晶甜’、‘墨石榴’发育期内的表达模式,并分析了果皮花色苷含量变化与基因转录水平的关系。结果表明,石榴中CHS和CHI基因cDNA全长分别为1 197 bp和693 bp,分别编码398和230个氨基酸,命名为PgCHS和PgCHI,在GenBank中的登录号分别为KF841615和KF841616。在氨基酸水平上,Pg CHS与荔枝、葡萄、山竹等果树的同源性达到90%以上。Pg CHI与果树中龙眼、梨、美洲葡萄、桑树等同源性达到70%以上。qRT-PCR结果显示,CHS和CHI基因的表达模式随色泽发育期和品种不同而有差异。在‘红宝石’石榴中,该两个基因都有前期和后期两个表达高峰期;而‘水晶甜’石榴中这两个基因的表达高峰期均出现在中后期;‘墨石榴’发育初期时CHS和CHI的表达量最高,以后的表达量都较低。同一品种内,CHS和CHI的表达具有协同性,两者的协同性表达有利于花色苷及其他类黄酮相关产物的合成。3个品种中CHS和CHI基因的表达与花色苷的积累并不一致。     

大豆籽粒发育过程中异黄酮合成相关酶基因的表达模式与异黄酮积累的相关分析

利用高效液相色谱法和实时定量PCR方法,分别测定了2个异黄酮含量显著差异的大豆品种鲁黑豆2号(LHD2)和南汇早黑豆(NHZ)在子粒发育过程中的异黄酮含量变化以及异黄酮合成相关酶基因的表达模式变化,试图分析异黄酮积累与各基因表达量变化的相关关系。结果表明在大豆子粒发育过程中,异黄酮含量逐渐升高,而不同异黄酮合成相关酶基因的表达趋势不同,CHS7、CHS8、CHR、CHI1A和IFS2的表达趋势与异黄酮积累模式基本一致,而IFS1和CHI1B1的表达趋势与异黄酮积累模式相反。IFR的表达模式在2个大豆品种中存在相反的趋势,在LHD2中与异黄酮组分积累趋势相反,而在NHZ中与异黄酮组分积累趋势相同。结果还表明,同一基因家族中不同基因在子粒发育过程中的表达量也存在差异。查尔酮合酶基因家族中CHS7和CHS8以及查尔酮异构酶基因家族的CHI1A的表达水平相对其他成员较高,异黄酮合酶基因家族中IFS2的表达量显著高于IFS1的表达量,预示这些基因家族在大豆子粒异黄酮积累过程中存在功能分化。此外,各基因表达模式与异黄酮积累的相关分析结果表明,不同基因表达模式与异黄酮积累的相关性在2个品种中也不尽相同。LHD2中CHS7、CHS8和IFS2在子粒发育过程中的表达量变化与不同异黄酮组分呈显著正相关,CHI1B1基因的表达量变化与不同异黄酮组分呈显著负相关。而在NHZ中,IFR在子粒发育过程中的表达量变化与多个异黄酮组分呈显著正相关。这预示了不同大豆品种异黄酮含量差异的潜在遗传基础。各异黄酮合成相关酶基因表达量变化的相关分析表明,在2个品种中,苯丙氨酸水解酶PAL1与4CL,4CL与CHS2以及CHS1与IFS2基因的表达量均呈现显著正相关。表明这些基因可能通过协同作用共同调控异黄酮的合成与积累。这些结果为今后利用基因工程提高大豆异黄酮含量奠定了基础。     

葡萄CHS和STS基因家族生物信息学鉴定和表达分析

查尔酮合成酶(CHS,chalcone synthase)是植物体类黄酮类化合物合成的第1个关键酶和限速酶,它能够催化丙二酰-Co A和对香豆酸-Co A合成柚皮素查尔酮。二苯乙烯合成酶(STS,stilbene synthase)是芪类化合物合成路径的关键酶,与查尔酮合成酶有共同的作用底物,二者具有很高的相似度。为更好地了解葡萄中CHS和STS基因的种类和数量,本研究采用生物信息学方法检索获得葡萄(Vitis vinifera L.)基因组数据库中的CHS和STS基因,通过分析其染色体定位、系统进化和保守基序,发现葡萄基因组可能含有33个STS基因,9个CHS基因,这些基因集中分布在6条葡萄染色体上,部分家族基因在染色体上形成基因簇。葡萄CHS和STS基因家族蛋白长度、基因结构和蛋白基序非常保守,具有很近的进化关系。葡萄芯片数据结果表明,葡萄CHS和STS基因在葡萄果实不同发育时期的果皮和果肉中均有表达,尤其葡萄CHS GroupsⅢ亚家族基因在葡萄果皮中大量表达。葡萄STS基因家族在果实中的表达量较低,部分探针在葡萄果实成熟期的果皮中表达量急剧增加。本研究结果可为葡萄CHS和STS基因在果实发育过程中的功能研究提供参考。     

植物查尔酮异构酶研究进展

黄酮类化合物属于多酚类次生代谢物,具有广泛的药用价值。查尔酮异构酶（CHI）是黄酮类代谢途径中的一个关键酶,催化分子内环化反应,使双环的查尔酮转化为有生物学活性的三环（2S）-黄烷酮。植物体内的CHI活性与类黄酮物质的合成有着密切联系,CHI转基因研究对于提高植物类黄酮含量有重要意义。简要概述了查尔酮异构酶的结构特点、催化反应机理以及CHI转基因的研究进展。     

红松查尔酮合成酶基因CHS密码子偏好性分析

查尔酮合成酶(Chalcone synthase,CHS)广泛存在于植物体内,是花色素形成过程中一种重要的酶,可以进一步催化生成黄酮类化合物。本研究采用Codon W和EMBOSS在线软件对红松查尔酮合成酶基因CHS的密码子使用偏好性进行分析,并与北美乔松等其他24种植物的CHS基因以及模式植物基因组进行比较,对认识红松CHS基因的密码子使用偏好性,为选择适宜的表达系统奠定了一定的基础。研究结果表明:红松CHS基因编码区的有效密码子数(ENC)和GC含量分别为48.92和0.548,C+G含量高于A+T含量,密码子偏好以A/T结尾;多数植物CHS基因的G+C含量高于A+T含量,且密码子更偏好C/G结尾;聚类分析表明,红松与马尾松和赤松的密码子使用偏好性的相似性较高;密码子使用频率研究发现,红松CHS遗传转化与异源表达较优的受体可能是大肠杆菌和拟南芥。     

定点突变提高虎杖聚酮合酶的苯亚甲基丙酮合酶活性北大核心CSCD

虎杖(Polygonum cuspidatum)聚酮合酶(polyketide synthase 1,PcPKS1)同时具有查尔酮合酶(chalcone synthase,CHS)及苯亚甲基丙酮合酶(benzylidene acetone synthase,BAS)催化活性,能够催化生成聚酮类化合物柚皮素查尔酮和苯亚甲基丙酮,进而催化合成黄酮类或覆盆子酮等具有多种生物学活性的化合物。本研究通过分析虎杖PcPKS1与掌叶大黄(Rheum palmatum)BAS、拟南芥(Arabidopsis thaliana)CHS等家族成员的序列以及酶催化位点的构象,确定可能影响酶功能的3个氨基酸位点:Thr133、Ser134、Ser339。采用定点突变对PcPKS1进行分子修饰,成功获得2个突变体并进行相关体外酶促反应,高效液相色谱(high performance liquid chromatography,HPLC)产物分析结果表明,在pH 7.0和pH 9.0的体外酶促条件下,突变体T133LS134A和S339V维持BAS和CHS双功能活性,且BAS活性显著高于原PcPKS1。本研究为利用PcPKS1进行基因工程调节黄酮类和覆盆子酮化合物的生物合成提供理论依据。     

水蕨(Ceratopteris thalictroides)查尔酮合成酶基因的克隆和表达（英文）

查尔酮合酶(chalcone synthase,CHS)是植物类黄酮化合物合成的关键酶,有关蕨类植物CHS基因的序列及功能信息尚不完善。本研究采用快速扩增c DNA末端(RACE)技术克隆获得了模式蕨类植物——水蕨(Ceratopteris thalictroides)Ct CHS基因(Gen Bank登录号:JX027616.1),其c DNA序列全长为1616 bp,具有3个外显子和2个内含子,开放阅读框(ORF)为1215 bp,编码404个氨基酸。进化树分析表明,Ct CHS与问荆(Equisetum arvense)、松叶蕨(Psilotum nudum)和3种薄囊蕨的查尔酮合成酶基因聚为一枝,说明这些蕨类植物亲缘关系较近且为单系起源。通过构建原核表达体系成功获得Ct CHS蛋白的多克隆抗体并用于免疫印迹分析,结果表明Ct CHS基因的表达明显受紫外光(UV)诱导。Ct CHS基因的克隆与表达分析为进一步研究水蕨类黄酮化合物的合成及其调控机制提供了依据。     

Optimization of a heterologous pathway for the production of flavonoids from glucose

The development of efficient microbial processes for the production of flavonoids has been a metabolic engineering goal for the past several years, primarily due to the purported health-promoting effects of these compounds. Although significant strides have been made recently in improving strain titers and yields, current fermentation strategies suffer from two major drawbacks-(1) the requirement for expensive phenylpropanoic precursors supplemented into the media and (2) the need for two separate media formulations for biomass/protein generation and flavonoid production. In this study, we detail the construction of a series of strains capable of bypassing both of these problems. A four-step heterologous pathway consisting of the enzymes tyrosine ammonia lyase (TAL), 4-coumarate:CoA ligase (4CL), chalcone synthase (CHS), and chalcone isomerase (CHI) was assembled within two engineered l-tyrosine Escherichia coli overproducers in order to enable the production of the main flavonoid precursor naringenin directly from glucose. During the course of this investigation, we discovered that extensive optimization of both enzyme sources and relative gene expression levels was required to achieve high quantities of both p-coumaric acid and naringenin accumulation. Once this metabolic balance was achieved, however, such strains were found to be capable of producing 29 mg/l naringenin from glucose and up to 84 mg/l naringenin with the addition of the fatty acid enzyme inhibitor, cerulenin. These results were obtained through cultivation of E. coli in a single minimal medium formulation without additional precursor supplementation, thus paving the way for the development of a simple and economical process for the microbial production of flavonoids directly from glucose.     

Functional expression of a P450 flavonoid hydroxylase for the biosynthesis of plant-specific hydroxylated flavonols in Escherichia coli

Flavonols are plant polyphenolic compounds that belong to the class of molecules collectively known as flavonoids. Because of their demonstrated health benefits towards a wide array of human pathological conditions, a great interest has emerged for their biosynthesis from well-characterized microbial hosts. We present the functional expression in Escherichia coli of a plant P450 flavonoid 3', 5'-hydroxylase (F3'5'H) as a fusion protein with a P450 reductase. This expression allowed metabolic engineering of E. coli to produce the flavonol kaempferol and the 3', 4' B-ring hydroxylated flavonol quercetin from the p-coumaric acid precursor by simultaneously co-expressing the fusion protein with 4-coumaroyl:CoA-ligase (4CL), chalcone synthase (CHS), chalcone isomerase (CHI), flavanone 3beta-hydroxylase (FHT) and flavonol synthase (FLS). Biosynthesis of the B-ring tri-hydroxylated flavonol myricetin from the engineered strains was accomplished when flavanones rather than phenylpropanoid acids were used as precursor molecules. Cultivation of the recombinant strains in rich medium increased the synthesis of all flavonoids with the exception of myricetin. The present work opens the possibility of the future production of several other hydroxylated flavonoid molecules in E. coli.     

Efficient Synthesis of Eriodictyol from l-Tyrosine in Escherichia coli

The health benefits of flavonoids for humans are increasingly attracting attention. Because the extraction of high-purity flavonoids from plants presents a major obstacle, interest has emerged in biosynthesizing them using microbial hosts. Eriodictyol is a flavonoid with anti-inflammatory and antioxidant activities. Its efficient synthesis has been hampered by two factors: the poor expression of cytochrome P450 and the low intracellular malonyl coenzyme A (malonyl-CoA) concentration in Escherichia coli. To address these issues, a truncated plant P450 flavonoid, flavonoid 3′-hydroxylase (tF3′H), was functionally expressed as a fusion protein with a truncated P450 reductase (tCPR) in E. coli. This allowed the engineered E. coli to produce eriodictyol from l-tyrosine by simultaneously coexpressing the fusion protein with tyrosine ammonia lyase (TAL), 4-coumarate-CoA ligase (4CL), chalcone synthase (CHS), and chalcone isomerase (CHI). In addition, metabolic engineering was employed to enhance the availability of malonyl-CoA so as to achieve a new metabolic balance and rebalance the relative expression of genes to enhance eriodictyol accumulation. This approach made the production of eriodictyol 203% higher than that in the control strain. By using these strategies, the production of eriodictyol from l-tyrosine reached 107 mg/liter. The present work offers an approach to the efficient synthesis of other hydroxylated flavonoids from l-tyrosine or even glucose in E. coli.     

Metabolic engineering of the phenylpropanoid pathway in Saccharomyces cerevisiae

Flavonoids are valuable natural products derived from the phenylpropanoid pathway. The objective of this study was to create a host for the biosynthesis of naringenin, the central precursor of many flavonoids. This was accomplished by introducing the phenylpropanoid pathway with the genes for phenylalanine ammonia lyase (PAL) from Rhodosporidium toruloides, 4-coumarate:coenzyme A (CoA) ligase (4CL) from Arabidopsis thaliana, and chalcone synthase (CHS) from Hypericum androsaemum into two Saccharomyces cerevisiae strains, namely, AH22 and a pad1 knockout mutant. Each gene was cloned and inserted into an expression vector under the control of a separate individual GAL10 promoter. Besides its PAL activity, the recombinant PAL enzyme showed tyrosine ammonia lyase activity, which enabled the biosynthesis of naringenin without introducing cinnamate 4-hydroxylase (C4H). 4CL catalyzed the conversion of both trans-cinnamic acid and p-coumaric acid to their corresponding CoA products, which were further converted to pinocembrin chalcone and naringenin chalcone by CHS. These chalcones were cyclized to pinocembrin and naringenin. The yeast AH22 strain coexpressing PAL, 4CL, and CHS produced approximately 7 mg liter(-1) of naringenin and 0.8 mg liter(-1) of pinocembrin. Several by-products, such as 2',4',6'-trihydroxydihydrochalcone and phloretin, were also identified. Precursor feeding studies indicated that metabolic flux to the engineered flavonoid pathway was limited by the flux to the precursor l-tyrosine.     

Modular Optimization of Heterologous Pathways for De Novo Synthesis of (2S)-Naringenin in Escherichia coli

Due to increasing concerns about food safety and environmental issues, bio-based production of flavonoids from safe, inexpensive, and renewable substrates is increasingly attracting attention. Here, the complete biosynthetic pathway, consisting of 3-deoxy-D-arabinoheptulosonate 7-phosphate synthase (DAHPS), chorismate mutase/prephenate dehydrogenase (CM/PDH), tyrosine ammonia lyase (TAL), 4-coumarate:CoA ligase (4CL), chalcone synthase (CHS), chalcone isomerase (CHI), malonate synthetase, and malonate carrier protein, was constructed using pre-made modules to overproduce (2S)-naringenin from D-glucose. Modular pathway engineering strategies were applied to the production of the flavonoid precursor (2S)-naringenin from L-tyrosine to investigate the metabolic space for efficient conversion. Modular expression was combinatorially tuned by modifying plasmid gene copy numbers and promoter strengths to identify an optimally balanced pathway. Furthermore, a new modular pathway from D-glucose to L-tyrosine was assembled and re-optimized with the identified optimal modules to enable de novo synthesis of (2S)-naringenin. Once this metabolic balance was achieved, the optimum strain was capable of producing 100.64 mg/L (2S)-naringenin directly from D-glucose, which is the highest production titer from D-glucose in Escherichia coli. The fermentation system described here paves the way for the development of an economical process for microbial production of flavonoids.     

Localization of flavonoid enzymes in Arabidopsis roots

Immunofluorescence and immuno-electron microscopy have been used to test the hypothesis that flavonoid metabolism is organized as a membrane-associated enzyme complex. The cellular and subcellular locations of chalcone synthase (CHS) and chalcone isomerase (CHI), the first two enzymes of this pathway, were examined in Arabidopsis roots. High levels of both enzymes were found in the epidermal and cortex cells of the elongation zone and the root tip, consistent with the accumulation of flavonoid endproducts at these sites. Co-localization of CHS and CHI was observed at the endoplasmic reticulum and tonoplast in these cells, and also in electron-dense regions that are, as yet, unidentified. In addition, a striking asymmetric distribution was observed for these enzymes in cortex cells of the elongation zone, which may provide clues about the physiological function of flavonoids in roots. The accumulation of CHS and CHI was also examined in tt7(88), a mutant in the gene for flavonoid 3'-hydroxylase (F3'H), which has been postulated to serve as a membrane anchor for the flavonoid enzyme complex. CHS and CHI accumulated to lower levels in cortex cells and higher levels in epidermal cells in the roots of this mutant as compared with wild-type plants. Moreover, the electron-dense regions containing these two enzymes were not observed. However, localization of CHS and CHI to the ER and tonoplast did not appear to be affected, suggesting that other proteins may function in recruiting the "soluble" flavonoid enzymes to membranes. Staining of flavonoid endproducts with DPBA was consistent with expression of CHS and CHI in these seedlings.     

Overexpression of the Saussurea medusa chalcone isomerase gene in S. involucrata hairy root cultures enhances their biosynthesis of apigenin

Saussurea involucrata is a medicinal plant well known for its flavonoids, including apigenin, which has been shown to significantly inhibit tumorigenesis. Since naturally occurring apigenin is in very low abundance, we took a transgenic approach to increase apigenin production by engineering the flavonoid pathway. A construct was made to contain the complete cDNA sequence of the Saussurea medusa chalcone isomerase (CHI) gene under the control of the cauliflower mosaic virus (CaMV) 35S promoter. Using an Agrobacterium rhizogenes-mediated transformation system, the chi overexpression cassette was incorporated into the genome of S. involucrata, and transgenic hairy root lines were established. CHI converts naringenin chalcone into naringenin that is the precursor of apigenin. We observed that transgenic hairy root lines grew faster and produced higher levels of apigenin and total flavonoids than wild-type hairy roots did. Over a culture period of 5 weeks, the best-performing line (C46) accumulated 32.1 mgL(-1) apigenin and 647.8 mgL(-1) total flavonoids, or 12 and 4 times, respectively, higher than wild-type hairy roots did. The enhanced productivity corresponded to elevated CHI activity, confirming the key role that CHI played for total flavonoids and apigenin synthesis and the efficiency of the current metabolic engineering strategy.     

Expression of chalcone synthase and chalcone isomerase proteins in Arabidopsis seedlings

Antibodies have been developed against the first two enzymes of flavonoid biosynthesis in Arabidopsis thaliana. Chalcone synthase (CHS) and chalcone isomerase (CHI) were overexpressed and purified from Escherichia coli as fusion proteins with glutathione S-transferase from Schistosoma japonicum. The recombinant proteins were then used to immunize chickens and the resulting IgY fraction was purified from egg yolks. Immunoblots of crude protein extracts from Arabidopsis seedlings carrying wild-type and null alleles for CHS and CHI showed that the resulting antibody preparations provide useful tools for characterizing expression of the flavonoid pathway at the protein level. An initial analysis of expression patterns in seedlings shows that CHS and CHI proteins are present at high levels during a brief period of early seedling germination that just precedes the transient accumulation of flavonoid end-products.     

Cross-talk interactions of sucrose and Fusarium oxysporum in the phenylpropanoid pathway and the accumulation and localization of flavonoids in embryo axes of yellow lupine

This study investigated the effects of cross-talk interactions of sucrose and infection caused by a pathogenic fungus Fusarium oxysporum f.sp. lupini on the regulation of the phenylpropanoid pathway, i.e. the level of expression of genes encoding enzymes participating in flavonoid biosynthesis, as well as cell location and accumulation of these compounds in embryo axes of Lupinus luteus L. cv. Polo. Embryo axes, both non-inoculated and inoculated, were cultured for 96 h on Heller medium with 60 mM sucrose (+Sn and +Si) or without it (−Sn and −Si). Real-time RT-PCR to assess expression levels of the flavonoid biosynthetic genes, phenylalanine ammonialyase (PAL), chalcone synthase (CHS), chalcone isomerase (CHI) and isoflavone synthase (IFS) were used. Sucrose alone strongly stimulated the expression of these genes. There was a very high expression level of these genes in +Si embryo axes in the early phase of infection. Signal amplification by sucrose and the infection was most intense in the 48-h +Si axes, resulting in the highest level of expression of flavonoid biosynthetic genes. In −Si tissues, the expression level of these genes increased at 48 and 72 h after inoculation relative to 24 h; however, the relative level of expression was much lower than in +Si axes, except at 72 h for PAL and CHS.Moreover, at 48 h of culture, considerably higher activity of CHI (EC 5.5.1.6) was observed in axes with a high level of sucrose than in those with a sucrose deficit. CHI activity in +Si axes at 48 and 96 h post-inoculation was over 1.5 and 2 times higher than that in +Sn axes, as well as higher than in −Si axes.Observations of yellow lupine embryo axes under a confocal microscope showed an increased post-infection accumulation of flavonoids, particularly in cells of embryo axes infected with F. oxysporum and cultured on a medium containing sucrose (+Si). Up to 48 h post-infection in +Si axes, a very intensive emission of green fluorescence was observed, indicating high accumulation of these compounds in whole cells. Moreover, a nuclear location of flavonoids was recorded in cells. Strong staining of flavonoid end products in +Si embryo axes was consistent with the expression of PAL, CHS, CHI and IFS.These results indicate that, in the early phase of infection, the flavonoid biosynthesis pathway is considerably enhanced in yellow lupine embryo axes as a strong signal amplification effect of sucrose and the pathogenic fungus F. oxysporum.