Alteration of a single amino acid changes the substrate specificity of dihydroflavonol 4-reductase

Many plant species exhibit a reduced range of flower colors due to the lack of an essential gene or to the substrate specificity of a biosynthetic enzyme. Petunia does not produce orange flowers because dihydroflavonol 4-reductase (DFR) from this species, an enzyme involved in anthocyanin biosynthesis, inefficiently reduces dihydrokaempferol, the precursor to orange pelargonidin-type anthocyanins. The substrate specificity of DFR, however, has not been investigated at the molecular level. By analyzing chimeric DFRs of Petunia and Gerbera, we identified a region that determines the substrate specificity of DFR. Furthermore, by changing a single amino acid in this presumed substrate-binding region, we developed a DFR enzyme that preferentially reduces dihydrokaempferol. Our results imply that the substrate specificity of DFR can be altered by minor changes in DFR.     

Redirection of anthocyanin synthesis in Osteospermum hybrida by a two-enzyme manipulation strategy

Modern biotechnology has developed powerful tools for genetic engineering and flower colours are an excellent object to study possibilities and limitations of engineering strategies. Osteospermum hybrida became a popular ornamental plant within the last 20 years. Many cultivars display rose to lilac flower colours mainly based on delphinidin-derived anthocyanins. The predominant synthesis of delphinidin derivatives is referred to a strong endogenous flavonoid 3',5'-hydroxylase (F3'5'H) activity. Furthermore, since dihydroflavonol 4-reductase (DFR) of Osteospermum does not convert dihydrokaempferol (DHK) to leucopelargonidin, synthesis of pelargonidin-based anthocyanins is naturally not realised. In order to redirect anthocyanin biosynthesis in Osteospermum towards pelargonidin derivatives, we introduced cDNAs coding for DFRs which efficiently convert DHK to LPg. But neither the expression of Gerbera hybrida DFR nor of Fragaria x ananassa DFR - the latter is characterised by an unusual high substrate preference for DHK - altered anthocyanin composition in flowers of transgenic plants. However, chemical inhibition of F3'5'H activity in ray florets of dfr transgenic plants resulted in the accumulation of pelargonidin derivatives. Accordingly, retransformation of a transgenic plant expressing Gerbera DFR with a construct for RNAi-mediated suppression of F3'5'H activity resulted in double transgenic plants accumulating predominantly pelargonidin derivatives in flowers.     

高等植物二氢黄酮醇4-还原酶基因研究进展

花青素苷是影响植物花瓣呈色的重要色素,而花色是决定花卉观赏价值和商业价值的一个重要因素。在花青素苷的生物合成过程中,二氢黄酮醇4-还原酶（DFR）是花青素苷生物合成下游途径中的第一个关键的酶。因此,DFR在高等植物花色的形成过程中发挥极其重要的作用,是形成花青素苷的一个非常重要的调控点。DFR对3种二氢黄酮醇底物具有选择特异性,但决定DFR底物特异性的分子机制目前仍不十分清楚。该文简单概述了花青素苷生物合成途径及其转录调控机制,并结合作者的工作重点综述了DFR的底物特异性以及克隆的DFR基因在植物基因工程中的应用。     

Regulation of gene expression involved in flavonol and anthocyanin biosynthesis during petal development in lisianthus (Eustoma grandiflorum)

To elucidate gene regulation of flower colour formation, the gene expressions of the enzymes involved in flavonoid biosynthesis were investigated in correlation with their product during floral development in lisianthus. Full-length cDNA clones of major responsible genes in the central flavonoid biosynthetic pathway, including chalcone synthase (CHS), chalcone isomerase (CHI), flavanone 3-hydroxylase (F3H), flavonoid 3',5'-hydroxylase (F3'5'H), dihydroflavonol 4-reductase (DFR), anthocyanidin synthase (ANS), and flavonol synthase (FLS), were isolated and characterized. In lisianthus, the stage of the accumulation of flavonols and anthocyanins was shown to be divided clearly. The flavonol content increased prior to anthocyanin accumulation during floral development and declined when anthocyanin began to accumulate. CHS, CHI, and F3H were necessary for both flavonol and anthocyanin biosynthesis and were coordinately expressed throughout all stages of floral development; their expressions were activated independently at the stages corresponding to flavonol accumulation and anthocyanin accumulation, respectively. Consistent with flavonol and anthocyanin accumulation patterns, FLS, a key enzyme in flavonol biosynthesis, was expressed prior to the expression of the genes involved in anthocyanin biosynthesis. The genes encoding F3'5'H, DFR, and ANS were expressed at later stages, just before pigmentation. The genes responsible for the flavonoid pathways branching to anthocyanins and flavonols were strictly regulated and were coordinated temporally to correspond to the biosynthetic order of their respective enzymes in the pathways, as well as in specific organs. In lisianthus, FLS and DFR, at the position of branching to flavonols and anthocyanins, were supposed to play a critical role in regulation of each biosynthesis.     

二氢黄酮醇 4 还原酶在花青素合成中的功能及调控研究进展

植物色素主要有花青素、类胡萝卜素和生物碱类色素三大类,其中花青素是决定大部分被子植物组织或器官颜色的重要色素。花青素通过类黄酮途径合成,该途径是生物学上研究较多且较为清楚的代谢途径之一。近年来的研究表明,在该途径中除了查尔酮合成酶(chalcone synthase,CHS)、查尔酮异构酶(chalcone isomerase,CHI)和黄烷酮-3-羟化酶(flavanone-3-hydrolase,F3H)起着关键作用外,二氢黄酮醇-4-还原酶(dihydroflavonol 4-reductase,DFR)对花青素的合成也至关重要。DFR可催化3种二氢黄酮醇和2种黄烷酮生成5种不同的花青素前体,且DFR基因家族不同成员对各个底物的催化效率不同,因此它在一定程度上决定着植物中花青素的种类和含量,从而影响植物组织或器官的颜色。该文对近年来国内外有关DFR在花青素合成过程中的生物学功能与调控,包括DFR的特征、作用机制和系统进化以及环境、转录因子和一些结构基因与DFR的关系等方面的研究进展进行了综述,以期为DFR今后的研究和利用基因工程改变植物组织或器官的颜色提供理论依据。     

Gene characterization, analysis of expression and in vitro synthesis of dihydroflavonol 4-reductase from [Citrus sinensis (L.) Osbeck

Dihydroflavonol 4-reductase (DFR, EC 1.1.1.219) catalyzes the reduction of dihydroflavonols to leucoanthocyanins, a key "late" step in the biosynthesis of anthocyanins. In this study we showed that a strong reduction in DFR expression occurs in the non-red orange cultivar (Navel and Ovale) compared to that of the red orange (Tarocco) suggesting that the enzyme could be involved in the lack of production of anthocyanins. Therefore, we isolated and compared the cDNAs, the genomic clones, as well as the promoter regions of blood and blond orange dfrs. Our data revealed that the cDNA sequences of pigmented and non-pigmented orange DFRs were 100% homologous and contained a 1017 bp open reading frame which encodes a protein of 338 amino acid residues, corresponding to a molecular mass of 38010.76 Da, with a theoretical pI of 5.96. Moreover, we found that there were no significant differences in non-coding regions (introns and 5' upstream region) of dfr sequences. Southern blot analysis of genomic DNA indicated that dfr was present as a single copy gene in both cultivars. From these findings the low expression level of blond orange dfr, which might play a role in the phenotypic change from blood to blond orange, is thought to be the result of a likely mutation in a regulatory gene controlling the expression of dfr. In addition, here we reported the successful expression of orange DFR cDNAs leading to an active DFR enzyme which converts dihydroquercetin to leucoanthocyanidin, thus confirming the involvement of the isolated genes in the biosynthesis of anthocyanins. Moreover, as far as we know, this is the first report concerning the in vitro expression of DFR from fruit flesh whose biochemical properties might be very different from those of other plant organ DFRs.     

Dihydroflavonol 4-reductase cDNA from non-anthocyanin-producing species in the Caryophyllales

Two types of red pigment, anthocyanins and betacyanins, never occur together in the same plant. Although anthocyanins are widely distributed in higher plants as flower and fruit pigments, betacyanins have replaced anthocyanins in the Caryophyllales. We isolated cDNAs encoding dihydroflavonol 4-reductase (DFR), which is the first enzyme committed to anthocyanin biosynthesis in the flavonoid pathway, from Spinacia oleracea and Phytolacca americana, plants that belong to the Caryophyllales. The deduced amino acid sequence of Spinacia DFR and Phytolacca DFR revealed a high degree of homology with DFRs of anthocyanin-producing plants. The DFR of carnation, an exception in the Caryophyllales that synthesizes anthocyanin, showed the highest level of identity. In the phylogenetic tree, Spinacia DFR and Phytolacca DFR clustered with the DFRs of anthocyanin-synthesizing dicots. Recombinant Spinacia and Phytolacca DFRs expressed in Escherichia coli convert dihydroflavonol to leucoanthocyanidin. The expression and function of DFR in spinach and pokeweed are discussed in relation to the molecular evolution of red pigment biosynthesis in higher plants.     

The COI1 and DFR Genes are Essential for Regulation of Jasmonate-Induced Anthocyanin Accumulation in Arabidopsis

Jasmonates(JAs)are a class of plant hormones that play important roles in the regulation of plant development and plantdefense.It has been shown that Arabidopsis plants produce much higher levels of anthocyanins when treated exogenouslywith methyl jasmonate(MeJA).However,a molecular link between the JA response and anthocyanin production hasnot been determined.The CORONATINE INSENTITIVE1(COI1)gene is a key player in the regulation of many JA-relatedresponses.In the present study,we demonstrate that the COI1 gene is also required for the JA-induced accumulation ofanthocyanins in Arabidopsis.Furthermore,the MeJA-inducible expression of DIHYDROFLAVONOL REDUCTASE(DFR),anessential component in the anthocyanin biosynthesis pathway,was completely eliminated in the coil mutant.Jasmonate-induced anthocyanin accumulation was found to be independent of auxin signaling.The present results indicate that theexpression of both COI1 and DFR genes is required for the regulation of JA-induced anthocyanin accumulation and thatDFR may be a key downstream regulator for this process.     

The COI1 and DFR Genes are Essential for Regulation of Jasmonate-Induced Anthocyanin Accumulation in Arabidopsis

Jasmonates （JAs） are a class of plant hormones that play important roles in the regulation of plant development and plant defense. It has been shown that Arabidopsis plants produce much higher levels of anthocyanins when treated exogenously with methyl jasmonate （MeJA）. However, a molecular link between the JA response and anthocyanin production has not been determined. The CORONATINE INSENTITIVE1 （COI1） gene is a key player in the regulation of many JA-related responses. In the present study, we demonstrate that the COI1 gene is also required for the JA-induced accumulation of anthocyanins in Arabidopsis. Furthermore, the MeJA-inducible expression of DIHYDROFLAVONOL REDUCTASE （DFR）, an essential component in the anthocyanin biosynthesis pathway, was completely eliminated in the coil mutant. Jasmonateinduced anthocyanin accumulation was found to be independent of auxin signaling. The present results indicate that the expression of both COI1 and DFR genes is required for the regulation of JA-induced anthocyanin accumulation and that DFR may be a key downstream regulator for this process.     

Complementation of the Tomato anthocyanin without (aw) Mutant Using the Dihydroflavonol 4-Reductase Gene

We isolated the dihydroflavonol 4-reductase (DFR) gene from tomato (Lycopersicon esculentum) using a previously characterized cDNA as probe. Earlier studies had indicated that the DFR gene is present in tomato as a single gene located on chromosome 2 near the locus anthocyanin without (aw). Mutant alleles of the aw locus result in the complete absence of anthocyanin pigmentation throughout all stages of plant development. When the genomic DFR clone was introduced by Agrobacterium-mediated transformation into plants bearing the aw mutation, primary transgenic seedlings accumulated anthocyanins that could be observed while the plants were still in tissue culture and which continued to be observed as the plants matured. Progeny of self pollinated and backcrossed transgenic plants segregated for anthocyanin pigmentation, and Southern hybridization analyses indicated the presence of the DFR transgene exclusively in those plants with pigmentation. These data indicate that the aw locus likely corresponds to the structural gene for DFR and that DFR can be used as a visual, nondestructive, plant-derived marker gene for tomato.     

Flower colour and cytochromes P450

Flavonoids are major constituents of flower colour. Plants accumulate specific flavonoids and thus every species often exhibits a limited flower colour range. Three cytochromes P450 play critical roles in the flavonoid biosynthetic pathway. Flavonoid 3′-hydroxylase (F3′H, CYP75B) and flavonoid 3′,5′-hydroxylase (F3′5′H, CYP75A) catalyze the hydroxylation of the B-ring of flavonoids and are necessary to biosynthesize cyanidin-(red to magenta) and delphinidin-(violet to blue) based anthocyanins, respectively. Pelargonidin-based anthocyanins (orange to red) are synthesized in their absence. Some species such as roses, carnations and chrysanthemums do not have violet/blue flower colour due to deficiency of F3′5′H. Successful expression of heterologous F3′5′H genes in roses and carnations results in delphinidin production, causing a novel blue/violet flower colour. Down-regulation of F3′H and F3′5′H genes has yielded orange petunia and pink torenia colour that accumulate pelargonidin-based anthocyanins. Flavone synthase II (CYP93B) catalyzes the synthesis of flavones that contribute to the bluing of flower colour, and modulation of FNSII gene expression in petunia and tobacco changes their flower colour. Extensive engineering of the anthocyanin pathway is therefore now possible, and can be expected to enhance the range of flower colours.     

Genetic engineering of the anthocyanin biosynthetic pathway with flavonoid-3′,5′-hydroxylase: specific switching of the pathway in petunia

Flavonoid-3',5'-hydroxylase (F3'5'H) is the key enzyme in the synthesis of 3',5'-hydroxylated anthocyanins, which are generally required for the expression of blue or purple flower color. It has been predicted that the introduction of this enzyme into a plant species that lacks it would enable the production of blue or purple flowers by altering the anthocyanin composition. We present here the results of the genetic engineering of petunia flower color, pigmentation patterns and anthocyanin composition with sense or antisense constructs of the F3'5'H gene under the control of the CaMV 35S promoter. When sense constructs were introduced into pink flower varieties that are deficient in the enzyme, transgenic plants showed flower color changes from pink to magenta along with changes in anthocyanin composition. Some transgenic plants showed novel pigmentation patterns, e.g. a star-shaped pattern. When sense constructs were introduced into blue flower petunia varieties, the flower color of the transgenic plants changed from deep blue to pale blue or even pale pink. Pigment composition analysis of the transgenic plants suggested that the F3'5'H transgene not only created or inhibited the biosynthetic pathway to 3',5'-hydroxylated anthocyanins but switched the pathway to 3',5'-hydroxylated or 3'-hydroxylated anthocyanins.     

Flower color modulations of Torenia hybrida by downregulation of chalcone synthase genes with RNA interference

Suppression of biosynthetic genes involved in flower color formation is an important approach for obtaining target flower colors. Here we report that flower color of the garden plant Torenia hybrida was successfully modulated by RNA interference (RNAi) against a gene of chalcone synthase (CHS), a key enzyme for anthocyanin and flavonoid biosynthesis. By using each of the coding region and the 3'-untranslated region of the CHS mRNA as an RNAi target, exhaustive and gene-specific gene silencing were successfully induced, and the original blue flower color was modulated to white and pale colors, respectively. Our results indicate that RNAi is quite useful for modulations of flower colors of commercially important garden plants.     

植物二氢黄酮醇4-还原酶基因的研究进展

二氢黄酮醇4-还原酶（DFR）是花青素合成途径的关键酶,在花色的修饰中起重要作用。我们简述了DFR基因及其调节基因的研究进展,构建的系统进化树体现了部分单子叶与双子叶植物间的亲缘关系与进化差异,阐述了DFR调控基因的调控机制及DFR基因的应用前景。     

不同花色菊花品种花色素结构基因的表达特性

对红色、黄色、粉紫色和白色菊花品种不同开放度的花序舌状花中CHS、CHI、DFR、F3H、F3′H和3GT基因的表达量进行了相对定量分析。结果表显示:6个基因的表达因不同花色、不同发育阶段而异。‘钟山红鹰’(红色)中各基因的表达量均较高,且均在Ⅱ(松蕾期)或Ⅲ(半开期)期达到峰值,其中DFR、3GT基因的表达量远高于其他花色品种。‘金陵娇黄’(黄色)中CHS、CHI基因表达量较高,且Ⅰ(紧蕾期)、Ⅱ期表达量高于Ⅲ、Ⅳ(盛开期)期;3GT、DFR基因表达量分别高或低于‘金陵笑靥’(粉紫色)品种中相应基因的表达量,但均比红色品种低;F3H在4个品种中表达量最低,F3′H表达量接近或略低于红色或粉紫色品种,且各阶段表达水平较稳定。‘金陵笑靥’中DFR表达量仅次于‘钟山红鹰’,3GT和CHS表达量低于红色与黄色品种。‘钟山雪桂’(白色)中各基因仅有微量表达,除F3H外各基因的表达量明显低于其他花色品种。研究表明,花色素结构基因DFR、3GT是菊花花色素合成的关键基因,DFR很可能是限速关键基因,一定表达水平的CHS、CHI也是菊花花色素合成所必须的,F3H基因与花色素合成不存在直接相关。     

七彩红竹二氢黄酮醇4-还原酶基因IhDFR1的克隆及表达分析

二氢黄酮醇4-还原酶（DFR）是植物花色素苷合成途径中的关键酶,在植物花色的形成过程中起重要作用。依据七彩红竹转录组数据设计特异引物,采用ImPcR技术从七彩红竹中克隆获得了一个新的DFR基因cDNA全长,命名为IhDFR1（登录号为KF728205）。序列分析结果表明,IhDFR1基因cDNA全长945bp,编码314个氨基酸。生物信息学预测显示,该基因编码的蛋白具有典型的DFR蛋白功能结构域,存在2个特异结合位点,属于非Asn／Asp型DFR酶,与禾本科植物中的DFR具有较高的相似性。对不同发育时期七彩红竹的IhDFR1基因进行时空表达的结果显示,只有在竹秆颜色呈现红紫色时,IhDFR1基因才有表达。以上结果初步显示IhDFR1蛋白可能作为一个重要的酶参与竹秆花色素苷的代谢调控,同时为进一步研究七彩红竹花色素苷产生的分子机理和综合开发利用奠定了基础。