Down-regulation of flavonoid 3'-hydroxylase gene expression by virus-induced gene silencing in soybean reveals the presence of a threshold mRNA level associated with pigmentation in pubescence

Changes in flavonoid content are often manifested as altered pigmentation in plant tissues. Two loci have been identified as controlling pigmentation in soybean pubescence. Of these, the T locus appears to encode flavonoid 3'-hydroxylase (F3'H) protein: the T and t alleles are associated with tawny and gray colors, respectively, in pubescence. We previously down-regulated F3'H gene expression by virus-induced gene silencing (VIGS) in soybean. Despite this successful VIGS, the tawny pubescence pigmentation proved to be unchanged in greenhouse-grown plants. We hypothesized that the reduced mRNA level of the F3'H gene resulting from VIGS remained high enough to induce pigmentation. To verify this hypothesis, in the present study, we performed F3'H VIGS on plants grown under controlled conditions, in which the steady-state mRNA level of the F3'H gene was reduced to approximately 5% of that of greenhouse-grown plants. This VIGS treatment resulted in the loss of tawny pigmentation in pubescence, suggesting that the sf3'h1 gene is involved in the control of pigmentation in pubescence. We detected a marked decrease in target mRNA, an accumulation of short interfering RNAs (siRNAs), and a decrease in quercetin content relative to kaempferol in leaf tissues, indicating that sequence-specific mRNA degradation of the F3'H gene was induced. These results suggest that leaf tissues have a threshold mRNA level of the F3'H gene, which is associated with the occurrence of tawny pigmentation in pubescence. The estimated threshold mRNA level for pigmentation in pubescence was approximately 3% of the steady-state mRNA level of the F3'H gene in greenhouse-grown plants.     

Selective accumulation of delphinidin derivatives in tobacco using a putative flavonoid 3',5'-hydroxylase cDNA from Campanula medium

Blue flowers generally contain 3',5'-hydroxylated anthocyanins (delphinidin derivatives) as pigments, which are formed only in the presence of flavonoid 3',5'-hydroxylases (F3'5'H). Heterologous expression of a F3'5'H gene therefore provides an opportunity to produce novel blue flowers for a number of ornamental plants missing blue flowering varieties. However, our previous study indicated difficulties in obtaining good accumulation of delphinidin derivatives in plants expressing F3'5'H. Here we report the isolation of a putative F3'5'H cDNA (Ka1) from canterbury bells (Campanula medium) and its expression in tobacco. Surprisingly, compared with other F3'5'H cDNAs, Ka1 encoded a protein with a unique primary structure that conferred high competence in the accumulation of delphinidin derivatives (up to 99% of total anthocyanins) and produced novel purple flowers. These results suggest that, among F3'5' H cDNAs, Ka1 is the best genetic resource for the creation of fine blue flowers by genetic engineering.     

Engineering of the rose flavonoid biosynthetic pathway successfully generated blue-hued flowers accumulating delphinidin

Flower color is mainly determined by anthocyanins. Rosa hybrida lacks violet to blue flower varieties due to the absence of delphinidin-based anthocyanins, usually the major constituents of violet and blue flowers, because roses do not possess flavonoid 3',5'-hydoxylase (F3'5'H), a key enzyme for delphinidin biosynthesis. Other factors such as the presence of co-pigments and the vacuolar pH also affect flower color. We analyzed the flavonoid composition of hundreds of rose cultivars and measured the pH of their petal juice in order to select hosts of genetic transformation that would be suitable for the exclusive accumulation of delphinidin and the resulting color change toward blue. Expression of the viola F3'5'H gene in some of the selected cultivars resulted in the accumulation of a high percentage of delphinidin (up to 95%) and a novel bluish flower color. For more exclusive and dominant accumulation of delphinidin irrespective of the hosts, we down-regulated the endogenous dihydroflavonol 4-reductase (DFR) gene and overexpressed the Irisxhollandica DFR gene in addition to the viola F3'5'H gene in a rose cultivar. The resultant roses exclusively accumulated delphinidin in the petals, and the flowers had blue hues not achieved by hybridization breeding. Moreover, the ability for exclusive accumulation of delphinidin was inherited by the next generations.     

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.     

Cloning of the pleiotropic T locus in soybean and two recessive alleles that differentially affect structure and expression of the encoded flavonoid 3' hydroxylase

Three loci (I, R, and T) control pigmentation of the seed coats in Glycine max and are genetically distinct from those controlling flower color. The T locus also controls color of the trichome hairs. We report the identification and isolation of a flavonoid 3' hydroxylase gene from G. max (GmF3'H) and the linkage of this gene to the T locus. This GmF3'H gene was highly expressed in early stages of seed coat development and was expressed at very low levels or not at all in other tissues. Evidence that the GmF3'H gene is linked to the T locus came from the occurrence of multiple RFLPs in lines with varying alleles of the T locus, as well as in a population of plants segregating at that locus. GmF3'H genomic and cDNA sequence analysis of color mutant lines with varying t alleles revealed a frameshift mutation in one of the alleles. In another line derived from a mutable genetic stock, the abundance of the mRNAs for GmF3'H was dramatically reduced. Isolation of the GmF3'H gene and its identification as the T locus will enable investigation of the pleiotropic effects of the T locus on cell wall integrity and its involvement in the regulation of the multiple branches of the flavonoid pathway in soybean.     

Flavonoid hydroxylase from Catharanthus roseus: cDNA, heterologous expression, enzyme properties and cell-type specific expression in plants

We investigated the P450 dependent flavonoid hydroxylase from the ornamental plant Catharanthus roseus. cDNAs were obtained by heterologous screening with the CYP75 Hf1 cDNA from Petunia hybrida. The C. roseus protein shared 68-78% identity with other CYP75s, and genomic blots suggested one or two genes. The protein was expressed in Escherichia coli as translational fusion with the P450 reductase from C. roseus. Enzyme assays showed that it was a flavonoid 3', 5'-hydroxylase, but 3'-hydroxylated products were also detected. The substrate specificity was investigated with the C. roseus enzyme and a fusion protein of the Petunia hybrida CYP75 with the C. roseus P450 reductase. Both enzymes accepted flavanones as well as flavones, dihydroflavonols and flavonols, and both performed 3'- as well as 3'5'-hydroxylation. Kinetics with C. roseus cultures on the level of enzyme activity, protein and RNA showed that the F3'5'H was present in dark-grown cells and was induced by irradiation. The same results were obtained for cinnamic acid 4-hydroxylase and flavanone 3beta-hydroxylase. In contrast, CHS expression was strictly dependent on light, although CHS is necessary in the synthesis of the F3'5'H substrates. Immunohistochemical localization of F3'5'H had not been performed before. A comparison of CHS and F3'5'H in cotyledons and flower buds from C. roseus identified CHS expression preferentially in the epidermis, while F3'5'H was only detected in the phloem. The cell-type specific expression suggests that intercellular transport may play an important role in the compartmentation of the pathways to the different flavonoids.     

Identification of the molecular basis for the functional difference between flavonoid 3'-hydroxylase and flavonoid 3',5'-hydroxylase

Flavonoid 3'-hydroxylase (F3'H) and flavonoid 3',5'-hydroxylase (F3'5'H) are cytochrome P450 enzymes and determine the B-ring hydroxylation pattern of flavonoids by introducing hydroxyl groups at the 3'- or the 3'- and 5'-position, respectively. Sequence identity between F3'H and F3'5'H is generally low since their divergence took place early in the evolution of higher plants. However, in the Asteraceae the family-specific evolution of an F3'5'H from an F3'H precursor occurred, and consequently sequence identity is substantially higher. We used this phenomenon for alignment studies, in order to identify regions which could be involved in determining substrate specificity and functionality. Subsequent construction and expression of chimeric genes indicated that substrate specificity of F3'H and F3'5'H is determined near the N-terminal end and the functional difference between these two enzymes near the C-terminal end. The impact on function of individual amino acids located in substrate recognition site 6 (SRS6) was further tested by site-directed mutagenesis. Most interestingly, a conservative Thr to Ser exchange at position 487 conferred additional 5'-hydroxylation activity to recombinant Gerbera hybrida F3'H, whereas the reverse substitution transformed recombinant Osteospermum hybrida F3'5'H into an F3'H with low remaining 5'-hydroxylation activity. Since the physicochemical properties of Thr and Ser are highly similar, the difference in size appears to be the main factor contributing to functional difference. The results further suggest that relatively few amino acids exchanges were required for the evolutionary extension of 3'- to 3',5'-hydroxylation activity.     

大豆种皮色相关基因研究进展

大豆种皮色在从野生大豆到栽培大豆的演变过程中逐渐从黑色变成黄色,是重要的形态标记,因此,大豆种皮色相关基因研究无论对进化理论还是育种实践都具有重要的意义。种皮颜色是通过各种花色苷的沉积而形成的。虽然很多植物色素沉积的分子调控机制比较明晰,但大豆中控制种皮颜色形成的基因尚未被完全了解。文章综述了控制大豆种皮色基因与位点的相关研究进展,主要有I、T、W1、R、O 5个经典遗传位点,其中I位点被定位在第8号染色体(A2连锁群)一个富含查尔酮合成酶(CHS)的区域,CHS基因在大豆中是多基因家族且同源性较高;定位于第6号染色体(C2连锁群)T位点的基因F3’H已被克隆和转基因验证,由于碱基缺失导致所编码的氨基酸缺少了保守域GGEK,从而不能与血红素结合而丧失功能;R位点定位在第9号染色体(K连锁群)A668-1与K387-1两标记之间,可能是R2R3类MYB转录因子,也可能是UDP类黄酮3-O糖基转移酶;O位点定位在第8号染色体(A2连锁群)Satt207与Satt493两标记之间,其分子特性尚不清楚;W1位点可能由F3’5’H基因控制遗传。     

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.     

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.     

转基因香石竹中F3’5’H基因的克隆、表达和免疫学鉴定

在研究转基因香石竹品系月之霓裳（Moonshade）、月之伊人（Moonlite）中外源基因F3’5’H的表达中,本文克隆了F3’5’H全长基因1.5kb,构建获得工程菌株Escherichia coli BL21（DE3）（＋F3＇5＇H）。SDS-PAGE分析的结果显示,该菌株高效表达出F3’5’H重组蛋白,约占菌体总蛋白的30%。用经纯化的F3’5’H重组蛋白作为抗原,制备F3’5’H重组蛋白的抗血清,经ELISA免疫学分析表明,该抗血清的效价为1：25600。Western blot结果表明F3’5’H重组蛋白具有良好的IgG结合活性,且抗血清与转基因香石竹品系月之霓裳和月之伊人中的外源基因F3’5’H所表达的蛋白发生明显的抗原抗体反应。这样,月之霓裳和月之伊人用于评价转基因香石竹品系的环境安全性在我国也得到了验证。     

Identification and characterisation of CYP75A31, a new flavonoid 3'5'-hydroxylase,isolated from <Emphasis Type="Italic">Solanum lycopersicum</Emphasis>

Background  

Understanding the regulation of the flavonoid pathway is important for maximising the nutritional value of crop plants and possibly enhancing their resistance towards pathogens. The flavonoid 3'5'-hydroxylase (F3'5'H) enzyme functions at an important branch point between flavonol and anthocyanin synthesis, as is evident from studies in petunia (Petunia hybrida), and potato (Solanum tuberosum). The present work involves the identification and characterisation of a F3'5'H gene from tomato (Solanum lycopersicum), and the examination of its putative role in flavonoid metabolism.