Linkage of the <Emphasis Type="Italic">A</Emphasis> locus for the presence of anthocyanin and <Emphasis Type="Italic">fs10.1</Emphasis>, a major fruit-shape QTL in pepper

The purple color of the foliage, flower and immature fruit of pepper ( Capsicum spp.) is a result of the accumulation of anthocyanin pigments in these tissues. The expression of anthocyanins is controlled by the incompletely dominant gene A. We have mapped A to pepper chromosome 10 in a Capsicum annuum (5226) x Capsicum chinense (PI 159234) F(2) population to a genomic region that also controls anthocyanin expression in two other Solanaceous species, tomato and potato, suggesting that variation for tissue-specific expression of anthocyanin pigments in these plants is controlled by an orthologous gene(s). We mapped an additional locus, Fc, for the purple anther filament in an F(2) population from a cross of IL 579, a C. chinense introgression line and its recurrent parent 100/63, to the same position as A, suggesting that the two loci are allelic. The two anthocyanin loci were linked to a major quantitative trait locus, fs10.1, for fruit-shape index (ratio of fruit length to fruit width), that also segregated in the F(2) populations. This finding verified the observation of Peterson in 1959 of linkage between fruit color and fruit-shape genes in a cross between round and elongated-fruited parents. The linkage relationship in pepper resembles similar linkage in potato, in which anthocyanin and tuber-shape genes were found linked to each other in a cross of round and elongated-tuber parents. It is therefore possible that the shape pattern of distinct organs such as fruit and tuber in pepper and potato is controlled by a similar gene(s).     

Co-suppression in transgenicPetunia hybrida expressing chalcone synthase A (chsA)

Chalcone synthase A is a key enzyme in the anthocyanin biosynthesis pathway. Expression ofchsA gene in transgenicPetunia hybrida resulted in flower color alterations and co-suppression of transgenes and endogenous genes. We fused the β-glucuronidase (uidA) gene to the C-terminal ofchsA gene, and transferred the fusion gene intoPetunia hybrida viaAgrobacterium tumefaciens. GUS histochemical staining analysis showed that co-suppression occurred specifically during the development of flowers and co-suppression required the mutual interaction of endogenous genes and transgenes. RNAin situ hybridization analysis suggested that co-suppression occurred in the entire plant, and RNA degradation occurred in the cytoplasm.     

Co-suppression in transgenic Petunia hybrida expressing chalcone synthase A ( chsA )

Chalcone synthase A is a key enzyme in the anthocyanin biosynthesis pathway. Expression ofchsA gene in transgenicPetunia hybrida resulted in flower color alterations and co-suppression of transgenes and endogenous genes. We fused the β-glucuronidase (uidA) gene to the C-terminal ofchsA gene, and transferred the fusion gene intoPetunia hybrida viaAgrobacterium tumefaciens. GUS histochemical staining analysis showed that co-suppression occurred specifically during the development of flowers and co-suppression required the mutual interaction of endogenous genes and transgenes. RNAin situ hybridization analysis suggested that co-suppression occurred in the entire plant, and RNA degradation occurred in the cytoplasm.     

A Strain of Bacillus thuringiensis for the Control of Plant‐parasitic Nematodes

An isolate of Bacillus thuringiensis, designated CR‐371, was evaluated for efficacy in controlling plant‐parasitic nematodes. This isolate was first shown to be nematicidal to Caenorhabditis elegans in an in vitro laboratory assay. Treatment resulted in a significant reduction in galls due to root‐knot nematode on tomato in a greenhouse trial. In two field trials in Puerto Rico, CR‐371‐treated tomatoes and pepper had significantly fewer root galls due to Meloidogyne incognita than untreated controls, and populations of Rotylenchulus reniformis were smaller. In one experiment, CR‐371 treatment was associated with significant increases in pepper yields, while in the second trial small yield increases of pepper and tomato occurred. In a greenhouse trial, incorporation of CR‐371 into a methyl cellulose seed coat gave similar control of root‐knot nematode on tomato as compared to CR‐371 applied as a drench. CR‐371‐treated strawberry plants also had smaller populations of Pratylenchus penetrans in roots in a greenhouse trial in Massachusetts.     

Candidate gene analysis of anthocyanin pigmentation loci in the<Emphasis Type="Italic"> Solanaceae</Emphasis>

Crop species in the Solanaceae, which includes tomato (Lycopersicon esculentum), potato (Solanum tuberosum), pepper (Capsicum spp.), and eggplant (S. melongena), exhibit natural variation in the types, levels, and tissue-specific expression patterns of anthocyanin pigments. While the identities of the genes underpinning natural variation in anthocyanin traits in these crops are largely unknown, many structural genes and regulators of anthocyanin biosynthesis have been isolated from the solanaceous ornamental species Petunia. To identify candidate genes that may correspond to loci controlling natural variation in the four crops, 13 anthocyanin-related genes were localized on a tomato F₂ genetic map. Gene map positions were then compared to mapped mutants in tomato and through comparative genetic maps to natural variants in potato, eggplant, and pepper. Similar map positions suggest that the tomato mutants anthocyaninless, entirely anthocyaninless, and anthocyanin gainer correspond to flavonoid 35-hydroxylase (f35h), anthocyanidin synthase, and the Petunia Myb domain trancriptional regulatory gene an2, respectively. Similarly potato R, required for the production of red pelargonidin-based pigments, P, required for production of purple delphinidin-based pigments, and I, required for tissue-specific expression in tuber skin, appear to correspond to dihydroflavonol 4-reductase, f35h and an2, respectively. The map location of an2 also overlaps pepper A and eggplant fap10.1, lla10.1, lra10.1, sa10.1, pa10.1 and ca10.1, suggesting that a homologous regulatory locus has been subjected to parallel selection in the domestication of many solanaceous crops. To test the hypothesis that tomato anthocyaninless corresponds to f35h, a portion of the gene was sequenced. A premature stop codon was observed in an anthocyaninless mutant, but not in wild-type.Communicated by H.F. Linskens     

Unstable elements at the locusLuteus-1 inPetunias hybrida: Genetic analysis of their mobility

At theLul (Luteus-1) locus from Petunia, semi-dominant mutations occur, characterized by partial chlorophyll deficiencies. They can show phenotypic instability with green spot reversions. Two types of unstable mutations are described. Thelu-ml type presents a low rate of somatic reversions that are regulated by non-linked various activating factors. In contrast thelu-m3 instability shows high reversion rates regulated by a linked specific activating factor (La3), not found otherwise among the genome. Under the effect of therecombination modulator (Rm1), lu-m3 andLa3 were separated inducing a stabilization oflu-m3. This allele,lu-m3rs, however, seems to be able to respond again to a transactivation by reintroduction ofLa3 through crossing. The high transposition potential of the associationlu-m3rs-La3 was implemented to test its capacity to reinster. This experiment, conducted on a large scale, has allowed us to detect and study two unstable mutations concerning the flower pigmentation. Those two genes that control the anthocyanin production and the flavonol synthesis, respectively, are strictly linke toLul. Consequently it can be assumed that those two unstable mutations are due to reinsertion of thelu-m3rs transposons through proximal transpositions.     

On the origin of anthocyanin methyltransferase isozymes of Petunia hybrida and their role in regulation of anthocyanin methylation

Summary Four genes controlling anthocyanin methylation in flowers of Petunia hybrida have been described. Three of them, Mt2, Mf1 and Mf2, caused a dosage effect on anthocyanin methyltransferase activity and degree of methylation of anthocyanins. Antiserum raised against partially purified Mf2-enzyme precipitated three of the four anthocyanin methyltransferases. In two subspecies of one of the ancestral species of P. hybrida: Petunia integrifolia, different anthocyanin methyltransferases were found as determined by immunoprecipitation. The methyltransferase isozymes showed no differences in subcellular or tissue location, and had no physiologically important difference in time course of activity during bud development. The methylation-system in Petunia is discussed with regard to anthocyanin methylation in other plant species.     

Upregulation of a tonoplast-localized cytochrome P450 during petal senescence in Petunia inflata

Background  

Gene expression in Petunia inflata petals undergoes major changes following compatible pollination. Severe flower wilting occurs reproducibly within 36 hours, providing an excellent model for investigation of petal senescence and programmed cell death. Expression of a number of genes and various enzyme activities involved in the degradation and remobilization of macromolecules have been found to be upregulated during the early stages of petal senescence.     

花色改造基因工程

自1987年世界首例成功运用转基因技术改造矮牵牛花色以来,花色改造基因工程技术不断展现它在培育新花色品系上的无穷魅力。介绍了近年来运用基因工程技术成功改造花色的3种主要策略:(1)采用反义RNA及共抑制的方法来改变花颜色的深浅;(2)通过导入新基因产生新奇花色;(3)利用转座子构建特殊表达载体,随机激活花色合成的基因来产生嵌合花色。此外,还对转基因株花色不稳定原因进行了讨论。     

Gerbera hybrida (Asteraceae) imposes regulation at several anatomical levels during inflorescence development on the gene for dihydroflavonol-4-reductase

In the ornamental cut flower plant Gerbera hybrida the spatial distribution of regulatory molecules characteristic of differentiation of the composite inflorescence is visualized as the various patterns of anthocyanin pigmentation of different varieties. In order to identify genes that the plant can regulate according to these anatomical patterns, we have analysed gene expression affecting two enzymatic steps, chalcone synthase (CHS) and dihydroflavonol-4-reductase (DFR), in five gerbera varieties with spatially restricted anthocyanin pigmentation patterns. The dfr expression profiles vary at the levels of floral organ, flower type and region within corolla during inflorescence development according to the anthocyanin pigmentation of the cultivars. In contrast, chs expression, although regulated in a tissue-specific manner during inflorescence development, varies only occasionally. The variation in the dfr expression profiles between the varieties reveals spatially specific gene regulation that senses the differentiation events characteristic of the composite inflorescence.     

Tobacco TTG2 and ARF8 function concomitantly to control flower colouring by regulating anthocyanin synthesis genes

• Recently we elucidated that tobacco TTG2 cooperates with ARF8 to regulate the vegetative growth and seed production.
• Here we show that TTG2 and ARF8 control flower colouring by regulating expression of ANS and DFR genes, which function in anthocyanin biosynthesis.
• Genetic modifications that substantially altered expression levels of the TTG2 gene and production quantities of TTG2 protein were correlated with flower development and colouring. Degrees of flower colour were increased by TTG2 overexpression but decreased through TTG2 silencing, in coincidence with high and low concentrations of anthocyanins in flowers. Of five genes involved in the anthocyanin biosynthesis pathway, only ANS and DFR were TTG2‐regulated and displayed enhancement and diminution of expression with TTG2 overexpression and silencing, respectively. The floral expression of ANS and DFR also needed a functional ARF8 gene, as ANS and DFR expression were attenuated by ARF8 silencing, which concomitantly diminished the role of TTG2 in anthocyanin production. While ARF8 required TTG2 to be expressed by itself and to regulate ANS and DFR expression, the concurrent presence of normally functional TTG2 and ARF8 was critical for floral production of anthocyanins and also for flower colouration.
• Our data suggest that TTG2 functions concomitantly with ARF8 to control degrees of flower colour by regulating expression of ANS and DFR, which are involved in the anthocyanin biosynthesis pathway. ARF8 depends on TTG2 to regulate floral expression of ANS and DFR with positive effects on anthocyanin production and flower colour.

     

Serologically-Related Anionic Peroxidases from Petunia and Cucumber can Substitute Flavonoid Antioxidants

In this study we have investigated whether naturally occurring flavonoid-deficient mutant Red Star of Petunia hybrida is capable of metabolizing H₂O₂ by invoking other antioxidant enzyme system. We demonstrated that reduced flower pigmentation due to a reduction in the chalcone synthase mRNA expression results in strong H₂O₂ accumulation accompanied by the induction of a specific set of anionic peroxidase (PRX), serologically-related to main cucumber srPRX. We found correlation between rate of H₂O₂ accumulation and qualitative, as well as quantitative changes in the srPRX expression which seems to be determined by flower phenotype. In detached flower buds cultured in vitro both abscisic acid and anther extirpation prevented anthocyanin pigmentation, and thus flavonoid biosynthesis, resulting in a marked accumulation of immunoprecipitable srPRX. In contrast, pigmented flowers cultivated under the same conditions did not accumulate corresponding srPRX. The results suggest that a specific set of anionic PRX can substitute for the absence of flavonoid antioxidants.     

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.     

Modification of the B-ring during flavonoid synthesis in Petunia hybrida: Effect of the hydroxylation gene Hf1 on dihydroflavonol intermediates

The white flowering mutant W48 of Petunia hybrida is dominant for the hydroxylation gene Hf1 and homozygous recessive for the hydroxylation gene Ht1 and the anthocyanin gene An1. Flower buds of this mutant accumulate dihydrokaempferol-glucosides. Thus the effect of Hf1 being dominant is not the hydroxylation of the C15 skeleton, as is the case in mutants that are able to synthesize anthocyanins. This can be explained either by a feed-back inhibition of the hydroxylation by small amounts of dihydromyricetin (glucosides), or by a controlling effect of the gene An1 on the expression of Hf1. However, the white flowering mutant W58, which is homozygous recessive for the gene An6 and dominant for Hf1, accumulates dihydromyricetin (glucosides). This excludes a possible feed-back inhibition by dihydromyricetin and we conclude that An1 controls the expression of Hf1. Feeding of radioactive malonic acid to isolated flower limbs of mutants able to synthesize anthocyanins, leads to the incorporation of radioactivity into dihydrokaempferol (glucosides) and dihydroquercetin (glucosides). These results show that glucosylation of dihydroflavonols is a normal event in anthocyanin biosynthesis and is not induced by an inhibition of anthocyanin synthesis.     

Resistance in tomato to Xanthomonas campestris pv vesicatoria is determined by alleles of the pepper-specific avirulence gene avrBs3

Bacterial spot disease of tomato and pepper caused by Xanthomonas campestris pv vesicatoria is prevented by resistance genes in the plant that match genes for avirulence in the bacterium. Based on DNA homology to the avirulence gene avrBs3, which induces the resistance response on pepper, we have isolated another avirulence gene from X. c. vesicatoria, designated avrBs3-2. This gene differs in specificity from avrBs3 in inducing the hypersensitive response on tomato but not on pepper. Sequence analysis of the avrBs3-2 gene revealed a high degree of conservation: the 3480 by open reading frame contains an internal region of 17.5 nearly identical 102 bp repeat units that differ in their order from those present in the avrBs3 gene. The coding region is 97% identical to avrBs3 and expresses constitutively a 122 kDa protein, thus representing a natural allele of this gene. The previously isolated 1.7 kb avrBsP gene from X. c. vesicatoria is 100% identical to the corresponding avrBs3-2 sequence, indicating that these genes might be identical. Interestingly, derivatives of avrBs3-2 lacking the C-terminal region and part of the repetitive region are still able to confer incompatibility in tomato. The avrBs3-2 gene is compared with the sequence of avrBs3 derivatives generated by deletion of repeat units that also have avirulence activity on tomato. Both genes, avrBs3 and avrBs3-2, are flanked by a 62 by long inverted repeat, which prompts speculations about the origin of the members of the avrBs3 gene family.     

Evidence for transposition in Petunia

Summary In Petunia interaction is described between a trans-regulatory genetic element Bi and responsive anthocyanin alleles, resulting in a variegated flower colour pattern. Crosses segregated white-flowering plants that had lost the Bi element and could be shown to contain a responsive allele by the colour pattern resulting from interaction with the standard variegated parent. A weak mutant of the Bi element is described. Some pure lines of Petunia contained the Bi element, others did not. In two lines it could be mapped to chromosome I.