We attempted to overexpress chalcone synthase (CHS) in pigmented petunia petals by introducing a chimeric petunia CHS gene. Unexpectedly, the introduced gene created a block in anthocyanin biosynthesis. Forty-two percent of plants with the introduced CHS gene produced totally white flowers and/or patterned flowers with white or pale nonclonal sectors on a wild-type pigmented background; none of hundreds of transgenic control plants exhibited such phenotypes. Progeny testing of one plant demonstrated that the novel color phenotype co-segregated with the introduced CHS gene; progeny without this gene were phenotypically wild type. The somatic and germinal stability of the novel color patterns was variable. RNase protection analysis of petal RNAs isolated from white flowers showed that, although the developmental timing of mRNA expression of the endogenous CHS gene was not altered, the level of the mRNA produced by this gene was reduced 50-fold from wild-type levels. Somatic reversion of plants with white flowers to phenotypically parental violet flowers was associated with a coordinate rise in the steady-state levels of the mRNAs produced by both the endogenous and the introduced CHS genes. Thus, in the altered white flowers, the expression of both genes was coordinately suppressed, indicating that expression of the introduced CHS gene was not alone sufficient for suppression of endogenous CHS transcript levels. The mechanism responsible for the reversible co-suppression of homologous genes in trans is unclear, but the erratic and reversible nature of this phenomenon suggests the possible involvement of methylation.

Introduction of a Chimeric Chalcone Synthase Gene into Petunia Results in Reversible Co-Suppression of Homologous Genes in trans.

Double-stranded RNAs can suppress expression of homologous genes through an evolutionarily conserved process named RNA interference (RNAi) or post-transcriptional gene silencing (PTGS). One mechanism underlying silencing is degradation of target mRNAs by an RNP complex, which contains approximately 22 nt of siRNAs as guides to substrate selection. A bidentate nuclease called Dicer has been implicated as the protein responsible for siRNA production. Here we characterize the Caenorhabditis elegans ortholog of Dicer (K12H4.8; dcr-1) in vivo and in vitro. dcr-1 mutants show a defect in RNAi. Furthermore, a combination of phenotypic abnormalities and RNA analysis suggests a role for dcr-1 in a regulatory pathway comprised of small temporal RNA (let-7) and its target (e.g., lin-41).

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Dicer functions in RNA interference and in synthesis of small RNA involved in developmental timing in C. elegans

Studies of the molecular genetics, mechanisms of activation and functional connections between general phenylpropanoid metabolism and certain branch pathways in parsley, bean, potato plants and cell cultures

Physiology and Molecular Biology of Phenylpropanoid Metabolism

Biosynthesis of flavonoids and effects of stress.

Flavonoids represent a large class of secondary plant metabolites, of which anthocyanins are the most conspicuous class, dueto the wide range of colors resulting from their synthesis. Anthocyanins are important to many diverse functions within plants. Synthesis of anthocyanins in petals is undoubtedly intended to attract pollinators, whereas anthocyanin synthesis in seeds and fruits may aid in seed dispersal. Anthocyanins and other flavonoids can also be important as feeding deterrents and as protection against damage from UV irradiation. The existence of such a diverse range of functions and types of anthocyanins raises questions about how these compounds are synthesized and how their synthesis is regulated. The study of the genetics of anthocyanin synthesis began last century with Mendel’s work on flower color in peas. Since that time, there have been periods of intensive study into the genetics and biochemistry of pigment production in a number of different species. In the early studies, genetic loci were correlated with easily observable color changes. After the structures of anthocyanins and other flavonoids were determined, it was possible to correlate single genes with particular structural alterations of anthocyanins or with the presence or absence of particular flavonoids. Mutations in anthocyanin genes have been studied for many years because they are easily identified and because they generally have no deleterious effect on plant growth and development. In most cases, mutations affecting different steps of the anthocyanin biosynthesis pathway were isolated and characterized well before their function was identified or the corresponding gene was isolated. More recently, many genes involved in the biosynthesis of anthocyanin pigments have been isolated and characterized using recombinant DNA technologies. Three species have been particularly important for elucidating the anthocyanin biosynthetic pathway and for isolating genes controlling the biosynthesis of flavonoids: maize (Zea mays), snapdragon (Anfirrhinum majus), and petunia (Wtunia hybrida). Petunia has more recently become the organism of choice for isolating flavonoid biosynthetic genes and studying their interactions and regulation. At least 35 genes are known to affect flower color in petuniawiering and de Vlaming, 1984). Because this field of research has been reviewed fairly extensively in the past (Dooner et al., 1991; van Tunen and MOI, 1991; Gerats and Martin, 1992), in this review we concentrate on the more recent developments in gene isolation and characterization. A review of the genetics of flavonoid biosynthesis in other species was recently covered by Forkmann (1993). The characterization of genetically defined mutations has enabled the order of many reactions in anthocyanin synthesis and their modification to be elucidated. Some reactions have been postulated only on the basis of genetic studies and have not yet been demonstrated in vitro. Chemico-genetic studies have been very important in determining the enzymatic steps involved in anthocyanin biosynthesis and modification. The generation of transposon-tagged mutations and the subsequent cloning of the transposons provided a relatively straightforward means of isolating many genes from maize (Wienand et al., 1990) and snapdragon (Martin et al., 1991). However, a number of genes in the pathway have not been amenable to transposon tagging. Anthocyanin biosynthetic genes have been isolated using a range of methodologies, including protein purification, transposon tagging, differential screening, and polymerase chain reaction (PCR) amplification. Functions of isolated anthocyanin genes can be confirmed by restriction fragment length polymorphism (RFLP) mapping, complementation, or expression in heterologous systems. Reverse genetics has also been used recently to identify gene function; this requires a welldefined pathway to correlate phenotype with gene function. Once a gene has been isolated from one species, it is usually a straightforward task to isolate the homologous gene from other species by using the original clone as a molecular probe.

/pdf/genetics-and-biochemistry-of-anthocyanin-biosynthesis-41091xx7zv.pdf

Genetics and Biochemistry of Anthocyanin Biosynthesis

To evaluate the effect of increased expression of genes involved in flower pigmentation, additional dihydroflavonol-4-reductase (DFR) or chalcone synthase (CHS) genes were transferred to petunia. In most transformants, the increased expression had no measurable effect on floral pigmentation. Surprisingly, however, in up to 25% of the transformants, a reduced floral pigmentation, accompanied by a dramatic reduction of DFR or CHS gene expression, respectively, was observed. This phenomenon was obtained with both chimeric gene constructs and intact CHS genomic clones. The reduction in gene expression was independent of the promoter driving transcription of the transgene and involved both the endogenous gene and the homologous transgene. The gene-specific collapse in expression was obtained even after introduction of only a single gene copy. The similarity between the sense transformants and regulatory CHS mutants suggests that this mechanism of gene silencing may operate in naturally occurring regulatory circuits.

Flavonoid genes in petunia: addition of a limited number of gene copies may lead to a suppression of gene expression.

In this paper we report the isolation of cDNA clones encoding the flavonoid-biosynthetic enzyme chalcone flavanone isomerase (CHI) from Petunia hybrida. A nearly full size cDNA clone, isolated from a corolla-specific expression library, was characterized by sequence analysis. Using this CHI cDNA and the previously cloned flavonoid-specific chalcone synthase (CHS) cDNA we show that CHI and CHS genes are coordinately and tissue-specifically expressed in a developmental and light-regulated manner. Furthermore, coordinate induction of both mRNAs is observed after continuous irradiation of Petunia plantlets with UV light, probably as part of the plants UV defence mechanism. The two CHI genes, denoted A and B, were isolated from a genomic library of the Petunia inbred line V30. Both genes are transcriptionally active: gene A is transcribed in corolla, tube and UV-irradiated plantlets (1.0 kb mRNA), whereas gene B is only transcribed in immature anthers (1.0 kb mRNA). In combination with Southern blot analysis these data implicate the presence of two distinct non-allelic CHI genes in the genome of the P. hybrida line V30. Unexpectedly, mature anthers accumulate a 0.3 kb larger CHI RNA. This RNA is transcribed from CHI gene A and has a 0.3 kb 5' extension relative to the gene A transcript found in corolla tissue. Furthermore it is neither coordinately expressed with CHS mRNA nor UV inducible. Its biological function is still obscure, since no active CHI enzyme could be demonstrated in the same tissue.

Cloning of the two chalcone flavanone isomerase genes from Petunia hybrida: coordinate, light-regulated and differential expression of flavonoid genes.

We have analysed the expression of the 8-10 members of the gene family encoding the flavonoid biosynthetic enzyme chalcone synthase (CHS) from Petunia hybrida. During normal plant development only two members of the gene family (CHS-A and CHS-J) are expressed. Their expression is restricted to floral tissues mainly. About 90% of the total CHS mRNA pool is transcribed from CHS-A, wheares CHS-J delivers about 10% in flower corolla, tube and anthers. Expression of CHS-A and CHS-J during flower development is coordinated and (red) light-dependent. In young seedlings and cell suspension cultures expression of CHS-A and CHS-J can be induced with UV light. In addition to CHS-A and CHS-J, expression of another two CHS genes (CHS-B and CHS-G) is induced in young seedlings by UV light, albeit at a low level. In contrast to CHS genes from Leguminoseae, Petunia CHS genes are not inducible by phytopathogen-derived elicitors. Expression of CHS-A and CHS-J is reduced to a similar extent in a regulatory CHS mutant, Petunia hybrida Red Star, suggesting that both genes are regulated by the same trans-acting factors. Comparison of the promoter sequences of CHS-A and CHS-J reveals some striking homologies, which might represent cis-acting regulatory sequences.

The chalcone synthase multigene family of Petunia hybrida (V30): differential, light-regulated expression during flower development and UV light induction.

Cloning and molecular characterization of the chalcone synthase multigene family of Petunia hybrida.

Introduction of a constitutive antisense full-length chalcone synthase (CHS) cDNA gene in petunia can result in an inhibition of flower pigmentation. We have evaluated some of the factors which may be important for the effectiveness of an antisense CHS gene.

J. N. M. Mol

Papers

Flavonoid genes in petunia: addition of a limited number of gene copies may lead to a suppression of gene expression.

Cloning of the two chalcone flavanone isomerase genes from Petunia hybrida: coordinate, light-regulated and differential expression of flavonoid genes.

The chalcone synthase multigene family of Petunia hybrida (V30): differential, light-regulated expression during flower development and UV light induction.

Cloning and molecular characterization of the chalcone synthase multigene family of Petunia hybrida.

Inhibition of flower pigmentation by antisense CHS genes: promoter and minimal sequence requirements for the antisense effect.