The strawberry FaMYB1 transcription factor suppresses anthocyanin and flavonol accumulation in transgenic tobacco

Fruit ripening is characterized by dramatic changes in gene expression, enzymatic activities and metabolism. Although the process of ripening has been studied extensively, we still lack valuable information on how the numerous metabolic pathways are regulated and co-ordinated. In this paper we describe the characterization of FaMYB1, a ripening regulated strawberry gene member of the MYB family of transcription factors. Flowers of transgenic tobacco lines overexpressing FaMYB1 showed a severe reduction in pigmentation. A reduction in the level of cyanidin 3-rutinoside (an anthocyanin) and of quercetin-glycosides (flavonols) was observed. Expression of late flavonoid biosynthesis genes and their enzyme activities were adversely affected by FaMYB1 overexpression. Two-hybrid assays in yeast showed that FaMYB1 could interact with other known anthocyanin regulators, but it does not act as a transcriptional activator. Interestingly, the C-terminus of FaMYB1 contains the motif pdLNL(D)/(E)Lxi(G)/S. This motif is contained in a region recently proposed to be involved in the repression of transcription by AtMYB4, an Arabidopsis MYB protein. Our results suggest that FaMYB1 may play a key role in regulating the biosynthesis of anthocyanins and flavonols in strawberry. It may act to repress transcription in order to balance the levels of anthocyanin pigments produced at the latter stages of strawberry fruit maturation, and/or to regulate metabolite levels in various branches of the flavonoid biosynthetic pathway.

Transcriptional and posttranscriptional gene silencing are mechanistically related

Two distinct gene-silencing phenomena are observed in plants: transcriptional gene silencing (TGS), which involves decreased RNA synthesis because of promoter methylation, and posttranscriptional gene silencing (PTGS), which involves sequence-specific RNA degradation. PTGS is induced by deliberate [1-4] or fortuitous production (R.v.B., unpublished data) of double-stranded RNA (dsRNA). TGS could be the result of DNA pairing [5], but could also be the result of dsRNA, as was shown by the dsRNA-induced inactivation of a transgenic promoter [6]. Here, we show that when targeting flower pigmentation genes in Petunia, transgenes expressing dsRNA can induce PTGS when coding sequences are used and TGS when promoter sequences are taken. For both types of silencing, small RNA species are found, which are thought to be dsRNA decay products [7] and determine the sequence specificity of the silencing process [8, 9]. Furthermore, silencing is accompanied by the methylation of DNA sequences that are homologous to dsRNA. DNA methylation is assumed to be essential for regulating TGS and important for reinforcing PTGS [10]. Therefore, we conclude that TGS and PTGS are mechanistically related. In addition, we show that dsRNA-induced TGS provides an efficient tool to generate gene knockouts, because not only does the TGS of a PTGS-inducing transgene fully revert the PTGS phenotype, but also an endogenous gene can be transcriptionally silenced by dsRNA corresponding to its promoter.

anthocyanin1 of petunia encodes a basic helix-loop-helix protein that directly activates transcription of structural anthocyanin genes

The petunia loci anthocyanin1 (an1), an2, an4, and an11 are required for the transcription of anthocyanin biosynthetic genes in floral organs. The an2 and an11 loci were recently cloned and shown to encode a MYB-domain transcriptional activator and a cytosolic WD40 protein, respectively. Here, we report the isolation of an1 by transposon tagging. an1 encodes a new member of the basic helix-loop-helix family of transcription factors that is functionally and evolutionarily distinct from JAF13, the apparent petunia ortholog of maize RED1 and snapdragon DELILA. We provide genetic evidence that the transcription factors encoded by an1, an2, and an4 operate in an unexpectedly complex regulatory hierarchy. In leaves, ectopic expression of AN2 induces an1 expression, whereas in anthers, an1 expression depends on an4, encoding (or controlling) a MYB protein that is paralogous to AN2. Experiments with transgenic plants expressing a post-translationally controlled AN1-GLUCOCORTICOID RECEPTOR fusion protein indicated that independent of protein synthesis, AN1 directly activates the expression of the dfrA gene encoding the enzyme dihydroflavonol 4-reductase and of Pmyb27 encoding a MYB-domain protein of unknown function.

Role of inverted DNA repeats in transcriptional and post-transcriptional gene silencing

Transgenes and endogenous genes are sensitive to silencing, in particular when the genes are tandemly repeated. Their expression can be transcriptionally or post-transcriptionally repressed, or both. It is remarkable that very often, two or more genes or parts of the genes are arranged as inverted repeats (IR). Many of such IRs are dominant silencing loci. They can repress the expression of homologous genes elsewhere in the genome in trans which is usually associated with an increase in the level of DNA methylation. Trans-silencing has been explained by DNA-DNA pairing between a repetitive silencing locus and a homologous target locus. However, there is accumulating evidence that the trans effect might be mediated by dsRNA transcribed from the IR (trans)genes. Besides dsRNA-directed DNA methylation, dsRNA in plants as well as in other systems also induces the degradation of homologous RNAs and silence genes post-transcriptionally. These findings indicate that several features associated with gene silencing can be attributed to the activities of dsRNA, which would explain why inverted transgene repeats are such efficient silencing loci.

Distinct features of post-transcriptional gene silencing by antisense transgenes in single copy and inverted T-DNA repeat loci

The application of antisense transgenes in plants is a powerful tool to inhibit gene expression. The underlying mechanism of this inhibition is still poorly understood. High levels of antisense RNA (as-RNA) are expected to result in strong silencing but often there is no clear correlation between as-RNA levels and the degree of silencing. To obtain insight into these puzzling observations, we have analyzed several petunia transformants of which the pigmentation gene chalcone synthase (Chs) is post-transcriptionally silenced in corollas by antisense (as) Chs transgenes. The transformants were examined with respect to the steady-state as-RNA level, transcription level of the as-transgenes, the repetitiveness and structure of the integrated T-DNAs, and the methylation status of the transgenes. This revealed that the transformants can be divided in two classes: the first class contains a single copy (S) T-DNA of which the as-Chs gene is transcribed, although several-fold lower than the endogenous Chs genes. As there are not sufficient as-RNAs to degrade every mRNA, we speculate that silencing is induced by double-stranded RNA. The second class contains two T-DNAs which are arranged as inverted repeats (IRs). These IR loci are severely methylated and the as-Chs transgenes transcriptionally barely active. The strongest silencing was observed with IR loci in which the as-Chs transgenes were proximal to the centre of the IR. Similar features have been described for co-suppression by IRs composed of sense Chs transgenes, suggesting that silencing by antisense IRs also occurs by co-suppression, either via ectopic DNA pairing or via dsRNA.

Position-dependent methylation and transcriptional silencing of transgenes in inverted T-DNA repeats: implications for posttranscriptional silencing of homologous host genes in plants

Posttranscriptional silencing of chalcone synthase (Chs) genes in petunia transformants occurs by introducing T-DNAs that contain a promoter-driven or promoterless Chs transgene. With the constructs we used, silencing occurs only by T-DNA loci which are composed of two or more T-DNA copies that are arranged as inverted repeats (IRs). Since we are interested in the mechanism by which these IR loci induce silencing, we have analyzed different IR loci and nonsilencing single-copy (S) T-DNA loci with respect to the expression and methylation of the transgenes residing in these loci. We show that in an IR locus, the transgenes located proximal to the IR center are much more highly methylated than are the distal genes. A strong silencing locus composed of three inverted T-DNAs bearing promoterless Chs transgenes was methylated across the entire locus. The host Chs genes in untransformed plants were moderately methylated, and no change in methylation was detected when the genes were silenced. Run-on transcription assays showed that promoter-driven transgenes located proximal to the center of a particular IR are transcriptionally more repressed than are the distal genes of the same IR locus. Transcription of the promoterless Chs transgenes could not be detected. In the primary transformant, some of the IR loci were detected together with an unlinked S locus. We observed that the methylation and expression characteristics of the transgenes of these S loci were comparable to those of the partner IR loci, suggesting that there has been cross talk between the two types of loci. Despite the similar features, S loci are unable to induce silencing, indicating that the palindromic arrangement of the Chs transgenes in the IR loci is critical for silencing. Since transcriptionally silenced transgenes in IRs can trigger posttranscriptional silencing of the host genes, our data are most consistent with a model of silencing in which the transgenes physically interact with the homologous host gene(s). The interaction may alter epigenetic features other than methylation, thereby impairing the regular production of mRNA.

Analysis of bHLH and MYB domain proteins: species-specific regulatory differences are caused by divergent evolution of target anthocyanin genes

The regulatory anthocyanin loci, an1, an2, an4 and an11 of Petunia hybrida, and r and c1 from Zea mays, control transcription of different sets of target genes. Both an2 and c1 encode a MYB-type protein. This study reports the isolation of a P. hybrida gene, jaf13, encoding a basic helix-loop-helix protein that, on the basis of sequence homology and intron/exon structure, represents the P. hybrida orthologue of the Z. mays r genes. Ectopic expression of an2 and jaf13 is sufficient for activation of the dihydroflavonol 4-reductase-A (dfrA) promoter and enhanced pigment accumulation in P. hybrida. This indicates that an2 and jaf13 play a key role in determining the tissue-specific expression pattern of structural genes. However, because chalcone synthase (chs) and flavanone-3-hydroxylase (f3h) are not activated, the pattern of pigmentation is not fundamentally altered. Expression of an2 in Z. mays complements a mutation in pl, a c1 paralogue, indicating that an2 activates a wider set of target genes in this host. Transient expression assays in Z. mays and P. hybrida tissues showed that C1 and R or AN2 and JAF13 can activate the promoter of the c2 gene, encoding Z. mays CHS, but not the chsA promoter from P. hybrida. These results indicate that regulatory anthocyanin genes are conserved between species and that divergent evolution of the target gene promoters is responsible for the species-specific differences in regulatory networks.

Genetic control of dihydroflavonol 4-reductase gene expression in Petunia hybrida

The functions of four loci (An1, An2, An4, and An6) which control pigmentation in flowers of Petunia hybrida have been characterized. Linkage-analysis and molecular complementation experiments showed that the An6 locus contains the structural dfrA gene, encoding the enzyme dihydroflavonol 4-reductase (DFR). Analysis of gus gene expression driven by the dfrA promoter in transgenic plants showed that the dfrA promoter is highly active in the flower corolla, the anthers and seeds and, at a lower level, in ovules and the flower stem. These data are discussed in relation to the expression of other pigmentation genes and the accumulation pattern of anthocyanins. The expression of the drfA-gus transgene was dependent on the genes an1 (in every tissue), an2 (in the flower limb only) and an4(in anthers), demonstrating that these genes encode regulatory factors that control drfA promoter activity.

Conditional inhibition of beta-glucuronidase expression by antisense gene fragments in petunia protoplasts

Antisense RNA-mediated inhibition of gene expression is a valuable tool to induce mutant phenotypes. We are interested in the application of antisense gene fragments with the aim to improve the efficiency of inhibition and to be able to selectively suppress gene family members in plants. Protoplasts may provide a rapid system to screen the efficiency of antisense gene segments. As a first step, we set up a transient expression system for leaf protoplasts of Petunia hybrida and used as a model system the inhibition of beta-glucuronidase (uidA) expression by uidA antisense gene segments. Both GUS enzyme activities and uidA RNA levels were measured. Co-introducing equal amounts of a full-length uidA antisense gene and a uidA sense gene reduced GUS activity by 60-70%. Various uidA antisense fragments also inhibited expression although with different efficiencies and we show that strong antisense fragments can be retrieved from weak antisense gene fragments. A promoter-less antisense gene did not reduce uidA expression indicating that the inhibition is mediated by antisense transcripts. Using quantitative PCR on first-strand cDNA we show that expression of functional antisense genes lead to reduced levels of uidA mRNA. This suggests that the mechanism of antisense RNA inhibition in protoplasts is similar to that in transgenic plants and that the protoplast system in combination with PCR can be used to preselect antisense fragments of any gene.

The petunia homologue of the Antirrhinum majus candi and Zea mays A2 flavonoid genes; homology to flavanone 3-hydroxylase and ethylene-forming enzyme

The synthesis of anthocyanins in higher plants involves many enzymatic steps. Here we describe the isolation and characterization of a cDNA, ant17, which encodes a protein that has 73% amino acid sequence identity with the candi gene product of Antirrhinum majus and 48% with that of the maize a2 gene. This protein may therefore be involved in the synthesis of anthocyanins in the steps after the action of dihydroflavonol 4-reductase. This is consistent with the absence of ant17 expression in the regulatory anthocyanin mutants of petunia an1, an2 and an11. Furthermore, ant17 is predominantly expressed in corollas and anthers and is induced by gibberellic acid.

Establishment of hairy root cultures of Linum flavum producing the lignan 5-methoxypodophyllotoxin

Hairy root cultures were induced from leaf explants of Linum flavum by infection with Agrobacterium rhizogenes. The transformed nature of tissue was confirmed by the production of opines. The cultures produced 1.5 to 3.5% of the lignan 5-methoxypodophyllotoxin (5-MPT) on a dry weight basis, which was 2 to 5 times higher than the 5-MPT content in untransformed root cultures and 5 to 12 times higher than in L. flavum cell suspensions. The 5-MPT production as a function of time was up to four times higher than that in cell suspensions.

Flavonols stimulate development, germination, and tube growth of tobacco pollen

The effect of anther-derived substances on pollen function was studied using pollen produced by in vitro culture of immature pollen of tobacco (Nicotiana tabacum L.) and petunia (Petunia hybrida). Addition of conditioned medium consisting of diffusates from in situ matured pollen strongly increased pollen germination frequency and pollen tube growth, as well as seed set after in situ pollination. Thin-layer chromatography and depletion of phenolic substances by Dowex treatment indicated that flavonols are present in the diffusate and may be the active compounds. When added to the germination medium, flavonols (quercetin, kaempferol, myricetin) but not other flavonoids strongly promoted pollen germination frequency and pollen tube growth in vitro. The best results were obtained at very low concentrations of the flavonols (0.15-1.5 mum), indicating a signaling function. The same compounds were also effective when added during pollen development in vitro.

Differential expression of two MADS box genes in wild-type and mutant petunia flowers

We isolated and characterized two flower-specific genes from petunia. The protein products of these genes, designated floral binding protein 1 (FBP1) and 2 (FBP2), are putative transcription factors with the MADS box DNA binding domain. RNA gel blot analysis showed that the fbp1 gene is exclusively expressed in petals and stamen of petunia flowers. In contrast, the FBP1 protein was only detectable in petals and not in stamens, suggesting post-transcriptional regulation of the fbp1 gene in these tissues. The fbp2 gene is expressed in petals, stamen, carpels, and at a very low level in sepals but not in vegetative tissues. We analyzed the spatial expression of these fbp genes in floral organs of two homeotic flower mutants. In the blind mutant, whose flower limbs are transformed into antheroid structures on top of normal tubes, identical expression levels of both genes were observed in the antheroid structures as in normal anthers. In the homeotic mutant green petals, the petals are replaced by sepaloid organs in which the expression of fbp1 is strongly reduced but not completely abolished. Our results suggest a regulation of the fbp1 gene expression by the green petals (gp) gene. Expression of the fbp2 gene was not affected in the green petals mutant. In contrast to the proposed models describing floral morphogenesis, our data indicated that homeotic genes can be functional in one whorl only.

Transactivation of Ds by Ac-transposase gene fusions in tobacco

To study regulation of the (Ds) transposition process in heterologous plant species, the transposase gene of Ac was fused to several promoters that are active late during plant development. These promoters are the flower-specific chalcone synthase A promoter (CHS A), the anther-specific chalcone isomerase B promoter CHI B and the pollen-specific chalcone isomerase A2 promoter CHI A2. The modified transposase genes were introduced into a tobacco tester plant. This plant contains Ds stably inserted within the leader sequence of the hygromycin resistance (HPT II) gene. As confirmed with positive control elements, excision of Ds leads to the restoration of a functional HPT II gene and to a hygromycin resistant phenotype. No hygromycin resistance was observed in negative control experiments with Ac derivatives lacking 5' regulatory sequences. Although transactivation of Ds was observed after the introduction of transposase gene fusions in calli, excision in regenerated plants was observed only for the CHS A- or CHI B-transposase gene fusions. With these modified transposase genes, somatic excision frequencies were increased (68%) and decreased (22%), respectively, compared to the situation with the Ac element itself (38%). The shifts in transactivation frequencies were not associated with significant differences in the frequencies of germinally transmitted excision events (approximately 5%). The relative somatic stability of Ds insertions bearing the CHI B-transposase gene fusion suggests the usefulness of this activator element for transposon tagging experiments.

Gibberellic Acid Regulates Chalcone Synthase Gene Transcription in the Corolla of Petunia hybrida

The pigmentation of Petunia hybrida corollas is regulated by gibberellic acid (GA(3)). It controls the increase of flavonoid enzyme levels and their corresponding mRNAs. We have used an in vitro culture system for corollas to study the regulatory role of GA(3) in the expression of flavonoid genes. By determining steady-state mRNA levels, we show that the accumulation of chalcone synthase (chs) mRNA in young corollas is dependent on the presence of both sucrose and GA(3) in the culture medium. Whereas sucrose had a general metabolic effect on gene expression, the stimulatory role of GA(3) was specific. Analysis of nascent transcripts in isolated corolla nuclei showed that changes in steady-state chs mRNA levels correlated very well with changes in the transcription rate. We therefore conclude that GA(3) controls the expression of chs at the transcriptional level. Preculturing the corollas in sucrose medium without GA(3) resulted in a lower chs mRNA level. The expression could be reinduced by the addition of GA(3). The hormone is thus required for the induction but also for the maintenance of chs transcription. The delayed reinduction of chs expression, the lag time in the kinetics of chs mRNA accumulation, and the inhibitory effect of cycloheximide on the action of GA(3) suggest that GA(3) controls chs transcription in an indirect manner. Our data support a model in which GA(3) induces the production of a regulatory protein such as a receptor or a trans-acting factor that is directly involved in chs transcription.

Regulation and manipulation of flavonoid gene expression in anthers of petunia: the molecular basis of the Po mutation

Molecular mechanisms governing development of the male reproductive organs of flowers, the anthers, are largely unknown. In this article, we report on the investigation of the molecular basis of a mutation involving the expression of a gene encoding the flavonoid biosynthesis enzyme chalcone flavanone isomerase (CHI) in anthers of petunia. In petunia, the gene Po regulates the expression of CHI in anthers: PoPo petunia lines contain CHI enzyme activity in petals and anthers, whereas popo lines contain the CHI enzyme only in petals but not in anthers. As a result of the Po mutation, the substrate of CHI accumulates and therefore the pollen of a popo line are yellow or greenish. The genome of petunia contains two chi genes, chiA and chiB. In a restriction fragment length polymorphism analysis, a 100% linkage was observed between Po and chiA. This result suggested that Po is identical to chiA and that Po is not a regulatory gene of chiA. Introduction of a chiA gene isolated from a PoPo line into a popo line resulted in a complementation of the mutation that was directly visible because the pollen color shifted from yellow to white. This proved that chiA and Po are identical. Because chiA encodes a functional CHI enzyme in flower petals of a popo line, we propose that the Po mutation is a mutation in the regulatory region of chiA abolishing chiA promoter activity in anthers but not in corollas. This change in anther color is a fine illustration of how floral pigmentation can be manipulated in a predictable way and suggests the use of CHI as a visible marker.

Stamens and Gibberellic Acid in the Regulation of Flavonoid Gene Expression in the Corolla of Petunia hybrida

Stamen removal at an early stage of flower development inhibits anthocyanin synthesis and chalcone flavanon isomerase (CHI) enzyme activity in corollas of Petunia hybrida. The inhibition can be overcome by gibberellic acid (GA(3)) application. Gibberellin also induces anthocyanin synthesis in detached, young green corollas, grown in vitro in a sucrose medium and promotes CHI enzyme activity. Western blot analysis indicates an increase in chalcone synthase (CHS) and CHI protein levels following GA(3) treatment in both the in vivo and the in vitro systems. Northern blot analysis shows a higher level of steady-state mRNAs for CHS and CHI 24 hours after GA(3) application. In corollas from a transgenic plant containing a beta-glucuronidase gene driven by a CHI promoter, a sixfold increase of beta-glucuronidase activity was measured following GA(3) application. The mode of action of stamens and GA(3) control over flavonoid gene expression is discussed.

Regulation of plant gene expression by antisense RNA

Regulation of gene expression by antisense RNA was first discovered as a naturally-occurring phenomenon in bacteria. Recently natural antisense RNAs have been found in a variety of eukaryotic organisms; their in vivo function is, however, obscure. Deliberate expression of antisense RNA in animal and plant systems has lead to successful down-regulation of specific genes. We will review the current status of antisense gene action in plant systems. The recent discovery that 'sense' genes are able to mimic the action of antisense genes indicates that (anti)sense genes must operate by mechanisms other than RNA-RNA interaction.

Pollen- and anther-specific chi promoters from petunia: tandem promoter regulation of the chiA gene

We have analyzed the spatial and temporal activities of chalcone flavanone isomerase (chi) A and B gene promoters from petunia. To study the tandem promoter regulation of chiA, various chiA promoter fragments were fused with the beta-glucuronidase (GUS) reporter gene. Analysis of transgenic plants containing these chimeric genes provided definitive proof that the chiA coding region is regulated by two distinct promoters (designated PA1 and PA2). We also showed that both promoters can function independently and that the chiA PA1 promoter is expressed in limb (epidermal and parenchyma cells), tube (inner epidermal and parenchyma cells), seed (seed coat, endosperm, and embryo), sepal, leaf, and stem. The use of chiA and chiB promoters in the regulation of anther- and pollen-specific gene expression has been studied. By analyzing transgenic plants containing chimeric genes consisting of chiA and B promoter fragments and the GUS reporter gene, we were able to identify a 0.44-kilobase chiA PA2 promoter fragment that drives pollen-specific gene expression and a 1.75-kilobase chiB PB promoter fragment that confers anther-specific (pollen and tapetum cells) expression to the GUS gene.

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

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

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.

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

Chalcone synthase-encoding genes (chs) in Petunia hybrida comprise a multigene family. Some of the chs genes have been grouped into a subfamily, based upon their strong cross-hybridization and tight genomic linkage. From genomic libraries eight 'complete' chs genes, two chs gene 5'-fragments and two chs gene 3'-fragments have been isolated. The nucleotide sequence of six complete chs genes is presented and discussed in relation to their evolutionary origin and expression in different tissues. Each member of the family consists of two exons separated by an intron of variable size and sequence, which is located at a conserved position. The chs gene fragments represent single exons. Homology between non-linked chs genes is approx. 80% at the DNA level and restricted to protein-coding sequences. Homology between subfamily members (which are tightly linked) is higher (90-99%) and extends into untranslated regions of the gene, strengthening the view that they arose by recent gene duplications. The chsD gene contains a mutated translation stop codon, suggesting that this is an inactive (pseudo)gene. None of the other members of the gene family exhibits characteristics of a pseudogene, indicating that if gene inactivation has occurred during their evolution, it must characteristics of a pseudogene, indicating that if gene inactivation has occurred during their evolution, it must have been a recent event. Homology at the protein level between some (expressed) chs genes is surprisingly low. The possibility that these genes encode proteins with slightly different enzymatic activities is discussed.

Regulation of chalcone flavanone isomerase (CHI) gene expression inPetunia hybrida: the use of alternative promoters in corolla, anthers and pollen

In this paper we report on the organization and expression of the two chalcone flavanone isomerase (CHI) genes A and B from thePetunia hybrida inbred line V30. From a combination of sequence data, primer extension and RNAse protection experiments we infer the presence of two promoters PA1 and PA2 upstream of the CHI gene A coding region. It is shown that both promoters are used differentially in various flower tissues: the PA1 promoter is active in corolla and tube tissue whereas the PA2 promoter, which gives rise to a 437 bp longer transcript, is only active in late stages of anther development and more specifically in pollen grains. The CHI-B gene, on the other hand, has only one promoter (PB) which is active only in immature anther tissue. Thus, in addition to the use of two alternative promoters in front of the same CHI coding region (CHI-A), the promoters in front of the two distinct CHI gene copies are also used differentially as a mechanism to regulate their expression. Comparison of PB with other flavonoid gene promoters active in immature anther tissue revealed a highly conserved region which was designated as 'anther box'. We hypothesize that it plays a regulatory role in anther-specific gene expression. Finally, a model describing the evolutionary relationship between both CHI genes is presented.

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

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.

Antisense genes in plants: an overview

Plants are the first multicellular higher eukaryotic organisms in which artificial antisense genes have been shown to down-regulate target gene expression. Manipulations with an antisense gene can serve as a tool to study the effect of a particular plant gene inactivation, the interaction of gene products whose genes are coordinately expressed, or the functional analysis of cryptic genes. Transgenic plants harbouring an antisense gene already gave rise to patentable new characteristics, showing that the technique has great scientific and economic value.

The chalcone synthase multigene family of Petunia hybrida (V30): sequence homology, chromosomal localization and evolutionary aspects

Chalcone synthase (CHS) genes in Petunia hybrida comprise a multigene family containing at least 7 complete members in the strain Violet 30 (V30). Based on a high sequence homology in both coding and non-coding sequence, a number of CHS genes can be placed into two subfamilies. By restriction fragment length polymorphism (RFLP) analysis it was shown that both chromosomes II and V carry one of these subfamilies, in addition to the other CHS genes identified so far. Members of a subfamily were found to be closely linked genetically. Analysis of the Petunia species that contributed to the hybrid nature of P. hybrida (P. axillaris, P. parodii, P. inflata and P. violacea) shows that none of the CHS gene clusters is specific for either one of the parents and therefore did not arise as a consequence of the hybridization. The number of CHS genes within a subfamily varies considerably among these Petunia species. From this we infer that the CHS subfamilies arose from very recent gene duplications.

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

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.

A novel purification procedure for chalcone flavanone isomerase from Petunia hybrida and the use of its antibodies to characterize the Po mutation

We have purified chalcone flavanone isomerase (CHI) from flowerbuds of Petunia hybrida to high purity. We made use of an affinity matrix consisting of Sepharose-bound Dextran Blue that is known to bind proteins containing the dinucleotide fold [S. T. Thompson, K. H. Cass, and E. Stellwagen (1975) Proc. Natl. Acad. Sci. USA 72, 669-672]. The final step, consisting of preparative elution from a denaturing acrylamide gel, yielded an approximately 2000-fold purified CHI protein. The enzyme is a single polypeptide with Mr = 29,000, and highly specific antiserum was raised against it. Using this antiserum it was shown that corolla and anther tissues express different forms of the enzyme as judged by pI. Furthermore, the absence of immunoreactive CHI was demonstrated in a mutant of P. hybrida (genotype popo) which accumulates 2',4,4',6'-tetrahydroxy-chalcone in anthers as a consequence of lack of enzyme activity.

The chalcone synthase multigene family of Petunia hybrida (V30): sequence homology, chromosomal localization and evolutionary aspects

Chalcone synthase (CHS) genes in Petunia hybrida comprise a multigene family containing at least 7 complete members in the strain Violet 30 (V30). Based on a high sequence homology in both coding and non-coding sequence, a number of CHS genes can be placed into two subfamilies. By restriction fragment length polymorphism (RFLP) analysis it was shown that both chromosomes II and V carry one of these subfamilies, in addition to the other CHS genes identified so far. Members of a subfamily were found to be closely linked genetically. Analysis of the Petunia species that contributed to the hybrid nature of P. hybrida (P. axillaris, P. parodii, P. inflata and P. violacea) shows that none of the CHS gene clusters is specific for either one of the parents and therefore did not arise as a consequence of the hybridization. The number of CHS genes within a subfamily varies considerably among these Petunia species. From this we infer that the CHS subfamilies arose from very recent gene duplications.

Floral tissue of Petunia hybrida (V30) expresses only one member of the chalcone synthase multigene family

Twenty independent, petal-specific chalcone synthase (CHS) cDNA clones have been isolated from Petunia hybrida variety Violet 30 (V30). Sequence analysis shows that the largest of these clones contains the entire coding sequence. Using this clone in Southern blot analysis reveals the presence of multiple CHS gene copies in the genome of Petunia hybrida V30. Hybridization and sequence analysis of the CHS cDNA clones shows that they are all copied from a single mRNA species. This indicates the presence of only one transcriptionally active CHS gene in petals. Finally we report the identification, cloning and partial characterization of this gene.

Isolation and physicochemical characterization of mitochondrial DNA from cultured cells ofPetunia hybrida

Mitochondrial DNA ofPetunia hybrida was purified from cell suspension cultures. Up to 50% of the DNA could be isolated as supercoiled DNA molecules by CsCl-ethidium bromide density gradient centrifugation. The DNA purified from DNase-treated mitochondria bands at a single buoyant density of 1.760 gcm(-3) in neutral density gradients and runs on agarose gels as a single band with an apparent molecular weight exceeding 30 megadaltons (Md). Summing of the restriction endonuclease fragment lengths indicates a mitochondrial genome size of at least 190 Md. Electron microscopic analysis reveals the presence of a heterogeneous population of circular DNA molecules, up to 60 Md in size. Small circular DNA molecules, ranging in size from 2-30 Md are present, but unlike in cultured cells of other plant species they do not form discrete size classes and furthermore, they constitute less than 5% of the total DNA content of the mitochondria. The restriction endonuclease patterns of mitochondrial DNA do not qualitatively alter upon prolonged culture periods (up to at least two years).

The induction of myeloid leukaemias by Rauscher murine leukaemia virus

A number of cloned viral preparations isolated from Rauscher virus-producing JLS-V5 cells were compared in their competence to induce different types of leukaemias. All preparations were able to induce myeloid leukaemias, but the induction of lymphatic or erythroid leukaemias was also observed. Serial infection of newborn mice with either cell-free extracts or serum from animals suffering from a myeloid leukaemia did not result in the occurrence of relatively more myeloid leukaemias nor did the infection with virus harvested from ascites fluid of permanent myeloid cell lines. It appears that the mechanism by which myeloid leukaemias are induced is not virus-specific.

Plastid gene expression in a yellow-green leaf mutant of Petunia hybrida

We have analyzed the morphology and gene expression in plastids of a yellow-green leaf mutant of Petunia hybrida (E 5059). Under normal light intensities (20,000 lx), yellow-green leaves develop with a typical proplastid morphology (few membranes, incomplete stacking). When such plants are grown under low light intensities (3,000 lx), the newly formed leaves are green. The plastids in these green leaves have a wild-type like chloroplast morphology (thylakoids and grana structure). Pre-existing green leaves remain green in 20,000 lx, indicating that chlorophyll is not degraded. An analysis of polypeptides synthesized in isolated plastids from the yellow-green and green leaves of this mutant plant shows several differences. In the yellow-green leaf plastids only a very small amount of the large subunit of ribulose-1,5-bisphosphate carboxylase (RuBPCase) is present, while in green plastids this polypeptide is present in much higher amounts. Hybridization experiments indicated that in plastids from the yellow-green leaves the mRNA coding for the large subunit polypeptide is present in much lower amounts than in plastids from the 3,000 lx green leaves of this mutant or in chloroplasts from wild type plants. These results indicate regulation at the mRNA level. Furthermore, in yellow-green leaf plastids eleven polypeptides are present with high molecular wieght (higher than 67,000 d). Five of them are synthesized by the yellow-green leaf plastid itself. Such high molecular weight polypeptides are also synthesized by proplastids isolated from white petunia cell suspension cultures, but are not synthesized by 3,000 lx green leaf plastids, or by isolated normal leaf chloroplasts. These results indicate that the synthesis of these polypeptides is specific for the proplastid stage of chloroplast biogenesis.

Rauscher spleen focus-forming virus: biological properties and relationship to helper viruses

A Rauscher virus (RV)-transformed erythroid cell line, RA-1, was shown to be a non-producer cell line. RA-1 cells express not only gp51-54 env-related glycoprotein, but also gp70, which is more closely related to gp51-54 coded by a recombinant env gene than to the MuLV-R gp70. RA-1 cells could be infected by Friend, Moloney and Gross viruses, but not by the homologous Rauscher murine leukaemia virus. Rescue of spleen focus-forming activity was obtained on infection of these cells with MuLV-F or MuLV-Mol, but not with MuLV-Gross. The RNA of the RV complex resembles closely that of Friend virus (FV). It contains a 32S, presumably defective, genome, which most likely is responsible for spleen focus formation, and a 35S helper virus genome. Oligonucleotide fingerprint data suggest that RV has evolved independently of FV. Erythroid early BFU-E cells of mice infected with RV of Friend helper virus-infected RA-1 cells were shown to require no addition of conditioned medium to form large erythroid colonies (BFU-E) in the presence of only small amounts of erythropoietin.

The relationship between genomic RNAs of polycythaemic forms of spleen focus-forming Friend virus and its helper virus

We have studied the relationship between Friend spleen focus-forming virus (SFFV) and its helper lymphoid leukaemia virus (LLV) by comparing RNase T1 fingerprints of genomic RNAs. Our data indicate that about 70% of the SFFV sequence is a perfect copy of parts of the helper genome. We conclude that our SFFV and LLV isolates have co-evolved very closely and that SFFV-specific sequences are not identical in different Friend virus isolates.

A conserved and unique (AT)-rich segment in yeast mitochondrial DNA

The mtDNA of the cytoplasmic petite mutant of yeast RD1A consists mainly of a perfect head-to-tail repetition of a known sequence of 66 consecutive AT and 2 GC base pairs. We have hybridized complementary RNA made on RD1A mtDNA with the mtDNAs of four different wild-type Saccharomyces strains that differ markedly in restriction fragmentation pattern. The tm's of the four heteroduplexes are identical to the tm of the homoduplex of RD1A mtDNA with complementary RNA of one repeat length. With all four wild-type mtDNAs this complementary RNA hybridizes mainly to a single restriction fragment of about 300 base pairs. This shows the conservation and individuality of at least one (AT)-rich segment in yeast mtDNA. The 300 base pair fragment has been mapped in the vicinity of the oxi-2 locus. The possible role of the (AT)-rich segment in the processing of the primary transcript of this region is discussed.

The presence of (dA.dT)20-25 tracts in the DNA of primitive eukaryotes

Previous work by Jacobson et al. (1) has shown that the number and distribution of (dA.dT)25 tracts in the nuclear DNA of the slime mold Dictyostelium discoideum reflects the number and the distribution of transcriptional units. To investigate whether this is a general phenomenon we compared the nuclear DNAs of other primitive eukaryotes with respect to their content of large (dA.dT)n tracts via the thermal stability of their hybrids with poly(rA). The results of our analysis indicate that all nuclear DNAs tested have (dA.dT)20-25 tracts, but the frequency of such tracts varies from one per 5.4 X 10(6) daltons in Dictyostelium nuclear DNA to one per 2.8 X 10(8) daltons in Crithidia luciliae nuclear DNA. We conclude that the presence of (dA.dT)20-25 tracts is not an obligatory characteristic of the transcriptional unit in primitive eukaryotes. Chromatography of native DNAs on poly(rU) Sephadex columns shows that the large (dA.dT)n tracts occurring in the genomes of both primitive and higher eukaryotes are widely distributed throught these genomes.

The binding of poly(rA) and poly(rU) to denatured DNA. I. Model studies with homopolymers

We have compared the properties of the poly(rA).oligo(dT) complex with those of the poly(rU).oligo(dA)n complex. Three main differences were found. First, poly(rA) and oligo(dT)n do not form a complex in concentrations of CsCl exceeding 2 M because the poly(rA) is insoluble in high salt. If the complex is made in low salt, it is destabilized if the CsCl concentration is raised. Complexes between poly(rU) and oligo(dA)n, on the other hand, can be formed in CsCl concentrations up to 6.6 M. Second, complexes between poly(rA) and oligo(dT)n are more rapidly destabilized with decreasing chain length than complexes between poly(rU) and oligo(dA)n. Third, the density of the complex between poly(rA) and poly(dT) in CsCl is slightly lower than that of poly(dT), whereas the density of the complex between poly(rU) and poly(dA) in CsCl is at least 300 g/cm3 higher than that of poly(dA). These results explain why denatured natural DNAs that bind poly(rU) in a CsCl gradient usually do not bind poly(rA).

The binding of poly (rA) and poly (rU) to denatured DNA. II. Studies with natural DNAs

We have studied the interaction of poly(rA) and poly(rU) with natural DNAs containing (dA.dT)n sequences. The results indicate that hybridization of poly(rA) to denatured DNA can be used to estimate the size and frequency of large (dA.dT)n tracts, whereas hybridization with poly(rU) does not give reliable information on these points. In 6.6 M CsCl, poly(rU) can form stable complexes with denatured DNA containing short (dA)n tracts (n less than or equal to 6), whereas binding of poly(rA) to denatured DNA under these conditions requires much larger (dT)n tracts (estimated n greater than 13). Moreover, binding of poly(rA) requires pre-hybridization in low salt, because free poly(rA) precipitates in 6.6 M CsCl.