Provocation of mutability in the level of mutation expressed at the pal-rec gene in Antirrhinum majus

Summary The pallida gene of Antirrhinum majus governs anthocyanin production. The nature of the mutability displayed by its unstable allele pal-rec was dramatically altered following crosses between two pal-rec pal-rec lines with certain separately maintained lines. In both cases a minority of progeny in F₁ or F₂ revealed unprecedented infrequent mutability termed Low mutability. These Low plants and their sibs showed many areas of contrasting mutability superimposed on their initial mutability level. This frequent shifting and Low mutability persisted through several generations of offspring obtained by both selfing and crossing to a non-mutable tester line. Evidence is presented to suggest a hypothesis that the two features of altered mutability are two aspects of the same phenomenon caused by joint action of two independent factors J and k, one contributed by each parental line at the outcross.A separate gene, eosinea, governs anthocyanin type, eos eos plants having pelargonin in place of wild-type magenta cyanin. In addition to the previously known simple depression of pal-rec to Pal mutation frequency in eos eos plants, eos also influences the action of J and k when heterozygous (i.e. Eos eos), thus contributing a basal and a third tier of control influencing mutability of pal-rec.Three levels of control are thus identified, the middle tier being governed by the partnership of J and k producing not a simple change but a complex mutability of mutability.     

TheSfm system of gene control inAntirrhinum majus

InAntirrhinum majus,pal-rec, an allele of thepallida series, is considered to be involved in anthocyanin production. Thepal-rec gene normally mutates autonomously from the recessive condition to the dominant giving fully pigmentedPal spots on a colorless background. TheSfm element, when inserted at thepal locus, destabilizes the activity of thepal-rec gene in such a way that the repressor (Sf) component abolishes gene activity in almost all of the cell lineages, whereas the mutator (m) acts to release full gene expression in some of the cells. Such a flip-flop control of thepal-rec results in what is known as shifting.     

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.     

Dominance relationships between alleles at the pallida locus in Antirrhinum majus

Flowers of the snapdragon, Antirrhinum majus, carrying various alleles at the pallida locus were examined for anthocyanin intensity. All the alleles were found to exert an effect in all combinations, with varying degrees of dominance.     

Comparison of genetic behaviour of the transposable element Tam3 at two unlinked pigment loci in Antirrhinum majus

Summary In Antirrhinum majus the transposable element Tam3 has been described at two unlinked loci pallida and nivea, both of which are required for the production of anthocyanin pigment in flowers. In each case the element is inserted in the promoter region and gives a variegated phenotype. We show that the rate of Tam3 excision at both loci is greatly affected by temperature, being approximately 1000-fold higher at 15°C compared with 25°C. Tam3 is also controlled by an unlinked gene Stabiliser, which considerably reduces excision rate. We show that the high degree of sensitivity to temperature and Stabiliser is an intrinsic property of Tam3 which is not shared by an unrelated element, Tam1. The Tam3 insertion at nivea gives rise to a series of alleles which confer reduced pigmentation, novel spatial patterns and changed instability. These are probably a result of imprecise excision and rearrangements of the Tam3 element.     

The paramutagenic line niv-44 has a 5 kb insert, Tam 2, in the chalcone synthase gene of Antirrhinum majus

Summary Several alleles of the nivea locus of Antirrhinum majus, both stable and unstable, have been characterised genetically (Harrison and Carpenter 1973 a, b). In this work the niv-44 allele is characterised at the molecular level. It contains a 5kb insertion element, Tam 2, which has 14 base pair inverted repeats. There is a three base pair duplication at the target site, which is at the first intron-exon boundary of the chalcone synthase gene. Tam 2 homologous sequences are present in multiple copies in several A. majus lines, including niv-53, and most have at least a 2.9 kb sequence in common with the copy at the chalcone synthase gene. Possible reasons for the apparent stability of the niv-44 allele and molecular explanations for the role of this allele in paramutation in A. majus are discussed.Dedicated to Professor Georg Melchers to celebrate his 50-year association with the journal     

A molecular recombination map of <Emphasis Type="Italic">Antirrhinum majus</Emphasis>

Background  

Genetic recombination maps provide important frameworks for comparative genomics, identifying gene functions, assembling genome sequences and for breeding. The molecular recombination map currently available for the model eudicot Antirrhinum majus is the result of a cross with Antirrhinum molle, limiting its usefulness within A. majus.     

De novo activation of the transposable element Tam2 of Antirrhinum majus

Summary The nivea locus of Antirrhinum majus encodes the enzyme chalcone synthase required for the synthesis of red anthocyanin pigment. The stable allele niv-44 contains an insertion in the nivea gene (Tam2) which has all the structural features of a transposable element. We have shown that this insertion can excise from the nivea locus when niv-44 is combined with another allele (niv-99) in a heterozygote. Activation of Tam2 excision is caused by a factor tightly linked to the niv-99 allele and may be due to complementation between Tam2 and a related element, Tam1. Factors which repress the excision of Tam2 and Tam1 are also described. Repression is not inherited in a simple mendelian way. Many stable mutations may be due to the insertion of transposable elements. Our data suggest that their stability may be due to the absence in the genome of activating factors and to the presence of repressors.     

Low Diversity and Divergence in the fil1 Gene Family of Antirrhinum (Scrophulariaceae)

Detailed nucleotide diversity studies revealed that the fil1 gene of Antirrhinum, which has been reported to be single copy, is a member of a gene family composed of at least five genes. In four Antirrhinum majus populations with different mating systems and one A. graniticum population, diversity within populations is very low. Divergence among Antirrhinum species and between Antirrhinum and Digitalis is also low. For three of these genes we also obtained sequences from a more divergent member of the Scrophulariaceae, Verbascum nigrum. Compared with Antirrhinum, little divergence is again observed. These results, together with similar data obtained previously for five cycloidea genes, suggest either that these gene families (or the Antirrhinum genome) are unusually constrained or that there is a low rate of substitution in these lineages. Using a sample of 52 genes, based on two measures of codon usage (ENC and GC3 content), we show that cyc and fil1 are among the least biased Antirrhinum genes, so that their low diversity is not due to extreme codon bias. Received: 20 June 2000 / Accepted: 25 October 2000     

Flavanones and dihydroflavonols as biosynthetic intermediates in Matthiola incana

In anthocyanin-producing flowers of Matthiola incana, the presence of naringenin, naringenin 7-glucoside, dihydrokaempferol and dihydrokaempferol 7-glucoside could be demonstrated. The four isolated compounds initiated anthocyanin synthesis after administration to acyanic flowers of genetically defined lines of Matthiola incana and Antirrhinum majus. Therefore, these compounds cannot be regarded as end-products but rather as intermediates in anthocyanin biosynthesis. Furthermore, naringenin 7-glucoside and dihydrokaempferol 7-glucoside most probably act as a pool for their aglycones, which serve as the actual substrates.     

An improved protocol for<Emphasis Type="Italic"> Agrobacterium</Emphasis>-mediated transformation of<Emphasis Type="Italic"> Antirrhinum majus</Emphasis> L.

Efficient Agrobacterium -mediated transformation of Antirrhinum majus L. was achieved via indirect shoot organogenesis from hypocotyl explants of seedlings. Stable transformants were obtained by inoculating explants with A. tumefaciens strain GV2260 harboring the binary vector pBIGFP121, which contains the neomycin phosphotransferase gene (NPT II) as a selectable marker and the gene for the Green Fluorescent Protein (GFP) as a visual marker. Putative transformants were identified by selection for kanamycin resistance and by examining the shoots using fluorescence microscopy. PCR and Southern analyses confirmed integration of the GFP gene into the genomes of the transformants. The transformants had a morphologically normal phenotype. The transgene was shown to be inherited in a Mendelian manner. This improved method requires only a small number of seeds for explant preparation, and three changes of medium; the overall transformation efficiency achieved, based on the recovery of transformed plants after 4–5 months of culture, reached 8–9%. This success rate makes the protocol very useful for producing transgenic A. majus plants.Communicated by G. Jürgens     

Trans-activation of an artificial dTam3 transposable element in transgenic tobacco plants

In Antirrhinum majus only autonomous Tam3 transposons have been characterized. We investigated whether an artificial dTam3 element, with a deletion in the presumptive transposase coding region, can be trans-activated in tobacco by an activator Tam3 element, which was immobilized by the deletion of one inverted repeat. A phenotypic assay based on restored hygromycin resistance demonstrates that a dTam3 element harbouring a bacterial plasmid can be trans-activated with a low frequency. Molecular analysis confirms that the dTam3 element has been excised from the HPTII marker gene. Reintegration of the dTam3 element into the tobacco genome is detected only in one out of six hygromycin-resistant plants analysed. PCR analysis of empty donor sites shows that excision of the dTam3 element in tobacco results in rearrangements (deletions and additions), that have been shown to be characteristic of Tam3 excision in the original host Antirrhinum majus. This trans-activation assay allowed us to establish that, in contrast to what has been detected in Antirrhinum majus, a periodical temperature shift down to 15°C does not enhance dTam3 transposition in regenerating tobacco calli.     

Mutagenesis of a race-specific rust resistance gene in Antirrhinum majus using a transposon-tagging protocol

In a transposon tagging experiment, lines of Antirrhinum majus exhibiting both race-specific resistance (homozygous for the dominant R gene) to the rust pathogen Puccinia antirrhini and a high frequency of transposition were crossed with homozygous susceptible lines. From a screen of 11153 F₁ progeny, 15 individuals were detected showing susceptibility to rust race α. Six of these exhibited a susceptibility phenotype (classified as type B) not previously observed. A control experiment involving the same tagging strategy but employing lines that do not exhibit high rates of transposition did not yield any susceptible mutants from a screen of 6243 progeny. In experiments on the heritability and stability of the mutation, the six plants exhibiting susceptibility phenotype B produced progeny in which the R locus had reverted to an active form (i.e. some of the progeny were resistant), a classic characteristic of transposon-tagged plant genes. Reversion was shown to occur somatically, and its rate was temperature dependent. Inheritance studies showed that the mutations in two of the susceptible plants from the tagging protocol map at, or very close to, the race α-specific resistance gene. The results are consistent with the transposon tagging of a race-specific gene for rust resistance.     

Cloning and analysis of two genes for chalcone synthase from Petunia hybrida

Summary With the help of a cDNA probe for a chalcone synthase gene of Petroselinum a cDNA clone for a chalcone synthase gene of Petunia hybrida could be identified. The homologous cDNA allowed the cloning of two genomic EcoRI fragments from Petunia hybrida containing complete chalcone synthase genes. It could be demonstrated that the genes on the two fragments are different and are not allelic but members of a gene family. The two genes are found in a variety of different Petunia lines including in the two conditional mutants affected in chalcone synthase expression in floral buds, White Joy and Red Star. The structure of the two chs genes from Petunia is compared to the chs gene from Antirrhinum majus.Dedicated to Professor Georg Melchers to celebrate his 50-year association with the journal     

Multiplication of Antirrhinum majus L. by shoot-tip culture

Nine varieties of Antirrhinum majus L. have been used in a study of in vitro multiplication of plants using shoot-tip culture. Acceptable multiplication rates were obtained in several media with only variety Victory showing significantly lower rates of shoot production. Wounded shoots of this variety produced callus in the absence of added auxin and some of this callus produced prolific roots.     

The homeotic Macho mutant of Antirrhinum majus reverts to wild-type or mutates to the homeotic plena phenotype

Plants of Antirrhinum majus carrying the semidominant Macho alleles of the plena gene display carpelloid sepals and staminoid petals, but the two inner flower whorls of stamens and carpels are normal and produce fertile gametes. In the recessive plena mutant, in contrast, the two outer whorls are normal whereas the stamens are largely or entirely petaloid and the carpels sepaloid, thus producing weakly male-fertile or fully sterile lines. Two new plena and two new Macho alleles have been induced in transposon tagging experiments. Genetic and molecular analysis revealed that the two contrasting mutant phenotypes are caused by mutations in one and the same gene: Several wild-type plants appeared among 27 000 F1 plants of a cross between Macho female plants and wild-type males bearing the active transposons Taml and Tam3. One of these plants segregated plena mutants, three showed reversions to wild-type and another two segregated Macho plants, possibly representing somatic reversions. Additional evidence was provided by an allelism test of Macho × plena. Molecular analysis has independently corroborated the genetical results. Moreover, the double mutant Macho/deficiens shows only carpels and plena/deficiens only sepals, which is in accord with combinatorial models for homeotic flower formation presented recently.     

The transposable element Tam1 of Antirrhinum majus is 17 kb long

Summary The nivea locus of Antirrhinum majus encodes chalcone synthase, a key enzyme in anthocyanin biosynthesis. Genetic instability is known to occur at this locus. In vitro cloning and characterization of genomic DNA fragments from the unstable nivea-recurrens allele T53 revealed that the instability of nivea-recurrens is due to the presence of a 17 kb DNA insert in the nivea locus. Somatic instability leading to the variegated phenotype, i.e. highly spotted flowers, is due to frequent excision of the 17 kb Tam1 element (Transposon antirrhinum majus) during development of the plant. Excision of Tam1 is not tissue specific, but occurs with similar frequencies in leaves and blossoms.