Iris Heidmann scite author profile

Somatic embryogenesis is an example of induced cellular totipotency, where embryos develop from vegetative cells rather than from gamete fusion. Somatic embryogenesis can be induced in vitro by exposing explants to growth regulators and/or stress treatments. The BABY BOOM (BBM) and LEAFY COTYLEDON1 (LEC1) and LEC2 transcription factors are key regulators of plant cell totipotency, as ectopic overexpression of either transcription factor induces somatic embryo formation from Arabidopsis (Arabidopsis thaliana) seedlings without exogenous growth regulators or stress treatments. Although LEC and BBM proteins regulate the same developmental process, it is not known whether they function in the same molecular pathway. We show that BBM transcriptionally regulates LEC1 and LEC2, as well as the two other LAFL genes, FUSCA3 (FUS3) and ABSCISIC ACID INSENSITIVE3 (ABI3). LEC2 and ABI3 quantitatively regulate BBM-mediated somatic embryogenesis, while FUS3 and LEC1 are essential for this process. BBM-mediated somatic embryogenesis is dose and context dependent, and the contextdependent phenotypes are associated with differential LAFL expression. We also uncover functional redundancy for somatic embryogenesis among other Arabidopsis BBM-like proteins and show that one of these proteins, PLETHORA2, also regulates LAFL gene expression. Our data place BBM upstream of other major regulators of plant embryo identity and totipotency.

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A new petunia flower colour generated by transformation of a mutant with a maize gene

Meyer¹,

Heidmann²,

Forkmann

et al. 1987

Nature

395

194

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Petunia hybrida is one of the classical subjects of investigation in plants in which the pathway of anthocyanin biosynthesis has been analysed genetically and biochemically. In petunia cyanidin- and delphinidin-derivatives, but no pelargonidin-derivatives are produced as pigments. This is due to the substrate specificity of the dihydroflavonol 4-reductase of petunia, which cannot reduce dihydrokaempferol. The petunia mutant RL01, which accumulates dihydrokaempferol, shows no flower pigmentation. RL01 served as a recipient for the transfer of the A1 gene of Zea mays encoding dihydroquercetin 4-reductase, which can reduce dihydrokaempferol and thereby provided the intermediate for pelargonidin biosynthesis. Transformation of RL01 with a vector p35A1, containing the A1-complementary DNA behind the 35S promotor leads to red flowers of the pelargonidin-type. Thus a new flower pigmentation pathway has been established in these plants.

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Differences in DNA‐methylation are associated with a paramutation phenomenon in transgenic petunia

Meyer¹,

Heidmann²,

Niedenhof³

1993

The Plant Journal

212

141

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The transgenic petunia line 17-R contains one copy of the maize A1 gene which mediates brick-red pelargonidin pigmentation of the flower. A white derivative, 17-W, was isolated from homozygous progeny of this line in which no pelargonidin pigmentation was observed. In 17-W the 35S promoter driving the A1 gene was hypermethylated, in contrast to its hypomethylated state in 17-R. Progeny plants carrying both the 17-R and 17-W allele did not show the expected A1 phenotype. Predominantly white progeny and variable plants were observed which showed a continuous change in pattern and intensity of pelargonidin pigmentation. This reduction of A1 activity argues for a semidominant effect of the 17-W allele which inhibits the activity of its homologue, 17-R. This system shows striking similarities to some paramutation phenomena in plants which represent a heritable change in gene function of a paramutable allele directed by a paramutagenic homologue. The analysis of the methylation patterns of the A1 alleles suggests that interactions between differentially methylated alleles are responsible for the paramutation-like effect which is mediated by somatic pairing. The analogy of this system to other phenomena based on homology-dependent interlocus trans-inactivation supports the assumption that those may be based on a related mechanism which includes an interaction between ectopic homologues.

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Epigenetic changes in the expression of the maize A1 gene inPetunia hybrida: Role of numbers of integrated gene copies and state of methylation

Heidmann²,

et al. 1990

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The Petunia hybrida mutant RL01 is white flowering due to a genetic block in the anthocyanin pathway. The introduction of the maize A1 cDNA under the control of the CaMV 35S RNA promoter leads to the production of pelargonidin derivatives, resulting in a brick red flower phenotype. Among the transgenic petunia plants the pigmentation of the petals exhibited different expression patterns which could be categorized into the 'red', the 'variegated', and the 'white' phenotype. This system proved to be especially suitable for the investigation of gene expression by simply looking at the pigmentation pattern of the petals. The uniformity of floral pelargonidin pigmentation is inversely correlated with the number of integrated A1 copies. Furthermore, a correlation was found between the methylation status of the 35S RNA promoter and the instability of the floral pelargonidin coloration. The status of promoter methylation controlling the expression of the A1 gene seems to be influenced by the copy number and the chromosomal position of the transferred gene.

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Endogenous and environmental factors influence 35S promoter methylation of a maize A1 gene construct in transgenic petunia and its colour phenotype

Meyer¹,

Linn

Heidmann³

et al. 1992

Molec. Gen. Genet.

247

123

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30,000 transgenic petunia plants carrying a single copy of the maize A1 gene, encoding a dihydroflavonol reductase, which confers a salmon red flower colour phenotype on the petunia plant, were grown in a field test. During the growing season plants with flowers deviating from this salmon red colour, such as those showing white or variegated phenotypes and plants with flowers exhibiting only weak pigmentation were observed with varying frequencies. While four white flowering plants were shown at the molecular level to be mutants in which part of the A1 gene had been deleted, other white flowering plants, as well as 13 representative plants tested out of a total of 57 variegated individuals were not mutants but rather showed hypermethylation of the 35S promoter directing A1 gene expression. This was in contrast to the homogeneous fully red flowering plants in which no methylation of the 35S promoter was observed. While blossoms on plants flowering early in the season were predominantly red, later flowers on the same plants showed weaker coloration. Once again the reduction of the A1-specific phenotype correlated with the methylation of the 35S promoter. This variation in coloration seems to be dependent not only on exogenous but also on endogenous factors such as the age of the parental plant from which the seed was derived or the time at which crosses were made.

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Iris Heidmann

The BABY BOOM Transcription Factor Activates the LEC1-ABI3-FUS3-LEC2 Network to Induce Somatic Embryogenesis

A new petunia flower colour generated by transformation of a mutant with a maize gene

Differences in DNA‐methylation are associated with a paramutation phenomenon in transgenic petunia

Epigenetic changes in the expression of the maize A1 gene inPetunia hybrida: Role of numbers of integrated gene copies and state of methylation

Endogenous and environmental factors influence 35S promoter methylation of a maize A1 gene construct in transgenic petunia and its colour phenotype

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