Ectopic expression of a single homeotic gene, the Petunia gene green petal, is sufficient to convert sepals to petaloid organs.

Genetic studies in Arabidopsis and Antirrhinum showed that petal determination requires the concomitant expression of two homeotic functions, A and B, whereas the A function alone determines sepal identity. The B function is represented by at least two genes. The Petunia homeotic gene green petal (gp) is essential for petal determination as demonstrated by a Petunia gp mutant that has sepals instead of petals. We have used ectopic expression of the gp gene as a tool to study flower development in Petunia. CaMV 35S-gp expression leads to homeotic conversion of sepals into petaloid organs when expressed early in development. This demonstrates that a single homeotic gene is sufficient to induce homeotic conversion of sepals to petals, suggesting that other petal determining genes are regulated in part by ectopically expressed gp. Indeed, two other MADS-box-containing genes, pmads 2 and fbp 1, which show homology to the Antirrhinum B function gene globosa, are activated in the converted petal tissue. Furthermore, our data provide evidence for autoregulation of gp expression in the petaloid tissue and uncover the role of gp in fusion of petal tissues.     

The seirena B Class Floral Homeotic Mutant of California Poppy (Eschscholzia californica) Reveals a Function of the Enigmatic PI Motif in the Formation of Specific Multimeric MADS Domain Protein Complexes

The products of B class floral homeotic genes specify petal and stamen identity, and loss of B function results in homeotic conversions of petals into sepals and stamens into carpels. Here, we describe the molecular characterization of seirena-1 (sei-1), a mutant from the basal eudicot California poppy (Eschscholzia californica) that shows homeotic changes characteristic of floral homeotic B class mutants. SEI has been previously described as EScaGLO, one of four B class–related MADS box genes in California poppy. The C terminus of SEI, including the highly conserved PI motif, is truncated in sei-1 proteins. Nevertheless, like the wild-type SEI protein, the sei-1 mutant protein is able to bind CArG-boxes and can form homodimers, heterodimers, and several higher order complexes with other MADS domain proteins. However, unlike the wild type, the mutant protein is not able to mediate higher order complexes consisting of specific B, C, and putative E class related proteins likely involved in specifying stamen identity. Within the PI motif, five highly conserved N-terminal amino acids are specifically required for this interaction. Several families lack this short conserved sequence, including the Brassicaceae, and we propose an evolutionary scenario to explain these functional differences.     

Spatial distribution of the RABBIT EARS protein and effects of its ectopic expression in Arabidopsis thaliana flowers

In many flowering plants, flowers consist of two peripheral organs, sepals and petals, occurring in outer two whorls, and two inner reproductive organs, stamens and carpels. These organs are arranged in a concentric pattern in a floral meristem, and the organ identity is established by the combined action of floral homeotic genes expressed along the whorls. Floral organ primordia arise at fixed positions in the floral meristem within each whorl. The RABBIT EARS (RBE) gene is transcribed in the petal precursor cells and primordia, and regulates petal initiation and early growth in Arabidopsis thaliana. We investigated the spatial and temporal expression pattern of a RBE protein fused to the green fluorescent protein (GFP). Expression of the GFP:RBE fusion gene under the RBE cis-regulatory genomic fragment rescues the rbe petal defects, indicating that the fusion protein is functional. The GFP signal is located to the cells where RBE is transcribed, suggesting that RBE function is cell-autonomous. Ectopic expression of GFP:RBE under the APETALA1 promoter causes the homeotic conversion of floral organs, resulting in sterile flowers. In these plants, the class B homeotic genes APETALA3 and PISTILLATA are down-regulated, suggesting that the restriction of the RBE expression to the petal precursor cells is crucial for flower development.     

Decreased Expression of a Gene Caused by a T-DNA Insertion in an Adjacent Gene in Arabidopsis

ALADIN is a component of the nuclear pore complex in higher eukaryotes. An Arabidopsis knockout line that had a T-DNA insertion in the ALADIN gene was defective in plant growth and thylakoid development and had reduced photosynthetic activity resulting from lower chlorophyll accumulation. The mutation appeared to decrease the level of chloroplast RuBisCO subunits and PSBA and PGL35 proteins. Unexpectedly, the T-DNA insertion in the ALADIN gene decreased the expression of the neighboring gene PSRP5, which functions in translation in chloroplasts. The mutant phenotype was rescued by expressing PSRP5, but not by expressing ALADIN. The abnormal phenotypes were also detected in an artificial microRNA (amiRNA)-mediated PSRPS5 knockdown, but not in an amiRNA-mediated ALADIN knockdown line. Thus, users of T-DNA insertions should be aware that a T-DNA insertion in one gene can have effects on the expression of neighboring genes.     

Improved Postharvest Quality of Inflorescences of <Emphasis Type="Italic">fbp1::etr1-1</Emphasis> Transgenic <Emphasis Type="Italic">Burrageara</Emphasis> ‘Stefan Isler Lava Flow’

Flowers of the complex orchid hybrid Burrageara ‘Stefan Isler Lava Flow’ had been shown previously to react sensitively to ethylene. Via Agrobacterium tumefaciens, the mutant ethylene receptor ETHYLENE RESPONSE 1 (etr1-1) from Arabidopsis thaliana under the control of the flower-specific promoter FLOWER BINDING PROTEIN 1 (fbp1) from Petunia hybrida was transferred to Burrageara. One single-copy event was analyzed in this study aiming to investigate the expression of the fbp1::etr1-1 transgene in different plant and flower organs by quantitative RT-PCR and the reaction of flowers and inflorescences to ethylene. It was shown that the heterologous promoter led to high expression levels in the perianth of the orchid flowers compared to low levels in leaves and roots. The expression shift to the first whorl (sepals) described here corresponds to extended expression of endogenous B class MADS box homeotic genes in orchids in general. The transgenic plants grew and developed similar to the wild-type plants, except for slightly faster rooting in vitro and smaller flowers. Flower longevity was improved by 7 days in 10 ppm ethylene. Moreover, bud drop starting at day 5 of incubation of inflorescences in 10 ppm ethylene in the wild-type was efficiently prevented for at least 19 days in the fbp1::etr1-1 transgenic plants. The function of the tissue-specific promoter fbp1 and the mutant receptor etr1-1 was shown for the first time in a monocotyledonous plant.     

Functional analysis of a cryptic promoter from <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> reveals bidirectionality

Cryptic promoter elements play a significant role in evolution of plant gene expression patterns and are prospective tools for creating gene expression systems in plants. In a previous report, a 452 bp promoter fragment designated as cryptic root-specific promoter (AY601849) was identified immediately upstream to T-DNA insertion, in the intergenic region between divergent genes SAHH1 and SHMT4, in T-DNA tagged mutant M57 of Arabidopsis thaliana. In silico analysis of 452 bp promoter revealed typical eukaryotic promoter architecture, presence of root-specific motifs and other cis-regulatory motifs responsible for the spatial and temporal expression. GUS expression driven by 452 bp in M57 was developmentally as well as light-regulated. The AT-rich 452 bp promoter does not show homology to any known sequences. The 452 bp promoter was further proved cryptic and detailed molecular characterization of the promoter carried out through serial 5′ and 3′ deletion analysis, by cloning the promoter fragments upstream to promoter-less GUS vector. A 279 bp fragment obtained by deleting 173 bp from 5′ end of 452 bp was capable of driving root-specific expression, similar to that of full-length promoter. Further, root tip-specific, root-specific and core-regulatory motifs for root-specific expression were identified at positions 173–227, 251–323 and 408–452 bp, respectively, from the 5′ end of 452 bp. The 452 bp promoter was equally functional in inverse orientation, hence bidirectional and symmetric. In heterologous systems, such as Brassica juncea and Oryza sativa, the promoter activity was not significant since GUS was not visually detected in transient assays.     

Isolation and Characterization of an AGAMOUS-Like Gene from Magnolia wufengensis (Magnoliaceae)

The floral homeotic C function gene AGAMOUS (AG) plays crucial roles in Arabidopsis development by specifying stamen and carpel identity, repressing A-class genes, as well as regulating floral meristem determination. Although the function of AG homologs from other core eudicots appears highly conserved, the role of AG orthologs in the design of floral architecture in basal angiosperm remains unknown. We isolated and identified an AG ortholog from Magnolia wufengensis, a woody basal angiosperm belonging to the Magnoliaceae. Sequence and phylogenetic analyses revealed that it is a clade member of the euAG lineage, and hence, the gene is referred to as MAwuAG (M. wu fengensis AGAMOUS). Moreover, two highly conserved motifs specific to C proteins, AG motifs I and II, are found in the C-terminal regions of the MAwuAG protein, but the N-terminal extensions that usually appear in euAG lineage members from eudicots were not found in MAwuAG. The cDNA has the first in-frame ATG immediately preceding the MADS domain. A semi-quantitative PCR analysis showed that the expression of MAwuAG was restricted to reproductive organs of stamens and carpels. The transgenic Arabidopsis containing 35S::MAwuAG displayed extremely early flowering, bigger stamens and carpels, and homeotic conversion of petals into staminoid organs, but ectopic expression of MAwuAG in the first whorls failed to convert the sepals into carpeloid structures that are usually observed in the overexpression transgenic Arabidopsis of AG orthologs from other core eudicots. In addition, the phenotype of the transgenic 35S::MAwuAG Arabidopsis revealed that the abscission of the outer three floral whorls (sepals, petals, and stamens) was inhibited.     

Allele-specific effects of PDF2 on floral morphology in Arabidopsis thaliana

The class IV Homeodomain-leucine zipper (HD-ZIP IV) gene family includes several genes that are functionally significant in epidermal development. Our recent study revealed that double mutants of the epidermis-expressed HD-ZIP IV members, PROTODERMAL FACTOR2 (PDF2) in combination with some HOMEODOMAIN GLABROUS (HDG, pronounced “hedge”) genes, affect stamen development and specification of petal and stamen identity, possibly in a non cell-autonomous manner. However, the effect of the pdf2 mutations on the floral development was largely different depending on T-DNA insertion locations: pdf2–1 hdg flowers exhibited homeotic conversion of petals and stamens, while pdf2–2 hdg flowers had only a reduced number of stamens. Here, we used 2 additional pdf2 alleles to make double mutants and found that their floral phenotypes were rather similar to those of pdf2–2 hdg. The allele-specific effect caused by pdf2–1, which carries a T-DNA in a steroidogenic acute regulatory protein-related lipid transfer (START) domain-encoding region, suggests the importance of the START domain in proper function of HD-ZIP IV proteins.     

New vector system for induction of gene expression in dicotyledonous plants

A system of two vectors, pEnLox and pCre, was developed. The pEnLox vector is used to induce insertional mutations, while pCre is used to obtain transgenic plants expressing the Cre recombinase gene. The T-DNA enhancer is flanked by the loxP sites in the pEnLox vector. As an Arabidopsis thaliana insertional mutant obtained by transformation with pEnLox is crossed with another transgenic line carrying the cre gene, the enhancer sequence is eliminated. The vector system makes it possible to induce insertional mutations and to determine whether the mutant phenotype is caused by the loss-of-function insertional mutation or by overespression of nearby genes in response to the enhancer contained in the insert.