V. Michelotti

Characterization of LEAFY COTYLEDON1-LIKE gene in Helianthus annuus and its relationship with zygotic and somatic embryogenesis

The Helianthus annuusLEAFY COTYLEDON1-LIKE (HaL1L) gene encodes a heme-activated protein 3 subunit of the CCAAT box-binding factor. The phylogenetic analysis indicates that HaL1L is closely related to LEAFY COTYLEDON1 (LEC1)-type of Arabidopsis thaliana. In particular, the peptide results homologous to the LEC1-LIKE gene of A. thaliana, with which it shares a high amino acid sequence identity (56%). HaL1L transcripts are accumulated primarily at an early stage of sunflower embryogenesis. High levels of HaL1L messenger RNA (mRNA) have been detected in the developing embryo proper, suspensor, endosperm, integument, and integumentary tapetum cells, while in unfertilized ovules, HaL1L mRNA was present at rather low levels. In an attempt to examine the involvement of HaL1L on somatic embryogenesis, a somaclonal variant of H. annuus × H. tuberosus (EMB-2) that produces ectopic embryo- and shoot-like structures, arranged in clusters along leaf veins, was used. We found that the epiphyllous proliferation of ectopic embryos on EMB-2 leaves was associated to HaL1L mRNA accumulation. The detection of HaL1L transcripts was evident in somatic embryos at the heart- and early cotyledon-stage. On the contrary, no signal related to HaL1L transcript accumulation was observed in EMB-2 leaves characterized by the presence of shoot-like structures. Together, these results support the conclusion that the transcription of the HaL1L gene is maintained both in zygotic and in somatic embryogenesis. In addition, the ectopic accumulation of HaL1L mRNA in parenchymal cells around the vascular bundles of epiphyllous leaves opens the possibility that HaL1L could also be involved in switching somatic cell fate towards embryogenic competence.

Ectopic expression of LEAFY COTYLEDON1-LIKE gene and localized auxin accumulation mark embryogenic competence in epiphyllous plants of Helianthus annuus × H. tuberosus

BACKGROUND AND AIMS The clone EMB-2 of the interspecific hybrid Helianthus annuus x H. tuberosus provides an interesting system to study molecular and physiological aspects of somatic embryogenesis. Namely, in addition to non-epiphyllous (NEP) leaves that expand normally, EMB-2 produces epiphyllous (EP) leaves bearing embryos on the adaxial surface. This clone was used to investigate if the ectopic expression of H. annuus LEAFY COTYLEDON1-LIKE (Ha-L1L) gene and auxin activity are correlated with the establishment of embryogenic competence. METHODS Ha-L1L expression was evaluated by semi-quantitative RT-PCR and in situ hybridization. The endogenous level and spatial distribution of free indole-3-acetic acid (IAA) were estimated by a capillary gas chromatography-mass spectrometry-selected ion monitoring method and an immuno-cytochemical approach. KEY RESULTS Ectopic expression of Ha-L1L was detected in specific cell domains of the adaxial epidermis of EP leaves prior to the development of ectopic embryos. Ha-L1L was expressed rapidly when NEP leaves were induced to regenerate somatic embryos by in vitro culture. Differences in auxin distribution pattern rather than in absolute level were observed between EP and A-2 leaves. More precisely, a strong IAA immuno-signal was detected in single cells or in small groups of cells along the epidermis of EP leaves and accompanied the early stages of embryo development. Changes in auxin level and distribution were observed in NEP leaves induced to regenerate by in vitro culture. Exogenous auxin treatments lightly influenced Ha-L1L transcript levels in spite of an enhancement of the regeneration frequency. CONCLUSIONS In EP leaves, Ha-L1L activity marks the putative founder cells of ectopic embryos. Although the ectopic expression of Ha-L1L seems to be not directly mediated by auxin levels per se, it was demonstrated that localized Ha-L1L expression and IAA accumulation in leaf epidermis domains represent early events of somatic embryogenesis displayed by the epiphyllous EMB-2 clone.

Molecular Cloning and Organ-Specific Expression of Two Gibberellin 20-Oxidase Genes of Helianthus annuus

The activity of GA 20-oxidase (GA20ox), a 2-oxoglutarate-dependent dioxygenase, is a critical regulatory factor in the gibberellin-(GA)-biosynthetic pathway. Two genes, HaGA20ox1 and HaGA20ox2, along with their corresponding cDNAs exhibiting structural features and homology to GA 20-oxidases of several plant species, have been isolated from vegetative shoots of sunflower (Helianthus annuus). Sequence analysis revealed that both genes consist of three exons and two introns. GA20ox genes from dicot and monocot species showed similar structures. The amino acid sequences deduced from the sunflower cDNA clones showed high level of similarity, with identities of HaGA20ox1/HaGA20ox2 of 84%. The phylogenetic analysis indicated that all monocot and all dicot GA20ox were grouped in two separate clusters. Within the dicot clade, HaGA20ox1 and HaGA20ox2 formed a subclade with GA 20-oxidases from Lactuca sativa (Ls20ox1 and Ls20ox2), Chrysanthemum x morifolium (DgGA20ox1), and Daucus carota (DcGA20ox2). Both HaGA20ox1 and HaGA20ox2 shared the highest similarity with the L. sativa Ls20ox1. The high accumulation of both HaGA20ox transcripts coincided with the period of rapid growth of the sunflower embryo, suggesting a role for GA in the first phase of embryo maturation. HaGA20ox1 mRNA was also detected in all the organs tested but occurred at a higher level in the vegetative shoot and the root, whereas HaGA20ox2 transcripts were preferentially accumulated in inflorescence meristems, vegetative shoots, internodal stem, and roots. Treatment of sunflower plants with an inhibitor of GA biosynthesis showed that HaGA20ox2, but not HaGA20ox1, was subject to feedback regulation by a reduction of bioactive GAs.

Phytoene accumulation in sunflower decreases the transcript levels of the phytoene synthase gene

The non dormant-1 (nd-1) mutant of sunflower (Helianthus annuus L.) and fluridone-treated plants were used to investigate the effect of phytoene accumulation on the transcript levels of the phytoene synthase (Ha-PSY) gene. A deficiency at the gene coding for ζ-carotene desaturase (ZDS) characterises the nd-1 mutant, which displays an accumulation of ζ-carotene, phytofluene and cis-phytoene and the absence of β-carotene and xanthophylls. The transcript levels of Ha-PSY, in concomitance with phytoene accumulation, decreased (1.9-fold) in fluridone-treated wild-type seedlings with respect to untreated leaves. Phytoene-accumulating cotyledons of nd-1 seedlings also displayed a 2.9-fold decrease of Ha-PSY mRNA levels in comparison with the control samples. To exclude that the reduced transcript levels of Ha-PSY was dependent by a decrease of the total carotenoid content another pigment-deficient mutant, named xantha1 (xan1), was used. The xan1 mutant has a normal carotenoid complement but photodestruction of both chlorophyll a and β-carotene directly correlate with light intensity. The increase of Ha-PSY mRNA, in normal-pigmented cotyledons, was concurrent with the enhanced light intensity. The same up-regulation for Ha-PSY was observed in xan1, irrespective of the drastic reduction of the total carotenoid content displayed by mutant seedlings grown under high light intensity. Taken together, our data suggest that in H. annuus the steady state levels of Ha-PSY mRNA was negatively affects by phytoene accumulation but not by a decrease in total carotenoid content.

Expression of HtKNOT1, a class I KNOX gene, overlaps cell layers and development compartments of differentiating cells in stems and flowers of Helianthus tuberosus

In plant, post‐embryonic development relies on the activities of indeterminate cell populations termed meristems, spatially clustered cell lineages, wherein a subset divides indeterminately. For correct growth, the plant must maintain a constant flow of cells through the meristem, where the input of dividing pluripotent cells offsets the output of differentiating cells. KNOTTED1‐like homeobox (KNOX) genes are expressed in specific patterns in the plant meristems and play important roles in maintaining meristematic cell identity. We have analyzed the expression pattern of HtKNOT1, a class I KNOX gene of Helianthus tuberosus, in stems, inflorescence meristems, floral meristems and floral organs. HtKNOT1 is expressed in cambial cells, phloem cells and xylematic parenchyma within apical stem internodes, while in basal internodes HtKNOT1 expression was restricted to the presumptive initials and recently derived phloem cells. In the reproductive phase, HtKNOT1 mRNAs were detected in both the inflorescence and floral meristems as well within lateral organ primordia (i.e. floral bracts, petals, stamens and carpels). In more differentiated flowers, the expression of HtKNOT1 was restricted to developing ovules and pollen mother cells. HtKNOT1 may play a dual role being required to maintain the meristem initials as well as initiating differentiation and/or conferring new cell identity. In particular, it is possible that HtKNOT1 cooperates at floral level with additional factors that more specifically control floral organs and pollen development in H. tuberosus.

Orange, yellow and white‐cream: inheritance of carotenoid‐based colour in sunflower pollen

Inheritance of pollen colour was studied in sunflower (Helianthus annuus L.) using three distinct pollen colour morphs: orange, yellow and white-cream. Orange is the most common colour of sunflower pollen, while the yellow morph is less frequent. These two types were observed in the inbred lines F11 and EF2L, respectively. White-cream pollen is a rare phenotype in nature, and was identified in a mutant, named white-cream pollen, recovered in the R(2) generation of an in vitro regenerated plant. The F11 inbred line was used as starting material for in vitro regeneration. The carotenoid content of these three pollen morphs differed, and was extremely reduced in white-cream pollen. The phenotype of F(1) populations obtained by reciprocal crosses revealed that the orange trait was dominant over both white-cream and yellow. Segregation of F(2) populations of both crosses, orange x yellow and orange x white-cream, approached a 3:1 ratio, indicating the possibility of simple genetic control. By contrast, a complementation cross between the two lines with white-cream and yellow pollen produced F(1) plants with orange pollen. The F(2) populations of this cross-segregated as nine orange: four white-cream: four yellow. A model conforming to the involvement of two unlinked genes, here designated Y and O, can explain these results. Accessions with yellow pollen would have the genotype YYoo, the white-cream pollen mutant would have yyOO and the accession with orange pollen would have YYOO. Within F(2) populations of the cross white-cream x yellow a new genotype, yyoo, with white-cream pollen was scored. The results of the cross yyoo x YYoo produced only F(1) plants with yellow pollen, supporting a recessive epistatic model of inheritance between two loci. In this model, yy is epistatic on O and o. In F(2) populations, the distributions of phenotypic classes suggested that the genetic control of carotenoid content is governed by major genes, with large effects segregating in a background of polygenic variation. These three pollen morphs can provide insight into the sequence in which genes act, as well into the biochemical pathway controlling carotenoid biosynthesis in anthers and the transfer of these different pigments into pollenkitt.