Dissecting embryonic and seedling morphogenesis in Arabidopsis by promoter trap insertional mutagenesis.

Development can be considered to comprise the co-ordinated regulation of patterning at different levels: patterning of cells to form tissues, patterning of tissues to form organs, and patterning of organs to generate the characteristic architecture of the organism. These processes are expected, in turn, to be mediated by the precise spatial and temporal regulation of patterns of gene expression during development, which depend on appropriate signalling mechanisms. In order to investigate molecular events of morphogenesis in plants, we have utilized a system of promoter trap insertional mutagenesis in Arabidopsis, to generate both phenotypic mutants and gene fusions that represent markers useful in studying the regulation of patterning. A screen of transgenic seedlings containing a T-DNA promoter trap has led to the identification of mutants defective in seedling shape and embryonic development, and of GUS fusion genes that are expressed in spatially restricted patterns. Mutants have been crossed with marker lines expressing cell type-specific GUS activities, to investigate their cellular organization. For example, the POLARIS marker gene is expressed in the embryonic and seedling root tip. When crossed with hydra, which lacks an embryonic root, and with emb30, which lacks both embryonic and seedling roots, it is nevertheless expressed in the correct relative position, and we hypothesize that it represents a novel marker of root positional information, independent of root morphogenesis.

Promoter trap markers differentiate structural and positional components of polar development in Arabidopsis.

To investigate mechanisms involved in establishing polar organization in Arabidopsis embryos and seedlings, we used promoter trapping to identify molecular markers (beta-glucuronidase fusion genes) expressed in spatially restricted patterns along the apical-basal axis. Three markers were identified that are expressed, respectively, in the embryonic and seedling root tip (POLARIS), cotyledons and shoot and root apices (EXORDIUM), and root cap (COLUMELLA). Each marker was crossed into the mutants hydra and emb30, which are defective in embryonic and seedling morphogenesis. All three markers were expressed in hydra mutants in patterns similar to those observed in phenotypically wild-type embryos and seedlings. In emb30 mutants, the EXORDIUM marker was expressed in cotyledons but not in the expected position of shoot and root meristems, and the marker COLUMELLA was not expressed at all, which is consistent with the view that the emb30 mutant, but not hydra, lacks shoot and root meristems. However, POLARIS was expressed in the basal part of hydra embryos lacking an embryonic root and in the basal parts of both hydra and emb30 seedlings. Expression of POLARIS is inducible by exogenous auxin and suppressed by cytokinin but is unaffected by inhibitors of polar auxin transport or cell division. We conclude that POLARIS differentiates positional aspects of polar development from structural aspects.

Mutations in the HYDRA1 gene of Arabidopsis perturb cell shape and disrupt embryonic and seedling morphogenesis.

Mutations in the HYDRA1 (HYD1) gene of Arabidopsis thaliana can prevent normal morphological development of embryos and seedlings. Three allelic mutants (hydra 1-1, hydra1-2 and hydra1-3) have been identified, and in each the seedling is characterized by having a variable number of cotyledons, a short and wide hypocotyl and a much reduced root system. hydra1 embryos appear to develop normally to the octant stage, but fail to establish a distinct protoderm and lack bilateral symmetry, developing multiple cotyledonary primordia of irregular size and shape. Cells of the embryo proper, but not the suspensor, exhibit abnormalities in size and shape. The hydra1 embryo fails to develop an embryonic root, but embryos and seedlings express molecular markers of apical-basal polarity. Mutant seedlings produce leaves to form a small cabbage-like habit and may occasionally produce sterile flowers, though the mutation is commonly seedling-lethal. hydra1 seedlings exhibit abnormal radial patterning, but nevertheless express at least one molecular marker of vascular cell differentiation. A model is proposed in which the HYDRA1 protein functions as an essential component of the cell expansion system.

Identification of molecular markers of embryogenesis in Arabidopsis thaliana by promoter trapping.

The technique of promoter trapping has been exploited to identify markers of embryogenesis in Arabidopsis thaliana. A population of transgenic A. thaliana was generated containing the promoter trap vector pdeltagusBin19, following Agrobacterium tumefaciens-mediated transformation. This vector contains at the T-DNA left border, a promoterless gusA gene, which is activated following integration downstream of a native gene promoter that directs transgene transcription. Screening of a population of 430 independent transgenic lines revealed that 74 lines (17.2%) exhibited GUS activity in siliques, as determined by fluorimetric assay. Histochemical GUS analysis was used to identify lines that expressed GUS in embryos, and three lines that were demonstrated to contain single T-DNA inserts were analysed in detail. Each line showed a distinct pattern of GUS fusion activity. Fusion transcripts were identified, demonstrating that transcription was initiated in the genomic DNA flanking the T-DNA left border. Inverse PCR was used to clone the T-DNA flanking sequences, and for one line a corresponding cDNA was identified, demonstrating that the tagged sequences are transcribed. The markers represent the earliest embryonic genes known to be expressed in plants.

Tagging genomic sequences that direct transgene expression by activation of a promoter trap in plants.

As part of a gene tagging strategy to study the developmental regulation of patterns of plant gene expression, a promoterless uidA (gusA) gene, encoding the beta-glucuronidase (GUS) reporter, was introduced into populations of tobacco, Arabidopsis and potato by Agrobacterium-mediated gene transfer. The objective was to generate random functional fusions following integration of the gusA gene downstream of native gene promoters. We describe here a detailed analysis of levels and patterns of gusA activation in diverse organs and cell types in those populations. gusA activation occurred at high frequency in all three species, and unique patterns of fusion gene expression were found in each transgenic line. The frequency of gusA activation was differentially biased in different organs in the three species. Fusion gene activity was identified in a wide range of cell types in all organs studied, and expression patterns were stably transmissible to the T2 and T3 progeny. Developmentally-regulated and environmentally-inducible expression of gusA is described for one transgenic line. Phenotypic variants were detected in the transgenic population. These results demonstrate the potential of T-DNA insertion as a means of creating functional tags of genes expressed in a wide spectrum of cell types, and the value of the approach as a complement to standard T-DNA insertional mutagenesis and transposon tagging for developmental studies is discussed.

Functional tagging of regulatory elements in the plant genome.

In comparison with animals, relatively few plant genes have been identified that have been shown to be under organ-, tissue- or cell-type-specific regulation. In this paper, we describe how the beta-glucuronidase (GUS) reporter gene (gusA or uidA), fused to a weak promoter (a truncated (-90 bp) CaMV35S promoter), can be used to identify tissue-specific markers in transgenic tobacco plants. The rationale was that the expression of gusA would be determined primarily by position effect. Quantitative analysis revealed that, of 184 -90-gus transgenic plants, 73% exhibited gusA gene activation in leaf tissue, and the level of GUS enzyme activity varied over a 300-fold range within the population. In comparison, transformation with a promoterless gusA gene resulted in GUS expression in 78% of all plants analyzed (in leaf and/or root) and expression levels were three-fold or more lower. Qualitative GUS analysis of single locus -90-gus transformants revealed differential expression in diverse tissues. The spatial pattern of GUS activity was unique to individual transformants, was a reflection of differential gusA gene transcription, and was stably transmissible to progeny. Evidence for preferential expression in roots not only of the -90-gus, but also the promoterless gusA gene is presented. The value of the -90 bp promoter-gusA sequence, which is termed an 'interposon', as a tool both to identify native enhancer sequences in situ and to investigate position effects in plants, is discussed.

Mitochondrial gene expression during wheat leaf development.

The expression of specific mitochondrial, chloroplast and nuclear genes has been investigated in leaves of 7-d-old light-grown wheat (Triticum aestivum cv. Maris Dove). In the wheat leaf there is a spatial separation of a temporal sequence of development from the basal meristem to the distal mature, photosynthetically competent cells. This sequence of cellular differentiation is paralleled by a functional differentiation in which the energy supply changes from oxidative phosphorylation in the non-green meristematic cells to a combined dependence on oxidative and photophosphorylation in the photosynthesizing cells. The changes in copy number per cell and expression of mitochondrial genes have been investigated in successive sections of the wheat leaf using quantitative DNA-DNA and DNA-RNA filter and protein-binding techniques. The abundance of specific mitochondrial genes (cox II.cob andatp A) per cell was found to decrease between five- and tenfold within the basal (1 cm) section of the leaf and then remain constant to the distal tip. The relative abundances of specific mitochondrial transcripts (cox I,cox II,cob andatp A) were found to decrease in successive sections from the basal meristem to the distal tip (from a relative value of 100% to 5-40%). In contrast, transcripts of chloroplast genes and nuclear genes encoding chloroplast polypeptides (psb A,rbc L andrbc S) were found to increase steadily in progressive leaf sections (from a relative value of 0-2% to 100%). The steady-state level of the α-subunit of the mitochondrial F1 ATPase was found to remain constant along the length of the leaf. Possible sites at which the regulation of organellar gene expression is coordinated during the development of photosynthetic competence within the wheat leaf are discussed.