Project description:Development of multicellular organisms proceeds via the correct interpretation of positional information to establish boundaries that separate developmental fields with distinct identities. The maize leaf is an ideal system to study plant morphogenesis as it is subdivided into a proximal sheath and a distal blade, each with distinct developmental patterning. Specialised ligule and auricle structures form at the blade-sheath boundary. The auricles act as a hinge, allowing the leaf blade to project at an angle from the stem, while the ligule comprises an epidermally-derived fringe. Recessive liguleless1 mutants lack ligules and auricles, and have upright leaves. We utilized laser-microdissection RNAseq to identify genes that are differentially expressed along discrete cell/tissue-specific domains along the proximal-distal axis of wild-type leaf primordia undergoing ligule initiation, and compared transcript accumulation in wild type and liguleless1 mutant leaf primordia. We identified transcripts that are specifically upregulated at the blade-sheath boundary. A surprising number of these ligule genes are also implicated to function during leaf initiation or lateral branching, and intersect multiple hormonal signalling pathways. We propose that genetic modules utilised in leaf and/or branch initiation are redeployed to regulate ligule outgrowth from leaf primordia.

Project description:Rice leaves consist of three distinct regions along a proximal-distal axis, namely, the leaf blade, sheath, and blade-sheath boundary region. Each region has a unique morphology and function, however,but the genetic programs underlying the development of each region are poorly understood. To capture the entire picture of rice leaf development and to discover genes with unique functions in rice and grasses, it is crucial to explore genome-wide transcriptional profiles during the development of the three regions. In this study, we performed microarray analysis to profile the spatial and temporal patterns of gene expression in the rice leaf using dissected parts of leaves sampled in broad developmental stages.

Project description:The leaf lamina joint joins the rice leaf blade and sheath, contributing significantly to the leaf angle trait. A more erect leaf facilitates the penetration of sunlight, enhancing photosynthetic efficiency and occupying less space in dense planting. Genetic screening found a mutant increased leaf angle1, ila1 from rice T-DNA insertional mutants library. We used microarrays to detail the transcriptional profile changes in the mutant ila1 lamina joint.

Project description:To study cell type-specific gene expression in the leaf boundary region in the genome scale, we employed the TRAP-seq approach recently implemented. In brief, we introduced a reporter line carrying the fusion of the large subunit ribosomal protein L18 with N-terminal His and FLAG epitope tags (HF-RPL18) under the control of the pOp promoter into driver lines expressing the chimeric TF LhG4 under the control of the LATERAL SUPPRESSOR (LAS) promoter, and under the control of the ASYMMETRIC LEAVES1 (AS1) promoter. These driver lines were chosen because pLAS::LhG4 has boundary region-specific activity (Goldshmidt et al, 2008), and pAS1::LhG4 drives pOp reporter expression throughout emerging leaf primordia, but not in the SAM. Cell type-specific expression of HF-RPL18 can efficiently incorporate epitope tags into polysomes for immunopurification of all translating cellular mRNAs. We immunopurified polysomes from seedlings at 7 days after germination (DAG), to isolate translating mRNA in the LAS-expressing organ boundary cells and AS1-expressing leaf primordia and cotyledon cells. Then, we used deep sequencing to map and quantify these mRNA samples.

Project description:Photosynthesis underpins the viability of most ecosystems, with C4 plants that exhibit ‘Kranz’ anatomy being the most efficient primary producers. Kranz anatomy is characterized by closely spaced veins that are encircled by two morphologically distinct photosynthetic cell types. Although Kranz anatomy evolved multiple times, the underlying genetic mechanisms remain largely elusive, with only the maize scarecrow gene so far implicated in Kranz patterning. To provide a broader insight into the regulation of Kranz differentiation, we performed a genome-wide comparative analysis of developmental trajectories in Kranz (foliar leaf blade) and non-Kranz (husk leaf sheath) leaves of the C4 plant maize. Using profile classification of gene expression in early leaf primordia, we identified cohorts of genes associated with procambium initiation and vascular patterning. In addition, we used supervised classification criteria inferred from anatomical and developmental analyses of five developmental stages to identify candidate regulators of cell-type specification. Our analysis supports the suggestion that Kranz anatomy is patterned, at least in part, by a SCARECROW/SHORTROOT regulatory network, and suggests likely components of that network. Furthermore, the data imply a role for additional pathways in the development of Kranz leaves.

Project description:Transcript profile of apices of 20 days-old Arabidopsis plants over expressing miR396b. We used ATH1 Affymetrics microarrays to obtain the transcription profile of plants overexpressing miR396b. We compared the transcriptome of 35S:miR396b plants vs wild-type plants (Col-0 accession), using ATH1 Affymetrics microarrays. For these experiments we collected vegetative apices together with the leaf primordia from plants of 20 days growth in short-day. For each genotype (Col-0, 35S:miR396b) we collected two samples.

Project description:As maize (Zea mays) plants undergo vegetative phase change from juvenile to adult, they both exhibit heteroblasty, an abrupt change in patterns of leaf morphogenesis, and gain the ability to produce flowers. Both processes are under the control of microRNA 156, whose levels decline at the end of the juvenile phase. Gain of ability to flower is conferred by expression of miR156 targets that encode Squamosa Promoter-Binding (SBP) transcription factors, which when derepressed in the adult phase induce the expression of MADS-box transcription factors that promote maturation and flowering. What gene expression differences underlie heteroblasty, as well as what regulates miR156 levels, remain open questions. Here, we compare gene expression in primordia that will develop into juvenile or adult leaves to identify genes that define these two developmental states and may influence vegetative phase change. In comparisons among successive leaves at the same developmental stage of plastochron 6, three-fourths of approximately 1,100 differentially expressed genes were more highly expressed in primordia of juvenile leaves. This juvenile set was enriched in photosynthetic genes, particularly those associated with cyclic electron flow at photosystem I, and in genes involved in oxidative stress and retrograde redox signaling. Pathogen- and herbivory-responsive pathways including jasmonic acid and salicylic acid were also up-regulated in juvenile primordia and indeed, exogenous application of jasmonic acid both delayed the appearance of adult traits and the decline of miR156 levels in maize seedlings. The successful amelioration of stress signals thus plays an important role in inducing vegetative phase change in maize. 12 untreated samples (8mm primordia of leaves 1-12) and 1 treated sample (leaf 5 primordium, 15mM JA treatment). 2 or more technical replicates per sample

Project description:A total of 18 libraries from Setaria viridis were constructed using the Illumina TruSeq sample preparation method. We used two biological replicate libraries from the leaf, whole panicles (inside leaf sheath), whole panicles (coming out of leaf sheath), whole panicles (completely out of leaf sheath), whole panicles (completely out of leaf sheath, after pollination), spikelet (inside leaf sheath), spikelet (coming out of leaf sheath), and spikelet (completely out of leaf sheath).

Project description:C4 grasses, such as maize (Zea mays), have high photosynthetic efficiency through combined biochemical and structural adaptations.C4 photosynthesis is established along the developmental axis of the leafblade, leading from an undifferentiated leaf base just above the ligule into highly specialized mesophyll cells (MCs) and bundle sheath cells (BSCs) at the tip. To resolve the kinetics of maize leaf development and C4 differentiation and to obtain a systems-level understanding of maize leaf formation, the accumulation profiles of proteomes of the leaf and the isolated BSCs with their vascular bundle along the developmental gradient were determined using large-scale mass spectrometry. This was complemented by extensive qualitative and quantitative microscopy analysis of structural features (e.g., Kranz anatomy, plasmodesmata, cell wall, and organelles). More than 4300 proteins were identified and functionally annotated. Developmental protein accumulation profiles and hierarchical cluster analysis then determined the kinetics of organelle biogenesis, formation of cellular structures, metabolism, and coexpression patterns. Two main expression clusters were observed, each divided in subclusters, suggesting that a limited number of developmental regulatory networks organize concerted protein accumulation along the leaf gradient. The coexpression with BSC and MC markers provided strong candidates for further analysis of C4 specialization, in particular transporters and biogenesis factors. Based on the integrated information, we describe five developmental transitions that provide a conceptual and practical template for further analysis. An online protein expression viewer is provided through the PlantProteomeDatabase.

Project description:The leaf lamina joint joins the rice leaf blade and sheath, contributing significantly to the leaf angle trait. A more erect leaf facilitates the penetration of sunlight, enhancing photosynthetic efficiency and occupying less space in dense planting. Genetic screening found a mutant increased leaf angle1, ila1 from rice T-DNA insertional mutants library. We used microarrays to detail the transcriptional profile changes in the mutant ila1 lamina joint. Two biological replicate sample of leaf lamina joints from the ila1 and wild-type plants at tillering stage were collected for RNA extraction. Total RNAs were isolated from each replicate via the TRIzol method (Invitrogen) and used in target synthesis for the Rice Genome Array from Affymetrix. The microarray analyses were performed through following standard protocols (Affymetrix).