Project description:The endosperm is a nutritive tissue that supports the growing embryo. Endosperm life span is restricted to seed development and germination. During maize kernel development in maize, two distinct endosperm cell death processes occur. The endosperm adjacent to the embryo scutellum (EAS) undergoes a lytic cell death supposedly to allow embryo expansion, whereas the starchy endosperm (SE) dies after kernel filling producing cell corpses that store nutrients required during germination. Here, we present a detailed analysis of these divergent cell death processes. During SE cell death, mitochondria, nuclei, and the endoplasmic reticulum disintegrate, while nuclear chromatin, cell walls, starch granules, and protein bodies are preserved. In contrast, EAS cells remobilize their stored nutrients, secrete extracellular vesicles, before the cells collapse and a complex post-mortem corpse clearance process ensues. Using single-nucleus RNA-sequencing transcriptome analysis of the developing endosperm, we identified the NAC transcription factors KIL1 and KIL2 as specifically expressed in the EAS. Dominant and recessive loss-of-function approaches demonstrate that KIL1 and KIL2 redundantly promote cell death execution and corpse clearance of the EAS, but are not required for SE cell death. The reduction of EAS cell death in loss-of-function lines strongly impeded embryo growth. Interestingly, KIL1 and KIL2 expression are promoted by DED1, an imprinted paternally expressed transcription factor, suggesting a paternal control over EAS cell death and embryo growth in maize.

Project description:Transcriptomics at maize embryo/endosperm interfaces identifies a novel transcriptionally distinct endosperm sub-domain adjacent to the embryo scutellum (EAS)

Project description:Grain development is a key life cycle stage of many plants. The development of seeds is the basis of agriculture and the primary source of calories consumed by humans. Here, we employ laser micro dissection (LMD) combined with shotgun proteomics to generate a cell-type proteome atlas of developing wheat endosperm at the early and late grain filling stages. We identified 1803 proteins from four different cell layers (aleurone (AL), sub-aleurone (SA), starchy endosperm (SE), and endosperm transfer cells (ETCs)) of developing endosperm at 15 Days after anthesis (DAA) and 26 DAA. Sixty-seven differentially expressed proteins in the aleurone, 31 in the sub-aleurone, 27 in the starchy endosperm, and 50 in the endosperm transfer cells were detected between these two-time points. The results revealed highly distinguishable proteome dynamics in the different cell layers of endosperm over the time course. We observed high general metabolic activity of the grain with regard to carbohydrate metabolism, defence against oxidative stress, and signalling in the different cell layers during the grain filling process. Cell-specific identification of SUT and GLUT transporters suggest a grain filling model via nucellar projections and endosperm transfer cells (ETCs) initiating starch biosynthesis in the starchy endosperm (SE). The identification and regulation dynamics of proteins in the different cell layers demonstrate a functional switch of the proteome from the early to the late grain filling stage. Based on these data, we proposed a model for sugar loading and starch biosynthesis in wheat developing endosperm, including an abundance switch of cell-type-specific key proteins.

Project description:Epigenetic modification plays important roles in plant and animal development. DNA methylation can impact the transposable element (TE) silencing, gene imprinting and regulate gene expression.Through a genome-wide analysis, DNA methylation peaks were respectively characterized and mapped in maize embryo and endosperm genome. Distinct methylation level across maize embryo and endosperm was observed. The maize embryo genome contained more DNA methylation peaks than endosperm. However, the endosperm chloroplast genome contained more DNA methylation peaks to compare with the embryo chloroplast genome. DNA methylation regions were characterized and mapped in genome. More CG island (CGI) shore are methylated than CGI in maize suggested that DNA methylation level is not positively correlated with CpG density. The DNA methylation occurred more frequently in the promoter sequence and transcriptional termination region (TTR) than other regions of the genes. The result showed that 99% TEs we characterized are methylated in maize embryo, but some (34.8%) of them are not methylated in endosperm. Maize embryo and endosperm exhibit distinct pattern/level of methylation. The most differentially methylated two regions between embryo and endosperm are High CpG content promoters (HCPs) and high CpG content TTRs (HCTTRs). DNA methylation peaks distinction of mitochondria and chloroplast DNA were less than the nucleus DNA. Our results indicated that DNA methylation is associated with the gene silencing or gene activation in maize endosperm and embryo. Many genes involved in embryogenesis and seed development were found differentially methylated in embryo and endosperm. We found 17 endosperm-specific expressed imprinting genes were hypomethylated in endosperm and were hypermethylated in embryo. The expression of a maize DEMETER -like (DME-like) gene and MBD101 gene (MBD4 homolog) which direct bulk genome DNA demethylation were higher in endosperm than in embryo. These two genes may be associated with the distinct methylation level across maize embryo and endosperm.The methylomes of maize embryo and endosperm was obtained by MeDIP-seq method. The global mapping of maize embryo and endosperm methylation in this study broadened our knowledge of DNA methylation patterns in maize genome, and provided useful information for future studies on maize seed development and regulation of metabolic pathways in different seed tissues.

Project description:Epigenetic modification plays important roles in plant and animal development. DNA methylation can impact the transposable element (TE) silencing, gene imprinting and regulate gene expression.Through a genome-wide analysis, DNA methylation peaks were respectively characterized and mapped in maize embryo and endosperm genome. Distinct methylation level across maize embryo and endosperm was observed. The maize embryo genome contained more DNA methylation peaks than endosperm. However, the endosperm chloroplast genome contained more DNA methylation peaks to compare with the embryo chloroplast genome. DNA methylation regions were characterized and mapped in genome. More CG island (CGI) shore are methylated than CGI in maize suggested that DNA methylation level is not positively correlated with CpG density. The DNA methylation occurred more frequently in the promoter sequence and transcriptional termination region (TTR) than other regions of the genes. The result showed that 99% TEs we characterized are methylated in maize embryo, but some (34.8%) of them are not methylated in endosperm. Maize embryo and endosperm exhibit distinct pattern/level of methylation. The most differentially methylated two regions between embryo and endosperm are High CpG content promoters (HCPs) and high CpG content TTRs (HCTTRs). DNA methylation peaks distinction of mitochondria and chloroplast DNA were less than the nucleus DNA. Our results indicated that DNA methylation is associated with the gene silencing or gene activation in maize endosperm and embryo. Many genes involved in embryogenesis and seed development were found differentially methylated in embryo and endosperm. We found 17 endosperm-specific expressed imprinting genes were hypomethylated in endosperm and were hypermethylated in embryo. The expression of a maize DEMETER -like (DME-like) gene and MBD101 gene (MBD4 homolog) which direct bulk genome DNA demethylation were higher in endosperm than in embryo. These two genes may be associated with the distinct methylation level across maize embryo and endosperm.The methylomes of maize embryo and endosperm was obtained by MeDIP-seq method. The global mapping of maize embryo and endosperm methylation in this study broadened our knowledge of DNA methylation patterns in maize genome, and provided useful information for future studies on maize seed development and regulation of metabolic pathways in different seed tissues. Examination of DNA methylated modifications in 2 maize tissues.

Project description:Barley (Hordeum vulgare) is one of the major food sources for humans and forage source for animal livestock. Barley endosperm is structured into three distinct cell layers: the starchy endosperm, which acts essentially as storage tissue for starch, the subaleurone, which is characterized by a high accumulation of endoplasmic reticulum (ER)-derived seed storage proteins (SSP) and finally the aleurone beside the seed coat with a prominent role during seed germination. Prolamins account for more than 50% of the total protein amount in mature seeds. Together with other seed storage proteins (SSPs) they are important for both grain quality and flour quality. Prolamins are synthesized on the rough ER, translocated into the ER lumen and accumulate in distinct, ER-derived protein bodies (PBs) that are most abundant in the SE. PB formation is regulated by the protein disulfide isomerase (PDI) that is involved in the disulfide transfer pathway. Here, we used laser microdisection (LMD) to characterize spatio-temporal molecular and morphological differences of the ER during barley endosperm development. We revealed by nanoLC-MS/MS proteomic analyses performed on whole seeds and collected tissues at different seed development stages that the protein level of the protein disulfide isomerase HvPDIL1-1 is spatio-temporally regulated in developing barley endosperm. Our microscopic studies showed that HvPDIL1-1 preferentially accumulates in SE, especially at 12 days after pollination (dap). HvPDIL1-1 re-localized from PBs to the protein matrix at the periphery of starch granules along grain filling process. Detailed analysis of SE proteome dynamics identified clusters of proteins with similar expression pattern as HvPDIL1-1, which were analysed in a protein-protein network. It revealed a strong functional interconnection between transcription and translation, protein folding and amino acid synthesis with sucrose and starch metabolism. Our data indicate a role of HvPDIL1-1 in the coordination of protein synthesis and prolamins deposition during grain filling processes in developing barley endosperm. These results are discussed in relation to the putative role of HvPDIL1-1 for cereal food end-product quality and recombinant protein production in cereal seeds.

Project description:Gene expression profiling of embryo and endosperm at 7-42 days after flowering (DAF) was performed to obtain an overall signature of the rice transcriptome during grain development and maturation. After the onset of pollination, embryo and endosperm samples at 7, 10, 14, 21, 28 and 42 DAF with three replicates were collected and used for microarray analysis. A total of 36 embryo and endosperm microarray data were obtained.

Project description:Gene expression profiling of embryo and endosperm at 7-42 days after flowering (DAT) was performed to obtain an overall signature of the rice transcriptome during grain development and maturation.

Project description:Grain filling and proper grain development are essential biological processes in the plant’s life cycle, which majorly contributes to the final seed yield and quality in all cereal crop. However, very scarcely this knowledge is available in the literature regarding how the different wheat grain components contribute to the overall development of the seed. We performed a proteomics and metabolomics analysis in four different developing components of the wheat grain (seed coat, embryo, endosperm and cavity fluid) to characterize molecular processes during early and late grain development. In-gel shotgun proteomics analysis in 12, 15, 20 and 25 days after anthesis (DAA) lead us to identify and quantify 15,484 proteins out of which 410 differentially expressed proteins (DEPs) were identified in the seed coat, 815 in embryo, 372 in endosperm and 492 in cavity fluid. The abundance of selected protein candidates revealed spatially and temporally resolved protein functions associated with development and grain filling. Multiple proteins such as pyruvate phosphate dikinase (PPDK) and 14 -3- 3 undergo a major change in abundance during wheat grain development. Proteins binned into the functional category of cell growth /division were highly expressed during early stages (12 and 15 DAA) whereas those of starch biosynthesis in the middle or late stages. At the metabolome level all tissues and especially the cavity fluid showed highly distinct metabolite profiles. The tissue specific data are integrated with biochemical networks to explore a comprehensive map of molecular processes during grain filling and developmental processes.

Project description:Endosperm is an absorptive structure that supports embryo development or seedling germination in angiosperms. The endosperm of cereals is a main source of food, feed, and industrial raw materials worldwide. However, the gene regulatory networks that control endosperm cell differentiation remain largely unclear. As a first step toward characterizing these networks, we profiled the mRNAs in five major cell types of the differentiating endosperm and in the embryo and four maternal compartments of the kernel. Comparisons of these mRNA populations revealed the diverged gene expression programs between filial and maternal compartments, and an unexpected close correlation between embryo and the aleurone layer of endosperm. Gene co-expression network analysis identified co-expression modules associated with single or multiple kernel compartments including modules for the endosperm cell types, some of which showed enrichment of previously identified temporally activated and/or imprinted genes. Detailed analyses of a co-expression module highly correlated with the basal endosperm transfer layer (BETL) identified a regulatory module activated by MRP-1, a regulator of BETL differentiation and function. These results provide a high-resolution atlas of gene activity in the compartments of the maize kernel and help to uncover the regulatory modules associated with the differentiation of the major endosperm cell types. RNAs from ten compartments of the maize kernel including the central starchy endosperm (CSE), conducting zone (CZ), aleurone (AL), basal endosperm transfer layer (BETL), embryo-surrounding region (ESR), nucellus (NU), pericarp (PE), placenta-chalazal region (PC), the vascular region of the pedicel (PED), and the embryo (EMB) were isolated at 8 days after pollination (DAP) using laser-capture microdissection and sequenced using an Illumina HiSeq 2000 platform.