Project description:The endosperm of cereal grains feeds the entire world as major food supply, however little is known for its defense responses during endosperm development. Inducer of CBF Expression 1 (ICE1) is a known regulator of cold tolerance in plants. ICE1 has a monocot-specific homologue that is preferentially expressed in cereal grains but with an unclear regulatory function. Here, we characterized the function of monocot-specific ZmICE1 (ZmICE1a) in maize (Zea mays) kernel. mRNA in situ hybridization (ISH) revealed that ZmICE1a is predominantly expressed in the peripheral endosperm (AL, SAL, and BETL). Loss-of-function of ZmICE1a reduced starch content and kernel weight. RNA-seq analysis revealed contradicted expression patterns between starch synthesis genes and genes involved in defense and phytohormone synthesis in zmice1a developing endosperm. Coupled with CUT&Tag-seq analysis, we found that ZmICE1a positively regulates genes in starch synthesis, while negatively regulates genes in AL-specific defense and the synthesis of IAA and JA. Explant assays revealed that exogenous IAA or JA induces the expression of numerous defense genes. mRNA ISH assays revealed that the defense genes induced by IAA and JA, exhibit distinct spatial specific expression in BETL and SAL, respectively. Moreover, we dissected a JA-ZmJAZ9-ZmICE1a-MPI signaling axis involved in JA-mediated defense regulation. Overall, our study revealed ZmICE1a as a key regulatory for endosperm defense responses, and coordinates defense-storage tradeoffs during endosperm development.

Project description:The kernel serves as a storage organ for various nutrients and determines the yield and quality of maize. Understanding the mechanisms regulating kernel development is important for maize production. In this study, a small kernel mutant smk7a of maize was characterized. Cytological observation suggested that the development of the endosperm and embryo was arrested in smk7a in the early development stage. Biochemical tests revealed that the starch, zein protein, and indole-3-acetic acid (IAA) contents were significantly lower in smk7a compared with wild-type (WT). Consistent with the defective development phenotype, transcriptome analysis of the kernels 12 and 20 days after pollination (DAP) revealed that the starch, zein, and auxin biosynthesis related genes were dramatically downregulated in smk7a. Genetic mapping indicated that the mutant was controlled by a recessive gene located on chromosome 2. Our results suggest that disrupted nutrition accumulation and auxin synthesis cause the defective endosperm and embryo development of smk7a.

Project description:OsbZIP58 is a regulator of starch synthesis in rice endosperm. T-DNA insertion null mutants of this gene showed a white belly phenotype indicating an altered starch composition and content. We further investigated how reduction of OsbZIP58 gene expression caused these changes by analyzing the transcriptomes in the immature endosperm at 9 DAF of the wild-type and osbzip58-1 mutants by microarray analysis.

Project description:Starch synthesis is an essential feature for crops, but its regulatory mechanism has been largely restricted to transcription factors. Starch synthesis parallels the endosperm development in maize. we obtained transcriptome, small RNAome and DNA methylome data from the multiple developing stages of endosperms, as well as kernel and leaf, via applying RNA-seq, sRNA-seq and BS-seq technologies. We demonstrated that genome-wide gene expression makes a sharp transition at the point when starch accumulation speeds between DAP 10-13, while the enriched up-regulation of starch and sucrose metabolism genes occurs earlier at DAP 9-10. Expression pattern analysis establishes a comprehensive network between starch synthesis genes and transcription factors. MiRNAs negatively regulating TF expression were extensively downregulated during maize endosperm development. We showed that TF ZmMYB33 and ZmMYB65 promotes the transcription of the GUS reporter under the control of Wx and Sbe2b/Bt2 gene promoters containing their binding motifs, respectively. We further showed that the abundantly expressed miR159k-3p negatively regulate the expression of these two transcription factors, suggesting that miRNAs are important regulators of starch synthesis. In addition, we showed that both starch synthesis genes and miRNAs are globally repressed by DNA methylation, while transcription factors are not. Taken together, the presented results establish the regulatory functions of miRNAs and DNA methylation in starch synthesis, and indicates DNA methylation as the master switch.

Project description:Starch synthesis is an essential feature for crops, but its regulatory mechanism has been largely restricted to transcription factors. Starch synthesis parallels the endosperm development in maize. we obtained transcriptome, small RNAome and DNA methylome data from the multiple developing stages of endosperms, as well as kernel and leaf, via applying RNA-seq, sRNA-seq and BS-seq technologies. We demonstrated that genome-wide gene expression makes a sharp transition at the point when starch accumulation speeds between DAP 10-13, while the enriched up-regulation of starch and sucrose metabolism genes occurs earlier at DAP 9-10. Expression pattern analysis establishes a comprehensive network between starch synthesis genes and transcription factors. MiRNAs negatively regulating TF expression were extensively downregulated during maize endosperm development. We showed that TF ZmMYB33 and ZmMYB65 promotes the transcription of the GUS reporter under the control of Wx and Sbe2b/Bt2 gene promoters containing their binding motifs, respectively. We further showed that the abundantly expressed miR159k-3p negatively regulate the expression of these two transcription factors, suggesting that miRNAs are important regulators of starch synthesis. In addition, we showed that both starch synthesis genes and miRNAs are globally repressed by DNA methylation, while transcription factors are not. Taken together, the presented results establish the regulatory functions of miRNAs and DNA methylation in starch synthesis, and indicates DNA methylation as the master switch.

Project description:Starch synthesis is an essential feature for crops, but its regulatory mechanism has been largely restricted to transcription factors. Starch synthesis parallels the endosperm development in maize. we obtained transcriptome, small RNAome and DNA methylome data from the multiple developing stages of endosperms, as well as kernel and leaf, via applying RNA-seq, sRNA-seq and BS-seq technologies. We demonstrated that genome-wide gene expression makes a sharp transition at the point when starch accumulation speeds between DAP 10-13, while the enriched up-regulation of starch and sucrose metabolism genes occurs earlier at DAP 9-10. Expression pattern analysis establishes a comprehensive network between starch synthesis genes and transcription factors. MiRNAs negatively regulating TF expression were extensively downregulated during maize endosperm development. We showed that TF ZmMYB33 and ZmMYB65 promotes the transcription of the GUS reporter under the control of Wx and Sbe2b/Bt2 gene promoters containing their binding motifs, respectively. We further showed that the abundantly expressed miR159k-3p negatively regulate the expression of these two transcription factors, suggesting that miRNAs are important regulators of starch synthesis. In addition, we showed that both starch synthesis genes and miRNAs are globally repressed by DNA methylation, while transcription factors are not. Taken together, the presented results establish the regulatory functions of miRNAs and DNA methylation in starch synthesis, and indicates DNA methylation as the master switch.

Project description:OsbZIP58 is a regulator of starch synthesis in rice endosperm. T-DNA insertion null mutants of this gene showed a white belly phenotype indicating an altered starch composition and content. We further investigated how reduction of OsbZIP58 gene expression caused these changes by analyzing the transcriptomes in the immature endosperm at 9 DAF of the wild-type and osbzip58-1 mutants by microarray analysis. 9 DAF endosperm of Dongjin (wild type) and osbzip58-1 were used to compare the gene expresion, and three independent biological replicates for each material.

Project description:Endosperm is a product of double fertilization, and provides nutrients and signals to the embryo during seed development in flowering plants. Early stages of endosperm development are critical for the development of its storage capacity through synthesis and accumulation of starch and storage proteins. Here we report on the isolation and sequencing of mRNAs from the central portion of the starchy endosperm of Zea mays (maize) B73 at 6 days after pollination. We detected high correlation among the four biological replicates of RNAs isolated using laser-capture microdissection of the cell type. Because the assayed stage of development precedes the synthesis and accumulation of the major storage proteins and starch in the endosperm, our dataset likely include mRNAs for genes that are involved in control and establishment of these developmental programs.

Project description:To uncover the mechanisms underlying pear fruit response to boron application, a comprehensive transcriptome analysis was performed. Boron application significantly induced expression of sorbitol metabolism and sucrose metabolism genes.Boron application also increased the expression of starch degradation, fatty acid synthesis, IAA degradation, GA synthesis and inhibit the expression of ethylene synthesis gene.

Project description:Endosperm is a product of double fertilization, and provides nutrients and signals to the embryo during seed development in flowering plants. Early stages of endosperm development are critical for the development of its storage capacity through synthesis and accumulation of starch and storage proteins. Here we report on the isolation and sequencing of mRNAs from the central portion of the starchy endosperm of Zea mays (maize) B73 at 6 days after pollination. We detected high correlation among the four biological replicates of RNAs isolated using laser-capture microdissection of the cell type. Because the assayed stage of development precedes the synthesis and accumulation of the major storage proteins and starch in the endosperm, our dataset likely include mRNAs for genes that are involved in control and establishment of these developmental programs. Four replicates of mRNAs from the central portion of starchy endopserm were isolated using laser-capture microdissection and sequenced using the Illumina GAIIx platform.