Project description:This was a comparative transcriptome analysis by using high throughput sequencing. To assess the effects of drought stress and NF-Y transcription factors ZmNF-YA1 and ZmNF-YB16 on maize, leaves from wild-type (W22), zmnf-ya1 (m67) mutant, wild-type (B104) and ZmNF-YB16 overexpression (OE) plants grow under well-watered and drought stress conditions were collected and RNAseq was performed. We tracked the gene expression events of inbred maize lines W22 or B104 seedlings in response to drought stress to evaluate how drought stress affects the gene expression program in maize. At the same time, we analyzed the effects of drought stress on gene expression in zmnf-ya1 and ZmNF-YB16 OE plants to investigate whether and how ZmNF-YA1 and ZmNF-YB16 confer drought stress tolerance in maize. Maize plants were grown under well-watered conditions until the V4 stage (zmnf-ya1 and W22) or V9 stage (ZmNF-YB16 OE and B104), and then half of them were exposed to drought stress treatment. Water loss in the soil and the electrolyte leakage from leaf cells were used to assess drought stress in plants. Leaves from 3-4 plants were pooled for each sample, and two replicates were used. RNA was extracted from small strips of leaf lamina excised from the first fully expanded leaf of the plants.

Project description:Cereal crops accumulate starch in seeds as an energy reserve. Sucrose synthase (SuSy) plays an important role in grain starch synthesis. In this study, ZmSUS1 was transformed into maize inbred line KN5585, and transgenic plants were obtained. Compared with the control, the content and activity of SuSy were significantly increased, the amylose content in mature seeds of transgenic maize increased by 41.1-69.2%, the total starch content increased by 5.0-13.5%, The 100-grain weight increased by 19.0-26.2% and the average diameter of starch granules increased by 10.8-17.2%. These results indicated that overexpression of ZmSUS1 can significantly improve the traits of maize kernels and obtain new lines with high amylose content. It was also found that ZmSUS1 may increase the amylose content by regulating the expression of Shrunken2 (Sh2) and Brittle2 (Bt2) which encodes endosperm ADP-glucose pyrophosphorylase (AGPase) size subunits, and the expression of Granule bound starchsynthase1 (GBSS1) and Starch synthase1 (SS1) which encodes starch synthase. This study proved the important role of ZmSUS1 in maize starch synthesis, and provided a new technology strategy for improving corn starch content and yield.

Project description:In plants, drought stress is a major growth limiting factor causing cell water loss through open stomata. In this study, guard cell-specific transcripts from drought-stressed Arabidopsis plants were analyzed and a down-regulation of β-amylase 1 (BAM1) was found. In previous studies, BAM1 was shown to be involved in stomatal starch degradation under ambient conditions. Impaired starch breakdown of bam1 mutant plants was accompanied by decreased stomatal opening. Here, we show that drought tolerance of bam1 mutant plants is improved as compared to wild type controls. Microarray-analysis of stomata-specific transcripts from bam1 mutant plants revealed a significant down-regulation of genes encoding aquaporins, auxin- and ethylene-responsive factors and cell-wall modifying enzymes. This expression pattern suggests that reduced water-uptake and limited cell wall extension are associated with the closed state of stomata of bam1 mutant plants. Together these data suggest that regulation of stomata-specific starch turnover is important for adapting stomata opening to environmental needs and its breeding manipulation may result in drought tolerant crop plants.

Project description:In plants, drought stress is a major growth limiting factor causing cell water loss through open stomata. In this study, guard cell-specific transcripts from drought-stressed Arabidopsis plants were analyzed and a down-regulation of β-amylase 1 (BAM1) was found. In previous studies, BAM1 was shown to be involved in stomatal starch degradation under ambient conditions. Impaired starch breakdown of bam1 mutant plants was accompanied by decreased stomatal opening. Here, we show that drought tolerance of bam1 mutant plants is improved as compared to wild type controls. Microarray-analysis of stomata-specific transcripts from bam1 mutant plants revealed a significant down-regulation of genes encoding aquaporins, auxin- and ethylene-responsive factors and cell-wall modifying enzymes. This expression pattern suggests that reduced water-uptake and limited cell wall extension are associated with the closed state of stomata of bam1 mutant plants. Together these data suggest that regulation of stomata-specific starch turnover is important for adapting stomata opening to environmental needs and its breeding manipulation may result in drought tolerant crop plants.

Project description:The mitogen-activated protein kinase (MAPK) cascade is an evolutionarily conserved signal transduction pathway that is involved in plant development and stress responses. As the first component of this phosphorelay cascade, mitogen-activated protein kinase kinase kinases (MAPKKKs) act as adaptors linking upstream signaling steps to the core MAPK cascade to promote the appropriate cellular responses; however, the functions of MAPKKKs in maize are unclear. Here, we identified 71 MAPKKK genes, of which 14 were novel, based on a computational analysis of the maize (Zea mays L.) genome. Using an RNA-seq analysis in the leaf, stem and root of maize under well-watered and drought-stress conditions, we identified 5,866 differentially expressed genes (DEGs), including 8 MAPKKK genes responsive to drought stress. Many of the DEGs were enriched in processes such as drought stress, abiotic stimulus, oxidation-reduction, and metabolic processes. The other way round, DEGs involved in processes such as oxidation, photosynthesis, and starch, proline, ethylene, and salicylic acid metabolism were clearly co-expressed with the MAPKKK genes. Furthermore, a quantitative real-time PCR (qRT-PCR) analysis was performed to assess the relative expression levels of MAPKKKs. Correlation analysis revealed that there was a significant correlation between expression levels of two MAPKKKs and relative biomass responsive to drought in 8 inbred lines. Our results indicate that MAPKKKs may have important regulatory functions in drought tolerance in maize.

Project description:In plants, drought stress is a major growth limiting factor causing cell water loss through open stomata. In this study, guard cell-specific transcripts from drought-stressed Arabidopsis plants were analyzed and a down-regulation of β-amylase 1 (BAM1) was found. In previous studies, BAM1 was shown to be involved in stomatal starch degradation under ambient conditions. Impaired starch breakdown of bam1 mutant plants was accompanied by decreased stomatal opening. Here, we show that drought tolerance of bam1 mutant plants is improved as compared to wild type controls. Microarray-analysis of stomata-specific transcripts from bam1 mutant plants revealed a significant down-regulation of genes encoding aquaporins, auxin- and ethylene-responsive factors and cell-wall modifying enzymes. This expression pattern suggests that reduced water-uptake and limited cell wall extension are associated with the closed state of stomata of bam1 mutant plants. Together these data suggest that regulation of stomata-specific starch turnover is important for adapting stomata opening to environmental needs and its breeding manipulation may result in drought tolerant crop plants. Stress induced gene expression in Arabidopsis leaves and Stomata was measured after exposure to single drought stress. Drought stress conditions were analysed for both, Col-0 plants and a T-DNA insertion line for β-amylase 1. Six week old plants were treated with drought stress (5 days) according to Prasch and Sonnewald, 2013. Two to three biological replicates have been hybridized for each treatment.

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:Constituting the final growth phase during the lifecycle of maize (Zea Mays L.), leaf senescence plays an important biological role in grain yield in crops. We undertook proteomic and physiological analyses in inbred line Yu816 in order to unravel the underlying mechanisms of leaf senescence induced by preventing pollination. A total of 6,941 proteins were identified by Isobaric tags for Relative and Absolute Quantitation (iTRAQ) analysis. Proteomic analyses between pollinated (POL) and non-pollinated (NONPOL) plants indicated that 973 different proteins accumulated in NONPOL plants. The accumulated proteins were classified into various groups, including response to stimuli, cellular processes, cell death and metabolic processes using functional analysis. Furthermore, in accordance with the changes in these different accumulated proteins, analysis of changes in leaf total soluble sugars and starch content showed that the prevention of pollination can disturb endogenousplant hormone and sugar metabolism and lead to ROS bursts, protein degradation and photosystem breakdown, eventually resulting in leaf senescence. This represents the first attempt at global proteome profiling in response to induced leaf senescence by preventing pollination in maize, and provides a better understanding of the molecular mechanisms involved in induced leaf senescence.Constituting the final growth phase during the lifecycle of maize (Zea Mays L.), leaf senescence plays an important biological role in grain yield in crops. We undertook proteomic and physiological analyses in inbred line Yu816 in order to unravel the underlying mechanisms of leaf senescence induced by preventing pollination. A total of 6,941 proteins were identified by Isobaric tags for Relative and Absolute Quantitation (iTRAQ) analysis. Proteomic analyses between pollinated (POL) and non-pollinated (NONPOL) plants indicated that 973 different proteins accumulated in NONPOL plants. The accumulated proteins were classified into various groups, including response to stimuli, cellular processes, cell death and metabolic processes using functional analysis. Furthermore, in accordance with the changes in these different accumulated proteins, analysis of changes in leaf total soluble sugars and starch content showed that the prevention of pollination can disturb endogenousplant hormone and sugar metabolism and lead to ROS bursts, protein degradation and photosystem breakdown, eventually resulting in leaf senescence. This represents the first attempt at global proteome profiling in response to induced leaf senescence by preventing pollination in maize, and provides a better understanding of the molecular mechanisms involved in induced leaf senescence.