Project description:Melatonin plays a potential role in multiple plant developmental processes and stress response. However, there are no reports regarding exogenous melatonin promoting rice seed germination under salinity and nor about the underlying molecular mechanisms at genome-wide. Here, we revealed that exogenous application of melatonin conferred roles in promoting rice seed germination under salinity. The putative molecular mechanisms of exogenous melatonin in promoting rice seed germination under high salinity were further investigated through metabolomic and transcriptomic analyses. The results state clearly that the phytohormone contents were reprogrammed, the activities of SOD, CAT, POD were enhanced, and the total antioxidant capacity was activated under salinity by exogenous melatonin. Additionally, melatonin-pre-treated seeds exhibited higher concentrations of glycosides than non-treated seeds under salinity. Furthermore, exogenous melatonin alleviated the accumulation of fatty acids induced by salinity. Genome-wide transcriptomic profiling identified 7160 transcripts that were differentially expressed in NaCl, MT100 and control. Pathway and GO term enrichment analysis revealed that genes involved in the response to oxidative stress, hormone metabolism, heme building, mitochondrion, tricarboxylic acid transformation were altered after melatonin pre-treatment under salinity. This study provides the first evidence of the protective roles of exogenous melatonin in increasing rice seed germination under salt stress, mainly via activation of antioxidants and modulation of metabolic homeostasis.

Project description:Background: Waterlogging was one of the most serious abiotic stresses in wheat-growing regions of China. There were great differences in waterlogging tolerance among different wheat varieties, and the mechanism of waterlogging tolerance of wheat seeds during germination was unclear. Methods: In order to reveal the adaptability of wheat to waterlogging stress during germination, we analyzed the germination rate and anatomical structure of three wheat seeds, ‘Zhoumai 22’, ‘Bainong 207’ and ‘Bainong 607’. At the same time, Illumina sequencing technology was used to determine the transcriptome of these three wheat varieties during germination. Results: The results showed that there was no significant difference between the germination rate of ‘Bainong 207’ after 3 days of waterlogging treatment and that of the control seeds. However, under waterlogging stress, the degree of emulsification and degradation of endosperm cells was higher than that of the control treatment, and starch granules in endosperm were significantly reduced. Transcriptome data were obtained from seed samples (a total of 18 samples) of three wheat varieties under waterlogging and control treatment. A total of 2,775 differentially expressed genes (DEGs) were identified by comprehensive analysis. In addition, by analyzing the correlation between the expression levels of DEGs and seed germination rates in three wheat varieties under waterlogging stress, it was found that the relative expression levels of 563 and 398 genes were positively and negatively correlated with the germination rate of wheat seeds, respectively. The GO and KEGG analysis found that the difference in waterlogging tolerance of the three wheat varieties was related to the abundance of key genes involved in the glycolysis pathway, the starch and sucrose metabolism pathway, and the lactose metabolism pathway. The ethanol dehydrogenase (ADH) gene in the endosperm of ‘Bainong 607’ was immediately induced after a short period of waterlogging, and the energy provided by glycolysis pathway enabled the seeds of ‘Bainong 607’ to germinate as early as possible, while the expression level of AP2/ERF transcription factor was up-regulated to further enhance its waterlogging tolerance. Conclusions: In general, this study provided a deeper understanding of the mechanisms by which different wheat varieties respond to waterlogging stress during germination.

Project description:Seed germination is a complicated physiological process, during which structures of mitochondria and plastids are recovered, and metabolisms are re-activated (Han and Yang, 2015). It has been shown that metabolism reactivation is very important for rice germination (He et al., 2011b;Han et al., 2014a). It is still unknown if protein acetylation involved in and regulate these metabolisms during rice seed germination. To answer this question, we globally profiled the acetylome in rice embryos from the germinating seeds. A number of acetylated enzymes were identified. The results provide more information about the metabolism regulation in germinating seeds.

Project description:To establish the basis for understanding molecular mechanism of seed germination response to temperature, we analyzed transcriptomes in freshly harvested dormant and dry stored after-ripened seeds. The after-ripened seeds started to show visible germination from 36h after the start of imbibition, and almost all the seeds germinated after 3 days. The freshly harvested seeds stayed dormant by imbibition at 26°C, and germination of the after-ripened seeds was almost completely inhibited at 34°C. Total RNA was prepared from 0 (dry), 6 and 24h imbibed seeds to find regulatory genes of seed dormancy and germination.

Project description:The acquisition of germination and post-embryonic developmental ability during seed maturation is vital for seed vigor, an important trait for plant propagation and crop production. How seed vigor is established in seeds is still poorly understood. Here, we report the crucial function of Arabidopsis histone variant H3.3 in chromatin structure regulation that endows seeds with post-embryonic developmental potentials. H3.3 is not essential for seed formation, but the loss of H3.3 results in severely impaired germination and post-embryonic development. H3.3 exhibits a seed-specific 5’ gene end distribution, which facilities chromatin opening in seeds. During germination, this H3.3-established chromatin accessibility is essential for proper gene transcriptional regulation. Moreover, H3.3 is constantly loaded at the 3’ gene end and restricts chromatin accessibility to prevent cryptic transcription and protect gene body DNA methylation. Our results suggest a fundamental role of H3.3 in initiating chromatin opening at regulatory regions in seed to license the embryonic to post-embryonic transition.

Project description:The acquisition of germination and post-embryonic developmental ability during seed maturation is vital for seed vigor, an important trait for plant propagation and crop production. How seed vigor is established in seeds is still poorly understood. Here, we report the crucial function of Arabidopsis histone variant H3.3 in chromatin structure regulation that endows seeds with post-embryonic developmental potentials. H3.3 is not essential for seed formation, but the loss of H3.3 results in severely impaired germination and post-embryonic development. H3.3 exhibits a seed-specific 5’ gene end distribution, which facilities chromatin opening in seeds. During germination, this H3.3-established chromatin accessibility is essential for proper gene transcriptional regulation. Moreover, H3.3 is constantly loaded at the 3’ gene end and restricts chromatin accessibility to prevent cryptic transcription and protect gene body DNA methylation. Our results suggest a fundamental role of H3.3 in initiating chromatin opening at regulatory regions in seed to license the embryonic to post-embryonic transition.

Project description:The acquisition of germination and post-embryonic developmental ability during seed maturation is vital for seed vigor, an important trait for plant propagation and crop production. How seed vigor is established in seeds is still poorly understood. Here, we report the crucial function of Arabidopsis histone variant H3.3 in chromatin structure regulation that endows seeds with post-embryonic developmental potentials. H3.3 is not essential for seed formation, but the loss of H3.3 results in severely impaired germination and post-embryonic development. H3.3 exhibits a seed-specific 5’ gene end distribution, which facilities chromatin opening in seeds. During germination, this H3.3-established chromatin accessibility is essential for proper gene transcriptional regulation. Moreover, H3.3 is constantly loaded at the 3’ gene end and restricts chromatin accessibility to prevent cryptic transcription and protect gene body DNA methylation. Our results suggest a fundamental role of H3.3 in initiating chromatin opening at regulatory regions in seed to license the embryonic to post-embryonic transition.

Project description:The acquisition of germination and post-embryonic developmental ability during seed maturation is vital for seed vigor, an important trait for plant propagation and crop production. How seed vigor is established in seeds is still poorly understood. Here, we report the crucial function of Arabidopsis histone variant H3.3 in chromatin structure regulation that endows seeds with post-embryonic developmental potentials. H3.3 is not essential for seed formation, but the loss of H3.3 results in severely impaired germination and post-embryonic development. H3.3 exhibits a seed-specific 5’ gene end distribution, which facilities chromatin opening in seeds. During germination, this H3.3-established chromatin accessibility is essential for proper gene transcriptional regulation. Moreover, H3.3 is constantly loaded at the 3’ gene end and restricts chromatin accessibility to prevent cryptic transcription and protect gene body DNA methylation. Our results suggest a fundamental role of H3.3 in initiating chromatin opening at regulatory regions in seed to license the embryonic to post-embryonic transition.

Project description:The acquisition of germination and post-embryonic developmental ability during seed maturation is vital for seed vigor, an important trait for plant propagation and crop production. How seed vigor is established in seeds is still poorly understood. Here, we report the crucial function of Arabidopsis histone variant H3.3 in chromatin structure regulation that endows seeds with post-embryonic developmental potentials. H3.3 is not essential for seed formation, but the loss of H3.3 results in severely impaired germination and post-embryonic development. H3.3 exhibits a seed-specific 5’ gene end distribution, which facilities chromatin opening in seeds. During germination, this H3.3-established chromatin accessibility is essential for proper gene transcriptional regulation. Moreover, H3.3 is constantly loaded at the 3’ gene end and restricts chromatin accessibility to prevent cryptic transcription and protect gene body DNA methylation. Our results suggest a fundamental role of H3.3 in initiating chromatin opening at regulatory regions in seed to license the embryonic to post-embryonic transition.

Project description:Seeds are highly resilient to the external environment, which allow plants to persist in unpredictable and unfavorable conditions. Some plant species have adopted a bet-hedging strategy to germinate a variable fraction of seeds in any given condition, and this could be explained by population-based threshold models. Here, in the model plant Arabidopsis (Arabidopsis thaliana) we induced secondary dormancy to address the transcriptional heterogeneity among seeds that leads to binary germination/non-germination outcomes. We developed a single seed RNA-seq strategy that allowed us to observe a reduction in seed transcriptional heterogeneity as seeds enter stress conditions, followed by an increase during recovery. We identified groups of genes whose expression showed a specific pattern through a time course and used these groups to position the individual seeds along the transcriptional gradient of germination competence. In agreement, transcriptomes of dormancy-deficient seeds (mutant of DELAY OF GERMINATION 1 gene) showed a shift towards higher values of the germination competence index. Interestingly, a significant fraction of genes with variable expression encoded translation-related factors. In summary, interrogating hundreds of single seed transcriptomes during secondary dormancy-inducing treatment revealed variability among the transcriptomes that could result from the distribution of population-based sensitivity thresholds. Our results also showed that single seed RNA-seq is the method of choice for analyzing seed bet-hedging-related phenomena.