A role of age-dependent DNA methylation reprogramming in regulating the regeneration capacity of Boea hygrometrica leaves
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The initiation and subsequent emergence of lateral roots from the tissues of the primary has been examined in attached and excised roots of Pisum. Lateral anlage inception took place in cultured roots which were 1 and 4 cm in length at the time of excision. However, whereas a few primordia completed their development and grew out as emerged laterals from those excised roots which were 4 cm long, at the onset of culturc none appeared on those which had an initial length of 1 cm. The changes which took place in the rate of cell proliferation in the apical millimetre of each batch of cultured roots with time following excision, were followed and related to the appearance or otherwise of secondary roots on the cultured primaries.
Primordium
Lateral root
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Reproductive decline in older female mice can be attributed to a failure of the uterus to decidualise in response to steroid hormones. Here, we show that normal decidualisation is associated with significant epigenetic changes. Notably, we identify a cohort of differentially methylated regions (DMRs), most of which gain DNA methylation between the early and late stages of decidualisation. These DMRs are enriched at progesterone-responsive gene loci that are essential for reproductive function. In female mice nearing the end of their reproductive lifespan, DNA methylation fidelity is lost at a number of CpG islands (CGIs) resulting in CGI hypermethylation at key decidualisation genes. Importantly, this hypermethylated state correlates with the failure of the corresponding genes to become transcriptionally upregulated during the implantation window. Thus, age-associated DNA methylation changes may underlie the decidualisation defects that are a common occurrence in older females. Alterations to the epigenome of uterine cells may therefore contribute significantly to the reproductive decline associated with advanced maternal age.
Epigenesis
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Sexual Differentiation
Illumina dye sequencing
RNA-Seq
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Primordium
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Root cap
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Wheat is one of the most important staple crops worldwide. Fusarium head blight severely reduces wheat yield and quality. Cultivation of a novel type of cleistogamous wheat mutant, ZK001, which was created by static magnetic field treatment, is a new strategy for controlling Fusarium head blight. However, little is known about the mechanism of cleistogamy in wheat. The present study demonstrated that anthers of ZK001 were retained on the glumes at all flowering stages, whereas those of YM18 were extruded from the paleae and lemmae. There was a clear difference in the morphological characteristics of lodicules between YM18 and ZK001. Lodicule calcium and potassium contents were significantly higher in YM18 than in ZK001 from white to yellow anther stages. In Fusarium head blight resistance, the diseased kernel rate and deoxynivalenol content of ZK001 were markedly lower than those of YM18 and QM725. Comparative transcriptome analysis of YM18 and ZK001 was performed to identify regulatory mechanisms of cleistogamy. The main differentially expressed genes identified in the spikelets of YM18 and ZK001 at the green anther stage were associated with cell walls, carbohydrates, phytohormones, water channel, and ion binding, transport, and homeostasis. These differentially expressed genes may play an important role in regulating cellular homeostasis, osmotic pressure, and lodicule development. The results indicate that ZK001 lost the ability to push the lemmae and paleae apart during the flowering stage because of the thin lodicules. ZK001 was speculated to provide structural barriers for Fusarium head blight during the flowering stage. The thin lodicule of ZK001 results from low levels of soluble sugar, calcium ions, and potassium ions in the lodicules. These levels are regulated by differentially expressed genes.
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