Neural stem cell is presently the research hotspot in neuroscience. Recent progress indicates that epigenetic modulation is closely related to the self-renewal and differentiation of neural stem cell. Epigenetics refe...Neural stem cell is presently the research hotspot in neuroscience. Recent progress indicates that epigenetic modulation is closely related to the self-renewal and differentiation of neural stem cell. Epigenetics refer to the study of mitotical/meiotical heritage changes in gene function that cannot be explained by changes in the DNA sequence. Major epigenetic mechanisms include DNA methylation, histone modification, chromatin remodeling, genomic imprinting, and non-coding RNA. In this review, we focus on the new insights into the epigenetic mechanism for neural stem cells fate.展开更多
●LateSoil feedback will change EarlySp and MidSp nutrient utilization strategies.●LateSp plant feedback will change the N restriction of microorganisms.●The intensity of plant P limitation diminishes with successi...●LateSoil feedback will change EarlySp and MidSp nutrient utilization strategies.●LateSp plant feedback will change the N restriction of microorganisms.●The intensity of plant P limitation diminishes with succession.●Enzyme activity more significantly affects plant nutrients than soil nutrients.●N and P remain major influences on vegetation growth after PSF impacts.●MidSp and LateSp are more affected by soil water-soluble and fast-acting nutrients.The response of plant−soil−microbial nutrients and stoichiometry to plant−soil feedback(PSF)during secondary succession(SS)is an important driver of plant−community recovery.However,the plant−soil−microbe responses to PSF during SS are unknown.The effects of PSF on plants at different successional stages and successional soils regulated by these plants were tested in this study by potting experiments.Results indicated that soils conditioned by Setaria viridis(EarlySoil)and soils conditioned by Artemisia sacrorum(MidSoil)feedback significantly increased the potassium content of Artemisia sacrorum(MidSp)and Bothriochloa ischaemum(LateSp),respectively.MidSp and Setaria viridis(EarlySp)aboveground carbon,nitrogen,and phosphorus contents were promoted by soils conditioned by Bothriochloa ischaemum(LateSoil)and MidSoil,respectively,but provided negative feedbacks on below-ground carbon and phosphorus.The EarlySp and MidSp significantly increased other nutrients in the MidSoil and LateSoil except water-soluble nutrients,the LateSp and MidSp significantly increased the soil nutrients in the MidSoil and EarlySoil,and the MidSp significantly increased their enzyme activity most significantly.Despite the significant impact of PSF on plant stoichiometry,reducing the intensity of phosphorus limitation,plant growth was always phosphorus limited.PSF changed the nitrogen limit of microorganisms,but microorganisms were always limited by phosphorus.Soil physicochemical properties and microbial abundance regulated by MidSp(or EarlySp)were facilitated by LateSp(or MidSp),which ultimately accelerated the SS process.This confirmed the irreversibility of SS and provided new information on plant-soil-microbe dynamics during SS.展开更多
文摘Neural stem cell is presently the research hotspot in neuroscience. Recent progress indicates that epigenetic modulation is closely related to the self-renewal and differentiation of neural stem cell. Epigenetics refer to the study of mitotical/meiotical heritage changes in gene function that cannot be explained by changes in the DNA sequence. Major epigenetic mechanisms include DNA methylation, histone modification, chromatin remodeling, genomic imprinting, and non-coding RNA. In this review, we focus on the new insights into the epigenetic mechanism for neural stem cells fate.
基金Funded by Key Laboratory of Degraded and Unused Land Consolidation Engineering,the Ministry of Natural Resources(Grant No.SXDJ2024-19)the Natural Science Foundation of Shaanxi Province(Grant No.2024JC-YBMS-194)+1 种基金Shaanxi Creative Talents Promotion Plan-Technological Innovation Team(Grant No.2023-CX-TD-37)the National Natural Science Foundation of China(Grant No.42107492).
文摘●LateSoil feedback will change EarlySp and MidSp nutrient utilization strategies.●LateSp plant feedback will change the N restriction of microorganisms.●The intensity of plant P limitation diminishes with succession.●Enzyme activity more significantly affects plant nutrients than soil nutrients.●N and P remain major influences on vegetation growth after PSF impacts.●MidSp and LateSp are more affected by soil water-soluble and fast-acting nutrients.The response of plant−soil−microbial nutrients and stoichiometry to plant−soil feedback(PSF)during secondary succession(SS)is an important driver of plant−community recovery.However,the plant−soil−microbe responses to PSF during SS are unknown.The effects of PSF on plants at different successional stages and successional soils regulated by these plants were tested in this study by potting experiments.Results indicated that soils conditioned by Setaria viridis(EarlySoil)and soils conditioned by Artemisia sacrorum(MidSoil)feedback significantly increased the potassium content of Artemisia sacrorum(MidSp)and Bothriochloa ischaemum(LateSp),respectively.MidSp and Setaria viridis(EarlySp)aboveground carbon,nitrogen,and phosphorus contents were promoted by soils conditioned by Bothriochloa ischaemum(LateSoil)and MidSoil,respectively,but provided negative feedbacks on below-ground carbon and phosphorus.The EarlySp and MidSp significantly increased other nutrients in the MidSoil and LateSoil except water-soluble nutrients,the LateSp and MidSp significantly increased the soil nutrients in the MidSoil and EarlySoil,and the MidSp significantly increased their enzyme activity most significantly.Despite the significant impact of PSF on plant stoichiometry,reducing the intensity of phosphorus limitation,plant growth was always phosphorus limited.PSF changed the nitrogen limit of microorganisms,but microorganisms were always limited by phosphorus.Soil physicochemical properties and microbial abundance regulated by MidSp(or EarlySp)were facilitated by LateSp(or MidSp),which ultimately accelerated the SS process.This confirmed the irreversibility of SS and provided new information on plant-soil-microbe dynamics during SS.
