Research has shown that the hypomagnetic field(HMF)can affect embryo development,cell proliferation,learning and memory,and in vitro tubulin assembly.In the present study,we aimed to elucidate the molecular mechanism ...Research has shown that the hypomagnetic field(HMF)can affect embryo development,cell proliferation,learning and memory,and in vitro tubulin assembly.In the present study,we aimed to elucidate the molecular mechanism by which the HMF exerts its effect,by comparing the transcriptome profiles of human neuroblastoma cells exposed to either the HMF or the geomagnetic field.A total of 2464 differentially expressed genes(DEGs)were identified,216 of which were up-regulated and2248 of which were down-regulated after exposure to the HMF.These DEGs were found to be significantly clustered into several key processes,namely macromolecule localization,protein transport,RNA processing,and brain function.Seventeen DEGs were verified by real-time quantitative PCR,and the expression levels of nine of these DEGs were measured every 6 h.Most notably,MAPK1 and CRY2,showed significant up-and down-regulation,respectively,during the first 6 h of HMF exposure,which suggests involvement of the MAPK pathway and cryptochrome in the early bio-HMF response.Our results provide insights into the molecular mechanisms underlying the observed biological effects of the HMF.展开更多
This thematic issue of Science China Life Sciences, "From brain function to therapy", highlights some of the exciting research being undertaken in the Joint Laboratory of Neu- roscience and Cognition, an internation...This thematic issue of Science China Life Sciences, "From brain function to therapy", highlights some of the exciting research being undertaken in the Joint Laboratory of Neu- roscience and Cognition, an international scientific collabo- ration between the Queensland Brain Institute (QBI) at The University of Queensland and the Institute of Biophysics (IBP) within the Chinese Academy of Sciences.展开更多
New neurons are continuously generated from resident pools of neural stem and precursor cells(NSPCs)in the adult brain.There are multiple pathways through which adult neurogenesis is regulated,and here we review the r...New neurons are continuously generated from resident pools of neural stem and precursor cells(NSPCs)in the adult brain.There are multiple pathways through which adult neurogenesis is regulated,and here we review the role of the N-methyl-D-aspartate receptor(NMDAR)in regulating the proliferation of NSPCs in the adult hippocampus.Hippocampal-dependent learning tasks,enriched environments,running,and activity-dependent synaptic plasticity,all potently up-regulate hippocampal NSPC proliferation.We first consider the requirement of the NMDAR in activity-dependent synaptic plasticity,and the role the induction of synaptic plasticity has in regulating NSPCs and newborn neurons.We address how specific NMDAR agonists and antagonists modulate proliferation,both in vivo and in vitro,and then review the evidence supporting the hypothesis that NMDARs are present on NSPCs.We believe it is important to understand the mechanisms underlying the activation of adult neurogenesis,given the potential that endogenous stem cell populations have for repopulating the hippocampus with functional new neurons.In conditions such as age-related memory decline,neurodegeneration and psychiatric disease,mature neurons are lost or become defective;as such,stimulating adult neurogenesis may provide a therapeutic strategy to overcome these conditions.展开更多
Although tau is mainly known as an axonal microtubule-associated protein,many studies indicate that it is not restricted to this subcellular compartment.Assessing tau’s subcellular distribution,however,is not trivial...Although tau is mainly known as an axonal microtubule-associated protein,many studies indicate that it is not restricted to this subcellular compartment.Assessing tau’s subcellular distribution,however,is not trivial as is evident from transgenic mouse studies.When human tau is over-expressed,it can be immunohistochemically localized to axons and the somatodendritic domain,modeling what is found in neurodegenerative diseases such as Alzheimer’s disease.Yet,in wild-type mice,despite its abundance,tau is difficult to visualize even in the axon.It is even more challenging to detect this protein in the nucleus,where tau has been proposed to protect DNA from damage.To establish a framework for future studies into tau’s nuclear functions,we compared several methods to visualize endogenous nuclear tau in cell lines and mouse brain.While depending on the fixation and permeabilization protocol,we were able to detect nuclear tau in SH-SY5Y human neuroblastoma cells,we failed to do so in N2a murine neuroblastoma cells.As a second method we used subcellular fractionation of mouse tissue and found that in the nucleus tau is mainly present in a hypophosphorylated form.When either full-length or truncated human tau was expressed,both accumulated in the cytoplasm,but were also found in the nuclear fraction.Because subcellular fractionation methods have their limitations,we finally isolated nuclei to probe for nuclear tau and found that the nuclei were free of cytoplasmic contamination.Together our analysis identifies several protocols for detecting tau in the nucleus where it is found in a less phosphorylated form.展开更多
基金supported by the Queensland-Chinese Academy of Sciences(QCAS)Biotechnology Fund(GJHZ1131)the Project of Chinese Academy of Sciences for the Development of Major Scientific Research Equipment(YZ201148)+1 种基金the National Natural Science Foundation of China(31200628)the External Cooperation Program of Bureau of International Cooperation,Chinese Academy of Sciences(GJHZ201302)
文摘Research has shown that the hypomagnetic field(HMF)can affect embryo development,cell proliferation,learning and memory,and in vitro tubulin assembly.In the present study,we aimed to elucidate the molecular mechanism by which the HMF exerts its effect,by comparing the transcriptome profiles of human neuroblastoma cells exposed to either the HMF or the geomagnetic field.A total of 2464 differentially expressed genes(DEGs)were identified,216 of which were up-regulated and2248 of which were down-regulated after exposure to the HMF.These DEGs were found to be significantly clustered into several key processes,namely macromolecule localization,protein transport,RNA processing,and brain function.Seventeen DEGs were verified by real-time quantitative PCR,and the expression levels of nine of these DEGs were measured every 6 h.Most notably,MAPK1 and CRY2,showed significant up-and down-regulation,respectively,during the first 6 h of HMF exposure,which suggests involvement of the MAPK pathway and cryptochrome in the early bio-HMF response.Our results provide insights into the molecular mechanisms underlying the observed biological effects of the HMF.
文摘This thematic issue of Science China Life Sciences, "From brain function to therapy", highlights some of the exciting research being undertaken in the Joint Laboratory of Neu- roscience and Cognition, an international scientific collabo- ration between the Queensland Brain Institute (QBI) at The University of Queensland and the Institute of Biophysics (IBP) within the Chinese Academy of Sciences.
文摘New neurons are continuously generated from resident pools of neural stem and precursor cells(NSPCs)in the adult brain.There are multiple pathways through which adult neurogenesis is regulated,and here we review the role of the N-methyl-D-aspartate receptor(NMDAR)in regulating the proliferation of NSPCs in the adult hippocampus.Hippocampal-dependent learning tasks,enriched environments,running,and activity-dependent synaptic plasticity,all potently up-regulate hippocampal NSPC proliferation.We first consider the requirement of the NMDAR in activity-dependent synaptic plasticity,and the role the induction of synaptic plasticity has in regulating NSPCs and newborn neurons.We address how specific NMDAR agonists and antagonists modulate proliferation,both in vivo and in vitro,and then review the evidence supporting the hypothesis that NMDARs are present on NSPCs.We believe it is important to understand the mechanisms underlying the activation of adult neurogenesis,given the potential that endogenous stem cell populations have for repopulating the hippocampus with functional new neurons.In conditions such as age-related memory decline,neurodegeneration and psychiatric disease,mature neurons are lost or become defective;as such,stimulating adult neurogenesis may provide a therapeutic strategy to overcome these conditions.
基金supported by the Estate of Dr.Clem Jones AO and the Aus-tralia-China Joint Laboratory of Neuroscience and Cognition,as well as grants from the Australian Research Councilthe National Health and Medical Research Council of Australia to Jürgen Gtz
文摘Although tau is mainly known as an axonal microtubule-associated protein,many studies indicate that it is not restricted to this subcellular compartment.Assessing tau’s subcellular distribution,however,is not trivial as is evident from transgenic mouse studies.When human tau is over-expressed,it can be immunohistochemically localized to axons and the somatodendritic domain,modeling what is found in neurodegenerative diseases such as Alzheimer’s disease.Yet,in wild-type mice,despite its abundance,tau is difficult to visualize even in the axon.It is even more challenging to detect this protein in the nucleus,where tau has been proposed to protect DNA from damage.To establish a framework for future studies into tau’s nuclear functions,we compared several methods to visualize endogenous nuclear tau in cell lines and mouse brain.While depending on the fixation and permeabilization protocol,we were able to detect nuclear tau in SH-SY5Y human neuroblastoma cells,we failed to do so in N2a murine neuroblastoma cells.As a second method we used subcellular fractionation of mouse tissue and found that in the nucleus tau is mainly present in a hypophosphorylated form.When either full-length or truncated human tau was expressed,both accumulated in the cytoplasm,but were also found in the nuclear fraction.Because subcellular fractionation methods have their limitations,we finally isolated nuclei to probe for nuclear tau and found that the nuclei were free of cytoplasmic contamination.Together our analysis identifies several protocols for detecting tau in the nucleus where it is found in a less phosphorylated form.
