Your search keyword '"Zilong Qiu"' showing total 214 results

201. Researching the Service-Quality to Power Customer Based on Ant Colony Algorithm and TOPSIS Method.

Author

Dongxiao Niu, Jialiang Lv, and Zilong Qiu

Published

2008

202. Supply chain network design based on fuzzy neural network and PSO.

Author

Yuansheng Huang, Zilong Qiu, and Qingchao Liu

Published

2008

203. Fuzzy BP neural network optimized by PSO for performance evaluation of the whole ecotype supply chain.

Author

Yuansheng Huang, Zilong Qiu, and Qingchao Liu

Published

2008

204. Network comprehensive optimization for schedule and cost in project construction based on PSO algorithm.

Author

Yuansheng Huang, Zilong Qiu, and Weina Zhang

Published

2008

205. Deep-brain magnetic stimulation promotes adult hippocampal neurogenesis and alleviates stress-related behaviors in mouse models for neuropsychiatric disorders.

Author

Yan Zhang, Rong-Rong Mao, Zhi-Fang Chen, Meng Tian, Da-Li Tong, Zheng-Run Gao, Min Huang, Xiao Li, Xiu Xu, Wen-Hao Zhou, Cheng-Yu Li, Jiang Wang, Lin Xu, and Zilong Qiu

Subjects

NEUROBEHAVIORAL disorders, DEVELOPMENTAL neurobiology, TRANSCRANIAL magnetic stimulation, PSYCHOLOGICAL stress, HIPPOCAMPUS (Brain)

Abstract

Background Repetitive Transcranial Magnetic Stimulation (rTMS)/ Deep-brain Magnetic Stimulation (DMS) is an effective therapy for various neuropsychiatric disorders including major depression disorder. The molecular and cellular mechanisms underlying the impacts of rTMS/DMS on the brain are not yet fully understood. Results Here we studied the effects of deep-brain magnetic stimulation to brain on the molecular and cellular level. We examined the adult hippocampal neurogenesis and hippocampal synaptic plasticity of rodent under stress conditions with deep-brain magnetic stimulation treatment. We found that DMS promotes adult hippocampal neurogenesis significantly and facilitates the development of adult new-born neurons. Remarkably, DMS exerts anti-depression effects in the learned helplessness mouse model and rescues hippocampal long-term plasticity impaired by restraint stress in rats. Moreover, DMS alleviates the stress response in a mouse model for Rett syndrome and prolongs the life span of these animals dramatically. Conclusions Deep-brain magnetic stimulation greatly facilitates adult hippocampal neurogenesis and maturation, also alleviates depression and stress-related responses in animal models. [ABSTRACT FROM AUTHOR]

Published

2014

206. A case report of Chinese brothers with inherited MECP2-containing duplication: autism and intellectual disability, but not seizures or respiratory infections.

Author

Xiu Xu, Qiong Xu, Ying Zhang, Xiaodi Zhang, Tianlin Cheng, Bingbing Wu, Yanhua Ding, Ping Lu, Jingjing Zheng, Min Zhang, Zilong Qiu, and Xiang Yu

Subjects

AUTISM, BRAIN diseases, EPILEPSY, TRANSCRIPTION factors, RESPIRATORY infections

Abstract

Background: Autistic spectrum disorders (ASDs) are a family of neurodevelopmental disorders with strong genetic components. Recent studies have shown that copy number variations in dosage sensitive genes can contribute significantly to these disorders. One such gene is the transcription factor MECP2, whose loss of function in females results in Rett syndrome, while its duplication in males results in developmental delay and autism. Case presentation: Here, we identified a Chinese family with two brothers both inheriting a 2.2 Mb MECP2-containing duplication (151,369,305--153,589,577) from their mother. In addition, both brothers also had a 213.7 kb duplication on Chromosome 2, inherited from their father. The older brother also carried a 48.4 kb duplication on Chromosome 2 inherited from the mother, and a 8.2 kb deletion at 11q13.5 inherited from the father. Based on the published literature, MECP2 is the most autism-associated gene among the identified CNVs. Consistently, the boys displayed clinical features in common with other patients carrying MECP2 duplications, including intellectual disability, autism, lack of speech, slight hypotonia and unsteadiness of movement. They also had slight dysmorphic features including a depressed nose bridge, large ears and midface hypoplasia. Interestingly, they did not exhibit other clinical features commonly observed in American-European patients with MECP2 duplication, including recurrent respiratory infections and epilepsy. Conclusions: To our knowledge, this is the first identification and characterization of Chinese Han patients with MECP2-containing duplications. Further cases are required to determine if the above described clinical differences are due to individual variations or related to the genetic background of the patients. [ABSTRACT FROM AUTHOR]

Published

2012

207. TOX3 regulates calcium-dependent transcription in neurons.

Author

Vuan, Shauna H., Zilong Qiu, and Ghosh, Anirvan

Subjects

*GENETIC transcription, *CALCIUM, *CARRIER proteins, *NERVOUS system, *CALCIUM-binding proteins

Abstract

We report the cloning and characterization of TOX3, a high mobility group box protein involved in mediating calcium-dependent transcription. TOX3 was identified as a calcium-dependent transactivator using the Transactivator Trap screen. We find that TOX3 interacts with both CAMP response element (CRE)-binding protein (CREB) and CREB-binding protein (CBP). and knockdown of the endogenous TOX3 by RNAi leads to significant reduction of calcium-induced c-fos expression and complete inhibition of calcium activation of the c-fos promoter. The effects of TOX3 on calcium-dependent transcription require the CRE elements. These observations identify TOX3 as an important regulator of calcium-dependent transcription and suggest that TOX3 exerts its effect on CRE-mediated transcription via its association with the CREB-CBP complex. [ABSTRACT FROM AUTHOR]

Published

2009

208. Calcium Activation of the LMO4 Transcription Complex and Its Role in the Patterning of Thalamocortical Connections.

Author

Kashani, Amir H., Zilong Qiu, Jurata, Linda, Soo-Kyung Lee, Pfaff, Samuel, Goebbels, Sandra, Nave, Klaus-Armin, and Ghosh, Anirvan

Subjects

*GENE expression, *NEURONS, *CALCIUM channels, *CALCIUM, *MICROTUBULES, *PROTEIN kinases, *CARRIER proteins

Abstract

Lasting changes in neuronal connectivity require calcium-dependent gene expression. Here we report the identification of LIM domainonly 4 (LMO4) as a mediator of calcium-dependent transcription in cortical neurons. Calcium influx via voltage-sensitive calcium channels and NMDA receptors contributes to synaptically induced LMO4-mediated transactivation. LMO4-mediated transcription is dependent on signaling via calcium/calmodulin-dependent protein (CaM) kinase IV and microtubule-associated protein (MAP) kinase downstream of synaptic stimulation. Coimmunoprecipitation experiments indicate that LMO4 can form a complex with cAMP response element-binding protein (CREB) and can interact with cofactor of LIM homeodomain protein 1 (CLIM1) and CLIM2. To evaluate the role of LMO4 in vivo, we examined the consequences of conditional loss of lmo4 in the forebrain, using the Cre-Lox gene-targeting strategy. The organization of the barrel field in somatosensory cortex is disrupted in mice in which lmo4 is deleted conditionally in the cortex. Specifically, in contrast to controls, thalamocortical afferents in conditional lmo4 null mice fail to segregate into distinct barrel-specific domains. These observations identify LMO4 as a calcium-dependent transactivator that plays a key role in patterning thalamocortical connections during development. [ABSTRACT FROM AUTHOR]

Published

2006

209. The protein phosphatase activity of PTEN is essential for regulating neural stem cell differentiation

Author

Zhi-Fang Chen, Jingjing Zhou, Ling-jie He, Guo-Qiang Cheng, Jingwen Lyu, Zilong Qiu, Cheng Cheng, Xiuya Yu, Tian-Lin Cheng, and Wenhao Zhou

Subjects

PTEN, Tumor suppressor gene, Neurogenesis, Cellular differentiation, Phosphatase, Short Report, Biology, Mice, Cellular and Molecular Neuroscience, Animals, Tensin, Protein phosphatase activity, Phosphorylation, Cyclic AMP Response Element-Binding Protein, Molecular Biology, Neurons, Neural stem cells, PTEN Phosphohydrolase, Cell Differentiation, Protein phosphatase 2, Enzyme Activation, Gene Knockdown Techniques, Differentiation, Lipid phosphatase activity, Cancer research, biology.protein, Mutant Proteins, RNA Interference, Gene Deletion

Abstract

Background The tumor suppressor gene Phosphatase and tensin homolog (PTEN) is highly expressed in neural progenitor cells (NPCs) and plays an important role in development of the central nervous system. As a dual-specificity phosphatase, the loss of PTEN phosphatase activity has been linked to various diseases. Results Here we report that the protein phosphatase activity of Pten is critical for regulating differentiation of neural progenitor cells. First we found that deletion of Pten promotes neuronal differentiation. To determine whether the protein or lipid phosphatase activity is required for regulating neuronal differentiation, we generated phosphatase domain-specific Pten mutations. Interestingly, only expression of protein phosphatase-deficient mutant Y138L could mimic the effect of knocking down Pten, suggesting the protein phosphatase of Pten is critical for regulating NPC differentiation. Importantly, we showed that the wild-type and lipid phosphatase mutant (G129E) forms of Pten are able to rescue neuronal differentiation in Pten knockout NPCs, but mutants containing protein phosphatase mutant cannot. We further found that Pten-dependent dephosphorylation of CREB is critical for neuronal differentiation. Conclusion Our data indicate that the protein phosphatase activity of PTEN is critical for regulating differentiation of NSCs during cortical development. Electronic supplementary material The online version of this article (doi:10.1186/s13041-015-0114-1) contains supplementary material, which is available to authorized users.

210. Novel function of PIWIL1 in neuronal polarization and migration via regulation of microtubule-associated proteins

Author

Mo-Fang Liu, Zilong Qiu, Si-yuan Chang, Xiao-bing Yuan, Lan-Tao Gou, Ping-Ping Zhao, and Mao-Jin Yao

Subjects

Small interfering RNA, endocrine system, Microtubule-associated protein, RNA Stability, Mitosis, Piwi-interacting RNA, Biology, Rats, Sprague-Dawley, Cellular and Molecular Neuroscience, Cell Movement, Polarization, Cell polarity, medicine, Animals, Humans, Gene silencing, RasiRNA, Molecular Biology, Cerebral Cortex, Neurons, Genetics, Spermatid, urogenital system, Research, Cell Polarity, DNA Methylation, Argonaute, Protein Structure, Tertiary, Cell biology, Microtubule-associated proteins, Mice, Inbred C57BL, PIWIL1, medicine.anatomical_structure, Radial migration, Gene Knockdown Techniques, Argonaute Proteins, Erratum

Abstract

Background Young neurons in the developing brain establish a polarized morphology for proper migration. The PIWI family of piRNA processing proteins are considered to be restrictively expressed in germline tissues and several types of cancer cells. They play important roles in spermatogenesis, stem cell maintenance, piRNA biogenesis, and transposon silencing. Interestingly a recent study showed that de novo mutations of PIWI family members are strongly associated with autism. Results Here, we report that PIWI-like 1 (PIWIL1), a PIWI family member known to be essential for the transition of round spermatid into elongated spermatid, plays a role in the polarization and radial migration of newborn neurons in the developing cerebral cortex. Knocking down PIWIL1 in newborn cortical neurons by in utero electroporation of specific siRNAs resulted in retardation of the transition of neurons from the multipolar stage to the bipolar stage followed by a defect in their radial migration to the proper destination. Domain analysis showed that both the RNA binding PAZ domain and the RNA processing PIWI domain in PIWIL1 were indispensable for its function in neuronal migration. Furthermore, we found that PIWIL1 unexpectedly regulates the expression of microtubule-associated proteins in cortical neurons. Conclusions PIWIL1 regulates neuronal polarization and radial migration partly via modulating the expression of microtubule-associated proteins (MAPs). Our finding of PIWIL1’s function in neuronal development implies conserved functions of molecules participating in morphogenesis of brain and germline tissue and provides a mechanism as to how mutations of PIWI may be associated with autism. Electronic supplementary material The online version of this article (doi:10.1186/s13041-015-0131-0) contains supplementary material, which is available to authorized users.

211. Deep-brain magnetic stimulation promotes adult hippocampal neurogenesis and alleviates stress-related behaviors in mouse models for neuropsychiatric disorders

Author

Zhi-Fang Chen, Zilong Qiu, Yan Zhang, Cheng-Yu Li, Zheng-Run Gao, Xiu Xu, Meng Tian, Min Huang, Dali Tong, Jiang Wang, Rong-Rong Mao, Xiao Li, Wenhao Zhou, and Lin Xu

Subjects

Aging, medicine.medical_specialty, Neurology, Neurogenesis, medicine.medical_treatment, Hippocampus, Stimulation, Deep-brain magnetic stimulation, Anxiety, Hippocampal formation, behavioral disciplines and activities, Rats, Sprague-Dawley, Mice, Cellular and Molecular Neuroscience, Rett syndrome, Neural Stem Cells, Neuroplasticity, medicine, Animals, Molecular Biology, MeCP2, Cell Proliferation, Neuronal Plasticity, Behavior, Animal, Depression, Research, Mental Disorders, Dentate gyrus, fungi, equipment and supplies, Transcranial Magnetic Stimulation, Rats, Mice, Inbred C57BL, Transcranial magnetic stimulation, Disease Models, Animal, Magnetic Fields, Phenotype, Gene Expression Regulation, Dentate Gyrus, Synapses, Long-term potentiation, Adult hippocampal neurogenesis, Psychology, human activities, Neuroscience, Stress, Psychological

Abstract

Background Repetitive Transcranial Magnetic Stimulation (rTMS)/ Deep-brain Magnetic Stimulation (DMS) is an effective therapy for various neuropsychiatric disorders including major depression disorder. The molecular and cellular mechanisms underlying the impacts of rTMS/DMS on the brain are not yet fully understood. Results Here we studied the effects of deep-brain magnetic stimulation to brain on the molecular and cellular level. We examined the adult hippocampal neurogenesis and hippocampal synaptic plasticity of rodent under stress conditions with deep-brain magnetic stimulation treatment. We found that DMS promotes adult hippocampal neurogenesis significantly and facilitates the development of adult new-born neurons. Remarkably, DMS exerts anti-depression effects in the learned helplessness mouse model and rescues hippocampal long-term plasticity impaired by restraint stress in rats. Moreover, DMS alleviates the stress response in a mouse model for Rett syndrome and prolongs the life span of these animals dramatically. Conclusions Deep-brain magnetic stimulation greatly facilitates adult hippocampal neurogenesis and maturation, also alleviates depression and stress-related responses in animal models.

212. MeCP2 Plays an Analgesic Role in Pain Transmission through Regulating CREB / miR-132 Pathway

Author

Jieyu Qi, Ran Zhang, Li-Yang Chiang, Zilong Qiu, Zhijuan Cao, and Min Huang

Subjects

congenital, hereditary, and neonatal diseases and abnormalities, Methyl-CpG-Binding Protein 2, Pain medicine, Neurogenesis, Analgesic, Short Report, Rett syndrome, p-CREB/miR-132, CREB, Synaptic Transmission, MECP2, Cellular and Molecular Neuroscience, Mice, mental disorders, medicine, Rett Syndrome, Animals, SNI model, MeCP2, Neurons, Analgesics, Spinal cord, Neuronal Plasticity, biology, business.industry, Chronic pain, medicine.disease, CREB-Binding Protein, nervous system diseases, MicroRNAs, Anesthesiology and Pain Medicine, Neuropathic pain, biology.protein, Molecular Medicine, business, Neuroscience, Neural development, Acute pain

Abstract

Background: The Methyl CpG binding protein 2 gene (MeCP2 gene) encodes a critical transcriptional repressor and is widely expressed in mammalian neurons. MeCP2 plays a critical role in neuronal differentiation, neural development, and synaptic plasticity. Mutations and duplications of the human MECP2 gene lead to severe neurodevelopmental disorders, such as Rett syndrome and autism. In this study we investigate the role of MeCP2 in the spinal cord and found that MeCP2 plays an important role as an analgesic mediator in pain circuitry. Findings: Experiments using MeCP2 transgenic mice showed that overexpression of MeCP2 weakens both acute mechanical pain and thermal pain, suggesting an analgesic role of MeCP2 in acute pain transduction. We found that through p-CREB/miR-132 signaling cascade is involved in MeCP2-mediated pain transduction. We also examined the role of MeCP2 in chronic pain formation using spared nerve injury (SNI) model. Strikingly, we found that development of neuropathic pain attenuates in MeCP2 transgenic mice comparing to wild type (WT) mice. Conclusions: Our study shows that MeCP2 plays an analgesic role in both acute pain transduction and chronic pain formation through regulating CREB-miR-132 pathway. This work provides a potential therapeutic target for neural pathologic pain, and also sheds new lights on the abnormal sensory mechanisms associated with autism spectrum orders.

213. NeuroD2 regulates the development of hippocampal mossy fiber synapses

Author

Benjamin J. Hall, Thomas Biederer, Stefanie Otto, Anirvan Ghosh, Katie Tiglio, Joseph K. Antonios, Bo Yuan, Zilong Qiu, Elissa M. Robbins, Fading Chen, Laura A. DeNardo, Scott A. Wilke, and Megan E. Williams

Subjects

Mice, Knockout, Neurons, Dendritic spine, Dendritic Spines, Neuropeptides, Long-term potentiation, Biology, Hippocampal formation, Hippocampus, lcsh:RC346-429, Synapse, Mice, Developmental Neuroscience, NEUROD2, Mossy Fibers, Hippocampal, Synapses, Biological neural network, Basic Helix-Loop-Helix Transcription Factors, Animals, Transcription factor, Neuroscience, Cells, Cultured, lcsh:Neurology. Diseases of the nervous system, Hippocampal mossy fiber, Research Article

Abstract

BackgroundThe assembly of neural circuits requires the concerted action of both genetically determined and activity-dependent mechanisms. Calcium-regulated transcription may link these processes, but the influence of specific transcription factors on the differentiation of synapse-specific properties is poorly understood. Here we characterize the influence of NeuroD2, a calcium-dependent transcription factor, in regulating the structural and functional maturation of the hippocampal mossy fiber (MF) synapse.ResultsUsing NeuroD2 null mice andin vivolentivirus-mediated gene knockdown, we demonstrate a critical role for NeuroD2 in the formation of CA3 dendritic spines receiving MF inputs. We also use electrophysiological recordings from CA3 neurons while stimulating MF axons to show that NeuroD2 regulates the differentiation of functional properties at the MF synapse. Finally, we find that NeuroD2 regulates PSD95 expression in hippocampal neurons and that PSD95 loss of functionin vivoreproduces CA3 neuron spine defects observed in NeuroD2 null mice.ConclusionThese experiments identify NeuroD2 as a key transcription factor that regulates the structural and functional differentiation of MF synapsesin vivo.

214. Extension of cortical synaptic development distinguishes humans from chimpanzees and macaques.

Author

Xiling Liu, Somel, Mehmet, Lin Tang, Zheng Yan, Xi Jiang, Song Guo, Yuan Yuan, Liu He, Oleksiak, Anna, Yan Zhang, Na Li, Yuhui Hu, Wei Chen, Zilong Qiu, Pääbo, Svante, and Khaitovich, Philipp

Subjects

*ONTOGENY, *BRAIN, *RNA, *GENE expression, *PREFRONTAL cortex, *RHESUS monkeys

Abstract

Over the course of ontogenesis, the human brain and human cognitive abilities develop in parallel, resulting in a phenotype strikingly distinct from that of other primates. Here, we used microarrays and RNA-sequencing to examine human-specific gene expression changes taking place during postnatal brain development in the prefrontal cortex and cerebellum of humans, chimpanzees, and rhesus macaques. We show that the most prominent human-specific expression change affects genes associated with synaptic functions and represents an extreme shift in the timing of synaptic development in the prefrontal cortex, but not the cerebellum. Consequently, peak expression of synaptic genes in the prefrontal cortex is shifted from <1 yr in chimpanzees and macaques to 5 yr in humans. This result was supported by protein expression profiles of synaptic density markers and by direct observation of synaptic density by electron microscopy. Mechanistically, the human-specific change in timing of synaptic development involves the MEF2A-mediated activity-dependent regulatory pathway. Evolutionarily, this change may have taken place after the split of the human and the Neanderthal lineages. [ABSTRACT FROM AUTHOR]

Published

2012