Your search keyword '"I-Feng Peng"' showing total 7 results

1. δ-Catenin Regulates Spine and Synapse Morphogenesis and Function in Hippocampal Neurons during Development

Author

Yu Gie Ng, Inbal Israely, Erik M. Ullian, I-Feng Peng, Louis F. Reichardt, Jyothi Arikkath, and Xin Liu

Subjects

Male, musculoskeletal diseases, Delta Catenin, Dendritic spine, Dendritic Spines, PDZ domain, Morphogenesis, Biology, Hippocampal formation, Hippocampus, Article, Synapse, Mice, Neuroplasticity, Biological neural network, Animals, Cells, Cultured, Mice, Knockout, Neurons, Neuronal Plasticity, Cadherin, General Neuroscience, Catenins, Phosphoproteins, Rats, Cell biology, Animals, Newborn, Synapses, Cognition Disorders, Cell Adhesion Molecules, Neuroscience

Abstract

The maintenance of spine and synapse number during development is critical for neuronal circuit formation and function. Here we show that delta-catenin, a component of the cadherin-catenin cell adhesion complex, regulates spine and synapse morphogenesis during development. Genetic ablation or acute knockdown of delta-catenin leads to increases in spine and synapse density, accompanied by a decrease in tetrodotoxin induced spine plasticity. Our results indicate that delta-catenin may mediate conversion of activity-dependent signals to morphological spine plasticity. The functional role of delta-catenin in regulating spine density does not require binding to cadherins, but does require interactions with PDZ domain-containing proteins. We propose that the perturbations in spine and synaptic structure and function observed after depletion of delta-catenin during development may contribute to functional alterations in neural circuitry, the cognitive deficits observed in mutant mice, and the mental retardation pathology of Cri-du-chat syndrome.

Published

2009

2. Temperature-Dependent Developmental Plasticity ofDrosophilaNeurons: Cell-Autonomous Roles of Membrane Excitability, Ca2+Influx, and cAMP Signaling

Author

Wei-Hua Lee, Chun-Fang Wu, Wenjia Chen, I-Feng Peng, Yue Zhu, and Brett Berke

Subjects

Potassium Channels, Neurite, Growth Cones, Action Potentials, Biology, medicine.disease_cause, Synaptic Transmission, Membrane Potentials, chemistry.chemical_compound, Cyclic AMP, Neurites, medicine, Animals, Channel blocker, Calcium Signaling, Growth cone, Cells, Cultured, Mushroom Bodies, Neurons, Mutation, Neuronal Plasticity, General Neuroscience, Cell Membrane, Temperature, Brain, Cell Differentiation, Articles, Embryonic stem cell, Cell biology, Drosophila melanogaster, chemistry, Mushroom bodies, Tetrodotoxin, Developmental plasticity, Calcium Channels, Neuroscience

Abstract

Environmental temperature is an important factor exerting pervasive influence on neuronal morphology and synaptic physiology. In theDrosophilabrain, axonal arborization of mushroom body Kenyon cells was enhanced when flies were raised at high temperature (30°C rather than 22°C) for several days. Isolated embryonic neurons in culture that lacked cell–cell contacts also displayed a robust temperature-induced neurite outgrowth. This cell-autonomous effect was reflected by significantly increased high-order branching and enlarged growth cones. The temperature-induced morphological alterations were blocked by the Na+channel blocker tetrodotoxin and a Ca2+channel mutation but could be mimicked by raising cultures at room temperature with suppressed K+channel activity. Physiological analyses revealed increased inward Ca2+currents and decreased outward K+currents, in conjunction with a distal shift in the site of action potential initiation and increased prevalence of TTX-sensitive spontaneous Ca2+transients. Importantly, the overgrowth caused by both temperature and hyperexcitability K+channel mutations were sensitive to genetic perturbations of cAMP metabolism. Thus, temperature acts in a cell-autonomous manner to regulate neuronal excitability and spontaneous activity. Presumably, activity-dependent Ca2+accumulation triggers the cAMP cascade to confer the activity-dependent plasticity of neuronal excitability and growth.

Published

2007

3. Drosophila cacophony Channels: A Major Mediator of Neuronal Ca(2+) Currents and a Trigger for K(+) Channel Homeostatic Regulation

Author

Chun-Fang Wu and I-Feng Peng

Subjects

Neurons, Α subunit, Potassium Channels, General Neuroscience, Mutant, Ca2 current, nutritional and metabolic diseases, Depolarization, Anatomy, Articles, Biology, Cell biology, Mediator, Downregulation and upregulation, cardiovascular system, population characteristics, Animals, Drosophila Proteins, Homeostasis, Drosophila, cardiovascular diseases, Calcium Channels, Cells, Cultured, K channels

Abstract

Thecacophony(cac) locus inDrosophilaencodes a Ca2+channel α subunit, but little is known about properties ofcac-mediated currents and functional consequences ofcacmutations in central neurons. We found that, inDrosophilacultured neurons, Ca2+currents were mediated predominantly by thecacchannels. Thecacchannels contribute to low- and high-threshold, fast- and slow-inactivating types of Ca2+currents, take part in membrane depolarization, and strongly activate Ca2+-activated K+current [IK(Ca)]. Incacneurons, unexpectedly, voltage-activated transient K+currentIAis upregulated to a level that matchesIK(Ca)reduction, implicating a homeostatic regulation that was mimicked by chronic pharmacological blockade of Ca2+currents in wild-type neurons. Among K+channel transcripts,ShakermRNA levels were preferentially increased incacflies. However, Ca2+current expression levels remained unaltered in several K+channel mutants, illustrating a key role ofcacin developmental regulation ofDrosophilaneuronal excitability.

Published

2007

4. Dact1 Is a Postsynaptic Protein Required for Dendrite, Spine, and Excitatory Synapse Development in the Mouse Forebrain.

Author

Okerlund, Nathan D., Kivimäe, Saul, Cheuk Ka Tong, I.-Feng Peng, Ullian, Erik M., and Cheyette, Benjamin N. R.

Subjects

PHOSPHOPROTEINS, DENDRITES, PROSENCEPHALON, MICE, CENTRAL nervous system, NEURONS

Abstract

Dact1 (Dapper/Frodo), an intracellular phosphoprotein that binds Dishevelled, catenins, and other signaling proteins, is expressed in the developing and mature mammalian CNS, but its function there is unknown. Dact1 colocalized with synaptic markers and partitioned to postsynaptic fractions from cultured mouse forebrain neurons. Hippocampal neurons from Dact1 knock-out mice had simpler dendritic arbors and fewer spines than hippocampal neurons from wild-type littermates. This correlated with reductions in excitatory synapses and miniature EPSCs, whereas inhibitory synapses were not affected. Loss of Dact1 resulted in a decrease in activated Rac, and recombinant expression of either Dact1 or constitutively active Rac, but not Rho or Cdc42, rescued dendrite and spine phenotypes in Dact1 mutant neurons. Our findings suggest that, during neuronal differentiation, Dact1 plays a critical role in a molecular pathway promoting Rac activity underlying the elaboration of dendrites and the establishment of spines and excitatory synapses. [ABSTRACT FROM AUTHOR]

Published

2010

5. δ-Catenin Regulates Spine and Synapse Morphogenesis and Function in Hippocampal Neurons during Development.

Author

Arikkath, Jyothi, I-Feng Peng, Yu Gie Ng, Israely, Inbal, Xin Liu, Ullian, Erik M., and Reichardt, Louis F.

Subjects

*HIPPOCAMPUS (Brain), *CEREBRAL cortex, *NERVOUS system, *BIOLOGICAL neural networks, *CELL communication, *NEUROTOXIC agents

Abstract

The maintenance of spine and synapse number during development is critical for neuronal circuit formation and function. Here we show that δ-catenin, a component of the cadherin-catenin cell adhesion complex, regulates spine and synapse morphogenesis during development. Genetic ablation or acute knockdown ofδ-catenin leads to increases in spine and synapse density, accompanied by a decrease in tetrodotoxin induced spine plasticity. Our results indicate that δ-catenin may mediate conversion of activity-dependent signals to morphological spine plasticity. The functional role of δ-catenin in regulating spine density does not require binding to cadherins, but does require interactions with PDZ domain-containing proteins. We propose that the perturbations in spine and synaptic structure and function observed after depletion of δ-catenin during development may contribute to functional alterations in neural circuitry, the cognitive deficits observed in mutant mice, and the mental retardation pathology of Cri-du-chat syndrome. [ABSTRACT FROM AUTHOR]

Published

2009

6. Temperature-Dependent Developmental Plasticity of Drosophila Neurons: Cell-Autonomous Roles of Membrane Excitability, Ca2+ Influx, and cAMP Signaling.

Author

I-Feng Peng, Berke, Brett A., Yue Zhu, Wei-Hua Lee, Wenjia Chen, and Chun-Fang Wu

Subjects

*TEMPERATURE, *MATERIAL plasticity, *DROSOPHILA, *CELLS, *CALCIUM channels, *GENETIC mutation

Abstract

Environmental temperature is an important factor exerting pervasive influence on neuronal morphology and synaptic physiology. In the Drosophila brain, axonal arborization of mushroom body Kenyon cells was enhanced when flies were raised at high temperature (30°C rather than 22°C) for several days. Isolated embryonic neurons in culture that lacked cell- cell contacts also displayed a robust temperature-induced neurite outgrowth. This cell-autonomous effect was reflected by significantly increased high-order branching and enlarged growth cones. The temperature-induced morphological alterations were blocked by the Na+ channel blocker tetrodotoxin and a Ca2+ channel mutation but could be mimicked by raising cultures at room temperature with suppressed K+ channel activity. Physiological analyses revealed increased inward Ca2+ currents and decreased outward K+ currents, in conjunction with a distal shift in the site of action potential initiation and increased prevalence of TTX-sensitive spontaneous Ca2+ transients. Importantly, the overgrowth caused by both temperature and hyperexcitability K+ channel mutations were sensitive to genetic perturbations of cAMP metabolism. Thus, temperature acts in a cell-autonomous manner to regulate neuronal excitability and spontaneous activity. Presumably, activity-dependent Ca2+accumulation triggers the cAMP cascade to confer the activity-dependent plasticity of neuronal excitability and growth. [ABSTRACT FROM AUTHOR]

Published

2007

7. Drosophila cacophony Channels: A Major Mediator of Neuronal Ca2+ Currents and a Trigger for K+ Channel Homeostatic Regulation.

Author

I.-Feng Peng and Chun-Fang Wu

Subjects

*NEURONS, *DROSOPHILA, *GENETIC mutation, *MESSENGER RNA, *NERVOUS system

Abstract

The cacophony (cac) locus in Drosophila encodes a Ca2+ channel α subunit, but little is known about properties of cac-mediated currents and functional consequences of cac mutations in central neurons. We found that, in Drosophila cultured neurons, Ca2+ currents were mediated predominantly by the cac channels. The cac channels contribute to low- and high-threshold, fast- and slow-inactivating types of Ca2+ currents, take part in membrane depolarization, and strongly activate Ca2+-activated K+ current [IK(Ca)]. In cac neurons, unexpectedly, voltage-activated transient K+ current IA is upregulated to a level that matches IK(Ca) reduction, implicating a homeostatic regulation that was mimicked by chronic pharmacological blockade of Ca2+ currents in wild-type neurons. Among K+ channel transcripts, Shaker mRNA levels were preferentially increased in cac flies. However, Ca2+ current expression levels remained unaltered in several K+ channel mutants, illustrating a key role of cac in developmental regulation of Drosophila neuronal excitability. [ABSTRACT FROM AUTHOR]

Published

2007