Your search keyword '"Wei Hua Lee"' showing total 3 results

1. 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

2. Correlation between insulin-like growth factor (IGF)-binding protein 5 and IGF-I gene expression during brain development

Author

Wei-Hua Lee and Carolyn A. Bondy

Subjects

Cerebellum, Subventricular zone, Gene Expression, Biology, Hippocampal formation, Hippocampus, Olfactory nerve, Thalamus, medicine, Animals, RNA, Messenger, Insulin-Like Growth Factor I, Brain Chemistry, General Neuroscience, Subiculum, Brain, Articles, Olfactory Bulb, Olfactory bulb, Rats, medicine.anatomical_structure, nervous system, Animals, Newborn, Cerebellar cortex, Forebrain, Carrier Proteins, Insulin-Like Growth Factor Binding Protein 5, Neuroscience

Abstract

Insulin-like growth factor (IGF)-binding proteins (IGFBPs) potently modulate the interactions of IGF-I and -II with the IGF-I receptor. Previous studies have shown that IGFBP2 gene expression is localized in astroglia, where it is anatomically and temporally coordinated with neuronal IGF-I expression during postnatal brain development. The present study shows that IGFBP5 gene expression is also highly abundant during brain development and also demonstrates significant spatiotemporal correlation with IGF-I, but exhibits a neuroanatomical distribution that is entirely distinct from IGFBP2. IGFBP5 and IGF-I mRNAs are synchronously coexpressed in principal neurons of sensory relay systems, including the olfactory bulb, medial and dorsal lateral geniculate bodies, and ventral tier, cochlear, lemniscal, and vestibular nuclei. They are also transiently coexpressed in principal neurons of the anterodorsal nucleus, but IGF-I mRNA disappears from this structure shortly after birth, while IGFBP5 mRNA remains highly abundant here in the adult. IGFBP5 and IGF-I gene expression demonstrate a temporally coordinated laminar association in the developing cerebellar cortex and hippocampal formation. IGF-I mRNA is concentrated in Purkinje cells, while IGFBP5 mRNA is localized in the external germinal zone in the developing cerebellar cortex. IGFBP5 mRNA is transiently expressed in the retrosplenial and cingulate cortex, subiculum, Ammon's horn, and amygdala, while IGF-I mRNA is contemporaneously localized in large interneurons distributed throughout the hippocampal formation. IGFBP5 mRNA is localized in the lateral ventricular germinal zone at birth and remains in the subventricular zone into maturity. It is also detected in forebrain white matter tracts and olfactory nerve from the second week after birth into maturity. Thus IGFBP5, in addition to IGFBP2, may be a significant determinant of IGF action in the brain. Colocalization in some sites and paralocalization with IGF-I in other sites suggests the potential for autocrine and paracrine interaction between the binding protein and IGF-I in different settings. Arguments are advanced suggesting a role for IGFBPs in the targeting of IGF action to specific cell addresses during brain development.

Published

1993

3. 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