Template:Jane Johnson Lab: Difference between revisions

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connectivity, imbalances in excitatory and inhibitory neuron formation and loss of control of neural cell number. Using transgenic mice, genomic sequences are being identified that direct temporal and spatial specific expression of these factors in the developing brain and spinal cord. We are using these regulatory sequences to uncover processes initiating neural stem cell differentiation, and to generate new models to study the molecular control of neural differentiation and specification throughout the nervous system.
connectivity, imbalances in excitatory and inhibitory neuron formation and loss of control of neural cell number. Using transgenic mice, genomic sequences are being identified that direct temporal and spatial specific expression of these factors in the developing brain and spinal cord. We are using these regulatory sequences to uncover processes initiating neural stem cell differentiation, and to generate new models to study the molecular control of neural differentiation and specification throughout the nervous system.
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Revision as of 20:37, 14 July 2008

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The Johnson Lab is located on the UT Southwestern Medical Center campus in the Department of Neuroscience. Our research is focused on vertebrate system development during the transition from proliferating neural stem cells to differentiating neurons and glia. These studies involve understanding the regulation and function of the neural specific class of bHLH transcription factors. Alteration in function and expression of the neural bHLH factors result in disturbances of connectivity, imbalances in excitatory and inhibitory neuron formation and loss of control of neural cell number. Using transgenic mice, genomic sequences are being identified that direct temporal and spatial specific expression of these factors in the developing brain and spinal cord. We are using these regulatory sequences to uncover processes initiating neural stem cell differentiation, and to generate new models to study the molecular control of neural differentiation and specification throughout the nervous system.


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