The Ohio State University
 
 
   
The Ohio State University College of Medicine & Public Health
Chen Gu, Ph.D.
 
Home > Faculty > Chen Gu, Ph.D.

Faculty
Christine Beattie, Ph.D.
Tony Brown, Ph.D
Chen Gu, Ph.D.
Tsonwin Hai, Ph.D.
Paul Henion, Ph.D.
James Jontes, Ph.D.
Jeff Kuret, Ph.D.
John Oberdick, Ph.D.
Mark Seeger, Ph.D.
Harald Vaessin, Ph.D.
Mariano Viapiano, Ph.D
Sung Ok Yoon, Ph.D.
Tony Young, Ph.D.
Mike Xi Zhu, Ph.D.

Assistant Professor

Department of Neuroscience and
Center for Molecular Neurobiology

Ph.D.: University of Colorado Health Sciences Center
Post-doctoral Training: University of California San Francisco

Center for Molecular Neurobiology
The Ohio State University
182 Rightmire Hall
1060 Carmack Road
Columbus, OH 43210

Phone: 614-292-0349
Fax: 614-292-5379
E-mail: gu.49@osu.edu    

Link to NLM & NIH PubMed publications list for Chen Gu (last 10 years)

Research Area:

  • Ion channel trafficking and neurological disease.

Research Description:

Precise targeting of ion channels into distinct subcellular domains is essential for neuronal electrical signaling. Altered electrical signaling caused by mis-targeting or malfunction of ion channels can induce clinical symptoms in neurological diseases. We are interested in studying the molecular mechanisms underlying and pathophysiological significance of ion channel trafficking. Currently, we are focusing on the following two projects:

  1. Molecular mechanisms underlying axonal targeting of voltage-gated potassium (Kv) channels.
    Dendrite and axon are the two prominent polarized structures of neurons, responsible for the input and output of electrical signals. Axonal Kv channels control the waveform and speed of action potentials that convey signals along axons from somatodendritic regions to nerve terminals. We are pursuing the intra-neuronal mechanisms governing axonal targeting of these channels.
  2. Targeting and function of ion channels in myelinated axons.
    Axons and myelinating glia exhibit remarkable cell-cell interactions during development. Crucial for the saltatory conduction and synchronized presynaptic input, myelin limits axonal ion channels into distinct membrane domains along axons, for instance voltage-gated sodium channels at nodes of Ranvier, Kv1 channels in juxtaparanodal regions. We are investigating how external factors (from myelin) regulate ion channel axonal targeting, and how this regulation is involved in demyelinating diseases, such as multiple sclerosis.

Techniques and Models:

  • Molecular Biology: PCR, site-directed mutagenesis, fluorescent protein fusion, siRNA knockdown, Western blotting, protein purification, immunoprecipitation.
  • Cell Biology: primary neuronal culture, neuron-glia co-culture, transfection, viral infection, immunocytochemistry.
  • Imaging: multi-color time lapse, fluorescence resonance energy transfer (FRET), total internal reflection fluorescence (TIRF).
  • Animal model: murine experimental autoimmune encephalomyelitis (EAE).

 



© 2008 Center for Molecular Neurobiology
206 Rightmire Hall
1060 Carmack Road
Columbus, OH 43210
The Ohio State University