Hugheslab

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Our lab studies circadian rhythms as a model to better understand how the nervous system regulates
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behavior and physiology.  We are especially interested in uncovering the molecular mechanisms
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driving rhythms of gene expression, and determining how these molecular rhythms ultimately influence
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physiological rhythms.  We use a combination of approaches, including behavioral neuroscience, genetics,
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genomics, and bioinformatics.
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Our laboratory studies circadian rhythms as a model to better understand how the nervous system regulates
 +
behavior and physiology.  We are especially interested in uncovering the mechanisms
 +
driving gene expression rhythms and determining how these molecular oscillations ultimately influence
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physiological rhythms.  We use a combination of approaches, including ''behavioral neuroscience'', ''molecular biology'', ''genetics'',
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''genomics'', and ''bioinformatics''.
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Hughes Lab<br>
[http://www.umsl.edu/~biology/ Department of Biology]<br>
[http://www.umsl.edu/~biology/ Department of Biology]<br>
University of Missouri, St. Louis<br>
University of Missouri, St. Louis<br>
(Starting in August, 2013)
(Starting in August, 2013)

Revision as of 12:01, 8 January 2013

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Our laboratory studies circadian rhythms as a model to better understand how the nervous system regulates behavior and physiology. We are especially interested in uncovering the mechanisms driving gene expression rhythms and determining how these molecular oscillations ultimately influence physiological rhythms. We use a combination of approaches, including behavioral neuroscience, molecular biology, genetics, genomics, and bioinformatics.




Hughes Lab
Department of Biology
University of Missouri, St. Louis
(Starting in August, 2013)

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