Haynes Lab

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Our group uses synthetic, systems, and quantitative biology to engineer useful gene and protein-based biological devices and to deepen our understanding of molecular cell biology. We operate biological devices primarily in human/ mammalian cells. Accelerating the pace of therepeutic technologies (such as tissue regeneration and customizable protein-based drugs) via modular design is the grand challenge that shapes our research plans.
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Our group uses synthetic, systems, and quantitative biology to engineer useful gene and protein-based biological devices and to deepen our understanding of molecular cell biology. We operate biological devices primarily in human/ mammalian cells. Accelerating the pace of therapeutic technologies (such as tissue regeneration and customizable protein-based drugs) via modular design is the grand challenge that shapes our research plans.
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CURRENT PROJECTS<br>
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* '''Synthetic chromatin for human cell differentiation''' - Behzad Damadzadeh
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* '''Microbial communication with synthetic quorum sensing''' - Rene Davis
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* '''Engineering epigenetic transcription factors''' - Brady Laughlin (FURI)
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* '''Protein-DNA fusions in living microbes''' - Ryan Muller (SOLUR)
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* '''Synthetic chromatin and UV-damage''' - Brendan Fries (SOLUR)
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Revision as of 20:20, 21 September 2013

link=Haynes_Lab
link=http://engineering.asu.edu/

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Our group uses synthetic, systems, and quantitative biology to engineer useful gene and protein-based biological devices and to deepen our understanding of molecular cell biology. We operate biological devices primarily in human/ mammalian cells. Accelerating the pace of therapeutic technologies (such as tissue regeneration and customizable protein-based drugs) via modular design is the grand challenge that shapes our research plans.

CURRENT PROJECTS

  • Synthetic chromatin for human cell differentiation - Behzad Damadzadeh
  • Microbial communication with synthetic quorum sensing - Rene Davis
  • Engineering epigenetic transcription factors - Brady Laughlin (FURI)
  • Protein-DNA fusions in living microbes - Ryan Muller (SOLUR)
  • Synthetic chromatin and UV-damage - Brendan Fries (SOLUR)

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