Kemp:Research

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Reactive oxygen species (ROS) such as hydrogen peroxide and superoxide are generated by ligand binding across a diverse range of receptor families. Redox couples provide a means of translating the presence of ROS into useful signals in the cell. Thioredoxin and glutathione-mediated post-translational modifications of proteins (S-thiolation and S-glutathionylation, respectively) have been shown to functionally alter the activity of certain proteins. Few proteins have been investigated in depth to understand this relationship. More broadly, how redox-related effects systemically influence the regulation of receptor signaling pathways is unknown. Challenges in quantifying post-translational events and discerning the effects of one redox couple from another have compounded the difficulties in understanding the role of redox couples in cellular signaling, mandating a modeling-based approach for gaining insight into these biological processes.  
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Aberrations in redox potential are associated with cancerous phenotypes, resulting in a resistance towards chemotherapeutic drugs.  Reactive oxygen species (ROS) such as hydrogen peroxide and superoxide are generated by ligation events across a diverse range of receptor families; redox couples provide a means of translating the presence of ROS into useful signals in the cell. Thioredoxin and glutathione-mediated post-translational modifications of proteins (thiolation and glutathionylation, respectively) have been shown to functionally alter the activity of certain proteins. However, few proteins have been investigated in depth to understand this relationship. More broadly, an in-depth quantitative analysis of how redox-related effects systemically influence the regulation of a receptor signaling pathway has never been undertaken. Challenges in quantifying post-translational events and discerning the effects of one redox couple from another have compounded the difficulties in understanding the role of redox-potential in cellular signaling, mandating a modeling-based approach for gaining insight into these biological processes.  
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The Kemp lab uses computational modeling and wet-lab experimentation to investigate how thiolation/glutathionylation of proteins influences the information flow from receptors to the nucleus. We study these effects in the context of T cell activation through TCR ligation. Research projects include: <br>
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Our lab uses computational modeling and wet-lab experimentation to investigate how thiolation/glutathionylation of proteins influences the information flow from receptors to the nucleus. We study these effects primarily in the context of T cell activation through TCR ligation. Research projects include: <br> <br>
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'''* Modeling of NF-kappaB regulation through redox couples in pediatric acute lymphoblastic leukemia (with Harry Findley, Children's Healthcare of Atlanta and Emory School of Medicine)''' <br>
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There has been increasing interest in the relationship between the NF-<math>k</math>B anti-apoptosis signaling pathway and the generation of reactive oxygen species (ROS) in pediatric acute lymphoblastic leukemia (ALL)  during clinical therapy. We are studying two patient-derived ALL cells lines which show differential regulation of NF-<math>k</math>B-activation levels post-treatment with a commonly used chemotherapeutic drug. We are investigating how key redox buffering components protect ALL cells from ROS-generating agents by preventing ROS-mediated downregulation of NF-<math>k</math>B. <br> <br>
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'''* Design of microfluidic devices for capturing fast dynamics of T cell signaling (with Hang Lu, Georgia Tech)''' <br>
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Adoptive transfer of T cells is a promising clinical cancer therapy that relies on enhancing the adaptive immune response to target tumor cells in vivo. Widespread application of this therapy, however, has been hindered by the necessary expansion of large populations of T cells for each patient (often selected for tumor antigen specificity) and loss of functionality of the T cells post-transfer. Our long-term objective is to understand how T cell activation is dampened in vivo by the tumor milieu and to be able to evaluate the responsiveness ex vivo-expanded T cells accurately for cancer therapy.  Microfluidic chips are ideal for high-throughput parallel experimentation and automation.  In addition, microfluidics also provides the relevant length scales (~microns) and unique physical phenomena (e.g. laminar flow) to handle cells.  The type of multiplex data that we can obtain from this technology will enable quantitative modeling of T cell activation and better understanding and characterization of anergy. <br> <br>
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* modeling of NF-kappaB regulation through redox couples in pediatric acute lymphoblastic leukemia (with Harry Findley, Children's Healthcare of Atlanta and Emory School of Medicine) <br> <br>
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'''* Development of new techniques to monitor glutathionylation of proteins''' <br> <br>
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* development of new techniques to monitor glutathionylation of proteins <br> <br>
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'''* Modeling systemic influences of endogenous hydrogen peroxide on cellular phosphorylation levels''' <br> <br>
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* modeling systemic influences of endogenous hydrogen peroxide on cellular phosphorylation levels <br> <br>
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* development of microfluidic devices for capturing fast dynamics of T cell signaling (with Hang Lu, Georgia Tech)
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Revision as of 13:33, 7 August 2008

The Kemp Lab

Redox Systems Biology at Georgia Tech

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Reactive oxygen species (ROS) such as hydrogen peroxide and superoxide are generated by ligand binding across a diverse range of receptor families. Redox couples provide a means of translating the presence of ROS into useful signals in the cell. Thioredoxin and glutathione-mediated post-translational modifications of proteins (S-thiolation and S-glutathionylation, respectively) have been shown to functionally alter the activity of certain proteins. Few proteins have been investigated in depth to understand this relationship. More broadly, how redox-related effects systemically influence the regulation of receptor signaling pathways is unknown. Challenges in quantifying post-translational events and discerning the effects of one redox couple from another have compounded the difficulties in understanding the role of redox couples in cellular signaling, mandating a modeling-based approach for gaining insight into these biological processes.

Our lab uses computational modeling and wet-lab experimentation to investigate how thiolation/glutathionylation of proteins influences the information flow from receptors to the nucleus. We study these effects primarily in the context of T cell activation through TCR ligation. Research projects include:

* Modeling of NF-kappaB regulation through redox couples in pediatric acute lymphoblastic leukemia (with Harry Findley, Children's Healthcare of Atlanta and Emory School of Medicine)
There has been increasing interest in the relationship between the NF-kB anti-apoptosis signaling pathway and the generation of reactive oxygen species (ROS) in pediatric acute lymphoblastic leukemia (ALL) during clinical therapy. We are studying two patient-derived ALL cells lines which show differential regulation of NF-kB-activation levels post-treatment with a commonly used chemotherapeutic drug. We are investigating how key redox buffering components protect ALL cells from ROS-generating agents by preventing ROS-mediated downregulation of NF-kB.

* Design of microfluidic devices for capturing fast dynamics of T cell signaling (with Hang Lu, Georgia Tech)
Adoptive transfer of T cells is a promising clinical cancer therapy that relies on enhancing the adaptive immune response to target tumor cells in vivo. Widespread application of this therapy, however, has been hindered by the necessary expansion of large populations of T cells for each patient (often selected for tumor antigen specificity) and loss of functionality of the T cells post-transfer. Our long-term objective is to understand how T cell activation is dampened in vivo by the tumor milieu and to be able to evaluate the responsiveness ex vivo-expanded T cells accurately for cancer therapy. Microfluidic chips are ideal for high-throughput parallel experimentation and automation. In addition, microfluidics also provides the relevant length scales (~microns) and unique physical phenomena (e.g. laminar flow) to handle cells. The type of multiplex data that we can obtain from this technology will enable quantitative modeling of T cell activation and better understanding and characterization of anergy.

* Development of new techniques to monitor glutathionylation of proteins

* Modeling systemic influences of endogenous hydrogen peroxide on cellular phosphorylation levels

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