<p>Much as excessive signal levels can destroy a radio transmitter, excessive genetic expression can cause damage in living systems.  While cells are usually well-equipped to modulate their own transcriptional behavior, an investigation into pathological gene expression indicates that many situations arise wherein the expected regulatory response fails.  Our device is designed to augment endogenous gene regulatory pathways.</p>   

<p>Much as excessive signal levels can destroy a radio transmitter, excessive genetic expression can cause damage in living systems.  While cells are usually well-equipped to modulate their own transcriptional behavior, an investigation into pathological gene expression indicates that many situations arise wherein the expected regulatory response fails.  Our device is designed to augment endogenous gene regulatory pathways.</p>   

=Cellular suicide and the cancer phenotype=

=Cellular suicide and the cancer phenotype=

In designing a system to target abnormally-absent apoptosis, one can consider two approaches.  It is possible to identify a key anti-apoptotic factor that requires down-regulation or, conversely, to target a pro-apoptotic factor that requires up-regulation.  For the former, one might consider X-linked Inhibitor of Apoptosis (XIAP), which, while not present on the above figure, is responsible for inhibiting caspases (Vucic and Fairbrother, 2007).  Caspase activation in the apoptotic pathway can be considered to be a point of no return, a trigger for the irreversible decision to undergo cellular suicide.  Downregulation of XIAP should thus help initiate apoptosis.  Alternatively, mutations in the gene encoding p53 have been found to exist in 50% of cancers (Toledo and Wahl, 2006).  These mutations occur overwhelmingly in the DNA binding domain of this protein, thus disabling its ability as a transcriptional regulator.  Since the inhibition of apoptosis stems from a defective p53, it might be necessary to introduce a protein into the cell with analogous activity to p53.  Upregulation of this exogenous genetic input would then result in apoptosis.  

In designing a system to target abnormally-absent apoptosis, one can consider two approaches.  It is possible to identify a key anti-apoptotic factor that requires down-regulation or, conversely, to target a pro-apoptotic factor that requires up-regulation.  For the former, one might consider X-linked Inhibitor of Apoptosis (XIAP), which, while not present on the above figure, is responsible for inhibiting caspases (Vucic and Fairbrother, 2007).  Caspase activation in the apoptotic pathway can be considered to be a point of no return, a trigger for the irreversible decision to undergo cellular suicide.  Downregulation of XIAP should thus help initiate apoptosis.  Alternatively, mutations in the gene encoding p53 have been found to exist in 50% of cancers (Toledo and Wahl, 2006).  These mutations occur overwhelmingly in the DNA binding domain of this protein, thus disabling its ability as a transcriptional regulator.  Since the inhibition of apoptosis stems from a defective p53, it might be necessary to introduce a protein into the cell with analogous activity to p53.  Upregulation of this exogenous genetic input would then result in apoptosis.  

=Apoptosis in yeast=

=Apoptosis in yeast=

=References=

=References=