Development and Application of Rapamycin-regulated Tyrosine Phosphatases.

Tyrosine phosphatases are an important family of enzymes that regulate critical physiological functions. They are often dysregulated in human diseases, making them key targets of biological studies. Tools that enable the regulation of phosphatase activity are instrumental in the dissection of their function. Traditional approaches, such as overexpression of constitutively active or dominant negative mutants, or downregulation using siRNA, lack temporal control. Phosphatase inhibitors often have poor specificity, and they only allow researchers to determine what processes are affected by the inhibition of the phosphatase. We developed a chemogenetic approach, the Rapamycin-regulated (RapR) system, which allows for allosteric regulation of a phosphatase catalytic domain that enables tight temporal control of phosphatase activation. The RapR system consists of an iFKBP domain inserted into an allosteric site in the phosphatase. The intrinsic structural dynamics of the RapR domain disrupt the catalytic domain, leading to the inactivation of the enzyme. The addition of rapamycin mediates the formation of a complex between iFKBP and a co-expressed FRB protein, which stabilizes iFKBP and restores activity to the phosphatase's catalytic domain. This system provides high specificity and tight temporal control of phosphatase activation in living cells. The unique capabilities of this system enable the identification of transient events and interrogation of individual signaling pathways downstream of a phosphatase. This protocol describes guidelines for the development of a RapR-phosphatase, its biochemical characterization, and the analysis of its effects on downstream signaling and regulation of cell morphodynamics. It also provides a detailed description of a protein engineering strategy, in vitro assays analyzing phosphatase activity, and live cell imaging experiments identifying changes in cell morphology.

Engineered Allosteric Regulation of Protein Function.

Allosteric regulation of proteins has been utilized to study various aspects of cell signaling, from unicellular events to organism-wide phenotypes. However, traditional methods of allosteric regulation, such as constitutively active mutants and inhibitors, lack tight spatiotemporal control. This often leads to unintended signaling consequences that interfere with data interpretation. To overcome these obstacles, researchers employed protein engineering approaches that enable tight control of protein function through allosteric mechanisms. These methods provide high specificity as well as spatial and temporal precision in regulation of protein activity in vitro and in vivo. In this review, we focus on the recent advancements in engineered allosteric regulation and discuss the various bioengineered allosteric techniques available now, from chimeric GPCRs to chemogenetic and optogenetic switches. We highlight the benefits and pitfalls of each of these techniques as well as areas in which future improvements can be made. Additionally, we provide a brief discussion on implementation of engineered allosteric regulation approaches, demonstrating that these tools can shed light on elusive biological events and have the potential to be utilized in precision medicine.

Dissecting protein tyrosine phosphatase signaling by engineered chemogenetic control of its activity.

Protein tyrosine phosphatases (PTPases) are critical mediators of dynamic cell signaling. A tool capable of identifying transient signaling events downstream of PTPases is essential to understand phosphatase function on a physiological time scale. We report a broadly applicable protein engineering method for allosteric regulation of PTPases. This method enables dissection of transient events and reconstruction of individual signaling pathways. Implementation of this approach for Shp2 phosphatase revealed parallel MAPK and ROCK II dependent pathways downstream of Shp2, mediating transient cell spreading and migration. Furthermore, we show that the N-SH2 domain of Shp2 regulates MAPK-independent, ROCK II-dependent cell migration. Engineered targeting of Shp2 activity to different protein complexes revealed that Shp2-FAK signaling induces cell spreading whereas Shp2-Gab1 or Shp2-Gab2 mediates cell migration. We identified specific transient morphodynamic processes induced by Shp2 and determined the role of individual signaling pathways downstream of Shp2 in regulating these events. Broad application of this approach is demonstrated by regulating PTP1B and PTP-PEST phosphatases.