Protein engineering strategies to stimulate the functions of bacterial pseudokinases.

Enzymes orchestrate an array of concerted functions that often culminate in the chemical conversion of substrates into products. In the bacterial kingdom, histidine kinases autophosphorylate, then transfer that phosphate to a second protein called a response regulator. Bacterial genomes can encode large numbers of histidine kinases that provide surveillance of environmental and cytosolic stresses through signal stimulation of histidine kinase activity. Pseudokinases lack these hallmark catalytic functions but often retain binding interactions and allostery. Characterization of bacterial pseudokinases then takes a fundamentally different approach than their enzymatic counterparts. Here we discuss models for how bacterial pseudokinases can utilize protein-protein interactions and allostery to serve as crucial signaling pathway regulators. Then we describe a protein engineering strategy to interrogate these models, emphasizing how signals flow within bacterial pseudokinases. This description includes design considerations, cloning strategies, and the purification of leucine zippers fused to pseudokinases. We then describe two assays to interrogate this approach. First is a C. crescentus swarm plate assay to track motility phenotypes related to a bacterial pseudokinase. Second is an in vitro coupled-enzyme assay that can be applied to test if and how a pseudokinase regulates an active kinase. Together these approaches provide a blueprint for dissecting the mechanisms of cryptic bacterial pseudokinases.

Regulation of the activity of the bacterial histidine kinase PleC by the scaffolding protein PodJ.

Scaffolding proteins can customize the response of signaling networks to support cell development and behaviors. PleC is a bifunctional histidine kinase whose signaling activity coordinates asymmetric cell division to yield a motile swarmer cell and a stalked cell in the gram-negative bacterium Caulobacter crescentus. Past studies have shown that PleC's switch in activity from kinase to phosphatase correlates with a change in its subcellular localization pattern from diffuse to localized at the new cell pole. Here we investigated how the bacterial scaffolding protein PodJ regulates the subcellular positioning and activity of PleC. We reconstituted the PleC-PodJ signaling complex through both heterologous expressions in Escherichia coli and in vitro studies. In vitro, PodJ phase separates as a biomolecular condensate that recruits PleC and inhibits its kinase activity. We also constructed an in vivo PleC-CcaS chimeric histidine kinase reporter assay and demonstrated using this method that PodJ leverages its intrinsically disordered region to bind to PleC's PAS sensory domain and regulate PleC-CcaS signaling. Regulation of the PleC-CcaS was most robust when PodJ was concentrated at the cell poles and was dependent on the allosteric coupling between PleC-CcaS's PAS sensory domain and its downstream histidine kinase domain. In conclusion, our in vitro biochemical studies suggest that PodJ phase separation may be coupled to changes in PleC enzymatic function. We propose that this coupling of phase separation and allosteric regulation may be a generalizable phenomenon among enzymes associated with biomolecular condensates.

Synthetic Control of Signal Flow Within a Bacterial Multi-Kinase Network.

The signal processing capabilities of bacterial signaling networks offer immense potential for advanced phospho-signaling systems for synthetic biology. Emerging models suggest that complex development may require interconnections between what were once thought to be isolated signaling arrays. For example, Caulobacter crescentus achieves the feat of asymmetric division by utilizing a novel pseudokinase DivL, which senses the output of one signaling pathway to modulate a second pathway. It has been proposed that DivL reverses signal flow by exploiting conserved kinase conformational changes and protein-protein interactions. We engineered a series of DivL-based modulators to synthetically stimulate reverse signaling of the network in vivo. Stimulation of conformational changes through the DivL signal transmission helix resulted in changes to hallmark features of the network: C. crescentus motility and DivL accumulation at the cell poles. Additionally, mutations to a conserved PAS sensor transmission motif disrupted reverse signaling flow in vivo. We propose that synthetic stimulation and sensor disruption provide strategies to define signaling circuit organization principles for the rational design and validation of synthetic pathways.

Manipulation of Bacterial Signaling Using Engineered Histidine Kinases.

Two-component systems allow bacteria to respond to changes in environmental or cytosolic conditions through autophosphorylation of a histidine kinase (HK) and subsequent transfer of the phosphate group to its downstream cognate response regulator (RR). The RR then elicits a cellular response, commonly through regulation of transcription. Engineering two-component system signaling networks provides a strategy to study bacterial signaling mechanisms related to bacterial cell survival, symbiosis, and virulence, and to develop sensory devices in synthetic biology. Here we focus on the principles for engineering the HK to identify unknown signal inputs, test signal transmission mechanisms, design small molecule sensors, and rewire two-component signaling networks.