A fragmented small GTPase capable of conditional effector binding is described. The effector binding function of this split-GTPase can be modulated using a small molecule input, thus allowing for the potential design of cellular signaling pathways.

We introduce a versatile approach for repurposing protein kinase chemosensors, containing the phosphorylation-sensitive sulfonamido-oxine fluorophore termed Sox, for the specific determination of endogenous protein phosphatase activity from whole cell lysates and tissue homogenates. As a demonstration of this approach, we design and evaluate a direct chemosensor for protein tyrosine phosphatase-1B (PTP1B), an established signaling node in human disease. The optimal sensor design is capable of detecting as little as 6 pM (12 pg) full-length recombinant PTP1B and is remarkably selective for PTP1B among a panel of highly homologous tyrosine phosphatases. Coupling this robust activity probe with the specificity of antibodies allowed for the temporal analysis of endogenous PTP1B activity dynamics in lysates generated from HepG2 cells after stimulation with insulin. Lastly, we leveraged this assay format to profile PTP1B activity perturbations in a rat model of nonalcoholic fatty liver disease (NAFLD), providing direct evidence for elevated PTP1B catalytic activity in this disease state. Given the modular nature of this assay, we anticipate that this approach will have broad utility in monitoring phosphatase activity dynamics in human disease states.

Given the clear role of protein aggregation in human disease, there is a critical need for assays capable of quantifying protein aggregation in living systems. We hypothesized that the inherently low background and biocompatibility of luminescence signal readouts could provide a potential solution to this problem. Herein, we describe a set of self-assembling NanoLuc luciferase (Nluc) fragments that produce a tunable luminescence readout that is dependent upon the solubility of a target protein fused to the N-terminal Nluc fragment. To demonstrate this approach, we employed this assay in bacteria to assess mutations known to disrupt amyloid-beta (Aβ) aggregation as well as disease-relevant mutations associated with familial Alzheimer’s diseases. The luminescence signal from these experiments correlates with the reported aggregation potential of these Aβ mutants and reinforces the increased aggregation potential of disease-relevant mutations in Aβ1–42. To further demonstrate the utility of this approach, we show that the effect of small molecule inhibitors on Aβ aggregation can be monitored using this system. In addition, we demonstrate that aggregation assays can be ported into mammalian cells. Taken together, these results indicate that this platform could be used to rapidly screen for mutations that influence protein aggregation as well as inhibitors of protein aggregation. This method offers a novel, genetically encodable luminescence readout of protein aggregation in living cells.

An improved miniprotein host capable of fluorogenic supramolecular assembly with a sI-Pht guest is reported. This improved host, termed 6.2.22, displays significant enhancements in both the EC50 for complexation and fluorescence activation of the sI-Pht guest, allowing for improved resolution of supramolecular complexation on the surface of living yeast.

Protein serine/threonine phosphatases (PSPs) are ubiquitously expressed in mammalian cells. In particular, PP2A accounts for up to 1% of the total protein within cells. Despite clear evidence for the role of PP2A in cellular signaling, there is a lack of information concerning the magnitude and temporal dynamics of PP2A catalytic activity during insulin stimulation. Herein, we describe the development of a direct, fluorescent activity probe capable of reporting on global changes in PP2A enzymatic activity in unfractionated cell lysates. Utilizing this new probe, we profiled the magnitude as well as temporal dynamics of PP2A activity during insulin stimulation of liver hepatocytes. These results provide direct evidence for the rapid response of PP2A catalytic activity to extracellular stimulation, as well as insight into the complex regulation of phosphorylation levels by opposing kinase and phosphatase activities within the cell. This study provides a new tool for investigating the chemical biology of PSPs.

Small-molecule-induced assembly of defined protein structures could have broad implications for the fabrication of new materials as well as biological signaling pathways. However, the design of new host–guest pairs capable of small-molecule-induced assembly in a biologically relevant context remains a significant challenge. Herein, we report a series of miniprotein hosts, evolved from the tenth type III domain of fibronectin (Fn3), that display remarkable binding affinity toward a red-shifted environment-sensitive merocyanine derivative, termed sI-Pht. Importantly, the consensus binder isolated from directed evolution experiments (6.2.18) forms a higher order assembly in response to addition of sI-Pht, as assessed by analytical ultracentrifugation. sI-Pht-induced assembly of 6.2.18 results in a 570-fold increase in fluorescence compared to free dye. This property enables the direct visualization of host–guest assemblies by fluorescence microscopy. As a demonstration, we show that supramolecular assembly of the 6.2.18-sI-Pht system can be visualized on the surface of living yeast cells. This new host–guest pair provides a tool for the potential development of new materials as well as pathway engineering. In a broader context, this work details a new design paradigm for the discovery of host–guest systems that function in the context of living cells.

Utilizing a novel 8-silyloxyquinoline scaffold, we demonstrate the ability to synthesize fluorogenic probes for the sensitive and selective detection of inorganic fluoride (NaF) in aqueous samples. Our initial probe design (2) is capable of detecting inorganic fluoride at levels as low as 3.8 μM (72 ppb) in aqueous solutions, well below PHS recommended levels for drinking water (0.7–1.2 ppm), placing this probe among the most sensitive fluoride sensors reported to date. Furthermore, our results highlight the utility of the readily modifiable 8-silyloxyquinoline scaffold for the design of tailored fluoride sensing platforms. We demonstrate the ability to rationally tune the fluorescence and physical properties of the 8-silyloxyquinoline scaffold, producing a red-shifted fluoride probe (4) capable of detecting 50 μM (0.95 ppm) NaF in aqueous samples using a straightforward test-strip-based assay format. Taken together this work provides a template for the design of fluoride sensors capable of reporting on relevant concentrations of fluoride in the laboratory and in the field.

•Present a novel direct activity probe for focal adhesion kinase.•Demonstrate a limit of detection of 1 nM FAK.•Demonstrate the ability to screen for FAK inhibitors.•Provide conditions to selectively monitor FAK activity.Focal adhesion kinase (FAK) has been identified as a potential therapeutic target for the treatment of metastatic cancers. Herein we describe the design, synthesis and optimization of a direct activity sensor for FAK and its application to screening FAK inhibitors. We find that the position of the sensing moiety, a phosphorylation-sensitive sulfonamido-oxine fluorophore, can dramatically influence the performance of peptide sensors for FAK. Real-time fluorescence activity assays using an optimized sensor construct, termed FAKtide-S2, are highly reproducible (Z' = 0.91) and are capable of detecting as little as 1 nM recombinant FAK. Utilizing this robust assay format, we define conditions for the screening of FAK inhibitors and demonstrate the utility of this platform using a set of well-characterized small molecule kinase inhibitors. Additionally, we provide the selectivity profile of FAKtide-S2 among a panel of closely related enzymes, identifying conditions for selectively monitoring FAK activity in the presence of off-target enzymes. In the long term, the chemosensor platform described in this work can be used to identify novel FAK inhibitor scaffolds and potentially assess the efficacy of FAK inhibitors in disease models.

A series of novel phosphinate-based dyes displaying near-infrared fluorescence (NIR) are reported. These dyes exhibit remarkable photostability and brightness. The phosphinate functionality is leveraged as an additional reactive handle in order to tune cell permeability as well as provide a proof-of-principle for a self-reporting small molecule delivery vehicle.