Multimodal assessment of autophagy in mammalian cells with a novel, LC3-based tandem reporter.

Autophagy is an important intracellular pathway for the degradation of superfluous or harmful subcellular materials, thereby playing a critical role in the maintenance of cell health under normal and stress-related conditions. Researchers interrogating autophagic activity in mammalian cell lines often leverage complementary assay technologies to confirm observations. The Autophagy LC3 HiBiT Reporter assay system utilizes a tandem reporter module, HiBiT-HaloTag, fused to a key marker of autophagic activity, LC3B protein, to enable multiple, cell-based assay modalities. This novel autophagy reporter expressed in a single cell line supports (a) a bioluminescent, homogeneous, plate-reader assay for rapid and quantitative assessment of changes in the level of the LC3-based reporter, (b) a fluorescence-based imaging approach to monitor reporter subcellular distribution in live cells, and (c) an antibody-free, protein blotting method to detect the relative amounts of the LC3-I and LC-II forms of the reporter associated with modulation of autophagic flux. Here we detail protocols for all three assay modalities applied to a U2OS human osteosarcoma cell line stably expressing the novel autophagy reporter, enabling the identification of modulators of autophagic activity and subsequent confirmation of mechanism of action.

NanoLuc Complementation Reporter Optimized for Accurate Measurement of Protein Interactions in Cells.

Protein-fragment complementation assays (PCAs) are widely used for investigating protein interactions. However, the fragments used are structurally compromised and have not been optimized nor thoroughly characterized for accurately assessing these interactions. We took advantage of the small size and bright luminescence of NanoLuc to engineer a new complementation reporter (NanoBiT). By design, the NanoBiT subunits (i.e., 1.3 kDa peptide, 18 kDa polypeptide) weakly associate so that their assembly into a luminescent complex is dictated by the interaction characteristics of the target proteins onto which they are appended. To ascertain their general suitability for measuring interaction affinities and kinetics, we determined that their intrinsic affinity (KD = 190 µM) and association constants (kon = 500 M(-1) s(-1), koff = 0.2 s(-1)) are outside of the ranges typical for protein interactions. The accuracy of NanoBiT was verified under defined biochemical conditions using the previously characterized interaction between SME-1 ß-lactamase and a set of inhibitor binding proteins. In cells, NanoBiT fusions to FRB/FKBP produced luminescence consistent with the linear characteristics of NanoLuc. Response dynamics, evaluated using both protein kinase A and ß-arrestin-2, were rapid, reversible, and robust to temperature (21-37 °C). Finally, NanoBiT provided a means to measure pharmacology of kinase inhibitors known to induce the interaction between BRAF and CRAF. Our results demonstrate that the intrinsic properties of NanoBiT allow accurate representation of protein interactions and that the reporter responds reliably and dynamically in cells.

Live cell evaluation of granzyme delivery and death receptor signaling in tumor cells targeted by human natural killer cells.

Growing interest in natural killer (NK) cell-based therapy for treating human cancer has made it imperative to develop new tools to measure early events in cell death. We recently demonstrated that protease-cleavable luciferase biosensors detect granzyme B and pro-apoptotic caspase activation within minutes of target cell recognition by murine cytotoxic lymphocytes. Here we report successful adaptation of the biosensor technology to assess perforin-dependent and -independent induction of death pathways in tumor cells recognized by human NK cell lines and primary cells. Cell-cell signaling via both Fc receptors and NK-activating receptors led to measurable luciferase signal within 15 minutes. In addition to the previously described aspartase-cleavable biosensors, we report development of granzyme A and granzyme K biosensors, for which no other functional reporters are available. The strength of signaling for granzyme biosensors was dependent on perforin expression in IL-2-activated NK effectors. Perforin-independent induction of apoptotic caspases was mediated by death receptor ligation and was detectable after 45 minutes of conjugation. Evidence of both FasL and TRAIL-mediated signaling was seen after engagement of Jurkat cells by perforin-deficient human cytotoxic lymphocytes. Although K562 cells have been reported to be insensitive to TRAIL, robust activation of pro-apoptotic caspases by NK cell-derived TRAIL was detectable in K562 cells. These studies highlight the sensitivity of protease-cleaved luciferase biosensors to measure previously undetectable events in live cells in real time. Further development of caspase and granzyme biosensors will allow interrogation of additional features of granzyme activity in live cells including localization, timing, and specificity.

Real-time detection of CTL function reveals distinct patterns of caspase activation mediated by Fas versus granzyme B.

Activation of caspase-mediated apoptosis is reported to be a hallmark of both granzyme B- and Fas-mediated pathways of killing by CTLs; however, the kinetics of caspase activation remain undefined owing to an inability to monitor target cell-specific apoptosis in real time. We have overcome this limitation by developing a novel biosensor assay that detects continuous, protease-specific activity in target cells. Biosensors were engineered from a circularly permuted luciferase, linked internally by either caspase 3/7 or granzyme B/caspase 8 cleavage sites, thus allowing activation upon proteolytic cleavage by the respective proteases. Coincubation of murine CTLs with target cells expressing either type of biosensor led to a robust luminescent signal within minutes of cell contact. The signal was modulated by the strength of TCR signaling, the ratio of CTL/target cells, and the type of biosensor used. Additionally, the luciferase signal at 30 min correlated with target cell death, as measured by a (51)Cr-release assay. The rate of caspase 3/7 biosensor activation was unexpectedly rapid following granzyme B- compared with Fas-mediated signal induction in murine CTLs; the latter appeared gradually after a 90-min delay in perforin- or granzyme B-deficient CTLs. Remarkably, the Fas-dependent, caspase 3/7 biosensor signal induced by perforin-deficient human CTLs was also detectable after a 90-min delay when measured by redirected killing. Thus, we have used a novel, real-time assay to demonstrate the distinct pattern of caspase activation induced by granzyme B versus Fas in human and murine CTLs.

Imaging proteolytic activity in live cells and animal models.

In addition to their degradative role in protein turnover, proteases play a key role as positive or negative regulators of signal transduction pathways and therefore their dysregulation contributes to many disease states. Regulatory roles of proteases include their hormone-like role in triggering G protein-coupled signaling (Protease-Activated-Receptors); their role in shedding of ligands such as EGF, Notch and Fas; and their role in signaling events that lead to apoptotic cell death. Dysregulated activation of apoptosis by the caspase family of proteases has been linked to diseases such as cancer, autoimmunity and inflammation. In an effort to better understand the role of proteases in health and disease, a luciferase biosensor is described which can quantitatively report proteolytic activity in live cells and mouse models. The biosensor, hereafter referred to as GloSensor Caspase 3/7 has a robust signal to noise (50-100 fold) and dynamic range such that it can be used to screen for pharmacologically active compounds in high throughput campaigns as well as to study cell signaling in rare cell populations such as isolated cancer stem cells. The biosensor can also be used in the context of genetically engineered mouse models of human disease wherein conditional expression using the Cre/loxP technology can be implemented to investigate the role of a specific protease in living subjects. While the regulation of apoptosis by caspase's was used as an example in these studies, biosensors to study additional proteases involved in the regulation of normal and pathological cellular processes can be designed using the concepts presented herein.

A luminescent biosensor with increased dynamic range for intracellular cAMP.

The second messenger cAMP is a key mediator of signal transduction following activation of G-protein coupled receptors. Investigations on Gs-coupled receptors would benefit from a second messenger assay that allows continuous monitoring of kinetic changes in cAMP concentration over a broad dynamic range. To accomplish this, we have evolved a luminescent biosensor for cAMP to better encompass the physiological concentration ranges present in living cells. When compared to an immunoassay, the evolved biosensor construct was able to accurately track both the magnitude and kinetics of cAMP change using a far less labor intensive format. We demonstrate the utility of this construct to detect a broad range of receptor activity, together with showing suitability for use in high-throughput screening.

Novel genetically encoded biosensors using firefly luciferase.

Genetically encoded biosensors have proven valuable for real-time monitoring of intracellular phenomena, particularly FRET-based sensors incorporating variants of green fluorescent protein. To increase detection sensitivity and response dynamics, we genetically engineered firefly luciferase to detect specific intermolecular interactions through modulation of its luminescence activity. This concept has been applied in covalent, noncovalent, and allosteric design configurations. The covalent design gives sensitive detection of protease activity through a cleavage-dependent increase in luminescence. The noncovalent and allosteric designs allow reversible detection of the small molecules rapamycin and cAMP, respectively. These sensors allow detection of molecular processes within living cells following addition of the luciferin substrate to the growth medium. For example, the cAMP sensor allows monitoring of intracellular signal transduction associated with G-protein coupled receptor function. These and other luminescent biosensors will be useful for the sensitive detection of cellular physiology in research and drug discovery.