Shimon Gross

Bioluminescence imaging of myeloperoxidase activity in vivo

The myeloperoxidase (MPO) system of activated phagocytes is central to normal host defense mechanisms, and dysregulated MPO contributes to the pathogenesis of inflammatory disease states ranging from atherosclerosis to cancer. Here we show that upon systemic administration, the small molecule luminol enables noninvasive bioluminescence imaging (BLI) of MPO activity in vivo. Luminol-BLI allowed quantitative longitudinal monitoring of MPO activity in animal models of acute dermatitis, mixed allergic contact hypersensitivity, focal arthritis and spontaneous large granular lymphocytic tumors. Bioluminescence colocalized with histological sites of inflammation and was totally abolished in gene-deleted Mpo−/− mice, despite massive tissue infiltration of neutrophils and activated eosinophils, indicating that eosinophil peroxidase did not contribute to luminol-BLI in vivo. Thus, luminol-BLI provides a noninvasive, specific and highly sensitive optical readout of phagocyte-mediated MPO activity in vivo and may enable new diagnostic applications in a wide range of acute and chronic inflammatory conditions.

Real-time imaging of ligand-induced IKK activation in intact cells and in living mice

The transcription factor NF-κB is a key regulator of cellular activation, proliferation and apoptosis. Defects in the NF-κB pathway contribute to a broad array of malignant, neurodegenerative and chronic inflammatory diseases. IKK-dependent IκBα degradation by the 26S proteasome is a critical NF-κB regulatory control point, which is emerging as an important target for drug development. To directly monitor regulation of IKK activation in intact organisms, we engineered an IκBα–firefly luciferase (IκBα-FLuc) fusion reporter. In cultured cells and living animals, the reporter provided a continuous, noninvasive readout of the kinetics of ligand-induced IKK activation and the pharmacodynamics of selective inhibitors of both IKK and the 26S proteasome. This IκBα-FLuc reporter now permits continuous readout of IKK activation in vivo, facilitates development and validation of target-specific therapeutics, and complements conventional NF-κB transcriptional reporters for more complete temporal and regional investigations of the NF-κB signaling pathway in health and disease.

Flavokawain B, the hepatotoxic constituent from kava root, induces GSH-sensitive oxidative stress through modulation of IKK/NF-κB and MAPK signaling pathways

Kava (Piper methysticum Foster, Piperaceae) organic solvent-extract has been used to treat mild to moderate anxiety, insomnia, and muscle fatigue in Western countries, leading to its emergence as one of the 10 best-selling herbal preparations. However, several reports of severe hepatotoxicity in kava consumers led the U.S. Food and Drug Administration and authorities in Europe to restrict sales of kava-containing products. Herein we demonstrate that flavokawain B (FKB), a chalcone from kava root, is a potent hepatocellular toxin, inducing cell death in HepG2 (LD(50)=15.3 ± 0.2 μM) and L-02 (LD(50)=32 μM) cells. Hepatocellular toxicity of FKB is mediated by induction of oxidative stress, depletion of reduced glutathione (GSH), inhibition of IKK activity leading to NF-κB transcriptional blockade, and constitutive TNF-α-independent activation of mitogen-activated protein kinase (MAPK) signaling pathways, namely, ERK, p38, and JNK. We further demonstrate by noninvasive bioluminescence imaging that oral consumption of FKB leads to inhibition of hepatic NF-κB transcriptional activity in vivo and severe liver damage. Surprisingly, replenishment with exogenous GSH normalizes both TNF-α-dependent NF-κB as well as MAPK signaling and rescues hepatocytes from FKB-induced death. Our data identify FKB as a potent GSH-sensitive hepatotoxin, levels of which should be specifically monitored and controlled in kava-containing herb products.

Monitoring proteasome activity in cellulo and in living animals by bioluminescent imaging: technical considerations for design and use of genetically encoded reporters.

The ubiquitin-proteasome pathway is the central mediator of regulated proteolysis, instrumental for switching on and off a variety of signaling cascades. Deregulation of proteasomal activity or improper substrate recognition and processing by the ubiquitin-proteasome machinery may lead to cancer, stroke, chronic inflammation, and neurodegenerative diseases. Quantifying total and substrate-specific proteasome activity in intact cells and living animals would enable analysis in vivo of proteasomal regulation and facilitate the screening and validation of potential modulators of the proteasome or its substrates. We discuss examples of tetra-ubiquitin or IkappaBalpha fused to firefly luciferase as genetically encoded reporters for monitoring total and IkappaBalpha-specific proteasomal activity by bioluminescence imaging. Such technology enables repetitive, temporally resolved, and regionally targeted assessment of proteasomal activity in vivo.

Continuous Delivery of D-Luciferin by Implanted Micro- osmotic Pumps Enables True Real-Time Bioluminescence Imaging of Luciferase Activity In Vivo

Bioluminescence imaging (BLI) of luciferase reporters in small animal models offers an attractive approach to monitor regulation of gene expression, signal transduction, and protein-protein interactions, as well as following tumor progression, cell engraftment, infectious pathogens, and target-specific drug action. Conventional BLI can be repeated within the same animal after bolus reinjections of a bioluminescent substrate. However, intervals between image acquisitions are governed by substrate pharmacokinetics and excretion, therefore restricting temporal resolution of reinjection protocols to the order of hours, limiting analyses of processes in vivo with short time constants. To eliminate these constraints, we examined use of implanted micro-osmotic pumps for continuous, long-term delivery of bioluminescent substrates. Pump-assisted d-luciferin delivery enabled BLI for ⩾ 7 days from a variety of luciferase reporters. Pumps allowed direct repetitive imaging at < 5-minute intervals of the pharmacodynamics of proteasome- and IKK-inhibiting drugs in mice bearing tumors stably expressing ubiquitin-firefly luciferase or IκBα-firefly luciferase fusion reporters. Circadian oscillations in the olfactory bulbs of transgenic rats expressing firefly luciferase under the control of the period1 promoter also were temporally resolved over the course of several days. We conclude that implanted pumps provide reliable, prolonged substrate delivery for high temporal resolution BLI, traversing complications of repetitive substrate injections.

T-cell activation promotes tumorigenesis in inflammation-associated cancer

Chronic inflammation has long been associated with a wide range of malignancies, is now widely accepted as a risk factor for development of cancer, and has been implicated as a promoter of a variety of cancers including hematopoietic malignancies. We have described a mouse model uniquely suited to examine the link between inflammation and lymphoma in which the Tax oncogene, expressed in activated T and NK cells, perpetuates chronic inflammation that begins as microscopic intraepithelial lesions and develops into inflammatory nodules, subcutaneous tumors, and large granular lymphocytic leukemia. The use of bioluminescent imaging in these mice has expanded our ability to interrogate aspects of inflammation and tumorigenesis non-invasively. Here we demonstrate that bioluminescence induction in these mice correlated with inflammation resulting from wounding, T cell activation, and exposure to chemical agents. In experiments in which long-term effects of inflammation on disease outcome were monitored, the development of lymphoma was promoted by an inflammatory stimulus. Finally we demonstrated that activation of T-cells in T-cell receptor (TCR) transgenic TAX-LUC animals dramatically exacerbated the development of subcutaneous TCR- CD16+ LGL tumors. The role of activated T-cells and acquired immunity in inflammation-associated cancers is broadly applicable to hematopoietic malignancies, and we propose these mice will be of use in dissecting mechanisms by which activated T-cells promote lymphomagenesis in vivo.

Imaging spontaneous tumorigenesis: inflammation precedes development of peripheral NK tumors

Early events in tumor development are spontaneous, microscopic, and affected by the microenvironment. We developed a mouse model of spontaneous lymphoma in which malignant transformation is coupled with light emission that can be detected noninvasively using bioluminescent imaging. The human T-cell leukemia virus (HTLV) type 1 transcriptional transactivator Tax is an oncogene sufficient to produce lymphoma in transgenic animal models. Using the granzyme B promoter to restrict Tax expression to the mature natural killer (NK)/T-cell compartment, we have reproduced many elements of HTLV-associated adult T-cell leukemia/lymphoma. Tax activates signaling cascades associated with transformation, inflammation, and tumorigenesis. Here, we report that Tax-mediated activation of luciferase in long terminal repeat-luciferase (LTR-LUC) mice serves as a reporter for imaging these processes in vivo. Using bioluminescent imaging (BLI), we discovered that microscopic intraepithelial lesions precede the onset of peripheral subcutaneous tumors, tumorigenesis progresses through early reversible stages, and Tax is sufficient for inducing tumors. Based on these findings, we propose that Tax expression in activated lymphocytes initiates a cascade of events that leads to NK/T cell recruitment, activation, and transformation. The use of BLI expands our ability to interrogate the role of Tax in tumorigenesis in vivo and has made the association of inflammation with tumor initiation amenable for study.

Identification of a Ligand-induced Transient Refractory Period in Nuclear Factor-κB Signaling

In response to a variety of extracellular ligands, nuclear factor-κB (NF-κB) signaling regulates inflammation, cell proliferation, and apoptosis. It is likely that cells are not continuously exposed to stimulating ligands in vivo but rather experience transient pulses. To study the temporal regulation of NF-κB and its major regulator, inhibitor of NF-κBα (IκBα), in real time, we utilized a novel transcriptionally coupled IκBα-firefly luciferase fusion reporter and characterized the dynamics and responsiveness of IκBα processing upon a short 30-s pulse of tumor necrosis factor α (TNFα) or a continuous challenge of TNFα following a 30-s preconditioning pulse. Strikingly, a 30-s pulse of TNFα robustly activated inhibitor of NF-κB kinase (IKK), leading to IκBα degradation, NF-κB nuclear translocation, and strong transcriptional up-regulation of IκBα. Furthermore, we identified a transient refractory period (lasting up to 120 min) following preconditioning, during which the cells were not able to fully degrade IκBα upon a second TNFα challenge. Kinase assays of IKK activity revealed that regulation of IKK activity correlated in part with this transient refractory period. In contrast, experiments involving sequential exposure to TNFα and interleukin-1β indicated that receptor dynamics could not explain this phenomenon. Utilizing a well accepted computational model of NF-κB dynamics, we further identified an additional layer of regulation, downstream of IKK, that may govern the temporal capacity of cells to respond to a second proinflammatory insult. Overall, the data suggested that nuclear export of NF-κB·IκBα complexes represented another rate-limiting step that may impact this refractory period, thereby providing an additional regulatory mechanism.

Interrogation of inhibitor of nuclear factor κB α/nuclear factor κB (IκBα/NF-κB) negative feedback loop dynamics: from single cells to live animals in vivo.

Background: Understanding the biological significance of feedback loops requires interrogation at multiple scales. Results: A nuclear factor κB (NF-κB) negative feedback reporter revealed stimulus-specific dynamics in cells and animals in vivo. Conclusion: Circulating tumor necrosis factor α (TNFα) doses are perceived by the liver as pulses. Significance: Bioluminescent imaging of live single cells and cell populations revealed reproducible behaviors that informed interpretation of in vivo data. Full understanding of the biological significance of negative feedback processes requires interrogation at multiple scales as follows: in single cells, cell populations, and live animals in vivo. The transcriptionally coupled IκBα/NF-κB negative feedback loop, a pivotal regulatory node of innate immunity and inflammation, represents a model system for multiscalar reporters. Using a κB5→IκBα-FLuc bioluminescent reporter, we rigorously evaluated the dynamics of ΙκBα degradation and subsequent NF-κB transcriptional activity in response to diverse modes of TNFα stimulation. Modulating TNFα concentration or pulse duration yielded complex, reproducible, and differential ΙκBα dynamics in both cell populations and live single cells. Tremendous heterogeneity in the transcriptional amplitudes of individual responding cells was observed, which was greater than the heterogeneity in the transcriptional kinetics of responsive cells. Furthermore, administration of various TNFα doses in vivo generated ΙκBα dynamic profiles in the liver resembling those observed in single cells and populations of cells stimulated with TNFα pulses. This suggested that dose modulation of circulating TNFα was perceived by hepatocytes in vivo as pulses of increasing duration. Thus, a robust bioluminescent reporter strategy enabled rigorous quantitation of NF-κB/ΙκBα dynamics in both live single cells and cell populations and furthermore, revealed reproducible behaviors that informed interpretation of in vivo studies.

Abstract LB-419: Multi-scalar approaches to interrogate the IκBα:NF-κB negative feedback loop: Quantitative dynamics in single cells, cell populations, and live animals in vivo

Cells have evolved complex molecular networks to sense environmental signals, transmit this information through the cell, and elicit appropriate biological responses. In particular, negative feedback loops represent a widely-utilized network motif capable of eliciting transient responses. To truly understand the biological significance of negative feedback processes, it is critical to study them at multiple scales: in single cells, in cell populations, and in animals. The IκBα:NF-κB negative feedback loop, a pivotal regulatory node of innate immunity and inflammation active in both immune cells and non-immune tissues, represents a model system for the use of multi-scalar reporter systems. To this end, we have utilized the κB 5 →IκBα-FLuc bioluminescent reporter to study dynamics of this transcriptionally-coupled negative feedback loop in response to diverse modes of stimulation which may be particularly relevant during cellular responses to inflammatory cytokines, such as TNFα. The κB 5 →IκBα-FLuc reporter enabled rigorous evaluation of the stimulus-specific dynamics of βκγα degradation and the downstream consequences of NF-κΔ nuclear translocation (i.e., NF-κΔ transcriptional activity) in single cells, cell populations and live animals in vivo. In response to modulation of TNFα concentration and pulse duration, complex, differential patterns in βκγα degradation and re-synthesis were discovered in both cell populations and single cells. Furthermore, IκBα dynamics observed in live animals in vivo upon modulation of TNFα dose strongly resembled those observed in single cells and cell populations upon modulating TNFα pulse duration, suggesting that increased doses of circulating TNFα were perceived by hepatocytes in vivo as pulses of increasing duration. Thus, a single bioluminescent reporter strategy enabled correlative quantitation of dynamic NF-κα:βκβα negative feedback loop responses in live single cells, cell populations, and tissues in vivo with a variety of rapid, low-cost, high-throughput approaches. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr LB-419. doi:1538-7445.AM2012-LB-419