BACKGROUND: The nuclear factor-κB (NF-κB) family of transcription factors plays a role in a wide range of cellular processes including the immune response and cellular growth. In addition, deregulation of the NF-κB system has been associated with a number of disease states, including cancer. Therefore, insight into the regulation of NF-κB activation has crucial medical relevance, holding promise for novel drug target discovery. Transcription of NF-κB-induced genes is regulated by differential dynamics of single NF-κB subunits, but only a few methods are currently being applied to study dynamics. In particular, while oscillations of NF-κB activation have been observed in response to the cytokine tumor necrosis factor α (TNFα), little is known about the occurrence of oscillations in response to bacterial infections. RESULTS: To quantitatively assess NF-κB dynamics we generated human and murine monoclonal cell lines that stably express the NF-κB subunit p65 fused to GFP. Furthermore, a high-throughput assay based on automated microscopy coupled to image analysis to quantify p65-nuclear translocation was established. Using this assay, we demonstrate a stimulus- and cell line-specific temporal control of p65 translocation, revealing, for the first time, oscillations of p65 translocation in response to bacterial infection. Oscillations were detected at the single-cell level using real-time microscopy as well as at the population level using high-throughput image analysis. In addition, mathematical modeling of NF-κB dynamics during bacterial infections predicted masking of oscillations on the population level in asynchronous activations, which was experimentally confirmed. CONCLUSIONS: Taken together, this simple and cost effective assay constitutes an integrated approach to infer the dynamics of NF-κB kinetics in single cells and cell populations. Using a single system, novel factors modulating NF-κB can be identified and analyzed, providing new possibilities for a wide range of applications from therapeutic discovery and understanding of disease to host-pathogen interactions

Bartfeld, S.

Bauer, B.

Hess, S.

Machuy, N.

Meyer, T.F.

Ogilvie, Lesley

Schuchhardt, J.

PubMed

Background: The nuclear factor-kappa B (NF-kappa B) family of transcription factors plays a role in a wide range of cellular processes including the immune response and cellular growth. In addition, deregulation of the NF-kappa B system has been associated with a number of disease states, including cancer. Therefore, insight into the regulation of NF-kappa B activation has crucial medical relevance, holding promise for novel drug target discovery. Transcription of NF-kappa B-induced genes is regulated by differential dynamics of single NF-kappa B subunits, but only a few methods are currently being applied to study dynamics. In particular, while oscillations of NF-kappa B activation have been observed in response to the cytokine tumor necrosis factor alpha (TNF alpha), little is known about the occurrence of oscillations in response to bacterial infections. Results: To quantitatively assess NF-kappa B dynamics we generated human and murine monoclonal cell lines that stably express the NF-kappa B subunit p65 fused to GFP. Furthermore, a high-throughput assay based on automated microscopy coupled to image analysis to quantify p65-nuclear translocation was established. Using this assay, we demonstrate a stimulus-and cell line-specific temporal control of p65 translocation, revealing, for the first time, oscillations of p65 translocation in response to bacterial infection. Oscillations were detected at the single-cell level using real-time microscopy as well as at the population level using high-throughput image analysis. In addition, mathematical modeling of NF-kappa B dynamics during bacterial infections predicted masking of oscillations on the population level in asynchronous activations, which was experimentally confirmed. Conclusions: Taken together, this simple and cost effective assay constitutes an integrated approach to infer the dynamics of NF-kappa B kinetics in single cells and cell populations. Using a single system, novel factors modulating NF-kappa B can be identified and analyzed, providing new possibilities for a wide range of applications from therapeutic discovery and understanding of disease to host-pathogen interactions

Bartfeld, Sina

Hess, Simone

Bauer, Bianca

Machuy, Nikolaus

Ogilvie, Lesley A.

Schuchhardt, Johannes

Meyer, Thomas F.

Max Planck Society eDoc Server

High-throughput and single-cell imaging of NF-kappa B oscillations using monoclonal cell lines

Sina Bartfeld

Simone Hess

Bianca Bauer

Nikolaus Machuy

Lesley A Ogilvie

Johannes Schuchhardt

Thomas F Meyer

Springer - Publisher Connector

High-throughput and single-cell imaging of NF-κB oscillations using monoclonal cell lines

University of Brighton Research Portal

High-throughput and single-cell imaging of NF-kappaB oscillations using monoclonal cell lines

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High-throughput and single-cell imaging of NF-kappaB oscillations using monoclonal cell lines

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