Integrated biophotonics approach for noninvasive and multiscale studies of biomolecular and cellular biophysics

Qianru Yu; Michael Proia; Ahmed A. Heikal

doi:10.1117/1.2952297

Integrated biophotonics approach for noninvasive and multiscale studies of biomolecular and cellular biophysics

Qianru Yu, Michael Proia, Ahmed A. Heikal

Chemistry & Biochemistry

Research output: Contribution to journal › Article › peer-review

28 Scopus citations

Abstract

In the crowded cellular milieu, biological processes require coordinated intermolecular interactions, conformational changes, and molecular transport that span a wide range of spatial and temporal scales. This complexity requires an integrated, noninvasive, multiscale experimental approach. Here, we develop a multimodal fluorescence microspectroscopy system, integrated on a single platform, to gain information about molecular interactions and their dynamics with high spatio-temporal resolution. To demonstrate the versatility of our experimental approach, we use rhodamine 123-labeled mitochondria in breast cancer cells (Hs578T), verified using differential interference contrast (DIC) and fluorescence (confocal and two-photon) microscopy, as a model system. We develop an assay to convert fluorescence intensity to actual concentrations in intact, individual living cells, which contrasts with conventional biochemical techniques that require cell lysates. In this assay, we employ two-photon fluorescence lifetime imaging microscopy (FLIM) to quantify the fluorescence quantum yield variations found within individual cells. Functionally driven changes in cell environment, molecular conformation, and rotational diffusion are investigated using fluorescence polarization anisotropy imaging. Moreover, we quantify translational diffusion and chemical kinetics of large molecular assemblies using fluorescence correlation spectroscopy. Our integrated approach can be applied to a wide range of molecular and cellular processes, such as receptor-mediated signaling and metabolic activation.

Original language	English (US)
Article number	041315
Journal	Journal of biomedical optics
Volume	13
Issue number	4
DOIs	https://doi.org/10.1117/1.2952297
State	Published - 2008

Bibliographical note

Funding Information:
We are grateful to Michael Edidin (The Johns Hopkins University) for intriguing and helpful discussions. We thank Andrew Lutes, Florly Ariola, Angel Davey, and Minjoung Ky-oung for their help with the manuscript preparation and useful discussion. We are also thankful to Jhanvi H. Dangaria (Dr. Peter Butler Laboratory, Bioengineering) for her help in the optical tracking calculation. This work was supported by the Penn State Materials Research Institute, the Penn State MR-SEC (under NSF grant DMR 0213623), the Lehigh-Penn State Center for Optical Technologies, and the Huck Institutes of the Life Science (Penn State University). Additional support was also provided by the National Science Foundation (Grant AG030949), and a Johnson and Johnson/Penn State Innovative Technology Research Seed Grant. We are thankful to Coherent Lasers, Incorporated for their loan of a pulse picker (MIRA9200).

Keywords

biophotonics
fluorescence correlation spectroscopy
fluorescence lifetime imaging microscopy
mitochondria
polarization anisotropy
rhodamine 123
rotational diffusion
translational diffusion

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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title = "Integrated biophotonics approach for noninvasive and multiscale studies of biomolecular and cellular biophysics",

abstract = "In the crowded cellular milieu, biological processes require coordinated intermolecular interactions, conformational changes, and molecular transport that span a wide range of spatial and temporal scales. This complexity requires an integrated, noninvasive, multiscale experimental approach. Here, we develop a multimodal fluorescence microspectroscopy system, integrated on a single platform, to gain information about molecular interactions and their dynamics with high spatio-temporal resolution. To demonstrate the versatility of our experimental approach, we use rhodamine 123-labeled mitochondria in breast cancer cells (Hs578T), verified using differential interference contrast (DIC) and fluorescence (confocal and two-photon) microscopy, as a model system. We develop an assay to convert fluorescence intensity to actual concentrations in intact, individual living cells, which contrasts with conventional biochemical techniques that require cell lysates. In this assay, we employ two-photon fluorescence lifetime imaging microscopy (FLIM) to quantify the fluorescence quantum yield variations found within individual cells. Functionally driven changes in cell environment, molecular conformation, and rotational diffusion are investigated using fluorescence polarization anisotropy imaging. Moreover, we quantify translational diffusion and chemical kinetics of large molecular assemblies using fluorescence correlation spectroscopy. Our integrated approach can be applied to a wide range of molecular and cellular processes, such as receptor-mediated signaling and metabolic activation.",

keywords = "biophotonics, fluorescence correlation spectroscopy, fluorescence lifetime imaging microscopy, mitochondria, polarization anisotropy, rhodamine 123, rotational diffusion, translational diffusion",

author = "Qianru Yu and Michael Proia and Heikal, {Ahmed A.}",

note = "Funding Information: We are grateful to Michael Edidin (The Johns Hopkins University) for intriguing and helpful discussions. We thank Andrew Lutes, Florly Ariola, Angel Davey, and Minjoung Ky-oung for their help with the manuscript preparation and useful discussion. We are also thankful to Jhanvi H. Dangaria (Dr. Peter Butler Laboratory, Bioengineering) for her help in the optical tracking calculation. This work was supported by the Penn State Materials Research Institute, the Penn State MR-SEC (under NSF grant DMR 0213623), the Lehigh-Penn State Center for Optical Technologies, and the Huck Institutes of the Life Science (Penn State University). Additional support was also provided by the National Science Foundation (Grant AG030949), and a Johnson and Johnson/Penn State Innovative Technology Research Seed Grant. We are thankful to Coherent Lasers, Incorporated for their loan of a pulse picker (MIRA9200).",

year = "2008",

doi = "10.1117/1.2952297",

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T1 - Integrated biophotonics approach for noninvasive and multiscale studies of biomolecular and cellular biophysics

AU - Yu, Qianru

AU - Proia, Michael

AU - Heikal, Ahmed A.

N1 - Funding Information: We are grateful to Michael Edidin (The Johns Hopkins University) for intriguing and helpful discussions. We thank Andrew Lutes, Florly Ariola, Angel Davey, and Minjoung Ky-oung for their help with the manuscript preparation and useful discussion. We are also thankful to Jhanvi H. Dangaria (Dr. Peter Butler Laboratory, Bioengineering) for her help in the optical tracking calculation. This work was supported by the Penn State Materials Research Institute, the Penn State MR-SEC (under NSF grant DMR 0213623), the Lehigh-Penn State Center for Optical Technologies, and the Huck Institutes of the Life Science (Penn State University). Additional support was also provided by the National Science Foundation (Grant AG030949), and a Johnson and Johnson/Penn State Innovative Technology Research Seed Grant. We are thankful to Coherent Lasers, Incorporated for their loan of a pulse picker (MIRA9200).

PY - 2008

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N2 - In the crowded cellular milieu, biological processes require coordinated intermolecular interactions, conformational changes, and molecular transport that span a wide range of spatial and temporal scales. This complexity requires an integrated, noninvasive, multiscale experimental approach. Here, we develop a multimodal fluorescence microspectroscopy system, integrated on a single platform, to gain information about molecular interactions and their dynamics with high spatio-temporal resolution. To demonstrate the versatility of our experimental approach, we use rhodamine 123-labeled mitochondria in breast cancer cells (Hs578T), verified using differential interference contrast (DIC) and fluorescence (confocal and two-photon) microscopy, as a model system. We develop an assay to convert fluorescence intensity to actual concentrations in intact, individual living cells, which contrasts with conventional biochemical techniques that require cell lysates. In this assay, we employ two-photon fluorescence lifetime imaging microscopy (FLIM) to quantify the fluorescence quantum yield variations found within individual cells. Functionally driven changes in cell environment, molecular conformation, and rotational diffusion are investigated using fluorescence polarization anisotropy imaging. Moreover, we quantify translational diffusion and chemical kinetics of large molecular assemblies using fluorescence correlation spectroscopy. Our integrated approach can be applied to a wide range of molecular and cellular processes, such as receptor-mediated signaling and metabolic activation.

AB - In the crowded cellular milieu, biological processes require coordinated intermolecular interactions, conformational changes, and molecular transport that span a wide range of spatial and temporal scales. This complexity requires an integrated, noninvasive, multiscale experimental approach. Here, we develop a multimodal fluorescence microspectroscopy system, integrated on a single platform, to gain information about molecular interactions and their dynamics with high spatio-temporal resolution. To demonstrate the versatility of our experimental approach, we use rhodamine 123-labeled mitochondria in breast cancer cells (Hs578T), verified using differential interference contrast (DIC) and fluorescence (confocal and two-photon) microscopy, as a model system. We develop an assay to convert fluorescence intensity to actual concentrations in intact, individual living cells, which contrasts with conventional biochemical techniques that require cell lysates. In this assay, we employ two-photon fluorescence lifetime imaging microscopy (FLIM) to quantify the fluorescence quantum yield variations found within individual cells. Functionally driven changes in cell environment, molecular conformation, and rotational diffusion are investigated using fluorescence polarization anisotropy imaging. Moreover, we quantify translational diffusion and chemical kinetics of large molecular assemblies using fluorescence correlation spectroscopy. Our integrated approach can be applied to a wide range of molecular and cellular processes, such as receptor-mediated signaling and metabolic activation.

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KW - fluorescence correlation spectroscopy

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KW - polarization anisotropy

KW - rhodamine 123

KW - rotational diffusion

KW - translational diffusion

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JO - Journal of biomedical optics

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ER -

Integrated biophotonics approach for noninvasive and multiscale studies of biomolecular and cellular biophysics

Abstract

Bibliographical note

Keywords

UN SDGs

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