As mitochondria are central hubs for energy metabolism and formation of intermediate metabolites, they must be able to transmit signals that communicate alterations in its functioning to the nucleus so that cells can remodel metabolism in response. Mitochondrial-nuclear signaling is particularly important when mitochondrial function is compromised by environmental toxicants, including heavy metals. However, the nature and dynamics of these inter-organelle signals and the mechanisms by which they are transduced are poorly understood. Given the importance of heme-regulated transcription factors that control diverse cellular processes from energy metabolism to the anti-oxidant stress response to cell proliferation, and the exquisite sensitivity of mitochondrial heme homeostasis to heavy metals, we propose that mitochondrial- derived heme signals the cellular response to heavy metal toxicity through mitochondrial-nuclear retrograde regulation. However, the chemical and genetic tools available to study the transmission of heme-based signals do not exist. In the current grant application, the focus is to generate and apply a genetically encoded ratiometric fluorescent heme sensors in cell and animal models to study the transduction of mitochondrial-derived intra- and inter-organ heme signals in response to heavy metal toxicity. During the R21 phase, the intent is develop and apply the first ratiometric heme sensors for quantitative heme imaging in yeast and mammalian cell models of heavy metal toxicity. Finally, the goal is to (a) characterize the thermodynamics of heme binding to the heme sensors and apply them site-specifically in the yeast mitochondrial matrix, inter-membrane space, cytosol, and nucleus to quantitatively image heme signals in response to lead toxicity; and (b) apply sensors in a compartment specific manner in mammalian cell models of lead toxicity. Successful completion of these aims will provide the impetus to begin the R33 phase in which studies will be expanded to develop heme sensors that can be utilized for simultaneous imaging of heme between cellular compartments, and that are oxidation state-specific, and apply them to animal models of Pb toxicity. In this phase the focus is to (a) diversify the color palate of the heme sensors for simultaneous fluorescence imaging between subcellular compartments and develop Fe3+ and Fe2+ heme specific sensors; and (b) deploy these sensors in mammalian cell lines and a C. elegans model of environmental toxicity. Altogether, these studies will result in the first sensors for quantitative imaging of labile heme relevant to its role in cell signaling and establish heme a a vital mitochondria-derived signaling molecule that initiates the adaptation to heavy metal toxicity in both cell and animal models.

Public Health Relevance

Heavy metals pose a significant environmental hazard and are a major public health concern due to their cytotoxicity. Through innovative imaging tools and model organisms, we propose to determine the role of mitochondria-derived heme signaling in initiating the adaptation to lead toxicity in cell and animal models of heavy metal stress. These studies will be the first to establish intra- and inter-organ heme signaling as a paradigm by which cells and organisms respond to environmental toxicants.

Agency
National Institute of Health (NIH)
Institute
National Institute of Environmental Health Sciences (NIEHS)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21ES025661-01
Application #
8927908
Study Section
Special Emphasis Panel (ZES1-LWJ-D (ME))
Program Officer
Shaughnessy, Daniel
Project Start
2015-05-01
Project End
2017-04-30
Budget Start
2015-05-01
Budget End
2016-04-30
Support Year
1
Fiscal Year
2015
Total Cost
$197,737
Indirect Cost
$46,737
Name
Georgia Institute of Technology
Department
Chemistry
Type
Schools of Arts and Sciences
DUNS #
097394084
City
Atlanta
State
GA
Country
United States
Zip Code
30332
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