A detailed understanding of human health and disease requires methods to probe cellular behaviors as they occur within intact organ structures and living subjects. In recent years, technologies have emerged from the imaging community that enable diverse biological features to be visualized and tracked in real time. While powerful, these approaches have been largely confined to monitoring cellular behaviors on a microscopic level. Visualizing cellular functions across larger spatial scales?including those involved in cancer progression and migration?requires new imaging tools. Grant GM107630 aims to develop general strategies for macroscopic, multi-cell tracking with bioluminescent tools in living organisms. Bioluminescence imaging is a powerful technique for visualizing small numbers of cells in rodent models. This technology employs enzymes (luciferases) that produce light upon incubation with small molecule substrates (luciferins). Several luciferase-luciferin pairs exist in nature, and many have been adapted for tracking cells in whole animals. Unfortunately, the optimal luciferases for in vivo imaging use the same substrate, and therefore cannot be used to distinguish multiple cell types in a single subject. The PI and her team have demonstrated that the substrate-binding interface of firefly luciferase can be re-engineered to generate panels of mutant enzymes that accept chemically distinct luciferins. When mutants and analogs are mixed together, light emission is produced only when complementary enzyme-substrate partners interact. Ongoing work seeks to generate improved orthogonal imaging tools using a combination of rational design and screening. Our goals include (1) uncovering the molecular determinants of orthogonality (via crystallography and deep-sequencing analyses) for lead pair optimization; 2) generating orthogonal probes with improved tissue penetrance; and 3) imaging tumor heterogeneity with expanded orthogonal toolsets. Our research would be dramatically accelerated by the purchase of an all-in-one fluorescence microscope. Successful translation of the orthogonal luciferases in vivo requires benchmarking the bioluminescent enzymes against established markers (e.g., fluorescent proteins). Luciferase-fluorescent protein constructs also provide a ?one-stop-shop? for tool users, enabling macro-scale imaging and analyses (via bioluminescence) and micro-scale imaging/ex vivo analyses (via fluorescence). The fluorescence microscope will also enable the development of probes that can demarcate cellular location and function within heterogeneous systems. Such tools will further augment our studies of tumor-immune cell interactions. The proposed research is significant, as the imaging tools will enable the direct interrogation of cellular networks not currently possible with existing toolsets. Such studies may fundamentally change existing views on cancer progression. Additionally, similar to other imaging technologies, the probes will likely inspire new discoveries in a broad spectrum of fields.

Public Health Relevance

Supplemental support is requested for the purchase of a fluorescence microscope. This instrument will enhance our NIH-funded research on bioluminescent probe development. The microscope will relieve a current bottleneck in our work and accelerate efforts to produce new imaging tools to track cancer progression and other multi-component processes in relevant model organisms. This application is coordinated with that of another NIGMS-funded scientist.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
3R01GM107630-06S1
Application #
9708293
Study Section
Program Officer
Fabian, Miles
Project Start
2013-07-01
Project End
2022-04-30
Budget Start
2018-05-01
Budget End
2019-04-30
Support Year
6
Fiscal Year
2018
Total Cost
Indirect Cost
Name
University of California Irvine
Department
Chemistry
Type
Schools of Arts and Sciences
DUNS #
046705849
City
Irvine
State
CA
Country
United States
Zip Code
92617
Zhang, Brendan S; Jones, Krysten A; McCutcheon, David C et al. (2018) Pyridone Luciferins and Mutant Luciferases for Bioluminescence Imaging. Chembiochem 19:470-477
Liu, Mira D; Warner, Elliot A; Morrissey, Charlotte E et al. (2018) Statistical Coupling Analysis-Guided Library Design for the Discovery of Mutant Luciferases. Biochemistry 57:663-671
Yao, Zi; Zhang, Brendan S; Prescher, Jennifer A (2018) Advances in bioluminescence imaging: new probes from old recipes. Curr Opin Chem Biol 45:148-156
Jones, Krysten A; Porterfield, William B; Rathbun, Colin M et al. (2017) Orthogonal Luciferase-Luciferin Pairs for Bioluminescence Imaging. J Am Chem Soc 139:2351-2358
Rathbun, Colin M; Porterfield, William B; Jones, Krysten A et al. (2017) Parallel Screening for Rapid Identification of Orthogonal Bioluminescent Tools. ACS Cent Sci 3:1254-1261
Steinhardt, Rachel C; Rathbun, Colin M; Krull, Brandon T et al. (2017) Brominated Luciferins Are Versatile Bioluminescent Probes. Chembiochem 18:96-100
Rathbun, Colin M; Prescher, Jennifer A (2017) Bioluminescent Probes for Imaging Biology beyond the Culture Dish. Biochemistry 56:5178-5184
Steinhardt, Rachel C; O'Neill, Jessica M; Rathbun, Colin M et al. (2016) Design and Synthesis of an Alkynyl Luciferin Analogue for Bioluminescence Imaging. Chemistry 22:3671-5
McCutcheon, David C; Porterfield, William B; Prescher, Jennifer A (2015) Rapid and scalable assembly of firefly luciferase substrates. Org Biomol Chem 13:2117-21
Evans, Melanie S; Chaurette, Joanna P; Adams Jr, Spencer T et al. (2014) A synthetic luciferin improves bioluminescence imaging in live mice. Nat Methods 11:393-5

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