Autofluorescent Proteins with Excitation in the Optical Window for Intravital Imaging in Mammals

Michael Z. Lin; Michael R. McKeown; Ho Leung Ng; Todd A. Aguilera; Nathan C. Shaner; Robert E. Campbell; Stephen R. Adams; Larry A. Gross; Wendy Ma; Tom Alber; Roger Y. Tsien

doi:10.1016/j.chembiol.2009.10.009

Autofluorescent Proteins with Excitation in the Optical Window for Intravital Imaging in Mammals

Michael Z. Lin, Michael R. McKeown, Ho Leung Ng, Todd A. Aguilera, Nathan C. Shaner, Robert E. Campbell, Stephen R. Adams, Larry A. Gross, Wendy Ma, Tom Alber, Roger Y. Tsien

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

211 Scopus citations

Abstract

Fluorescent proteins have become valuable tools for biomedical research as protein tags, reporters of gene expression, biosensor components, and cell lineage tracers. However, applications of fluorescent proteins for deep tissue imaging in whole mammals have been constrained by the opacity of tissues to excitation light below 600 nm, because of absorbance by hemoglobin. Fluorescent proteins that excite efficiently in the "optical window" above 600 nm are therefore highly desirable. We report here the evolution of far-red fluorescent proteins with peak excitation at 600 nm or above. The brightest one of these, Neptune, performs well in imaging deep tissues in living mice. The crystal structure of Neptune reveals a novel mechanism for red-shifting involving the acquisition of a new hydrogen bond with the acylimine region of the chromophore.

Original language	English (US)
Pages (from-to)	1169-1179
Number of pages	11
Journal	Chemistry and Biology
Volume	16
Issue number	11
DOIs	https://doi.org/10.1016/j.chembiol.2009.10.009
State	Published - 2009

Keywords

CELLBIO
CHEMBIO

ASJC Scopus subject areas

Biochemistry
Molecular Medicine
Molecular Biology
Pharmacology
Drug Discovery
Clinical Biochemistry

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10.1016/j.chembiol.2009.10.009

Cite this

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title = "Autofluorescent Proteins with Excitation in the Optical Window for Intravital Imaging in Mammals",

abstract = "Fluorescent proteins have become valuable tools for biomedical research as protein tags, reporters of gene expression, biosensor components, and cell lineage tracers. However, applications of fluorescent proteins for deep tissue imaging in whole mammals have been constrained by the opacity of tissues to excitation light below 600 nm, because of absorbance by hemoglobin. Fluorescent proteins that excite efficiently in the {"}optical window{"} above 600 nm are therefore highly desirable. We report here the evolution of far-red fluorescent proteins with peak excitation at 600 nm or above. The brightest one of these, Neptune, performs well in imaging deep tissues in living mice. The crystal structure of Neptune reveals a novel mechanism for red-shifting involving the acquisition of a new hydrogen bond with the acylimine region of the chromophore.",

keywords = "CELLBIO, CHEMBIO",

author = "Lin, {Michael Z.} and McKeown, {Michael R.} and Ng, {Ho Leung} and Aguilera, {Todd A.} and Shaner, {Nathan C.} and Campbell, {Robert E.} and Adams, {Stephen R.} and Gross, {Larry A.} and Wendy Ma and Tom Alber and Tsien, {Roger Y.}",

note = "Funding Information: We thank Paul Steinbach for assisting with protein photobleaching and related analysis. We acknowledge the following sources of support: the Jane Coffin Childs Foundation and a Burroughs Wellcome Career Award for Medical Scientists (M.Z.L.), the University of California, San Diego, Chancellor's Award for Undergraduate Research (M.R.M.), a Howard Hughes Medical Institute (HHMI) predoctoral fellowship (N.C.S.), a Canadian Institutes of Health Research postdoctoral fellowship (R.E.C.), the National Institutes of Health (NIH) Medical Scientist Training Program and U.S. Army Breast Cancer Research Program (BCRP) grant W81XWH-05-01-0183 (T.A.A.), NIH grant R01 GM048958 (H-L.N., W.M., and T.A.), HHMI, NIH grants R01 GM086197 and R37 NS027177, and BCRP grant W81XWH-05-01-0183 (R.Y.T.). ",

year = "2009",

doi = "10.1016/j.chembiol.2009.10.009",

language = "English (US)",

volume = "16",

pages = "1169--1179",

journal = "Chemistry and Biology",

issn = "1074-5521",

publisher = "Elsevier Inc.",

number = "11",

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TY - JOUR

T1 - Autofluorescent Proteins with Excitation in the Optical Window for Intravital Imaging in Mammals

AU - Lin, Michael Z.

AU - McKeown, Michael R.

AU - Ng, Ho Leung

AU - Aguilera, Todd A.

AU - Shaner, Nathan C.

AU - Campbell, Robert E.

AU - Adams, Stephen R.

AU - Gross, Larry A.

AU - Ma, Wendy

AU - Alber, Tom

AU - Tsien, Roger Y.

N1 - Funding Information: We thank Paul Steinbach for assisting with protein photobleaching and related analysis. We acknowledge the following sources of support: the Jane Coffin Childs Foundation and a Burroughs Wellcome Career Award for Medical Scientists (M.Z.L.), the University of California, San Diego, Chancellor's Award for Undergraduate Research (M.R.M.), a Howard Hughes Medical Institute (HHMI) predoctoral fellowship (N.C.S.), a Canadian Institutes of Health Research postdoctoral fellowship (R.E.C.), the National Institutes of Health (NIH) Medical Scientist Training Program and U.S. Army Breast Cancer Research Program (BCRP) grant W81XWH-05-01-0183 (T.A.A.), NIH grant R01 GM048958 (H-L.N., W.M., and T.A.), HHMI, NIH grants R01 GM086197 and R37 NS027177, and BCRP grant W81XWH-05-01-0183 (R.Y.T.).

PY - 2009

Y1 - 2009

N2 - Fluorescent proteins have become valuable tools for biomedical research as protein tags, reporters of gene expression, biosensor components, and cell lineage tracers. However, applications of fluorescent proteins for deep tissue imaging in whole mammals have been constrained by the opacity of tissues to excitation light below 600 nm, because of absorbance by hemoglobin. Fluorescent proteins that excite efficiently in the "optical window" above 600 nm are therefore highly desirable. We report here the evolution of far-red fluorescent proteins with peak excitation at 600 nm or above. The brightest one of these, Neptune, performs well in imaging deep tissues in living mice. The crystal structure of Neptune reveals a novel mechanism for red-shifting involving the acquisition of a new hydrogen bond with the acylimine region of the chromophore.

AB - Fluorescent proteins have become valuable tools for biomedical research as protein tags, reporters of gene expression, biosensor components, and cell lineage tracers. However, applications of fluorescent proteins for deep tissue imaging in whole mammals have been constrained by the opacity of tissues to excitation light below 600 nm, because of absorbance by hemoglobin. Fluorescent proteins that excite efficiently in the "optical window" above 600 nm are therefore highly desirable. We report here the evolution of far-red fluorescent proteins with peak excitation at 600 nm or above. The brightest one of these, Neptune, performs well in imaging deep tissues in living mice. The crystal structure of Neptune reveals a novel mechanism for red-shifting involving the acquisition of a new hydrogen bond with the acylimine region of the chromophore.

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JO - Chemistry and Biology

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Autofluorescent Proteins with Excitation in the Optical Window for Intravital Imaging in Mammals

Abstract

Keywords

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