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Cyanine Conformational Restraint in the Far-Red Range

  1. Author:
    Michie, Megan S
    Götz, Ralph
    Franke, Christian
    Bowler, Matthew
    Kumari, Nikita
    Magidson, Valentin
    Levitus, Marcia
    Loncarek, Jadranka
    Sauer, Markus
    Schnermann, Martin [ORCID]

  2. Author Address

    Laboratory of Chemical Biology, NIH/NCI/CCR , 376 Boyles Street, Frederick, Maryland 21702, United States., Department of Biotechnology and Biophysics, Julius Maximilian University W 252;rzburg , Am Hubland 97074 W 252;rzburg, Germany., Optical Microscopy and Analysis Laboratory, NIH/NCI/CCR , 1050 Boyles Street, Frederick, Maryland 21702, United States., School of Molecular Sciences and The Biodesign Institute at Arizona State University , Tempe, Arizona 85287, United States., Optical Microscopy and Analysis Laboratory, Leidos Biomedical Res. Inc., Frederick National Laboratory for Cancer Research , Frederick, Maryland 21702, United States., Laboratory of Protein Dynamics and Signaling, NIH/NCI/CCR , 1050 Boyles Street, Frederick, Maryland 21702, United States.,
    1. Year: 2017
    2. Date: SEP 13
    3. Epub Date: 2017 Sep 01
  2. Journal: Journal of the American Chemical Society
    1. 139
    2. 36
    3. Pages: 12406-12409
  4. Type of Article: Article
  5. ISSN: 0002-7863
  1. Abstract:

    Far-red cyanine fluorophores find extensive use in modern microscopy despite modest quantum yields. To improve the photon output of these molecules, we report a synthetic strategy that blocks the major deactivation pathway: excited-state trans-to-cis polyene rotation. In the key transformation, a protected dialdehyde precursor undergoes a cascade reaction to install the requisite tetracyclic ring system. The resulting molecules exhibit the characteristic features of conformational restraint, including improved fluorescence quantum yield and extended lifetime. Moreover, these compounds recover from hydride reduction with dramatically improved efficiency. These observations enable efficient single-molecule localization microscopy in oxygenated buffer without addition of thiols. Enabled by modern organic synthesis, these studies provide a new class of far-red dyes with promising spectroscopic and chemical properties.

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External Sources

  1. View Full Text
  2. DOI: 10.1021/jacs.7b07272
  3. PMID: 28862842
  4. View record in Web of Science®
  5. WOS: 000411043900019

Library Notes

  1. Fiscal Year: FY2016-2017
  2. Group/Lab/Department: Chemical Biology Laboratory, Chief = Joel P. Schneider (NCI); Optical Microscopy and Analysis Laboratory, Director = Stephen Lockett (Leidos)
NCI at Frederick

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