[R35] Photoswitchable Dyes for Super-Resolution Microscopy
Ente: National Institute of General Medical Sciences
Scadenza: 2031-06-30
Importo max: 408.750 EUR
Paese: US
Descrizione
Super-resolution microscopy, i.e., nanoscopy, breaks away from the ~200 nm resolution restriction of
optical microscopy, known as the Abbe diffraction limit, opening the way for the optical imaging of small
molecules that are at the core of biological processes. In principle, nanoscopy techniques can result in real-time,
3D, single molecule imagining in live specimens. To this end, molecules whose emission can be switched ON
and OFF are required, and while there has been much progress in this area, the development of fluorescent
molecules with appropriate properties (e.g., high ON/OFF contrast, photo-stability, fatigue resistance, red-shifted
activation/emission, fast kinetics, biocompatibility, etc.) has proved to be extremely challenging. For example,
while there are reversible photoswitchable proteins, their emission wavelengths and quantum yields are limited
and/or low. On the other hand, reversible organic dyes might be brighter but suffer from poor biocompatibility,
small contrast ratios, photobleaching and so on. Addressing these issues will be critical for nanoscopy to realize
its full potential - the molecular level visualization of biological processes as they occur.
My group has developed a new family of bistable hydrazone-based switches whose emission can be
toggled ON and OFF using different wavelengths of light in organic and aqueous solutions (including serum),
the solid-state and even in HeLa cells. The switches have very good absorption coefficients and emission
quantum yields, and hence brightness. The combination of these properties in a structurally simple platform that
can be easily synthesized and derivatized is unique and highly desirable, making this family of switchable
fluorophores highly competitive with protein or organic dye-based switchable fluorophores.
The overarching goal of this MIRA proposal is to transform these switchable hydrazones into an array of
multifunctional, bright, tunable, water-soluble, biocompatible, and conjugatable dyes with broad potential utility
in nanoscopy. As part of the grant, we will apply a multipronged approach to enhance the photophysical
properties of the dyes through hypothesis-driven structure-property analyses, which will be aided and guided by
DFT calculations, combined with spectroscopic characterization including bio-imaging. Ultimately, and through
feedback loops that will guide us in improving our design principles and hypotheses, we will gain the fundamental
insights needed to transform the switchable hydrazones into probes that can be used in multiplexed live-cell
imaging using nanoscopy. Such an accomplishment will in turn expand the toolbox available to practitioners,
while enhancing the window of application opportunities available to them. As part of our efforts, we will also
design switchable fluorophores that can selectively bind to soluble amyloid (A) oligomers, so they can be
imaged using nanoscopy. These studies will provide insights and high-resolution images
Istituzione: DARTMOUTH COLLEGE
PI: Ivan Aprahamian
Progetto: 1R35GM161714-01
Settori: National Institute of General Medical Sciences
Vai al bando originale
Registrati gratis su Bandolo per trovare bandi compatibili con la tua azienda.