Giving the Green Light to Photochemical Uncaging of Large Biomolecules in High Vacuum

Yong Hua; Marcel Strauss; Sergey Fisher; Martin F.X. Mauser; Pierre Manchet; Martina Smacchia; Philipp Geyer; Armin Shayeghi; Michael Pfeffer; Tim Henri Eggenweiler; Steven Daly; Jan Commandeur; Marcel Mayor; Markus Arndt; Tomáš Šolomek; Valentin Köhler

doi:10.26434/chemrxiv-2023-mgqg3

Giving the Green Light to Photochemical Uncaging of Large Biomolecules in High Vacuum

Yong Hua, Marcel Strauss, Sergey Fisher, Martin F.X. Mauser, Pierre Manchet, Martina Smacchia, Philipp Geyer, Armin Shayeghi, Michael Pfeffer, Tim Henri Eggenweiler, Steven Daly, Jan Commandeur, Marcel Mayor, Markus Arndt (Corresponding author), Tomáš Šolomek (Corresponding author), Valentin Köhler (Corresponding author)

Quantum Optics, Quantum Nanophysics and Quantum Information

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

The isolation of biomolecules in a high vacuum enables experiments on fragile species in the absence of a perturbing environment. Since many molecular properties are influenced by local electric fields, here we seek to gain control over the number of charges on a biopolymer by photochemical uncaging. We present the design, modeling, and synthesis of photoactive molecular tags, their labeling to peptides and proteins as well as their photochemical validation in solution and in the gas phase. The tailored tags can be selectively cleaved off at a well-defined time and without the need for any external charge-transferring agents. The energy of a single or two green photons can already trigger the process, and it is soft enough to ensure the integrity of the released biomolecular cargo. We exploit differences in the cleavage pathways in solution and in vacuum and observe a surprising robustness in upscaling the approach from a model system to genuine proteins. The interaction wavelength of 532 nm is compatible with various biomolecular entities, such as oligonucleotides or oligosaccharides.

Original language	English
Pages (from-to)	2790-2799
Number of pages	10
Journal	JACS Au
Volume	3
Issue number	10
DOIs	https://doi.org/10.26434/chemrxiv-2023-mgqg3 https://doi.org/10.1021/jacsau.3c00351
Publication status	Published - 23 Oct 2023

Austrian Fields of Science 2012

104017 Physical chemistry

Keywords

bioconjugation
biomolecular mass spectrometry
bodipy chromophore
charge reduction
gas-phase heterolysis
molecular beams
photocages
selective fragmentation

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10.26434/chemrxiv-2023-mgqg3Licence: CC BY-NC-ND 4.0
10.1021/jacsau.3c00351Licence: CC BY 4.0

https://phaidra.univie.ac.at/o:2068601Licence: CC BY 4.0

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Hua, Y., Strauss, M., Fisher, S., Mauser, M. F. X., Manchet, P., Smacchia, M., Geyer, P., Shayeghi, A., Pfeffer, M., Eggenweiler, T. H., Daly, S., Commandeur, J., Mayor, M., Arndt, M., Šolomek, T., & Köhler, V. (2023). Giving the Green Light to Photochemical Uncaging of Large Biomolecules in High Vacuum. JACS Au, 3(10), 2790-2799. https://doi.org/10.26434/chemrxiv-2023-mgqg3, https://doi.org/10.1021/jacsau.3c00351

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abstract = "The isolation of biomolecules in a high vacuum enables experiments on fragile species in the absence of a perturbing environment. Since many molecular properties are influenced by local electric fields, here we seek to gain control over the number of charges on a biopolymer by photochemical uncaging. We present the design, modeling, and synthesis of photoactive molecular tags, their labeling to peptides and proteins as well as their photochemical validation in solution and in the gas phase. The tailored tags can be selectively cleaved off at a well-defined time and without the need for any external charge-transferring agents. The energy of a single or two green photons can already trigger the process, and it is soft enough to ensure the integrity of the released biomolecular cargo. We exploit differences in the cleavage pathways in solution and in vacuum and observe a surprising robustness in upscaling the approach from a model system to genuine proteins. The interaction wavelength of 532 nm is compatible with various biomolecular entities, such as oligonucleotides or oligosaccharides.",

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doi = "10.26434/chemrxiv-2023-mgqg3",

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Hua, Y, Strauss, M, Fisher, S, Mauser, MFX, Manchet, P, Smacchia, M, Geyer, P, Shayeghi, A, Pfeffer, M, Eggenweiler, TH, Daly, S, Commandeur, J, Mayor, M, Arndt, M, Šolomek, T & Köhler, V 2023, 'Giving the Green Light to Photochemical Uncaging of Large Biomolecules in High Vacuum', JACS Au, vol. 3, no. 10, pp. 2790-2799. https://doi.org/10.26434/chemrxiv-2023-mgqg3, https://doi.org/10.1021/jacsau.3c00351

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AU - Smacchia, Martina

AU - Geyer, Philipp

AU - Shayeghi, Armin

AU - Pfeffer, Michael

AU - Eggenweiler, Tim Henri

AU - Daly, Steven

AU - Commandeur, Jan

AU - Mayor, Marcel

AU - Arndt, Markus

AU - Šolomek, Tomáš

AU - Köhler, Valentin

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N2 - The isolation of biomolecules in a high vacuum enables experiments on fragile species in the absence of a perturbing environment. Since many molecular properties are influenced by local electric fields, here we seek to gain control over the number of charges on a biopolymer by photochemical uncaging. We present the design, modeling, and synthesis of photoactive molecular tags, their labeling to peptides and proteins as well as their photochemical validation in solution and in the gas phase. The tailored tags can be selectively cleaved off at a well-defined time and without the need for any external charge-transferring agents. The energy of a single or two green photons can already trigger the process, and it is soft enough to ensure the integrity of the released biomolecular cargo. We exploit differences in the cleavage pathways in solution and in vacuum and observe a surprising robustness in upscaling the approach from a model system to genuine proteins. The interaction wavelength of 532 nm is compatible with various biomolecular entities, such as oligonucleotides or oligosaccharides.

AB - The isolation of biomolecules in a high vacuum enables experiments on fragile species in the absence of a perturbing environment. Since many molecular properties are influenced by local electric fields, here we seek to gain control over the number of charges on a biopolymer by photochemical uncaging. We present the design, modeling, and synthesis of photoactive molecular tags, their labeling to peptides and proteins as well as their photochemical validation in solution and in the gas phase. The tailored tags can be selectively cleaved off at a well-defined time and without the need for any external charge-transferring agents. The energy of a single or two green photons can already trigger the process, and it is soft enough to ensure the integrity of the released biomolecular cargo. We exploit differences in the cleavage pathways in solution and in vacuum and observe a surprising robustness in upscaling the approach from a model system to genuine proteins. The interaction wavelength of 532 nm is compatible with various biomolecular entities, such as oligonucleotides or oligosaccharides.

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Giving the Green Light to Photochemical Uncaging of Large Biomolecules in High Vacuum

Abstract

Austrian Fields of Science 2012

Keywords

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ELUQUINT: Exploring the Limits of Universal Quantum Interferometry

SuperMaMa: Superconducting Mass Spectrometry and Molecule Analysis

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Giving the Green Light to Photochemical Uncaging of Large Biomolecules in High Vacuum

Abstract

Austrian Fields of Science 2012

Keywords

Access to Document

Other files and links

Fingerprint

Projects

ELUQUINT: Exploring the Limits of Universal Quantum Interferometry

SuperMaMa: Superconducting Mass Spectrometry and Molecule Analysis

Cite this