¹⁹F NMR as a tool in chemical biology

• Diana Gimenez,
• Aoife Phelan,
• Cormac D. Murphy and
• Steven L. Cobb

Beilstein J. Org. Chem. 2021, 17, 293–318, doi:10.3762/bjoc.17.28

• biosynthesis and biodegradation of fluorinated organic compounds is also described. Keywords: biotransformation; chemical biology; fluorine; 19F NMR; probes; protein structure; Introduction Although fluorine is abundant in the environment, it is not a nutrient nor is it a feature of biochemistry for most

• that can be used as 19F NMR reporters. Aromatic amino acids have been preferentially used as 19F NMR probes both in binding and in conformational studies owing to their ready availability. However, more recently fluoro-aliphatic, and in particular perfluoro-aliphatic amino acids, have become

• tyrosine [16] (pFtBTyr, 9) and proline [17] (4R and 4S-pFtBHyp, 10 and 11, Figure 1) have also been utilised as 19F NMR probes, both showing promise as valuable tools for biomolecular studies. Particularly impressive is that by incorporating pFtBTyr (9) into a model peptide, Tressler and Zondlo were able

The use of 4,4,4-trifluorothreonine to stabilize extended peptide structures and mimic β-strands

• Yaochun Xu,
• Isabelle Correia,
• Tap Ha-Duong,
• Nadjib Kihal,
• Jean-Louis Soulier,
• Julia Kaffy,
• Benoît Crousse,
• Olivier Lequin and
• Sandrine Ongeri

Beilstein J. Org. Chem. 2017, 13, 2842–2853, doi:10.3762/bjoc.13.276

• activity [3][4]. Fluorinated amino acids can also be used as powerful 19F NMR probes for the study of protein–ligand interactions and enzymatic activities [5][6][7][8]. However, the development of fluorinated peptides as drug candidates seems to be largely under-exploited. Investigation on the influence of

NMR reaction monitoring in flow synthesis

• M. Victoria Gomez and
• Antonio de la Hoz

Beilstein J. Org. Chem. 2017, 13, 285–300, doi:10.3762/bjoc.13.31

• 10.3762/bjoc.13.31 Abstract Recent advances in the use of flow chemistry with in-line and on-line analysis by NMR are presented. The use of macro- and microreactors, coupled with standard and custom made NMR probes involving microcoils, incorporated into high resolution and benchtop NMR instruments is

• optimization is discussed. Keywords: expert systems; flow chemistry; microcoil; NMR probes; Introduction New enabling technologies have facilitated the transition from traditional chemistry to a more automated approach that will be the chemistry of the 21st century [1][2]. The objective is that the reaction

• geometry of the coil should be optimized in order to obtain the highest possible sensitivity and resolution. The most widely used geometries for NMR coils are represented in Figure 2. The most typical geometry used in commercial solution NMR probes is the saddle type. Although this geometry generates a

A one-pot synthesis of 3-trifluoromethyl-2-isoxazolines from trifluoromethyl aldoxime

• Raoni S. B. Gonçalves,
• Michael Dos Santos,
• Guillaume Bernadat,
• Danièle Bonnet-Delpon and
• Benoit Crousse

Beilstein J. Org. Chem. 2013, 9, 2387–2394, doi:10.3762/bjoc.9.275

• inhibitors [17][18][19][20][21]. Another powerful area, yet a somewhat less utilised role for fluorine is as a tag for 19F NMR that offers several analytical advantages including speed, sensitivity and selectivity [22][23]. Fluorinated molecules have served as valuable 19F NMR probes in high-throughput

Synthesis of fluorinated maltose derivatives for monitoring protein interaction by ¹⁹F NMR

• Michaela Braitsch,
• Hanspeter Kählig,
• Georg Kontaxis,
• Michael Fischer,
• Toshinari Kawada,
• Robert Konrat and
• Walther Schmid

Beilstein J. Org. Chem. 2012, 8, 448–455, doi:10.3762/bjoc.8.51

• of protein binding improves with decreasing ligand concentration, and thus even smaller protein and ligand concentrations can be used in the experiment [45]. Full exploitation of this effect, however, requires high performance 19F NMR probes (e.g., cryoprobes). Relative affinity studies using the 2-F