63945-11-9Relevant articles and documents
Visible-Light-Driven Dehydrogenative Coupling of Primary Alcohols with Phenols Forming Aryl Carboxylates
Ishida, Naoki,Kawasaki, Tairin,Murakami, Masahiro,Tosaki, Tomohiro
supporting information, p. 7683 - 7687 (2021/10/12)
A preparative method for obtaining aryl esters from aliphatic primary alcohols and phenols was developed. The reaction proceeds under the irradiation of visible light at ambient temperature, dispensing with any oxidant or hydrogen acceptor. Primary alcohols having a variety of functional groups are successfully esterified with phenols. The produced esters can be utilized as the precursor of various carbonyl compounds.
Live-Cell Protein Modification by Boronate-Assisted Hydroxamic Acid Catalysis
Adamson, Christopher,Kajino, Hidetoshi,Kanai, Motomu,Kawashima, Shigehiro A.,Yamatsugu, Kenzo
supporting information, p. 14976 - 14980 (2021/09/29)
Selective methods for introducing protein post-translational modifications (PTMs) within living cells have proven valuable for interrogating their biological function. In contrast to enzymatic methods, abiotic catalysis should offer access to diverse and new-to-nature PTMs. Herein, we report the boronate-assisted hydroxamic acid (BAHA) catalyst system, which comprises a protein ligand, a hydroxamic acid Lewis base, and a diol moiety. In concert with a boronic acid-bearing acyl donor, our catalyst leverages a local molarity effect to promote acyl transfer to a target lysine residue. Our catalyst system employs micromolar reagent concentrations and affords minimal off-target protein reactivity. Critically, BAHA is resistant to glutathione, a metabolite which has hampered many efforts toward abiotic chemistry within living cells. To showcase this methodology, we installed a variety of acyl groups inE. colidihydrofolate reductase expressed within human cells. Our results further establish the well-known boronic acid-diol complexation as abona fidebio-orthogonal reaction with applications in chemical biology and in-cell catalysis.
Non-imidazole histamine H3 Ligands. Part VII. Synthesis, in vitro and in vivo characterization of 5-substituted-2-thiazol-4-n-propylpiperazines
Guryn, Roman,Staszewski, Marek,Stasiak, Anna,Flores, Daniel McNaught,Fogel, Wies?awa Agnieszka,Leurs, Rob,Walczynski, Krzysztof
, (2018/02/14)
H3 receptors present on histaminergic and non-histaminergic neurons, act as autoreceptors or heteroreceptors controlling neurotransmitter release and synthesis. Previous, studies have found that the compound N-methyl-N-3-phenylalkyl-2-[2-(4-n-propylpiperazin-1-yl)-1,3-thiazol-5-yl]ethan-1 -amine (ADS-531, 2c) exhibits high in vitro potency toward H3 Guinea pig jejunal receptors, with pA2 = 8.27. To optimize the structure of the lead compound ADS-531, a series of 5-substituted-2-thiazol-4-n-propylpiperazines 3 were synthesized and subjected to in vitro pharmacological characterization; the alkyl chain between position 2 of the thiazole ring and the terminal secondary N-methylamino function was elongated from three to four methylene groups and the N-methylamino functionality was substituted by benzyl-, 2-phenylethyl-, and 3-phenyl-propyl- moieties. SAR studies on novel non-imidazole, 5-substituted-2-thiazol-4-n-propyl-piperazines 3 showed that the most active compound 3a (pA2 = 8.38), additionally possessed a weak competitive H1-antagonistic activity. Therefore, compound ADS-531, which did not exhibit any H1-antagonistic activity, was chosen for further evaluation for its affinity to the recombinant rat and human histamine H3 receptors (rH3R and hH3R, respectively). ADS-531 exhibited nanomolar affinity for both rH3R and hH3R receptors. It was also shown that, ADS-531 given subchronically to rats (s.c. 3 mg/kg, 5 days) penetrated the brain, where it affected dopamine, noradrenaline and serotonin concentration; however, it did not affect histamine concentration nor feeding behavior.