Supramolecular detection of geometrical differences of azobenzene carboxylates

Anion Recognition by a Pincer-Type Host Constructed from Two Polyamide Macrocyclic Frameworks Jointed by a Photo-Addressable Azobenzene Switch

A sterically crowded light-responsive host 1 was synthetized with a 93% yield by applying a post-functionalization protocol utilizing the double amidation of 4,4'-azodibenzoyl dichloride with a readily available 26-membered macrocyclic amine. X-ray structures of two hydrates of trans-1 demonstrate a very different alignment of the azobenzene linkage, which is involved in T-shape or parallel-displaced π⋯π stacking interactions with the pyridine-2,6-dicarboxamide moieties from the macrocyclic backbone. Despite the rigidity of the macrocyclic framework, which generates a large steric hindrance around the azobenzene chromophore, the host 1 retains the ability to undergo a reversible cis⟷trans isomerization upon irradiation with UVA (368 nm) and blue (410 nm) light. Moreover, thermal cis→trans back-isomerization (ΔG0 = 106.5 kJ∙mol-1, t½ = 141 h) is markedly slowed down as compared to the non-macrocyclic analog. 1H NMR titration experiments in DMSO-d6/0.5% water solution reveal that trans-1 exhibits a strong preference for dihydrogenphosphate (H2PO4-) over other anions (Cl-, MeCO2-, and PhCO2-), whereas the photogenerated metastable cis-1 shows lower affinity for the H2PO4- anion.

Photo-responsive host-guest complexation directs dynamic covalent condensation of phenyl boronic acid and d-fructose

Inspired by the way templates have been used to drive dynamic combinatorial libraries by molecular recognition, we exploited the photo-responsive host-guest interaction of an azo-based photoswitch with permethylated cyclodextrin to reversibly manipulate the dynamic covalent interaction of a phenyl boronic acid and d-fructose by irradiation with light.

Visible-Light Responsive Sucrose-Containing Macrocyclic Host for Cations

Chiral photoresponsive host 1 was prepared by a high-yield Cs₂CO₃-templated macrocyclization. Trans-1 transforms into long-lived cis-1 (25 days) upon irradiation with green light, and the backward transformation is triggered by blue light. Both isomers prefer potassium among alkali metal cations, and cis-1 binds cations stronger than trans-1 (K_cis/K_trans ≤ 4.1). ¹H NMR titration experiments as well as density functional theory studies reveal that sucrose ring oxygen residues and azobenzene nitrogen atoms in 1 contribute to cation coordination.

Light-controlled out-of-equilibrium assembly of cyclodextrins in an enzyme-mediated dynamic system

We show that the selective enzymatic synthesis of specific cyclodextrins can be modulated using light. We use enzyme-mediated dynamic combinatorial chemistry to generate a mixture of interconverting linear and cyclic α-1,4-glucans, and employ an azobenzene photoswitch as a template. Using UV or blue light to switch between photostationary states with different azobenzene cis/trans isomeric ratios, we can promote the out-of-equilibrium assembly of either α-cyclodextrin or β-cyclodextrin.

Evidence for Ion-Templation During Macrocyclooligomerization of Depsipeptides

The ion-mediated Mitsunobu macrocyclooligomerization (M-MCO) reaction of hydroxy acid depsipeptides provides small collections of cyclic depsipeptides with good mass recovery. The approach can produce good yields of a single macrocycle or provide rapid access to multiple oligomeric macrocycles in good overall yield. While Lewis acidic alkali metal salts are known to play a role in the outcome of MCO reactions, it is unclear whether their effect is due to an organizational (e.g., templating) mechanism. Isothermal titration calorimetry (ITC) was used to study macrocycle-metal ion binding interactions, and this report correlates these thermodynamic measurements to the (kinetically determined) size distributions of depsipeptides formed during a Mitsunobu-based macrocyclooligomerization (MCO). Key trends have been identified in quantitative metal ion-cyclic depsipeptide binding affinity ( K_a), enthalpy of binding (Δ H), and stoichiometry of complexation across discrete series of macrocycles, and they provide the first analytical platform to rationally select a metal-ion template for a targeted size regime of cyclic oligomeric depsipeptides.

Disulphide bond exchange inhibited by air – kinetic and thermodynamic products in a library of macrocyclic cysteine derivatives

Oxidation of dithiols provides strained monomeric macrocycles which transform upon disulphide bond exchange into stable dimers.

Oligocarboxylates as useful templates in dynamic combinatorial chemistry

Dynamic combinatorial chemistry deals with systems (libraries) of multiple compounds formed by reversible reactions. Interactions of all library components with introduced template molecule are reflected in modification of library composition and are analysed simultaneously. In our studies we investigated a single-substrate dynamic combinatorial library of macrocycles, based on dipicolinic acid diamide, with disulphide bond exchange as the reversible reaction. The library components equipped with hydrogen bond donors interact with anionic guests – carboxylates which act as templates inducing amplification of selected library members. We proved that quantitative analysis of interactions with templates is possible, which led us to a novel method of analysis of association constants of static receptors introduced to the system. With a large set of carboxylates differing in number of anionic groups, size, shape, and flexibility of the linker, we proved that the library is very sensitive to structural parameters of the template. We also showed that with mediation of a photoswitchable azobenzene-based template it is possible to change the library composition by light stimulus. Similarly, with mediation of EDTA the library is sensitive to introduction of metal cations.