This account highlights three significant fields of applications for cucurbiturils (CBs). The first relates to cucurbituril‐based devices and sensors involving spectral effects associated with the formation and dissociation of inclusion complexes. The second refers to the use of CBs as catalysts that control the rate and selectivity of chemical reactions. The third deals with the potential use of CBs for the assembly of mechanical devices and molecular motors. An example of the sensor application is based on the discovery that 4‐aminobipyridine derivatives form strong inclusion complexes with CB6, exhibiting remarkably large enhancements of fluorescence intensity and quantum yields. This reversible binding phenomenon can be used for the design of switchable beacons that can be incorporated into cascades of binding networks for various applications. The second application is exemplified by selective, enhanced photoaddition reactions as well as [3+2]cycloaddition and other reactions mediated by the CB cavity. The third application is based on the idea that low‐barrier molecular rotary motors having rotaxane architecture can be constructed using a cucurbituril host and a polyyne guest serving as stator and rotator, respectively. The “low friction” between these components is supported by molecular mechanics calculations with model systems and experimentally verified by X‐ray crystallography with several synthetic host–guest complexes, all suggesting that the diyne rod floats at the center of the macrocyclic host with no apparent van der Waals contacts between them.
Modulation of the H-bond basicity (pK HB) of various functional groups (FGs) by attaching fluorine functions and its impact on lipophilicity and bioisosterism considerations are described. In general, H/F replacement at the α-position to H-bond acceptors leads to a decrease of the pK HB value, resulting, in many cases, in a dramatic increase in the compounds’ lipophilicity (log P o/w). In the case of α-CF2H, we found that these properties may also be affected by intramolecular H-bonds between CF2H and the FG. A computational study of ketone and sulfone series revealed that α-fluorination can significantly affect overall polarity, charge distribution, and conformational preference. The unique case of α-di- and trifluoromethyl ketones, which exist in octanol/water phases as ketone, hemiketal, and gem-diol forms, in equilibrium, prevents direct log P o/w determination by conventional methods, and therefore, the specific log P o/w values of these species were determined directly, for the first time, using Linclau’s 19F NMR-based method.
Genetic disorders of excessive salt loss from sweat glands have been observed in pseudohypoaldosteronism type I (PHA) and cystic fibrosis that result from mutations in genes encoding epithelial Na+ channel (ENaC) subunits and the transmembrane conductance regulator (CFTR), respectively. We identified a novel autosomal recessive form of isolated salt wasting in sweat, which leads to severe infantile hyponatremic dehydration. Three affected individuals from a small Bedouin clan presented with failure to thrive, hyponatremic dehydration and hyperkalemia with isolated sweat salt wasting. Using positional cloning, we identified the association of a Glu143Lys mutation in carbonic anhydrase 12 (CA12) with the disease. Carbonic anhydrase is a zinc metalloenzyme that catalyzes the reversible hydration of carbon dioxide to form a bicarbonate anion and a proton. Glu143 in CA12 is essential for zinc coordination in this metalloenzyme and lowering of the protein-metal affinity reduces its catalytic activity. This is the first presentation of an isolated loss of salt from sweat gland mimicking PHA, associated with a mutation in the CA12 gene not previously implicated in human disorders. Our data demonstrate the importance of bicarbonate anion and proton production on salt concentration in sweat and its significance for sodium homeostasis.
The very high stability of cucurbiturils under harsh acidic conditions and their reported prolific chemistry over more than three decades pose a question: why has no thiocucurbituril been reported to date? Furthermore, although glycoluril is a highly stable, easily accessible precursor of all cucurbiturils, its sulfur analog represents a yet unmet synthetic challenge. The reaction between glyoxal and thiourea was found to stop at the level of dihydroxyimidazolidine‐2‐thione, which is quite unstable under various acidic conditions. In an attempt to answer these questions, several stable analogs of thioglycoluril, that is, monothioglycoluril, ditolylthioglycoluril, and its diether derivative were prepared and characterized in the hope that they could be employed as building blocks for the synthesis of thiocucurbiturils. Several side products were also obtained that highlight the complex reactivity of thiourea in these reactions. The crystal structures of the above‐mentioned thioglycolurils are dominated by networks of hydrogen‐bonding interactions. Attempts to co‐oligomerize these compounds with formaldehyde clearly suggest that it is impossible to synthesize thiocucurbiturils by the methods commonly used for the preparation of cucurbiturils. Given that thiocucurbiturils are expected to be stable molecules, alternative synthetic strategies that are different from the thermodynamically controlled approaches must be designed.
Penta(tert-butylthio)corannulene and penta(4-dimethylaminophenylthio)corannulene form highly stable monolayers on gold surfaces, as indicated by X-ray photoelectron spectroscopy (XPS). Formation of these homogeneous monolayers involves multivalent coordination of the five sulfur atoms to gold with the peripheral alkyl or aryl substituents pointing away from the surface. No dissociation of C-S bonds upon binding could be observed at room temperature. Yet, the XPS experiments reveal strong chemical bonding between the thioether groups and gold. Temperature-dependent XPS study shows that the thermal stability of the monolayers is higher than the typical stability of self-assembled monolayers (SAMs) of thiolates on gold.
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