Pyruvate formate-lyase (also called formate acetyltransferase; EC 2.3.1.54; PFI .) catalyses the thiolytic cleavage of pyruvate by CoA, yielding acetyl-CoA and formate. This reaction is the key step in the glucose-fermentation route in Escherichziz coli and various other bacteria. Operationally, it resembles the (B-keto)thiolase reaction of the fatty-acid degradation cycle. The mechanism of pyruvate formate-lyase, however, is fundamentally different, since the carbon-carbon bond of its substrate is cleaved homolytically rather than heterolytically. This property emerged with the discovery of a protein-based radical in the active enzyme form [ 11. The unpaired spin has recently been assigned to C-2 of (;lyi" [ 2 ] .The radical is produced by a postribosomal hydrogen-atom abstraction that is catalysed by PFI, activase using adenosylmethionine (AdoMet) and reduced flavodoxin as co-substrates [ 11. A separate reaction that quenches the protein radical in PFI, is catalysed by the multifunctional AdhE protein and is initiated when anaerobic cells are shifted to positive redox potentials [3].Metabolic aspects of PFI, interconversion between inactive (E) and active (Em) forms and the genetic/transcriptional background of the system have already been reviewed 141. This review will focus on enzyme-catalytic structure/function properties.
The development of a synthetic approach to a C3v -symmetric tris-salicylaldehyde based on triptycene is presented. The tris-salicylaldehyde is a versatile precursor for porous molecular materials, as demonstrated in the [4+4] condensation reaction with a triptycene triamine to form a molecular shape-persistent porous cube. The amorphous material of the molecular porous cube shows a very high surface area of 1014 m(2) g(-1) (BET model) and a high uptake of CO2 (18.2 wt % at 273 K and 1 bar). Furthermore, during the multistep synthesis of the tris-salicylaldehyde precursor, a relatively rare (twofold) addition of the aryne to the anthracene in the 1,4- and 1,4,5,8-positions have been found during a Diels-Alder reaction, as proven by X-ray structure analysis.
In recent years, interest in shape‐persistent organic cage compounds has steadily increased, not least because dynamic covalent bond formation enables such structures to be made in high to excellent yields. One often used type of dynamic bond formation is the generation of an imine bond from an aldehyde and an amine. Although the reversibility of the imine bond formation is advantageous for high yields, it is disadvantageous for the chemical stability of the compounds. Amide bonds are, in contrast to imine bonds much more robust. Shape‐persistent amide cages have so far been made by irreversible amide bond formations in multiple steps, very often accompanied by low yields. Here, we present an approach to shape‐persistent amide cages by exploiting a high‐yielding reversible cage formation in the first step, and a Pinnick oxidation as a key step to access the amide cages in just three steps. These chemically robust amide cages can be further transformed by bromination or nitration to allow post‐functionalization in high yields. The impact of the substituents on the gas sorption behavior was also investigated.
Chiral self-sorting is intricately connected to the complicated chiral processes observed in nature and no artificial systems of comparably complexity have been generated by chemists.H owever,o nly af ew examples of purely organic molecules have been reported so far,w here the selfsorting process could be controlled. Herein, we describe the chiral self-sorting of large cubic [8+ +12] salicylimine cage compounds based on ac hiral TBTQ precursor.O ut of 23 possible cage isomers only the enantiopure and am eso cage were observed to be formed, whichhave been unambiguously characterized by single crystal X-raydiffraction. Furthermore, by careful choice of solvent the formation of meso cage could be controlled. With internal diameters of d in = 3.3-3.5 nm these cages are among the largest organic cage compounds characterizedand show very high specific surface areas up to approx. 1500 m 2 g À1 after desolvation.
In recent years the interest of shape-persistent organic cage compounds synthesized by dynamic covalent chemistry (DCC) has risen, because these cages are potentially interesting for gas sorption or -separation. One such reaction in DCC is the condensation of boronic acids with diols to form boronic esters. Most interestingly, the variety of geometries and sizes for boronic ester cages is much lower than that of, for example, imine-based cages. Here, a small series of shape-persistent [4+6] tetrahedral boronic ester cages is introduced. One cage has a high specific surface area of 511 m g and selectively adsorbs ethane over ethylene and acetylene.
Porous shape-persistent organic cages have become the object of interest in recent years because they are soluble and thus processable from solution. A variety of cages can be achieved by applying dynamic covalent chemistry (DCC), but they are less chemically stable. Here the transformation of a salicylimine cage into a quinoline cage by a twelve-fold Povarov reaction as the key step is described. Besides the chemical stability of the cage over a broad pH regime, it shows a unique absorption and emission depending on acid concentration. Furthermore, thin films for the vapor detection of acids were investigated, showing color switches from pale-yellow to red, and characteristic emission profiles.
Anthropogenic greenhouse gases contribute to global warming. Among those gases, perfluorocarbons (PFCs) are thousands to tens of thousands of times more harmful to the environment than comparable amounts of carbon dioxide. To date, materials that selectively adsorb perfluorocarbons in favor of other less harmful gases have not been reported. Here, a series of porous organic cage compounds with alkyl‐, fluoroalkyl‐, and partially fluorinated alkyl groups is presented. Their isomorphic crystalline states allow the study of the structure–property relationship between the degree of fluorination of the alkyl chains and the gas sorption properties for PFCs and their selective uptakes in comparison to other, nonfluorinated gases. By this approach, one compound having superior selectivities of PFCs versus N2 or CO2 under ambient conditions is identified.
Homoconjugation and intramolecular “through-space” charge transfers are molecular phenomena that have been studied since the 1960s. A detailed understanding and control of these effects would provide a tool to tune the optoelectronic properties of organic molecules in respect of the necessities for applications such as for organic electronics. Triptycene is a perfect candidate to investigate homoconjugation effects due to its three-dimensional alignment of three aromatic phenylene units, separated by two methine bridges. Here, a series of 16 π-extended triptycenes with up to three different permuted electron-accepting units and an electron-rich veratrole unit are studied in detail by UV/vis spectroscopy and cyclovoltammetry in combination with DFT calculations to get a deeper understanding of homoconjugation and charge-transfer processes of triptycenes. Furthermore, the gained knowledge can be exploited to construct triptycene-based electron acceptors with fine-tuned adjustment of electronic properties, such as electron affinities, by thorough choice of the aromatic blades that interact through homoconjugation.
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