We disclose the highly diastereoselective combination of monoamine oxidase‐catalyzed oxidation of meso‐pyrrolidines and aza‐Friedel–Crafts reactions in aqueous buffer to give valuable enantioenriched 2‐substituted pyrrolidines in a formal double C H activation process. A range of secondary as well as tertiary amines were shown to be suitable substrates for the biocatalytic oxidation and subsequent addition of a variety of C‐nucleophiles.
The multistep catalytic process using designer cells, either added as freshly prepared suspensions or as stable lyophilized powder, and click reaction can be performed in one pot. The sequence of four reactions allows the production of both enantiomers of β‐hydroxytriazoles with high enantiomeric excess. 相似文献
A single-transaminase-catalyzed biocatalytic cascade was developed by employing the desired biocatalyst, ATA-117-Rd11, that showed high activity toward 2-oxo-4-[(hydroxy)(methyl)phosphinoyl] butyric acid (PPO) and α-ketoglutarate, and low activity against pyruvate. The cascade successfully promotes a highly asymmetric amination reaction for the synthesis of l -phosphinothricin (l -PPT) with high conversion (>95 %) and>99 % ee. In a scale-up experiment, using 10 kg pre-frozen E. coli cells harboring ATA-117-Rd11 as catalyst, 80 kg PPO was converted to ≈70 kg l -PPT after 24 hours with a high ee value (>99 %). 相似文献
A synthetic method for the construction of fully substituted enantioenriched 1,4‐dihydroquinolines using an organocatalytic aza‐Michael/Michael cascade reaction has been developed. The asymmetric reaction of 2‐(tosylamino)phenyl α,β‐unsaturated ketones with alkynyl aldehydes, promoted by diphenylprolinol O‐TMS ether as an organocatalyst, generated chiral 1,4‐dihydroquinolines in good to high yields with excellent enantioselectivities (up to 97 % ee).
By the design of suitable starting materials, a silver(I)‐catalyzed epoxide ring‐opening/1,2‐acyl migration/cyclization cascade has been developed, which allowed us to systematically prepare unsymmetrical 3‐formylfurans. Various 3‐formylfurans were prepared in good to excellent yields. In addition, the distinct fluorescence properties of 3‐formylfurans in solution and the solid state are disclosed.
An efficient catalytic asymmetric three‐component sulfa‐Michael/aldol cascade reaction has been developed using a chiral multi‐functional catalyst. This reaction provided facile access to γ‐sulfur‐β‐nitro‐α‐hydroxy esters bearing three consecutive linear stereocenters in high yields (up to 97%) with excellent diastereo‐ (up to >97:3 dr) and enantioselectivities (>99% ee). These compounds were readily converted into 2‐nitroallylic alcohols and potentially bioactive γ‐sulfur‐β‐amino‐α‐hydroxy esters, which could be further used for the synthesis of Bestatin derivatives.
An efficient cascade methodology toward chemoselective synthesis of N‐fused heterocycles including 9H‐pyrrolo[1,2‐a]indole, 3H‐pyrrolo[1,2‐a]indole and 1H‐pyrrolo[1,2‐a]indole derivatives has been developed. This transformation proceeds via a silver(I) triflate‐catalyzed consecutive Friedel–Crafts reaction/N C bond formation sequence between readily available propargyl alcohols and 3‐substituted 1H‐indoles. Not only is excellent chemoselectivity observed according to the substitution patterns of propargyl alcohols, but also the Lewis acid‐catalyzed N C bond formation process can be carried out under base‐ and ligand‐free conditions. 相似文献
Biomimetic synthesis routes towards the important natural d ‐mannosyl donor guanosine 5′‐diphospho‐d ‐mannose (GDP‐Man) rely on kinase‐catalyzed nucleotide triphosphate (NTP)‐dependent phosphorylations of d ‐mannose (Man), to give d ‐mannose 6‐phosphate or α‐d ‐mannose 1‐phosphate (αMan 1‐P) as an intermediate product. A GDP‐Man synthesis not requiring the kinase/NTP system would be practical and cost‐effective. Here, we have developed a multienzyme cascade towards GDP‐Man, characterized in that αMan 1‐P was obtained by a diastereoselective phosphatase‐catalyzed phosphorylation of Man. α‐d ‐Glucose 1‐phosphate (αGlc 1‐P), prepared in situ through phosphorylase‐catalyzed conversion of sucrose in the presence of inorganic phosphate, was used as an expedient phosphoryl donor. The incipient αMan 1‐P and guanosine triphosphate (GTP) were converted into GDP‐Man by a highly manno compared to gluco selective nucleotidyltransferase. Pyrophosphatase was additionally required to hydrolyze the pyrophosphate released from the GTP, thus driving the reaction towards GDP‐Man. The enzymatic cascade was operated with the αMan 1‐P and the GDP‐Man formation decoupled from one another (sequential mode) or having all steps run concurrently (simultaneous mode). Detailed time course analysis revealed that kinetic pull due to the constant removal of the intermediate αMan 1‐P in simultaneous‐mode reactions was important to promote phosphorylation of Man from αGlc 1‐P in high efficiency, avoiding loss of sugar 1‐phosphates by hydrolysis. Under optimized conditions for the one‐pot transformation involving four enzymes, 100 mM (67 g L−1) GDP‐Man was prepared from 140 mM sucrose and phosphate, using 400 mM Man as the phosphoryl acceptor. The product was recovered by anion‐exchange and size‐exclusion chromatography in ≥95% purity in about 50% yield (100 mg). These results demonstrate for the first time the practical use of a phosphorylase‐phosphatase combi‐catalyst as an alternative to the canonical kinase for the anomeric phosphorylation of the sugar substrate in nucleoside diphospho‐sugar synthesis. Phosphorylation from inorganic phosphate via the intermediate αGlc 1‐P rather than from NTP, particularly GTP, appears advantageous specifically in cases where the sugar acceptor is a bulk commodity that can be applied in suitable excess to the phosphatase reaction.
The enzymatic reduction of C=C bonds in allylic alcohols with Old Yellow Enzymes represents a challenging task, due to insufficient activation through the hydroxy group. In our work, we coupled an alcohol dehydrogenase with three wild‐type ene reductases—namely nicotinamide‐dependent cyclohex‐2‐en‐1‐one reductase (NCR) from Zymomonas mobilis, OYE1 from Saccharomyces pastorianus and morphinone reductase (MR) from Pseudomonas putida M10—and four rationally designed β/α loop variants of NCR in the bienzymatic cascade hydrogenation of allylic alcohols. Remarkably, the wild type of NCR was not able to catalyse the cascade reaction whereas MR and OYE1 demonstrated high to excellent activities. Through the rational loop grafting of two intrinsic β/α surface loop regions near the entrance of the active site of NCR with the corresponding loops from OYE1 or MR we successfully transferred the cascade reduction activity from one family member to another. Further we observed that loop grafting revealed certain influences on the interaction with the nicotinamide cofactor. 相似文献
A novel one‐pot reaction which combines halogenation, decarboxylation/desulfonamidation with oxidation has been developed. Diverse valuable 3,3‐dihalo‐2‐oxindole compounds can be produced rapidly and safely with isolated yields of up to 98% under mild conditions.
A highly diastereo‐ and enantioselective synthesis of 2,3‐disubstituted tetrahydropyridines was accomplished via a proline‐mediated cascade Mannich‐type/intramolecular cyclization reaction from preformed N‐PMP (p‐methoxyphenyl) aldimines and inexpensive aqueous tetrahydro‐2H‐pyran‐2,6‐diol. 相似文献
A catalytic enantioselective sulfa‐Michael/Horner–Wadsworth–Emmons reaction cascade has been developed, taking advantage of phosphonate as an electrophilic activator and a traceless binding site. Using a chiral bifunctional urea derivative as the catalyst, a variety of aryl and heteroaryl substituted thiochromenes was obtained in excellent yield with a high level of enantioselectivity. 相似文献
Treatment of cyclobutanecarboxamide with bis(trifluoroacetoxy)iodobenzene, PhI(OCOCF3)2, resulted in the formation of 1‐pyrroline via Hofmann rearrangement of the former followed by in situ ring expansion reaction of the cyclobutylamine intermediate. Further elaboration of this methodology to the synthesis of 2,3‐dihydro‐1H‐pyrrolo[2,1‐a]isoquinolinium salts has also been described.
An efficient organocatalytic highly asymmetric cascade aza‐Michael/Michael addition reaction for the synthesis of tetrahydroquinolines and tetrahydrochromanoquinolines has been developed. This cascade reaction proceeds well at low catalyst loading with a broad substrate scope, furnishing the desired products in excellent yields with excellent diastereoselectivities and enantioselectivities (up to >99:1 dr, 99% ee) under mild conditions. Importantly, it is the first catalytic asymmetric method for tetrahydrochromanoquinolines. This protocol provides a straightforward entry to highly functionalized chiral tetrahydroquinoline and tetrahydrochromanoquinoline derivatives from simple starting materials.
Screening for stereoselective cyanohydrin synthesis in 96‐well plates was employed in the development of an efficient, pH‐stable hydroxynitrile lyase for the conversion of sterically hindered aliphatic aldehydes. Site‐saturation mutagenesis (SSM) resulted in a powerful catalyst for the stereoselective conversion of hydroxypivalaldehyde and pivalaldehyde to their corresponding (R)‐cyanohydrins (ee >97%) which are used as chiral building blocks (e.g., for pantothenic acid production). Furthermore, redesigning the PaHNL5 gene and improving its expression by Pichia pastoris with the help of a new PAOX1 promoter variant and the helper protein PDI (protein disulfide isomerase) led to elevated amounts of today’s most efficient biocatalyst for vitamin B5 synthesis. 相似文献
This paper describes the synthesis of quinazolinones via a tandem reaction using the laccase‐mediator system under mild conditions. The procedure involved the laccase‐catalyzed oxidation of alcohols to the corresponding aldehydes, followed by cyclocondensation with isatoic anhydride and a number of amines to afford 2,3‐dihydroquinazolin‐4(1H)‐ones, which were further oxidized to quinazolinones in useful yields. The use of an enzyme as the catalyst, O2 as an environmentally friendly oxidant, and a citrate buffer as the green solvent represents a novel and efficient approach for the one‐pot synthesis of quinazolinones.
Lignin is the most abundant aromatic biopolymer, functioning as an integral component of woody materials. In its unmodified form it shows limited water solubility and is relatively unreactive, so biotechnological lignin valorisation for high‐performance applications is greatly underexploited. Lignin can be obtained from the pulp and paper industry as a by‐product. To expand its application, a new synthesis route to new dispersing agents for use as concrete additives was developed. The route is based on lignin functionalisation by enzymatic transformation. Screening of lignin‐modifying systems resulted in functionalised lignin polymers with improved solubility in aqueous systems. Through grafting of sulfanilic acid or p‐aminobenzoic acid by fungal laccases, lignin became soluble in water at pH≤4 or pH≤7, respectively. Products were analysed and evaluated in miniaturised application tests in cement paste and mortar. Their dispersing properties match the performance criteria of commercially available lignosulfonates. The study provides examples of new perspectives for the use of lignin. 相似文献
Laccase, a blue multicopper oxidase, has recently received considerable attention because of its usefulness in oxidizing phenolic and non‐phenolic compounds, as well as its suitability for organic synthesis, environmental pollutant treatment, and other biotechnological applications. This review covers recent studies on the structural properties, occurrence, reaction mechnisms, redox mediators of laccases and their application in organic synthesis procedures, such as dimerization, polymerization, oxidation, and amination. We also present a brief discussion on laccase activity in non‐aqueous media. Given that the development of green protocols for the synthesis of pure compounds is one of the main goals of sustainable chemistry, the exploitation of laccases is expected to remain one of the most popular directions in future biocatalysis research.
