Search Results (868)

The influence of steric hindrance caused by the dienophiles on the stereoselectivity of cycloadditions of 2H-pyran-2-ones with maleimides was investigated in this study. It was found that sufficiently bulky N-substituents on the maleimides (such as N-triphenylmethyl) can cause the cycloaddition to proceed differently than expected, thus yielding asymmetric exo,endo-bicyclo[2.2.2]octenes instead of the commonly obtained symmetric exo,exo products. Furthermore, the incorporation of an N-triphenylmethyl group, which induces highly diastereoselective formation of asymmetric exo,endo adducts and can later be easily removed under acidic conditions, can be described as an example of an efficient exo,endo-diastereoselective auxiliary. Full article

Imine reductases (IREDs) have emerged as valuable biocatalysts for the asymmetric synthesis of chiral amines, key intermediates in numerous active pharmaceutical ingredients. Their ability to operate under mild reaction conditions with high chemo- and stereoselectivity provides an attractive alternative to conventional metal-catalyzed or chemical reduction processes. However, the broader industrial application of wild-type IREDs is often constrained by their limited substrate scope and moderate catalytic efficiency. Recent advances in biocatalysis have demonstrated that engineered IREDs can catalyze the reduction of a wide range of natural and non-natural imines, significantly expanding their applicability in pharmaceutical and fine chemical synthesis. In parallel, enzyme immobilization strategies have proven highly effective for improving operational stability, facilitating enzyme reuse, and enabling continuous flow biocatalytic processes. Efficient cofactor regeneration systems have further enhanced the practical implementation of IRED-based transformations. Advances in protein engineering, including structure-guided design, semi-rational mutagenesis, and directed evolution, have generated enzyme variants with improved catalytic activity, stereoselectivity, and substrate tolerance. The integration of high-throughput screening technologies and machine-learning-assisted enzyme design has further accelerated the discovery and optimization of efficient IRED biocatalysts. This review summarizes recent progress in the protein engineering and immobilization of IREDs and discusses future perspectives for their industrial application. Full article

Alkenylidenecyclopropanes (ACPs) have emerged as versatile and highly reactive building blocks in transition-metal-catalyzed transformations. Their strained cyclopropane framework, combined with an exocyclic alkene, enables diverse bond-activation pathways and promotes efficient cycloaddition reactions. In recent years, ACPs have been widely developed as three-carbon synthons in a variety of higher-order cycloadditions. This review provides a systematic overview of transition-metal-catalyzed ACP transformations, focusing on their applications in [3+2], [3+2+2], [3+2+1], [4+3], and [4+3+2] cycloaddition reactions with reaction partners such as alkenes, alkynes, carbonyl compounds, imines, dienes, and carbon monoxide. Particular attention is given to mechanistic aspects, including cyclopropane ring-opening processes and the formation of key metal–carbene and π-allyl intermediates that govern reactivity and selectivity. Factors influencing regioselectivity, stereoselectivity, and catalyst design are also discussed. The synthetic potential of ACP chemistry is illustrated through representative applications in the total synthesis of complex natural products, such as pyrovellerolactone and (+)-zizaene. Overall, this review highlights recent advances in ACP-based cycloaddition strategies and emphasizes their growing significance in modern synthetic chemistry. Full article

Aldolases are powerful biocatalysts for the stereoselective formation of carbon–carbon bonds and are widely used in the synthesis of chiral intermediates for pharmaceutical applications. Among them, 2-deoxyribose-5-phosphate aldolase (DERA) has been extensively exploited for the preparation of the conserved side chain of statins. In this work, we report a novel chemoenzymatic approach for the synthesis of nucleobase-substituted lactol products as potential precursors of new statin analogues. A C49M variant of DERA from Pectobacterium atrosepticum (PaDERA C49M) was employed to catalyze sequential aldol additions using aldehyde-functionalized nucleobases as non-natural electrophilic substrates. The formation of nucleobase-containing lactols was confirmed, demonstrating for the first time the acceptance of nucleobase-derived aldehydes in DERA-catalyzed aldol reactions. This strategy provides access to structurally novel statin side-chain precursors and expands the synthetic potential of DERA toward the generation of new classes of bioactive compounds. Full article

Guanidines are structurally unique, highly basic, nitrogen-containing organic compounds with strong hydrogen-bonding ability and biological activity, providing valuable functionality in medicinal chemistry, organocatalysis, and materials science. Among modern strategies for assembling guanidine-containing molecules, cycloaddition reactions have emerged as powerful tools due to their efficiency, stereoselectivity, and ability to rapidly build molecular complexity. Recent innovations have expanded cycloaddition methodologies for generating guanidine functionalities, incorporating guanidine-containing substrates, and using guanidine-based catalysts. This review summarizes these advances and highlights the current trends in guanidine-related cycloaddition chemistry. Full article

Enzymatic cascades, defined here as multi-enzymatic sequences operating on a shared reaction pathway and inspired by the spatial and temporal organization of metabolism, have emerged as powerful and versatile tools for sustainable organic synthesis. They minimize intermediate isolation, enhance atom economy and ensure outstanding chemo-, regio- and stereoselectivity, providing efficient alternatives to conventional multistep routes. Here, we highlight the conceptual role of substrate channeling, minimal cells, artificial metabolism and enzyme promiscuity in the translation of enzymatic cascades into synthetic strategies. Special attention is focused on advanced immobilization on functional and renewable supports, which enhance stability and recyclability and introduce new ways for thermodynamic and kinetic control. Hybrid systems integrating enzymes with photocatalysis, electrochemistry and chemical modules expand the catalytic repertoire far beyond biology. Complementary tools in bioinformatics, structural modeling and artificial intelligence may also enable pathway balancing, predictive design and dynamic optimization. Applications span from the valorization of renewable feedstocks to the synthesis of privileged scaffolds and fine chemicals. Full article

This study investigates the influence of reaction conditions on the stereoselective Wittig synthesis of a thienostilbene analogue of trans-resveratrol. Reaction conditions were systematically varied across batch experiments and analysed using Spearman correlation, principal component analysis (PCA), and response surface methodology (RSM) to identify key factors (base type and amount, solvent type and volume, system configuration, and reaction time) affecting conversion and the trans/cis ratio. The base type, solvent type, and system configuration had the strongest impact on stereoselectivity, while solvent volume proved effective in enhancing the trans-isomer. PCA revealed that cyclic ether solvents combined with medium-strong bases provide the best balance between conversion and selectivity. RSM predicted optimal conditions in a two-phase NaOH system via phase transfer catalysis (PTC) with increased organic solvent volume, which experimentally increased conversion from 35% to over 92% and raised the trans/cis ratio to 1.81. Transferring the optimized process to continuous flow dramatically reduced reaction time, achieving 67.5% conversion in 15 min while maintaining stereoselectivity. These results demonstrate how statistical optimization combined with flow processing can significantly accelerate the development of stereoselective Wittig reactions. Full article

New aminonitrocyclitols were directly synthesized through stereoselective, one-pot, multistep cascade reactions. The aminonitrocyclitol moiety was constructed by the sequential action of two enzymes followed by a spontaneous intramolecular Henry reaction. To construct the carbocycle, two C–C bonds were stereoselectively cleaved, one by aldolase and the other by the intramolecular nitroaldol reaction. The aldolase acceptor substrates were generated by adding an amino group to 4-nitrobutanal. As expected, only the (R,R)- or d-erythroaldol configuration was obtained with l-fuculose-1-phosphate aldolase (F1PA). In the case of l-rhamnulose-1-phosphate aldolase (R1PA), both the aldol (R,S)- or l-threo and erythroaldol (R,R)- or d-erythroaldol configurations were obtained in very close ratios. The presence of a ketone and a terminal nitro group in the aldol formed led to a stereoselective intramolecular Henry reaction. The various aminonitrocyclitols were obtained in amide form with an average overall yield of 60%. Deprotection of the amine function was achieved by hydrolysis of the amide group by the action of papain without epimerization at the ring carbon stereochemistries defined in the previous steps. All these reactions led to the preparation of new aminonitrocyclitols with high stereoselectivity. Full article

The concept of “Smart Secondary Metabolites” is introduced here to describe a privileged class of natural products defined by structural originality, biosynthetic adaptability, and broad interaction potential with biological systems. Elatol, a halogenated sesquiterpene chiefly produced by Laurencia red seaweeds and occasionally accumulated by their consumers, exemplifies this concept with remarkable clarity. Its biosynthesis unfolds from farnesyl diphosphate via γ-bisabolane cations, bromochlorination, and stereoselective cyclization to chamigrene scaffolds, generating both (+)- and (–)-enantiomers, two metabolites with clearly distinct potential ecological roles and pharmacological profiles. This review synthesizes the current state of knowledge on elatol’s distribution, biosynthetic origins, ecological relevance, and therapeutic potential. Elatol serves as a multifunctional chemical mediator, fulfilling defensive, communicative, and regulatory roles whose intensity shifts in response to herbivory, biofouling, temperature, and salinity. In parallel, its potent activities against infectious, metabolic, and neoplastic diseases highlight its growing value as a drug lead, reflected in a rising number of patent claims. Altogether, elatol emerges as a model Smart Secondary Metabolite whose ecological sophistication and biochemical versatility position it as a promising scaffold for marine-derived drug discovery. Full article

Apart from in hydrosilylation, platinum has traditionally played a limited role in homogeneous catalysis due to its high thermodynamic stability and lower intrinsic reactivity compared to other group 10 metals. However, the emergence of N-heterocyclic carbene (NHC) ligands has substantially broadened the catalytic profile of transition metals by enabling access to new mechanistic pathways and enhancing robustness under demanding conditions. This review summarizes advances in Pt–NHC catalysis reported between 2010 and 2025. These transformations encompass hydrosilylation of amides and CO₂, hydroboration and diboration, hydroamination, alkyne hydration, hydrogenation, selective alkyne dimerization, Suzuki–Miyaura coupling, arene C–H borylation, and cycloisomerization reactions, in which NHC ligands enhance bond activation, control regio- and stereoselectivity, and stabilize reactive Pt intermediates, including chiral architectures, enabling high enantioselectivity. Full article

A concise and efficient synthesis of the aggregation pheromone of Cryptolestes ferrugineus, Ferrulactone II, and its enantiomer has been developed. The synthetic route features CBS reduction, the zipper reaction, a copper(I)-catalyzed coupling, stereoselective partial hydrogenation, Yamaguchi esterification, and the Mitsunobu inversion reaction. The structures and absolute configurations of both enantiomers of the target pheromone were confirmed by NMR, HRMS, specific rotation, and ECD spectroscopy. This study provides a reliable supply of material for further biological evaluation. Full article

This study established an HPLC-MS/MS method to quantify the enantiomers of spirotetramat in tubifex. To assess the accuracy and precision of the approach, recovery tests were conducted for insecticide. For all enantiomers, the limits of detection were 0.003 mg/kg. The quantization limits were 0.01 mg/kg. Spirotetramat enantiomers recovery rates in tubifex were found to be between 81 and 114%, with relative standard deviations being less than 7%. The half-lives of spirotetramat enantiomers in tubifex were 3.81–10.58 d, respectively. The 22.4% spirotetramat suspension was sprayed on tubifex three times at a low dosage (high dosage advised). After 14 days after harvesting, the terminal residues of spirotetramat enantiomers in the tubifex were less than 0.03 mg/kg. The findings offer a quantitative foundation for setting China’s maximum residue limits as well as a recommendation for the safe and responsible usage of spirotetramat enantiomers in tubifex. Full article

A computational study of the mechanism of asymmetric hydrogenation of γ-keto acids with the Ni(S,S)-QuinoxP* system was conducted. The main steps of the reaction mechanism were determined, including the formation of the NiH(S,S-QuinoxP*)⁺ complex starting from a γ-keto acid molecule and the involvement of the hydrogen “metathesis” step. The rate-limiting and stereo-determining step of the reaction was identified as the transfer of a hydrogen atom from the catalytic particle to the carbonyl group of the substrate molecule. The stereochemical outcome of the process was calculated. The influence of weak interactions on the stereoselectivity of the process was demonstrated using NCI and sobEDAw analyses. Full article

Density functional theory (DFT) calculations elucidate the mechanism of diastereoselective cyclization of 2-picoline with 1,5-hexadiene catalyzed by a cationic half-sandwich scandium complex. The catalytic cycle proceeds through four key stages: formation of active species, initial alkene insertion, cis-selective cyclization, and protonation. Central to the mechanism is the dual role of 2-picoline, which initially coordinates as a supporting ligand to facilitate C–H activation and regioselective 1,2-insertion but must dissociate to enable stereocontrol. The mono(2-picoline)-coordinated complex C3 is identified as the thermodynamically favored active species. C–H activation reactivity follows the trend: ortho-C(sp²)–H (2-picoline-free) > ortho-C(sp²)–H (2-picoline-coordinated) > benzylic C(sp³)–H (2-picoline-free) > benzylic C(sp³)–H (2-picoline-coordinated), a preference governed by a wider C_α–Sc–C_α′ angle and shorter Sc···X (X = C_α, C_α′, H) distances that enhance scandium–substrate interaction. Subsequent 1,5-hexadiene insertion proceeds with high 1,2-regioselectivity through a picoline-assisted pathway. The stereoselectivity-determining step reveals a mechanistic dichotomy: while picoline coordination is essential for initial activation, its dissociation is required for intramolecular cyclization. This ligand displacement avoids prohibitive steric repulsion in the transition state, directing the reaction exclusively toward the cis-cyclized product. The cycle concludes with a sterically accessible mono-coordinated protonation. This work establishes a “ligand-enabled then ligand-displaced” mechanism, highlighting dynamic substrate coordination as a critical design principle for achieving high selectivity in rare-earth-catalyzed C–H functionalization. Full article