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Biocatalysis, the application of enzymes as catalysts for chemical synthesis, has become an increasingly valuable tool for the synthetic chemist. Enzymatic transformations carried out by enzymes or whole-cell catalysts are used for the production of a wide variety of compounds ranging from bulk to fine chemicals. The primary consideration for the incorporation of biotransformation in a synthetic sequence is regio- and stereocontrol that can be achieved with enzyme-catalyzed reactions. Biotransformations are thus becoming accepted as a method for generating optically pure compounds as well as for developing efficient routes to target compounds. This Special Issue aims to address the main applications of biocatalysts, isolated enzymes, and whole microorganisms in the synthesis of bioactive compounds and their precursors.

Research & information: general --- Biology, life sciences --- 8-hydroxydaidzein --- stable --- soluble --- anti-inflammation --- amylosucrase --- Deinococcus geothermalis --- coumarin --- biotransformation --- filamentous fungi --- selective hydroxylation --- bromination --- chlorination --- pharmaceuticals --- active agent synthesis --- biocatalysis --- haloperoxidase --- halogenase --- glycosyltransferase --- Glycine max (L.) Merr. --- HPLC/MS --- isoflavone aglycone-rich extract --- isoflavone α-glucoside --- alkene cleavage --- aryl alkenes --- basidiomycota --- carotene degradation --- dye-decolorizing peroxidase (DyP) --- manganese --- Komagataella pfaffii --- Pleurotus sapidus --- monoterpenes --- limonene --- glycerol --- mevalonate pathway --- reaction engineering --- bioprocess --- biocatalyst --- two-liquid phase fermentation --- in situ product removal --- lipase --- unsaturated fatty acid --- oxidative cleavage --- oxidation --- adaptation --- UV/NTG mutagenesis --- psychrotrophs --- terpenes

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• Reference Manager
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Biocatalysis, the application of enzymes as catalysts for chemical synthesis, has become an increasingly valuable tool for the synthetic chemist. Enzymatic transformations carried out by enzymes or whole-cell catalysts are used for the production of a wide variety of compounds ranging from bulk to fine chemicals. The primary consideration for the incorporation of biotransformation in a synthetic sequence is regio- and stereocontrol that can be achieved with enzyme-catalyzed reactions. Biotransformations are thus becoming accepted as a method for generating optically pure compounds as well as for developing efficient routes to target compounds. This Special Issue aims to address the main applications of biocatalysts, isolated enzymes, and whole microorganisms in the synthesis of bioactive compounds and their precursors.

Research & information: general --- Biology, life sciences --- 8-hydroxydaidzein --- stable --- soluble --- anti-inflammation --- amylosucrase --- Deinococcus geothermalis --- coumarin --- biotransformation --- filamentous fungi --- selective hydroxylation --- bromination --- chlorination --- pharmaceuticals --- active agent synthesis --- biocatalysis --- haloperoxidase --- halogenase --- glycosyltransferase --- Glycine max (L.) Merr. --- HPLC/MS --- isoflavone aglycone-rich extract --- isoflavone α-glucoside --- alkene cleavage --- aryl alkenes --- basidiomycota --- carotene degradation --- dye-decolorizing peroxidase (DyP) --- manganese --- Komagataella pfaffii --- Pleurotus sapidus --- monoterpenes --- limonene --- glycerol --- mevalonate pathway --- reaction engineering --- bioprocess --- biocatalyst --- two-liquid phase fermentation --- in situ product removal --- lipase --- unsaturated fatty acid --- oxidative cleavage --- oxidation --- adaptation --- UV/NTG mutagenesis --- psychrotrophs --- terpenes

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A total of 16 original research articles. Contributions from 10 countries from 3 continents. Organic synthesis towards novel heterocyclic compounds. Fully characterized inorganic and organic molecules including X-ray crystallographic analysis. Cyclization reactions, reactivity of aromatic compounds and improved synthetic methodologies of important intermediate compounds.

Research & information: general --- heterocycle --- piperazine --- pyrimidine --- DABCO --- nucleophilic displacement --- chlorination --- [1,3]-H shift --- aza-Michael addition --- DFT calculations --- dimethyl acetylenedicarboxylate --- isoxazolo[3,4-b]quinolin-3(1H)-one --- pyrazolines --- curcuminoids --- nitrogen heterocycles --- cytotoxic --- DNA binding --- MDR reversal --- oxygen-nitrogen heterocycles --- 11a,12-dihydrobenzo[b]benzo[5,6][1,4]oxazino[2,3-e][1,4]oxazine --- disulfur dichloride --- o-aminophenol --- condensation --- 4-anilino-quin(az)olines --- hinge binder --- conformational flexibility --- kinase inhibitor design --- imine --- Schiff base --- X-ray crystallographic analysis --- Cu(II) complex --- gamma-amino acid --- ruthenium --- carbonyl complex --- azopyridine --- anion radical --- electronic structure --- magnetic properties --- chalcogenophene --- heterocycles --- ligands --- pyridine derivatives --- thiophene derivatives --- aminocyclopentitol --- bicyclic aziridine --- water chemistry --- nucleophilic substitution --- homopiperazine --- X-ray structure --- C-C bond length --- 15N-NMR --- catechol --- alkyne --- thiol-alkyne click reaction --- domino reactions --- bromination --- intramolecular SN displacement --- carbocyclic hydantoins --- N-1 substituted hydantoin --- spiro hydantoins --- imidazolidine-2,4-diones --- stereochemistry --- NMR --- HRMS --- GIAO --- ring closing --- Au-nanoparticles --- NaBH4 --- amino-substituted fused oxazolocoumarin --- fused oxazolocoumarins --- chemoselective reduction --- o-hydroxynitrocoumarins --- benzimidazole --- nucleophilic aromatic substitution --- thiosemicarbazone