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The concept of a circular economy relies on waste reduction, valorization, and recycling. Global trends for “green” synthesis of chemicals have positioned the field of enzyme technology and biocatalysis (multi-enzymes and whole-cells) as an alternative for the synthesis of more social- and environmentally-responsible bio-based chemicals. Recent advances in synthetic biology, computational tools, and metabolic engineering have supported the discovery of new enzymes and the rational design of whole-cell biocatalysts. In this book, we highlight these current advances in the field of biocatalysis, with special emphasis on novel enzymes and whole-cell biocatalysts for applications in several industrial biotechnological applications.
Technology: general issues --- 2G ethanol --- hemicellulose usage --- S. cerevisiae --- enzyme immobilization --- cell immobilization --- SHIF --- mannonate dehydratase --- mannose metabolism --- Thermoplasma acidophilum --- mannono-1,4-lactone --- 2-keto-3-deoxygluconate --- aldohexose dehydrogenase --- cyclodextrin glucanotransferases --- large-ring cyclodextrins --- semi rational mutagenesis --- carbohydrate active enzymes --- archaea --- glycosidase --- Sulfolobus solfataricus --- Saccharolobus solfataricus --- Lactobacillus --- β-galactosidase --- immobilization --- cell surface display --- LysM domains --- biocatalysis --- extremophile --- 5-hydroxymethylfurfural --- 5-hydroxymethylfuroic acid --- platform chemicals --- whole cells --- New Delhi metallo-β-lactamase --- NDM-24 --- kinetic profile --- secondary structure --- glycoside hydrolase --- thioglycosides --- Fervidobacterium --- endo-β-1,3-glucanase --- laminarinase --- thermostable --- gene duplication --- cofactor F420 --- deazaflavin --- oxidoreductase --- hydride transfer --- hydrogenation --- asymmetric synthesis --- cofactor biosynthesis --- ω-transaminase --- α-methylbenzylamine --- chiral amine --- biotransformation --- biodiesel --- waste cooking oil --- lipase immobilization --- interfacial activation --- functionalized magnetic nanoparticles --- DNase --- kinetic profiles --- RNase --- semi-rational mutagenesis --- substrate specificity --- engineered Escherichia coli --- flavonoid glucuronides --- multienzyme whole-cell biocatalyst --- organic solvents --- psychrophilic yeast --- hormone-sensitive lipase --- Glaciozyma antarctica --- Antarctica and homology modelling --- keratinase --- serine protease --- metalloprotease --- peptidase --- keratin hydrolysis --- keratin waste --- valorisation --- bioactive peptides --- ene reductase --- enzyme sourcing --- old yellow enzyme --- solvent stability --- machine learning --- flux optimization --- artificial neural network --- synthetic biology --- glycolysis --- metabolic pathways optimization --- cell-free systems --- hydrolase --- lipase --- esterase --- Bacillus subtilis lipase A --- transesterification --- organic solvent --- water activity --- immobilized lipase --- RSM --- fuel properties --- chemo-enzymatic synthesis --- glycosyl transferases --- protein engineering --- carbohydrates --- industrial enzymes --- thermostable enzymes --- glycoside hydrolases --- cell-free biocatalysis --- natural and non-natural multi-enzyme pathways --- bio-based chemicals
Choose an application
The concept of a circular economy relies on waste reduction, valorization, and recycling. Global trends for “green” synthesis of chemicals have positioned the field of enzyme technology and biocatalysis (multi-enzymes and whole-cells) as an alternative for the synthesis of more social- and environmentally-responsible bio-based chemicals. Recent advances in synthetic biology, computational tools, and metabolic engineering have supported the discovery of new enzymes and the rational design of whole-cell biocatalysts. In this book, we highlight these current advances in the field of biocatalysis, with special emphasis on novel enzymes and whole-cell biocatalysts for applications in several industrial biotechnological applications.
2G ethanol --- hemicellulose usage --- S. cerevisiae --- enzyme immobilization --- cell immobilization --- SHIF --- mannonate dehydratase --- mannose metabolism --- Thermoplasma acidophilum --- mannono-1,4-lactone --- 2-keto-3-deoxygluconate --- aldohexose dehydrogenase --- cyclodextrin glucanotransferases --- large-ring cyclodextrins --- semi rational mutagenesis --- carbohydrate active enzymes --- archaea --- glycosidase --- Sulfolobus solfataricus --- Saccharolobus solfataricus --- Lactobacillus --- β-galactosidase --- immobilization --- cell surface display --- LysM domains --- biocatalysis --- extremophile --- 5-hydroxymethylfurfural --- 5-hydroxymethylfuroic acid --- platform chemicals --- whole cells --- New Delhi metallo-β-lactamase --- NDM-24 --- kinetic profile --- secondary structure --- glycoside hydrolase --- thioglycosides --- Fervidobacterium --- endo-β-1,3-glucanase --- laminarinase --- thermostable --- gene duplication --- cofactor F420 --- deazaflavin --- oxidoreductase --- hydride transfer --- hydrogenation --- asymmetric synthesis --- cofactor biosynthesis --- ω-transaminase --- α-methylbenzylamine --- chiral amine --- biotransformation --- biodiesel --- waste cooking oil --- lipase immobilization --- interfacial activation --- functionalized magnetic nanoparticles --- DNase --- kinetic profiles --- RNase --- semi-rational mutagenesis --- substrate specificity --- engineered Escherichia coli --- flavonoid glucuronides --- multienzyme whole-cell biocatalyst --- organic solvents --- psychrophilic yeast --- hormone-sensitive lipase --- Glaciozyma antarctica --- Antarctica and homology modelling --- keratinase --- serine protease --- metalloprotease --- peptidase --- keratin hydrolysis --- keratin waste --- valorisation --- bioactive peptides --- ene reductase --- enzyme sourcing --- old yellow enzyme --- solvent stability --- machine learning --- flux optimization --- artificial neural network --- synthetic biology --- glycolysis --- metabolic pathways optimization --- cell-free systems --- hydrolase --- lipase --- esterase --- Bacillus subtilis lipase A --- transesterification --- organic solvent --- water activity --- immobilized lipase --- RSM --- fuel properties --- chemo-enzymatic synthesis --- glycosyl transferases --- protein engineering --- carbohydrates --- industrial enzymes --- thermostable enzymes --- glycoside hydrolases --- cell-free biocatalysis --- natural and non-natural multi-enzyme pathways --- bio-based chemicals
Choose an application
The concept of a circular economy relies on waste reduction, valorization, and recycling. Global trends for “green” synthesis of chemicals have positioned the field of enzyme technology and biocatalysis (multi-enzymes and whole-cells) as an alternative for the synthesis of more social- and environmentally-responsible bio-based chemicals. Recent advances in synthetic biology, computational tools, and metabolic engineering have supported the discovery of new enzymes and the rational design of whole-cell biocatalysts. In this book, we highlight these current advances in the field of biocatalysis, with special emphasis on novel enzymes and whole-cell biocatalysts for applications in several industrial biotechnological applications.
Technology: general issues --- 2G ethanol --- hemicellulose usage --- S. cerevisiae --- enzyme immobilization --- cell immobilization --- SHIF --- mannonate dehydratase --- mannose metabolism --- Thermoplasma acidophilum --- mannono-1,4-lactone --- 2-keto-3-deoxygluconate --- aldohexose dehydrogenase --- cyclodextrin glucanotransferases --- large-ring cyclodextrins --- semi rational mutagenesis --- carbohydrate active enzymes --- archaea --- glycosidase --- Sulfolobus solfataricus --- Saccharolobus solfataricus --- Lactobacillus --- β-galactosidase --- immobilization --- cell surface display --- LysM domains --- biocatalysis --- extremophile --- 5-hydroxymethylfurfural --- 5-hydroxymethylfuroic acid --- platform chemicals --- whole cells --- New Delhi metallo-β-lactamase --- NDM-24 --- kinetic profile --- secondary structure --- glycoside hydrolase --- thioglycosides --- Fervidobacterium --- endo-β-1,3-glucanase --- laminarinase --- thermostable --- gene duplication --- cofactor F420 --- deazaflavin --- oxidoreductase --- hydride transfer --- hydrogenation --- asymmetric synthesis --- cofactor biosynthesis --- ω-transaminase --- α-methylbenzylamine --- chiral amine --- biotransformation --- biodiesel --- waste cooking oil --- lipase immobilization --- interfacial activation --- functionalized magnetic nanoparticles --- DNase --- kinetic profiles --- RNase --- semi-rational mutagenesis --- substrate specificity --- engineered Escherichia coli --- flavonoid glucuronides --- multienzyme whole-cell biocatalyst --- organic solvents --- psychrophilic yeast --- hormone-sensitive lipase --- Glaciozyma antarctica --- Antarctica and homology modelling --- keratinase --- serine protease --- metalloprotease --- peptidase --- keratin hydrolysis --- keratin waste --- valorisation --- bioactive peptides --- ene reductase --- enzyme sourcing --- old yellow enzyme --- solvent stability --- machine learning --- flux optimization --- artificial neural network --- synthetic biology --- glycolysis --- metabolic pathways optimization --- cell-free systems --- hydrolase --- lipase --- esterase --- Bacillus subtilis lipase A --- transesterification --- organic solvent --- water activity --- immobilized lipase --- RSM --- fuel properties --- chemo-enzymatic synthesis --- glycosyl transferases --- protein engineering --- carbohydrates --- industrial enzymes --- thermostable enzymes --- glycoside hydrolases --- cell-free biocatalysis --- natural and non-natural multi-enzyme pathways --- bio-based chemicals
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