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MURAMIDASE --- PHYSIOLOGY --- MURAMIDASE --- PHYSIOLOGY
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ADVANCES IN PROTEIN CHEMISTRY VOL 41
Proteins. --- Lysozyme. --- Mucopeptide glucohydrolase --- Muramidase --- Glycosidases --- Proteids --- Biomolecules --- Polypeptides --- Proteomics
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Enzymology --- Medical microbiology, virology, parasitology --- Pathological biochemistry --- Muramidase. --- Lysozyme --- -Mucopeptide glucohydrolase --- Muramidase --- Glycosidases --- Leftose --- N-Acetylmuramide Glycanhydrolase --- Glycanhydrolase, N-Acetylmuramide --- N Acetylmuramide Glycanhydrolase --- Congresses --- -Congresses --- Mucopeptide glucohydrolase
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577.15 --- 57.083.332 --- Lysozyme --- #abib:almm --- Mucopeptide glucohydrolase --- Muramidase --- Glycosidases --- Enzymes. Catalysts of biological reactions. Enzymology --- Lytic reactions. Bacteriolytic reactions --- 57.083.332 Lytic reactions. Bacteriolytic reactions --- 577.15 Enzymes. Catalysts of biological reactions. Enzymology
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Malaria remains an alarming emergency in developing countries. It is thus urgent to identify any parasite or host molecules that can serve as new affordable markers for early diagnosis of disease complications or as new targets for vector control. In this context, human and mosquito lysozymes are good candidate molecules, as their involvement in malaria has been recently reported by several independent groups. This book reviews the grounded knowledge on malaria etiology and physiopathology, as well as the current approaches for diagnosis, therapy, and vector control. In addition, the emerging evidence on the involvement of human and mosquito lysozymes in malaria from available experimental models and clinical studies is thoroughly discussed, as is the potential use of other antimicrobial peptides against malaria. Intriguingly, the contributors propose that old well-known molecules such as lysozymes might be used as new targets for cost-effective strategies to fight malaria. About the Editor Mauro Prato currently works as an Adjunct Professor of Biochemistry at the University of Torino, Italy. His research activity focuses on the involvement of proteolytic enzymes in malaria. His track-record includes 40 papers published by peer-reviewed journals, 1 book, 7 book chapters, 97 communications in well-established conferences, and 1 patent.
Biomedicine. --- Parasitology. --- Medical Microbiology. --- Immunology. --- Medicine. --- Microbiology. --- Medical parasitology. --- Médecine --- Immunologie --- Microbiologie --- Parasitologie médicale --- Biology --- Health & Biological Sciences --- Microbiology & Immunology --- Lysozyme. --- Mucopeptide glucohydrolase --- Muramidase --- Medical microbiology. --- Glycosidases --- Immunobiology --- Life sciences --- Serology --- Microbial biology --- Microorganisms --- Human beings --- Human parasitology --- Medical sciences --- Parasitology --- Parasitic diseases --- Parasites
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Enzyme-mediated catalysis offers special advantages over chemical methods. First of all, enzymes are considered an environmentally friendly tool as they help to avoid the requirements of toxic chemicals and high energy. In addition, more feasible processes can be accomplished through enzymatic reactions owing to the enzyme’s innate properties related to high substrate specificity and selectivity. For this reason, biotechnological production of a wide range of products, such as alternative fuels and value-added biochemicals, has been commercially applicable with the aid of enzymes, either in isolated form or in the whole-cell system. In particular, enzymatic transformation of low-value but cheap/abundant starting materials (i.g. biomass) into high-value materials can facilitate the circular and sustainable bioeconomy. This Special Issue on “Enzyme Catalysis: Advances, Techniques, and Outlooks” consists of six articles, which address diverse industrially relevant enzymes with applications in foods, detergent, cosmetics, medicine, etc. A robust methodology related to enzyme kinetics is also addressed.
Technology: general issues --- History of engineering & technology --- CYP102A1 --- atorvastatin --- 4-hydroxy atorvastatin --- hydrogen peroxide --- P450 peroxygenase --- NADPH --- enzyme inhibition --- integrated Michaelis-Menten equations --- reaction product inhibition --- two mutually exclusive inhibitors --- protease --- detergent --- surfactant --- cleaning --- glucose isomerase --- xylose isomerase --- high-fructose corn syrup --- HFCS --- bioethanol --- structure --- l-fucose isomerase --- l-fucose --- l-fuculose --- extremophile --- halothermophilic bacteria --- Halothermothrix orenii --- lysozyme --- muramidase --- N-acetylmuramide glycanhydrolase --- human --- N-acetyl-β-d-glucosaminidase --- NAG --- crystal structure --- CYP102A1 --- atorvastatin --- 4-hydroxy atorvastatin --- hydrogen peroxide --- P450 peroxygenase --- NADPH --- enzyme inhibition --- integrated Michaelis-Menten equations --- reaction product inhibition --- two mutually exclusive inhibitors --- protease --- detergent --- surfactant --- cleaning --- glucose isomerase --- xylose isomerase --- high-fructose corn syrup --- HFCS --- bioethanol --- structure --- l-fucose isomerase --- l-fucose --- l-fuculose --- extremophile --- halothermophilic bacteria --- Halothermothrix orenii --- lysozyme --- muramidase --- N-acetylmuramide glycanhydrolase --- human --- N-acetyl-β-d-glucosaminidase --- NAG --- crystal structure
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Enzyme-mediated catalysis offers special advantages over chemical methods. First of all, enzymes are considered an environmentally friendly tool as they help to avoid the requirements of toxic chemicals and high energy. In addition, more feasible processes can be accomplished through enzymatic reactions owing to the enzyme’s innate properties related to high substrate specificity and selectivity. For this reason, biotechnological production of a wide range of products, such as alternative fuels and value-added biochemicals, has been commercially applicable with the aid of enzymes, either in isolated form or in the whole-cell system. In particular, enzymatic transformation of low-value but cheap/abundant starting materials (i.g. biomass) into high-value materials can facilitate the circular and sustainable bioeconomy. This Special Issue on “Enzyme Catalysis: Advances, Techniques, and Outlooks” consists of six articles, which address diverse industrially relevant enzymes with applications in foods, detergent, cosmetics, medicine, etc. A robust methodology related to enzyme kinetics is also addressed.
Technology: general issues --- History of engineering & technology --- CYP102A1 --- atorvastatin --- 4-hydroxy atorvastatin --- hydrogen peroxide --- P450 peroxygenase --- NADPH --- enzyme inhibition --- integrated Michaelis–Menten equations --- reaction product inhibition --- two mutually exclusive inhibitors --- protease --- detergent --- surfactant --- cleaning --- glucose isomerase --- xylose isomerase --- high-fructose corn syrup --- HFCS --- bioethanol --- structure --- l-fucose isomerase --- l-fucose --- l-fuculose --- extremophile --- halothermophilic bacteria --- Halothermothrix orenii --- lysozyme --- muramidase --- N-acetylmuramide glycanhydrolase --- human --- N-acetyl-β-d-glucosaminidase --- NAG --- crystal structure --- n/a --- integrated Michaelis-Menten equations
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Enzyme-mediated catalysis offers special advantages over chemical methods. First of all, enzymes are considered an environmentally friendly tool as they help to avoid the requirements of toxic chemicals and high energy. In addition, more feasible processes can be accomplished through enzymatic reactions owing to the enzyme’s innate properties related to high substrate specificity and selectivity. For this reason, biotechnological production of a wide range of products, such as alternative fuels and value-added biochemicals, has been commercially applicable with the aid of enzymes, either in isolated form or in the whole-cell system. In particular, enzymatic transformation of low-value but cheap/abundant starting materials (i.g. biomass) into high-value materials can facilitate the circular and sustainable bioeconomy. This Special Issue on “Enzyme Catalysis: Advances, Techniques, and Outlooks” consists of six articles, which address diverse industrially relevant enzymes with applications in foods, detergent, cosmetics, medicine, etc. A robust methodology related to enzyme kinetics is also addressed.
CYP102A1 --- atorvastatin --- 4-hydroxy atorvastatin --- hydrogen peroxide --- P450 peroxygenase --- NADPH --- enzyme inhibition --- integrated Michaelis–Menten equations --- reaction product inhibition --- two mutually exclusive inhibitors --- protease --- detergent --- surfactant --- cleaning --- glucose isomerase --- xylose isomerase --- high-fructose corn syrup --- HFCS --- bioethanol --- structure --- l-fucose isomerase --- l-fucose --- l-fuculose --- extremophile --- halothermophilic bacteria --- Halothermothrix orenii --- lysozyme --- muramidase --- N-acetylmuramide glycanhydrolase --- human --- N-acetyl-β-d-glucosaminidase --- NAG --- crystal structure --- n/a --- integrated Michaelis-Menten equations
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