Enzyme active sites and their reaction mechanisms /
"Enzyme Active Sites and their Reaction Mechanisms provides a one-stop reference on how enzymes'work.'Here, Dr. Harry Morrison, PhD and Professor Emeritus at Purdue University, provides a detailed overview of the origin and function of forty enzymes, the chemical details of their acti...
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| Format: | eBook |
| Language: | English |
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Amsterdam :
Academic Press,
2021.
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| Subjects: | |
| Online Access: | Connect to the full text of this electronic book |
Table of Contents:
- Front Cover
- Enzyme Active Sites and Their Reaction Mechanisms
- Copyright Page
- Dedication
- Contents
- Preface
- Acknowledgments
- 1 Acetylcholinesterase
- 1.1 Acetylcholinesterase
- 1.2 Physiological function
- 1.3 Key structural features
- 1.4 Reaction sequence
- 1.5 Mechanism and the role of active site residues
- Leading references
- 2 Aconitase
- 2.1 Aconitase
- 2.2 Physiological function
- 2.3 Key structural features
- 2.4 Reaction sequence
- 2.5 Detailed mechanism and the role of the active site residues
- Leading references
- 3 Adenosine deaminase
- 3.1 Adenosine deaminase (adenosine aminohydrolase)
- 3.2 Physiological function
- 3.3 Key structural features
- 3.4 Reaction sequence
- 3.5 Detailed mechanism and the role of active site residues
- Leading references
- 4 Alcohol dehydrogenase (horse liver)
- 4.1 Horse liver alcohol dehydrogenase
- 4.2 Physiological function
- 4.3 Key structural features
- 4.4 Reaction sequence
- 4.5 Detailed mechanism and the role of the active site residues
- Leading references
- 5 Aldehyde dehydrogenase
- 5.1 Aldehyde dehydrogenase
- 5.2 Physiological function
- 5.3 Key structural features
- 5.4 Reaction sequence
- 5.5 Detailed mechanism and the role of active site residues
- Leading references
- 6 Arginase I
- 6.1 Arginase
- 6.2 Physiological function
- 6.3 Key structural features
- 6.4 Reaction sequence
- 6.5 Detailed mechanism and the role of the active site residues
- Leading references
- 7 Carbonic anhydrase II
- 7.1 Human carbonic anhydrase II
- 7.2 Physiological function
- 7.3 Key structural features
- 7.4 Reaction sequence
- 7.5 Detailed mechanism and the role of active site residues
- Leading references
- 8 Carboxypeptidase A
- 8.1 Carboxypeptidase A
- 8.2 Physiological function
- 8.3 Key structural features
- 8.4 Reaction sequence.
- 16.1 Farnesyl pyrophosphate synthase
- 16.2 Physiological function
- 16.3 Key structural features
- 16.4 Reaction sequence
- 16.5 Detailed mechanism and the role of active site residues
- Leading references
- 17 Fructose-1,6-bisphosphate aldolase
- 17.1 Fructose-1,6-bisphosphate aldolase
- 17.2 Physiological function
- 17.3 Key structural features
- 17.4 Reaction sequence
- 17.5 Detailed mechanism and the role of the active site residues
- Leading references
- 18 Hepatitis C NS2/3 protease
- 18.1 Hepatitis C NS2/3 protease
- 18.2 Physiological function
- 18.3 Key structural features
- 18.4 Reaction sequence
- 18.5 Detailed mechanism and the role of the active site residues
- Leading references
- 19 HIV-1 protease
- 19.1 HIV-1 protease
- 19.2 Physiological function
- 19.3 Key structural features
- 19.4 Reaction sequence
- 19.5 Detailed mechanism and the role of the active site residues
- Leading references
- 20 Indoleamine 2,3-dioxygenase-1
- 20.1 Indoleamine 2,3-dioxygenase-1
- 20.2 Physiological function
- 20.3 Key structural features
- 20.4 Reaction sequence
- 20.5 Detailed mechanism and the role of active-site residues
- Leading references
- 21 Lysine 2,3-aminomutase
- 21.1 Lysine 2,3-aminomutase
- 21.2 Physiological function
- 21.3 Key structural features
- 21.4 Reaction sequence
- 21.5 Detailed mechanism and the role of active site residues
- Leading references
- 22 Lysozyme
- 22.1 Lysozyme
- 22.2 Physiological function
- 22.3 Key structural features
- 22.4 Reaction sequence
- 22.5 Detailed mechanism and the role of the active site residues
- Leading references
- 23 Methyl-coenzyme M reductase
- 23.1 Methyl-coenzyme M reductase
- 23.2 Physiological function
- 23.3 Key structural features
- 23.4 Reaction sequence
- 23.5 Detailed mechanism and role of active site residues
- Leading references.
- 31.3 Key structural features
- 31.4 Reaction sequence
- 31.5 Detailed mechanism and role of the active site residues
- Leading references
- 32 Ribonuclease A
- 32.1 Bovine pancreatic ribonuclease A
- 32.2 Physiological function
- 32.3 Key structural features
- 32.4 Reaction sequence
- 32.5 Detailed mechanism including the role of His12 and His119 at the active site
- Leading references
- 33 Ribonucleotide reductase
- 33.1 Ribonucleotide reductase
- 33.2 Physiological function
- 33.3 Key structural features
- 33.4 Reaction sequence
- 33.5 Detailed mechanisms and the role of the active site residues
- Leading references
- 34 Serine racemase
- 34.1 Serine racemase
- 34.2 Physiological function
- 34.3 Key structural features
- 34.4 Reaction sequence
- 34.5 Detailed mechanism and the role of active site residues
- Leading references
- 35 Soluble quinoprotein glucose dehydrogenase
- 35.1 Soluble quinoprotein glucose dehydrogenase
- 35.2 Physiological function
- 35.3 Key structural features
- 35.4 Reaction sequence
- 35.5 Detailed mechanism and the role of active-site residues
- Leading references
- 36 Tetrachloroethene reductive dehalogenase-PceA
- 36.1 PceA
- 36.2 Physiological function
- 36.3 Key structural features
- 36.4 Reaction sequence
- 36.5 Detailed mechanism and the role of active-site residues
- Leading references
- 37 Thymidylate synthase
- 37.1 Thymidylate synthase
- 37.2 Physiological function
- 37.3 Key structural features
- 37.4 Reaction sequence
- 37.5 Detailed mechanism(s) and the roles of active site residues
- Leading references
- 38 The 20S proteasome
- 38.1 The 20S proteasome
- 38.2 Physiological function
- 38.3 Key structural features
- 38.4 Reaction sequence
- 38.5 Detailed mechanism and the role of active-site residues
- Leading references
- 39 Uracil-DNA glycosylase.