| Record ID | marc_columbia/Columbia-extract-20221130-028.mrc:69918700:5906 |
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008 180625s2018 enk o 001 0 eng d
035 $a(OCoLC)on1041854598
035 $a(NNC)13610001
040 $aUKRSC$beng$erda$epn$cUKRSC$dN$T$dCOO$dEBLCP$dUIU$dMERER$dOCLCF$dOCLCQ$dNLE$dSTF$dUAB$dUKMGB$dLVT$dERL$dKNOVL$dESU$dUKAHL$dOCLCQ$dK6U$dUX1$dAKR$dOCLCQ$dOCLCO$dUIU$dOCLCQ$dOCLCO
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020 $a9781788010450$q(electronic bk.)
020 $a1788010450$q(electronic bk.)
020 $a9781788014533
020 $a1788014537
020 $a9781523119431$q(electronic bk.)
020 $a1523119438$q(electronic bk.)
020 $z9781782627265$q(print)
020 $z178262726X$q(print)
035 $a(OCoLC)1041854598$z(OCoLC)1041484637$z(OCoLC)1136184339$z(OCoLC)1144217387$z(OCoLC)1162604587$z(OCoLC)1198252807$z(OCoLC)1250576025$z(OCoLC)1300641570
037 $a4771:4623$bRoyal Society of Chemistry$nhttp://www.rsc.org/spr
050 4 $aTP248.25.B55
060 4 $a2018 G-972
060 4 $aQU 135
072 7 $aSCI$x013040$2bisacsh
072 7 $aPSB$2bicssc
072 7 $aTCB$2bicssc
082 04 $a547/.215$223
049 $aZCUA
245 00 $aModern biocatalysis :$badvances towards synthetic biological systems /$ceditors: Gavin Williams, Mélanie Hall.
264 1 $aCambridge :$bRoyal Society of Chemistry,$c2018
300 $a1 online resource (574 pages)
336 $atext$btxt$2rdacontent
337 $acomputer$bc$2rdamedia
338 $aonline resource$bcr$2rdacarrier
490 1 $aRSC catalysis series ;$v32
500 $aIncludes index.
500 $aTitle from title details screen.
505 0 $aCover; Preface; Contents; Section I: Accessing New Enzymes; Chapter 1 Genome Mining for Enzyme Discovery; 1.1 Introduction; 1.2 Text-based Searches Using Enzyme Name; 1.3 Sequence-driven Approaches; 1.3.1 Probe Technology Based on PCR Primer Design; 1.3.2 Pairwise Sequence Alignment-based Strategy; 1.3.3 Signature-/Key Motif-based Strategy; 1.4 3D Structure-guided Approach; 1.4.1 Exploring 3D Structures of Proteins; 1.4.2 Active Site Topology/Constellation-guided Strategy; 1.5 Conclusion; References; Chapter 2 Exploiting Natural Diversity for Industrial Enzymatic Applications
505 8 $a2.1 Introduction2.2 Screening Enzymes from Soil Microbes, Plants, and Animals (Millipede) by Activity Measurement; 2.2.1 Hydrolases; 2.2.2 Oxidoreductases; 2.2.3 Lyases; 2.3 Genetic Approaches to Natural Enzyme Sources; 2.3.1 Isomerases; 2.3.2 Oxidoreductases; 2.4 Creation of Amine Oxidase by Directed Evolution of D-Amino Acid Oxidase; 2.5 From Discovery to Application -- Aldoxime Dehydratases; 2.5.1 Isolation, Characterization and Comparison of Aldoxime Dehydratases; 2.5.2 Iron Heme Redox Catalysis and Mechanistic Studies; 2.5.3 Substrate Spectrum of Aldoxime Dehydratases
505 8 $a2.5.4 Application of Oxds for Nitrile Synthesis2.5.5 Perspectives; 2.6 Conclusion; Acknowledgements; References; Chapter 3 Artificial Metalloenzymes; 3.1 Introduction; 3.2 Direct Insertion of Inorganic Metal Ions into Proteins; 3.2.1 Carbonic Anhydrase; 3.2.2 Ferritin; 3.2.3 Serum Albumins; 3.2.4 Phytase and Other Proteins; 3.3 Supramolecular Anchoring of Metal Cofactors; 3.3.1 The ""Trojan-Horse"" Strategy; 3.3.2 The ""Host-Guest"" Strategy; 3.4 Covalent Linking of Metallic Cofactors to a Protein; 3.5 Cascade Reactions; 3.6 Conclusion; References
505 8 $aChapter 4 Computational Enzyme Design: Successes, Challenges, and Future Directions4.1 Introduction; 4.2 Examples of Computational Enzyme Design; 4.2.1 Phase I: Initial Application of CPD Towards Enzyme Design; 4.2.2 Phase II: Incorporation of TransitionStates and Theozymes into Computational Enzyme Design; 4.3 Challenges in Computational Enzyme Design; 4.4 Future Directions; 4.5 Conclusions; Acknowledgements; References; Section II: Understanding and Engineering Enzymes; Chapter 5 Computational Techniques for Efficient Biocatalysis; 5.1 Introduction to Computational Biocatalysis
505 8 $a5.1.1 Bioinformatic Tools5.1.2 Ancestral Gene Resurrection; 5.1.3 Structure-based Computational Tools; 5.1.4 QM Computational Tools; 5.1.5 Molecular Mechanics and Molecular Dynamics Computational Tools; 5.1.6 QM/MM; 5.2 Implementation of Computational Tools in Biocatalysis; 5.2.1 Identification of Novel Biocatalysts from Sequence Space; 5.2.2 Ancestral Enzyme Reconstruction for the Study and Engineering of Binding and Catalysis; 5.3 Structural-based In Silico Modelling for Efficient Biocatalysis
520 $aWith contributions from leading academics around the world, this book makes a ground-breaking contribution to the field of biocatalysis and is essential reading for graduates and researchers investigating (bio)catalysis, enzyme engineering, chemical biology, and synthetic biology.
650 0 $aBiocatalysis.
650 2 $aBiocatalysis
650 6 $aBiocatalyse.
650 7 $aBiochemistry.$2bicssc
650 7 $aBiotechnology.$2bicssc
650 7 $aSCIENCE$xChemistry$xOrganic.$2bisacsh
650 7 $aBiocatalysis.$2fast$0(OCoLC)fst01896571
655 4 $aElectronic books.
700 1 $aWilliams, Gavin$c(Professor of chemistry),$eeditor.
700 1 $aHall, Mélanie,$eeditor.
776 08 $iPrint version:$z9781782627265
830 0 $aRSC catalysis series ;$vno. 32.
856 40 $uhttp://www.columbia.edu/cgi-bin/cul/resolve?clio13610001.001$zACADEMIC - Chemistry & Chemical Engineering
856 40 $uhttp://www.columbia.edu/cgi-bin/cul/resolve?clio13610001.002$zACADEMIC - Sustainable Energy & Development
852 8 $blweb$hEBOOKS