ebook img

Chemistry and Physics of Lipids 1998: Vol 93 Index PDF

5 Pages·1998·0.64 MB·English
by  
Save to my drive
Quick download
Download
Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.

Preview Chemistry and Physics of Lipids 1998: Vol 93 Index

CPL CHEMISTRY AND ELSEVIER Chemistry and Physics of Lipids PHYSICS OF LIPIDS 93 (1998) 209 Author index Volume 93 (1998) Alberghina, L. 93, 47 Fernandez-Lorente, G. 93, 185 Orrenius, S.C. 93, 81 Alcantara, A.R. 93, 169 Fischer, M. 93, 67 Overbeeke, P.L. 93, 81 Alquati, C. 93, 47 Anthonsen, T. 93, 199 Gastinel, L. 93, 103 Palocci, C. 93, 157 Armisén, P. 93, 185 Gordillo, M.A. 93, 131 Park, J.-W. 93, 149 Gotz, F. 93, 15, 27 Patkar, S. 93, 95 Bezzine, S. 93, 103 Guisan, J.M. 93, 185 Pignol, D. 93, 123 Blanchette-Mackie, E.J. 93, 149 Pleiss, J. 93, 67 Borch, K. 93, 95 Hermoso, J. 93, 123 Brocea, S. 93, 47, 143 Hoff, B.H. 93, 199 RReoestezn,s teMi.nT,. R. 93, 933, 15 Holmquist, M. 93, 57 Roussel, A. 93, 103 Cambillau, C. 93, 103 Carlos Fontecilla-Camps, J. 93, 123 Jaeger, K.-E. 93, 3 Sabuquillo, P. 93, 185 Carriére, F. 93, 103 Jongejan, J.A. 93, 81 Schmid, R.D. 93, 67 Casas, C. 93, 131 Schultz, C.J. 93, 149 Cernia, E. 93, 157 Kelstrup, E. 93, 95 Scow, R.O. 93, 149 Chapus, C. 93, 123 Kerfelec, B. 93, 123 Simons, J.-W.F.A. 93, 27, 39 Christensen, M.W. 93, 95 Kirk, O. 93, 95 Sinisterra, J.V. 93, 169 Crenon, I. 93, 123 Sola, C. 93, 131 Soro, S. 93, 157 de Caro, A. 93, 103 Lafuente, J. 93, 131, 143 Svendsen, A. 93, 95 de Caro, J. 93, 103 Lang, D.A. 93, 115 de Fuentes, I.E. 93, 169 Leydier, S. 93, 103 Takagi, M. 93, 47 Dekker, N. 93, 39 Lotti, M. 93, 47, 143 Dijkstra, B.W. 93, 115 Luis Montesinos, J. 93, 143 Valero, F. 93, 131, 143 Duine, J.A. 93, 81 van Kampen, M.D. 93, 39 Mileto, D. 93, 47 Verger, R. 93, 103 Egmond, M.R. 93, 27, 39 Montesinos, J.L. 93, 131 Verheij, H.M. 93, 15, 27, 39 Fernandez-Lafuente, R. 93, 185 Monticelli, S. 93, 143 Vind, J. 93, 95 PII $0009-3084(98)00055-3 CPL CHEMISTRY AND Chemistry and Physics of Lipids PHYSICS OF LIPIDS 93 (1998) 211 213 Subject index Volume 93 (1998) Active site architecture; Lipase; Enantioselectivity; Stereospe- Combined lipase deficiency; Lipoprotein lipase; Hepatic lipase; cificity; Crystal structure: X-ray crystallography 93, 115 Dimerization; Endoplasmic reticulum; Brefeldin A 93, 149 Acyl donors; Resolution; C-3 chirons; CALB; Substrate effect: Crystal structure; Lipase; Enantioselectivity; Stereospecificity; Solvent effect; Water activity 93, 199 Active site architecture; X-ray crystallography 93, 115 Biocatalysis; Lipase; Organic solvent; Supercritical fluids 93, C-terminal; Phospholipase activity; Staphylococcus hyicus 93, 157 39 Biochemical properties; Staphylococcus; (Phospho)lipase; Sub- Dimerization; Lipoprotein lipase; Hepatic lipase; Combined strate selectivity; Structure-function relationship 93, 27 lipase deficiency; Endoplasmic reticulum; Brefeldin A 93, 149 Brefeldin A; Lipoprotein lipase; Hepatic lipase; Combined Enantioselectivity; Candida antarctica; Lipase; Protein engi- lipase deficiency; Dimerization; Endoplasmic reticulum 93, neering; Stability 93, 95 149 Enantioselectivity; Lipases; Enthalpy—entropy compensation; CALB; Resoiution; C-3 chirons; Substrate effect; Soivent ef- Organic media; Two-state models 93, 81 fect; Acyl donors; Water activity 93, 199 Enantioselectivity; Lipase; Stereospecificity; Crystal structure; Candida antarctica, Lipase; Protein engineering; Stability; Active site architecture; X-ray crystallography 93, 115 Enantioselectivity 93, 95 Enantioselectivity; Pseudomonas lipase; Overexpression; Li- pase-specific foldase; Immobilization; In vitro evolution 93, 3 Candida, Lipase; Isoenzymes; Genetic code 93, 47 Enantioselectivity; Structure-function relationships; Interfacial Candida rugosa; Lipase; Isoenzymes; Expression; Secre- activation; Protein engineering; Molecular modeling; Chiral tion 93, 143 recognition 93, 57 Candida rugosa, Lipase production; On-line monitoring and Endoplasmic reticulum; Lipoprotein lipase; Hepatic lipase; estimation control strategies; Purification; Fermentation 93, 131 Combined lipase deficiency; Dimerization; Brefeldin A 93, 149 C-3 chirons; Resolution; CALB; Substrate effect: Solvent ef- Enthalpy—entropy compensation; Lipases; Enantioselectivity; fect; Acyl donors; Water activity 93, 199 Organic media; Two-state models 93, 81 Chain length specificity; Modeling; Structure; Mutant; Es- Esterase; Modeling; Structure; Chain length specificity; Mu- terase; Protein engineering 93, 67 tant; Protein engineering 93, 67 Chiral compounds; Rhizomucor miehei; Lipase; Resolu- Expression; Lipase; Candida rugosa; Isoenzymes; Secre- tion 93, 169 tion 93, 143 Chiral recognition; Structure-function relationships; Interfacial Fermentation; Lipase production; Candida rugosa; On-line activation; Protein engineering: Molecular modeling; Enan- monitoring and estimation control strategies; Purification 93, tioselectivity 93, 57 131 PIT $0009-3084(98)00056-5 Subject index Genetic code; Lipase; Candida: Isoenzymes 93, 47 Lipase. Rhizomucor miehei; Resolution; Chiral com- pounds 93, 169 Glycerides; Pancreatic juice; Pancreatic lipase; X-ray struc- ture 93, 103 Lipases; Enantioselectivity; Enthalpy—entropy compensation; Organic media; Two-state models 93, 81 Hepatic lipase; Lipoprotein lipase; Combined lipase deficiency: Dimerization; Endoplasmic reticulum; Brefeldin A 93, 149 Lipase-specific foldase; Pseudomonas lipase; Overexpression; Immobilization; In vitro evolution; Enantioselectivity 93, 3 Immobilization—hyperactivation of lipases: Interfacial activa- tion of lipases on solid interfaces; Immobilization — purifica- Lipoprotein lipase; Hepatic lipase: Combined lipase deficiency; tion of lipases; Immobilized lipases in aqueous media 93, 185 Dimerization; Endoplasmic reticulum; Brefeldin A 93, 149 Immobilization, Pseudomonas lipase; Overexpression; Lipase- Micelle, Neutron crystallographic evidence; Lipase/colipase specific foldase: In vitro evolution; Enantioselectivity 93, 3 complex 93, 123 Immobilization— purification of lipases; Interfacial activation Modeling: Structure; Chain length specificity: Mutant; Es- of lipases on solid interfaces; Immobilization — hyperactiva- terase; Protein engineering 93, 67 tion of lipases; Immobilized lipases in aqueous media 93, 185 Molecular modeling: Structure-function relationships; Interfa- Immobilized lipases in aqueous media; Interfacial activation of cial activation; Protein engineering; Chiral recognition; Enan- lipases on solid interfaces; Immobilization— purification of tioselectivity 93, 57 lipases; Immobilization — hyperactivation of lipases 93, 185 Mutant; Modeling: Structure; Chain length specificity; Es- Interfacial activation of lipases on solid interfaces: Immobiliza- terase; Protein engineering 93, 67 tion — purification of lipases; Immobilization — hyperactiva- tion of lipases; Immobilized lipases in aqueous media 93, 185 Neutron crystallographic evidence; Micelle: Lipase colipase complex 93, 123 Interfacial activation: Structure-function relationships; Protein engineering; Molecular modeling; Chiral recognition; Enan- On-line monitoring and estimation control strategies; Lipase tioselectivity 93, 57 production; Candida rugosa; Purification; Fermentation 93, 131 In vitro evolution; Pseudomonas lipase; Overexpression; Lipase- specific foldase; Immobilization; Enantioselectivity 93, 3 Organic media; Lipases; Enantioselectivity; Enthalpy—entropy Isoenzymes; Lipase: Candida: Genetic code 93, 47 compensation; Two-state models 93, 81 Isoenzymes; Lipase: Candida rugosa; Expression; Secre- Organic solvent; Lipase; Biocatalysis; Supercritical fluids 93, 157 tion 93, 143 Lipase, Biocatalysis; Organic solvent: Supercritical fluids 93, Overexpression; Pseudomonas lipase, Lipase-specific foldase; 157 Immobilization: In vitro evolution; Enantioselectivity 93, 3 Lipase, Candida antarctica; Protein engineering: Stability: Pancreatic juice; Pancreatic lipase: Glycerides; X-ray struc- Enantioselectivity 93, 95 ture 93, 103 Lipase; Candida; lsoenzymes; Genetic code 93, 47 Pancreatic lipase: Pancreatic juice: Glycerides; X-ray struc- ture 93, 103 Lipase, Candida rugosa: Isoenzymes; Expression; Secre- tion 93, 143 Phospholipase activity; Staphylococcus hyicus; C-terminal 93, 39 Lipase/colipase complex: Neutron crystallographic evidence: Micelle 93, 123 (phospho) lipases; Pre-pro-enzyme: Processing: Staphylococ- cus 93, 15 Lipase; Enantioselectivity; Stereospecificity; Crystal structure; Active site architecture; X-ray crystallography 93, 115 (Phospho)lipase; Staphylococcus; Biochemical properties; Sub- strate selectivity; Structure-function relationship 93, 27 Lipase production; Candida rugosa; On-line monitoring and estimation control strategies; Purification; Fermentation 93, Pre-pro-enzyme; (phospho) lipases; Processing: Staphylococ- 131 cus 93, 15 Subject index 213 Processing; (phospho) lipases; Pre-pro-enzyme; Staphylococ- Staphylococcus; (Phospho)lipase; Biochemical properties; Sub- cus 93, 15 strate selectivity; Structure-function relationship 93, 27 Protein engineering; Candida antarctica; Lipase; Stability; Staphylococcus, (phospho) lipases; Pre-pro-enzyme; Process- Enantioselectivity 93, 95 ing 93, 15 Protein engineering; Modeling; Structure; Chain length specifi- Stereospecificity; Lipase; Enantioselectivity; Crystal structure; city; Mutant; Esterase 93, 67 Active site architecture; X-ray crystallography 93, 115 Protein engineering; Structure-function relationships; Interfa- Structure-function relationships; Interfacial activation; Protein cial activation; Molecular modeling; Chiral recognition; Enan- engineering; Molecular modeling; Chiral recognition; Enan- tioselectivity 93, 57 tioselectivity 93, 57 Pseudomonas \ipase, Overexpression; Lipase-specific foldase; Structure-function _relationship; Staphylococcus; _(Phos- Immobilization; In vitro evolution; Enantioselectivity 93, 3 pho)lipase; Biochemical properties; Substrate selectivity 93, 27 Purification; Lipase production; Candida rugosa; On-line mon- itoring and estimation control strategies; Fermentation 93, Structure, Modeling; Chain length specificity; Mutant; Es- 131 terase; Protein engineering 93, 67 Resolution; C-3 chirons; CALB; Substrate effect; Solvent ef- Substrate effect; Resolution; C-3 chirons; CALB; Solvent ef- fect; Acyl donors; Water activity 93, 199 fect; Acyl donors; Water activity 93, 199 Resolution; Rhizomucor miehei; Lipase; Chiral com- Substrate selectivity; Staphylococcus, (Phospho)lipase; Bio- pounds 93, 169 chemical properties; Structure-function relationship 93, 27 Rhizomucor miehei, Lipase; Resolution; Chiral com- Supercritical fluids; Lipase; Biocatalysis; Organic solvent 93, pounds 93, 169 157 Secretion; Lipase; Candida rugosa; Isoenzymes; Expres- Two-state models; Lipases; Enantioselectivity; Enthalpy—en- sion 93, 143 tropy compensation; Organic media 93, 81 Solvent effect; Resolution; C-3 chirons; CALB; Substrate ef- Water activity; Resolution; C-3 chirons; CALB; Substrate fect: Acyl donors; Water activity 93, 199 effect; Solvent effect; Acyl donors 93, 199 Stability; Candida antarctica,; Lipase; Protein engineering; X-ray crystallography; Lipase; Enantioselectivity; Stereospecifi- Enantioselectivity 93, 95 city; Crystal structure; Active site architecture 93, 115 Staphylococcus hyicus, Phospholipase activity; C-terminal 93, X-ray structure; Pancreatic juice; Pancreatic lipase; Glyce- 39 rides 93, 103

See more

The list of books you might like

Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.