| 190L | A:1-162 | A HELIX INITIATION SIGNAL IN T4 LYSOZYME IDENTIFIED BY POLYALANINE MUTAGENESIS |
| 191L | A:1-162 | A HELIX INITIATION SIGNAL IN T4 LYSOZYME IDENTIFIED BY POLYALANINE MUTAGENESIS |
| 192L | A:1-162 | A HELIX INITIATION SIGNAL IN T4 LYSOZYME IDENTIFIED BY POLYALANINE MUTAGENESIS |
| 1C60 | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/F153A IN THE PRESENCE OF 8 ATM ARGON |
| 1C61 | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/F153A IN THE PRESENCE OF 8 ATM KRYPTON |
| 1C62 | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/F153A IN THE PRESENCE OF 8 ATM XENON |
| 1C63 | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L121A IN THE PRESENCE OF 8 ATM ARGON |
| 1C64 | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L121A IN THE PRESENCE OF 8 ATM KRYPTON |
| 1C65 | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L121A IN THE PRESENCE OF 8 ATM XENON |
| 1C66 | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L121A/L133A IN THE PRESENCE OF 8 ATM ARGON |
| 1C67 | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L121A/L133A IN THE PRESENCE OF 8 ATM KRYPTON |
| 1C68 | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L121A/L133A IN THE PRESENCE OF 8 ATM XENON |
| 1C69 | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L133A IN THE PRESENCE OF 8 ATM ARGON |
| 1C6A | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L133A IN THE PRESENCE OF 8 ATM KRYPTON |
| 1C6B | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L133A IN THE PRESENCE OF 8 ATM XENON |
| 1C6C | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A IN THE PRESENCE OF 16 ATM ARGON |
| 1C6D | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A IN THE PRESENCE OF 16 ATM KRYPTON |
| 1C6E | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A IN THE PRESENCE OF 2 ATM XENON |
| 1C6F | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A IN THE PRESENCE OF 32 ATM ARGON |
| 1C6G | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A IN THE PRESENCE OF 4 ATM KRYPTON |
| 1C6H | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A IN THE PRESENCE OF 4 ATM XENON |
| 1C6I | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A IN THE PRESENCE OF 8 ATM ARGON |
| 1C6J | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A IN THE PRESENCE OF 8 ATM KRYPTON |
| 1C6K | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A IN THE PRESENCE OF 8 ATM XENON |
| 1C6L | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A/F153A IN THE PRESENCE OF 8 ATM ARGON |
| 1C6M | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A/F153A IN THE PRESENCE OF 8 ATM KRYPTON |
| 1C6N | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/L99A/F153A IN THE PRESENCE OF 8 ATM XENON |
| 1C6P | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A IN THE PRESENCE OF 8 ATM ARGON |
| 1C6Q | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A IN THE PRESENCE OF 8 ATM KRYPTON |
| 1C6T | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A IN THE PRESENCE OF 8 ATM XENON |
| 1CV3 | A:1-162 | T4 LYSOZYME MUTANT L121M |
| 1CV4 | A:1-162 | T4 LYSOZYME MUTANT L118M |
| 1CV5 | A:1-162 | T4 LYSOZYME MUTANT L133M |
| 1CV6 | A:1-162 | T4 LYSOZYME MUTANT V149M |
| 1CVK | A:1-162 | T4 LYSOZYME MUTANT L118A |
| 1CX6 | A:2-162 | T4 LYSOZYME SUBSTITUTED WITH SELENOMETHIONINE |
| 1CX7 | A:1-162 | T4 LYSOZYME METHIONINE CORE MUTANT |
| 1D2W | A:1-162 | N-TERMINAL DOMAIN CORE METHIONINE MUTATION |
| 1D2Y | A:1-162 | N-TERMINAL DOMAIN CORE METHIONINE MUTATION |
| 1D3F | A:1-162 | N-TERMINAL DOMAIN CORE METHIONINE MUTATION |
| 1D3J | A:1-162 | N-TERMINAL DOMAIN CORE METHIONINE MUTATION |
| 1D3M | A:1-162 | METHIONINE CORE MUTATION |
| 1D3N | A:2-162 | METHIONINE CORE MUTATION |
| 1D9W | A:1-162 | BACTERIOPHAGE T4 LYSOZYME MUTANT |
| 1G1V | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/I58T |
| 1G1W | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/Q105M |
| 1I6S | A:1-162 | T4 LYSOZYME MUTANT C54T/C97A/N101A |
| 1JQU | A:1-164; B:1-164; C:1-164; D:1-164 | ARE CARBOXY TERMINII OF HELICES CODED BY THE LOCAL SEQUENCE OR BY TERTIARY STRUCTURE CONTACTS |
| 1JTM | A:1-178 | ALTERNATIVE STRUCTURES OF A SEQUENCE EXTENDED T4 LYSOZYME SHOW THAT THE HIGHLY CONSERVED BETA-SHEET HAS WEAK INTRINSIC FOLDING PROPENSITY |
| 1JTN | B:1-174; A:1-177 | ALTERNATIVE STRUCTURES OF A SEQUENCE EXTENDED T4 LYSOZYME SHOW THAT THE HIGHLY CONSERVED BETA-SHEET REGION HAS WEAK INTRINSIC FOLDING PROPENSITY |
| 1K28 | A:174-342 | THE STRUCTURE OF THE BACTERIOPHAGE T4 CELL-PUNCTURING DEVICE |
| 1KS3 | A:1-162 | METHIONINE CORE MUTANT OF T4 LYSOZYME |
| 1KW5 | A:1-162 | METHIONINE CORE MUTANT OF T4 LYSOZYME |
| 1KW7 | A:1-162 | METHIONINE CORE MUTANT OF T4 LYSOZYME |
| 1KY0 | A:1-162 | METHIONINE CORE MUTANT OF T4 LYSOZYME |
| 1KY1 | A:1-162 | METHIONINE CORE MUTANT OF T4 LYSOZYME |
| 1L01 | A:1-164 | STRUCTURAL STUDIES OF MUTANTS OF THE LYSOZYME OF BACTERIOPHAGE T4. THE TEMPERATURE-SENSITIVE MUTANT PROTEIN THR157 (RIGHT ARROW) ILE |
| 1L02 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L03 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L04 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L05 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L06 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L07 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L08 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L09 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L0J | A:1-162 | METHIONINE CORE MUTANT OF T4 LYSOZYME |
| 1L0K | A:1-162 | METHIONINE CORE MUTANT OF T4 LYSOZYME |
| 1L10 | A:1-164 | STRUCTURAL STUDIES OF MUTANTS OF THE LYSOZYME OF BACTERIOPHAGE T4. THE TEMPERATURE-SENSITIVE MUTANT PROTEIN THR157 (RIGHT ARROW) ILE |
| 1L11 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L12 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L13 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L14 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L15 | A:1-164 | CONTRIBUTIONS OF HYDROGEN BONDS OF THR 157 TO THE THERMODYNAMIC STABILITY OF PHAGE T4 LYSOZYME |
| 1L16 | A:1-164 | STRUCTURAL ANALYSIS OF THE TEMPERATURE-SENSITIVE MUTANT OF BACTERIOPHAGE T4 LYSOZYME, GLYCINE 156 (RIGHT ARROW) ASPARTIC ACID |
| 1L17 | A:1-164 | HYDROPHOBIC STABILIZATION IN T4 LYSOZYME DETERMINED DIRECTLY BY MULTIPLE SUBSTITUTIONS OF ILE 3 |
| 1L18 | A:1-164 | HYDROPHOBIC STABILIZATION IN T4 LYSOZYME DETERMINED DIRECTLY BY MULTIPLE SUBSTITUTIONS OF ILE 3 |
| 1L19 | A:1-164 | ENHANCED PROTEIN THERMOSTABILITY FROM DESIGNED MUTATIONS THAT INTERACT WITH ALPHA-HELIX DIPOLES |
| 1L20 | A:1-164 | ENHANCED PROTEIN THERMOSTABILITY FROM DESIGNED MUTATIONS THAT INTERACT WITH ALPHA-HELIX DIPOLES |
| 1L21 | A:1-164 | CONTRIBUTIONS OF LEFT-HANDED HELICAL RESIDUES TO THE STRUCTURE AND STABILITY OF BACTERIOPHAGE T4 LYSOZYME |
| 1L22 | A:1-164 | CONTRIBUTIONS OF LEFT-HANDED HELICAL RESIDUES TO THE STRUCTURE AND STABILITY OF BACTERIOPHAGE T4 LYSOZYME |
| 1L23 | A:1-164 | ENHANCED PROTEIN THERMOSTABILITY FROM SITE-DIRECTED MUTATIONS THAT DECREASE THE ENTROPY OF UNFOLDING |
| 1L24 | A:1-164 | ENHANCED PROTEIN THERMOSTABILITY FROM SITE-DIRECTED MUTATIONS THAT DECREASE THE ENTROPY OF UNFOLDING |
| 1L25 | A:1-164 | REPLACEMENTS OF PRO86 IN PHAGE T4 LYSOZYME EXTEND AN ALPHA-HELIX BUT DO NOT ALTER PROTEIN STABILITY |
| 1L26 | A:1-164 | REPLACEMENTS OF PRO86 IN PHAGE T4 LYSOZYME EXTEND AN ALPHA-HELIX BUT DO NOT ALTER PROTEIN STABILITY |
| 1L27 | A:1-164 | REPLACEMENTS OF PRO86 IN PHAGE T4 LYSOZYME EXTEND AN ALPHA-HELIX BUT DO NOT ALTER PROTEIN STABILITY |
| 1L28 | A:1-164 | REPLACEMENTS OF PRO86 IN PHAGE T4 LYSOZYME EXTEND AN ALPHA-HELIX BUT DO NOT ALTER PROTEIN STABILITY |
| 1L29 | A:1-164 | REPLACEMENTS OF PRO86 IN PHAGE T4 LYSOZYME EXTEND AN ALPHA-HELIX BUT DO NOT ALTER PROTEIN STABILITY |
| 1L30 | A:1-164 | REPLACEMENTS OF PRO86 IN PHAGE T4 LYSOZYME EXTEND AN ALPHA-HELIX BUT DO NOT ALTER PROTEIN STABILITY |
| 1L31 | A:1-164 | REPLACEMENTS OF PRO86 IN PHAGE T4 LYSOZYME EXTEND AN ALPHA-HELIX BUT DO NOT ALTER PROTEIN STABILITY |
| 1L32 | A:1-164 | REPLACEMENTS OF PRO86 IN PHAGE T4 LYSOZYME EXTEND AN ALPHA-HELIX BUT DO NOT ALTER PROTEIN STABILITY |
| 1L33 | A:1-164 | CONTRIBUTIONS OF LEFT-HANDED HELICAL RESIDUES TO THE STRUCTURE AND STABILITY OF BACTERIOPHAGE T4 LYSOZYME |
| 1L34 | A:1-164 | HIGH-RESOLUTION STRUCTURE OF THE TEMPERATURE-SENSITIVE MUTANT OF PHAGE LYSOZYME, ARG 96 (RIGHT ARROW) HIS |
| 1L35 | A:1-164 | STRUCTURE OF A THERMOSTABLE DISULFIDE-BRIDGE MUTANT OF PHAGE T4 LYSOZYME SHOWS THAT AN ENGINEERED CROSSLINK IN A FLEXIBLE REGION DOES NOT INCREASE THE RIGIDITY OF THE FOLDED PROTEIN |
| 1L37 | A:1-164 | CONTRIBUTIONS OF ENGINEERED SURFACE SALT BRIDGES TO THE STABILITY OF T4 LYSOZYME DETERMINED BY DIRECTED MUTAGENESIS |
| 1L38 | A:1-164 | CONTRIBUTIONS OF ENGINEERED SURFACE SALT BRIDGES TO THE STABILITY OF T4 LYSOZYME DETERMINED BY DIRECTED MUTAGENESIS |
| 1L39 | A:1-164 | CONTRIBUTIONS OF ENGINEERED SURFACE SALT BRIDGES TO THE STABILITY OF T4 LYSOZYME DETERMINED BY DIRECTED MUTAGENESIS |
| 1L40 | A:1-164 | CONTRIBUTIONS OF ENGINEERED SURFACE SALT BRIDGES TO THE STABILITY OF T4 LYSOZYME DETERMINED BY DIRECTED MUTAGENESIS |
| 1L41 | A:1-164 | CONTRIBUTIONS OF ENGINEERED SURFACE SALT BRIDGES TO THE STABILITY OF T4 LYSOZYME DETERMINED BY DIRECTED MUTAGENESIS |
| 1L42 | A:1-164 | CUMULATIVE SITE-DIRECTED CHARGE-CHANGE REPLACEMENTS IN BACTERIOPHAGE T4 LYSOZYME SUGGEST THAT LONG-RANGE ELECTROSTATIC INTERACTIONS CONTRIBUTE LITTLE TO PROTEIN STABILITY |
| 1L43 | A:1-164 | CUMULATIVE SITE-DIRECTED CHARGE-CHANGE REPLACEMENTS IN BACTERIOPHAGE T4 LYSOZYME SUGGEST THAT LONG-RANGE ELECTROSTATIC INTERACTIONS CONTRIBUTE LITTLE TO PROTEIN STABILITY |
| 1L44 | A:1-164 | CUMULATIVE SITE-DIRECTED CHARGE-CHANGE REPLACEMENTS IN BACTERIOPHAGE T4 LYSOZYME SUGGEST THAT LONG-RANGE ELECTROSTATIC INTERACTIONS CONTRIBUTE LITTLE TO PROTEIN STABILITY |
| 1L45 | A:1-164 | CUMULATIVE SITE-DIRECTED CHARGE-CHANGE REPLACEMENTS IN BACTERIOPHAGE T4 LYSOZYME SUGGEST THAT LONG-RANGE ELECTROSTATIC INTERACTIONS CONTRIBUTE LITTLE TO PROTEIN STABILITY |
| 1L46 | A:1-164 | CUMULATIVE SITE-DIRECTED CHARGE-CHANGE REPLACEMENTS IN BACTERIOPHAGE T4 LYSOZYME SUGGEST THAT LONG-RANGE ELECTROSTATIC INTERACTIONS CONTRIBUTE LITTLE TO PROTEIN STABILITY |
| 1L47 | A:1-164 | CUMULATIVE SITE-DIRECTED CHARGE-CHANGE REPLACEMENTS IN BACTERIOPHAGE T4 LYSOZYME SUGGEST THAT LONG-RANGE ELECTROSTATIC INTERACTIONS CONTRIBUTE LITTLE TO PROTEIN STABILITY |
| 1L48 | A:1-164 | STRUCTURAL AND THERMODYNAMIC ANALYSIS OF THE PACKING OF TWO ALPHA-HELICES IN BACTERIOPHAGE T4 LYSOZYME |
| 1L49 | A:1-164 | STRUCTURAL AND THERMODYNAMIC ANALYSIS OF THE PACKING OF TWO ALPHA-HELICES IN BACTERIOPHAGE T4 LYSOZYME |
| 1L50 | A:1-164 | STRUCTURAL AND THERMODYNAMIC ANALYSIS OF THE PACKING OF TWO ALPHA-HELICES IN BACTERIOPHAGE T4 LYSOZYME |
| 1L51 | A:1-164 | STRUCTURAL AND THERMODYNAMIC ANALYSIS OF THE PACKING OF TWO ALPHA-HELICES IN BACTERIOPHAGE T4 LYSOZYME |
| 1L52 | A:1-164 | STRUCTURAL AND THERMODYNAMIC ANALYSIS OF THE PACKING OF TWO ALPHA-HELICES IN BACTERIOPHAGE T4 LYSOZYME |
| 1L53 | A:1-164 | STRUCTURAL AND THERMODYNAMIC ANALYSIS OF THE PACKING OF TWO ALPHA-HELICES IN BACTERIOPHAGE T4 LYSOZYME |
| 1L54 | A:1-164 | THE STRUCTURAL AND THERMODYNAMIC CONSEQUENCES OF BURYING A CHARGED RESIDUE WITHIN THE HYDROPHOBIC CORE OF T4 LYSOZYME |
| 1L56 | A:1-164 | ANALYSIS OF THE INTERACTION BETWEEN CHARGED SIDE CHAINS AND THE ALPHA-HELIX DIPOLE USING DESIGNED THERMOSTABLE MUTANTS OF PHAGE T4 LYSOZYME |
| 1L58 | A:1-164 | ANALYSIS OF THE INTERACTION BETWEEN CHARGED SIDE CHAINS AND THE ALPHA-HELIX DIPOLE USING DESIGNED THERMOSTABLE MUTANTS OF PHAGE T4 LYSOZYME |
| 1L60 | A:1-164 | ANALYSIS OF THE INTERACTION BETWEEN CHARGED SIDE CHAINS AND THE ALPHA-HELIX DIPOLE USING DESIGNED THERMOSTABLE MUTANTS OF PHAGE T4 LYSOZYME |
| 1LLH | A:1-162 | ARE CARBOXY TERMINII OF HELICES CODED BY THE LOCAL SEQUENCE OR BY TERTIARY STRUCTURE CONTACTS |
| 1LPY | A:2-162 | MULTIPLE METHIONINE SUBSTITUTIONS IN T4 LYSOZYME |
| 1P56 | A:1-162 | DUPLICATION-EXTENSION OF HELIX A OF T4 LYSOZYME |
| 1P5C | A:13-178; B:13-178; C:13-178; D:13-178 | CIRCULAR PERMUTATION OF HELIX A IN T4 LYSOZYME |
| 1PQD | A:1-164 | T4 LYSOZYME CORE REPACKING MUTANT CORE10/TA |
| 1PQI | A:1-164 | T4 LYSOZYME CORE REPACKING MUTANT I118L/CORE7/TA |
| 1PQJ | A:1-164 | T4 LYSOZYME CORE REPACKING MUTANT A111V/CORE10/TA |
| 1PQK | A:1-164; B:1-164; C:1-164 | REPACKING OF THE CORE OF T4 LYSOZYME BY AUTOMATED DESIGN |
| 1PQM | A:1-164 | T4 LYSOZYME CORE REPACKING MUTANT V149I/T152V/TA |
| 1PQO | A:1-164 | T4 LYSOZYME CORE REPACKING MUTANT L118I/TA |
| 1QSQ | A:1-162 | CAVITY CREATING MUTATION |
| 1SWY | A:1-164 | USE OF A HALIDE BINDING SITE TO BYPASS THE 1000-ATOM LIMIT TO AB INITIO STRUCTURE DETERMINATION |
| 1SWZ | A:1-164 | USE OF AN ION-BINDING SITE TO BYPASS THE 1000-ATOM LIMIT TO AB INITIO STRUCTURE DETERMINATION BY DIRECT METHODS |
| 1SX2 | A:1-164 | USE OF A HALIDE BINDING SITE TO BYPASS THE 1000-ATOM LIMIT TO STRUCTURE DETERMINATION BY DIRECT METHODS |
| 1SX7 | A:1-164 | USE OF AN ION-BINDING SITE TO BYPASS THE 1000-ATOM LIMIT TO AB INITIO STRUCTURE DETERMINATION BY DIRECT METHODS |
| 1T6H | A:1-164 | CRYSTAL STRUCTURE T4 LYSOZYME INCORPORATING AN UNNATURAL AMINO ACID P-IODO-L-PHENYLALANINE AT POSITION 153 |
| 1T8A | A:1-175 | USE OF SEQUENCE DUPLICATION TO ENGINEER A LIGAND-TRIGGERED LONG-DISTANCE MOLECULAR SWITCH IN T4 LYSOSYME |
| 1T8F | A:1-162 | CRYSTAL STRUCTURE OF PHAGE T4 LYSOZYME MUTANT R14A/K16A/I17A/K19A/T21A/E22A/C54T/C97A |
| 1T8G | A:1-162 | CRYSTAL STRUCTURE OF PHAGE T4 LYSOZYME MUTANT L32A/L33A/T34A/C54T/C97A/E108V |
| 1T97 | A:1-173; B:1-173 | USE OF SEQUENCE DUPLICATION TO ENGINEER A LIGAND-TRIGGERED LONG-DISTANCE MOLECULAR SWITCH IN T4 LYSOSYME |
| 1WTH | A:174-342 | CRYSTAL STRUCTURE OF GP5-S351L MUTANT AND GP27 COMPLEX |
| 1XEP | A:1-162 | CATECHOL IN COMPLEX WITH T4 LYSOZYME L99A/M102Q |
| 209L | A:1-162 | PROTEIN STRUCTURE PLASTICITY EXEMPLIFIED BY INSERTION AND DELETION MUTANTS IN T4 LYSOZYME |
| 210L | A:1-162 | PROTEIN STRUCTURE PLASTICITY EXEMPLIFIED BY INSERTION AND DELETION MUTANTS IN T4 LYSOZYME |
| 211L | A:1-162 | PROTEIN STRUCTURE PLASTICITY EXEMPLIFIED BY INSERTION AND DELETION MUTANTS IN T4 LYSOZYME |
| 212L | A:1-168 | PROTEIN STRUCTURE PLASTICITY EXEMPLIFIED BY INSERTION AND DELETION MUTANTS IN T4 LYSOZYME |
| 213L | A:1-162 | PROTEIN STRUCTURE PLASTICITY EXEMPLIFIED BY INSERTION AND DELETION MUTANTS IN T4 LYSOZYME |
| 214L | A:1-162 | PROTEIN STRUCTURE PLASTICITY EXEMPLIFIED BY INSERTION AND DELETION MUTANTS IN T4 LYSOZYME |
| 215L | A:1-162 | PROTEIN STRUCTURE PLASTICITY EXEMPLIFIED BY INSERTION AND DELETION MUTANTS IN T4 LYSOZYME |
| 218L | A:1-162 | PROTEIN STRUCTURE PLASTICITY EXEMPLIFIED BY INSERTION AND DELETION MUTANTS IN T4 LYSOZYME |
| 219L | A:1-164 | PROTEIN STRUCTURE PLASTICITY EXEMPLIFIED BY INSERTION AND DELETION MUTANTS IN T4 LYSOZYME |
| 220L | A:1-162 | GENERATING LIGAND BINDING SITES IN T4 LYSOZYME USING DEFICIENCY-CREATING SUBSTITUTIONS |
| 222L | A:1-162 | GENERATING LIGAND BINDING SITES IN T4 LYSOZYME USING DEFICIENCY-CREATING SUBSTITUTIONS |
| 223L | A:1-162 | GENERATING LIGAND BINDING SITES IN T4 LYSOZYME USING DEFICIENCY-CREATING SUBSTITUTIONS |
| 225L | A:1-162 | GENERATING LIGAND BINDING SITES IN T4 LYSOZYME USING DEFICIENCY-CREATING SUBSTITUTIONS |
| 226L | A:1-162 | GENERATING LIGAND BINDING SITES IN T4 LYSOZYME USING DEFICIENCY-CREATING SUBSTITUTIONS |
| 227L | A:1-162 | GENERATING LIGAND BINDING SITES IN T4 LYSOZYME USING DEFICIENCY-CREATING SUBSTITUTIONS |
| 228L | A:1-162 | GENERATING LIGAND BINDING SITES IN T4 LYSOZYME USING DEFICIENCY-CREATING SUBSTITUTIONS |
| 229L | A:1-162 | GENERATING LIGAND BINDING SITES IN T4 LYSOZYME USING DEFICIENCY-CREATING SUBSTITUTIONS |
| 231L | A:1-162 | T4 LYSOZYME MUTANT M106K |
| 235L | A:1-162 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 236L | A:1-162 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 237L | A:1-164 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 238L | A:1-162 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 239L | A:1-162 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 240L | A:1-162 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 241L | A:1-162 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 242L | A:1-164 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 243L | A:1-162 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 245L | A:1-164 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 246L | A:1-164 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 247L | A:1-164 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 248L | A:1-162 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 249L | A:1-164 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 250L | A:1-162 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 251L | A:1-162 | THE RESPONSE OF T4 LYSOZYME TO LARGE-TO-SMALL SUBSTITUTIONS WITHIN THE CORE AND ITS RELATION TO THE HYDROPHOBIC EFFECT |
| 252L | A:1-164 | GENERATING LIGAND BINDING SITES IN T4 LYSOZYME USING DEFICIENCY-CREATING SUBSTITUTIONS |
| 253L | A:1-164 | LYSOZYME |
| 254L | A:1-164 | LYSOZYME |
| 255L | A:1-164 | HYDROLASE |
| 257L | A:1-162 | AN ADAPTABLE METAL-BINDING SITE ENGINEERED INTO T4 LYSOZYME |
| 258L | A:1-163 | AN ADAPTABLE METAL-BINDING SITE ENGINEERED INTO T4 LYSOZYME |
| 259L | A:1-162 | AN ADAPTABLE METAL-BINDING SITE ENGINEERED INTO T4 LYSOZYME |
| 260L | A:1-162 | AN ADAPTABLE METAL-BINDING SITE ENGINEERED INTO T4 LYSOZYME |
| 261L | A:1-173 | STRUCTURAL CHARACTERISATION OF AN ENGINEERED TANDEM REPEAT CONTRASTS THE IMPORTANCE OF CONTEXT AND SEQUENCE IN PROTEIN FOLDING |
| 262L | A:1-173; B:1-173 | STRUCTURAL CHARACTERISATION OF AN ENGINEERED TANDEM REPEAT CONTRASTS THE IMPORTANCE OF CONTEXT AND SEQUENCE IN PROTEIN FOLDING |
| 2A4T | A:1-164 | CRYSTAL STRUCTURE OF SPIN LABELED T4 LYSOZYME (V131R7) |
| 2B6T | A:1-162 | T4 LYSOZYME MUTANT L99A AT 200 MPA |
| 2B6W | A:1-162 | T4 LYSOZYME MUTANT L99A AT 200 MPA |
| 2B6Z | A:1-162 | T4 LYSOZYME MUTANT L99A AT AMBIENT PRESSURE |
| 2B70 | A:1-162 | T4 LYSOZYME MUTANT L99A AT AMBIENT PRESSURE |
| 2B72 | A:1-162 | T4 LYSOZYME MUTANT L99A AT 100 MPA |
| 2B7X | D:1-168; A:1-168; B:1-168; C:1-168 | SEQUENTIAL REORGANIZATION OF BETA-SHEET TOPOLOGY BY INSERTION OF A SINGLE STRAND |
| 2F2Q | A:1-175 | HIGH RESOLUTION CRYSTAL STRCUTURE OF T4 LYSOSYME MUTANT L20R63/A LIGANDED TO GUANIDINIUM ION |
| 2F32 | A:1-175 | XRAY CRYSTAL STRUCTURE OF LYSOZYME MUTANT L20/R63A LIGANDED TO ETHYLGUANIDINIUM |
| 2F47 | A:1-175 | XRAY CRYSTAL STRUCTURE OF T4 LYSOZYME MUTANT L20/R63A LIGANDED TO METHYLGUANIDINIUM |
| 2HUK | A:1-164 | CRYSTAL STRUCTURE OF T4 LYSOZYME V131C SYNTHETIC DIMER |
| 2HUL | A:1-164 | CRYSTAL STRUCTURE OF T4 LYSOZYME S44C SYNTHETIC DIMER |
| 2HUM | A:1-164; B:1-164 | CRYSTAL STRUCTURE OF T4 LYSOZYME D72C SYNTHETIC DIMER |
| 2LZM | A:1-164 | STRUCTURE OF BACTERIOPHAGE T4 LYSOZYME REFINED AT 1.7 ANGSTROMS RESOLUTION |
| 2NTG | A:1-164 | STRUCTURE OF SPIN-LABELED T4 LYSOZYME MUTANT T115R7 |
| 2NTH | A:1-164 | STRUCTURE OF SPIN-LABELED T4 LYSOZYME MUTANT L118R1 |
| 2O79 | A:1-162 | T4 LYSOZYME WITH C-TERMINAL EXTENSION |
| 2OE4 | X:1-162 | HIGH PRESSURE PSUEDO WILD TYPE T4 LYSOZYME |
| 2OE7 | X:1-162 | HIGH-PRESSURE T4 LYSOZYME |
| 2OE9 | X:1-162 | HIGH-PRESSURE STRUCTURE OF PSEUDO-WT T4 LYSOZYME |
| 2OEA | X:1-162 | HIGH-PRESSURE STRUCTURE OF PSEUDO-WT T4 LYSOZYME |
| 2OTY | X:1-162 | 1,2-DICHLOROBENZENE IN COMPLEX WITH T4 LYSOZYME L99A |
| 2OTZ | X:1-162 | N-METHYLANILINE IN COMPLEX WITH T4 LYSOZYME L99A |
| 2OU0 | X:1-162 | 1-METHYLPYRROLE IN COMPLEX WITH T4 LYSOZYME L99A |
| 2OU8 | A:1-164 | STRUCTURE OF SPIN-LABELED T4 LYSOZYME MUTANT T115R1 AT ROOM TEMPERATURE |
| 2OU9 | A:1-164 | STRUCTURE OF SPIN-LABELED T4 LYSOZYME MUTANT T115R1/R119A |
| 2Q9D | A:1-164 | STRUCTURE OF SPIN-LABELED T4 LYSOZYME MUTANT A41R1 |
| 2Q9E | A:1-164; B:1-164; C:1-164 | STRUCTURE OF SPIN-LABELED T4 LYSOZYME MUTANT S44R1 |
| 2RAY | X:1-162 | BETA-CHLOROPHENETOLE IN COMPLEX WITH T4 LYSOZYME L99A |
| 2RAZ | X:1-162 | 4-(METHYLTHIO)NITROBENZENE IN COMPLEX WITH T4 LYSOZYME L99A |
| 2RB0 | X:1-162 | 2,6-DIFLUOROBENZYLBROMIDE COMPLEX WITH T4 LYSOZYME L99A |
| 2RB2 | X:1-162 | 3-METHYLBENZYLAZIDE IN COMPLEX WITH T4 LYSOZYME L99A |
| 2RBN | A:1-162 | N-PHENYLGLYCINONITRILE IN COMPLEX WITH T4 LYSOZYME L99A/M102Q |
| 2RBO | A:1-162 | 2-NITROTHIOPHENE IN COMPLEX WITH T4 LYSOZYME L99A/M102Q |
| 2RBP | A:1-162 | 2-(N-PROPYLTHIO)ETHANOL IN COMPLEX WITH T4 LYSOZYME L99A/M102Q |
| 2RBQ | A:1-162 | 3-METHYLBENZYLAZIDE IN COMPLEX WITH T4 L99A/M102Q |
| 2RBR | A:1-162 | 2-PHENOXYETHANOL IN COMPLEX WITH T4 LYSOZYME L99A/M102Q |
| 2RBS | A:1-162 | (R)(+)-3-CHLORO-1-PHENYL-1-PROPANOL IN COMPLEX WITH T4 LYSOZYME L99A/M102Q |
| 2Z6B | A:174-342 | CRYSTAL STRUCTURE ANALYSIS OF (GP27-GP5)3 CONJUGATED WITH FE(III) PROTOPORPHYRIN |
| 3GUI | A:1-162 | T4 LYSOZYME M102E/L99A MUTANT WITH BURIED CHARGE IN APOLAR CAVITY--APO STRUCTURE |
| 3GUJ | A:1-162 | T4 LYSOZYME M102E/L99A MUTANT WITH BURIED CHARGE IN APOLAR CAVITY--BENZENE BINDING |
| 3GUK | A:1-162; B:1-162 | T4 LYSOZYME M102E/L99A MUTANT WITH BURIED CHARGE IN APOLAR CAVITY--TOLUENE BINDING |
| 3GUL | A:1-162; B:1-162 | T4 LYSOZYME M102E/L99A MUTANT WITH BURIED CHARGE IN APOLAR CAVITY--ETHYLBENZENE BINDING |
| 3GUM | A:1-162; B:1-162 | T4 LYSOZYME M102E/L99A MUTANT WITH BURIED CHARGE IN APOLAR CAVITY--P-XYLENE BINDING |
| 3GUN | A:1-162; B:1-162 | T4 LYSOZYME M102E/L99A MUTANT WITH BURIED CHARGE IN APOLAR CAVITY--ANILINE BINDING |
| 3GUO | A:1-162; B:1-162 | T4 LYSOZYME M102E/L99A MUTANT WITH BURIED CHARGE IN APOLAR CAVITY--PHENOL BINDING |
| 3GUP | A:1-162; B:1-162 | T4 LYSOZYME M102E/L99A MUTANT WITH BURIED CHARGE IN APOLAR CAVITY--PYRIDINE BINDING |
| 3HH3 | A:1-164 | NEW AZABORINE COMPOUNDS BIND TO THE T4 LYSOZYME L99A CAVITY - 1,2-DIHYDRO-1,2-AZABORINE |
| 3HH4 | A:1-164 | NEW AZABORINE COMPOUNDS BIND TO THE T4 LYSOZYME L99A CAVITY - BENZENE AS CONTROL |
| 3HH5 | A:1-164 | NEW AZABORINE COMPOUNDS BIND TO THE T4 LYSOZYME L99A CAVITY - 1-ETHYL-2-HYDRO-1,2-AZABORINE |
| 3HH6 | A:1-163 | NEW AZABORINE COMPOUNDS BIND TO THE T4 LYSOZYME L99A CAVITY - ETHYLBENZENE AS CONTROL |
| 3HWL | A:1-162 | CRYSTAL STRUCTURE OF T4 LYSOZYME WITH THE UNNATURAL AMINO ACID P-ACETYL-L-PHENYLALANINE INCORPORATED AT POSITION 131 |
| 3LZM | A:1-164 | STRUCTURAL STUDIES OF MUTANTS OF T4 LYSOZYME THAT ALTER HYDROPHOBIC STABILIZATION |
| 4LZM | A:1-162 | COMPARISON OF THE CRYSTAL STRUCTURE OF BACTERIOPHAGE T4 LYSOZYME AT LOW, MEDIUM, AND HIGH IONIC STRENGTHS |
| 5LZM | A:1-162 | COMPARISON OF THE CRYSTAL STRUCTURE OF BACTERIOPHAGE T4 LYSOZYME AT LOW, MEDIUM, AND HIGH IONIC STRENGTHS |
| 6LZM | A:1-162 | COMPARISON OF THE CRYSTAL STRUCTURE OF BACTERIOPHAGE T4 LYSOZYME AT LOW, MEDIUM, AND HIGH IONIC STRENGTHS |
| 7LZM | A:1-162 | COMPARISON OF THE CRYSTAL STRUCTURE OF BACTERIOPHAGE T4 LYSOZYME AT LOW, MEDIUM, AND HIGH IONIC STRENGTHS |
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