0.016340 0.009434 0.000000 0.000000 0.018868 0.000000 0.000000 0.000000 0.010341 0.00000 0.00000 0.00000 RESIDUES 162 - 164 IN WILD-TYPE AND ALL MUTANT LYSOZYMES ARE EXTREMELY MOBILE. THUS THE COORDINATES FOR THESE RESIDUES ARE VERY UNRELIABLE. THIS ENTRY DOES NOT INCLUDE RESIDUES 163 AND 164. SG SEO 54 IS BONDED TO SG CYS 54 AND SG SEO 97 IS BONDED TO SG CYS 97. SEO 900 IS BONDED TO ANOTHER SEO FROM A DIFFERENT ASYMMETRIC UNIT. Bell, J.A. Wilson, K. Zhang, X.-J. Faber, H.R. Nicholson, H. Matthews, B.W. http://mmcif.pdb.org/dictionaries/ascii/mmcif_pdbx.dic 6 90.00 90.00 120.00 61.200 61.200 96.700 C3 H7 N O2 89.093 y ALANINE L-peptide linking C6 H15 N4 O2 1 175.209 y ARGININE L-peptide linking C4 H8 N2 O3 132.118 y ASPARAGINE L-peptide linking C4 H7 N O4 133.103 y ASPARTIC ACID L-peptide linking C2 H6 O S 78.133 BETA-MERCAPTOETHANOL non-polymer Cl -1 35.453 CHLORIDE ION non-polymer C3 H7 N O2 S 121.158 y CYSTEINE L-peptide linking C5 H10 N2 O3 146.144 y GLUTAMINE L-peptide linking C5 H9 N O4 147.129 y GLUTAMIC ACID L-peptide linking C2 H5 N O2 75.067 y GLYCINE peptide linking C6 H10 N3 O2 1 156.162 y HISTIDINE L-peptide linking H2 O 18.015 WATER non-polymer C6 H13 N O2 131.173 y ISOLEUCINE L-peptide linking C6 H13 N O2 131.173 y LEUCINE L-peptide linking C6 H15 N2 O2 1 147.195 y LYSINE L-peptide linking C5 H11 N O2 S 149.211 y METHIONINE L-peptide linking C9 H11 N O2 165.189 y PHENYLALANINE L-peptide linking C5 H9 N O2 115.130 y PROLINE L-peptide linking C3 H7 N O3 105.093 y SERINE L-peptide linking C4 H9 N O3 119.119 y THREONINE L-peptide linking C11 H12 N2 O2 204.225 y TRYPTOPHAN L-peptide linking C9 H11 N O3 181.189 y TYROSINE L-peptide linking C5 H11 N O2 117.146 y VALINE L-peptide linking US Proteins PSFGEY 0867 0887-3585 10 10 21 10.1002/prot.340100103 2062826 Comparison of the crystal structure of bacteriophage T4 lysozyme at low, medium, and high ionic strengths. 1991 To be Published 0353 The Structural and Thermodynamic Consequences of Burying a Charged Residue within the Hydrophobic Core of T4 Lysozyme To be Published 0353 The Structure of a "Hinge-Bending" T4 Lysozyme Mutant, Il3 3-> Pro To be Published 0353 Multiple Replacements of Leu 99 and Phe 153 within the Hydrophobic Core of T4 Lysozyme Have Different Structural and Thermodynamic Consequences US Proc.Natl.Acad.Sci.USA PNASA6 0040 0027-8424 89 3751 Folding and Function of a T4 Lysozyme Containing 10 Consecutive Alanines Illustrate the Redundancy of Information in an Amino Acid Sequence 1992 US Science SCIEAS 0038 0036-8075 255 178 Response of a Protein Structure to Cavity-Creating Mutations and its Relation to the Hydrophobic Effect 1992 UK Nature NATUAS 0006 0028-0836 355 371 A Cavity-Containing Mutant of T4 Lysozyme is Stabilized by Buried Benzene 1992 US J.Biol.Chem. JBCHA3 0071 0021-9258 267 2393 Tolerance of T4 Lysozyme to Proline Substitutions within the Long Interdomain Alpha-Helix Illustrates the Adaptability of Proteins to Potentially Destabilizing Lesions 1992 UK J.Mol.Biol. JMOBAK 0070 0022-2836 221 873 Cumulative Site-Directed Charge-Change Replacements in Bacteriophage T4 Lysozyme Suggest that Long-Range Electrostatic Interactions Contribute Little to Protein Stability 1991 US Biochemistry BICHAW 0033 0006-2960 30 9816 Analysis of the Interaction between Charged Side Chains and the Alpha-Helix Dipole Using Designed Thermostable Mutants of Phage T4 Lysozyme 1991 UK J.Mol.Biol. JMOBAK 0070 0022-2836 221 647 Structural and Thermodynamic Analysis of the Packing of Two Alpha-Helices in Bacteriophage T4 Lysozyme 1991 US Biochemistry BICHAW 0033 0006-2960 30 7142 Contributions of Engineered Surface Salt Bridges to the Stability of T4 Lysozyme Determined by Directed Mutagenesis 1991 US Biochemistry BICHAW 0033 0006-2960 30 2012 Toward a Simplification of the Protein Folding Problem: A Stabilizing Polyalanine Alpha-Helix Engineered in T4 Lysozyme 1991 US Biochemistry BICHAW 0033 0006-2960 29 2592 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 1990 US J.Biol.Chem. JBCHA3 0071 0021-9258 264 16059 Structural Studies of Mutants of T4 Lysozyme that Alter Hydrophobic Stabilization 1989 US Biochemistry BICHAW 0033 0006-2960 28 3793 High-Resolution Structure of the Temperature-Sensitive Mutant of Phage Lysozyme, Arg 96 (Right Arrow) His 1989 UK J.Mol.Biol. JMOBAK 0070 0022-2836 210 181 Contributions of Left-Handed Helical Residues to the Structure and Stability of Bacteriophage T4 Lysozyme 1989 UK Nature NATUAS 0006 0028-0836 334 406 Hydrophobic Stabilization in T4 Lysozyme Determined Directly by Multiple Substitutions of Ile 3 1988 UK Nature NATUAS 0006 0028-0836 336 651 Enhanced Protein Thermostability from Designed Mutations that Interact with Alpha-Helix Dipoles 1988 US Science SCIEAS 0038 0036-8075 239 631 Replacements of Pro86 in Phage T4 Lysozyme Extend an Alpha-Helix But Do not Alter Protein Stability 1988 US Proc.Natl.Acad.Sci.USA PNASA6 0040 0027-8424 84 6663 Enhanced Protein Thermostability from Site-Directed Mutations that Decrease the Entropy of Unfolding 1987 US J.Biol.Chem. JBCHA3 0071 0021-9258 262 16858 Structural Analysis of the Temperature-Sensitive Mutant of Bacteriophage T4 Lysozyme, Glycine 156 (Right Arrow) Aspartic Acid 1987 UK Nature NATUAS 0006 0028-0836 330 41 Contributions of Hydrogen Bonds of Thr 157 to the Thermodynamic Stability of Phage T4 Lysozyme 1987 UK J.Mol.Biol. JMOBAK 0070 0022-2836 197 315 Structural Studies of Mutants of the Lysozyme of Bacteriophage T4. The Temperature-Sensitive Mutant Protein Thr157 (Right Arrow) Ile 1987 UK J.Mol.Biol. JMOBAK 0070 0022-2836 193 189 Structure of Bacteriophage T4 Lysozyme Refined at 1.7 Angstroms Resolution 1987 US Biochemistry BICHAW 0033 0006-2960 26 3754 Temperature-Sensitive Mutations of Bacteriophage T4 Lysozyme Occur at Sites with Low Mobility and Low Solvent Accessibility in the Folded Protein 1987 UK Nature NATUAS 0006 0028-0836 290 334 Common Precursor of Lysozymes of Hen Egg-White and Bacteriophage T4 1981 UK J.Mol.Biol. JMOBAK 0070 0022-2836 147 523 Crystallographic Determination of the Mode of Binding of Oligosaccharides to T4 Bacteriophage Lysozyme. Implications for the Mechanism of Catalysis 1981 UK J.Mol.Biol. JMOBAK 0070 0022-2836 147 545 Relation between Hen Egg White Lysozyme and Bacteriophage T4 Lysozyme. Evolutionary Implications 1981 UK J.Mol.Biol. JMOBAK 0070 0022-2836 118 81 Structure of the Lysozyme from Bacteriophage T4, an Electron Density Map at 2.4 Angstroms Resolution 1978 US Biochem.Biophys.Res.Commun. BBRCA9 0146 0006-291X 75 265 Atomic Coordinates for T4 Phage Lysozyme 1977 NE Biochim.Biophys.Acta BBACAQ 0113 0006-3002 405 442 Comparison of the Predicted and Observed Secondary Structure of T4 Phage Lysozyme 1975 US Proc.Natl.Acad.Sci.USA PNASA6 0040 0027-8424 71 4178 The Three Dimensional Structure of the Lysozyme from Bacteriophage T4 1974 UK J.Mol.Biol. JMOBAK 0070 0022-2836 78 575 Crystallographic Data for Lysozyme from Bacteriophage T4 1973 To be Published 0353 1.000000 0.000000 0.000000 0.000000 1.000000 0.000000 0.000000 0.000000 1.000000 0.00000 0.00000 0.00000 101 298 1 Kodak No-Screen X-ray film FILM OSCILLATION CAMERA graphite SINGLE WAVELENGTH M x-ray 1.5418 1 1.0 ROTATING ANODE Cu ELLIOTT GX-21 40 18662.467 T4 LYSOZYME 3.2.1.17 1 man polymer 35.453 CHLORIDE ION 2 syn non-polymer 78.133 BETA-MERCAPTOETHANOL 3 syn non-polymer 18.015 water 119 nat water no no MNIFEMLRIDEGLRLKIYKDTEGYYTIGIGHLLTKSPSLNAAKSELDKAIGRNCNGVITKDEAEKLFNQDVDAAVRGILR NAKLKPVYDSLDAVRRCALINMVFQMGETGVAGFTNSLRMLQQKRWDEAAVNLAKSRWYNQTPNRAKRVITTFRTGTWDA YKNL MNIFEMLRIDEGLRLKIYKDTEGYYTIGIGHLLTKSPSLNAAKSELDKAIGRNCNGVITKDEAEKLFNQDVDAAVRGILR NAKLKPVYDSLDAVRRCALINMVFQMGETGVAGFTNSLRMLQQKRWDEAAVNLAKSRWYNQTPNRAKRVITTFRTGTWDA YKNL A polypeptide(L) n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n n T4-like viruses Enterobacteria phage T4 sensu lato sample 10665 EGG Enterobacteria phage T4 2.80 56.08 pdbx_database_status struct_conf struct_conf_type diffrn diffrn_detector diffrn_radiation diffrn_radiation_wavelength diffrn_source pdbx_database_status software struct_conn diffrn_detector diffrn_source struct_site repository Initial release Version format compliance Version format compliance Derived calculations Other Data collection Derived calculations Other Refinement description Data collection Derived calculations 1 0 1992-07-15 1 1 2008-03-25 1 2 2011-07-13 1 3 2017-11-29 1 4 2020-07-22 1 5 2021-06-30 _pdbx_database_status.process_site _pdbx_database_status.status_code_sf _struct_conn.pdbx_leaving_atom_flag _diffrn_detector.detector _diffrn_source.source _struct_site.pdbx_auth_asym_id _struct_site.pdbx_auth_comp_id _struct_site.pdbx_auth_seq_id SHEET THERE ARE SEVERAL SUBTLE ASPECTS OF THE SECONDARY STRUCTURE OF THIS MOLECULE WHICH CANNOT CONVENIENTLY BE REPRESENTED IN THE HELIX AND SHEET RECORDS BELOW. THESE ASPECTS INFLUENCE THE REPRESENTATION OF HELIX 6 AND STRAND 3 OF SHEET *S1*. THE 1978 S.J.REMINGTON ET AL. PAPER SHOULD BE CONSULTED FOR THESE SUBTLETIES. Y BNL 1991-01-25 REL REL CL CHLORIDE ION BME BETA-MERCAPTOETHANOL HOH water CL 173 2 CL CL 173 A CL 178 2 CL CL 178 A SEO 54 3 BME BME 179 A SEO 97 3 BME BME 180 A SEO 900 3 BME BME 900 A HOH 171 4 HOH HOH 901 A HOH 172 4 HOH HOH 902 A HOH 174 4 HOH HOH 903 A HOH 175 4 HOH HOH 904 A HOH 176 4 HOH HOH 905 A HOH 177 4 HOH HOH 906 A HOH 179 4 HOH HOH 907 A HOH 180 4 HOH HOH 908 A HOH 181 4 HOH HOH 909 A HOH 182 4 HOH HOH 910 A HOH 183 4 HOH HOH 911 A HOH 185 4 HOH HOH 912 A HOH 186 4 HOH HOH 913 A HOH 187 4 HOH HOH 914 A HOH 188 4 HOH HOH 915 A HOH 189 4 HOH HOH 916 A HOH 190 4 HOH HOH 917 A HOH 191 4 HOH HOH 918 A HOH 192 4 HOH HOH 919 A HOH 193 4 HOH HOH 920 A HOH 195 4 HOH HOH 921 A HOH 198 4 HOH HOH 922 A HOH 200 4 HOH HOH 923 A HOH 201 4 HOH HOH 924 A HOH 202 4 HOH HOH 925 A HOH 203 4 HOH HOH 926 A HOH 206 4 HOH HOH 927 A HOH 208 4 HOH HOH 928 A HOH 209 4 HOH HOH 929 A HOH 211 4 HOH HOH 930 A HOH 212 4 HOH HOH 931 A HOH 213 4 HOH HOH 932 A HOH 214 4 HOH HOH 933 A HOH 215 4 HOH HOH 934 A HOH 216 4 HOH HOH 935 A HOH 217 4 HOH HOH 936 A HOH 218 4 HOH HOH 937 A HOH 219 4 HOH HOH 938 A HOH 220 4 HOH HOH 939 A HOH 221 4 HOH HOH 940 A HOH 223 4 HOH HOH 941 A HOH 224 4 HOH HOH 942 A HOH 226 4 HOH HOH 943 A HOH 227 4 HOH HOH 944 A HOH 228 4 HOH HOH 945 A HOH 231 4 HOH HOH 946 A HOH 232 4 HOH HOH 947 A HOH 233 4 HOH HOH 948 A HOH 234 4 HOH HOH 949 A HOH 235 4 HOH HOH 950 A HOH 237 4 HOH HOH 951 A HOH 238 4 HOH HOH 952 A HOH 239 4 HOH HOH 953 A HOH 240 4 HOH HOH 954 A HOH 242 4 HOH HOH 955 A HOH 244 4 HOH HOH 956 A HOH 246 4 HOH HOH 957 A HOH 247 4 HOH HOH 958 A HOH 248 4 HOH HOH 959 A HOH 249 4 HOH HOH 960 A HOH 251 4 HOH HOH 961 A HOH 256 4 HOH HOH 962 A HOH 262 4 HOH HOH 963 A HOH 266 4 HOH HOH 964 A HOH 268 4 HOH HOH 965 A HOH 270 4 HOH HOH 966 A HOH 273 4 HOH HOH 967 A HOH 274 4 HOH HOH 968 A HOH 277 4 HOH HOH 969 A HOH 278 4 HOH HOH 970 A HOH 279 4 HOH HOH 971 A HOH 280 4 HOH HOH 972 A HOH 281 4 HOH HOH 973 A HOH 282 4 HOH HOH 974 A HOH 283 4 HOH HOH 975 A HOH 284 4 HOH HOH 976 A HOH 285 4 HOH HOH 977 A HOH 287 4 HOH HOH 978 A HOH 288 4 HOH HOH 979 A HOH 291 4 HOH HOH 980 A HOH 293 4 HOH HOH 981 A HOH 295 4 HOH HOH 982 A HOH 298 4 HOH HOH 983 A HOH 299 4 HOH HOH 984 A HOH 300 4 HOH HOH 985 A HOH 301 4 HOH HOH 986 A HOH 309 4 HOH HOH 987 A HOH 311 4 HOH HOH 988 A HOH 312 4 HOH HOH 989 A HOH 313 4 HOH HOH 990 A HOH 314 4 HOH HOH 991 A HOH 315 4 HOH HOH 992 A HOH 316 4 HOH HOH 993 A HOH 317 4 HOH HOH 994 A HOH 318 4 HOH HOH 995 A HOH 319 4 HOH HOH 996 A HOH 320 4 HOH HOH 997 A HOH 321 4 HOH HOH 998 A HOH 322 4 HOH HOH 999 A HOH 323 4 HOH HOH 1000 A HOH 324 4 HOH HOH 1001 A HOH 325 4 HOH HOH 1002 A HOH 326 4 HOH HOH 1003 A HOH 327 4 HOH HOH 1004 A HOH 328 4 HOH HOH 1005 A HOH 329 4 HOH HOH 1006 A HOH 330 4 HOH HOH 1007 A HOH 331 4 HOH HOH 1008 A HOH 332 4 HOH HOH 1009 A HOH 333 4 HOH HOH 1010 A HOH 334 4 HOH HOH 1011 A HOH 335 4 HOH HOH 1012 A HOH 336 4 HOH HOH 1013 A HOH 337 4 HOH HOH 1014 A HOH 338 4 HOH HOH 1015 A HOH 339 4 HOH HOH 1016 A HOH 340 4 HOH HOH 1017 A HOH 341 4 HOH HOH 1018 A HOH 342 4 HOH HOH 1019 A MET 1 n 1 MET 1 A ASN 2 n 2 ASN 2 A ILE 3 n 3 ILE 3 A PHE 4 n 4 PHE 4 A GLU 5 n 5 GLU 5 A MET 6 n 6 MET 6 A LEU 7 n 7 LEU 7 A ARG 8 n 8 ARG 8 A ILE 9 n 9 ILE 9 A ASP 10 n 10 ASP 10 A GLU 11 n 11 GLU 11 A GLY 12 n 12 GLY 12 A LEU 13 n 13 LEU 13 A ARG 14 n 14 ARG 14 A LEU 15 n 15 LEU 15 A LYS 16 n 16 LYS 16 A ILE 17 n 17 ILE 17 A TYR 18 n 18 TYR 18 A LYS 19 n 19 LYS 19 A ASP 20 n 20 ASP 20 A THR 21 n 21 THR 21 A GLU 22 n 22 GLU 22 A GLY 23 n 23 GLY 23 A TYR 24 n 24 TYR 24 A TYR 25 n 25 TYR 25 A THR 26 n 26 THR 26 A ILE 27 n 27 ILE 27 A GLY 28 n 28 GLY 28 A ILE 29 n 29 ILE 29 A GLY 30 n 30 GLY 30 A HIS 31 n 31 HIS 31 A LEU 32 n 32 LEU 32 A LEU 33 n 33 LEU 33 A THR 34 n 34 THR 34 A LYS 35 n 35 LYS 35 A SER 36 n 36 SER 36 A PRO 37 n 37 PRO 37 A SER 38 n 38 SER 38 A LEU 39 n 39 LEU 39 A ASN 40 n 40 ASN 40 A ALA 41 n 41 ALA 41 A ALA 42 n 42 ALA 42 A LYS 43 n 43 LYS 43 A SER 44 n 44 SER 44 A GLU 45 n 45 GLU 45 A LEU 46 n 46 LEU 46 A ASP 47 n 47 ASP 47 A LYS 48 n 48 LYS 48 A ALA 49 n 49 ALA 49 A ILE 50 n 50 ILE 50 A GLY 51 n 51 GLY 51 A ARG 52 n 52 ARG 52 A ASN 53 n 53 ASN 53 A CYS 54 n 54 CYS 54 A ASN 55 n 55 ASN 55 A GLY 56 n 56 GLY 56 A VAL 57 n 57 VAL 57 A ILE 58 n 58 ILE 58 A THR 59 n 59 THR 59 A LYS 60 n 60 LYS 60 A ASP 61 n 61 ASP 61 A GLU 62 n 62 GLU 62 A ALA 63 n 63 ALA 63 A GLU 64 n 64 GLU 64 A LYS 65 n 65 LYS 65 A LEU 66 n 66 LEU 66 A PHE 67 n 67 PHE 67 A ASN 68 n 68 ASN 68 A GLN 69 n 69 GLN 69 A ASP 70 n 70 ASP 70 A VAL 71 n 71 VAL 71 A ASP 72 n 72 ASP 72 A ALA 73 n 73 ALA 73 A ALA 74 n 74 ALA 74 A VAL 75 n 75 VAL 75 A ARG 76 n 76 ARG 76 A GLY 77 n 77 GLY 77 A ILE 78 n 78 ILE 78 A LEU 79 n 79 LEU 79 A ARG 80 n 80 ARG 80 A ASN 81 n 81 ASN 81 A ALA 82 n 82 ALA 82 A LYS 83 n 83 LYS 83 A LEU 84 n 84 LEU 84 A LYS 85 n 85 LYS 85 A PRO 86 n 86 PRO 86 A VAL 87 n 87 VAL 87 A TYR 88 n 88 TYR 88 A ASP 89 n 89 ASP 89 A SER 90 n 90 SER 90 A LEU 91 n 91 LEU 91 A ASP 92 n 92 ASP 92 A ALA 93 n 93 ALA 93 A VAL 94 n 94 VAL 94 A ARG 95 n 95 ARG 95 A ARG 96 n 96 ARG 96 A CYS 97 n 97 CYS 97 A ALA 98 n 98 ALA 98 A LEU 99 n 99 LEU 99 A ILE 100 n 100 ILE 100 A ASN 101 n 101 ASN 101 A MET 102 n 102 MET 102 A VAL 103 n 103 VAL 103 A PHE 104 n 104 PHE 104 A GLN 105 n 105 GLN 105 A MET 106 n 106 MET 106 A GLY 107 n 107 GLY 107 A GLU 108 n 108 GLU 108 A THR 109 n 109 THR 109 A GLY 110 n 110 GLY 110 A VAL 111 n 111 VAL 111 A ALA 112 n 112 ALA 112 A GLY 113 n 113 GLY 113 A PHE 114 n 114 PHE 114 A THR 115 n 115 THR 115 A ASN 116 n 116 ASN 116 A SER 117 n 117 SER 117 A LEU 118 n 118 LEU 118 A ARG 119 n 119 ARG 119 A MET 120 n 120 MET 120 A LEU 121 n 121 LEU 121 A GLN 122 n 122 GLN 122 A GLN 123 n 123 GLN 123 A LYS 124 n 124 LYS 124 A ARG 125 n 125 ARG 125 A TRP 126 n 126 TRP 126 A ASP 127 n 127 ASP 127 A GLU 128 n 128 GLU 128 A ALA 129 n 129 ALA 129 A ALA 130 n 130 ALA 130 A VAL 131 n 131 VAL 131 A ASN 132 n 132 ASN 132 A LEU 133 n 133 LEU 133 A ALA 134 n 134 ALA 134 A LYS 135 n 135 LYS 135 A SER 136 n 136 SER 136 A ARG 137 n 137 ARG 137 A TRP 138 n 138 TRP 138 A TYR 139 n 139 TYR 139 A ASN 140 n 140 ASN 140 A GLN 141 n 141 GLN 141 A THR 142 n 142 THR 142 A PRO 143 n 143 PRO 143 A ASN 144 n 144 ASN 144 A ARG 145 n 145 ARG 145 A ALA 146 n 146 ALA 146 A LYS 147 n 147 LYS 147 A ARG 148 n 148 ARG 148 A VAL 149 n 149 VAL 149 A ILE 150 n 150 ILE 150 A THR 151 n 151 THR 151 A THR 152 n 152 THR 152 A PHE 153 n 153 PHE 153 A ARG 154 n 154 ARG 154 A THR 155 n 155 THR 155 A GLY 156 n 156 GLY 156 A THR 157 n 157 THR 157 A TRP 158 n 158 TRP 158 A ASP 159 n 159 ASP 159 A ALA 160 n 160 ALA 160 A TYR 161 n 161 TYR 161 A LYS 162 n 162 LYS 162 A n 163 163 A n 164 164 A author_defined_assembly 1 monomeric 1.0000000000 0.0000000000 0.0000000000 0.0000000000 1.0000000000 0.0000000000 0.0000000000 0.0000000000 1.0000000000 1_555 x,y,z identity operation 0.0000000000 0.0000000000 0.0000000000 A N ILE 58 A N ILE 58 A O LEU 15 A O LEU 15 A N ASP 20 A N ASP 20 A O TYR 24 A O TYR 24 A O ILE 27 A O ILE 27 A N HIS 31 A N HIS 31 1 A ASN 163 A ASN 163 1 Y 1 A LEU 164 A LEU 164 1 Y 1 A A CL O CL HOH 173 980 1.54 1 -5.44 0.90 118.30 112.86 A A A CB CG OD2 ASP ASP ASP 10 10 10 N 1 6.29 0.90 118.30 124.59 A A A CB CG OD2 ASP ASP ASP 20 20 20 N 1 6.87 0.90 118.30 125.17 A A A CB CG OD1 ASP ASP ASP 47 47 47 N 1 -7.33 0.90 118.30 110.97 A A A CB CG OD2 ASP ASP ASP 47 47 47 N 1 -5.50 0.90 118.30 112.80 A A A CB CG OD2 ASP ASP ASP 70 70 70 N 1 3.21 0.50 120.30 123.51 A A A NE CZ NH1 ARG ARG ARG 80 80 80 N 1 3.70 0.50 120.30 124.00 A A A NE CZ NH1 ARG ARG ARG 119 119 119 N 1 6.22 0.50 120.30 126.52 A A A NE CZ NH1 ARG ARG ARG 125 125 125 N 1 -5.60 0.50 120.30 114.70 A A A NE CZ NH2 ARG ARG ARG 125 125 125 N 1 -3.72 0.60 121.00 117.28 A A A CB CG CD1 TYR TYR TYR 139 139 139 N 1 -9.97 1.40 123.60 113.63 A A A CD NE CZ ARG ARG ARG 145 145 145 N 1 9.13 1.40 123.60 132.73 A A A CD NE CZ ARG ARG ARG 154 154 154 N 1 6.38 0.50 120.30 126.68 A A A NE CZ NH1 ARG ARG ARG 154 154 154 N 1 A A O O HOH HOH 979 979 2.00 1_555 5_555 1 A PHE 114 -83.70 47.72 RESIDUES 162 - 164 IN WILD-TYPE AND ALL MUTANT LYSOZYMES ARE EXTREMELY MOBILE. THUS THE COORDINATES FOR THESE RESIDUES ARE VERY UNRELIABLE. THIS ENTRY DOES NOT INCLUDE RESIDUES 163 AND 164. 0.159 1.8 6.0 1 1.8 6.0 131 1425 2 0 1292 0.017 2.43 0.019 0.020 refinement TNT data scaling AGROVATA / ROTAVATA LYSOZYME (E.C.3.2.1.17) (MEDIUM SALT) COMPARISON OF THE CRYSTAL STRUCTURE OF BACTERIOPHAGE T4 LYSOZYME AT LOW, MEDIUM, AND HIGH IONIC STRENGTHS 1 N N 2 N N 2 N N 3 N N 3 N N 3 N N 4 N N A ILE 3 A ILE 3 HELX_P A GLU 11 A GLU 11 1 H1 9 A LEU 39 A LEU 39 HELX_P A ILE 50 A ILE 50 1 H2 12 A LYS 60 A LYS 60 HELX_P A ARG 80 A ARG 80 1 H3 21 A ALA 82 A ALA 82 HELX_P A SER 90 A SER 90 1 H4 9 A ALA 93 A ALA 93 HELX_P A MET 106 A MET 106 1 H5 14 A GLU 108 A GLU 108 HELX_P A GLY 113 A GLY 113 5 H6 6 A THR 115 A THR 115 HELX_P A GLN 123 A GLN 123 1 H7 9 A TRP 126 A TRP 126 HELX_P A ALA 134 A ALA 134 1 H8 9 A ARG 137 A ARG 137 HELX_P A GLN 141 A GLN 141 1 H9 5 A PRO 143 A PRO 143 HELX_P A THR 155 A THR 155 1 H10 13 covale 2.005 none A CYS 54 A SG CYS 54 1_555 A BME 179 D S2 BME 1_555 covale 2.068 none A CYS 97 A SG CYS 97 1_555 A BME 180 E S2 BME 1_555 covale 1.898 none A BME 900 F S2 BME 1_555 A BME 900 F S2 BME 5_555 HYDROLASE (O-GLYCOSYL) HYDROLASE (O-GLYCOSYL) LYS_BPT4 UNP 1 1 P00720 MNIFEMLRIDEGLRLKIYKDTEGYYTIGIGHLLTKSPSLNAAKSELDKAIGRNCNGVITKDEAEKLFNQDVDAAVRGILR NAKLKPVYDSLDAVRRCALINMVFQMGETGVAGFTNSLRMLQQKRWDEAAVNLAKSRWYNQTPNRAKRVITTFRTGTWDA YKNL 1 164 5LZM 1 164 P00720 A 1 1 164 4 anti-parallel anti-parallel anti-parallel A GLY 56 A GLY 56 A ILE 58 A ILE 58 A ARG 14 A ARG 14 A ASP 20 A ASP 20 A TYR 24 A TYR 24 A ILE 27 A ILE 27 A HIS 31 A HIS 31 A THR 34 A THR 34 BINDING SITE FOR RESIDUE CL A 173 A CL 173 Software 5 BINDING SITE FOR RESIDUE CL A 178 A CL 178 Software 1 BINDING SITE FOR RESIDUE BME A 179 A BME 179 Software 7 BINDING SITE FOR RESIDUE BME A 180 A BME 180 Software 6 BINDING SITE FOR RESIDUE BME A 900 A BME 900 Software 2 A THR 142 A THR 142 5 1_555 A ASN 144 A ASN 144 5 1_555 A ARG 145 A ARG 145 5 1_555 A HOH 929 G HOH 5 1_555 A HOH 980 G HOH 5 1_555 A HOH 934 G HOH 1 1_555 A ARG 52 A ARG 52 7 1_555 A ASN 53 A ASN 53 7 1_555 A CYS 54 A CYS 54 7 1_555 A VAL 57 A VAL 57 7 1_555 A ILE 58 A ILE 58 7 1_555 A THR 59 A THR 59 7 1_555 A GLU 62 A GLU 62 7 1_555 A ILE 3 A ILE 3 6 1_555 A ASN 68 A ASN 68 6 5_555 A ALA 93 A ALA 93 6 1_555 A CYS 97 A CYS 97 6 1_555 A BME 900 F BME 6 1_555 A HOH 921 G HOH 6 1_555 A ASP 72 A ASP 72 2 5_555 A BME 180 E BME 2 1_555 154 P 32 2 1