data_wwPDB_remediated_restraints_file_for_PDB_entry_1xbl # This wwPDB archive file contains, for PDB entry 1xbl: # # - Sequence information from the PDB mmCIF file # - NMR restraints from the PDB MR file # # In this file, the NMR restraints share the same atom names as in the coordinate # file, and in this way can differ from the data deposited at the wwPDB. To achieve # this aim, the NMR restraints were parsed from their original format files, and # the coordinates and NMR restraints information were subsequently harmonized. # # Due to the complexity of this harmonization process, minor modifications could # have occurred to the NMR restraints information, or data could have been lost # because of parsing or conversion errors. The PDB file remains the # authoritative reference for the atomic coordinates and the originally deposited # restraints files remain the primary reference for these data. # # This file is generated as part of the wwPDB at the BioMagResBank (BMRB) in # collaboration with the PDBe (formerly MSD) group at the European # Bioinformatics Institute (EBI) and the CMBI/IMM group at the Radboud # University of Nijmegen. # # Several software packages were used to produce this file: # # - Wattos (BMRB and CMBI/IMM). # - FormatConverter and NMRStarExport (PDBe). # - CCPN framework (http://www.ccpn.ac.uk/). # # More information about this process can be found in the references below. # Please cite the original reference for this PDB entry. # # JF Doreleijers, A Nederveen, W Vranken, J Lin, AM Bonvin, R Kaptein, JL # Markley, and EL Ulrich (2005). BioMagResBank databases DOCR and FRED # containing converted and filtered sets of experimental NMR restraints and # coordinates from over 500 protein PDB structures. J. Biomol. NMR 32, 1-12. # # WF Vranken, W Boucher, TJ Stevens, RH Fogh, A Pajon, M Llinas, EL Ulrich, JL # Markley, J Ionides, ED Laue (2005). The CCPN data model for NMR spectroscopy: # development of a software pipeline. Proteins 59, 687-696. # # JF Doreleijers, WF Vranken, C Schulte, J Lin, JR Wedell, CJ Penkett, GW Vuister, # G Vriend, JL Markley, and EL Ulrich (2009). The NMR Restraints Grid at BMRB for # 5,266 Protein and Nucleic Acid PDB Entries. J Biomol. NMR 45, 389–396. save_entry_information _Entry.Sf_category entry_information _Entry.Sf_framecode entry_information _Entry.ID rr_1xbl _Entry.Title "wwPDB remediated NMR restraints for PDB entry 1xbl" _Entry.NMR_STAR_version 3.1 _Entry.Experimental_method NMR _Entry.Experimental_method_subtype solution _Entry.Details "Contains the remediated restraint lists and coordinates for PDB entry 1xbl" save_ save_assembly _Assembly.Sf_category assembly _Assembly.Sf_framecode assembly _Assembly.Entry_ID rr_1xbl _Assembly.ID 1 _Assembly.Name 1xbl _Assembly.Number_of_components 1 _Assembly.Organic_ligands 0 _Assembly.Metal_ions 0 _Assembly.Non_standard_bonds no _Assembly.Paramagnetic no _Assembly.Thiol_state "not present" _Assembly.Molecular_mass 11824.9804 loop_ _Entity_assembly.ID _Entity_assembly.Entity_assembly_name _Entity_assembly.Entity_ID _Entity_assembly.Entity_label _Entity_assembly.Asym_ID _Entity_assembly.PDB_chain_ID _Entity_assembly.Experimental_data_reported _Entity_assembly.Physical_state _Entity_assembly.Conformational_isomer _Entity_assembly.Chemical_exchange_state _Entity_assembly.Magnetic_equivalence_group_code _Entity_assembly.Role _Entity_assembly.Details _Entity_assembly.Entry_ID _Entity_assembly.Assembly_ID 1 DNAJ 1 $DNAJ A . no . . . . . . rr_1xbl 1 stop_ save_ save_DNAJ _Entity.Sf_category entity _Entity.Sf_framecode DNAJ _Entity.Entry_ID rr_1xbl _Entity.ID 1 _Entity.Name DNAJ _Entity.Type polymer _Entity.Polymer_type polypeptide(L) _Entity.Polymer_strand_ID A _Entity.Polymer_seq_one_letter_code ; AKQDYYEILGVSKTAEEREI RKAYKRLAMKYHPDRNQGDK EAEAKFKEIKEAYEVLTDSQ KRAAYDQYGHAAFEQGGMGG GGFGGGADFSDIFGDVFGDI FGGGRGR ; _Entity.Ambiguous_conformational_states no _Entity.Ambiguous_chem_comp_sites no _Entity.Nstd_monomer no _Entity.Nstd_chirality no _Entity.Nstd_linkage no _Entity.Number_of_monomers 107 _Entity.Paramagnetic no _Entity.Thiol_state "not present" _Entity.Parent_entity_ID 1 _Entity.Formula_weight 11824.9804 loop_ _Entity_comp_index.ID _Entity_comp_index.Auth_seq_ID _Entity_comp_index.Comp_ID _Entity_comp_index.Comp_label _Entity_comp_index.Entry_ID _Entity_comp_index.Entity_ID 1 . ALA . rr_1xbl 1 2 . LYS . rr_1xbl 1 3 . GLN . rr_1xbl 1 4 . ASP . rr_1xbl 1 5 . TYR . rr_1xbl 1 6 . TYR . rr_1xbl 1 7 . GLU . rr_1xbl 1 8 . ILE . rr_1xbl 1 9 . LEU . rr_1xbl 1 10 . GLY . rr_1xbl 1 11 . VAL . rr_1xbl 1 12 . SER . rr_1xbl 1 13 . LYS . rr_1xbl 1 14 . THR . rr_1xbl 1 15 . ALA . rr_1xbl 1 16 . GLU . rr_1xbl 1 17 . GLU . rr_1xbl 1 18 . ARG . rr_1xbl 1 19 . GLU . rr_1xbl 1 20 . ILE . rr_1xbl 1 21 . ARG . rr_1xbl 1 22 . LYS . rr_1xbl 1 23 . ALA . rr_1xbl 1 24 . TYR . rr_1xbl 1 25 . LYS . rr_1xbl 1 26 . ARG . rr_1xbl 1 27 . LEU . rr_1xbl 1 28 . ALA . rr_1xbl 1 29 . MET . rr_1xbl 1 30 . LYS . rr_1xbl 1 31 . TYR . rr_1xbl 1 32 . HIS . rr_1xbl 1 33 . PRO . rr_1xbl 1 34 . ASP . rr_1xbl 1 35 . ARG . rr_1xbl 1 36 . ASN . rr_1xbl 1 37 . GLN . rr_1xbl 1 38 . GLY . rr_1xbl 1 39 . ASP . rr_1xbl 1 40 . LYS . rr_1xbl 1 41 . GLU . rr_1xbl 1 42 . ALA . rr_1xbl 1 43 . GLU . rr_1xbl 1 44 . ALA . rr_1xbl 1 45 . LYS . rr_1xbl 1 46 . PHE . rr_1xbl 1 47 . LYS . rr_1xbl 1 48 . GLU . rr_1xbl 1 49 . ILE . rr_1xbl 1 50 . LYS . rr_1xbl 1 51 . GLU . rr_1xbl 1 52 . ALA . rr_1xbl 1 53 . TYR . rr_1xbl 1 54 . GLU . rr_1xbl 1 55 . VAL . rr_1xbl 1 56 . LEU . rr_1xbl 1 57 . THR . rr_1xbl 1 58 . ASP . rr_1xbl 1 59 . SER . rr_1xbl 1 60 . GLN . rr_1xbl 1 61 . LYS . rr_1xbl 1 62 . ARG . rr_1xbl 1 63 . ALA . rr_1xbl 1 64 . ALA . rr_1xbl 1 65 . TYR . rr_1xbl 1 66 . ASP . rr_1xbl 1 67 . GLN . rr_1xbl 1 68 . TYR . rr_1xbl 1 69 . GLY . rr_1xbl 1 70 . HIS . rr_1xbl 1 71 . ALA . rr_1xbl 1 72 . ALA . rr_1xbl 1 73 . PHE . rr_1xbl 1 74 . GLU . rr_1xbl 1 75 . GLN . rr_1xbl 1 76 . GLY . rr_1xbl 1 77 . GLY . rr_1xbl 1 78 . MET . rr_1xbl 1 79 . GLY . rr_1xbl 1 80 . GLY . rr_1xbl 1 81 . GLY . rr_1xbl 1 82 . GLY . rr_1xbl 1 83 . PHE . rr_1xbl 1 84 . GLY . rr_1xbl 1 85 . GLY . rr_1xbl 1 86 . GLY . rr_1xbl 1 87 . ALA . rr_1xbl 1 88 . ASP . rr_1xbl 1 89 . PHE . rr_1xbl 1 90 . SER . rr_1xbl 1 91 . ASP . rr_1xbl 1 92 . ILE . rr_1xbl 1 93 . PHE . rr_1xbl 1 94 . GLY . rr_1xbl 1 95 . ASP . rr_1xbl 1 96 . VAL . rr_1xbl 1 97 . PHE . rr_1xbl 1 98 . GLY . rr_1xbl 1 99 . ASP . rr_1xbl 1 100 . ILE . rr_1xbl 1 101 . PHE . rr_1xbl 1 102 . GLY . rr_1xbl 1 103 . GLY . rr_1xbl 1 104 . GLY . rr_1xbl 1 105 . ARG . rr_1xbl 1 106 . GLY . rr_1xbl 1 107 . ARG . rr_1xbl 1 stop_ loop_ _Entity_poly_seq.Hetero _Entity_poly_seq.Mon_ID _Entity_poly_seq.Num _Entity_poly_seq.Comp_index_ID _Entity_poly_seq.Entry_ID _Entity_poly_seq.Entity_ID . ALA 1 1 rr_1xbl 1 . LYS 2 2 rr_1xbl 1 . GLN 3 3 rr_1xbl 1 . ASP 4 4 rr_1xbl 1 . TYR 5 5 rr_1xbl 1 . TYR 6 6 rr_1xbl 1 . GLU 7 7 rr_1xbl 1 . ILE 8 8 rr_1xbl 1 . LEU 9 9 rr_1xbl 1 . GLY 10 10 rr_1xbl 1 . VAL 11 11 rr_1xbl 1 . SER 12 12 rr_1xbl 1 . LYS 13 13 rr_1xbl 1 . THR 14 14 rr_1xbl 1 . ALA 15 15 rr_1xbl 1 . GLU 16 16 rr_1xbl 1 . GLU 17 17 rr_1xbl 1 . ARG 18 18 rr_1xbl 1 . GLU 19 19 rr_1xbl 1 . ILE 20 20 rr_1xbl 1 . ARG 21 21 rr_1xbl 1 . LYS 22 22 rr_1xbl 1 . ALA 23 23 rr_1xbl 1 . TYR 24 24 rr_1xbl 1 . LYS 25 25 rr_1xbl 1 . ARG 26 26 rr_1xbl 1 . LEU 27 27 rr_1xbl 1 . ALA 28 28 rr_1xbl 1 . MET 29 29 rr_1xbl 1 . LYS 30 30 rr_1xbl 1 . TYR 31 31 rr_1xbl 1 . HIS 32 32 rr_1xbl 1 . PRO 33 33 rr_1xbl 1 . ASP 34 34 rr_1xbl 1 . ARG 35 35 rr_1xbl 1 . ASN 36 36 rr_1xbl 1 . GLN 37 37 rr_1xbl 1 . GLY 38 38 rr_1xbl 1 . ASP 39 39 rr_1xbl 1 . LYS 40 40 rr_1xbl 1 . GLU 41 41 rr_1xbl 1 . ALA 42 42 rr_1xbl 1 . GLU 43 43 rr_1xbl 1 . ALA 44 44 rr_1xbl 1 . LYS 45 45 rr_1xbl 1 . PHE 46 46 rr_1xbl 1 . LYS 47 47 rr_1xbl 1 . GLU 48 48 rr_1xbl 1 . ILE 49 49 rr_1xbl 1 . LYS 50 50 rr_1xbl 1 . GLU 51 51 rr_1xbl 1 . ALA 52 52 rr_1xbl 1 . TYR 53 53 rr_1xbl 1 . GLU 54 54 rr_1xbl 1 . VAL 55 55 rr_1xbl 1 . LEU 56 56 rr_1xbl 1 . THR 57 57 rr_1xbl 1 . ASP 58 58 rr_1xbl 1 . SER 59 59 rr_1xbl 1 . GLN 60 60 rr_1xbl 1 . LYS 61 61 rr_1xbl 1 . ARG 62 62 rr_1xbl 1 . ALA 63 63 rr_1xbl 1 . ALA 64 64 rr_1xbl 1 . TYR 65 65 rr_1xbl 1 . ASP 66 66 rr_1xbl 1 . GLN 67 67 rr_1xbl 1 . TYR 68 68 rr_1xbl 1 . GLY 69 69 rr_1xbl 1 . HIS 70 70 rr_1xbl 1 . ALA 71 71 rr_1xbl 1 . ALA 72 72 rr_1xbl 1 . PHE 73 73 rr_1xbl 1 . GLU 74 74 rr_1xbl 1 . GLN 75 75 rr_1xbl 1 . GLY 76 76 rr_1xbl 1 . GLY 77 77 rr_1xbl 1 . MET 78 78 rr_1xbl 1 . GLY 79 79 rr_1xbl 1 . GLY 80 80 rr_1xbl 1 . GLY 81 81 rr_1xbl 1 . GLY 82 82 rr_1xbl 1 . PHE 83 83 rr_1xbl 1 . GLY 84 84 rr_1xbl 1 . GLY 85 85 rr_1xbl 1 . GLY 86 86 rr_1xbl 1 . ALA 87 87 rr_1xbl 1 . ASP 88 88 rr_1xbl 1 . PHE 89 89 rr_1xbl 1 . SER 90 90 rr_1xbl 1 . ASP 91 91 rr_1xbl 1 . ILE 92 92 rr_1xbl 1 . PHE 93 93 rr_1xbl 1 . GLY 94 94 rr_1xbl 1 . ASP 95 95 rr_1xbl 1 . VAL 96 96 rr_1xbl 1 . PHE 97 97 rr_1xbl 1 . GLY 98 98 rr_1xbl 1 . ASP 99 99 rr_1xbl 1 . ILE 100 100 rr_1xbl 1 . PHE 101 101 rr_1xbl 1 . GLY 102 102 rr_1xbl 1 . GLY 103 103 rr_1xbl 1 . GLY 104 104 rr_1xbl 1 . ARG 105 105 rr_1xbl 1 . GLY 106 106 rr_1xbl 1 . ARG 107 107 rr_1xbl 1 stop_ save_ save_conformer_statistics _Conformer_stat_list.Sf_category conformer_statistics _Conformer_stat_list.Sf_framecode conformer_statistics _Conformer_stat_list.Entry_ID rr_1xbl _Conformer_stat_list.ID 1 _Conformer_stat_list.Conf_family_coord_set_ID 1 _Conformer_stat_list.Conf_family_coord_set_label $Original_constraints_and_structures _Conformer_stat_list.Conformer_submitted_total_num 20 save_ save_global_Org_file_characteristics _Constraint_stat_list.Sf_framecode global_Org_file_characteristics _Constraint_stat_list.Sf_category constraint_statistics _Constraint_stat_list.Entry_ID rr_1xbl _Constraint_stat_list.ID 1 loop_ _Constraint_file.ID _Constraint_file.Constraint_filename _Constraint_file.Software_ID _Constraint_file.Software_label _Constraint_file.Software_name _Constraint_file.Block_ID _Constraint_file.Constraint_type _Constraint_file.Constraint_subtype _Constraint_file.Constraint_subsubtype _Constraint_file.Constraint_number _Constraint_file.Entry_ID _Constraint_file.Constraint_stat_list_ID 1 1xbl.mr . . "MR format" 1 comment "Not applicable" "Not applicable" 0 rr_1xbl 1 1 1xbl.mr . . n/a 2 "chemical shift" "Not applicable" "format 3" 0 rr_1xbl 1 1 1xbl.mr . . "MR format" 3 "coupling constant" "Not applicable" "Not applicable" 0 rr_1xbl 1 1 1xbl.mr . . "MR format" 4 distance NOE simple 0 rr_1xbl 1 1 1xbl.mr . . "MR format" 5 "dihedral angle" "Not applicable" "Not applicable" 0 rr_1xbl 1 1 1xbl.mr . . n/a 6 comment "Not applicable" "Not applicable" 0 rr_1xbl 1 1 1xbl.mr . . "MR format" 7 "nomenclature mapping" "Not applicable" "Not applicable" 0 rr_1xbl 1 stop_ save_ save_MR_file_comment_1 _Org_constr_file_comment.Sf_framecode MR_file_comment_1 _Org_constr_file_comment.Sf_category org_constr_file_comment _Org_constr_file_comment.Entry_ID rr_1xbl _Org_constr_file_comment.ID 1 _Org_constr_file_comment.Constraint_file_ID 1 _Org_constr_file_comment.Block_ID 1 _Org_constr_file_comment.Details "Generated by Wattos" _Org_constr_file_comment.Comment ; *HEADER CHAPERONE 07-OCT-96 1XBL *TITLE NMR STRUCTURE OF THE J-DOMAIN (RESIDUES 2-76) IN THE *TITLE 2 ESCHERICHIA COLI N-TERMINAL FRAGMENT (RESIDUES 2-108) OF *TITLE 3 THE MOLECULAR CHAPERONE DNAJ, 20 STRUCTURES *COMPND MOL_ID: 1; *COMPND 2 MOLECULE: DNAJ; *COMPND 3 CHAIN: NULL; *COMPND 4 FRAGMENT: N-TERMINAL FRAGMENT (RESIDUES 2-108) OF THE *COMPND 5 MOLECULAR CHAPERONE DNAJ; *COMPND 6 ENGINEERED: YES; *COMPND 7 BIOLOGICAL_UNIT: HOMODIMER *SOURCE MOL_ID: 1; *SOURCE 2 ORGANISM_SCIENTIFIC: ESCHERICHIA COLI; *SOURCE 3 EXPRESSION_SYSTEM: ESCHERICHIA COLI *KEYWDS CHAPERONE, DNA REPLICATION, HEAT SHOCK, REPEAT *EXPDTA NMR, 20 STRUCTURES *AUTHOR M.PELLECCHIA,T.SZYPERSKI,D.WALL,C.GEORGOPOULOS,K.WUTHRICH *REVDAT 1 11-JAN-97 1XBL 0 JRNL AUTH MAURIZIO PELLECCHIA,THOMAS SZYPERSKI, JRNL AUTH 2 DANIEL WALL,COSTA GEORGOPOULOS,KURT WUTHRICH JRNL TITL NMR STRUCTURE OF THE J-DOMAIN AND THE GLY/PHE RICH JRNL TITL 2 REGION OF THE ESCHERICHIA COLI DNAJ CHAPERONE JRNL REF J.MOL.BIOL. V. 260 236 1996 JRNL REFN ASTM JMOBAK UK ISSN 0022-2836 070 REMARK 1 REMARK 1 THIS FILE CONTAINS DATA THAT WAS USED IN THE DETERMINATION REMARK 1 OF THE THREE-DIMENSIONAL STRUCTURE OF THE J-DOMAIN IN THE REMARK 1 MOLECULAR CHAPERONE DNAJ(2-108) FROM ESCHERICHIA COLI BY REMARK 1 NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY IN SOLUTION. THE REMARK 1 THE DIFFERENT KINDS OF DATA, TOGETHER WITH THE CORRESPONDING REMARK 1 RECORD IDENTIFIERS ARE GIVEN IN THE FOLLOWING TABLE. REMARK 1 SEE REMARK 2 FOR THE DETAILS. REMARK 1 NOTE: THIS FILE CONTAINS ALL THE NMR CONTRAINTS USED TO REMARK 1 CALCULATE THE STRUCTURE OF THE J-DOMAIN (RESIDUES 2 TO 76) REMARK 1 IN THE FRAGMENT 2 TO 108. THE REGION COMPRISING RESIDUES REMARK 1 77 TO 108 (CALLED GLY/PHE RICH REGION) IS FLEXIBLY REMARK 1 DISORDERED IN SOLUTION (T. SZYPERSKI, M. PELLECCHIA. REMARK 1 D. WALL, C. GEORGOPOULOS, AND K. WUTHRICH (1994) PROC. NATL. REMARK 1 ACAD. SCI. USA VOL. 91, 11343-11347).THEREFORE, FOR RESIDUES 77-108 REMARK 1 ONLY CHEMICAL SHIFTS DATA ARE REPORTED. REMARK 1 REMARK 1 RECORD CONTENT UNIT REMARK 1 ------ ------------------------------------------- --------- REMARK 1 SHIFTH CHEMICAL SHIFTS OF THE ASSIGNED PROTONS PPM REMARK 1 SHIFTNC CHEMICAL SHIFTS OF THE ASSIGNED NITROGEN15 REMARK 1 AND CARBON13 NUCLEI PPM REMARK 1 JCOUPL VICINAL 1H-1H SCALAR COUPLING CONSTANTS HERTZ REMARK 1 NOEUPP UPPER LIMITS FOR INTERATOMIC DISTANCES ANGSTROMS REMARK 1 DETERMINED FROM NUCLEAR OVERHAUSER EFFECTS REMARK 1 ANGLE TORSION ANGLE CONSTRAINTS IN THE FORM OF DEGREES REMARK 1 AN ALLOWED INTERVAL REMARK 1 REMARK 1 ALL EXPERIMENTAL INPUT DATA (EXCEPT FOR THE AMINO ACID REMARK 1 SEQUENCE) IS GIVEN IN THE RECORDS NOEUPP, AND ANGLE. REMARK 1 COUPLING CONSTANS AND ANGLE CONSTRAINTS THAT WERE NOT REMARK 1 USED IN THE REFINEMENT REMARK 1 ARE NOT LISTED. REMARK 2 REMARK 2 REMARK 2 THE NEXT TABLE CONTAINS A DETAILED DESCRIPTION OF THE REMARK 2 CONTENTS AND FORMATS OF THE VARIOUS DATA RECORDS. REMARK 2 REMARK 2 VICINAL 1H-1H J COUPLINGS, NOE UPPER DISTANCE CONSTRAINTS REMARK 2 AND ANGLE CONSTRAINTS ARE GIVEN IN THE FORMAT FOR THE REMARK 2 PROGRAMS HABAS (P. GUNTERT, W. BRAUN, M. BILLETER, AND REMARK 2 K. WUTHRICH (1989) J. AM. CHEM. SOC. VOL. 111, 3997-4004) REMARK 2 AND DIANA (P. GUNTERT, W. BRAUN, AND K. WUTHRICH (1991) REMARK 2 J. MOL. BIOL. VOL. 217, 517-530) REMARK 2 REMARK 2 RECORD CONTENTS REMARK 2 ------ ----------------------------------------------------- REMARK 2 SHIFTH RESIDUE NAME, RESIDUE NUMBER, BACKBONE HN CHEMICAL SHIFT, REMARK 2 HA CHEMICAL SHIFT(S), HB CHEMICAL SHIFT(S), ATOM NAME, REMARK 2 CHEMICAL SHIFT(S). REMARK 2 SHIFTNC RESIDUE NAME, RESIDUE NUMBER, BACKBONE N CHEMICAL SHIFT, REMARK 2 CA CHEMICAL SHIFT, CB CHEMICAL SHIFT, ATOM NAME, REMARK 2 CHEMICAL SHIFT(S). REMARK 2 JCOUPL RESIDUE NUMBER, RESIDUE NAME, FIRST AND SECOND ATOM REMARK 2 NAME, J-COUPLING CONSTANT. REMARK 2 NOEUPP FIRST RESIDUE NAME, FIRST RESIDUE NUMBER, FIRST ATOM REMARK 2 NAME, SECOND RESIDUE NAME, SECOND RESIDUE NUMBER, REMARK 2 SECOND ATOM NAME, UPPER DISTANCE LIMIT REMARK 2 ANGLE RESIDUE NAME, RESIDUE NUMBER, ANGLE NAME, LOWER AND REMARK 2 UPPER BOUND. REMARK 3 REMARK 3 ATOM NAMES HAVE BEEN ASSIGNED FOLLOWING THE RECOMMENDATIONS REMARK 3 OF THE IUPAC-IUB COMMISSION AS PUBLISHED IN BIOCHEMISTRY REMARK 3 (1970) VOL. 9, 3471-3479, EXCEPT THAT BACKBONE AMIDE REMARK 3 HYDROGENS ARE DENOTED BY HN INSTEAD OF H. THE HYDROGEN ATOM REMARK 3 NUMBERS OF THOSE HYDROGEN ATOMS WHICH ARE CONNECTED TO THE REMARK 3 SAME NON-HYDROGEN ATOM ARE WRITTEN AS THE FIRST CHARACTER REMARK 3 RATHER THAN THE LAST CHARACTER OF THE ATOM NAMES. REMARK 4 REMARK 4 PSEUDO-ATOMS DESIGNATED AS Q ARE DIMENSIONLESS REFERENCE REMARK 4 POINTS REPRESENTING A GROUP OF HYDROGEN ATOMS REMARK 4 (K.WUTHRICH, M.BILLETER AND W.BRAUN, J. MOL. BIOL. (1983) REMARK 4 VOL. 169, 949-961). THEY ARE USED TO DESCRIBE ALL METHYL REMARK 4 GROUPS, AND THOSE GROUPS OF PROCHIRAL HYDROGEN ATOMS FOR REMARK 4 WHICH NO STEREOSPECIFIC ASSIGNMENTS HAD BEEN OBTAINED. REMARK 4 FOR ALL METHYLENE GROUPS, EVEN IN CASE OF IDENTICAL SHIFTS, REMARK 4 TWO CHEMICAL SHIFTS ARE LISTED FOR THE TWO PROTONS. REMARK 4 TWO CHEMICAL SHIFTS ARE ALSO ALWAYS GIVEN FOR THE TWO REMARK 4 METHYLS IN THE ISOPROPYL GROUPS. REMARK 5 REMARK 5 DETAILS OF THE NOMENCLATURE FOR THE PSEUDO-ATOMS ARE REMARK 5 AS FOLLOWS: QA REPRESENTS THE TWO METHYLENE HYDROGEN REMARK 5 ATOMS OF GLY. QB, QG, ... REPRESENT BETA, GAMMA, ... REMARK 5 METHYLENE OR METHYL GROUPS IN THE SIDE CHAINS. IN CASE OF REMARK 5 BRANCHES IN THE SIDE CHAINS THE NUMBERS OF THE PSEUDO-ATOMS REMARK 5 ARE THE SAME AS THE NUMBERS OF THE CARBONS TO WHICH THE REMARK 5 HYDROGEN ATOMS ARE ATTACHED. REMARK 5 QQG AND QQD DENOTE THE PSEUDO-ATOMS FOR THE 6 HYDROGEN REMARK 5 ATOMS OF THE ISOPROPYL METHYL GROUPS OF VAL AND LEU, RESPEC- REMARK 5 TIVELY. QR IS THE PSEUDO-ATOM FOR THE DELTA AND EPSILON REMARK 5 HYDROGENS OF THE AROMATIC RINGS OF TYR AND PHE. WHERE THE REMARK 5 DELTA AND EPSILON HYDROGENS OF THE AROMATIC RINGS HAVE BEEN REMARK 5 INDIVIDUALLY IDENTIFIED BUT ARE DEGENERATE IN THE ONE AND REMARK 5 TWO POSITIONS, THE CHEMICAL SHIFTS WERE LISTED UNDER CG AND REMARK 5 CZ RESPECTIVELY. REMARK 6 REMARK 6 THE CHEMICAL SHIFTS ARE IN PPM RELATIVE TO INTERNAL REMARK 6 2,2-DIMETHYL-2-SILAPENTANE-5-SULONATE SODIUM SALT (DSS). REMARK 6 13C AND 15N CHEMICAL SHIFTS ARE IN PPM RELATIVE TO REMARK 6 EXTERNAL DSS WITH THE FOLLOWING Z RATIOS 13C/1H = 0.251449530, REMARK 6 15N/1H = 0.101329118 (D. S. WISHART, C. G. BIGAM, J. YAO, REMARK 6 F. ABILDGAARD, H. J. DYSON, E. OLDFIELD, J. L. MARKLEY, REMARK 6 AND B. D. SYKES (1995) J. BIOMOL. NMR VOL. 6, 135-140. REMARK 6 ; save_ save_MR_file_comment_6 _Org_constr_file_comment.Sf_framecode MR_file_comment_6 _Org_constr_file_comment.Sf_category org_constr_file_comment _Org_constr_file_comment.Entry_ID rr_1xbl _Org_constr_file_comment.ID 2 _Org_constr_file_comment.Constraint_file_ID 1 _Org_constr_file_comment.Block_ID 6 _Org_constr_file_comment.Details "Generated by Wattos" _Org_constr_file_comment.Comment ; END ; save_