All Stories

  1. Recent improvements to the automatic characterization and data collection algorithms on MASSIF-1
  2. Structural Evidence for a Role of the Multi-functional Human Glycoprotein Afamin in Wnt Transport
  3. An algal photoenzyme converts fatty acids to hydrocarbons
  4. Structural insights into a family 39 glycoside hydrolase from the gut symbiont Bacteroides cellulosilyticus WH2
  5. Designing an autonomous system for protein crystallography
  6. An autonomous system to perform complex experiments for biologists
  7. Structure of FAE solved by SAD from data collected by Direct Data Collection (DDC) using the ESRF RoboDiff goniometer
  8. Structure of trypsin solved by MR from data collected by Direct Data Collection (DDC) using the ESRF RoboDiff goniometer
  9. Structure of thermolysin solved by SAD from data collected by Direct Data Collection (DDC) using the ESRF RoboDiff goniometer
  10. Automated data collection based on RoboDiff at the ESRF beamline MASSIF-1
  11. MASSIF1: fully automated macromolecular crystallography
  12. Protein crystallography becomes hands free
  13. The status of the macromolecular crystallography beamlines at the European Synchrotron Radiation Facility
  14. Crystal Structure of the endo-beta-N-acetylglucosaminidase from Thermotoga maritima
  15. Le rayonnement synchrotron : comprendre la relation structure-fonction des macromolécules biologiques
  16. Recent progress in robot-based systems for crystallography and their contribution to drug discovery
  17. Circular Permutation Provides an Evolutionary Link between Two Families of Calcium-dependent Carbohydrate Binding Modules
  18. vCBM60 in complex with cellobiose
  19. vCBM60 in complex with galactobiose
  20. The ID23-2 structural biology microfocus beamline at the ESRF
  21. A decade of user operation on the macromolecular crystallography MAD beamline ID14-4 at the ESRF
  22. Online collection and analysis of X-ray fluorescence spectra on the macromolecular crystallography beamlines of the ESRF
  23. An inexpensive automatically operated device for the flash annealing of crystals of macromolecules
  24. Technical Report: Automatic Experiments at the European Synchrotron Radiation Facility MX Beam-lines
  25. Structures of two mutants that probe the role in iron release of the dilysine pair in the N-lobe of human transferrin
  26. Crystal structure of K206E mutant of N-lobe human transferrin
  27. Crystal structure of K206E/K296E mutant of the N-terminal half molecule of human transferrin
  28. Crystal Structure of Nsp 15 from SARS
  29. The ID23-1 structural biology beamline at the ESRF
  30. lysozyme (60sec) and UV laser excited fluorescence
  31. insuline(60sec) and UV laser excited fluorescence
  32. insuline(1sec) and UV laser excited fluorescence
  33. lysozyme (1sec) and UV lasr excited fluorescence
  34. UV laser-excited fluorescence as a tool for the visualization of protein crystals mounted in loops
  35. Probing the Mechanism of Ligand Recognition in Family 29 Carbohydrate-binding Modules
  36. CBM29-2 mutant R112A: Probing the Mechanism of Ligand Recognition by Family 29 Carbohydrate Binding Modules
  37. CBM29-2 mutant K85A: Probing the Mechanism of Ligand Recognition by Family 29 Carbohydrate Binding Modules
  38. CBM29-2 mutant Y46A: Probing the Mechanism of Ligand Recognition by Family 29 Carbohydrate Binding Modules
  39. CBM29-2 mutant D114A: Probing the Mechanism of Ligand Recognition by Family 29 Carbohydrate Binding Modules
  40. Native Bacillus subtilis Arabinanase Arb43A
  41. E78R mutant of a carbohydrate binding module family 29
  42. X-ray crystal structure of a non-crystalline cellulose specific carbohydrate-binding module: CBM28.
  43. X-ray Crystal Structure of a Non-crystalline Cellulose-specific Carbohydrate-binding Module: CBM28
  44. CRYSTAL STRUCTURE OF A BACTERIAL LIPOCALIN, THE BLC GENE PRODUCT FROM E. COLI
  45. Structural and thermodynamic dissection of specific mannan recognition by a carbohydrate-binding module
  46. The crystal structure of theEscherichia colilipocalin Blc suggests a possible role in phospholipid binding
  47. Ligand-mediated Dimerization of a Carbohydrate-binding Module Reveals a Novel Mechanism for Protein–Carbohydrate Recognition
  48. Crystal structure of aminoglycoside-3'-phosphotransferase-IIa
  49. Structural and Thermodynamic Dissection of Specific Mannan Recognition by a Carbohydrate Binding Module, TmCBM27
  50. Pseudomonas cellulosa E292A alpha-D-glucuronidase mutant complexed with aldotriuronic acid
  51. Structural and thermodynamic dissection of specific mannan recognition by a carbohydrate-binding module, TmCBM27
  52. Structural and thermodynamic dissection of specific mannan recognition by a carbohydrate-binding module, TmCBM27
  53. The α-Glucuronidase, GlcA67A, ofCellvibrio japonicusUtilizes the Carboxylate and Methyl Groups of Aldobiouronic Acid as Important Substrate Recognition Determinants
  54. Carbohydrate binding module family29 complexed with glucohexaose
  55. Carbohydrate binding module family29 complexed with mannohexaose
  56. Carbohydrate binding module family29
  57. The Crystal Structure of Aminoglycoside-3′-Phosphotransferase-IIa, an Enzyme Responsible for Antibiotic Resistance
  58. CBM4 structure and function
  59. CBM4 structure and function
  60. Structure of Pseudomonas cellulosa alpha-D-glucuronidase complexed with glucuronic acid
  61. Structure of Pseudomonas cellulosa alpha-D-glucuronidase complexed with xylobiose
  62. Structure of Pseudomonas cellulosa alpha-D-glucuronidase
  63. Structure of Pseudomonas cellulosa alpha-D-glucuronidase complexed with glucuronic acid and xylotriose
  64. structure of D158A Cellovibrio cellulosa alpha-L-arabinanase mutant
  65. Structure of Cellvibrio cellulosa alpha-L-arabinanase complexed with Arabinohexaose
  66. Structure of Cellvibrio cellulosa alpha-L-arabinanase
  67. Cellvibrio japonicus α-L-arabinanase 43A has a novel five-blade β-propeller fold
  68. Pseudomonas aeruginosa cd1 nitrite reductase reduced cyanide complex
  69. Differential Oligosaccharide Recognition by Evolutionarily-related β-1,4 and β-1,3 Glucan-binding Modules
  70. The Structural Basis for Catalysis and Specificity of the Pseudomonas cellulosa α-Glucuronidase, GlcA67A
  71. Cyanide Binding to cd1 Nitrite Reductase from Pseudomonas aeruginosa: Role of the Active-Site His369 in Ligand Stabilization
  72. Reduced Precursor Form of Glucose-Fructose Oxidoreductase from Zymomonas mobilis
  73. Oxidized Precursor Form of Glucose-Fructose Oxidoreductase from Zymomonas mobilis complexed with succinate
  74. Reduced Precursor Form of Glucose-Fructose Oxidoreductase from Zymomonas mobilis complexed with glycerol
  75. Oxidized Precursor Form of Glucose-Fructose Oxidoreductase from Zymomonas mobilis complexed with glycerol
  76. Crystal Structures of the Precursor Form of Glucose-Fructose Oxidoreductase fromZymomonas mobilisand Its Complexes with Bound Ligands†,‡
  77. CRYSTAL STRUCTURES OF MUTANT (K296A) THAT ABOLISH THE DILYSINE INTERACTION IN THE N-LOBE OF HUMAN TRANSFERRIN
  78. CRYSTAL STRUCTURES OF MUTANT (K206A) THAT ABOLISH THE DILYSINE INTERACTION IN THE N-LOBE OF HUMAN TRANSFERRIN
  79. Crystal Structures and Iron Release Properties of Mutants (K206A and K296A) That Abolish the Dilysine Interaction in the N-Lobe of Human Transferrin†,‡
  80. STRUCTURE OF PSEUDOMONAS NAUTICA CYTOCHROME C552, BY MAD METHOD
  81. FOLLOWING THE C HEME REDUCTION IN NITRITE REDUCTASE FROM PSEUDOMONAS AERUGINOSA
  82. FOLLOWING THE C HEME REDUCTION IN NITRITE REDUCTASE FROM PSEUDOMONAS AERUGINOSA
  83. FOLLOWING THE C HEME REDUCTION IN NITRITE REDUCTASE FROM PSEUDOMONAS AERUGINOSA
  84. MAD Structure of Pseudomonas nautica Dimeric Cytochrome c552Mimicks thec4 Dihemic Cytochrome Domain Association
  85. Does the Reduction of c Heme Trigger the Conformational Change of Crystalline Nitrite Reductase?
  86. CONFORMATIONAL CHANGES OCCURRING UPON NO BINDING IN NITRITE REDUCTASE FROM PSEUDOMONAS AERUGINOSA
  87. CONFORMATIONAL CHANGES OCCURRING UPON REDUCTION IN NITRITE REDUCTASE FROM PSEUDOMONAS AERUGINOSA
  88. Conformational Changes Occurring upon Reduction and NO Binding in Nitrite Reductase fromPseudomonas aeruginosa†,‡
  89. OXYDIZED NITRITE REDUCTASE FROM PSEUDOMONAS AERUGINOSA
  90. N-terminal arm exchange is observed in the 2.15 Å crystal structure of oxidized nitrite reductase from Pseudomonas aeruginosa