Structure Calculation and Validation: Difference between revisions
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== '''Introduction''' == | == '''Introduction''' == | ||
Protein structure determination by nuclear magnetic resonance (NMR) spectroscopy is a burdgeoning field of study that encompasses a wide variety of techniques and methodologies. In addition, validation of structures determined during and at the end of the structure determination process is critical to the accuracy of the final structures. Under Structure Calculation and Validation we describe the standard protocols for protein structure determination adopted by the NMR laboratories in the NESG. The section is broadly divided into 4 categories: | |||
*Structure Calculation | |||
*Structure Refinement | |||
*Special Topcis | |||
*Structure Validation and Deposition | |||
<br> | == '''Structure Calculation''' == | ||
The Structure Calculation chapter features several sub-categories assigned on the basis of the program or approach used for protein structure calculation. Here is a bried description of each sub-category: | |||
=== CYANA and AutoStructure === | |||
CYANA and AutoStructure are the two primary programs used in the NESG for initial protein structure calculation. CYANA is torsion angle dynamics based approach and can be run with manually assigned NOEs and distance constraints or fully automated NOESY assignment mode. Structures are computed in several cycles and structures with the lowest target function are retained in the conclusion of each cycle. AutoStructure uses a bottom-up approach and internal automated NOESYASSIGN module for iterative autmated NOESY assignment. In each cycle of AutoStructure, distance and torsion angle constraints are fed into either CYANA or XPLOR for structure calculation. | |||
For automated structure calculations, required input for each program includes: <br> | |||
*protein sequence | |||
*chemical shift assignment list | |||
*NOESY peak lists | |||
*torsional angle constraints (i.e., from TALOS) | |||
*user defined options including: total number of structure calculated, number of "best" structures kept at the end of each cycle. | |||
Optional input for the programs includes:<br> | |||
*manual distance constraints | |||
*hydrogen bond constraints | |||
*AutoStructure can also interpret J-coupling and slow N-H exchange data in its initial secondary structure and fold analysis | |||
*The newest version of CYANA (3.0) can use orientational constraints (i.e., residual dipolar couplings) | |||
Dihedral angle (J-coupling, chemical shifts) | Dihedral angle (J-coupling, chemical shifts) | ||
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== '''Structure Validation and Quality Assessment''' == | == '''Structure Validation and Quality Assessment''' == | ||
'''THIS PAGE IS UNDER CONSTRUCTION''' | '''THIS PAGE IS UNDER CONSTRUCTION''' | ||
Revision as of 17:31, 14 December 2009
Introduction
Protein structure determination by nuclear magnetic resonance (NMR) spectroscopy is a burdgeoning field of study that encompasses a wide variety of techniques and methodologies. In addition, validation of structures determined during and at the end of the structure determination process is critical to the accuracy of the final structures. Under Structure Calculation and Validation we describe the standard protocols for protein structure determination adopted by the NMR laboratories in the NESG. The section is broadly divided into 4 categories:
- Structure Calculation
- Structure Refinement
- Special Topcis
- Structure Validation and Deposition
Structure Calculation
The Structure Calculation chapter features several sub-categories assigned on the basis of the program or approach used for protein structure calculation. Here is a bried description of each sub-category:
CYANA and AutoStructure
CYANA and AutoStructure are the two primary programs used in the NESG for initial protein structure calculation. CYANA is torsion angle dynamics based approach and can be run with manually assigned NOEs and distance constraints or fully automated NOESY assignment mode. Structures are computed in several cycles and structures with the lowest target function are retained in the conclusion of each cycle. AutoStructure uses a bottom-up approach and internal automated NOESYASSIGN module for iterative autmated NOESY assignment. In each cycle of AutoStructure, distance and torsion angle constraints are fed into either CYANA or XPLOR for structure calculation.
For automated structure calculations, required input for each program includes:
- protein sequence
- chemical shift assignment list
- NOESY peak lists
- torsional angle constraints (i.e., from TALOS)
- user defined options including: total number of structure calculated, number of "best" structures kept at the end of each cycle.
Optional input for the programs includes:
- manual distance constraints
- hydrogen bond constraints
- AutoStructure can also interpret J-coupling and slow N-H exchange data in its initial secondary structure and fold analysis
- The newest version of CYANA (3.0) can use orientational constraints (i.e., residual dipolar couplings)
Dihedral angle (J-coupling, chemical shifts)
Orientational constraints (RDC, PRE)
Advanced Approaches to Derive Structural Information
SAXS
Computational Methods
Assignment of NOESY Peaklists and Structure Calculation
Structure Validation and Quality Assessment
THIS PAGE IS UNDER CONSTRUCTION