TY - JOUR
T1 - The implementation of SOMO (SOlution MOdeller) in the UltraScan analytical ultracentrifugation data analysis suite
T2 - Enhanced capabilities allow the reliable hydrodynamic modeling of virtually any kind of biomacromolecule
AU - Brookes, Emre
AU - Demeler, Borries
AU - Rosano, Camillo
AU - Rocco, Mattia
N1 - Funding Information:
Acknowledgments We thank M. Nöllmann for providing his newAtoB code, and O. Byron for suggestions. The development of the UltraScan and US-SOMO is supported by the National Institute of Health Grant # RR022200 (to B. D.). M. R. gratefully acknowledges support from the Istituto Superiore della Sanità, program Italia-USA.
PY - 2010/2
Y1 - 2010/2
N2 - The interpretation of solution hydrodynamic data in terms of macromolecular structural parameters is not a straightforward task. Over the years, several approaches have been developed to cope with this problem, the most widely used being bead modeling in various flavors. We report here the implementation of the SOMO (SOlution MOdeller; Rai et al. in Structure 13:723-734, 2005) bead modeling suite within one of the most widely used analytical ultracentrifugation data analysis software packages, UltraScan (Demeler in Modern analytical ultracentrifugation: techniques and methods, Royal Society of Chemistry, UK, 2005). The US-SOMO version is now under complete graphical interface control, and has been freed from several constraints present in the original implementation. In the direct beads-per-atoms method, virtually any kind of residue as defined in the Protein Data Bank (e.g., proteins, nucleic acids, carbohydrates, prosthetic groups, detergents, etc.) can be now represented with beads whose number, size and position are all defined in user-editable tables. For large structures, a cubic grid method based on the original AtoB program (Byron in Biophys J 72:408-415, 1997) can be applied either directly on the atomic structure, or on a previously generated bead model. The hydrodynamic parameters are then computed in the rigid-body approximation. An extensive set of tests was conducted to further validate the method, and the results are presented here. Owing to its accuracy, speed, and versatility, US-SOMO should allow to fully take advantage of the potential of solution hydrodynamics as a complement to higher resolution techniques in biomacromolecular modeling.
AB - The interpretation of solution hydrodynamic data in terms of macromolecular structural parameters is not a straightforward task. Over the years, several approaches have been developed to cope with this problem, the most widely used being bead modeling in various flavors. We report here the implementation of the SOMO (SOlution MOdeller; Rai et al. in Structure 13:723-734, 2005) bead modeling suite within one of the most widely used analytical ultracentrifugation data analysis software packages, UltraScan (Demeler in Modern analytical ultracentrifugation: techniques and methods, Royal Society of Chemistry, UK, 2005). The US-SOMO version is now under complete graphical interface control, and has been freed from several constraints present in the original implementation. In the direct beads-per-atoms method, virtually any kind of residue as defined in the Protein Data Bank (e.g., proteins, nucleic acids, carbohydrates, prosthetic groups, detergents, etc.) can be now represented with beads whose number, size and position are all defined in user-editable tables. For large structures, a cubic grid method based on the original AtoB program (Byron in Biophys J 72:408-415, 1997) can be applied either directly on the atomic structure, or on a previously generated bead model. The hydrodynamic parameters are then computed in the rigid-body approximation. An extensive set of tests was conducted to further validate the method, and the results are presented here. Owing to its accuracy, speed, and versatility, US-SOMO should allow to fully take advantage of the potential of solution hydrodynamics as a complement to higher resolution techniques in biomacromolecular modeling.
KW - Analytical ultracentrifugation
KW - Bead modeling
KW - Macromolecular hydrodynamics
KW - NMR spectroscopy
KW - Protein structure and dynamics
KW - X-ray crystallography
UR - http://www.scopus.com/inward/record.url?scp=77950552976&partnerID=8YFLogxK
U2 - 10.1007/s00249-009-0418-0
DO - 10.1007/s00249-009-0418-0
M3 - Article
C2 - 19234696
AN - SCOPUS:77950552976
SN - 0175-7571
VL - 39
SP - 423
EP - 435
JO - European Biophysics Journal
JF - European Biophysics Journal
IS - 3
ER -