Refinement of the influenza virus hemagglutinin by simulated annealing.Weis, W.I., Brunger, A.T., Skehel, J.J., Wiley, D.C.
(1990) J Mol Biol 212: 737-761
- PubMed: 2329580
- DOI: 10.1016/0022-2836(90)90234-D
- Primary Citation of Related Structures:
4HMG, 3HMG, 2HMG, 5HMG
- PubMed Abstract:
- Structure of the Influenza Virus Haemagglutinin Complexed with its Receptor, Sialic Acid
Weis, W., Brown, J.H., Cusack, S., Paulson, J.C., Skehel, J.J., Wiley, D.C.
(1988) Nature 333: 426
- Three-Dimensional Structure of an Antigenic Mutant of the Influenza Virus Haemagglutinin
Knossow, M., Daniels, R.S., Douglas, A.R., Skehel, J.J., Wiley, D.C.
(1984) Nature 311: 678
- Structure of the Haemagglutinin Membrane Glycoprotein of Influenza Virus at 3 Angstroms Resolution
Wilson, I.A., Skehel, J.J., Wiley, D.C.
(1981) Nature 289: 366
- Structural Identification of the Antibody-Binding Sites of Hong Kong Influenza Haemagglutinin and Their Involvement in Antigenic Variation
Wiley, D.C., Wilson, I.A., Skehel, J.J.
(1981) Nature 289: 373
- Crystallization and X-Ray Diffraction Studies on the Haemagglutinin Glycoprotein from the Membrane of Influenza Virus
Wiley, D.C., Skehel, J.J.
(1977) J Mol Biol 112: 343
We have applied the method of simulated annealing to the refinement of the 3 A resolution crystal structure of the influenza virus hemagglutinin glycoprotein, using the program X-PLOR. Two different methods were introduced into X-PLOR to treat the no ...
We have applied the method of simulated annealing to the refinement of the 3 A resolution crystal structure of the influenza virus hemagglutinin glycoprotein, using the program X-PLOR. Two different methods were introduced into X-PLOR to treat the non-crystallographic symmetry present in this and in other crystal structures. In the first, only the unique protomer atoms are refined; by application of the non-crystallographic symmetry operators to the protomer atoms, the X-ray structure factor derivatives are effectively averaged, and a non-bonded energy term models the interactions of the protomer with its neighbors in the oligomer without explicit refinement of the other protomers in the crystallographic asymmetric unit. In the second method, the entire asymmetric unit is refined, but an effective energy term is added to the empirical energy that restrains symmetry-related atomic positions to their average values after least-squares superposition. Several other modifications and additions were made to previously published X-PLOR protocols, including weighting of the X-ray terms, maintenance of the temperature of the molecular dynamics simulation, treatment of charged groups, changes in the values of certain empirical energy parameters, and the use of N-linked carbohydrate empirical energy parameters. The hemagglutinin refinement proceeded in several stages. An initial round of simulated annealing of the monomer was followed by rigid-body refinement of the 3-fold non-crystallographic symmetry axis position and a second round of monomer refinement. A third round was performed on the trimer using non-crystallographic symmetry restraints in all regions except those in lattice contacts showing obvious derivations from 3-fold symmetry. The refinement was completed with several rounds of conventional positional and isotropic temperature factor refinement needed to correct bad model geometry introduced by high-temperature molecular dynamics in regions of weak electron density. This structure was then used as the basis for refinement of three crystallographically isomorphous hemagglutinin structures, including complexes with the influenza virus receptor, sialic acid. Model geometry comparable to well-refined high-resolution structures was obtained with relatively little manual intervention, demonstrating the ability of simulated annealing refinement to produce highly idealized structures at moderate resolution.
Howard Hughes Medical Institute, Yale University, New Haven, CT 06511.