TY - JOUR
T1 - Probing antibody internal dynamics with fluorescence anisotropy and molecular dynamics simulations
AU - Kortkhonjia, Ekaterine
AU - Brandman, Relly
AU - Zhou, Joe Zhongxiang
AU - Voelz, Vincent A.
AU - Chorny, Ilya
AU - Kabakoff, Bruce
AU - Patapoff, Thomas W.
AU - Dill, Ken A.
AU - Swartz, Trevor E.
PY - 2013/3
Y1 - 2013/3
N2 - The solution dynamics of antibodies are critical to antibody function. We explore the internal solution dynamics of antibody molecules through the combination of time-resolved fluorescence anisotropy experiments on IgG1 with more than two microseconds of all-atom molecular dynamics (MD) simulations in explicit water, an order of magnitude more than in previous simulations. We analyze the correlated motions with a mutual information entropy quantity, and examine state transition rates in a Markov-state model, to give coarse-grained descriptors of the motions. Our MD simulations show that while there are many strongly correlated motions, antibodies are highly flexible, with Fab and Fc domains constantly forming and breaking contacts, both polar and non-polar. We find that salt bridges break and reform, and not always with the same partners. While the MD simulations in explicit water give the right time scales for the motions, the simulated motions are about 3-fold faster than the experiments. Overall, the picture that emerges is that antibodies do not simply fluctuate around a single state of atomic contacts. Rather, in these large molecules, different atoms come in contact during different motions.
AB - The solution dynamics of antibodies are critical to antibody function. We explore the internal solution dynamics of antibody molecules through the combination of time-resolved fluorescence anisotropy experiments on IgG1 with more than two microseconds of all-atom molecular dynamics (MD) simulations in explicit water, an order of magnitude more than in previous simulations. We analyze the correlated motions with a mutual information entropy quantity, and examine state transition rates in a Markov-state model, to give coarse-grained descriptors of the motions. Our MD simulations show that while there are many strongly correlated motions, antibodies are highly flexible, with Fab and Fc domains constantly forming and breaking contacts, both polar and non-polar. We find that salt bridges break and reform, and not always with the same partners. While the MD simulations in explicit water give the right time scales for the motions, the simulated motions are about 3-fold faster than the experiments. Overall, the picture that emerges is that antibodies do not simply fluctuate around a single state of atomic contacts. Rather, in these large molecules, different atoms come in contact during different motions.
KW - Fluorescence anisotropy
KW - Molecular dynamics simulations
KW - Monoclonal antibodies
KW - Solution dynamics
KW - Therapeutic antibodies
UR - http://www.scopus.com/inward/record.url?scp=84876534299&partnerID=8YFLogxK
U2 - 10.4161/mabs.23651
DO - 10.4161/mabs.23651
M3 - Article
SN - 1942-0862
VL - 5
SP - 306
EP - 322
JO - mAbs
JF - mAbs
IS - 2
ER -