Coordinated motions of proteins
are known to be relevant to their function.
The current methods for studying
protein dynamics (spectroscopic studies, MD simulation etc.) either
suffer from incomplete sampling of comformational space or becomes
computationally too expensive.
Hemoglobin (Hb)
Hemoglobin is a model protein to
study allosteric protein mechanism.
Hb has two identical a-chains of
141 amino acids and two b-chains of 146 amino acid each.
Each subunit has similar 3-d
structure and has a heme-binding pocket that bind oxygen.
The binding of the first O2
molecule enhances O2 binding affinity of the other subunits (allosteric
effect).
The allosteric effect is
believed to be conveyed by the subunit interfaces.
Two pdb structures (1a3n and
1bbb) corresponding to the T (unliganded) and R2 (liganded) conformation
of Hb were used in this study.
Model
We used an
analytical approach based on a model originating from statistical
mechanics of elastic networks. The earlier version of this model is
known as Gaussian network model (GNM).
GNM has recently
been extended to predict the directionalities of collective motions.
This new version, called anisotropic network model (ANM), will be used for comparing dynamics
of Hb in T and R2 conformation. We then relate the dynamics of the
protein to mechanisms of Hb function.
University of Pittsburgh ---------- School of Medicine
W1041 Biomedical Science Tower 200 Lothrop St., Pittsburgh, PA
15261. Phone : (412) 648-3333, Fax: (412) 648-3163
