Abstract
Although the crystal structures of the HIV-1 gp120 core bound and pre-bound by CD4 are known, the details of dynamics involved in conformational equilibrium and transition in relation to gp120 function have remained elusive. The homology models of gp120 comprising the N- and C-termini and loops V3 and V4 in the CD4-bound and CD4-unbound states were built and subjected to molecular dynamics (MD) simulations to investigate the differences in dynamic properties and molecular motions between them. The results indicate that the CD4-bound gp120 adopted a more compact and stable conformation than the unbound form during simulations. For both the unbound and bound gp120, the large concerted motions derived from essential dynamics (ED) analyses can influence the size/shape of the ligand-binding channel/cavity of gp120 and, therefore, were related to its functional properties. The differences in motion direction between certain structural components of these two forms of gp120 were related to the conformational interconversion between them. The free energy calculations based on the metadynamics simulations reveal a more rugged and complex free energy landscape (FEL) for the unbound than for the bound gp120, implying that gp120 has a richer conformational diversity in the unbound form. The estimated free energy difference of ∼−6.0 kJ/mol between the global minimum free energy states of the unbound and bound gp120 indicates that gp120 can transform spontaneously from the unbound to bound states, revealing that the bound state represents a high-probability “ground state” for gp120 and explaining why the unbound state resists crystallization. Our results provide insight into the dynamics-and-function relationship of gp120, and facilitate understandings of the thermodynamics, kinetics and conformational control mechanism of HIV-1 gp120.
Highlights
Acquired immune deficiency syndrome (AIDS), which is caused by a retro-virus termed human immunodeficiency virus (HIV), has been a life-threatening health problem and brought about catastrophic consequences to human society [1,2]
We have built the near-full-length gp120 structural models in the unbound and bound states and investigated the dynamics, molecular motions and free energy landscape (FEL) characteristics of these two forms of gp120 based on the standard molecular dynamics (MD) and metadynamics simulations
The comparisons in the static structures, dynamic geometric properties, root mean square fluctuation (RMSF) values, and essential dynamics (ED) properties between these two forms of gp120 commonly reveal that the bound gp120 assumes a more compactly packed and stable conformation than the unbound gp120
Summary
Acquired immune deficiency syndrome (AIDS), which is caused by a retro-virus termed human immunodeficiency virus (HIV), has been a life-threatening health problem and brought about catastrophic consequences to human society [1,2]. The binding of gp120 to the receptor CD4 leads to the exposure of its binding-site to the co-receptor CCR5 or CXCR4 [12,13]; subsequently, the binding of gp120 to the co-receptor triggers its conformational rearrangements, which in turn facilitate the membrane fusion between the virus and host cell through insertion of the transmembrane protein gp into the cell membrane This entry process involves a series of conformational rearrangements of gp120 and its multiple interactions with receptor and co-receptor, and the dynamics of gp120 and its two-step binding to receptor and co-receptor are thought to play important roles in the virus infection and immune evasion [14]
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