Abstract
The human immunodeficiency virus type 1 (HIV-1) integrase (IN) is a critical enzyme involved in infection. It catalyzes two reactions to integrate the viral cDNA into the host genome, 3' processing and strand transfer, but the dynamic behavior of the active site during catalysis of these two processes remains poorly characterized. NMR spectroscopy can reveal important structural details about enzyme mechanisms, but to date the IN catalytic core domain has proven resistant to such an analysis. Here, we present the first NMR studies of a soluble variant of the catalytic core domain. The NMR chemical shifts are found to corroborate structures observed in crystals, and confirm prior studies suggesting that the alpha4 helix extends toward the active site. We also observe a dramatic improvement in NMR spectra with increasing MgCl(2) concentration. This improvement suggests a structural transition not only near the active site residues but also throughout the entire molecule as IN binds Mg(2+). In particular, the stability of the core domain is linked to the conformation of its C-terminal helix, which has implications for relative domain orientation in the full-length enzyme. (15)N relaxation experiments further show that, although conformationally flexible, the catalytic loop of IN is not fully disordered in the absence of DNA. Indeed, automated chemical shift-based modeling of the active site loop reveals several stable clusters that show striking similarity to a recent crystal structure of prototype foamy virus IN bound to DNA.
Highlights
An essential step in the life cycle of retroviruses is the integration of their reverse-transcribed genome into that of the infected host
Mutagenesis studies, where inherently flexible Gly residues in this catalytic loop are replaced with Ala, suggest that the dynamics of the active site are important for catalysis [29]
Computational studies on the core domain particle have yielded conflicting results: short time scale simulations suggest that the active site loop samples ␣-helical conformations [38], whereas longer time scale simulations suggest that this loop acts as a gate over the other catalytic residues in IN [39]
Summary
The structure of an IN homolog from prototype foamy virus (PFV) was crystallized in complex with DNA [37]. Computational studies on the core domain particle have yielded conflicting results: short time scale simulations suggest that the active site loop samples ␣-helical conformations [38], whereas longer time scale simulations suggest that this loop acts as a gate over the other catalytic residues in IN [39]. Experimental validation of these simulations to date has been limited. We investigate a structural transition induced by Mg2ϩ binding that dramatically improves the NMR spectral quality This conformational shift, while requiring relatively high concentrations of MgCl2, may reveal important clues about the structural stability of IN, including effects on the N- and C-terminal domain orientations. We study the interaction of the IN core domain with raltegravir, a commercially available drug for IN inhibition [17]
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