Abstract
We determined conditions to produce milligram quantities of the soluble Rous sarcoma virus (RSV) synaptic complex that is kinetically trapped by HIV strand transfer inhibitors (STIs). Concerted integration catalyzed by RSV integrase (IN) is effectively inhibited by HIV STIs. Optimized assembly of the RSV synaptic complex required IN, a gain-of-function 3'-OH-recessed U3 oligonucleotide, and an STI under specific conditions to maintain solubility of the trapped synaptic complex at 4 °C. A C-terminal truncated IN (1-269 residues) produced a homogeneous population of trapped synaptic complex that eluted at ∼ 151,000 Da upon Superdex 200 size-exclusion chromatography (SEC). Approximately 90% of input IN and DNA are incorporated into the trapped synaptic complex using either the C-terminally truncated IN or wild type IN (1-286 residues). No STI is present in the SEC running buffer suggesting the STI-trapped synaptic complex is kinetically stabilized. The yield of the trapped synaptic complex correlates with the dissociative half-life of the STI observed with HIV IN-DNA complexes. Dolutegravir, MK-2048, and MK-0536 are equally effective, whereas raltegravir is ∼ 70% as effective. Without an STI present in the assembly mixture, no trapped synaptic complex was observed. Fluorescence and mass spectroscopy analyses demonstrated that the STI remains associated with the trapped complex. SEC-multiangle light scattering analyses demonstrated that wild type IN and the C-terminal IN truncation are dimers that acted as precursors to the tetramer. The purified STI-trapped synaptic complex contained a tetramer as shown by cross-linking studies. Structural studies of this three-domain RSV IN in complex with viral DNA may be feasible.
Highlights
Structure of the three-domain Rous sarcoma virus integrase with viral DNA is lacking
Rous sarcoma virus (RSV) replication was inhibited by RAL but not EVG, and this resistance to EVG mapped to residue Ser-150 of RSV IN [27]
EVG at high concentrations (Ͼ500 nM) was necessary for noticeable inhibition of either concerted or circular half-site (CHS) integration (Fig. 1, lanes 9 –11), RAL was effective at 25 nM (Fig. 1, lanes 5– 8)
Summary
Structure of the three-domain Rous sarcoma virus integrase with viral DNA is lacking. We determined conditions to produce milligram quantities of the soluble Rous sarcoma virus (RSV) synaptic complex that is kinetically trapped by HIV strand transfer inhibitors (STIs). Besides their ability to bind within the active site of PFV IN [6] and to inhibit Spumavirus prototype foamy virus replication [18], HIV IN STIs have the ability to differentially inhibit the replication of Alpharetrovirus, Betaretrovirus, and Gammaretrovirus [27] These studies suggest that RSV IN would be susceptible to inhibition by STIs. We demonstrate here that STIs at low nanomolar concentrations inhibit the concerted integration catalyzed by RSV IN as effectively as observed previously with HIV IN using similar large size DNA substrates (ϳ1 kb) [10, 21]. The results provide insights into the mechanism of RSV SC assembly and its interactions with STIs, and they suggest that future structural studies of the three-domain RSV IN in complex with viral DNA may be feasible
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