A possible role for the asymmetric C-terminal domain dimer of Rous sarcoma virus integrase in viral DNA binding.

Integration of the retrovirus linear DNA genome into the host chromosome is an essential step in the viral replication cycle, and is catalyzed by the viral integrase (IN). Evidence suggests that IN functions as a dimer that cleaves a dinucleotide from the 3' DNA blunt ends while a dimer of dimers (tetramer) promotes concerted integration of the two processed ends into opposite strands of a target DNA. However, it remains unclear why a dimer rather than a monomer of IN is required for the insertion of each recessed DNA end. To help address this question, we have analyzed crystal structures of the Rous sarcoma virus (RSV) IN mutants complete with all three structural domains as well as its two-domain fragment in a new crystal form at an improved resolution. Combined with earlier structural studies, our results suggest that the RSV IN dimer consists of highly flexible N-terminal domains and a rigid entity formed by the catalytic and C-terminal domains stabilized by the well-conserved catalytic domain dimerization interaction. Biochemical and mutational analyses confirm earlier observations that the catalytic and the C-terminal domains of an RSV IN dimer efficiently integrates one viral DNA end into target DNA. We also show that the asymmetric dimeric interaction between the two C-terminal domains is important for viral DNA binding and subsequent catalysis, including concerted integration. We propose that the asymmetric C-terminal domain dimer serves as a viral DNA binding surface for RSV IN.

HIV-1 integrase strand transfer inhibitors stabilize an integrase-single blunt-ended DNA complex.

Integration of human immunodeficiency virus cDNA ends by integrase (IN) into host chromosomes involves a concerted integration mechanism. IN juxtaposes two DNA blunt ends to form the synaptic complex, which is the intermediate in the concerted integration pathway. The synaptic complex is inactivated by strand transfer inhibitors (STI) with IC(50) values of ∼20 nM for inhibition of concerted integration. We detected a new nucleoprotein complex on a native agarose gel that was produced in the presence of >200 nM STI, termed the IN-single DNA (ISD) complex. Two IN dimers appear to bind in a parallel fashion at the DNA terminus, producing an ∼32-bp DNase I protective footprint. In the presence of raltegravir (RAL), MK-2048, and L-841,411, IN incorporated ∼20-25% of the input blunt-ended DNA substrate into the stabilized ISD complex. Seven other STI also produced the ISD complex (≤5% of input DNA). The formation of the ISD complex was not dependent on 3'OH processing, and the DNA was predominantly blunt ended in the complex. The RAL-resistant IN mutant N155H weakly forms the ISD complex in the presence of RAL at ∼25% level of wild-type IN. In contrast, MK-2048 and L-841,411 produced ∼3-fold to 5-fold more ISD than RAL with N155H IN, which is susceptible to these two inhibitors. The results suggest that STI are slow-binding inhibitors and that the potency to form and stabilize the ISD complex is not always related to inhibition of concerted integration. Rather, the apparent binding and dissociation properties of each STI influenced the production of the ISD complex.

Physical trapping of HIV-1 synaptic complex by different structural classes of integrase strand transfer inhibitors.

Raltegravir is an FDA approved inhibitor directed against human immunodeficiency virus type 1 (HIV-1) integrase (IN). In this study, we investigated the mechanisms associated with multiple strand transfer inhibitors capable of inhibiting concerted integration by HIV-1 IN. The results show raltegravir, elvitegravir, MK-2048, RDS 1997, and RDS 2197 all appear to encompass a common inhibitory mechanism by modifying IN-viral DNA interactions. These structurally different inhibitors bind to and inactivate the synaptic complex, an intermediate in the concerted integration pathway in vitro. The inhibitors physically trap the synaptic complex, thereby preventing target DNA binding and thus concerted integration. The efficiency of a particular inhibitor to trap the synaptic complex observed on native agarose gels correlated with its potency for inhibiting the concerted integration reaction, defined by IC(50) values for each inhibitor. At low nanomolar concentrations (<50 nM), raltegravir displayed a time-dependent inhibition of concerted integration, a property associated with slow-binding inhibitors. Studies of raltegravir-resistant IN mutants N155H and Q148H without inhibitors demonstrated that their capacity to assemble the synaptic complex and promote concerted integration was similar to their reported virus replication capacities. The concerted integration activity of Q148H showed a higher cross-resistance to raltegravir than observed with N155H, providing evidence as to why the Q148H pathway with secondary mutations is the predominant pathway upon prolonged treatment. Notably, MK-2048 is equally potent against wild-type IN and raltegravir-resistant IN mutant N155H, suggesting this inhibitor may bind similarly within their drug-binding pockets.

Molecular Interactions between HIV-1 integrase and the two viral DNA ends within the synaptic complex that mediates concerted integration.

A macromolecular nucleoprotein complex in retrovirus-infected cells, termed the preintegration complex, is responsible for the concerted integration of linear viral DNA genome into host chromosomes. Isolation of sufficient quantities of the cytoplasmic preintegration complexes for biochemical and biophysical analysis is difficult. We investigated the architecture of HIV-1 nucleoprotein complexes involved in the concerted integration pathway in vitro. HIV-1 integrase (IN) non-covalently juxtaposes two viral DNA termini forming the synaptic complex, a transient intermediate in the integration pathway, and shares properties associated with the preintegration complex. IN slowly processes two nucleotides from the 3' OH ends and performs the concerted insertion of two viral DNA ends into target DNA. IN remains associated with the concerted integration product, termed the strand transfer complex. The synaptic complex and strand transfer complex can be isolated by native agarose gel electrophoresis. In-gel fluorescence resonance energy transfer measurements demonstrated that the energy transfer efficiencies between the juxtaposed Cy3 and Cy5 5'-end labeled viral DNA ends in the synaptic complex (0.68+/-0.09) was significantly different from that observed in the strand transfer complex (0.07+/-0.02). The calculated distances were 46+/-3 A and 83+/-5 A, respectively. DNaseI footprint analysis of the complexes revealed that IN protects U5 and U3 DNA sequences up to approximately 32 bp from the end, suggesting two IN dimers were bound per terminus. Enhanced DNaseI cleavages were observed at nucleotide positions 6 and 9 from the terminus on U3 but not on U5, suggesting independent assembly events. Protein-protein cross-linking of IN within these complexes revealed the presence of dimers, tetramers, and a larger multimer (>120 kDa). Our results suggest a new model where two IN dimers individually assemble on U3 and U5 ends before the non-covalent juxtaposition of two viral DNA ends, producing the synaptic complex.

Biochemical and biophysical analyses of concerted (U5/U3) integration.

Retrovirus integrase (IN) integrates the viral linear DNA genome ( approximately 10 kb) into a host chromosome, a step which is essential for viral replication. Integration occurs via a nucleoprotein complex, termed the preintegration complex (PIC). This article focuses on the reconstitution of synaptic complexes from purified components whose molecular properties mirror those of the PIC, including the efficient concerted integration of two ends of linear viral DNA into target DNA. The methods described herein permit the biochemical and biophysical analyses of concerted integration. The methods enable (1) the study of interactions between purified recombinant IN and its viral DNA substrates at the molecular level; (2) the identification and characterization of nucleoprotein complexes involved in the human immunodeficiency virus type-1 (HIV-1) concerted integration pathway; (3) the determination of the multimeric state of IN within these complexes; (4) dissection of the interaction between HIV-1 IN and cellular proteins such as lens epithelium-derived growth factor (LEDGF/p75); (5) the examination of HIV-1 Class II and strand transfer inhibitor resistant IN mutants; (6) the mechanisms associated with strand transfer inhibitors directed against HIV-1 IN that have clinical relevance in the treatment of HIV-1/AIDS.

Synaptic complex formation of two retrovirus DNA attachment sites by integrase: a fluorescence energy transfer study.

The integration of retroviral DNA by the viral integrase (IN) into the host genome occurs via assembled preintegration complexes (PIC). We investigated this assembly process using purified IN and viral DNA oligodeoxynucleotide (ODN) substrates (93 bp in length) that were labeled with donor (Cy3) and acceptor fluorophores (Cy5). The fluorophores were attached to the 5' 2 bp overhangs of the terminal attachment (att) sites recognized by IN. Addition of IN to the assay mixture containing the fluorophore-labeled ODN resulted in synaptic complex formation at 14 degrees C with significant fluorescence resonance energy transfer (FRET) occurring between the fluorophores in close juxtaposition (from approximately 15 to 100 A). Subsequent integration assays at 37 degrees C with the same ODN (32P-labeled) demonstrated a direct association of a significant FRET signal with concerted insertion of the two ODNs into the circular DNA target, here termed full-site integration. FRET measurements (deltaF) show that IN binds to a particular set of 3' OH recessed substrates (type I) generating synaptic complexes capable of full-site integration that, as shown previously, exhibit IN mediated protection from DNaseI digestion up to approximately 20 bp from the ODN att ends. In contrast, IN also formed complexes with nonspecific DNA ends and loss-of-function att end substrates (type II) that had significantly lower deltaF values and were not capable of full-site integration, and lacked the DNaseI protection properties. The type II category may exemplify what is commonly understood as "nonspecific" binding by IN to DNA ends. Two IN mutants that exhibited little or no integration activity gave rise to the lower deltaF signals. Our FRET analysis provided the first direct physical evidence that IN forms synaptic complexes with two DNA att sites in vitro, yielding a complex that exhibits properties comparable to that of the PIC.