Project description:The DNA cutting and joining reactions of HIV-1 integration are catalyzed by integrase (IN), a viral protein that functions as a tetramer bridging the two viral DNA ends (intasome). Two major obstacles for biochemical and structural studies of HIV-1 intasomes are 1) the low efficiency of assembly with oligonucleotide DNA substrates, and 2) the non-specific aggregation of both intasomes and free IN in the reaction mixture. By fusing IN with a small non-specific DNA binding protein, Sulfolobus solfataricus chromosomal protein Sso7d (PDB: 1BNZ), we have engineered a highly soluble and hyperactive IN. Unlike wild-type IN, it efficiently catalyzes intasome assembly and concerted integration with oligonucleotide DNA substrates. The fusion IN protein also functions to integrate viral reverse transcripts during HIV-infection. The hyperactive HIV-1 IN may assist in facilitating future biochemical and structural studies of HIV-1 intasomes. Understanding the mechanistic basis of the Sso7d-IN fusion protein could provide insight into the factors that have hindered biophysical studies of wild-type HIV-1 IN and intasomes.

Project description:Commentary on Hare, S.; Gupta, S.S.; Valkov, E.; Engelman, A.; Cherepanov, P. Retroviral intasome assembly and inhibition of DNA strand transfer. Nature2010, 464, 232-236.

Project description:Retroviral integrases catalyze two reactions, 3'-processing of viral DNA ends, followed by integration of the processed ends into chromosomal DNA. X-ray crystal structures of integrase-DNA complexes from prototype foamy virus, a member of the Spumavirus genus of Retroviridae, have revealed the structural basis of integration and how clinically relevant integrase strand transfer inhibitors work. Underscoring the translational potential of targeting virus-host interactions, small molecules that bind at the host factor lens epithelium-derived growth factor/p75-binding site on HIV-1 integrase promote dimerization and inhibit integrase-viral DNA assembly and catalysis. Here, we review recent advances in our knowledge of HIV-1 DNA integration, as well as future research directions.

Project description: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.

Project description:Retroviral DNA made by reverse transcription is blunt-ended, and the viral integrase protein must remove two nucleotides from each 3' end prior to integration into chromosomal DNA. Under most reaction conditions for integration in vitro, the majority of the reaction products are "half-site" products that result from integration of only one viral DNA end into one strand of the target DNA. Preprocessed DNA substrates are more efficient substrates for half-site reactions than are blunt-ended substrates, which require the removal of two nucleotides prior to integration. In contrast, we find that blunt-ended DNA is a better substrate for the biologically relevant reaction of concerted integration of pairs of viral DNA ends. The reaction pathway is channeled to concerted integration, and half-site integration products are reduced with blunt-ended DNA substrate that must first be processed by integrase. In addition, the terminal nucleotide requirements for concerted integration are more stringent than for the half-site reaction. Longer DNA is more efficient for the concerted reaction than is shorter DNA that is capable of efficient half-site integration. This suggests that nonspecific interactions of integrase with viral DNA distant from the termini contribute to the assembly of a complex that is competent for concerted integration. Finally, differential effects of mutation of a residue in the C-terminal domain of integrase on concerted versus half-site integration implicate protein-protein interactions involving this domain as important for concerted integration.

Project description:HIV-1 integrase integrates retroviral DNA through 3'-processing and strand transfer reactions in the presence of a divalent cation (Mg(2+) or Mn(2+)). The alpha4 helix exposed at the catalytic core surface is essential to the specific recognition of viral DNA. To define group determinants of recognition, we used a model composed of a peptide analogue of the alpha4 helix, oligonucleotides mimicking processed and unprocessed U5 LTR end and 5 mM Mg(2+). Circular dichroism, fluorescence and NMR experiments confirmed the implication of the alpha4 helix polar/charged face in specific and non-specific bindings to LTR ends. The specific binding requires unprocessed LTR ends-i.e. an unaltered 3'-processing site CA downward arrowGT3'-and is reinforced by Mg(2+) (K(d) decreases from 2 to 0.8 nM). The latter likely interacts with the ApG and GpT3' steps of the 3'-processing site. With deletion of GT3', only persists non-specific binding (K(d) of 100 microM). Proton chemical shift deviations showed that specific binding need conserved amino acids in the alpha4 helix and conserved nucleotide bases and backbone groups at LTR ends. We suggest a conserved recognition mechanism based on both direct and indirect readout and which is subject to evolutionary pressure.

Project description:BACKGROUND: The prevention of persistent human immunodeficiency virus type 1 (HIV-1) infection requires the clarification of the mode of viral transduction into resting macrophages. Recently, DNA double-strand breaks (DSBs) were shown to enhance infection by D64A virus, which has a defective integrase catalytic activity (IN-CA). However, the mechanism by which DSBs upregulate viral transduction was unclear. Here we analyzed the roles of DSBs during IN-CA-independent viral transduction into macrophages. RESULTS: We used cellular systems with rare-cutting endonucleases and found that D64A virus integrated efficiently into the sites of artificially induced DSBs. This IN-CA-independent viral transduction was blocked by an inhibitor of ataxia telangiectasia mutated protein (ATM) but was resistant to raltegravir (RAL), an inhibitor of integrase activity during strand transfer. Moreover, Vpr, an accessory gene product of HIV-1, induced DSBs in resting macrophages and significantly enhanced the rate of IN-CA-independent viral transduction into macrophages with concomitant production of secondary viruses. CONCLUSION: DSBs contribute to the IN-CA-independent viral infection of macrophages, which is resistant to RAL. Thus, the ATM-dependent cellular pathway and Vpr-induced DNA damage are novel targets for preventing persistent HIV-1 infection.

Project description:: The oligomerization of HIV-1 integrase onto DNA is not well understood. Here we show that HIV-1 integrase binds the DNA in biphasic (high-affinity and low-affinity) modes. For HIV-1 subtype B, the high-affinity mode is ∼100-fold greater than the low-affinity mode (Kd.DNA = 37 and 3400 nmol/l, respectively). The Kd.DNA values of patient-derived integrases containing subtype-specific polymorphisms were affected two- to four-fold, suggesting that polymorphisms may have an influence on effective-concentrations of inhibitors, as these inhibitors preferably bind to integrase-DNA complex.

Project description:BackgroundThe retroviral Integrase protein catalyzes the insertion of linear viral DNA into host cell DNA. Although different retroviruses have been shown to target distinctive chromosomal regions, few of them display a site-specific integration. ZAM, a retroelement from Drosophila melanogaster very similar in structure and replication cycle to mammalian retroviruses is highly site-specific. Indeed, ZAM copies target the genomic 5'-CGCGCg-3' consensus-sequences. To enlighten the determinants of this high integration specificity, we investigated the functional properties of its integrase protein denoted ZAM-IN.Principal findingsHere we show that ZAM-IN displays the property to nick DNA molecules in vitro. This endonuclease activity targets specific sequences that are present in a 388 bp fragment taken from the white locus and known to be a genomic ZAM integration site in vivo. Furthermore, ZAM-IN displays the unusual property to directly bind specific genomic DNA sequences. Two specific and independent sites are recognized within the 388 bp fragment of the white locus: the CGCGCg sequence and a closely apposed site different in sequence.ConclusionThis study strongly argues that the intrinsic properties of ZAM-IN, ie its binding properties and its endonuclease activity, play an important part in ZAM integration specificity. Its ability to select two binding sites and to nick the DNA molecule reminds the strategy used by some site-specific recombination enzymes and forms the basis for site-specific integration strategies potentially useful in a broad range of genetic engineering applications.

Project description:HIV-1 integrase (IN) oligomerization and DNA recognition are crucial steps for the subsequent events of the integration reaction. Recent advances described the involvement of stable intermediary complexes including dimers and tetramers in the in vitro integration processes, but the initial attachment events and IN positioning on viral ends are not clearly understood. In order to determine the role of the different IN oligomeric complexes in these early steps, we performed in vitro functional analysis comparing IN preparations having different oligomerization properties. We demonstrate that in vitro IN concerted integration activity on a long DNA substrate containing both specific viral and nonspecific DNA sequences is highly dependent on binding of preformed dimers to viral ends. In addition, we show that IN monomers bound to nonspecific DNA can also fold into functionally different oligomeric complexes displaying nonspecific double-strand DNA break activity in contrast to the well known single strand cut catalyzed by associated IN. Our results imply that the efficient formation of the active integration complex highly requires the early correct positioning of monomeric integrase or the direct binding of preformed dimers on the viral ends. Taken together the data indicates that IN oligomerization controls both the enzyme specificity and activity.