There is now substantial virological evidence that the precursor of integrated viral DNA, or provirus, is a linear viral DNA generated by reverse transcription of the viral genome. Two reactions are required for the covalent integration of viral DNA into the host DNA. The integrase (IN) first binds to a short sequence at each end of the viral DNA known as the long terminal repeat (LTR) and catalyses an endonucleotide cleavage known as 3'-processing, in which a dinucleotide is eliminated from each end of the viral DNA (Fig 1). The resulting cleaved DNA is then used as a substrate for integration or strand transfer leading to the covalent insertion of the viral DNA into the genome of the infected cell (Fig 1). This second reaction occurs simultaneously at both ends of the viral DNA molecule, with an offset of precisely five base pairs between the two opposite points of insertion.

These two reactions also occur in vivo in a sequential manner. The two reactions are also energetically independent. In both cases, the reaction is a single-step trans-esterification involving the disruption of a phosphodiester bond by nucleophilic attack. In the first reaction, the bond concerned is part of the viral DNA molecule and in the second, the bond is in the target DNA. There is therefore no covalent intermediate between the enzyme and the DNA as it is observed during catalytic reaction of topoisomerase or IN of lambda phage, for example. The removal of the dinucleotides from the 5' overhang, of viral origin, and DNA repair (i.e. polymerisation and ligation) are required to complete the full integration reaction. One study suggested that this might involve a DNA-dependent DNA polymerase activity of the IN 41, but, to date, such a polymerase activity of IN was not confirmed and it is generally thought that this DNA repair is performed by cellular mechanisms that can be reproduced in vitro with purified host cell factors 42. The final reaction thus results in a viral DNA molecule, the provirus, integrated into and collinear with the genomic DNA, with a characteristic 5 base pairs duplication (in the case of HIV-1) of genomic sequence flanking the integration site. Several lines of evidence support a non-random integration with preferential integration in transcription units for HIV-1 43. Integration is then mainly directed by interactions between the pre-integration complex and chromatin. From a DNA sequence point of view, it was recently shown that integration occurs preferentially within symmetric sequences 444546 (see # 2.3).

Both reactions (3'-processing and strand transfer) can be reproduced in vitro using short double-stranded oligonucleotides mimicking the sequence of the ends of the viral LTR U5 or U3 in the presence of a recombinant integrase 47. 3'-processing is a highly specific reaction. This reaction involves the removal of a dinucleotide, adjacent to the highly conserved CA dinucleotide, from the 3' strand of the U3 and U5 viral DNA LTRs. Mutations in this sequence completely abolish activity, whereas the integrity of flanking sequences is much less important 1548. The 3'-processing reaction corresponds to a nucleophilic attack by a water molecule. However, other alternative nucleophilic agents can be used such as glycerol but generally conduct to non-specific endonucleolytic cleavage 495051. This mainly occurs when Mn²⁺ is used. The 3'-OH of the unprocessed DNA can also be used directly as a nucleophilic agent leading to 3'-5' cyclic dinucleotide product 49. The use of the physiological relevant cofactor Mg²⁺ improves the specificity of the cleavage with water as the mainly used nucleophilic agent.

During the same reaction, IN can catalyse, with a modest yield, the strand transfer. In the strand transfer reaction, the nucleophilic agent corresponds to the 3'-OH extremity of the processed strand. It is possible to increase the yield of the strand transfer with pre-processed oligonucleotides 36. By using an oligonucleotide mimicking one LTR end, only a half-transfer reaction can be observed. In vitro, long DNA fragments with two viral extremities can be used to reproduce the concerted integration process which corresponds to the simultaneous integration of two viral ends 35365253. Concerted integration appears less tolerant to reaction conditions, i.e. enzyme preparation and oligomerization state than strand transfer. Although it was shown by different groups that IN alone is sufficient to catalyse the concerted integration, viral or cellular protein, acting as cofactors for the integration process, such as the viral nucleocapsid protein NC 54 and the cellular proteins HMG I(Y) 55 and LEDGF 565758 may increase its efficacy. Interestingly, it was recently shown that, in contrast to the half-transfer reaction, a higher reaction yield was obtained for the concerted integration starting from a blunt-ended as compared to a pre-processed DNA substrate 36. Furthermore, activity of IN is strongly dependent on its oligomeric state 144759. In contrast to 3'-processing which requires the dimeric form of IN 31, it was shown that concerted integration requires a tetrameric organization 32.

Both the 3'-processing and strand transfer reactions require a metallic cofactor. This cofactor may be Mn²⁺ or Mg²⁺, but Mg²⁺ is preferentially used in vivo. Indeed, there is considerable experimental evidence to suggest that Mg²⁺ is more physiologically relevant, particularly as the specificity of the reaction is much greater in the presence of this cation: (i) IN displays strong non-specific nuclease activity in the presence of Mn²⁺ 6061. (ii) The tolerance of sequence variation at the ends of the viral DNA molecule is much greater in the presence of Mn²⁺ than in the presence of Mg²⁺ 1548. (iii) Many IN mutations remain silent in the presence of Mn²⁺ but not in the presence of Mg²⁺. For example, mutations of the HHCC domain that are deleterious to the virus in vivo affect 3'-processing and integration activities in in vitro tests using Mg²⁺, but have no such effect in tests using Mn²⁺ 6263. Furthermore, zinc has no stimulatory effect on IN activity when using Mn²⁺ as a cofactor while zinc stimulates the Mg²⁺-dependent activity 14. In the Pearson Hard-Soft Acid-Base theory (HSBA), hards metal ions such as Mg²⁺ (with d⁰ electron configuration) are characterized by electron clouds which are not easily deformed, in contrast to soft metals ions such as Mn²⁺, with direct consequences on the active site plasticity and reaction specificity for many metal-dependent enzymes when comparing their activities under either Mg²⁺ or Mn²⁺ context. The presence of Mg²⁺ generally leads to more stringent conditions for catalysis in term of reaction specificity as found for RAG1/2 proteins 64, Tn10 transposase 65, RNase H activity 66. HIV-1 integrase also displays such a differential qualitative behaviour between Mg²⁺ and Mn²⁺-dependent catalysis. It was also reported that IN/DNA complexes display different stabilities depending on the cofactor context with IN/DNA complexes being more stable in the presence of Mn²⁺ than in the presence of Mg²⁺ 676869. Such a differential stability of complexes is generally observed using IN purified in the presence of detergent and accounts for quantitative differences in term of enzymatic activity when comparing Mg²⁺ and Mn²⁺. Indeed, IN from detergent-containing preparations displays more Mn²⁺-dependant than Mg²⁺-dependant activity as compared to detergent-free preparations that quantitatively display similar activities. The difference between cofactors has pharmacological implications, as the apparent efficacy of various IN inhibitors differs between tests using Mg²⁺ or Mn²⁺ as a cofactor 707172, and the effects of mutations conferring drug resistance are often detectable only in tests using Mg²⁺ as the cofactor 73. These considerations have led to the use of chemical groups chelating Mg²⁺ in the rational design of integrase inhibitors. Such groups are present in all the inhibitors developed to date, including raltegravir and elvitegravir 1.

Whatever the activity tested, IN is characterized by an overall slow cleavage efficiency. Furthermore, IN form stable complexes with both DNA substrate and DNA product, limiting multiple turnover 74. Taken together, these features resemble to those observed for other polynucleotidyl-tranferases such as transposases. These enzymes share a peculiar enzymatic property: they have evolved to catalyse multi-sequential steps (two reactions for IN and four for Tn5 transposase) in a single active site. A multi-sequential reaction requires a strong binding of the enzyme to the DNA product after each chemical step to optimise the entire process but consequently diminishes the overall enzymatic efficacy in term of turnover. However, this weak catalytic activity is not detrimental for these enzymes in the cellular context, because a single event of integration or transposition is sufficient for the overall function. In vivo, this tight binding of IN to the viral processed DNA most likely allows the complex to remain associated after the 3'-processing reaction long enough for subsequent integration. Two strategies have been considered for the development of IN inhibitors: screening using the unbound protein (before complex formation) or screening with the preformed IN-viral DNA complex. The success of these two approaches has been demonstrated by the identification of (i) inhibitors of 3'-processing targeting the DNA free enzyme and blocking its binding to the viral DNA 75 and (ii) inhibitors of strand transfer targeting the preformed complex more related to the preintegration complex (PIC) 76. These two families of compounds are respectively called INBI (

IN

B

I

IN S

T

I

The presence either of the catechol or an another group on the SQLs able to form a complex of coordination with a divalent ion suggests that these compounds interact with the active site of the enzyme by a chelation with the metallic cofactor. These compounds are mainly inhibitors of the 3'-processing reaction, and their mechanism of action in vitro can be assimilated to a competitive mechanism. Recently, experiments based on fluorescence anisotropy demonstrated that SQLs are DNA-binding inhibitors of HIV-1 IN 75. In summary, INBI compounds primarily compete with the binding of the donor DNA (viral DNA) while INSTI compounds compete with the binding of the acceptor DNA (target DNA). However, the mechanism of inhibition of SQLs in the cell context is not completely understood. These compounds appear to act at steps prior to integration, more particularly during RT 82 and nuclear import 83. These effects are mediated by IN as evidenced by the appearance of resistance mutation in IN sequence. It is then suggested that, ex vivo, non catalytic region of IN are targeted by SQs (see paragraph "non catalytic role of IN"). It is interesting to note that the two classes of IN inhibitors, INBI and INSTI, induce distinct resistant mutations 7682848586.

A third reaction, disintegration, is observed in vitro (Fig 1). Disintegration may be considered to be the reverse of the strand transfer reaction 2. Unlike the 3'-processing and strand transfer reactions which requires the full-length protein, the disintegration reaction can be catalysed by the catalytic domain alone (IN^55–212) or by truncated proteins, IN^1–212 or IN^55–288 478788. This activity was widely used for testing the competitive mechanisms of certain inhibitors. There is currently no experimental evidence to suggest that this reaction occurs in vivo.

Recently, our group has identified a new internal and specific cleavage activity in vitro of HIV-1 IN 3. Until now, all attempts to study a specific internal endonucleolytic cleavage in vitro have failed. Vink et al. have demonstrated that when the CA dinucleotide, indispensable for the 3'-processing, was separated by more than 2 nucleotides from the 3'-OH end, the activity was dramatically impaired 89. Nevertheless, we have demonstrated that oligonucleotides mimicking the palindromic sequence found at the LTR-LTR junction of the 2-LTR circles (found in infected cells) were efficiently cleaved at internal positions by HIV-1 IN, with cleavage kinetics comparable to the 3'-processing reaction (Fig 1). This reaction occurs symmetrically on both strands, with a strong cleavage at the CA dinucleotide (corresponding to the CA sequence used for the 3'-processing reaction). A second weaker cleavage site appears after the next adenine (TA sequence) in the 5'-3' direction. Furthermore, HIV-1 IN can efficiently cleave a plasmid mimicking the 2-LTR circles specifically at the LTR-LTR junction. The specificity of this reaction is similar to the one catalysed by transposases which cleave the DNA substrate after a CA or TA dinucleotide 90. Such internal cleavages are not observed using a mutant of the catalytic site (E152A) testifying that the DDE triad is also implicated in this reaction. In addition, this novel activity is stringent and highly specific as (i) it occurs with the physiological metallic cofactor (Mg²⁺) and not only Mn²⁺, (ii) only the full-length IN is competent for the internal cleavage of the palindrome, in contrast to the disintegration reaction that is efficiently catalysed by truncated proteins such as IN^55–212, IN^55–288, IN^1–212 and (iii) it does not sustain any mutation in the sequence of the LTR-LTR junction. Furthermore, the cleavage of the LTR-LTR junction requires the tetrameric forms of IN whereas the 3'-processing reaction is efficiently catalysed by a dimer 3132. This new activity seems to be generalised to other retroviral IN as reported earlier for PFV-1 IN 9192. However, although PFV-1 IN performs this cleavage activity, it is important to note that both IN are strictly restricted to their own cognate palindromic sequence: HIV-1 IN is unable to cleave the PFV LTR-LTR junction and PFV-1 IN is unable to cleave the HIV-1 LTR-LTR junction.

Recently, mapping of extensive integration sites, notably for HIV-1, put in light the existence of a weak palindromic consensus 444546. It is important to note that the sequence of the weak palindromic consensus is similar, although not identical, to the one found at the LTR-LTR junction. This specific endonucleolytic activity on a palindromic LTR-LTR junction as well as the symmetrical organization of integration sites reveal a common structural feature of IN: IN intrinsically prefers to bind to symmetric DNA sequences. Moreover, we have found that tetramers catalyses the cleavage of the palindromic sequence while others have suggested that the same oligomeric form is responsible for the concerted integration in the context of the synaptic complex 3536. Therefore, one could reasonably imagine that the same multimeric organization of IN (i.e. the tetrameric form) is stabilised by a corresponding symmetry at the DNA level, either at the viral DNA (LTR-LTR junction) or at the target level (integration sites).

In vivo, unintegrated viral DNA could represent 99% of total viral DNA in infected cells 93 underlying that integration is a rare event. Un-integrated DNA is mainly linear but also circular – 1-LTR or 2-LTR circles. In the absence of integration (for example using strand-transfer inhibitors such as diketo acids), at least the 2-LTR circular forms of viral DNA, which are usually believed to be dead-end molecules, are accumulated 94. It is tempting to speculate about a possible role of 2-LTR circles in a subsequent integration process after removing the drug pressure, mediated by the ability of IN to cleave the LTR-LTR junction. However, to date, although IN is able to cleave the LTR-LTR junction in vitro, there is no proof that such a cleavage can occur in vivo and thus that 2-LTR circles could be an efficient precursor for integration.

Several cellular and viral proteins have been reported to stimulate IN activities in vitro as well as in vivo. Among these cofactors, some proteins are known to interact directly with IN and thus enhance its solubility or favours an active conformation of IN, while other proteins do not physically interact with IN but could indirectly stimulate IN activities as found for proteins playing a structural role on DNA conformation.

For instance, in the group of IN interactors, the yeast chaperoning protein, yHSP60, was described by Parissi and colleagues to interact directly with HIV-1 IN 95. It has also been demonstrated that the human counterpart of the yHSP60, hHSP60, was able to stimulate the in vitro processing as well as joining activities of IN, suggesting that hHSP60-IN interaction could allow IN to adopt a more competent conformation for activity or prevent IN from aggregation 95. However, further investigations must be done to confirm the potential role of HSP60 in the viral life cycle.

LEDGF/p75, Lens Epithelial Derived Growth Factor, has been reported to interact with IN and stimulate both concerted integration and strand transfer. Addition of recombinant LEDGF/p75 to an in vitro mini HIV-based IN assay enhanced the strand transfer activity of the recombinant HIV-1 IN 56. This stimulation is highly dependent of the ratio between IN and LEDGF used for the reaction 58. Probably, LEDGF/p75 has a double effect on IN. The first one is similar to the one described for HSP60. Indeed, it was shown that LEDGF-IN complex displays a more favourable solubility profiles as compared to the free IN 96. In the same publication, a second effect could explain the enhancement of IN activity as LEDGF/p75 binding to DNA concomitantly increases IN-DNA affinity 96. Concerning more specifically the concerted integration, it has been reported that LEDGF increases the stabilisation of the tetrameric state of IN which is responsible for the concerted integration 97. In vivo, LEDGF displays an important role in the targeting of the viral integration 98 (see also # 2.5).

It is important to note that IN activity is also highly regulated by the structure of the viral and host DNA substrates which can be influenced by protein interactions on DNA. Pruss et al. studied the propensity of IN to integrate an oligonucleotide mimicking the HIV LTR into either DNA molecules of known structure or nucleosomal complexes 99100. Results highlight that the structure of the target greatly influences the site of integration, and that DNA curvature, flexibility/rigidity in solution, all parameters influence the frequency of integration. Furthermore, using a model target comprising a 13-nucleosome extended array that includes binding sites for specific transcription factors and which can be compacted into a higher-ordered structure, Taganov et al. demonstrated that the efficiency of the in vitro integration was decreased after compaction of this target with histone H1 101. Consequently, both intrinsic DNA structure and the folding of DNA into chromosomal structures will exert a major influence on both catalysis efficiency and target site selection for the viral genome integration. The structure of the viral DNA also greatly influences IN activity 102, as illustrated by alterations in the minor groove of the viral DNA which result in a greater decrease in 3'-processing activity than major groove substitutions, suggesting a great importance of the structure of the viral DNA for IN activities.

Several cellular proteins greatly influence the structure of the viral DNA and thus modulate IN activities. For example, BAF (Barrier-to-autointegration factor), a component of the functional HIV-1 pre-integration complex, stimulates the integration reaction in the PIC complex 103104. The effect of BAF on integration is probably due, in vitro, to its DNA binding activity and its effect on the viral DNA structure 105. HMG I(Y), a protein partner of the HIV-1 PICs, has been also described to stimulate concerted integration in vitro. Li and colleagues demonstrated that HMG I(Y) can condense model HIV-1 cDNA in vitro, possibly by approximating both LTR ends and facilitating IN binding by unwinding the LTR termini 106. These data suggest that binding of HMG I(Y) to multiple cDNA sites compacts retroviral cDNA, thereby promoting formation of active integrase-cDNA complexes 106. In addition, Carteau and colleagues led to the finding that concerted integration can be stimulated more than 1,000-fold in the presence of the nucleocapsid protein in comparison to integrase alone under some conditions of reaction 54. To date, the effect of the NC on concerted integration is not clear but is probably due its capability to promote DNA distorsion.

Another IN cofactor, INI-1 (Integrase Interactor 1), has been described to enhance IN activity probably by structural and topological effect on DNA. INI-1, is one of the core subunits of the ATP-dependent chromatin remodelling complex SWI/SNF that regulates expression of numerous eukaryotic genes by altering DNA/histone interaction. INI-1 was identified by a two-hybrid system that binds to IN and enhances the strand transfer activity of the protein 107. Taking into account that INI-1 interacts with IN, it is not excluded that a solubility effect induced by protein-protein interaction may account for the stimulation effect on IN activity as reported for LEDGF/p75. It is important to note that conflicting results concerning the role of INI-1 in the HIV-1 life cycle have been reported. It has been described that SNF5/INI-1 interferes with early steps of HIV-1 replication 108. Boese and colleagues found no effects on viral integration in cells depleted for INI-1 109, whereas it has been proposed that INI-1 was required for efficient activation of Tat-mediated transcription 110. The comprehension of the role of such IN partners, as well as the discovery of novel partners will be crucial to reproduce more authentic integrase complexes for mechanistic studies and development of IN inhibitors.

Additionally, interactions between IN and cellular protein partners play key role in the targeting of integration. A systematic study of the sites of HIV DNA integration into the host DNA has shown that integration is not entirely random. Analysis of integration sites in vivo indicates that HIV tends to integrate into sites of active transcription 43. It is likely that this integration bias results from interactions between PICs and components of cellular origin in relationship with the chromatin tethering. Several cellular cofactors, including INI-1 107111, BAF 103112, Ku 113 and LEDGF/p75 114, are known to interact with the PIC in the nucleus. Among these proteins, at least INI-1 and LEDGF/p75 physically interact with IN 107115. Recent work with LEDGF/p75 strongly suggests that this cofactor is actually responsible for targeting integration 11. LEDGF/p75 silencing modifies the bias from transcription units to CpG islands 43116. As LEDGF/p75 is essential for HIV-1 replication and LEDGF/p75 interacts directly with IN, the domain of interaction between these two proteins is therefore a promising target for the development of integrase ligands with antiviral activity. Although no direct interaction between IN and BAF or Ku was described, it is suggested that these two cofactors could influence the profile or efficiency of integration 117118. For example, interaction of BAF with emerin, an internal-inner-nuclear-envelope protein, could favour the access of the PIC to the chromatin and thus facilitate integration 119. In relationship with chromatin, it was recently described that the C-terminal domain of IN is acetylated by a histone acetyl transferase (HAT) 120. However, the effect of IN acetylation on integration in vivo remains unclear 121.