Dissecting the Role of the N-Terminal Domain of Human Immunodeficiency Virus Integrase by trans-Complementation Analysis

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Journal of Virology, April 1999, p. 3176-3183, Vol. 73, No. 4
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Dissecting the Role of the N-Terminal Domain of Human Immunodeficiency Virus Integrase by trans-Complementation Analysis

Fusinita M. I. van den Ent, Arnold Vos, and Ronald H. A. Plasterk^*

Division of Molecular Biology, The Netherlands Cancer Institute, 1066 CX Amsterdam, The Netherlands

Received 4 September 1998/Accepted 18 January 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The human immunodeficiency virus (HIV) integrase protein (IN) catalyzes two reactions required to integrate HIV DNA into thehuman genome: 3' processing of the viral DNA ends and integration.IN has three domains, the N-terminal zinc-binding domain, thecatalytic core, and the C-terminal SH3 domain. Previously, itwas shown that IN proteins mutated in different domains couldcomplement each other. We now report that this does not requireany overlap between the two complementing proteins; an N-terminaldomain, provided in trans, can restore IN activity of a mutantlacking this domain. Only the zinc-coordinating form of the N-terminaldomain can efficiently restore IN activity of an N-terminal deletionmutant. This suggests that interaction between different domainsof IN is needed for functional multimerization. We find that theN-terminal domain of feline immunodeficiency virus IN can supportIN activity of an N-terminal deletion mutant of HIV type 2 IN.These cross-complementation experiments indicate that the N-terminaldomain contributes to the recognition of specific viral DNAends.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Integration of the viral DNA into a chromosome of an infected cell is essential for replication of the human immunodeficiencyvirus (HIV). The integration process is catalyzed by the integraseprotein (IN) and consists of two steps. In the first step, usuallytwo nucleotides are removed from the 3' ends of the viral DNA(cleavage reaction). In the second step, the newly generated 3'hydroxyl groups of the viral DNA are coupled to phosphate groupson opposite strands of the target DNA (integration or strand transferreaction). The single-stranded gaps flanking the integrated viralDNA are repaired, probably by cellular enzymes. The resultingprovirus is flanked by a 5-bp direct duplication of target DNA.(For recent reviews on retroviral integration, see references1, 34, 50, and 69.)

Purified, recombinant IN mediates cleavage and integration of oligonucleotides that mimic the viral DNA ends (6, 10,33). In the cleavage reaction, IN makes a specific phosphodiesterbond near the viral DNA ends accessible for nucleophilic attack.In vitro, several hydroxyl group-containing compounds can serveas the nucleophile, such as water, glycerol, or the 3' ends ofthe viral DNA (25, 73). The choice of nucleophile varies betweendifferent INs and can be affected by substitutions of residuesaround the active site (14, 21, 23, 46, 61, 64, 71).Besides cleavage and integration, IN can also mediate a phosphoryltransfer reaction, called disintegration (9). The substrateof the disintegration reaction is similar to the product of theintegration of viral DNA ends into target DNA. IN releases theviral DNA in the disintegration reaction and restores the targetDNA. In contrast to the integration reaction, disintegration activitydoes not require specific viral DNA ends; IN can still catalyzethis reaction when the viral DNA ends are replaced by a singleA nucleotide (9) or by random sequences (60).

Two amino acid sequence motifs are conserved among retroviral and retrotransposon IN proteins (37, 38). The N-terminaldomain contains a phylogenetically conserved motif, His(X_3-7)His(X_23-32)Cys(X₂)Cys(13, 32, 37) that coordinates a zinc ion (5, 7). Theprecise role of the N-terminal domain in the integration processis unknown. Some studies suggested that it is involved in protein-proteininteractions, whereas other experiments indicate that it contributesto substrate specificity. Structure elucidation of the N terminusshowed that it consists of three-helix bundles that are stabilizedby Zn²⁺ (8, 18). Although its fold is similar to that of DNA-bindingproteins, such as the Trp repressor, no direct DNA binding bythe N-terminal domain has been observed (37, 47, 56, 74).Zinc induces tetramerization in the full-length protein and enhancesMg²⁺-dependent IN activity (42, 43, 77). This suggests thatthe N-terminal domain either contributes to intersubunit contactswithin the tetramer or has an allosteric effect on IN that favorstetramerization of the protein. Deletion of the N-terminal domainabolishes Mn²⁺-dependent aggregation of HIV type 1 (HIV-1) IN (20), againsuggesting a possible role of the N-terminal domain in protein-proteininteraction. Mutagenesis of the zinc-coordinating residues reducescleavage up to 90%, whereas integration activity is less affected(23, 63). The HHCC motif may therefore be involved in correctpositioning of the viral DNA ends for the 3' processing reaction.Disintegration activity of mutants in the N-terminal domain onvarious substrates have indicated that the viral DNA sequencesinternal to the conserved CA are recognized by the N-terminaldomain (67).

The second conserved motif of IN is located in the core of the protein (amino acids 50 to 212). This motif, the acidic triadDD(35)E, is found in all retroviruses, retrotransposons, and sometransposases (23, 26, 38, 49, 54). Mutational analyseshave shown that replacement of these acidic residues impairs allIN activities (7, 15, 23, 38, 41, 63). This indicatesthat the DD(35)E motif is part of a single active site of IN.Elucidation of the three-dimensional structure of the core ofHIV-1 IN (16) and of avian sarcoma virus IN (3) revealedthat IN is a member of a group of structurally related polynucleotidyltransferases (53, 76). It has been shown for avian sarcomavirus IN that two Asp residues of the active site coordinate onemetal ion (Mn²⁺ or Mg²⁺) (4). The core domain of IN determines target site selectionand is involved in binding of the viral DNA termini (27-29, 31,35, 36, 57).

The C terminus of IN (amino acids 220 to 270) is the least conserved domain. It binds DNA nonspecifically (24, 37, 52,68, 74), and its structure is similar to that of Src homology3 (SH3) domains (17, 44). Mutations in the dimer interfaceof the C-terminal domain can affect oligomerization of the full-lengthprotein (51).

Previously, it has been demonstrated that certain combinations of inactive proteins restore IN activity (22, 65). Mutationsin different domains can rescue each other, indicating that eachdomain belongs to a separate complementation group. This suggeststhat IN is active as a dimer or higher-order oligomer. All threedomains form dimers themselves (8, 16-18, 44). If the intraproteincomplementation were to depend on this, one would predict thatno functional IN can be formed when an N-terminal domain is mixedwith an IN from which the complete N-terminal domain has beenremoved, since no oligomerization can happen between the two mutantproteins. To investigate whether the N-terminal domain can functionin trans, we did complementation experiments using an N-terminaldomain and an N-terminal deletion mutant. We show that a structuralN-terminal domain restores IN activity of an N-terminal deletionmutant. This suggests that for IN activity, interaction betweenthe N-terminal domain and another IN domain is required. In cross-complementationexperiments between feline immunodeficiency virus (FIV) and HIVIN mutants, we demonstrate that the N terminus of FIV IN can restoreIN activity of an N-terminal deletion mutant of HIV-2 IN. By usingdifferent substrates, we found that the N-terminal domain contributesto specific recognition of the viral DNAends.

	MATERIALS AND METHODS

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Construction of protein expression vectors. The HIV-2 IN gene of pRP279 (62) was cloned into pET-15b vector (Novagen, Madison, Wis.). In the resulting plasmid (pRP1013),the HIV-2 IN gene is fused at its 5' end to the 3' end of a Histag and a thrombin cleavage site. The IN gene of FIV was amplifiedby PCR from pRP817 (71) by using oligonucleotides 93M313 (5'-GGACGCATATGTCCTCTTGGGTTGACAGAATTG-3')and 93M312 (5'-CCTGCGGATCCTCACTCATCCCCTTCAGGAAG-3'). The PCR productwas purified, digested with NdeI and BamHI, and ligated into theNdeI/BamHI-digested vector pET3c, resulting in plasmid pRP824.A double-stranded oligonucleotide (4030/4031) containing codonsfor six His residues was cloned into NdeI-digested pRP824, resultingin plasmid pRP825. The sequence of oligonucleotide 4030 is 5'-TATGAGAGGATCGCATCACCATCACCATCACAGATC-3';that of oligonucleotide 4031 is 5'-TAGATCTGTGATGGTGATGGTGATGCGATCCTCTCA-3'.The N-terminal deletion mutant of HIV-2 IN (amino acids 50 to293) was cloned by PCR using 95A2537 (5'-CGGGGAACATATGCATGGGCAAGTAAATGCAGAAC-3')as the forward primer and a reverse primer identical to the T7terminator sequence (5'-GCTAGTTATTGCTCAGCGGTGGATCCATC-3'). ThePCR product was cloned into pET-15b, resulting in plasmid pRP1707.The N terminus of FIV IN was amplified by PCR and fused in frameat its 5' end to the 3' end of the glutathione S-transferase genein vector pGEX-2T, resulting in plasmid pRP1713. Cloning of theN-terminal domain of HIV-2 IN has been published previously (18).Mutagenesis of the N-terminal domain of HIV-2 IN was done by thesame procedure as that described for site-directed mutagenesis(61). Mutant clones were verified bysequencing.

Protein expression and purification. Full-length INs from HIV-2 and FIV were expressed and purified as described previously (61). Purification of the N-terminaldomain of FIV IN was done as described for the N-terminal domainof HIV-2 IN (18). The N-terminal deletion mutant derived fromHIV-2 IN was expressed and purified as follows: plasmid pRP1707was introduced into E. coli BL21(DE3), containing the plasmidpLysS (55, 58). An overnight culture of this strain was diluted1:200 in 2 liters of TB medium (55) containing ampicillin andchloramphenicol. The culture was grown at 37°C to an optical densityat 615 nm of 0.8. Protein expression was induced by the additionof isopropyl- $beta$ -D-thiogalactopyranoside (IPTG) at a final concentrationof 0.4 mM. The bacteria were harvested after 3 h by centrifugationand resuspended in 30 ml of buffer A (50 mM HEPES [pH 7.5], 1mM EDTA, 3 mM $beta$ -mercaptoethanol). The cell suspension was sonicatedand centrifuged for 30 min at 15,000 × g (SS34 rotor; Beckman).The pellet was Dounce homogenized in 30 ml of buffer B (20 mMTris-HCl [pH 6.7], 1 M NaCl, 0.1 mM EDTA, 3 mM $beta$ -mercaptoethanol)and rotated for 15 min at 4°C in the presence of 0.1% Tween 20-5mM imidazole (pH 6.7). The supernatant was cleared by a 30-minspin at 15,000 × g (SS34 rotor; Beckman) and bound to 2 ml ofNi²⁺-nitrilotriacetic acid agarose beads (Qiagen) for 2 h. The beadswere packed into a column, washed with 20 ml of buffer B, whichhad been supplemented with 0.1% Tween 20 and 20 mM imidazole (pH6.7), and subsequently washed with 20 ml of buffer B containing20 mM imidazole (pH 6.7). The protein was eluted with buffer B,which had been supplemented with 10% glycerol and 200 mM imidazole(pH 6.7). Fractions containing the N-terminal deletion mutantwere dialyzed against buffer C (0.5 M NaCl, 20 mM Tris-HCl [pH6.7], 3 mM $beta$ -mercaptoethanol), and the His tag was removed bythrombin digestion overnight (approximately 0.5 NIH units/mg ofprotein). The protein fraction that still contained a His tagwas removed by the addition of 50 µl of Ni²⁺-nitrilotriacetic acid agarose beads (Qiagen). Thrombin was removedby incubating the protein with benzamidine-Sepharose 6B (Pharmacia).The purified protein was dialyzed to 1 M NaCl-20 mM Tris-HCl (pH7.6)-1 mM EDTA and coupled to thiopropyl-Sepharose (Pharmacia).After 2.5 h of incubation, the beads were washed with buffer D(10 mM morpholinepropanesulfonic acid [MOPS; pH 7.2], 0.5 mM dithithreitol,10% glycerol) and stored as a 50% slurry in buffer D at $-$ 80°C.

Size exclusion chromatography. The oligomeric state of the N-terminal domains of the FIV and HIV-2 IN mutants was analyzed on a Superdex 75 HR 10/30 column(Pharmacia) in a buffer containing 150 mM NaCl, 50 mM Tris-HCl(pH 6.7), 3 mM $beta$ -mercaptoethanol, and 4 µM ZnCl₂. After centrifugationof the sample at 15,000 rpm (in an Eppendorf Microfuge), 100 µlof 0.4 mM protein was injected. The size exclusion column wascalibrated with the following globular proteins, unless statedotherwise: 100 µg of aprotinin (6.5 kDa), 125 µg of RNase A (13.7kDa), and 55 µg of chymotrypsinogen (25 kDa). Protein elutionwas done at a flow rate of 0.5 ml/min and monitored by UV absorptionat 280 nm. Several runs were performed for each protein, in parallelto a wild-type run. A representative profile is shown in Fig.3a and 5a.

Cleavage, integration, and disintegration assays. Cleavage and integration assays were done with oligonucleotides that mimic the viral DNA ends of HIV-2 (63), FIV (71),and Moloney murine leukemia virus (MoMLV) (71). Oligonucleotideswere labeled at the 5' end as described previously (72). Thedisintegration substrate represents an integration intermediatein which two oligonucleotides representing the U5 and U3 endsof the HIV long terminal repeats are integrated into a targetDNA oligonucleotide (60). Prior to each complementation reaction,the proteins were mixed and incubated on ice for 30 min. The reactionvolume was 10 µl and contained 0.02 µM oligonucleotide substrate,20 mM MOPS (pH 7.2), 3 mM dithiothreitol, 1 mM MnCl₂, 0.1 µg ofbovine serum albumin/µl, and approximately 3 pmol of HIV-2 INor FIV IN, 7 pmol of an N-terminal deletion mutant coupled tothiopropyl-Sepharose, and 20 pmol to 2 nmol of the N-terminaldomain of HIV-2 IN or FIV IN. Cleavage and integration reactionmixtures were incubated at 37°C, and disintegration was carriedout at 30°C. Reactions were stopped after 1 h by the additionof formamide loading dye (95% formamide, 20 mM EDTA, 0.05% bromophenolblue, 0.05% xylene cyanol), and the mixtures were incubated at80°C for 5 min. The samples were analyzed by denaturing polyacrylamidegel electrophoresis followed byautoradiography.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Complementation between the N terminus and an N-terminal deletion mutant. Structural studies have shown that the N-terminal domain of IN (IN_1-55) exists as a dimer in solution and that zincbinding is required for complete folding of this domain (8,18). However, whether the structured N-terminal domain has aconformation that is active is not known. To address this question,we overexpressed and purified the 55-amino-acid N-terminal domainof HIV-2 IN and mixed it with a deletion mutant lacking the N-terminalregion ( $Delta$ N mutant; amino acids 50 to 293) (Fig. 1a). As shownin Fig. 1b, IN_1-55 restores integration activity of a $Delta$ Nmutant, which by itself is inactive. Integration activity increaseswith increasing concentrations of IN_1-55. These resultsshow that IN_1-55 has an active conformation.

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FIG. 1. (a) Schematic representation of the three domains of HIV-2 IN. The N-terminal domain contains a helix-turn-helix motif (HTH) and the zinc-coordinating residues HHCC. The catalytic core (spanning amino acids to 50 to 212) has the three active site residues DD(35)E. The C-terminal nonspecific DNA binding domain has an SH3-like fold. For complementation experiments, the N-terminal domain (IN_1-55, spanning amino acids 1 to 55) of HIV-2 IN is mixed with the N-terminal deletion mutant of HIV-2 IN ( $Delta$ N, comprising amino acids 50 to 293). (b) Complementation between an N-terminal deletion mutant of HIV-2 IN ( $Delta$ N HIV) and the N-terminal domain of HIV-2 IN (IN₅₅). In the left lane, IN₅₅ is omitted from the reaction; in the middle and right lanes, increasing amounts of IN₅₅ (20 and 200 pmol) are mixed with the N-terminal deletion mutant (7 pmol) prior to the reaction (see Materials and Methods). The substrate (S) represents the precleaved HIV-2 U5 end; strand transfer products are indicated on the left (P).

Thus far, complementation assays were done with mutant proteins that have an extensive region in common (12, 22, 65).It was unknown whether the common region is needed for the interactionbetween the mutant proteins or that multimerization occurred betweendifferent domains of IN. Here, we show that two mutant proteinswithout an extensive overlap (only six amino acids) are activewhen mixed together in an activity assay. This implies that interactionbetween different domains is essential for formation of a functionalmultimeric complex, either directly or viaDNA.

Previously, it has been shown that IN can release viral DNA ends from an integration intermediate (9). This can be donein two ways (Fig. 2). In the intermolecular disintegration reaction,the 3' hydroxyl group of the target DNA attacks the phosphodiesterbond of the viral DNA-target DNA junction of the opposite halfmolecule. In the intramolecular disintegration reaction, thisphosphodiester bond is attacked by the 3' hydroxyl group of thetarget DNA in the same half molecule (9, 45). For catalysisof the intramolecular disintegration reaction, specific viralDNA sequences are important (11, 60). The intermolecular disintegrationreaction is independent of specific viral DNA sequences (9,11, 60) and can be catalyzed by the core domain of IN alone(7, 68). Here, we show that IN_1-55 enhances intramoleculardisintegration activity of a $Delta$ N mutant (Fig. 2, lanes 3 to 5).The intermolecular disintegration activity remains the same. Whenthe concentration of IN_1-55 is 200 µM, disintegration activityis lost (lane 6).

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FIG. 2. Disintegration activity in a complementation assay between the N-terminal deletion mutant of HIV-2 ( $Delta$ N HIV) and the N-terminal domain of HIV-2 IN (IN₅₅). The disintegration substrate was incubated with 2 nmol of ZnCl₂ (lane 1), 2 nmol of IN₅₅ (lane 2), and the N-terminal deletion mutant without IN₅₅ (7 pmol) (lane 3) or with increasing amounts of IN₅₅ (20 pmol, 200 pmol, and 2 nmol [lanes 4 to 6, respectively]). In lane 7, part of the reaction mixture from lane 2 was extracted with phenol and chloroform. The substrate is shown on the right with an arrow indicating the product of the intermolecular disintegration reaction (labeled intermolecular) or to the product of the intramolecular disintegration reaction (intramolecular). The substrate itself runs as a 10-mer on a denaturing 20% polyacrylamide gel. The arrow on the left indicates the migration position of the IN_1-55-dependent band.

Under these conditions, a new band appears; this band is dependent on the presence of IN_1-55 and appears at high concentrations(Fig. 2, lane 2). Incubation of the disintegration substrate withthe $Delta$ N mutant (lane 3) or with zinc (lane 1) does not result inthe formation of this band. The interaction between IN_1-55and the disintegration substrate is disrupted by extraction withphenol and chloroform (lane 7). The IN_1-55-dependent bandand the substrate were eluted from the gel and precipitated withethanol. Mung bean nuclease digestion showed that this band isnot the result of a newly formed covalent bond in the DNA backbone(data not shown). The nature of this band remains mysterious (seeDiscussion).

Only a well-structured N-terminal domain is active in a complementation assay. Coordination of zinc by two His and two Cys residues is required for a completely structured IN_1-55 (8, 18). BothHIV-1 IN_1-55 and HIV-2 IN_1-55 elute at the dimer positionfrom a gel filtration column (data not shown and reference 18).The dimer interface of HIV-1 IN_1-55 contains residues ofthe first and third helix (8). We mutated residues in HIV-2IN_1-55 that are either involved in zinc coordination orpart of the putative dimer interface. Mutant proteins were subjectedto gel filtration experiments and tested for activity in the complementationassay. Gel filtration experiments show that replacement of oneof the His residues (H12L) results in a partially disordered IN_1-55(Fig. 3a, compare profiles A and D). The mutant protein containingsubstitutions of residues in the putative dimer interface elutesearlier from the gel filtration column than wild-type IN_1-55,indicating that this protein no longer has a globular shape likewild-type IN_1-55 (profile B). Replacement of the first residue(F1E) results in a shift of the elution profile towards the unfoldedprotein, but not as dramatic a shift as that of mutant B, whichcontains additional substitutions. Mutant proteins containingsubstitutions in the dimer interface do not have the expectedprofile of a globular monomer of 6.3 kDa. Although we replacedall residues of the dimer interface with nonconservative aminoacids and introduced them alone or in different combinations intoIN_1-55, a globular monomer was never observed. This couldindicate that a globular form of IN_1-55 can only be dimeric.Mutant proteins were tested for complementation activity. As shownin Fig. 3b, replacement of one of the His residues of the zincbinding unit abolishes complementation activity (Fig. 3b, comparetwo-lane panels A and D). Also, substituting residues in the putativedimer interface of the N terminus of HIV-2 IN impairs complementationactivity (Fig. 3b, two-lane panel B). Taken together, these resultsindicate that only the structured form of IN_1-55 is ableto complement the $Delta$ N mutant.

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FIG. 3. (a) Size exclusion chromatography of mutant proteins of the N-terminal domain of HIV-2 IN (amino acids 1 to 55). Proteins were injected on a Superdex 75 HR 10/30 column (Pharmacia), which had been equilibrated in buffer G (150 mM NaCl, 50 mM Tris-HCl [pH 6.7], 3 mM $beta$ -mercaptoethanol, 4 µM ZnCl₂). The following markers were used: aprotinin (6.5 kDa, 100 µg), RNase A (13.7 kDa, 125 µg), and chymotrypsinogen (25 kDa, 55 µg). Elution profiles are of the following proteins: wild-type IN₅₅ (profile A), mutant F1E;L2D;I5A (profile B), mutant F1E (profile C), and mutant H12L (profile D). Profile E is of the mutant F1E in IN_1-55 in the presence of 4 mM EDTA. All proteins were injected at a concentration of 0.4 mM. The retention time in minutes is indicated on the X axis, and the absorption at 280 nm (A₂₈₀, in arbitrary units) is shown in the Y axis. (b) Complementation between the N-terminal deletion mutant of HIV-2 IN ( $Delta$ N HIV) and several mutants of the N-terminal domain of HIV-2 IN (IN₅₅). In the first and second lanes, only IN₅₅ or $Delta$ N is present in the reaction. The N-terminal deletion mutant was incubated with the mutants of profiles A to D of IN₅₅ (see description for panel a), prior to the integration reaction. In each two-lane panel, increasing amounts of IN₅₅ protein were added (20 and 200 pmol, respectively). The migration positions of the substrate (S) and strand transfer products (P) are indicated on the left.

Although complementation experiments were performed with the N-terminal deletion mutant coupled to thiopropyl-Sepharose, activitywas also observed with a soluble $Delta$ N mutant mixed with IN_1-55(data notshown).

Stable complex formation requires the N-terminal domain in cis. Previously, it has been shown that IN can form a stable complex with the viral DNA substrate (19, 70). This stable interactionbetween IN and viral DNA is dependent on metal ions and is notcompeted by an excess of nonspecific DNA or other polyanions,like poly(Asp⁵⁰, Glu⁵⁰). Deletion of the HHCC motif or chemical modification of Cys-65impairs assembly of the stable complex (20). We investigatedwhether a stable complex can be formed when IN_1-55 complementsthe $Delta$ N mutant in trans. As shown in Fig. 4, full-length IN bindsstably to viral DNA after incubation of the protein with Mn²⁺ and viral DNA ends. Competition by a 25 M excess of nonspecificDNA does not destroy this specific interaction. When IN is firstincubated with nonspecific DNA or nonlabeled viral DNA ends inthe presence of Mn²⁺, addition of viral DNA ends does not result in integration activity(Fig. 4, lanes 1 to 3). Under these conditions, full-length INbinds stably to nonlabeled DNA, which is consistent with previousreports (19, 70). When we do the same experiment in a complementationassay, we do not observe a difference in the order of additionof viral or nonspecific DNA (lanes 4 and 5). This indicates thatthe N terminus is required in cis to the remainder of the proteinin order to form a stable complex. Furthermore, these order-of-additionexperiments show that in a complementation assay, integrationoccurs even in the presence of an excess of nonspecific DNA, implyinga high on-off rate of initial DNA binding. Assuming that the on-offrate of DNA binding in the complementation assay is independentof the DNA sequence, one would expect the same integration activitywhether competition is done with nonlabeled viral or nonspecificDNA. To investigate this, we added a 25 M excess of nonlabeledviral DNA substrate to the reaction mixture, prior to the additionof radiolabeled substrate. As shown in Fig. 4, lane 6, the integrationactivity was reduced. This is in contrast to the competition withnonspecific DNA and suggests that the IN_1-55- $Delta$ N mutant complexbinds more tightly to specific DNA than to nonspecific DNA.

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FIG. 4. Stable complex formation between IN mutants and the integration substrate. The proteins were incubated with the reaction mixture containing 1 mM MnCl₂ for 5 min at t = 0', prior to the addition of 0.2 pmol of labeled integration substrate (*V; lanes 1 and 4), 5 pmol of nonspecific DNA (C; lanes 2 and 5), or 5 pmol of nonlabeled integration substrate (V; lanes 3 and 6). After 5 min (t = 5'), 5 pmol of nonspecific DNA was added to the reaction mixtures in lanes 1 and 4 and 0.2 pmol of labeled integration substrate was added to the reaction mixtures in lanes 2, 3, 5, and 6. Incubations were done at room temperature. The integration substrate (S) is radioactively labeled; integration products (P) are indicated. Stable complex formation of full-length HIV-2 IN is shown in lanes 1 to 3. The same experiment was done with an N-terminal deletion mutant of HIV-2 IN ( $Delta$ N HIV), which was mixed with the N-terminal domain of HIV-2 IN 30 min prior to the reaction (lanes 4 to 6).

Cross-complementation between HIV and FIV IN. The N-terminal domains of FIV and HIV-2 INs are 36% identical at the amino acid level. FIV IN contains two additional Serresidues at the N terminus. The N terminus of FIV IN (IN₅₇) wasoverexpressed and purified in the same way as has been done forIN_1-55 of HIV-2. As shown in Fig. 5a, the N-terminal domainof FIV IN elutes at the dimer position from a size exclusion column.

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FIG. 5. (a) Size exclusion chromatography of the N-terminal domain of FIV IN (IN₅₇). FIV IN_1-57 was injected at a concentration of 0.4 mM on a Superdex 75 HR 10/30 column (Pharmacia), which had been equilibrated in buffer G (see legend to Fig. 3a). Protein markers were injected prior to each experiment (see legend to Fig. 3a). The retention time (minutes is indicated on the X axis, and the absorption at 280 nm (A₂₈₀, in arbitrary units) is depicted on the y axis. (b) Cross-complementation between FIV and HIV-2 IN mutants. Integration activities of full-length HIV-2 IN and FIV IN are depicted in lanes 1 and 4, respectively. Prior to the integration assay, an N-terminal deletion mutant of HIV-2 IN ( $Delta$ N HIV) was mixed with the N-terminal domain of HIV-2 (HIV IN₅₅) or FIV IN (FIV IN₅₇) (lanes 2 and 3, respectively). The substrate (S) mimics the U5 end of FIV; integration products (P) are indicated.

We tested whether the N terminus of FIV IN can complement integration activity of a $Delta$ N mutant of HIV-2 IN. As shown in Fig.5b, FIV IN_1-55 can complement a $Delta$ N mutant of HIV-2 IN ata similar efficiency as in the complementation between HIV-2 IN_1-55and the $Delta$ N mutant of HIV-2 IN (lanes 2 and3).

Full-length IN proteins from HIV and FIV have different preferences for the sites of integration (Fig. 5b, lanes 1 and 4)(57, 71). Cross-complementation experiments show the sametarget site preference for an N-terminal deletion mutant of HIV-2IN that is complemented by either FIV IN_1-57 or HIV-2 IN_1-55(Fig. 5b, lanes 2 and 3). This indicates that the N-terminal domaindoes not control target site preference, which is in agreementwith results obtained with chimeric proteins between HIV-1 INand FIV IN (57).

It has been shown that the choice of nucleophile in the cleavage reaction is different for HIV IN and FIV IN (71). In across-complementation assay, the choice of nucleophile is independentof the source of the N-terminal domain (data not shown). Thisis consistent with results described elsewhere indicating thatresidues near the active site determine the choice of nucleophilein the cleavage reaction (23, 61, 64).

Cross-complementation activity on different substrates. Previous reports have indicated that the efficiency of 3' processing of different viral DNA substrates varies between HIV-1IN and FIV IN (71). The most pronounced difference was foundfor the MoMLV substrate; FIV IN cleaves this substrate much betterthan HIV IN (Fig. 6, lanes 5 and 6) (71). To address the questionof whether the N-terminal domain is involved in viral DNA recognition,a cross-complementation experiment was done using HIV-2 and MoMLVsubstrates. Protein concentrations were such that the efficiencyof 3' processing of HIV-2 substrate was similar in all reactions(Fig. 6, lanes 1 to 4). The same protein concentrations were usedin the cleavage reaction of MoMLV substrate (lanes 5 to 8). Forboth substrates, HIV IN_1-55 and FIV IN_1-57 can complementa $Delta$ N mutant in the 3' processing reaction. Under these conditionsthe HIV-2 substrate is cleaved at a similar rate in all reactions,whereas the MoMLV substrate is processed more efficiently by FIVIN than by HIV-2 IN (Fig. 6, lanes 1 and 2 and lanes 5 and 6,respectively). Moreover, cleavage of MoMLV substrate is more efficientwith FIV IN_1-57 than with HIV IN_1-57 in the complementationassay (lanes 7 and 8). This indicates that the N-terminal domainof IN is involved in recognition of the specific viral DNA ends.

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FIG. 6. Cross-complementation assay between FIV and HIV-2 mutants on different substrates. Cleavage activity of full-length HIV-2 is shown in lanes 1 and 5; that of FIV IN is shown in lanes 2 and 6. The N-terminal deletion mutant of HIV-2 IN ( $Delta$ N HIV; 7 pmol) is complemented by the N-terminal domain of HIV-2 IN (HIV IN₅₅; 0.2 nmol) (lanes 3 and 7) or the N-terminal domain of FIV IN (FIV IN₅₇; 0.1 nmol) (lanes 4 and 8). HIV-2 substrate is used in lanes 1 to 4, and MoMLV substrate is used in lanes 5 to 8. The migration positions of the 28-mer substrate (S) and the 26-mer product (P) are indicated.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Structure elucidation of the N-terminal domains of HIV-1 IN and HIV-2 IN revealed a dimeric three-helix bundle, stabilizedby a zinc-binding unit (8, 18). The topology of the N-terminaldomain is very similar to that of DNA binding proteins, containinga helix-turn-helix motif such as the Trp repressor (48), thePrd paired domain (75), and the N terminus of Tc3 transposase(66). In contrast to the DNA binding proteins, which use thesecond helix of the helix-turn-helix motif to bind DNA, HIV-1IN_1-55 uses this helix for dimerization (8). Althoughno direct DNA binding of IN_1-55 has been observed, severalstudies have indicated that the N-terminal domain may be involvedin recognition of the viral DNA ends. Since mutations in the HHCCmotif affect cleavage more than integration, the N-terminal domaincould participate in correct positioning of the viral DNA ends(7, 63, 67). Disintegration activity of HHCC mutants suggestedthat the N-terminal domain may interact with viral DNA sequencesinternal to the conserved CA (67). Alternatively, the N-terminaldomain could be involved indirectly in viral DNA recognition throughthe interaction with other domains of IN. Interaction betweenthe HHCC motif and the core has been suggested by chemical modificationof specific Cys residues by N-ethylmaleimide, which impairs metal-inducedaggregation of IN (20). In addition, it has been shown thatpreincubation of IN with a C-terminal specific monoclonal antibodyinterferes with binding of an N-terminal specific monoclonal antibody,indicating that the N- and C-terminal domains are close to eachother (2). To dissect the role of the N-terminal domain, wedeveloped an in trans complementation assay. The N-terminal domain(IN_1-55) is provided on a separate molecule, unlinked tothe catalytic core and C-terminal DNA binding domain. Althoughhigh levels of IN activity require an excess of IN_1-55,significant levels of reaction products were detected when themolar ratio of IN_1-55 to the N-terminal deletion mutantwas around2.

The N-terminal domain complements an N-terminal deletion mutant in trans. We have shown that the N-terminal domain of IN can restore IN activity of an N-terminal deletion mutant when provided in transto the active site. Previously, it has been shown that IS10 transposaseretains transposition activity after two of its domains that arenot covalently attached are mixed (40). In contrast to IN, bothdomains of IS10 contribute residues to the active site. In transcomplementation has been reported for the enhancer region of bacteriophageMu; when the enhancer is provided on an unlinked DNA molecule,it still can promote correct synapsis of the left and right MuDNA ends (59). In contrast to the in trans complementation describedhere, the Mu transposable enhancer is only required in the initialsteps of the Mu reaction and is dispensable for cleavage and strandtransfer. To restore 3' processing and strand transfer activityof an N-terminal deletion mutant, IN_1-55 needs to be properlyfolded. The active conformation of IN_1-55 is disturbed bynonconservative substitutions in the putative dimer interface,as well as by the loss of zinc coordination (either by replacementof one of the zinc-binding residues or by chelation of zinc byEDTA). Although the introduction of negatively charged residuesin the dimer interface would be expected to result in a monomericprotein, no mutant proteins that elute at a monomer position froma size exclusion column were found. Also, not a trace of monomerwas observed in zinc-containing IN_1-55. This could indicatethat IN_1-55 cannot exist as a globular foldedmonomer.

Complementation of disintegration activity. Intermolecular disintegration of an N-terminal deletion mutant is independent of the presence of IN_1-55. This is consistentwith the finding that intermolecular disintegration activity isindifferent to zinc (77) and can be carried out in the absenceof the N-terminal domain (7, 39, 68). The intramoleculardisintegration activity of an N-terminal deletion mutant is enhancedin the presence of increasing amounts of IN_1-55. Based onsequence requirements of the intramolecular disintegration reaction,it has been postulated that the intramolecular disintegrationactivity resembles the 3' processing reaction (45, 60). Theenhanced intramolecular disintegration activity of the N-terminaldeletion mutant upon addition of IN_1-55 supports this hypothesis.At high concentrations of IN_1-55 (0.2 mM), no disintegrationactivity takes place and a new band appears. This band probablyresults from a noncovalent interaction between the substrate andIN_1-55. It is surprising that the complex survives heatingin formamide and denaturing gel electrophoresis. We propose thatthe N-terminal domain impairs disintegration activity by sequesteringthe substrate. Support for the interaction between the N terminusof IN and the disintegration substrate comes from photo-cross-linkingstudies, which showed that the N terminus of IN interacts withthe target DNA portion of a disintegration substrate (29).

Stable complex formation. Stable complex formation between IN and viral DNA is established by incubation of IN with Mn²⁺, followed by addition of viral DNA (19, 70). Once the viralDNA is bound, nonspecific DNA no longer competes for viral DNAbinding but functions as a target for the strand transfer reaction.When nonlabeled DNA is added prior to the viral DNA ends, no integrationtakes place. Here, we show that integration occurs in a complementationassay even in the presence of an excess of nonspecific DNA. Whennonlabeled viral DNA sequences are added prior to the labeledviral DNA substrate, integration activity is reduced. These resultssuggest that DNA binding by the IN_1-55 $Delta$ N complex has ahigher off rate than that of full-length IN. In addition, theIN_1-55- $Delta$ N complex binds nonspecific DNA less tightly thanspecific viral DNAends.

Cross-complementation activity between FIV and HIV-2 IN mutants. Previously, it has been shown that HIV IN and FIV IN have different preferences for viral DNA substrates, as well as differenttarget site choices. To address which domains contribute to substratespecificity and target site preference, cross-complementationexperiments were done by using FIV and HIV-2 IN mutants. We haveestablished that an N-terminal domain of FIV IN can function intrans to an N-terminal deletion mutant of HIV-2 IN. The integrationpattern corresponds to that of HIV-2 IN, which is consistent withresults obtained with chimeric proteins that have an integrationpattern dependent on the source of the core domain of IN (57).

Cross-complementation experiments show that the N-terminal domains of HIV IN and FIV IN contribute to substrate specificity.This is in contrast to the result obtained with a chimeric proteinthat contains the N-terminal domain of HIV-1 IN fused to the coreand C terminus of visna virus IN (35, 36). This chimeric proteinhas the same substrate specificity as full-length visna virusIN, suggesting that the core domain of visna virus IN alone determinessubstrate specificity. To extend this conclusion to IN proteinsfrom HIV and other viruses, additional swaps should be tested.Also, chimeric proteins of HIV and FIV IN tested on MoMLV substratecould demonstrate the role of the N-terminal domain in substraterecognition. We cannot fully exclude the possibility that theconformation of the active complex in the complementation assaymay be different from that of chimeric proteins and can thereforeaffect the results. However, since the choice of nucleophile inthe cleavage reaction and the target choice in the strand transferreaction in the complementation between FIV IN_1-55 and the $Delta$ N mutant of HIV-2 IN is similar to that of full-length HIV-2IN, it is not very likely that gross changes in topology havetaken place. As mentioned by Katzman and Sudol, the assignmentof viral DNA recognition to the central domain of IN does notexclude that other parts of IN can facilitate the formation ofa viral DNA complex (36). Recently, cross-linking studies haveindeed revealed that binding to the viral DNA ends is not limitedto a single domain (27-29, 31). The N-terminal domain may functionas a module within the multimeric complex of IN and the viralDNA ends. It is likely that functional multimerization requiresinteractions between nonequivalent domains, but we cannot excludethe possibility that complementation activity is achieved viathe interaction of the N-terminal domain withDNA.

Previously, Heuer and Brown (30) proposed a role of the N-terminal domain in the formation of a bridge between two IN protomers.The N-terminal domain of one protomer would interact with thecore of another protomer, thereby approaching target and viralDNA sequences. Binding of the catalytic core to the viral DNAend would be stabilized by its interaction with the N-terminaldomain. The results presented here are in agreement with the proposedmodel in the sense that the N-terminal domain can act in transto the active site. They suggest that by interacting with thecore, the N-terminal domain influences the binding of the complexto the viral DNA ends, which is in accordance with the locationof the N-terminal domain in the model of Heuer andBrown.

	ACKNOWLEDGMENTS

This work was supported by a grant from The Netherlands AIDSfoundation.

We thank Karin van der Linden for construction of pRP825 and appreciate the assistance of Henk Hilkman with the high-performanceliquid chromatography. We thank Chris Vos, Henri van Luenen, PietBorst, and Ramon Puras Lutzke for critically reading themanuscript.

	FOOTNOTES

^* Corresponding author. Mailing address: Division of Molecular Biology, The Netherlands Cancer Institute, Plesmanlaan 121, 1066CX Amsterdam, The Netherlands. Phone: 31-20-5122081. Fax: 31-20-5122086.E-mail: rplas{at}nki.nl.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
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