Human Immunodeficiency Virus Type 1 cDNA Integration: New Aromatic Hydroxylated Inhibitors and Studies of the Inhibition Mechanism

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Antimicrobial Agents and Chemotherapy, September 1998, p. 2245-2253, Vol. 42, No. 9
0066-4804/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Human Immunodeficiency Virus Type 1 cDNA Integration: New Aromatic Hydroxylated Inhibitors and Studies of the Inhibition Mechanism

C. M. Farnet,¹^, B. Wang,¹ M. Hansen,¹ J. R. Lipford,² L. Zalkow,³ W. E. Robinson Jr.,⁴ J. Siegel,⁵ and F. Bushman¹^,^*

Salk Institute for Biological Studies, La Jolla,¹ Departments of Pathology and Microbiology and Molecular Genetics, University of California at Irvine, Irvine,⁴ and Department of Chemistry, University of California at San Diego, San Diego,⁵ California, Department of Biology, Massachusetts Institute of Technology, Cambridge, Massachusetts,² and School of Chemistry and Biochemistry, Georgia Institute of Technology, Atlanta, Georgia³

Received 12 January 1998/Returned for modification 12 March 1998/Accepted 19 June 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

Integration of the human immunodeficiency virus type 1 (HIV-1) cDNA is a required step for viral replication. Integrase, thevirus-encoded enzyme important for integration, has not yet beenexploited as a target for clinically useful inhibitors. Here wereport on the identification of new polyhydroxylated aromaticinhibitors of integrase including ellagic acid, purpurogallin,4,8,12-trioxatricornan, and hypericin, the last of which is knownto inhibit viral replication. These compounds and others werecharacterized in assays with subviral preintegration complexes(PICs) isolated from HIV-1-infected cells. Hypericin was foundto inhibit PIC assays, while the other compounds tested were inactive.Counterscreening of these and other integrase inhibitors againstadditional DNA-modifying enzymes revealed that none of the polyhydroxylatedaromatic compounds are active against enzymes that do not requiremetals (methylases, a pox virus topoisomerase). However, all werecross-reactive with metal-requiring enzymes (restriction enzymes,a reverse transcriptase), implicating metal atoms in the inhibitorymechanism. In mechanistic studies, we localized binding of someinhibitors to the catalytic domain of integrase by assaying competitionof binding by labeled nucleotides. These findings help elucidatethe mechanism of action of the polyhydroxylated aromatic inhibitorsand provide practical guidance for further inhibitor development.

	INTRODUCTION

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Early during infection of a sensitive cell, the RNA genome of human immunodeficiency virus (HIV) type 1 (HIV-1) is reversetranscribed to yield a double-stranded cDNA copy, and that DNAcopy is then integrated into a chromosome of the host (for reviews,see references 4, 14, 19, 29, 38, 58, and 63).Retroviruses encode a protein, named integrase, that carries outthe initial DNA breaking and joining reactions involved in integration.The integrase enzyme is a potentially attractive target for antiretroviralagents, since it is known to be required for HIV replication (1,18, 66, 70, 71). Although many inhibitors that are activeagainst purified recombinant integrase protein have been described,none have yet proven to be useful clinically (2, 12, 13,22, 23, 25, 28, 33, 34, 48, 51-53, 55, 59-62, 64,65, 73).

Several in vitro assays are available for assessing the function of integrase inhibitors. Integrase protein purified afteroverexpression in insect cells or Escherichia coli can carry outDNA cleavage and joining reactions that mimic normal integrationin several respects. Integrase protein can remove two nucleotidesfrom the 3' end of a model viral cDNA end (6, 9, 21, 35,47, 68), probably to prepare a defined substrate for joining(57), and can then join the recessed 3' end to a 5' phosphatein a target DNA (11, 21, 46) (Fig. 1A). Integrase can alsocatalyze a reversal of this reaction, playfully named "disintegration"(17). However, reactions catalyzed by purified HIV-1 integrasemainly model reactions at one viral cDNA end only, whereas integrationin vivo involves the coordinated joining of both cDNA ends (Fig.1B).

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FIG. 1. DNA cutting and joining reactions involved in cDNA integration. (A) Reactions of purified integrase. The lines represent double-stranded oligonucleotides that match in sequence a cDNA end (LTR). DNA 5' ends are shown as balls; unpaired bases are shown as short lines. Integrase first cleaves the LTR to remove two nucleotides (middle) and then attaches the exposed 3' hydroxyl to the 5' end of a break in the target DNA (bottom). The reversal of this reaction is named "disintegration." (B) Reactions mediating integration in vivo. The viral cDNA is shown as the curved line; target DNA is shown as the straight line. Integrase first removes two nucleotides from each 3' cDNA end (parts 1 and 2). The recessed 3' ends are then joined to protruding 5' ends of breaks made in the target DNA (part 3), yielding the integration intermediate labeled "II." The target DNA between the points of joining then comes unpaired, leaving gaps at each host-virus DNA junction (part 4). These gaps are then repaired (part 5) to yield the integrated provirus. Reactions with preintegration complexes recapitulate parts 1 to 4 but do not support the final repair step (part 5).

More authentic integration reactions can be carried out in vitro by using preintegration complexes (PICs) (5) isolatedfrom HIV-1-infected cells (26, 30). To prepare PICs, humanT cells are infected with HIV-1 and are then permeabilized 4 to6 h after infection. The resulting extracts contain the viralcDNA in association with integrase (31), further viral proteins(7, 36, 57), and also at least one cellular protein (27).Reactions with PICs in vitro yield products with the structuresexpected for coupled integration (Fig. 1B). Importantly in thiscontext, reactions with PICs are much less sensitive to small-moleculeinhibitors than reactions with purified integrase (28, 39).Thus, PIC reactions represent attractive secondary screens forassessing the promise of integrase inhibitors.

Many reported inhibitors of purified integrase share a common characteristic, a benzene ring with cis-hydroxyls (catechol;Fig. 2) (8). We have previously reported on studies of onegroup of compounds containing this structure, the polyhydroxylatedanthraquinones such as quinalizarin (Fig. 2). These compoundsare of particular interest, since they are active against PICsand have been reported to be active against retroviruses in cellculture, although as discussed below, it is not clear that thesecompounds are active against integrase itself in cell culture(28, 67).

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FIG. 2. Structures of catechol and QLZ.

Here we describe the characterization of additional polyhydroxylated aromatic compounds as integrase inhibitors and studiesof their mechanisms of action. A series of new anthraquinonesand related quinones yielded new inhibitors, as did a family ofcompounds containing the catechol moiety embedded in larger structures.We also found that hypericin, a previously described polyhydroxylatedaromatic inhibitor of viral replication, was in fact an inhibitorof integration in vitro. We used assays with both purified integraseand PICs to better understand the promise of different inhibitors.We also present the results of counterscreening of several integraseinhibitors against a battery of DNA-modifying enzymes; these resultsemphasize the role of metal atoms in inhibition. In mechanisticstudies, we find that the polyhydroxylated anthraquinone and severalother compounds compete with a compound that binds the integrasecatalytic domain, placing the likely site of action of these compoundson the catalytic domain.

	MATERIALS AND METHODS

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Materials. Unless indicated otherwise, test compounds were obtained from Sigma. Anthrarobin (Aldrich), alizarin red S (ARS; Aldrich),quercetagetin (QTN; Indofine Chemicals), and myricetin (IndofineChemicals) were obtained elsewhere. L-Chicoric acid (LCH) wasa gift of Manfred Reinecke (Texas Christian University, Fort Worth,Tex.).

Integration assays. Integrase protein and deletion derivatives were purified as described previously (10). Assays for inhibition of reactionswith purified integrase were performed as described elsewhere(9, 14, 28). Preparation of PICs was carried out as describedpreviously (30). Tests of inhibition were performed as describedpreviously (28).

Counterscreening. Assays of inhibition of EcoRT and PvuII (New England Biolabs, Beverly, Mass.) were carried out by incubating 1 U of enzymewith several concentrations of inhibitor for 5 min in 20 µl ofthe manufacturer's recommended buffer (containing 10 mM MgCl₂)and then adding 0.2 µg of pUC19 reaction substrate. Reactionswere stopped after 5 min by the addition of loading dye containingexcess EDTA. The products were separated by electrophoresis andwere visualized by staining with ethidium bromide. The reactionswere quantitated with a Speedlight Gel Documentation System andIP Lab Gel software.

Reactions with EcoRT methylase (New England Biolabs) and SssI methylase (also known as CpG methylase; New England Biolabs)were carried out in 50 mM NaCl-50 mM Tris HCl (pH 8.0)-10 mM EDTA-80µM S-adenosylmethionine. Compounds were incubated with methylase(0.8 U) in the buffer described above for 5 min at room temperature,and then pUC19 DNA substrate was added and the reaction mixtureswere incubated for 15 min at 37°C. Reactions were stopped by phenolextraction, and the reaction mixtures were chilled to 4°C. DNAswere recovered by ethanol precipitation, resuspended in restrictiondigestion buffer, and cleaved with EcoRI (to test for methylationby EcoRI methylase) or AatII (to test for methylation by CpG methylase).The reaction products were analyzed by electrophoresis as describedabove. In some cases inhibition was seen with concentrations ofinhibitors greater than 50 µM, thereby arguing against variouspossible systematic errors in assaying the methylases.

Assays of molluscum contagiosum virus (MCV) topoisomerase were carried out as described previously (44). Briefly, purifiedenzyme was incubated for 5 min with test compounds in buffer containing10 mM EDTA, 20 mM Tris (pH 8), 200 mM potassium glutamate, 1 mMdithiothreitol, and 0.1% Nonidet P-40, and then the assays werestarted by the addition of 0.2 µg of pUC19 DNA substrate. Relaxationof DNA substrates was monitored by gel electrophoresis and quantitatedas described above.

Assays of Moloney murine leukemia virus (MoMuLV) reverse transcriptase (RT) were carried out essentially as described previously(37). The reaction mixtures contained 2.5 U of RT (New EnglandBiolabs), 50 mM Tris (pH 7.9), 75 mM KCl, 2 mM dithiothreitol,25 µg of poly (rA)-oligo(dT) template (Pharmacia) per ml, 5 mMMgCl₂ or MnCl₂, 0.05% Nonidet P-40, and 2.3 mM [³H]TTP. RT was preincubated in the reaction mixture with the compoundto be tested for 5 min at room temperature and was then incubatedfor 1 h at 37°C. Reactions were stopped by spotting the reactionmixtures onto filter paper disks (Whatman DE81). The dried filterswere washed in 2× SSC (1× SSC is 0.15 M NaCl plus 0.015 M sodiumcitrate) and then in 95% ethanol, dried, and counted by liquidscintillation counting in the presence of EcoLume scintillationcocktail (ICN).

Nucleotide binding to integrase and drug competition. Assays of binding of oxidized [ $alpha$ -³²P]ATP to integrase were carried out exactly as described previously (50). To test for competitionby integrase inhibitors, the compounds were added to integrase,and the mixture was preincubated for 5 min at room temperatureprior to the addition of oxidized ATP.

Synthesis of emodin-9-anthrone (DZ-III-77). A solution of emodin 1,3-dimethyl ether (200 mg, 0.67 mmol) in glacial acetic acid (20 ml) and HI (47% aqueous, 10 ml) wasrefluxed for 3 h. The solution was cooled at 3°C overnight, andthe product crystallized as pale yellow plates. The solid wascollected, washed with water, and air dried (121 mg; 71%). Ananalytical sample was obtained via recrystallization from acetone;melting point (mp) 255 to 256°C, dec. (literature mp 255°C, dec.);¹H nuclear magnetic resonance (NMR) (300 HMz, dimethyl sulfoxide[DMSO]-d₆) $delta$ 2.33 (s, 3H), 4.32 (s, 2H), 6.24 (d, 1H, J = 2.3Hz), 6.43 (d, 1H, J = 2.3 Hz), 6.70 (bs, 1H), 6.80 (bs, 1H), 10.84(s, 1H), 12.34 (s, 1H), 12.39 (s, 1H); electron ionization-massspectrometry (EIMS) m/e 256 (100), 241 (17), 227 (10), 213 (14);Fourier transform infrared (FTIR) (Nujol) 3378, 3312, 1625, 1598,1277, 1242, 1157 cm¹. Exact mass calculated for C₁₅H₁₂O₄: 256.0736. Found: 256.0748.

Synthesis of emodic acid N,N-diethylamide-9-anthrone (DZ-III-126). A solution of emodic acid N,N-diethylamide (130 mg, 0.37 mmol) was dissolved in glacial acetic acid (20 ml) by refluxing undernitrogen. A suspension of stannous chloride (3.5 g) in concentratedHCl (8.75 ml) was carefully added and the solution was stirredat reflux for 2 min. The solution was cooled to 60°C, dilutedwith water (50 ml), and cooled at 3°C. The light tan solid wascollected by vacuum filtration, washed with water, and air dried.Recrystallization from acetone afforded pale yellow needles (85mg, 67%); mp 233 to 235°C (dec) with darkening at 221 to 222°C.¹H NMR (300 MHz, acetone-d₆) $delta$ 1.10-1.26 (m, 6H), 3.31 (m, 2H),3.52 (m, 2H), 4.43 (s, 2H), 6.35 (d, 1H, J = 2.2 Hz), 6.56 (m,1H), 6.79 (bs, 1H), 6.93 (bs, 1H), 12.39 (s, 1H), 12.45 (s, 1H);EIMS m/e 341 (84), 324 (19), 269 (100), 242 (54), 213 (32), 184(15), 155 (10), 139 (28), 128 (22); infrared (Nujol) 1627, 1594,1286, 1161 cm¹. Exact mass calculated for C₁₉H₁₉NO₅: 341.1263. Found: 341.1279.Analysis calculated for C₁₉H₁₉NO₅ · 1/2 H₂O: C, 65.13; H, 5.75.Found: C, 65.15; H, 5.23.

Synthesis of bromoquinalizarin. Bromoquinalizarin was prepared as follows. A 500-ml, two-neck, round-bottom flask was charged with quinalizarin (QLZ; 2.02g, 7.4 mmol) and dimethylformamide (100 ml) and cooled to 0°C.A solution of N-bromosuccinimide in dimethylformamide (2.64 g,14.8 mmol in 110 ml) was added dropwise to the cooled reactionmixture. After the addition, the reaction mixture was warmed toroom temperature and was stirred overnight. The solvent was thenremoved by distillation at reduced pressure to leave a red precipitate.The solid was triturated with chloroform to remove the residualsuccinimide. After trituration, the red solid was characterizedas bromoquinalizarin (1.7 g, 65% yield). mp 280 to 280°C (dec);1H NMR (DMSO-d₆) d ppm 7.84 (s, 1H), 7.43 (d, 2H, 9 Hz), 7.39(d, 2H, 9 Hz); ¹³C NMR (DMSO-d₆) d ppm 189.9, 184.0, 156.9, 156.5, 150.3, 150.1,129.6, 128.8, 123.6, 123.4, 116.4, 115.0, 112.4, 112.0. EIMS (m⁺) = 351.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Assays of inhibition of purified HIV-1 integrase. HIV-1 integrase protein was purified after overexpression in E. coli and was assayed with oligonucleotide substrates thatmodel the viral long terminal repeat (LTR) and target DNA. A particularlyconvenient assay monitors disintegration (Fig. 1A) (17). Ifintegrase protein is provided with a Y-shaped model substrateresembling the in vitro integration product, integrase can catalyzethe release of the viral DNA analog and reclosure of the targetDNA. One useful version of these substrates has the DNA ends joinedby loops, permitting particularly easy synthesis and analysisof the reaction products ("dumbbell disintegration") (15, 28).An example of the use of this substrate for inhibitor screeningis shown in Fig. 3B. Incubation of this substrate with purifiedintegrase results in the release of an LTR-like duplex and resealingof the model target DNA. When a ³²P label is placed in the DNA at the 5' end (Fig. 3A), the disintegrationproduct can be visualized by the appearance of a single band oflower molecular weight (16).

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FIG. 3. Tests of integrase inhibitors by dumbbell disintegration. (A) Diagram of the dumbbell disintegration reaction. The asterisk marks the position of a 5' ³²P label. (B) Inhibition of dumbbell disintegration by hypericin. The concentrations of hypericin are indicated above the lanes. S, substrate; P, product.

This dumbbell disintegration reaction was used as a first screen in testing candidate inhibitors. Previous studies have indicatedthat the disintegration reaction is relatively permissive comparedwith other integrase assays. The disintegration reaction was usedhere as a primary screen in an effort to select for particularlypotent inhibitors. To determine the concentrations required for50% inhibition (IC₅₀s), different concentrations of small moleculeswere added to test reactions, and the yield of product was quantitatedwith a PhosphorImager instrument. IC₅₀s were derived from thesemeasurements as described previously (28).

Assays of inhibition of PICs. As discussed above, in vitro assays based on PICs isolated from HIV-1-infected cells more closely resemble integration invivo than do assays with purified integrase (see reference 28and 29 for a discussion). To characterize the inhibitors, PICscontaining HIV cDNA were incubated with a naked DNA target invitro. The reaction products were then deproteinized and assayedon Southern blots probed with labeled HIV LTR sequences. The compoundsto be tested for inhibition were titrated into the reaction mixtures,and inhibition was quantitated by determining the level of reductionin the appearance of the integration product (an example is shownin Fig. 4A) (28).

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FIG. 4. Tests of integrase inhibitors in PIC assays and the structures of LCH and derivatives. (A) Assay of inhibitors of PIC reactions. Shown is a Southern blot analysis of reaction products probed with labeled LTR sequences. Bands corresponding to the unreacted cDNA and integration intermediate (II; part 4 in Fig. 1) are marked beside the autoradiogram. Lanes 1 to 12, inhibitors at the indicated concentrations; lane 10, 20% ethanol (EtOH), the solvent used to dissolve CHL. HYP, hypericin. (B) Structures of LCH and its chemical relatives.

Test of hypericin. The polyhydroxylated aromatic compound hypericin, isolated from the medicinal herb St. John's wort (Hypericum perforatum),has previously been reported to inhibit the replication of HIVand other viruses (49, 56). Hypericin was tested for its abilityto inhibit dumbbell disintegration and was found to be active,with an IC₅₀ of 15 µM (Fig. 3B). Hypericin also displayed inhibitoryactivity against PICs, with an IC₅₀ of about 100 µM (Fig. 4A,lanes 10 and 11).

Tests of new polyhydroxylated aromatic compounds. Since many polyhydroxylated aromatic compounds were found to be integrase inhibitors, further compounds of this class weretested for their inhibitory activities. The compounds were titratedinto mixtures containing purified integrase, and the mixtureswere incubated for 5 min at room temperature. Dumbbell disintegrationsubstrates were then added to start the reaction. Compounds wereanalyzed for inhibitory activity initially at 40 µM. Those compoundsshowing any inhibitory activity at this concentration were thencharacterized further to determine the IC₅₀. The structures ofthe compounds studied and the measured IC₅₀s are shown in Fig.5. The IC₅₀s of the single-ring compounds tetroquinone, pyrogallol,and trihydroxypyrimidine were well above 40 µM, as was the IC₅₀of catechol itself. Of the multiring compounds tested, purpurogallin,ellagic acid (ELA), and 3,3,3',3'-tetramethyl-1,1'-spirobis(indan)-5,5',6,6'-tetraol(TMS) were active, while the parasiticide anthrarobin was inactive.Two compounds related in structure to TMS $---$ 4,8,12-trioxatricornanand 2,6,10-triamino-4,8,12-trioxatricornan $---$ were also inactive.These data emphasize the importance of residues in addition tothe catechol moiety in potentiating the inhibition of integrase.

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FIG. 5. Structures of polyhydroxylated aromatic compounds and some chemical relatives with IC₅₀s for inhibition of dumbbell disintegration. The measured IC₅₀ is given beneath each structure. TTC, 4,8,12-trioxatricornan; TAT, 2,6,10-triamino-4,8,12-trioxatricornan.

The active compounds described above were tested against the PICs isolated from infected cells. None were detectably inhibitoryat 40 µM (data not shown).

Test of LCH and derivatives against PICs. Previously, LCH and several derivatives were found to inhibit purified integrase in vitro and viral replication in vivo (64,65), raising the possibility that these compounds inhibit integrasein vivo. LCH, the inactive relative chlorogenic acid (CHL), andthe active related molecule 1-MO-3,5-DCQA (MCQ) were tested fortheir inhibitory activities against PICs (Fig. 4A and B). Noneof these compounds displayed detectable inhibitory activity, evenat concentrations of 100 µM (Fig. 4A, lanes 4 to 10). QLZ wastested in parallel as a control and was shown to be inhibitory,as reported previously (28) (Fig. 4A, lane 3).

A further chemical relative of LCH, nordihydroguaiaretic acid (NDGA; Fig. 4B), was also tested. This compound is composedof two catechol moieties, as in LCH and MCQ, but NDGA is tetheredby a 2,3-dimethylbutane moiety. NDGA displayed no inhibitory activityagainst the terminal cleavage or strand transfer activities ofpurified integrase (data not shown). Evidently, features in additionto the catechol rings are important for inhibition in this seriesof compounds.

Effects of ring substituents on inhibition by anthraquinones. To explore the potential of the anthraquinone nucleus, 14 further anthraquinones and two related anthrones (72) were testedfor their abilities to inhibit dumbbell disintegration (Fig. 6).The compounds were initially tested at 40 µM. Those showing detectableinhibition at this concentration were tested to determine theIC₅₀. The IC₅₀s of danthron, DZ-III-77, and DZ-III-126 were between40 and 70 µM, while the other compounds tested were inactive.These data emphasize the importance of the cis-hydroxyls presentin the previously reported compounds.

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FIG. 6. Anthraquinones and anthrones tested for inhibition of dumbbell disintegration. IC₅₀s are shown beneath each structure.

All of the compounds described above were also tested against PICs and were found to be inactive at a concentration of 40µM (data not shown).

A new derivative of QLZ containing a bromine atom was synthesized in an effort to improve its inhibitory activity. Bromoquinalizarindid inhibit dumbbell disintegration, but the IC₅₀ was higher thanthat of QLZ itself (10 versus 2 µM) (data not shown) (28).

Tests of function of integrase inhibitors against other DNA-modifying enzymes. Many previous reports of integrase inhibitors have not presented data on the specificity of inhibition from counterscreeningexperiments. To investigate specificity more carefully, sevenrepresentative polyhydroxylated aromatic integrase inhibitorswere tested against a panel of six DNA-modifying enzymes (Table1). In addition to representatives of the compounds mentionedabove (QLZ, TMS, LCH, and ELA), three other previously describedinhibitors were also tested: aurintricarboxylic acid (ATC) (23),QTN (a flavone) (34), and ARS (an anthraquinone) (28).

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TABLE 1. IC₅₀s for inhibition of DNA-modifying enzymes by polyhydroxylated aromatic inhibitors of integrase^a

Enzymes that either required metal cofactors (MoMLV RT and the restriction enzymes PvuII and EcoRI) or functioned in theirabsence (MCV topoisomerase, EcoRI methylase, or CpG methylase)were selected. Integrase inhibitors were titrated into reactionmixtures containing each enzyme, and reactions were started bythe addition of substrate. Inhibition of product formation wasquantitated for each compound and was expressed as an IC₅₀ (Table1).

All compounds tested were found to inhibit at least some of the metal-utilizing enzymes. TMS was most specific, inhibitingEcoRI but not the other enzymes. QLZ was least specific, inhibitingall the metal-requiring enzymes tested. Strikingly, none of thecompounds were active against enzymes that did not require metalcofactors at less than 50 µM, highlighting the likely role ofmetal atoms in inhibition. Note that the inhibitors are presentin the test reaction mixtures at concentrations much lower thanthose of the metal ions themselves, ruling out the trivial possibilitythat the added inhibitors are simply sequestering the requiredmetal cofactor.

The role of the particular metal atom bound was probed by comparing the IC₅₀s for MoMLV RT in the presence of Mg²⁺ or Mn²⁺. In all cases the compounds inhibited MoMLV RT more effectivelyin the presence of Mn²⁺. More potent inhibition of HIV integrase itself by polyhydroxylatedaromatic compounds in the presence of Mn²⁺ than in the presence of Mg²⁺ has also been reported (40).

Binding of QLZ and other inhibitors to integrase measured by competition of nucleotide binding. Previously, it was reported that labeled nucleotides can bind to HIV-1 integrase (50, 51, 54), an observation that formsthe basis for localizing the binding site of integrase inhibitors.Purified HIV-1 integrase can be incubated with oxidized [ $alpha$ -³²P]ATP and then reduced with NaBH₃CN to form a covalent complex,likely involving cross-linking of ATP to a lysine residue on theprotein. Such reaction mixtures can then be separated by electrophoresison sodium dodecyl sulfate-polyacrylamide gels and visualized byautoradiography (Fig. 7, lane 3). The formation of the labeledcomplex was dependent on the addition of [ $alpha$ -³²P]ATP and the reducing agent NaBH₃CN (Figure 7, lanes 1 and 2).To localize the site of binding, oxidized ATP was incubated withjust the catalytic domain fragment of integrase (residues 50 to212) and was subsequently reduced. Two catalytic domain fragmentswere compared: one containing the wild-type sequence (Fig. 7,lanes 4 to 6) and one containing a mutation (F185K) that was reportedto improve solubility (45). Both catalytic domain fragmentsbound oxidized ATP with an efficiency comparable to that of full-lengthintegrase (Fig. 7, lanes 3, 6, and 9). These data indicate thatATP associates primarily with the catalytic domain.

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FIG. 7. Nucleotide binding to the catalytic domain of integrase. Integrase (IN) protein (lanes 1 to 3), the catalytic domain only (integrase residues 50 to 212; lanes 4 to 6), and the catalytic domain containing the F185K mutant (lanes 7 to 9) were incubated with [ $alpha$ -³²P]ATP and NaBH₃CN (lanes 1, 4, and 7), oxidized ATP (ox ATP) (lanes 2, 5, and 8), or oxidized ATP and NaBH₃CN (lanes 3, 6, and 9). In each case, Coomassie brilliant blue staining confirmed that the labeled band had the mobility of the integrase derivative studied (data not shown).

To investigate whether QLZ or other inhibitors bound to sites overlapping the ATP-binding site on the catalytic domain, integrasewas preincubated with inhibitors and then oxidized [ $alpha$ -³²P]ATP was added. Several other integrase inhibitors, in additionto those described above, were tested: curcumin, isolated fromthe spice turmeric (55); myricetin and quercetin, two flavones(34); doxorubicin, a topoisomerase inhibitor (28); genistein,an isoflavone; and dihydroxynaphthaquinone, a naphthaquinone (28,33).

The nucleotide binding activity detected in this assay (Fig. 8, lane 1) was not changed by the addition of 10% DMSO or 10%ethanol, solvents used to resuspend some of the inhibitors (Fig.8, lanes 1 to 3). Preincubation with 100 µM unlabeled oxidizedATP prevented subsequent binding of labeled oxidized ATP, whilepreincubation with 10 µM ATP blocked binding only partially (Fig.8, lanes 4 and 5). Several of the anthraquinones (QLZ, purpurin,alizarin and CB3GA) inhibited cross-linking to oxidized ATP (Fig.8, lanes 26 to 33). Several other compounds also inhibited bindingof oxidized ATP (ATC [Fig. 8, lanes 7 and 8], dihydroxynaphthaquinone[Fig. 8, lanes 16 and 17], myrcetin [Fig. 8, lanes 20 and 21],and quercetin [Fig. 8, lanes 22 and 23]). However, not all ofthe polyhydroxylated aromatic compounds inhibited the bindingof oxidized ATP, indicating that the binding sites of these compoundsmay not be the same in all cases. These data taken together supporta model in which some of the polyhydroxylated anthraquinones andthe other inhibitors of binding inhibit integrase by binding tothe catalytic domain. Alternatives are possible, however, sinceindirect effects of ATP binding on inhibitor binding are not ruledout. Some of these compounds may be good candidates for cocrystallizationtrials with the integrase catalytic domain.

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FIG. 8. Analysis of the binding site of integrase inhibitors by competition with nucleotide binding. In each case integrase was incubated with the indicated compound and then oxidized [ $alpha$ -³²P]ATP was added and cross-linked by the subsequent addition of NaBH₃CN. Reaction products were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and visualized by autoradiography. Compound codes: EtOH, ethanol; oATO, oxidized ATP; ATC, aurintricarboxylic acid; QNZ, quinizarin; EMO, emodin; CUR, curcumin; GEN, genistein; DHNQ, dihydroxynaphthaquinone; DOX, doxorubicin; MYR, myricetin; QRC, quercetin; DHAQ, 1,8-dihydroxyanthraquinone; QLZ, quinalizarin; PUR, purpurin; ALZ, alizarin. CB3GA is an anthraquinone.

To control for the possibility that the added compounds were interacting with the oxidized ATP directly, compounds were incubatedwith oxidized [ $alpha$ -³²P]ATP and the reaction products were analyzed by thin-layer chromatography.No new labeled forms were detected, arguing against the idea thatthe drugs reacted with the oxidized nucleotide itself (data notshown).

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Here we describe new polyhydroxylated aromatic inhibitors of the HIV-1 integrase protein and report on studies of their mechanismsof action. We previously found that certain polyhydroxylated anthraquinonesare of particular interest, since they inhibited both purifiedintegrase protein and PICs (28), so in the present study weanalyzed new anthraquinones and related polyhydroxylated phenolicmolecules for their inhibitory activities. We also report on thecounterscreening of molecules of this class against six otherDNA-modifying enzymes and studies of binding to integrase. Thesedata help clarify the nature of the active pharmacophore and itsmechanism of action and also provide practical guidance for furtherscreening of inhibitors.

Structure of the active pharmacophore. No anthraquinones lacking the catechol motif were as active as those containing this motif, highlighting the importance ofthe catechol structure. However, simply embedding the catecholmoiety in an aromatic backbone is not sufficient to generate aninhibitor, as indicated by the lack of inhibition by anthrarobin(Fig. 5). The paired carbonyls in the central ring of the anthraquinonesdo not both appear to be strictly necessary, since two anthrones(containing a single carbonyl) were at least somewhat inhibitory.Thus, one functionality sufficient for the inhibition of purifiedintegrase by the anthraquinone-related catechol inhibitors appearsto be a naphthaquinone nucleus with cis-hydroxyls on one ringand a carbonyl on the adjacent ring. Two other groups have alsoconcluded that substituents in addition to the catechol moietyare important for inhibition by related compounds (8, 34,48, 62).

However, as described below it may be that not all of the polyhydroxylated aromatic inhibitors act by the same mechanism,raising the possibility that multiple pharmacophores may be contributingto the inhibition. Potentially consistent with this idea are recentstudies with several different pharmacophore models to identifynew integrase inhibitors in small-molecule databases (42, 62).Also consistent with the idea that multiple pharmacophores areinvolved, LCH and hypericin do not contain the dihydroxynaphthaquinonemotif described above.

Mechanism of inhibition by the polyhydroxylated anthraquinones. Data presented here clarify a previously unresolved issue, that of whether the polyhydroxylated anthraquinone inhibitors acton the integrase protein or on substrate DNA. Anthraquinones mayhave some potential to intercalate into DNA due to their planarshape, although they lack the net positive charge characteristicof many strong intercalators, and the results of gel shift assaysfor intercalation were negative (unpublished data) (33). Thedata from competition with binding of nucleotides indicate thatthe polyhydroxylated anthraquinones can bind to integrase in theabsence of DNA, supporting the inference that integrase bindingis at least part of the inhibitory mechanism. Recently, zidovudinehas been cross-linked to integrase and the binding site was mapped,and a possible site for the binding of oxidized ATP and the drugswith which it competes was localized (24). For some of the otherpolyhydroxylated aromatic inhibitors, binding to the catalyticdomain was not detected by competition with nucleotide binding.These compounds may bind to sites that do not overlap the ATP-bindingsite or that instead bind to DNA.

Previous work has suggested that many of the aromatic polyhydroxylated inhibitors may act by blocking binding of integraseto DNA (40). This observation potentially explains the lackof activity against PICs, in which integrase and cDNA are stablyprebound (3, 5, 26, 27, 30). However, the findingthat QLZ and related compounds are active against PICs indicatesthat, at least for these compounds, blocking of binding is notthe only mechanism of inhibition.

Some of the polyhydroxylated aromatic integrase inhibitors can potentially chelate metal atoms, and the data from counterscreeningexperiments highlight the likely role of metal binding in inhibition.Three of the six enzymes screened, EcoRI methylase, CpG methylase,and MCV topoisomerase (44), do not require metals to function,while the other three, MoMLV RT, PvuII, and EcoRI, do requiremetals. Strikingly, none of the inhibitors tested were activeat the concentrations tested against enzymes that did not requiremetal cofactors, while all inhibitors were cross-reactive withone or more of the metal-containing enzymes. Further support forthe idea that metals are involved in inhibition comes from theobservation that the IC₅₀ for inhibition of MoMuLV RT differsdepending on the metal cofactor, with inhibition being more efficientin the presence of Mn²⁺ than in the presence of Mg²⁺. It was similarly reported for HIV integrase that the actionsof many of the polyhydroxylated aromatic inhibitors were morepotent in the presence of Mn²⁺ than in the presence of Mg²⁺ (34, 40). Interestingly, the catalytic domain of integrase,the site of action of the QLZ and certain other inhibitors, alsobinds to metals. This raises the possibility that these drugsmay form a ternary complex with enzymes and metals. In any caseit seems likely that the inhibitors act as metal complexes.

Polyhydroxylated anthraquinones have been reported previously to be active against HIV in vivo (41, 67), but the issueof whether this effect is due to inhibition of integrase itselfin vivo remains unresolved. QLZ at concentrations close to orbelow the concentrations necessary for viral inhibition is toxicto cells, depending on the assay (41, 65a, 67). Furthermore,QLZ at 5 µM can inhibit the growth of yeast cells when QLZ isadded to the growth medium (44a). Certain polyhydroxylated aromaticcompounds have been reported to be able to cross-link proteinswhen added to cells, and a specific chemical mechanism has beenproposed (69). Taken together, these data raise concerns aboutthe toxic effects of polyhydroxylated anthraquinones in vivo.

Mechanism of inhibition by LCH. LCH and related compounds are of particular interest since they are potent inhibitors of purified integrase and are activeagainst virus in vivo (64, 65). The suggestion that LCH andthe related molecule MCQ are active against integrase in vivo,however, is complicated by the finding that LCH also inhibitsinteractions between the HIV envelope protein and the cellularligand CD4 (cited in reference 65). Here we report that LCHand MCQ are not active against PICs, findings that do not strengthenthe idea that these compounds are active against integrase invivo. However, it may be possible that compounds that cannot inhibitPICs might still inhibit integration by acting earlier, duringthe assembly of PICs following the completion of reverse transcriptionbut prior to the assembly of integrase with the cDNA. It is alsopossible that LCH acts in vivo against other targets, disruptingenv-CD4 interactions or reverse transcription. A further possibilityis that the in vivo effect on HIV is indirect, mediated in partby toxic effects on cells. Consistent with this idea, LCH is cross-reactivewith other metal-requiring enzymes (although antiviral activityhas been reported at nontoxic concentrations [64, 65]). Theanalysis of LCH-resistant derivatives of HIV may resolve someof these issues.

Mechanism of inhibition by hypericin. Hypericin has been reported to show anti-HIV activity in cell culture (49, 56), and the findings presented here of actionagainst purified integrase and PICs raise the possibility thatintegrase may be a target protein in vivo. In the presence oflight, hypericin can produce singlet oxygen and also superoxideand hypericinium ion. Possibly, these species mediate inhibition(although for another view, see reference 32).

The IC₅₀ of hypericin for the blocking of HIV-mediated fusion in cell cultures is in the high nanomolar range, and the IC₅₀for the blocking of HIV-induced syncytium formation is about 1µM (depending on the assay and the time points compared) (49).However, values for inhibition of integrase or PICs are higher(IC₅₀s, 10 to 100 µM). Although the assays differ in importantrespects, these differences in IC₅₀s raise the possibility thatintegration is not the major target in vivo. Hypericin may alsobe active against membranes, since hypericin inhibits the replicationof several enveloped viruses, some of which do not encode integrases,but not the replication of nonenveloped viruses (20, 43, 56).The isolation of HIV mutants insensitive to hypericin could clarifywhether this antiviral agent is active against integrase in vivo.

Practical lessons for identifying integrase inhibitors. This work emphasizes the usefulness of counterscreens for integrase inhibitors based on metal-requiring DNA-modifying enzymes(see also reference 48). Counterscreens against enzymes thatdo not require metals have been reported (61), but on the basisof the data reported here, such studies risk concluding incorrectlythat the studied inhibitors are specific for integrase. The observationthat different inhibitors are cross-reactive with different metal-utilizingenzymes also emphasizes the importance of studying multiple enzymesin secondary screens.

The promise of the polyhydroxylated aromatic inhibitors of integrase is unclear. Several lines of data argue against the utilityof these compounds. The observed cross-reactivity with metal-requiringenzymes is potentially consistent with observations of toxic effectson cells. The tight binding of QLZ to PICs (data not shown) raisesthe possibility that the compound binds to PICs covalently, asdo studies of the cross-linking of proteins by some compoundsof this class. However, in support of the utility of the polyhydroxylatedaromatic inhibitors, covalent binding of QLZ to PICs would haveto be somewhat specific given the observation that the IC₅₀ isnot altered when high concentrations of cellular proteins arepresent in test reaction mixtures (28). Furthermore, cells canclearly tolerate the presence of catechol-containing compounds.For example, the catechol-containing catecholamines are an importantgroup of neurotransmitters. Perhaps the catechol-related pharmacophorewill be a useful inhibitor substituent when it is combined withother chemical groups that improve the specificity for integrase.

	ACKNOWLEDGMENTS

We thank members of the laboratory of F. D. Bushman for suggestions and helpful discussions.

This work was supported by grants GM56553 and AI34786 to F.D.B. F.D.B. is a scholar of the Leukemia Society of America.

	ADDENDUM IN PROOF

A mutant of HIV-1 has been isolated that displays reduced sensitivity to LCH (P. G. King and W. E. Robinson, Jr., J. Virol.,in press). Sequencing revealed a change in the integrase codingregion. A virus in which wild-type integrase was replaced withthe mutant integrase also displayed reduced sensitivity. Thesedata strengthen the view that LCH acts at least in part againstintegrase in vivo.

	FOOTNOTES

^* Corresponding author. Mailing address: Salk Institute for Biological Studies, 10010 North Torrey Pines Rd., La Jolla, CA 92037.Phone: (619) 453-4100, ext. 1630. Fax: (619) 554-0341. E-mail:rick_bushman{at}qm.salk.edu.

Present address: Ecopia Biosciences Inc., Montreal, Quebec, H2X 3V8 Canada.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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1.	Adachi, A., N. Ono, H. Sakai, K. Ogawa, R. Shibata, T. Kiyomasu, H. Masuike, and S. Ueda. 1991. Generation and characterization of the human immunodeficiency virus type 1 mutants. Arch. Virol. 117:45-58[Medline].
2.	Billich, A., M. Schauer, S. Frank, B. Rosenwirth, and S. Billich. 1992. HIV-1 integrase: high-level production and screening assay for the endonucleolytic activity. Antivir. Chem. Chemother. 3:113-119.
3.	Bowerman, B., P. O. Brown, J. M. Bishop, and H. E. Varmus. 1989. A nucleoprotein complex mediates the integration of retroviral DNA. Genes Dev. 3:469-478[Abstract/Free Full Text].
4.	Brown, P. O. 1990. Integration of retroviral DNA. Curr. Top. Microbiol. Immunol. 157:19-48[Medline].
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