{theta} Defensins Protect Cells from Infection by Herpes Simplex Virus by Inhibiting Viral Adhesion and Entry

We tested the ability of 20 synthetic ${theta}$ defensins to protectcells from infection by type 1 and type 2 herpes simplex viruses(HSV-1 and -2, respectively). The peptides included rhesus ${theta}$ defensins (RTDs) 1 to 3, originally isolated from rhesus macaqueleukocytes, and three peptides (retrocyclins 1 to 3) whose sequenceswere inferred from human ${theta}$ -defensin (DEFT) pseudogenes. We alsotested 14 retrocyclin analogues, including the retro, enantio,and retroenantio forms of retrocyclin 1. Retrocyclins 1 and2 and RTD 3 protected cervical epithelial cells from infectionby both HSV serotypes, but only retrocyclin 2 did so withoutcausing cytotoxicity or requiring preincubation with the virus.Surface plasmon resonance studies revealed that retrocyclin2 bound to immobilized HSV-2 glycoprotein B (gB2) with highaffinity (K_d, 13.3 nM) and that it did not bind to enzymaticallydeglycosylated gB2. Temperature shift experiments indicatedthat retrocyclin 2 and human ${alpha}$ defensins human neutrophil peptide1 (HNP 1) to HNP 3 protected human cells from HSV-2 by differentmechanisms. Retrocyclin 2 blocked viral attachment, and itsaddition during the binding or penetration phases of HSV-2 infectionmarkedly diminished nuclear translocation of VP16 and expressionof ICP4. In contrast, HNPs 1 to 3 had little effect on bindingbut reduced both VP16 transport and ICP4 expression if addedduring the postbinding (penetration) period. We recently reportedthat ${theta}$ defensins are miniature lectins that bind gp120 of humanimmunodeficiency virus type 1 (HIV-1) with high affinity andinhibit the entry of R5 and X4 isolates of HIV-1. Given itssmall size (18 residues), minimal cytotoxicity, lack of activityagainst vaginal lactobacilli, and effectiveness against bothHSV-2 and HIV-1, retrocyclin 2 provides an intriguing prototypefor future topical microbicide development.

INTRODUCTION

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Introduction

The worldwide AIDS epidemic has intensified interest in identifyingnaturally occurring antiviral molecules (5, 29, 34, 57). Certainrabbit and human ${alpha}$ defensins were shown to protect cells frominfection by herpes simplex virus type 1 (HSV-1) and HSV-2 almost20 years ago (17, 30), and more recent studies indicated thatrabbit ${alpha}$ defensin NP-1 blocks HSV infection at a very early stage(46). Even adenoviruses, which are nonenveloped, are susceptibleto ${alpha}$ defensins (3, 21), although the mechanism of this effectis unknown. In vitro, human ${alpha}$ defensins human neutrophil peptide1 (HNP 1) to HNP 3 can protect cells from infection by humanimmunodeficiency virus type 1 (HIV-1), and release of thesedefensins from the ${alpha}$ , ß CD8-positive T cells of HIV-infectedsubjects may (60) or may not (11) correlate with their long-termclinical stability.

Defensin peptides belonging to three subfamilies, designated ${alpha}$ , ß, and ${theta}$ defensins, have been identified in leukocytesand other cells of humans or nonhuman primates. ${alpha}$ defensins contain29 to 35 residues and are produced as $~$ 100-residue prepropeptides(16). Human neutrophils (polymorphonuclear leukocytes) containfour ${alpha}$ defensins, called HNPs 1, 2, 3, and 4. HNPs 1 and 3 areidentical in 29 of their 30 residues, differing only in theirN-terminal residue, which is alanine in HNP 1 and aspartic acidin HNP 3. HNP 2 contains 29 residues, and its sequence is identicalto residues 2 to 30 of HNP 1 and HNP 3. Collectively, HNPs 1to 3 constitute 5 to 7% of the total protein of human neutrophils.HNP 4 exists in much smaller amounts, and its sequence bearslittle resemblance to the sequences of HNPs 1 to 3. HNPs 1,2, and 3 are also present in some human mononuclear cells, includingNK and certain T cells. Human ${alpha}$ defensins HD 5 and HD 6 are expressedin the small intestine (27, 28) and genitourinary tract (42),and HNPs 1 to 3 are found in vaginal secretions and the cervicalplug (24, 53).

${theta}$ defensins are circular octadecapeptides with two antiparallelß sheets that are bridged by a tridisulfide ladderand connected by two ß turns (50). Three ${theta}$ -defensinpeptides (or RTDs, an abbreviation for rhesus ${theta}$ defensins) werepurified from the leukocytes and bone marrow of rhesus macaques(31, 49, 51). In vivo, their formation entails ligation of twononapeptides, each derived from the C-terminal domain of a prepropeptide(49) that is encoded by a ${theta}$ -defensin (DEFT) gene. The human genomehas at least six DEFT genes, some of which are expressed. However,because the human DEFT genes and mRNA carry a premature stopcodon that aborts translation, ${theta}$ -defensin peptides are not presentin human polymorphonuclear leukocytes (38). Phylogenetic studiessuggest that the native counterparts of the synthetic retrocyclinsused in this study were lost by mutation(s) that occurred ina common ancestor of gorillas, chimpanzees, and humans (38).

It was recently reported that certain ${theta}$ defensins, includingretrocyclins, protect cells from infection by HIV-1 in vitro(12) and that they are miniature lectins (56) that bind gp120and block the entry of HIV-1 (12, 36). The present experimentsexamined the ability of synthetic ${theta}$ defensins to protect humancervical epithelial cells from infection by HSV-1 and HSV-2and their ability to bind gB2, a glycoprotein that allows HSV-2to attach to and enter cells.

MATERIALS AND METHODS

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Materials and Methods

Peptides. The peptides used in this study are described in Table 1. Retrocyclin1 (RC [retrocyclin congener] 100) was synthesized by Anaspec(San Jose, Calif.) and purified, folded, and cyclized in ourlaboratory. The other peptides were synthesized at the Universityof California, Los Angeles, on a Perkin-Elmer ABI 431 A synthesizer,with prederivatized polyethylene glycol polystyrene arginineresin (PerSeptive Biosystems, Framingham, Mass.) and FastMocchemistry, with double coupling throughout. The crude peptidewas reduced at 50°C under N₂ with excess dithiothreitolin 6 M guanidine HCl-0.2 M EDTA (pH 8.2). After addition ofglacial acetic acid to a 5% final concentration, the reducedpeptide was stored under N₂ until further purification by reversed-phasehigh-pressure liquid chromatography (RP-HPLC). After this step,the peptides appeared homogenous and their theoretical massagreed closely with the mass found by matrix-assisted laserdesorption ionization mass spectrometry analysis.

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TABLE 1. ${theta}$ defensins used in this study^a

Cystine disulfide bonds were formed by dissolving the reducedpeptides in 0.1% acetic acid (0.1 mg of peptide/ml) and adjustingthe pH to 7.4 with ammonium hydroxide. After the stirred solutionwas incubated for 24 h at room temperature, acetic acid wasadded to a 5% final concentration. The oxidized peptides werepurified by another round of RP-HPLC and showed the expected6-atomic-mass-unit decrease. To form an amide bond between theiramino- and carboxy-terminal residues, the oxidized peptideswere incubated for 18 h at room temperature in a 3:1 mixtureof ethylenediaminecarbodiimide and anhydrous N-hydroxybenzotriazolein dimethyl sulfoxide (49). After lyophilization of the reactionproducts, the cyclic peptide was subjected to RP-HPLC on a C₁₈column with a linear gradient of acetonitrile: water in 0.1%trifluoroacetic acid, resulting in >95% purity. HNPs 1 to3, purified from healthy human neutrophils as previously described(23), contained HNP 1, HNP 2, and HNP 3 in a ratio of 2:2:1.

Cells and viruses. HSV strains and cell lines were from the American Type CultureCollection. They included HSV-1 M (the MacIntyre strain, ATCCVR-539), HSV-2 G (ATCC VR-734), ME-180 human cervical carcinomacells (HTB 33), Vero African green monkey kidney cells (CCL81), and CaSki human cervical epithelial cells (ATCC CRL 1550).The viruses were propagated on Vero cells in a conventionalmanner and were stored at –85°C until used.

Viral glycoprotein. HSV-2 recombinant glycoprotein B (gB2) was generated using theBac-to-Bac system (Gibco) and purified by heparin-affinity chromatography.Sodium dodecyl sulfate-polyacrylamide gel electrophoresis followedby silver staining confirmed its purity (25). Anti-gB2 monoclonalantibody (1123) was purchased from the Goodwin Institute, Plantation,Fla.

Direct viral inactivation. Viral titers were assayed by infecting ME-180 cell monolayersin 96-well plates with twofold serially diluted viral inoculaand incubating the cells for 72 h at 37°C. A viral dilutionthat produced 75 to 80% cell death, based on MTT [3-(4,5-dimethylthiazolyl-2)-2,5-diphenyltetrazolium bromide] reduction, was used in the inactivationassays. The corresponding multiplicity of infection (MOI) andPFU-per-well values were approximately 0.2 and $~$ 6 x 10³, respectively,for HSV-1 M and 0.04 and 1 x 10³, respectively, for HSV-2 G.ME-180 target cells were seeded in 96-well tissue culture platesat 2.5 x 10⁴ cells/well and incubated for 48 h at 37°C.In our initial screening assays, unless otherwise noted, theviruses were preincubated with 50 µg of peptide/ml for2 h at 37°C before they were added to the target cells.To do so, we added the 8.8 µl of virus inoculum to 304.7µl of RPMI with 2% fetal bovine serum and introduced 16.5µl of the 1-mg/ml stock peptide solution. Virus-free controls(peptide only) and peptide-free controls (virus plus acidifiedwater only) were incubated in parallel. To initiate infection,the regular medium was aspirated from the target cells and replacedwith 100 µl of the peptide-treated viral inoculum/wellor appropriate controls. Trays were incubated at 37°C for72 h, and cytotoxicity was measured with the MTT kit. Calculationsof activity and corrections for background cytotoxicity wereas previously described (47, 48, 58).

Dose-response experiments were done on RTD 3, retrocyclin 1(RC 100), and retrocyclin 2 (RC 100b) by incubating final peptideconcentrations of 25, 20, 10, and 5 µg/ml with the virusstocks for 2 h as described above. This mixture was added directlyto ME-180 cells in incubation medium containing the same peptideconcentration present during preincubation. The plates wereincubated at 37°C for 72 h, and cytotoxicity was measuredwith the MTT kit.

Confirmatory plaque reduction assays were performed with themost active peptides, retrocyclins 1 and 2 and RTD 3. In someexperiments, a 2-h preincubation of virus with 5 to 50 µgof peptide/ml was followed by delivering the inoculum to ME-180cells in wells containing the corresponding peptide concentration.In other experiments, preincubation was omitted and the viruseswere delivered directly into the wells containing target cellsand peptide. Plaques were counted 24 h later, after the monolayerswere stained with crystal violet (43).

Time course. Confluent monolayers of CaSki cells in six-well dishes werecooled to 4°C and inoculated with 200 to 500 PFU of HSV-2G virus/well at 4°C for 3 h. Unbound virus was removed bywashing the cells three times, and the cultures were transferredto 37°C for 1 h to permit penetration. Any nonpenetratingviruses were inactivated by washing the monolayer for 2 minwith an acidic buffer (pH 3.0) that contained 50 mM sodium citrateand 4 mM KCl. Then, fresh medium was added, and 1 h later thewells were overlaid with medium containing 0.5% methylcelluloseand incubated for 48 h. Plaques were counted by immunoassay(black plaque) (26, 46). HNPs 1 to 3 or retrocyclin 2 was added(i) during the 4°C binding period, (ii) when cells wereshifted to 37°C, or (iii) immediately post-citrate treatmentfor 1 h to determine whether the defensins inhibited infectionif present during these time windows.

Surface plasmon resonance. Experiments were performed on a Biacore 2000 system (Biacore,Inc., Piscataway, N.J.). Running buffer (pH 7.4) contained 10mM HEPES, 150 mM NaCl, 3 mM EDTA, and 0.005% polysorbate 20.The HSV-2 glycoprotein, gB2, was dissolved at 20 µ g/mlin 10 mM sodium acetate, pH 5.0, and immobilized on a CM5 sensorchip by the amine coupling method. The chip was activated bymixing 400 mM N-ethyl-N-(3-dimethylaminopropyl)-carbodiimidehydrochloride and 100 mM N-hydroxysuccinimide. An immobilizationlevel of approximately 6,000 response units was attained forthe bound protein. Residual reactive groups on the chip surfacewere blocked using 1.0 M ethanolamine-HCl, pH 8.5.

The flow cell 1 (FC1) chip, which served as a control, lackedimmobilized protein but was treated as described above. Signalswere corrected for nonspecific binding by subtracting the FC1signal. To regenerate the chips, bound ligands were removedwith 10 mM HCl. Data were analyzed with BIAevaluation 3.1 software.Curve fitting was done assuming one-to-one binding. In someexperiments, immobilized gB2 was deglycosylated for 3 h at 37°Cwith recombinant enzymes—peptide:N-glycosidase F (PNGaseF) (5 U), sialidase A (0.005 U), and/or endo-O-glycosidase (0.00125U)—from the GlycoPro deglycosylation kit (ProZyme, SanLeandro, Calif.).

Binding studies. To determine if the defensins inhibited binding of gB2 to cells,we exposed CaSki cells to recombinant gB2 for 1 h at 37°Cin the presence or absence of HNPs 1 to 3 or retrocylin 2. Afterthis, unbound gB2 and defensins were removed by washing thecells extensively. Cell-bound glycoprotein was analyzed by Westernblotting, with the use of cell lysates and an anti-gB2 monoclonalantibody. Blots were subsequently incubated with goat anti-mouseimmunoglobulin G conjugated to horseradish peroxidase and developedwith the ECL chemiluminescence kit (DuPont, Boston, Mass.).Western blots were scanned, and bound gB2 was analyzed usingthe GELDOC 2000 Bio-Rad system linked to an IBM PC computer.

VP16 and ICP4. To delineate the steps in HSV infection inhibited by ${alpha}$ and ${theta}$ defensins,we conducted synchronized studies and monitored infection byexamining transport of the tegument protein VP16 to the nucleusor expression of immediate-early gene product ICP4 as previouslydescribed (9). Synchronized infectivity assays were done asdescribed above except that the MOI was equivalent to 1 PFU/celland the penetration time (i.e., the time from temperature shiftto citrate treatment) was reduced to 15 min. Defensins or controlagents were added for 1 h during the 4°C binding period,at the time at which the cells were transferred to 37°C(penetration), or immediately after the citrate treatment (postpenetration).Thereafter, the cells were overlaid with medium and viral infectionwas monitored by examining transport of VP16 or expression ofICP4. Nuclear extracts were prepared 3 h postinfection to examinetransport of VP16 to the nucleus; alternatively cell lysateswere prepared 5 h postinfection to examine ICP4 expression

Cytotoxicity. Assays were done with the MTT Cell Proliferation Kit I (BoehringerMannheim/Roche) according to the manufacturer's instructions.Briefly, ME-180 cells grown to confluency in RPMI 1640 with10% fetal bovine serum, 2 mM L-glutamine, and 50 µg ofgentamicin/ml were harvested with trypsin-EDTA, washed, anddiluted in the above medium to 5 x 10⁴ cells/ml. Cells (100µl) were dispensed into 96-well tissue culture platesand allowed to adhere for 5 h at 37°C in an atmosphere ofroom air plus 5% CO₂. Then, 10 µl of peptide (variousconcentrations) or its vehicle (0.01% acetic acid) was added,and the incubation was continued for 20 h. The cells were solubilizedovernight, and the optical density was measured at 600 and 650nm, on a SpectraMax 250 microplate spectrophotometer (MolecularDevices, Sunnyvale, Calif.).

Statistics. Unpaired t tests were performed with the SigmaStat 2.0 statisticalpackage (Jandel Scientific, San Rafael, Calif.).

RESULTS

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Results

Activity against HSV-1. Screening studies were done in 96-well microplates, with a recentlydescribed MTT reduction assay. Peptides were tested at a singleconcentration (50 µg/ml), and the viral inoculum was preincubatedfor 2 h with each peptide. Under these conditions (Fig. 1),RTD 3 and retrocyclins 1 and 2 were effective, but RTDs 1 and2 and retrocyclin 3 were not. The most effective peptides, RTD3 and retrocyclins 1 and 2, constitute group A in Fig. 1. Exceptfor RC 110 (retroenantioretrocyclin 1), none of the retrocyclin1 analogues had much activity against HSV-1. All of the peptidesin group B (RCs 101 to 108) were significantly less active againstHSV-1 than were those in group A (P < 0.001). RCs 102 to108 were peptides in which a single ß-sheet residuehad been replaced by a tyrosine. RC 101 contained a single arginine-to-lysinereplacement in one of the ß turns. Although RC 111,the retroanalogue of retrocyclin 1, retained some activity,RC 112 (enantioretrocyclin 1) was inactive.

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FIG. 1. Protection of ME-180 cells from infection by HSV-1 and HSV-2 (MTT assay). Peptides (50 µg/ml) and viruses were coincubated for 2 h, before being added to target cell monolayers that also contained 50 µg of peptide/ml. After incubation at 37°C for 72 h, cytotoxicity was measured with a kit. The bars (black, HSV-1; gray, HSV-2) represent means ± standard errors of the means of two to five experiments with each peptide. Asterisks identify the peptides whose activities against HSV-1 and HSV-2 differed significantly (P < 0.001). Group A and group B peptides are further described in the text.

Activity against HSV-2. Similar studies were performed with HSV-2 (Fig. 1). RTD 3 andretrocyclin 2 showed the best activity, followed by RTD 2 andretrocyclin 1. RC 103 was moderately effective against HSV-2,but RTD 1 and RC 110 (retroenantioretrocyclin 1) lacked activityagainst HSV-2 despite their effectiveness against HSV-1 (P <0.001). Only three peptides (RTD 3 and retrocyclins 1 and 2)were active against both HSV-1 and HSV-2. To confirm the activityand assess relative potency, we tested these peptides in a plaquereduction assay (Fig. 2). In descending order of potency, thepeptides ranked as follows: retrocyclin 2 > RTD 3 > retrocyclin1.

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FIG. 2. Protection against HSV-1 and HSV-2. The most active peptides against HSV-1 and HSV-2 were RTD 3, retrocyclin 1 (RC 100), and retrocyclin 2 (RC 100b). Each peptide (various concentrations) was incubated with HSV-1 or HSV-2 for 2 h and added to ME-180 cell monolayers with the same concentration of peptide. After a 24-h incubation, aliquots were harvested for plaque counting.

Comparative activity against herpesviruses and HIV-1. It was recently reported that retrocyclin 1 and certain RTDscan protect human peripheral blood mononuclear cells from infectionby T- and M-tropic strains of HIV-1 (56). Because of these studieswith HIV-1, each peptide had already been tested against HIV-1strains IIIB and JR-CSF. In Fig. 3, the y axis shows activityagainst HSV-2 and the x axis shows previously published (12)activity of 20 µg of peptide/ml against HIV-1 strainsJR-CSF (solid circles) and IIIB (open triangles). A 4-log₁₀decrease (i.e., 99.99%) in the concentration of p24 antigenon day 9 of culture, relative to the p24 concentration in theabsence of peptide, represents complete protection from HIV-1infection. With respect to activity against HSV-1, HSV-2, andthe HIV-1 strains the peptides ranked as follows: retrocyclin2 > RTD 3 > retrocyclin 1. The structures of these peptidesand that of RTD 1 are shown in Fig. 4.

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FIG. 3. Comparative antiviral activity. Each peptide is represented by a closed circle, and the most active peptides are labeled with their identifier in Table 1. The x axis shows activity against HIV-1, and the y axis shows activity against HSV-2. The JR-CSF strain (R5) of HIV-1 is represented by closed circles, and the IIIB strain (X4) is represented by open triangles. The most active peptides, retrocyclin 2 (RC 100b), RTD 3, and retrocyclin 1 (RC 100) are labeled.

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FIG. 4. Structures of selected ${theta}$ defensins. Four ${theta}$ defensins are diagrammed. ${theta}$ defensins are circular octadecapeptides with two antiparallel ß sheets that are linked by ß turns and bridged by an evenly spaced tridisulfide ladder. Their 18 residues represent two 9-residue peptides contributed by a truncated, ${alpha}$ -defensin-like prepropeptide. Black arrows identify the sites where the individual nonapeptide elements would be spliced together in vivo. The white arrows show the direction of the peptide backbone and point from the N terminus toward the C terminus.

To this point, all results with HSV-1 and -2 were obtained afterpreincubating the viruses and peptides together for 2 h beforeadding them to target cells. To see if a preincubation stepwas necessary, we turned to plaque-forming assays (Fig. 5).These revealed that retrocyclin 2 showed substantial activitywithout any preincubation step and that retrocyclin 1 and RTD3 had little or no activity unless they were preincubated withHSV-2. Figure 5 also shows that retrocyclin 1 and RTD 3 hadmuch greater activity against HSV-2 than against HSV-1.

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FIG. 5. Effect of preincubation on activity. HSV-1 and HSV-2 were exposed to various concentrations (5, 10, 20, and 25 µg/ml) of retrocyclins 1 to 3. Some viruses were preincubated with peptide for 2 h before being added to the ME-180 target cells ("2h pre"). In other assays, the peptide and virus were added to the target cells without preincubation ("no pre"). Viral replication was assessed by plaque counting, and percent protection was equated with the percent reduction in PFU. Results are means of two separate experiments with very similar results.

Retrocyclin 2, but not HNPs 1 to 3, blocks HSV-2 attachment. Since retrocyclin 2 was the most protective peptide, we furtherexplored the mechanism of its antiviral activity by examiningwhich steps in viral invasion were blocked by retrocyclin 2.For comparison, we tested HNPs 1 to 3. We have previously shownthat rabbit ${alpha}$ defensin NP-1 blocks HSV-2 infection at a steppostbinding, but similar studies with human ${alpha}$ defensins havenot been reported. To define the step(s) in HSV invasion thatwas blocked by retrocyclin 2 and HNPs 1 to 3 (25), kinetic assayswere performed as previously described. CaSki cells were cooledto 4°C and exposed to virus for 3 h to allow viral attachment.Then, unbound virus was removed by washing, and cells were shiftedto 37°C to allow penetration. After 1 h, the cells werewashed with a low-pH citrate buffer to inactivate nonpenetrantvirus and fresh medium was added. After 1 additional h of incubation,the cells were again washed and overlaid with medium containingmethylcellulose. Retrocyclin 2, HNPs 1 to 3, or control buffer(0.01% acetic acid in water) was added during the 4°C bindingperiod (time A), at the time of temperature shift (penetration)(time B), or immediately post-citrate treatment for 1 h (postentry)(time C). Plaques were counted 48 h later. Results are depictedin Fig. 6. At 25 µg/ml, retrocyclin 2 inhibited HSV-2infection by 99% if added at time A (during binding). An antiviralactivity persisted, albeit a reduced one, if the peptide wasadded at time B (temperature shift) but not if added at timeC (postentry). In contrast HNPs 1 to 3 primarily inhibited viralinfection if added at time B (temperature shift), during thepostbinding period of viral penetration.

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FIG. 6. Time signature of the antiviral effect. Cells were cooled to 4°C and inoculated with HSV-2 G in the presence of peptide-free control buffer, retrocyclin 2, or HNPs 1 to 3. Peptides were added at different times, as described in Materials and Methods. The bars, which show PFU formed in the presence of defensin as a percentage of PFU formed in the control wells, represent the means ± standard deviations of two independent experiments, each performed in duplicate.

Other effects of retrocyclin. The earliest detectable measures of HSV-2 entry are translocationof VP16, a viral tegument protein, to the nucleus and expressionof ICP4, the immediate-early gene product. To assess the effectsof retrocyclin 2 on these indicator responses, we conductedsynchronized infectivity assays as described above, except thatthe MOI was 1 PFU/cell and the time from temperature shift tocitrate treatment (penetration period) was reduced to 15 min.Representative results are shown in Fig. 7. Nuclear VP16 andexpression of ICP4 were markedly diminished when retrocyclin2 was added during either binding or penetration. HNP 1 hadlittle effect if added during binding, but it reduced both VP16transport and ICP4 expression if added during the penetrationperiod, suggesting that the ${alpha}$ defensins prevent an early postbindingstep. In contrast, retrocyclin 2 inhibits viral entry when presentduring either the binding or the penetration period.

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FIG. 7. VP16 transport and IC4 expression. (a) These assays examined the effects of retrocyclin 2 or HNPs 1 to 3 on VP16 transport to the nucleus and ICP4 expression after infection with HSV-2(G). Peptides were added during the 4°C binding period or at the temperature shift. After 4 h, nuclear extracts were prepared for VP16, and after 5 h, cell lysates were prepared for ICP4 expression. Lanes contained extracts or lysates from equivalent cell numbers, and VP16, ICP4, and ß-actin (loading control) were detected by Western blotting. (b) To examine the effect on binding, cells were exposed to recombinant gB-2 (10^–5 µg/cell) for 1 h at 37°C ± the indicated concentration of retrocyclin 2. Bound gB-2 was estimated by probing Western blots of cell lysates with anti-gB monoclonal antibody. Results are representative of three independent experiments.

To more specifically examine the effects of retrocyclin 2 onbinding of gB2 to target cell heparan sulfate, binding studieswere conducted with recombinant gB2. Figure 7 shows that 25µg of retrocyclin 2/ml completely inhibited the bindingof recombinant gB2 to CaSki cells. These results differ fromthose previously published for the rabbit ${alpha}$ defensin NP-1, whichfailed to inhibit binding of recombinant gB2 to CaSki cells.Similarly, HNPs 1 to 3 also showed little or no inhibitory effectson binding of recombinant gB2 to cells (data not shown).

It was recently reported that ${theta}$ defensins inhibit the cellularentry of HIV-1 (12, 36) and that they bind with high affinityto gp120 (56), a viral envelope glycoprotein whose interactionswith CD4 and other coreceptors on the target cell surface arerequired for penetration. This suggested that ${theta}$ defensins mightprotect cells from HSV-2 infection by binding gB2, an envelopeglycoprotein whose presence is essential for target cell bindingand penetration by HSV-2 (10). Figure 8a to c shows that 0.12µg of retrocyclin 2/ml, 0.5 µg of retrocyclin 1/ml,and 1.0 µg of RTD 3/ml all bound to immobilized gB2 toabout the same extent. Judging from its lower "off rate," thegB2-retrocyclin 2 complex was more stable than the complexesformed between gB2 and either retrocyclin 1 or RTD 3 were. Quantitativeanalysis of these binding isotherms (Table 2) indicated thatgB2 binds retrocyclin 2 with much higher affinity (K_d, 13.3nM) than it bound retrocyclin 1 (K_d, 142 nM) or RTD 3 (K_d, 174nM). The 10-fold-greater affinity of retrocyclin 2 for gB2 derivesin approximately equal measure from its higher K_on (on rate)and lower K_off (off rate).

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FIG. 8. Binding of ${theta}$ defensins to gB2. Surface plasmon resonance binding curves (isotherms) of binding to immobilized gB2 are shown for retrocyclin 1 (RC 100a) (a), retrocyclin 2 (RC 100b) (b), RTD 3 (c), HNP 1 (d), HNP 2 (e), and HNP 3 (f). The concentration of peptide in each run is shown adjacent to its curve. The peptides were introduced into the flow cell at the 1-min mark, and 60 s later, at the 2-min mark, the sensor chips were perfused with peptide-free buffer to allow the off rate to be measured. Rate and affinity constants can be found in Tables 2 and 3.

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TABLE 2. Correlation between the binding of ${theta}$ defensins to immobilized gB2 and protective activity against HSV-2

The DEFT genes that encode ${theta}$ defensins are mutated ${alpha}$ -defensingenes (38, 49). Because we have previously shown that rabbitand human ${alpha}$ defensins protect cells from infections by HSV-1and -2 and because ${alpha}$ defensins are homologous to ${theta}$ defensins,we performed surface plasmon resonance experiments to determineif ${alpha}$ defensins also bind gB2. Our results with HNPs 1 to 4 aresummarized in Table 3 and illustrated for selected ${alpha}$ defensinsin Fig. 8d to f. Table 3 shows that HNP 2 (net charge, +3) boundgB2 with an affinity (K_d, 30.3 nM) that was higher than thatof every ${theta}$ defensin shown in Table 2, except for retrocyclin2, whose K_d was 13.3 nM. HNPs 1 and 3 bound gB2 with somewhatreduced affinity (K_d of 50 to 60 nM). The sequences of HNPs1 to 3 are identical at 29 of their 30 residues (96.7%), differingonly at their N-terminal residue (Table 3). HNP 4, which ismore cationic (net charge, +4) than HNPs 1 to 3 (net charge,+2 to +3), has a 50- to 100-fold-lower affinity for gB2 (K_d,2,880 nM) than they do. HNP 4 is identical to HNPs 1 to 3 inonly 11 of 34 (32.4%) positions, and at least 8 of the 11 identicalresidues (six cysteines, one arginine, and one glycine) havewell-established structural roles. Thus, as we found for the ${theta}$ defensins, the ability of ${alpha}$ defensins to bind gB2 is primarilydetermined by their sequence, rather than by their net cationiccharge.

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TABLE 3. Binding of ${alpha}$ defensins HNP 1 to HNP 4 to immobilized gB2

${alpha}$ and ${theta}$ defensins bind carbohydrate moieties on gB2. Selective removal of O-linked or N-linked glycans from immobilizedgB2 greatly reduced its binding by ${alpha}$ and ${theta}$ defensins (Fig. 9).Removing O-linked glycans with endo-O-glycosidase reduced themagnitude of binding by at least 50%, and simply removing thesialic acids with sialidase A decreased binding by at leasttwo-thirds. Removing the N-linked glycans of gB2 had an evengreater effect, such that binding was nearly undetectable. Overall,these findings indicate that sialic acid and other carbohydratemoieties in the O- and N-linked glycans of gB2 are responsiblefor defensin binding. Since removing the O-linked glycans alonesubstantially reduced binding and removing the N-linked residuesvirtually abolished binding, we infer that the O-linked andN-linked glycans may act cooperatively in providing bindingsites for defensins or that defensin binding was influencedby the local density of sugar residues.

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FIG. 9. Effect of deglycosylation on binding to gB2. Immobilized gB2 was selectively deglycosylated by incubation with sialidase A, endo-O-glycosidase, PNGase F, or a mixture of all three enzymes. Sialidase A removes nonreducing terminal and branched sialic acid residues. Endo-O-glycosidase removes O-linked glycans by cleaving Ser/Thr-linked unsubstituted Galß(1-3)GalNAc ${alpha}$ disaccharides. PNGase F removes N-linked glycans.

Cytotoxicity. The cytotoxicity of the three RTDs, 1 to 3, for human ME-180cervical epithelial cells is shown in Fig. 10a. Whereas RTD3 caused substantial cytotoxicity, RTD 1 and RTD 2 were welltolerated, even at 200 µg/ml. Neither retrocyclin 1 norretrocyclin 2 caused appreciable cytotoxicity to ME-180 cells,even at 500 µg/ml (Fig. 10b). Retrocyclin 3 was more cytotoxicthan was retrocyclin 1 or 2 but less so than RTD 3. Since retrocyclin2 (RC 100b) was the most effective ${theta}$ defensin in preventing HSV-1and HSV-2 from infecting ME-180 cells, its activity againstthese viruses cannot be attributable to cytotoxicity.

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FIG. 10. Lack of cytotoxicity. (a) Effects of three RTDs, 1 to 3, on human ME-180 cervical epithelial cells. (b) Effects of retrocyclins 1 to 3 on these cells. The sequences of these peptides can be found in Table 1.

Inactivity against vaginal lactobacilli. Unlike many previously reported ${alpha}$ and ß defensins, ${theta}$ defensins have shown distinctly unimpressive antibacterialproperties in our experiments. Their inactivity against twostrains of lactobacilli, Lactobacillus acidophilus and Lactobacilluscrispatus, at pH 4.5 (a normal vaginal pH) and pH 7.0 was entirelyconsistent with this behavior (data not shown). Although thisproperty would be considered an unusual attribute for an antimicrobialpeptide, it may be highly advantageous for an antiviral peptide,especially if it were to be used as a topical microbicide.

DISCUSSION

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Discussion

The prevalence of HSV-2 infection has increased greatly overthe past 20 years, and it is estimated that 22% of adult Americansare currently infected with this virus (20). A recent modelingstudy concluded that, without intervention, the prevalence ofHSV-2 infection among individuals aged 15 to 39 years wouldlikely increase to 39% among men and 49% among women by 2025.Unlike the sexually transmitted infections caused by HIV-1,those caused by HSV-2 are infrequently lethal. Nonetheless,HSV-2 infections cause substantial morbidity, and over the next25 years new HSV-2 infections will cost upwards of 61 billiondollars (20).

Since it was determined that nonoxynol-9 failed to protect at-riskindividuals from acquiring sexually transmitted infections (19,29), interest has grown in developing topical microbicides ableto prevent infection by HIV-1. Recent reviews mention that over30 agents are currently in clinical or preclinical development(52, 54). They include BufferGel (22), an acidic buffer; surfactantssuch as C31G⁴ (Savvy) (4) and sodium dodecyl sulfate; variousacidic polymers (37) including carrageenan (32) (Carraguard);D2S (a dextran-sulfate analogue); certain reverse transcriptaseinhibitors (18); monoclonal antibodies (41, 55, 59); and thelectin cyanovirin-N (Cv-N) (35). A few of these agents alsohave the potential to protect against HSV-2 infection (59).

Of the above, retrocyclins and ${theta}$ defensins most closely resembleCv-N, because their carbohydrate-binding and antiviral propertiesare intimately related. Cv-N, an 11-kDa protein from the cyanobacteriumNostoc ellipsosporum (39), selectively binds Man (8) and Man(9) oligosaccharides with nanomolar affinity (6), includingthose on HIV-1 envelope glycoproteins gp120 and gp41 (7, 45).Extremely low Cv-N concentrations protect cells from infectionby M- and T-tropic strains of HIV-1. As concentrations thatcompletely inhibit HIV-1 infection do not block binding of solubleCD4 receptor to HIV-1 lysates or attachment of intact HIV-1virions to target T-cell lines, the protective effects of Cv-Nagainst HIV-1 may arise from interference with postbinding fusionevents (33). Cv-N is active against other viruses, includingEbola virus (1) and influenza A and B viruses (40), but wasinactive (50% effective concentration of >10 µg/ml)against HSV-2 and had only moderate activity (a 50% effectiveconcentration of 0.7 µg/ml) against a strain of HSV-1.Cv-N may be much more cytotoxic than retrocyclin 2 and other ${theta}$ defensins are, since its 50% inhibitory concentration (theconcentration that caused 50% cytotoxicity) for Vero cells wasonly 2.3 µg/ml (40).

The carbohydrate residues to which ${theta}$ defensins bind are not yetdefined, and there is a dearth of published information aboutglycans associated with HSV-2 glycoproteins. We have establishedthat retrocyclin 2 and other ${theta}$ defensins do not bind to the high-mannoseoligosaccharides that are recognized by Cv-N (unpublished data),and studies to identify the glycan residues that are recognizedby ${theta}$ defensins are in progress.

This report showed that retrocyclin 2 bound to HSV-2 gB2 withextremely high affinity, that it prevented gB2 from associatingwith target cell membranes, and that it blocked the entry ofHSV-2 into target cells. For initial binding to cells, bothHSV-1 and -2 use heparan sulfate moieties as receptors (10).Given the critical role of gB2 in HSV-2 binding and its essentialrole in penetration and cell-cell spread, this glycoprotein,which contains eight potential N-glycosylation sites (8), isan important target for development of novel antiviral drugs.It remains to be determined if retrocyclin 2 can also interactwith glycan moieties in the other essential glycoproteins, gDand gH-gL. Furthermore, since retrocyclin 2 has shown effectivenessagainst herpesviruses 1 and 2 and HIV-1, its effects on otherviruses of biomedical interest merit exploration.

Although phylogenetic analysis suggests that ${theta}$ defensins havebeen around for over 30 million years (38), they are "novel"molecules for many reasons. Whereas circular peptides have beenidentified in various plants (2, 13, 15, 44) and bacteria (14), ${theta}$ defensins are the only known circular peptides of animal origin.They were first described in 1999 (49), but as yet only a fewpublications (12, 31, 49, 50, 56) describe their provenanceand properties. The unusual posttranslational modificationsinvolved in their formation by leukocytes (49) remain to beexplored, as does the in vivo significance that their antiviralproperties may have for the primates still able to produce them.There is remarkable parallelism between the effects of retrocyclinson HIV-1 and those on HSV. In both cases, the peptide bindswith very high affinity to a viral surface glycoprotein involvedin viral entry, either gp120 (56) or gB2 (this paper), and itis able to prevent cellular entry of HIV-1 (12, 36) and HSV-2(this paper).

Retrocyclin 2 is currently the most potent antiviral ${theta}$ defensinthat we have tested that is active against both HIV-1 and HSV-2.Whether ${theta}$ defensins will prove to be effective against otherviruses remains to be established. Their inactivity againstlactobacilli and their negligible cytotoxicity are desirableproperties for a potential topical microbicide. While additionalquestions remain to be addressed, retrocyclins and other ${theta}$ defensinsare interesting molecules whose chemical and biological propertiesdeserve increased attention.

ACKNOWLEDGMENTS

This study was supported by grants from the National Institutesof Health, AI 37845 and AI 22838 to R.I.L. and HD 43733 andAI 39740 to B.C.H.

FOOTNOTES

* Corresponding author. Mailing address: Department of Medicine, CHS 37-062, David Geffen School of Medicine at UCLA, Los Angeles, CA 90095. Phone: (310) 825-5340. Fax: (310) 206-8766. E-mail: rlehrer{at}mednet.ucla.edu.

REFERENCES

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