Impact of Secondary Structure of Toll-Like Receptor 9 Agonists on Interferon Alpha Induction

Oligodeoxynucleotides containing a CpG motif and double- ormultistranded structure-forming sequences act as agonists ofToll-like receptor 9 (TLR9) and induce high levels of interferonalpha (IFN- ${alpha}$ ) in addition to other Th1-type cytokines. In thepresent study, we evaluated three highly effective IFN- ${alpha}$ -inducingagonists of TLR9 to determine the type of duplex structuresformed and the agonist's ability to induce immune responses,including IFN- ${alpha}$ induction, in human cell-based assays and invivo in mice and nonhuman primates. Thermal melting studiesshowed that two of the agonists evaluated had a single meltingtransition with similar hyperchromicity in both heating andcooling cycles, suggesting the formation of intermolecular duplexes.A third agonist showed a biphasic melting transition in theheating cycle and a monophasic melting transition with lowerhyperchromicity during the cooling cycle, suggesting the formationof both intra- and intermolecular duplexes. All three agonistsinduced the production of Th1-type cytokines and chemokines,including high levels of IFN- ${alpha}$ , in human peripheral blood mononuclearcell and plasmacytoid dendritic cell cultures. Subcutaneousadministration of the two intermolecular duplex-forming agonists,but not the intramolecular duplex-forming agonist, induced cytokinesecretion in mice. In nonhuman primates, the two agonists thatformed intermolecular duplexes induced IFN- ${alpha}$ and IP-10 secretion.On the contrary, the agonist that formed an intramolecular duplexinduced only low levels of cytokines in nonhuman primates, suggestingthat this type of structure formation is less immunostimulatoryin vivo than the other structure. Taken together, the presentresults suggest that oligonucleotide-based agonists of TLR9that form intermolecular duplexes induce potent immune responsesin vivo.

INTRODUCTION

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INTRODUCTION

The vertebrate immune system recognizes highly conserved molecularpatterns that are present in pathogens through a number of patternrecognition receptors. Toll-like receptors (TLRs) are amongthe well-characterized pattern recognition receptors. At least10 TLRs have been identified in humans, and one of them, TLR9,is the receptor for bacterial and synthetic DNA containing unmethylatedCpG motifs (4). TLR9 is expressed predominantly in B cells andplasmacytoid dendritic cells (pDCs) in humans. Activation ofthese two cell types by synthetic oligonucleotides containingunmethylated CpG motifs via TLR9 results in a Th1-type immuneresponse which includes the secretion of interferon alpha (IFN- ${alpha}$ ),IFN- ${gamma}$ , interleukin-12 (IL-12), tumor necrosis factor alpha (TNF- ${alpha}$ ),and IL-6 with an increase in the levels of costimulatory surfacemolecules (1, 11, 12, 17, 19, 28). A number of TLR9 agonistsare currently being evaluated in clinical trials as therapiesfor various diseases, including cancers, infectious diseases,allergy, and asthma, and as vaccine adjuvants (1, 10).

The immune response profiles induced via TLR9 stimulation dependon the stimulatory motif and secondary structure present inthe oligonucleotides (1-3, 5, 13, 15, 22, 23). Agonists of TLR9that induce high levels of IFN- ${alpha}$ contain either poly(dG)-basedhyperstructure-forming sequences (14, 20) or regions of duplex-formingsequences (3, 15, 22). However, TLR9 agonists containing poly(dG)sequences lack pharmaceutical properties and have not been evaluatedin clinical trials. Agonists of TLR9 containing duplex-formingsequences induce IFN- ${alpha}$ production in cell-based assays and arebeing examined as candidates for the treatment of chronic hepatitisC virus infection in humans.

The type of duplex structure, intra- versus intermolecular,required for IFN- ${alpha}$ induction in vitro and in vivo has not beeninvestigated. In the present study, we have selected three sequencesthat induce high levels of IFN- ${alpha}$ in vitro (7, 15, 22) and evaluatedtheir duplex structures and ability to induce TLR9-mediatedimmune responses in vitro and in vivo in mice and nonhuman primates.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Synthesis and purification of agonists of TLR9. Agonists of TLR9 and control oligonucleotides were synthesizedon a 1- to 2-µmol scale by using β-cyanoethylphosphoramiditechemistry on a PerSeptive BioSystems 8909 Expedite DNA synthesizeras described earlier (9, 25). The purity of agonists rangedfrom 90 to 95%, with the rest being shorter by one or two nucleotides(n – 1 and n – 2) as determined by capillary gelelectrophoresis and/or denaturing polyacrylamide gel electrophoresis.All of the compounds contained less than 0.5 EU/ml endotoxin,as determined by the Limulus assay (Bio-Whittaker).

Thermal melting study. Agonists of TLR9 at a 2 µM concentration in 1 ml of 10mM sodium phosphate buffer, pH 7.2, containing 100 mM NaCl wereheated for 5 min at 95°C and allowed to return to room temperatureslowly. The solutions were stored at 4°C overnight beforethe thermal melting temperature (T_m) was measured. Thermal meltingexperiments were carried out with a Perkin-Elmer Lambda 20 UV/VISspectrophotometer equipped with a Pelteir temperature controllerand a multicell holder. Data were collected at each degree byheating or cooling the samples at a rate of 0.5°C/min. Thedata were collected and analyzed by using Templab software ona personal computer attached to the instrument. Each experimentwas carried out at least two times.

Stimulation of HEK293 cells expressing TLR9. HEK293 cells stably expressing mouse TLR9 (Invivogen, San Diego,CA) were cultured in 48-well plates in 250 µl/well Dulbeccomodified Eagle medium supplemented with 10% heat-inactivatedfetal bovine serum in a 5% CO₂ incubator. At 80% confluence,cultures were transiently transfected with 400 ng/ml SEAP (secretedform of human embryonic alkaline phosphatase) reporter plasmid(pNifty2-SEAP; Invivogen) in the presence of 4 µl/ml Lipofectamine(Invitrogen, Carlsbad, CA) in culture medium. Plasmid DNA andLipofectamine were diluted separately in serum-free medium andincubated at room temperature for 5 min. After incubation, thediluted DNA and Lipofectamine were mixed and the mixtures wereincubated at room temperature for 20 min. Aliquots of 25 µlof the DNA-Lipofectamine mixture containing 100 ng of plasmidDNA and 1 µl of Lipofectamine were added to each wellof the cell culture plate, and the cultures were continued for6 h. After transfection, the medium was replaced with freshculture medium, agonists or control oligonucleotide were addedto the cultures, and the cultures were continued for 18 h. Atthe end of the experiment, 20 µl of culture supernatantwas taken from each treatment and used for SEAP assay in accordancewith the manufacturer's (Invivogen) protocol. Briefly, culturesupernatants were incubated with QUANTI-Blue substrate and theblue color generated was measured by a plate reader at 650 nm.The data are shown as n-fold increases in NF- ${kappa}$ B activity overthe phosphate-buffered saline (PBS) control.

Isolation of human B cells and pDCs. Peripheral blood mononuclear cells (PBMCs) from blood freshlydrawn from healthy volunteers (Research Blood Components, Brighton,MA) were isolated by Ficoll density gradient centrifugation(Histopaque-1077; Sigma). B cells and pDCs were isolated fromPBMCs by positive selection with the CD19 and BDCA4 cell isolationkits, respectively, according to the manufacturer's (MiltenyiBiotec) instructions.

Human B-cell proliferation assay. About 1 x 10⁵ B cells/well were stimulated with different concentrationsof TLR9 agonists for 66 h and then pulsed with 0.75 µCiof [³H]thymidine and harvested 8 h later. The incorporationof [³H]thymidine was measured by scintillation counter, andthe data are shown as counts per minute.

Human PBMC and pDC cultures. Human PBMCs and pDCs were plated in 96-well plates at 5 x 10⁶and 1 x 10⁶ cells/ml, respectively. The compounds dissolvedin Dulbecco's PBS were added at a final concentration of 10µg/ml to the cell cultures. The cells were then incubatedat 37°C for 24 h, and the supernatants were collected forLuminex multiplex assays.

Luminex multiplex assay. The levels of cytokines and chemokines in cell culture supernatantswere determined by human cytokine multiplex 25-bead assay (Invitrogen,Camarillo, CA). Data were collected on a Luminex 100 instrument,and fluorescence intensity was transformed into cytokine concentrationwith StarStation software (Applied Cytometry Systems).

Assessment of mouse serum cytokine levels. Female C57BL/6 mice, 5 to 8 weeks old, were obtained from CharlesRiver Laboratories and maintained in accordance with Idera Pharmaceutical'sIACUC-approved animal protocols. Each agonist or control oligonucleotidewas administered to mice (n = 3) subcutaneously (s.c.) at 1mg/kg (single dose). Blood was collected by retro-orbital bleeding2 h after agonist administration, and serum IL-12 levels weredetermined by sandwich enzyme-linked immunosorbent assay (ELISA)as described previously (9). All reagents, including cytokineantibodies and standards, were purchased from PharMingen (SanDiego, CA).

Nonhuman primate study. Healthy young cynomolgus monkeys (Macaca fascicularis) weighingapproximately 2 to 5 kg were used in this study. All studieswere approved by the WIL Research Laboratories or MPI ResearchAnimal Care and Use Committee and were conducted at WIL ResearchLaboratories, Inc., Ashland, OH, or MPI Research, Inc., Mattawan,MI, respectively. Animals were monitored daily by veterinarians.Each TLR9 agonist was administered s.c. to three animals onday 1 at 1 mg/kg. Blood samples (1 ml) were collected for plasmacytokine measurement at 0, 1, 2, 4, 8, 24, 48, and 72 h afteragonist administration. All animals remained in good healththroughout the experiment.

Cytokine analysis of monkey blood samples. Plasma samples were thawed on ice and tested in duplicate forIFN- ${alpha}$ , IL-6, and IP-10 with commercial kits obtained from PBL(human IFN- ${alpha}$ ), BD PharMingen (human IL-6), and R&D Systems(human IP-10) according to the manufacturer's instructions.

Statistical analysis. The results reported for human cell culture assays representmeans plus standard deviations obtained from multiple determinationsin three or more separate experiments, and the significanceof changes was evaluated with Student's t test. For nonhumanprimate studies, in any one experiment, there were at leastthree or four animals in each treatment group. The area underthe curve was computed with the MedCalc software. Statisticalanalyses were carried out by analysis of variance, and the significanceof changes was evaluated by the Student-Newman-Keuls post hoctest. P < 0.05 was considered statistically significant.

RESULTS

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RESULTS

TLR9 agonists. The nucleotide sequences of agonists 1 to 3 were taken frompublished papers (7, 15, 22) and are shown in Table 1. Agonists1 and 2 had natural CpG stimulatory motifs at the 5' end anda duplex-forming sequence toward the 3' end. Agonist 3 containedtwo short oligomers linked through their 3' ends (7). Agonist3 also contained synthetic CpR (R = 2'-deoxy-7-deazaguanosine)motifs in a palindromic sequence that allows the formation ofa duplex structure. All three agonists were of similar length(21 or 22 nucleotides) and were characterized by mass spectralanalysis for sequence integrity and by capillary and/or slabgel electrophoresis for purity.

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TABLE 1. Phosphorothioate oligonucleotide sequences and chemical modifications of TLR9 agonists

Thermal melting study. The three agonists were studied for secondary structure formationby UV thermal melting experiments. At a concentration of 2 µM,all three agonists showed cooperative dissociation curves asthe temperature increased from 5 to 95°C (Fig. 1), and theT_ms calculated are shown in Table 1. Agonists 2 and 3 showedmonophasic melting transitions with T_ms of 30.1 and 20.8°C,respectively. On the contrary, agonist 1 showed a biphasic meltingtransition with T_ms of 58 and 82°C (Fig. 1A). Both agonists2 and 3 had association curves similar to their respective dissociationcurves (Fig. 1B and C), with T_ms of 31.4 and 21.5°C, respectively.The association curve of agonist 1 was monophasic, with a T_mof 56°C, unlike its biphasic dissociation curve with lowerhyperchromicity (Fig. 1A). These results suggest that agonists2 and 3 form a single homogeneous structure, while agonist 1forms at least two different structural populations under theexperimental conditions used. Possible secondary structuresformed by each agonist are shown in Fig. 1 along with the theoreticallycalculated ${Delta}$ G values.

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FIG. 1. UV thermal melting curves of agonists 1 (A), 2 (B), and 3 (C). The thick line in each plot represents the dissociation curve obtained as the temperature increased from 5 to 95°C (heating curve), and the thin line represents the association curve obtained during cooling of the samples from 95 to 5°C (cooling curve). The data shown are representative of at least two independent experiments. See Table 1 for sequence information.

Activation of TLR9 by agonists. To determine if the agonists were recognized by TLR9, we usedHEK293 cells expressing mouse TLR9. All three agonists activatedNF- ${kappa}$ B, unlike the control compound lacking a stimulatory CpGmotif, indicating that TLR9 recognizes CpG and CpR dinucleotidesin the agonists (Fig. 2).

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FIG. 2. Activation of HEK293 cells expressing mouse TLR9 by agonists at a 10 µg/ml concentration. The data shown are representative of three or more independent experiments.

Activation of human PBMCs and pDCs and induction of IFN- ${alpha}$ secretion. Agonists were evaluated for their biological effects on freshlyisolated human PBMCs. All three agonists induced the productionof IFN- ${alpha}$ and other cytokines and chemokines, including IL-12,IP-10, IL-6, IL-2R, MIP-1 ${alpha}$ , and MIP-1β, by human PBMCs (Fig.3). Of the three compounds, agonist 3 induced the highest levelsof IFN- ${alpha}$ in PBMC cultures. All three agonists were also testedfor the ability to induce cytokine and chemokine productionby freshly isolated human pDCs, which express TLR9 (Fig. 4).All three agonists induced the production of similar levelsof IL-6, IL-12, IFN- ${alpha}$ , IP-10, IL-2R, MCP-1, MIP-1 ${alpha}$ , and MIP-1βin pDC cultures (Fig. 4). All three agonists produced significantlyhigher levels of cytokines and chemokines compared with thecontrol oligonucleotide in both human PBMCs and pDCs. The statisticalsignificance of differences between the compounds is indicatedin Fig. 3 and 4.

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FIG. 3. Induction of cytokine and chemokine production by TLR9 agonists in human PBMC cultures. PBMCs isolated from fresh blood obtained from healthy human volunteers were cultured in the presence or absence of 10 µg/ml TLR9 agonists for 24 h as described in Materials and Methods. Supernatants were collected and analyzed by Luminex multiplex assay. The data shown are representative of three or more independent experiments. M and C stand for medium and control oligonucleotide 4, respectively. The statistical significance of differences between the agonists was determined and is indicated by the symbols #, $, and *, where P < 0.05 for 1 versus 2, 2 versus 3, and 1 versus 3, respectively.

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FIG. 4. Induction of cytokine and chemokine production by TLR9 agonists in human pDC cultures. pDCs isolated from PBMCs of healthy human volunteers were cultured in the presence or absence of 10 µg/ml TLR9 agonists for 24 h as described in Materials and Methods. Supernatants were collected and analyzed by Luminex multiplex assay. The data shown are representative of three or more independent experiments. M and C stand for medium and control oligonucleotide 4, respectively. The statistical significance of differences between the agonists was determined and is indicated by the symbols #, $, and *, where P < 0.05 for 1 versus 2, 2 versus 3, and 1 versus 3, respectively.

Activation of human B cells by agonists. As B cells also express TLR9, we further evaluated the abilitiesof the agonists to induce B-cell proliferation. All three agonistsproduced a dose-dependent increase in the proliferation of Bcells, and the extents of proliferation were similar among theagonists (Fig. 5). The control compound did not induce B-cellproliferation, suggesting that the proliferation was sequencespecific (Fig. 5).

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FIG. 5. Human B-cell proliferation induced by agonists at various concentrations of agonists 1 ( ${diamond}$ ), 2 ( ${square}$ ), and 3 ( ${triangleup}$ ); control oligonucleotide 4 (•); and PBS ( ${blacktriangleup}$ ). Experiments were carried out as described in Materials and Methods. The data shown are representative of three or more independent experiments.

IL-12 induction in vivo in mice. Administration of 1 mg/kg agonist 3 or 2 s.c. to mice resultedin the elevation of serum IL-12 levels to about 115 and 17.5ng/ml, respectively (Fig. 6). On the contrary, administrationof agonist 1 at the same dose to mice did not result in anychange in the levels of serum IL-12 compared with the controlcompound (Fig. 6).

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FIG. 6. In vivo IL-12 induction by agonists in mice at a 1 mg/kg dose. Blood was collected 2 h after agonist administration, and serum IL-12 was determined by ELISA as described in Materials and Methods. The data shown are representative of three independent experiments.

Cytokine profiles of TLR9 agonists in nonhuman primates. Each agonist was administered s.c. to cynomolgus monkeys ata single dose of 1 mg/kg, blood was collected at different timeintervals, and plasma levels of IFN- ${alpha}$ , IP-10, and IL-6 were determinedby ELISA (Fig. 7). Administration of agonist 2 or 3 to monkeysresulted in maximal levels of IFN- ${alpha}$ induction by 8 h (Fig. 7A).Agonists 2 and 3 induced similar levels of IFN- ${alpha}$ . A sustainedlevel of IFN- ${alpha}$ was observed up to 72 h postadministration inthe plasma of monkeys that received agonist 3. In contrast,plasma IFN- ${alpha}$ of monkeys that received agonist 2 returned to predoselevels by 48 h (Fig. 7A). Agonist 1 induced lower levels ofIFN- ${alpha}$ than did agonists 2 and 3; the maximal levels were observedat around 24 h, and the levels returned to the background by48 h (Fig. 7A). Agonists 1 and 2 produced similar levels ofIP-10, with peak concentrations reached by 4 to 8 h after agonistadministration (Fig. 7B). Agonist 3 induced levels of IP-10more than two times higher than those induced by agonists 1and 2. Both agonists 2 and 3 induced minimal levels (<50pg/ml) of IL-6 (Fig. 7C). On the contrary, agonist 1 inducedrelatively higher levels of IL-6; a maximal concentration ofabout 250 pg/ml was measured at 8 h after agonist administration(Fig. 7C).

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FIG. 7. In vivo IFN- ${alpha}$ (A), IP-10 (B), and IL-6 (C) induction by agonists 1 ( ${diamond}$ ), 2 ( ${square}$ ), and 3 ( ${triangleup}$ ) in cynomolgus monkeys. The plasma levels of IFN- ${alpha}$ produced by agonist 3 are statistically significantly different from those produced by agonists 1 and 2.

DISCUSSION

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DISCUSSION

TLR9 agonists promote B-cell proliferation, immunoglobulin production,and the secretion of a number of Th1-type cytokines, includingIL-12, IFN- ${gamma}$ , IL-6, and IFN- ${alpha}$ . TLR9 recognizes synthetic and bacterialDNA that contains unmethylated CpG motifs and initiates an immunesignaling cascade in a MyD88-dependent fashion (10, 22), leadingto the activation of the transcription factors NF- ${kappa}$ B (18) andAP-1 (24). While a CpG dinucleotide is essential for TLR9 activation,a number of other factors, such as the nucleotides flankingthe CpG dinucleotide, the presence of an accessible 5' end,the position of the CpG dinucleotide in oligonucleotides, andthe secondary structures of the oligonucleotides, play criticalroles in the activation of immune cells (1).

Our previous studies with mouse and human cell-based assaysshowed that CpG oligonucleotides containing a hairpin structureat the 3', but not the 5', end were immunostimulatory (2, 5).These results were consistent with our studies showing thatan accessible 5' end of a CpG oligonucleotide is required forTLR9 stimulation (6-9, 26, 27). In fact, the 3' hairpin structure-formingCpG oligonucleotides induce high levels of IFN- ${alpha}$ production byhuman pDCs, suggesting that a secondary structure is requiredfor IFN- ${alpha}$ induction by TLR9 agonists (2, 3, 5). However, surprisingly,such intramolecular hairpin structure-forming CpG oligonucleotidesdid not induce immune responses in vivo (our unpublished results).

CpG oligonucleotides containing palindromic sequences, referredto as class C, activate B cells and pDCs and induce the productionof high levels of IFN- ${alpha}$ in vitro (3, 15, 22). Because of theirability to induce IFN- ${alpha}$ production, some of these compounds havebeen evaluated as candidates in clinical trials with hepatitisC-infected patients (16, 21). The presence of longer palindromicsequences in oligonucleotides can facilitate the formation ofboth intra- and intermolecular duplexes. It is not known whetherdifferent types of TLR9 agonists that induce high levels ofIFN- ${alpha}$ form intra- or intermolecular duplexes or if their secondarystructures affect the induction of immune responses in vivo.In the present study, we evaluated three different TLR9 agoniststhat have three distinct sequence compositions (7, 15, 22) buthave a common feature of forming duplexes and inducing the productionof high levels of IFN- ${alpha}$ in cell-based assays. Additionally, agonists1 to 3 have seven, four, and six CpG (R) dinucleotides, respectively.However, studies have shown that the presence of more than threeCpG dinucleotides in a 22- to 25-mer oligonucleotide does notenhance activity further (12). The goal of this study was todetermine the type of structures formed and the immune responseprofiles produced by these compounds in vitro and in vivo.

In UV thermal melting studies, agonists 2 and 3 showed a monophasicthermal melting transition, suggesting that they formed a singletype of duplex structure. In fact, the association curve wasvery similar to the dissociation curve. In contrast, agonist1 showed a biphasic thermal melting curve with two distincttransitions and the association curve showed a monophasic transitionwith lower hyperchromicity. These results suggest that agonist1 forms two distinct populations of secondary structures atequilibrium and upon rapid cooling it forms a kinetically morefeasible secondary structure with lower hyperchromicity. Thetype of 3'-3'-attached structure in agonist 3 does not permitthe formation of a hairpin structure between the two branches.Similarly, a short, 10-nucleotide-long palindromic sequencein each branch of agonist 3 does not permit the formation ofthe intramolecular hairpin type of structure. Therefore, agonist3 forms only an intermolecular duplex. In contrast, agonist1 forms a mixture of both intra- and intermolecular duplexes.Based on the thermal melting study results, agonist 2 appearsto form only an intermolecular duplex.

In HEK293 and primary human cell-based assays, all three compoundsactivated TLR9 and produced TLR9-mediated immune responses.In fact, all three compounds induced comparable levels of IFN- ${alpha}$ and other cytokines and chemokines in human pDCs and inducedsimilar levels of human B-cell proliferation. These resultsare consistent with our earlier studies showing that both inter-and intramolecular duplex-forming CpG oligonucleotides induceimmune responses in vitro (2, 5). The differences in the activitiesobserved in vitro could be a result of differences in oligonucleotidesequence composition rather than the number of CpG dinucleotidespresent in each agonist.

In vivo in mice, agonists 2 and 3, which form intermolecularduplexes, induced IL-12 production. Agonist 1, which can formboth intra- and intermolecular duplexes, failed to induce IL-12production. These results are consistent with other intramolecularhairpin-forming oligonucleotides that were studied in our laboratoryand found not to induce immune responses in vivo in mice (ourunpublished results).

Not many studies of TLR9 agonists in vivo in monkeys have beenreported. Comparison of the three agonists in nonhuman primatesshowed that agonist 1 induced lower levels of IFN- ${alpha}$ and IP-10than did agonists 2 and 3. Agonist 3, which forms a multimericintermolecular duplex, induced significantly higher and sustainedlevels of IFN- ${alpha}$ up to 72 h after administration at the dose leveltested. Additionally, the immune response profiles induced byagonists 2 and 3 differed as agonist 1 induced IL-6 in nonhumanprimates whereas agonists 2 and 3 did not.

In summary, the present in vitro and in vivo studies suggestthat CpG oligonucleotides containing palindromic sequences canform both intra- and intermolecular duplexes. In vitro studiesshow that both intra- and intermolecular secondary structure-formingCpG oligonucleotides induce potent cytokine production, includingIFN- ${alpha}$ induction in pDCs. Intramolecular secondary structure-formingCpG oligonucleotides are less potent than intermolecular secondarystructure-forming CpG oligonucleotides in vivo, however. Intermolecularsecondary structure-forming agonists of TLR9 induce potent immuneresponses in vivo, including IFN- ${alpha}$ induction in nonhuman primates.Based on these results, we have selected agonist 3, which formsan intermolecular duplex and induces high levels of IFN- ${alpha}$ innonhuman primates, as a candidate for the treatment of hepatitisC. Agonist 3 is currently being evaluated in a phase I clinicaltrial with hepatitis C-infected patients.

FOOTNOTES

* Corresponding author. Mailing address: Idera Pharmaceuticals, 167 Sidney Street, Cambridge, MA 02139. Phone: (617) 679-5501. Fax: (617) 679-5542. E-mail: sagrawal{at}iderapharma.com

Published ahead of print on 13 October 2008.

REFERENCES

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