Anthrax Toxin-Mediated Delivery In Vivo and In Vitro of a Cytotoxic T-Lymphocyte Epitope from Ovalbumin

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Infect Immun, February 1998, p. 615-619, Vol. 66, No. 2
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Anthrax Toxin-Mediated Delivery In Vivo and In Vitro of a Cytotoxic T-Lymphocyte Epitope from Ovalbumin

Jimmy D. Ballard, Amy M. Doling, Kathryn Beauregard, R. John Collier, and Michael N. Starnbach^*

Department of Microbiology and Molecular Genetics, Harvard Medical School, Boston, Massachusetts 02115

Received 14 August 1997/Returned for modification 15 October 1997/Accepted 20 November 1997

	ABSTRACT

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We reported earlier that a nontoxic form of anthrax toxin was capable of delivering a cytotoxic T-lymphocyte (CTL) epitopein vivo, such that a specific CTL response was primed againstthe epitope. The epitope, of bacterial origin, was fused to anN-terminal fragment (LFn) from the lethal-factor component ofthe toxin, and the fusion protein was injected, together withthe protective antigen (PA) component, into BALB/c mice. Herewe report that PA plus LFn is capable of delivering a differentepitope $---$ OVA_257-264 from ovalbumin. Delivery was accomplishedin a different mouse haplotype, H-2K^b and occurred in vitro as well as in vivo. An OVA_257-264-specificCTL clone, GA-4, recognized EL-4 cells treated in vitro with PAplus as little as 30 fmol of the LFn-OVA_257-264 fusion protein.PA mutants attenuated in toxin self-assembly or translocationwere inactive, implying that the role of PA in epitope deliveryis the same as that in toxin action. Also, we showed that OVA_257-264-specificCTL could be induced to proliferate by incubation with splenocytestreated with PA plus LFn-OVA_257-264. These findings implythat PA-LFn may serve as a general delivery vehicle for CTL epitopesin vivo and as a safe, efficient tool for the ex vivo expansionof patient-derived CTL for use in adoptive immunotherapy.

	INTRODUCTION

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Cytotoxic T-Lymphocytes (CTL) recognize and clear defective host cells which display nonself peptides on their surface (13,28). These peptides arise from various sources, such as infectiousagents or aberrant expression of self proteins, and mark defectivecells for CTL recognition. Proteins within the cytosol are processedby the multicatalytic proteasome to generate small peptides, whichare then transported to the lumen of the endoplasmic reticulum(ER) by specific transporters, TAP1 and TAP2 (16). Once in theER, the peptides complex with newly synthesized class I majorhistocompatibility molecules (MHC-I), and the peptide-MHC-I complexesegress from the ER and are presented at the cell surface. Uponrecognition of foreign peptide-MHC-I complexes, specific CTL areactivated to clear the pathogen or defective cell (1, 7).Activated CTL lyse the infected cell, secrete cytokines, proliferate,and differentiate. Lysis of the target cell may deprive an infectiousorganism of its replicative niche or, in the case of tumor cells,limit the expansion of the defective cells. By secreting cytokines(e.g., interleukin-2 and gamma interferon) CTL recruit other componentsof the immune response to the site of the defect. Proliferationand differentiation expand the number of specific CTL availablefor targeting similar defective cells and generate a set of long-livedmemory cells available to respond more quickly and effectivelyto subsequent challenge. Vaccines that prime these memory CTLprovide protection for the host upon subsequent exposure to similardefective cells.

The development of vaccines to specifically prime CTL has been hindered by difficulties in developing safe mechanisms to deliverCTL epitopes to the host cell cytosol. Several approaches to thisproblem have been reported (23, 26, 34, 35), includingthe use of attenuated viruses, intracellular bacteria, naked DNA,and adjuvants. Each of these approaches presents inherent problemsof safety and/or efficiency. The use of attenuated viruses andbacteria raises questions about possible pathogenic effects ofthese agents, especially in immunocompromised individuals (25).The use of DNA vaccines risks the integration of naked DNA intothe host chromosome (10), and most promising adjuvants are notwell tolerated in humans (25). Recently we reported the developmentof a noninfectious, nontoxic vehicle for the delivery of epitopes,involving a modified form of anthrax toxin (4). This techniqueinvolves genetically fusing a CTL epitope to a nontoxic componentof anthrax toxin that can enter the cytosol of cells.

Anthrax toxin is composed of three proteins that act in binary combinations to elicit two toxic effects, death and edema (18).Lethal factor (LF) and edema factor (EF) are intracellularly actingproteins, which require protective antigen (PA) for translocationto the cytosol of mammalian cells. During cellular entry, PA isproteolytically activated at the cell surface, generating a 63-kDafragment, PA₆₃, which contains a site at which EF and LF competefor binding. Following EF or LF binding to PA, the protein complexis endocytosed and trafficked to the endosome, where the boundLF or EF is translocated to the cytosol following endosomal acidification.Within the cytosol, EF expresses its adenylate cyclase activityand LF expresses a yet undefined activity inducing the overproductionof cytokines in macrophage target cells (14, 15).

Recently, it was found that the amino-terminal 255-amino-acid domain of LF (LFn) directs interactions with PA (2, 3).LFn contains the information necessary for PA binding and translocationbut is devoid of lethal activity. Thus, heterologous proteinsgenetically fused to LFn can be delivered to the cytosol of culturedmammalian cells in the presence of PA (24). These results suggestedthat if CTL epitopes were fused to LFn, the resulting fusion proteinsmight be delivered to the cytosol by PA and generate a CTL responsein vivo. In an initial report, we described the use of the PA-LFnsystem to prime specific CTL in vivo by using a known epitopederived from the intracellular pathogen Listeria monocytogenes(4). Delivery was efficient, with as little as 300 fmol ofthe fusion priming epitope-specific CTL. Mice vaccinated by thisapproach were partially protected against an L. monocytogeneschallenge.

In the present study, PA-LFn was used to deliver a CTL epitope (OVA_257-264) derived from ovalbumin and presented inthe context of H-2 K^b (6, 21). LFn was genetically fused to OVA_257-264,and the epitope was shown to be presented in complex with MHC-Iboth in vivo and in vitro. PA mutants attenuated in steps of LFnbinding or translocation are unable to deliver LFn-OVA_257-264,confirming that cytosolic delivery is an essential step in generatingtarget cells by this approach.

In addition, we show that PA plus LFn-OVA_257-264 can be used to generate stimulator cells that expand specific CTL invitro. Expansion of patient-derived CTL in vitro is an importantstep for adoptive immunotherapy targeting a variety of infectiousdiseases and cancers (5, 9, 20, 36).

	MATERIALS AND METHODS

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Peptide. The synthetic peptide OVA_257-264, with the sequence SIINFEKL, was purchased from Biosynthesis Inc. (Lewisville, Tex.).

Construction, expression, and purification of fusion proteins. DNA fragments encoding LFn-OVA_257-264 were constructed by PCR. LFn-OVA_257-264 was amplified with an upstream primerwhich included an NdeI site and sequence homologous to the 5'end of the LF gene. The downstream primer was homologous to thesequence encoding the last 6 amino acids of LFn and included (downstreamof the homology) sequence encoding the OVA_257-264 epitope,stop codons, and a BamHI site. The toxin-encoding plasmid fromBacillus anthracis Sterne, pXO1, was used as the template. TheNdeI-BamHI fragment was ligated into compatible sites within themultiple-cloning region of pET15b (Novagen) and used to transformEscherichia coli XL1-Blue (Stratagene). For each clone, the plasmidDNA was amplified, purified, and screened for the appropriateinsert by restriction analysis. Clones containing inserts werelocally sequenced to confirm that the fusion was correct. Theseclones were then used to transform E. coli BL21(DE3) (31) forexpression of the fusion protein.

Recombinant proteins expressed in pET15b contain a His₆ tag at the amino terminus of the protein. This tag allows for a one-stepaffinity purification of the expressed protein on a Ni²⁺-charged column. Cultures of BL-21/pET15b(LFn-OVA_257-264)were grown in Luria broth containing ampicillin (50 µg/ml) toan optical density at 600 nm of 0.6 to 0.8, and protein expressionwas induced by the addition of 1 mM isopropyl- $beta$ -D-thiogalactopyranoside(IPTG) for approximately 3 h. The cells were then pelleted anddisrupted by sonication. The sonicate was centrifuged, and thesupernatant was passed over an equilibrated Ni²⁺-charged column. The bound fusion protein was removed with 0.5M imidazole as specified by the manufacturer (Novagen). The elutedprotein was then equilibrated in 20 mM Tris-HCl (pH 7.5). Theprotein concentration was determined, and the sample was frozenat $-$ 20°C.

Wild-type PA was isolated from supernatant cultures of an attenuated strain of B. anthracis by an established method (19).

Stimulation of OVA_257-264-specific CTL. All the mice used in this study were female C57BL/6 (Jackson Laboratories), H-2^b, between 8 and 12 weeks of age. Mouse splenocytes were harvestedand CTL were stimulated as described previously (29), with thefollowing modifications. Spleen cells from immunized and controlmice were isolated and washed once in RP-10. Cells used as stimulatorswere naive, irradiated (2,000 rads), syngeneic splenocytes treatedwith 10 µM sterile OVA_257-264 peptide. The stimulator cellswere incubated for 1 h in the presence of peptide and then washedonce in RP-10. Cultures contained 3 × 10⁷ stimulator cells and 3 × 10⁷ splenocytes from either immunized or control mice. These wereincubated upright in a T-75 flask at 37°C in 7% CO₂ in a totalvolume of 20 ml of RP-10.

CTL assay. For target cells, mouse thymoma EL-4 (H-2^b) cells were incubated with 10 µM OVA_257-264 synthetic peptide and labeledwith 20 µl of sodium [⁵¹Cr]chromate (600 Ci/ml; 1 Ci = 37 GBq) for 1 h. The cells werethen washed twice with medium to remove unbound peptide and extracellularradionuclide. Ten thousand radiolabeled cells either treated withpeptide or untreated (negative control) were then added to stimulatedeffector cell dilutions. The total volume in each assay well was200 µl. Spontaneous and complete lysis of target cells was determinedby incubating target cells with RP-10 or 1% Triton X-100, respectively.After 4 h of incubation at 37°C, the 96-well plates were centrifugedat 2,000 × g and 100 µl of the supernatant was counted for releaseof ⁵¹Cr. The percent specific lysis was determined as 100 × (CTL release $-$ spontaneous release)/(maximum release $-$ spontaneous release).

In vitro assay for cytosolic delivery of OVA_257-264. EL-4 cells were aliquoted into 12 15-ml conical tubes at 5 × 10⁵ cells/tube. Six of the tubes contained PA (100 ng) in 1 ml (PAplus), and the other six contained 1 ml of RP-10 medium alone(PA minus). The samples, both PA plus and PA minus, were treatedwith either 100, 10, or 1 ng of LFn-OVA_257-264 for 3.5 h.Duplicate samples were tested at each concentration. The treatedcells were then centrifuged, and the total volume was reducedto 50 µl in RP-10. After the cells were resuspended, 20 µl ofsodium [⁵¹Cr]chromate was added to each sample and the cells were incubatedfor an additional 1 h. The cells were then washed three timesand resuspended in a final volume of 5 ml of RP-10. Dilutionsof the CTL clone GA-4 (starting with 10⁵) were made and added to wells of a 96-well round-bottom plate.A 100-µl volume of the treated EL-4 cells (10⁴ cells) was added to each of the GA-4 dilutions. In addition,both peptide-coated and uncoated target cells were mixed withmedium alone (spontaneous control) or 1% Triton X-100 (completelysis control). The assay mixture was incubated for 4 h, the platewas centrifuged, and 100 µl of the supernatant was analyzed ina gamma counter to determine ⁵¹Cr release.

Construction, expression, and analysis of PA mutants. Site mutants of PA defective in receptor binding or translocation of LFn were analyzed by the above system. Both PA mutantshave been described previously, and their phenotypes are wellestablished (12, 27). The first mutant, PA --D³¹⁵, has two amino acid deletions (FFD³¹⁵ to --D³¹⁵) within the chymotrypsin loop and is unable to translocate LFto the cytosol but binds LF with similar efficiency to the wildtype. The second mutant, PA RSSR¹⁶⁷, has three substitutions (RKKR¹⁶⁷ to SSSR¹⁶⁷) within a furin-sensitive region. This PA mutant is not nickedby furin and is unable to bind LF.

Both mutants were generated by two-step PCR mutagenesis, where the sense-strand primer encodes the appropriate mutations.The mutant PCR products were subcloned into the wild-type PA genemaintained in pET22b (Novagen). The mutant proteins were transformedinto E. coli BL-21 and purified from periplasmic extracts by acombination of gel filtration and anion-exchange chromatography.

In vitro expansion of GA-4 CTL with spleen cells treated with PA plus LFn-OVA_257-264. The ability of PA-LFn to be used as a tool for generating specific CTL stimulator cells was evaluated by the following approach.Splenocytes from a C57BL/6 mouse were washed and resuspended in2 ml of ACK lysis buffer to lyse erythrocytes (8). After 1min of incubation, 8 ml of RP-10 was added to the cells and thecells were pelleted by centrifugation. The cells were then resuspendedto a concentration of 5 × 10⁶ cells/ml in RP-10, and 1 ml was added to each of six tubes. Toeach of the six tubes was added one of the following: RP-10, 1µM peptide (SIINFEKL), 10 ng of LFn-OVA_257-264 plus 100ng of PA, 10 ng of LFn-OVA_257-264, 100 ng of LFn-OVA_257-264plus 100 ng of PA, or 100 ng of LFn-OVA_257-264. The treatedcells were incubated for 4 h and then irradiated (2,000 rads),washed, and resuspended in 1 ml of RP-10 supplemented with $alpha$ -methylmannoside and rat spleen supernatants treated with concanavalinA (30). A 100-µl volume of each sample was plated in each oftriplicate wells of a flat-bottom 96-well plate. GA-4 CTL (10⁴ cells) and irradiated (2,000 rads) syngeneic spleen cells (6× 10⁵ cells) were added to each well, and the samples were incubatedin the presence of 7% CO₂ at 37°C for 48 h. Following the incubation,20 µl of [³H]thymidine (6.7 Ci/mmol) was added to a final concentration of2.5 µCi/ml. Following 14 h of incubation, the samples were harvestedwith a model 96 well plate harvester (TomTec Inc., Orange, Conn.)and counted with a model 1205 Beta-Plate counter (Wallac Instruments,Gaithersburg, Md.).

	RESULTS

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LFn-OVA_257-264 plus PA primes an epitope-specific CTL response in vivo. To determine if LFn-PA could be used to stimulate OVA_257-264-specific CTL in vivo, we constructed plasmids encodingthe 8-amino-acid OVA_257-264 CTL epitope fused downstreamof the first 255 amino acids of LF (generating LFn-OVA_257-264).Mice (5 per group) were injected intraperitoneally (i.p.) with30 pmol of the fusion protein mixed with 6 pmol of PA. Controlgroups of mice were injected with LFn-OVA_257-264 withoutPA. After 2 weeks, the animals were sacrificed and 3 × 10⁷ splenocytes were stimulated on syngeneic spleen cells coatedwith the OVA_257-264 peptide. After 5 days of stimulationin vitro, the cells were assayed for the ability to lyse EL-4cells coated with OVA_257-264.

As shown in Fig. 1, lysis of peptide-coated EL-4 was substantially higher than lysis of EL-4 cells alone, indicating thatthe mice had mounted an OVA_257-264-specific CTL response.This result is similar to our initial findings with LLO_91-99epitope fusions, in BALB/c mice. As with the LFn-LLO_91-99fusion protein, LFn-OVA_257-264 delivery was dependent onthe presence of PA. These results demonstrate the versatilityof the system, showing the delivery of a different epitope invivo in a different murine haplotype.

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FIG. 1. CTL-mediated lysis of OVA_257-264 peptide-coated EL-4 cells. Mice were injected i.p. with LFn-OVA_257-264 plus PA (A) or LFn-OVA_257-264 without PA (B). After in vitro stimulation, samples were assayed for their ability to lyse ⁵¹Cr-labeled EL-4 cells coated with OVA_257-264 peptide (solid circles) or not coated (open circles). Targeting was evaluated by measuring the amount of ⁵¹Cr release. The effector-to-target-cell ratios (E:T ratios) examined were 10:1, 3:1, and 1:1. Similar levels of lysis were observed in each of five replicates.

PA can mediate delivery of an LFn-epitope fusion to the cytosol of cells in vitro. To study LFn plus PA-mediated delivery of OVA_257-264 at the cellular and molecular levels, we designed experiments forin vitro delivery of OVA_257-264. EL-4 cells were used astargets and treated with 100 to 1 ng (3 to 0.3 pmol) of the LFn-OVA_257-264fusion protein in the presence or absence of 100 ng of PA (~1pmol). The cells were incubated with the fusion proteins for 3.5h and then loaded with ⁵¹Cr. They were then assayed for the presentation of OVA_257-264by incubation with the epitope-specific CTL clone, GA-4. Targetcells presenting OVA_257-264 are recognized by GA-4 CTL andlysed, releasing ⁵¹Cr.

Figure 2 shows that when EL-4 cells were treated with the fusion protein in the presence of PA, the cells presented the OVA_257-264epitope and were lysed by GA-4 CTL. Specific lysis of the treatedEL-4 cells decreased when the cells were treated with 10-foldless fusion protein. PA was an essential component of in vitrodelivery, since only targets treated with the fusion protein inthe presence of PA were recognized by GA-4 (Fig. 2). The amountof fusion protein needed for presentation was minimal. GA-4 recognizedtarget cells treated with 100 and 10 ng of the fusion protein(3 and 0.3 pmol, respectively) and even cells treated with only1 ng of the fusion protein were recognized, although the specificlysis was low (<10%).

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FIG. 2. GA-4-mediated lysis of EL-4 cells treated with LFn-OVA_257-264 plus PA. EL-4 cells were treated with 100 ng of LFn-OVA_257-264 (A), 10 ng of LFn-OVA_257-264 (B), or 1 ng of LFn-OVA_257-264 (C). Each sample was treated in the presence (solid circles) or absence (open circles) of PA. Following treatment with the fusion protein, the target cells were loaded with ⁵¹Cr. The target cells were incubated with OVA_257-264-specific CTL to give E:T ratios of 10:1, 3:1, and 1:1. Targeting was evaluated by measuring the amount of ⁵¹Cr release. Similar levels of lysis was observed in each of three repeat experiments.

Mutations in PA inhibit the delivery of LFn-epitope fusion proteins. In both the in vitro and in vivo studies, we have found that PA was essential for generating a CTL response with LFn fusions.Several PA-mediated steps are important for the action of anthraxtoxin on mammalian cells. To confirm that these steps are alsoimportant for the delivery of the CTL epitopes, we used two well-characterizedPA mutants. One (SSSR) was altered in the furin-specific cleavagesite, which blocks its activation by furin or other cell-associatedproteases and thereby prevents toxin self-assembly, includingLFn binding. The other (--D) blocks membrane translocation.

EL-4 target cells were treated with the LFn-OVA_257-264 fusion (100 ng) mixed with the PA mutants (--D and SSSR) or wild-typePA (100 ng). The cells were then loaded with ⁵¹Cr as described above and tested for antigen presentation by incubationwith the OVA_257-264-specific CTL. As seen in Fig. 3, onlyEL-4 cells treated with the fusion protein in the presence ofwild-type PA were recognized for targeting by GA-4. Both PA mutantsshowed levels of specific lysis similar to those of the controlswithout PA and thus were highly attenuated in their ability tomediate epitope delivery.

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FIG. 3. GA-4 targeting of EL-4 cells treated with LFn-OVA_257-264 and PA mutants. EL-4 cells were treated with LFn-OVA_257-264 plus wild-type PA (solid circles), --D mutant PA (solid squares), SSSR mutant PA (open squares), or no PA (open circles). Following treatment with the fusion protein and PA, the target cells were loaded with ⁵¹Cr. The target cells were added to OVA_257-264-specific CTL at E:T ratios of 10:1, 3:1, and 1:1. Targeting was evaluated by measuring the amount of ⁵¹Cr release. Similar levels of lysis was observed in each of three repeat experiments.

To confirm whether these PA mutations also block the ability of toxin fusions to prime CTL in vivo, C57BL/6 mice (three pergroup) were injected i.p. with 30 pmol of the LFn-OVA_257-264fusion protein mixed with 30 pmol of the PA mutants (--D and SSSR)or wild-type PA. A control group consisted of mice injected withthe LFn-OVA_257-264 fusion protein without PA. At 2 weeksafter immunization, the animals were sacrificed and splenocytesfrom each mouse were stimulated in vitro as described above. After5 days of stimulation, the cultures were tested for CTL activityspecific for OVA_257-264. As shown in Fig. 4, a specificCTL response was primed only in mice immunized with wild-typePA. CTL specific for OVA_257-264 were not primed in miceimmunized with either PA mutant. These results further demonstratethe attenuation of these mutants in their ability to deliver epitopesinto a compartment that allows for the priming of CTL.

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FIG. 4. CTL-mediated lysis of OVA_257-264 peptide-coated EL-4 cells. Mice were injected i.p. with LFn-OVA_257-264 plus PA (A), LFn-OVA_257-264 without PA (B), LFn-OVA_257-264 plus PA mutant SSSR (C), or LFn-OVA_257-264 plus PA mutant --D (D). After in vitro stimulation, the samples were assayed for their ability to lyse ⁵¹Cr-labeled EL-4 cells coated with OVA_257-264 peptide (solid circles) or not coated (open circles). Targeting was evaluated by measuring the amount of ⁵¹Cr release. The E:T ratios examined were 10:1, 3:1, and 1:1. Similar levels of lysis were observed in each of three replicates.

Anthrax toxin fusion proteins may be used to expand antigen-specific CTL in vitro. Having demonstrated the use of anthrax toxin fusion proteins to target cells for lysis by CTL, we performed experiments todetermine if an LFn-epitope fusion plus PA might also be usedto generate stimulator cells for the in vitro expansion of specificCTL. In this study, splenocytes were incubated with LFn-OVA_257-264(100 or 10 ng) plus PA (100 ng) and control groups were treatedwith LFn-OVA_257-264 without PA, with SIINFEKL peptide, orwith RP-10 medium. GA-4 CTL were added to the treated splenocytes,and the proliferation of the CTL clone was measured by [³H]thymidine incorporation.

Splenocytes treated with LFn-OVA_257-264 plus PA showed a significantly higher level of proliferation than did the PA-minusand RP-10 controls (Fig. 5). As expected, splenocytes treatedwith synthetic peptide were also able to stimulate the proliferationof the GA-4 CTL. Additionally, as was the case with the in vitrodelivery assay, there was a dose-dependent response to the targetcells. Decreasing the amount of fusion protein 10-fold resultedin a lower [³H]thymidine incorporation by CTL.

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FIG. 5. In vitro expansion of OVA_257-264 specific CTL. Aliquoted mouse splenocytes were treated for 4 h with medium alone, 1 µM OVA_257-264 synthetic peptide, 100 ng of LFn-OVA_257-264 fusion plus PA, 100 ng of LFn-OVA_257-264 minus PA, 10 ng of LFn-OVA_257-264 fusion plus PA, or 10 ng of LFn-OVA_257-264 minus PA. OVA_257-264-specific CTL were added to each sample. Following 48 h of incubation, [³H]thymidine was added to the samples. At 14 h later, the samples were harvested and thymidine incorporation into the cells was assessed. Statistical analysis was performed by Student's t test.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Novel methods of priming specific CTL may well be important in the development of vaccines against various intracellular pathogensand cancers. Recently, we reported using PA-LFn as a moleculartool to deliver the CTL epitope LLO_91-99 in mice (4).Here we report the PA-LFn-mediated delivery of a different epitopein a different mouse haplotype in vivo. OVA_257-264-specificCTL were primed in C57BL/6 (H-2^b) mice by using the anthrax toxin delivery system (Fig. 1). Theresults were similar to those obtained with LLO_91-99, inwhich delivery was efficient and PA dependent. Remarkably, onlya single injection with a minimal amount of protein was neededto prime specific CTL with either epitope.

Because it is difficult to examine the events at a cellular or molecular level by using the system in vivo, we expanded ourstudies to determine the capacity of this system to function invitro. Delivery of the OVA_257-264 epitope to EL-4 targetcells was demonstrated with a specific CTL clone, GA-4, that recognizesthe ovalbumin-derived epitope and targets EL-4 cells for lysis.A dose-dependent response was observed across the range of LFn-OVA_257-264used in the assay.

Epitope delivery with the anthrax toxin system is PA dependent, presumably because PA functions in this system as it doesin anthrax toxin action, by mediating receptor binding, LF-EFinteraction, and translocation of EF or LF to the cytosol. Totest this assumption, we used two PA mutants, known to be attenuatedin toxin self-assembly and translocation, in delivery assays invitro and in vivo. The findings that neither PA mutant allowedtargeting of EL-4 by specific CTL and that neither mutant allowedfor priming of CTL in vivo serve as strong evidence that PA playssimilar functional roles in both LF/EF and epitope delivery.

The in vitro expansion of patient CTL represents a viable and promising approach for therapeutic treatment of a variety ofdiseases (5, 9, 11, 17, 20, 22, 32, 33). Forreasons that remain unclear, patients often mount a CTL responsethat recognizes cancer or infected cells but are not able to clearthe defective cells. This may be due in large part to the numberof CTL generated, so that expansion of these CTL might give sufficientnumbers to clear the defective cells. CTL expanded in vitro couldbe transferred back to the patient in sufficient numbers to effectivelyclear the infected or tumor cells. Patients in this situationare often immunocompromised, which may account in part for theirabbreviated immune response. Moreover, the immunocompromised stateof the patients makes it important to carefully choose approachesfor the in vitro expansion of CTL, avoiding attenuated virusesor other potential infectious agents. As shown in Fig. 4, LFn-OVA_257-264plus PA can be used to stimulate specific CTL. These stimulatorscan then be used to expand the cultured population of GA-4 CTL.LFn-PA may be well suited for in vitro expansion of CTL sinceit is both efficient and nontoxic.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Microbiology and Molecular Genetics, Harvard Medical School, 200 LongwoodAve., Boston, MA 02115. Phone: (617) 632-1873. Fax: (617) 738-7664.E-mail: mstarnba{at}warren.med.harvard.edu.

Editor: J. T. Barbieri

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