Generation of CMV-specific T lymphocytes using protein-spanning pools of pp65-derived overlapping pentadecapeptides for adoptive immunotherapy

doi:10.1182/blood-2003-05-1433

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Blood, 1 April 2005, Vol. 105, No. 7, pp. 2793-2801.
Prepublished online as a Blood First Edition Paper on October 28, 2004; DOI 10.1182/blood-2003-05-1433.

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IMMUNOBIOLOGY
Generation of CMV-specific T lymphocytes using protein-spanning pools of pp65-derived overlapping pentadecapeptides for adoptive immunotherapy
Deepa Trivedi, Roxanne Y. Williams, Richard J. O'Reilly, and Guenther Koehne
From the Allogeneic Bone Marrow Transplantation Service, Department of Pediatrics, Transplantation Biology Laboratory, Sloan-Kettering Institute, Memorial Sloan-Kettering Cancer Center, New York, NY.

   Abstract

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Abstract
Introduction
Materials and methods
Results
Discussion
References

Cell-mediated immunity is essential for control of human cytomegalovirus(HCMV) infection. We used a pool of 138 synthetic overlappingpentadecapeptides overspanning the entire pp65 protein to generatepolyclonal CMV-specific T-cell lines from 12 CMV-seropositivedonors inheriting different HLA genotypes. Autologous monocyte-deriveddendritic cells (DCs) pulsed with this complete pool consistentlyinduced highly specific T cells that selectively recognized1-3 pentadecapeptides identified by secondary responses to amapping grid of pentadecapeptide subpools with single overlaps.Responses against peptide-loaded targets sharing single HLAclass I or II alleles identified the restricting HLAalleles.HLA-A*0201⁺ donors consistently responded to pentadecapeptidescontaining HLA-A*0201-binding epitope_aa495-503NLVPMVATV. T-celllines from other donors contained high frequencies of CD4 and/orCD8 T cells selectively reactive against peptides presentedby other HLA alleles, including both known epitopes such as_aa341-350QYDPVAALF (HLA-A*2402) as well as unreported epitopessuch as _aa267-275HERNGFTVL (HLA-B*4001 and B*4002) and _aa513-523FFWDANDIYRI(HLA-DRB1*1301). These T cells consistently lysed CMV-infectedtarget cells. Thus, this approach fosters expansion and selectionof HLA-restricted CMV-pp65–reactive T-cell lines of highspecificity that also lyse CMV-infected targets, and from afunctional and regulatory perspective, may have advantages forgenerating virus-specific T cells for adoptive immunotherapy.

   Introduction

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Abstract
Introduction
Materials and methods
Results
Discussion
References

Human cytomegalovirus (HCMV) infections continue to be a majorcomplication of allogeneic hematopoietic stem cell transplants(SCTs).^1,2,3 Prophylactic or preemptive administration of ganciclovir(GCV) has reduced the incidence of early CMV disease significantly,but prolonged antiviral treatment may result in a delayed immunereconstitution, favoring the onset of CMV disease after day100.^1,3,4,5
Cell-mediated immunity plays an essential role in the controlof CMV infection and recovery from CMV disease.^6,7 Riddell etal⁸ have shown that protective immunity could be successfullytransferred by the infusion of donor-derived CMV-specific CD8⁺cytotoxic T-cell clones. However, the approaches used to generatethese clones were logistically complex, limiting their broadapplication. Furthermore, in the absence of CD4⁺ T-helper cells,CMV-specific CD8⁺ T-cell clones declined rapidly.⁹ Several alternativeapproaches to generate T cells for adoptive immunotherapy toprevent or treat CMV infections have been proposed. Sun et al¹⁰demonstrated in in vitro studies that Epstein-Barr virus (EBV)–transformedB lymphoblastic cell lines (EBV-BLCLs) transduced with retrovirusencoding the immunodominant CMV protein pp65 could be used asantigen-presenting cells (APCs) to sensitize donor T lymphocytesagainst EBV and CMV epitopes simultaneously. However, theseapproaches necessitate gene transfer and selection of autologoustransduced antigen-presenting cells in each individual caseprior to the initiation of CMV-specific T-cell cultures. Recently,Einsele et al¹¹ and Peggs et al¹² have reported the use of donor-derivedCMV-specific T cells generated by sensitization with CMV lysatesloaded on either donor blood peripheral mononuclear cells (PBMCs)or monocyte-derived cytokine-activated dendritic cells, respectively.The former approach yields predominantly CD4⁺ CMV-specific Tcells,¹¹ while the latter fosters CD8⁺ cytotoxic T-cell populations.¹²Nevertheless, the initial clinical results with each approachhave been encouraging. However, concerns have been raised byregulatory agencies regarding the possibility that lysates ofCMV-infected cells might contain live viral particles that couldbe transferred to the host. CMV-pp65 peptide–specificT cells sensitized with dendritic cells loaded with single immunogenicnonamers binding HLA-A*0201¹³ or isolated from the blood onthe basis of their capacity to bind HLA peptide tetramers¹⁴also are being evaluated. However, T cells specific for singleCMV-pp65–derived peptides may be unduly restricted intheir antiviral activity. Furthermore, these techniques selectfor CD8⁺ T cells, excluding the CD4⁺ helper cell support requiredfor expansion and persistence.⁹
To address these concerns, we have explored the use of poolsof overlapping pentadecapeptides spanning the sequence of themajor protein of CMV-pp65 for sensitization and generation ofCMV-specific T cells. Such pentadecapeptides previously havebeen used to identify immunogenic viral epitopes recognizedby T cells in the blood of healthy individuals and allograftrecipients.^15,16 In this report, we demonstrate that this methodologyalso permits the rapid generation of polyclonal CMV-specificT-cell lines that recognize immunodominant epitopes of CMV-pp65presented by different HLA class I and class II alleles andcan lyse CMV-infected targets. We further demonstrate that suchcytotoxic T-cell lines can be regularly generated from CMV-seropositiveindividuals with uncommon HLA alleles for which immunogenicepitopes are not already identified. T cells could thereforepotentially be generated from donors of any HLA type capableof presenting pp65 peptides.

   Materials and methods

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Abstract
Introduction
Materials and methods
Results
Discussion
References

Donors
Blood samples were obtained from 12 consenting CMV-seropositivehealthy donors according to protocols approved by our institutionalreview board of Memorial Sloan-Kettering Cancer Center (NewYork, NY). Of these donors, 5 expressed HLA-A*0201, 2 coexpressedHLA-A*2402, and 7 expressed other HLA alleles as noted in specificexperiments. HLA typing of the blood donors and cell lines usedin the experiments were performed by the HistocompatibilityTesting Laboratory at Memorial Sloan Kettering Cancer Center.Analysis of specific nucleotide sequences was done using standardhigh-resolution typing techniques.
Generation, culture, and peptide pulsing of antigen-presenting cells
DCs were generated from PBMCs obtained after Ficoll-Hypaquecentrifugation. CD14⁺ monocytes were enriched by negative selectionusing the monocyte isolation kit and Miltenyi microbead columns(Miltenyi Biotec, Auburn, CA). CD14⁺ monocytes were resuspendedat a concentration of 1 x 10⁶/mL in serum-free medium, supplementedwith granulocyte-macrophage colony-stimulating factor (GM-CSF)(1500 IU/mL; Immunex, Seattle, WA) and interleukin-4 (1200 IU/mL;Biosource, Camarillo, CA). On days 2, 4, and 6 of culture, freshcytokines were added. Fresh medium was added depending on cellgrowth. On day 7 of culture, 10 ng/mL tumor necrosis factor- ${alpha}$ (TNF- ${alpha}$ ) (Biosource, Camarillo, CA) was added for the maturationof the dendritic cells.
Autologous EBV-BLCLs and a panel of allogeneic EBV-BLCLs, usedto identify restricting HLA alleles, were generated as previouslydescribed.^17,18 K562 cells transfected to express the HLA-A*0201allele (K562/A*0201 transfectants) also were evaluated as APCs.¹⁹Cells were fed RPMI 1640, 10% fetal calf serum (FCS), L-glutamine,penicillin, and streptomycin 3 times a week and expanded accordingto the growth and cell number.
Peptide pulsing of APCs was performed as previously described.¹⁷In brief, 2.5 µg of each nonamer peptide (Research Genetics,Huntsville, AL) and single pentadecapeptide or a total of 24µg pooled pentadecapeptides (2 µg/pentadecapeptideof subpools and 0.18 µg/pentadecapeptide of complete pool)was added to 1 x 10⁶ APCs/mL in Iscove modified Dulbecco medium(IMDM) for 3 hours at room temperature prior to irradiation.Each of the 138 pentadecapeptides was synthesized by Naturaland Medical Sciences Institute (NMI) (Tuebingen, Germany) tospecifications of validated sequence, purity, sterility, andabsence of endotoxin.
Generation of CMV-specific T-cell lines
T-cell lines were generated as previously described.^17,18 Inbrief, CD3⁺ T-cell–enriched cell fractions were isolatedby Ficoll-Hypaque gradient separation of PBMCs, followed bydepletion of CD20⁺ B cells, CD14⁺ monocytes, and CD56⁺ naturalkiller (NK) cells with monoclonal antibody–coated immunomagneticbeads (Miltenyi Biotec). Thereafter, aliquots of enriched Tcells, at a concentration of 1 x 10⁶ cells/mL, were stimulatedwith 0.5 x 10⁵/mL 6000 rad irradiated DCs and pulsed with singlepentadecapeptide or with peptide pools in IMDM supplementedwith 10% heat-inactivated human AB serum (Gemini, Calabasas,CA) for 7 days in 25 cm² flasks. T cells were restimulated weeklyat an effector-stimulator ratio of 20:1 and recultured at aconcentration of 1 x 10⁶/mL; 5 to 10 IU/mL of interleukin-2(Collaborative Biomedical Products, Bedford, MA) was added atday 10 to the cultures and 2 to 3 times weekly thereafter.
The principle of the protein-spanning pools of overlapping pentadecapeptides
To generate polyclonal CMV-specific T-cell lines, we used poolsof pentadecapeptides with 11–amino acid overlaps spanningthe 561 amino acid sequence of pp65 protein. (Figure 1A). Atotal of 138 pentadecapeptides, spanning the pp65 protein, werepurchased from NMI.

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Figure 1.. The pp65 protein and the overlapping pentadecapeptides. (A) The sequence of the pp65 protein, consisting of 561 amino acids and the principle of 11 amino acids overlapping pentadecapeptides are illustrated. The sequence of the first 3 pentadecapeptides with 11aa overlap each is highlighted. A total of 138 pentadecapeptides are required for overspanning the entire pp65 protein. As a result of the 11aa overlap, HLA-A*0201-restricted peptide NLVPMVATV (aa 495-503) is contained within the pentadecapeptides 123 (AGILA RNLVP MVATV) and 124 (ARNLV PMVAT VQGQN). The HLA-A*2402-restricted peptide QYDPVAALF (aa 341-350) is represented by the pentadecapeptides 85 (VELRQ YDPVA ALFFF) and 86 (QYDPV AALFF FDIDL). (B) The principle of pp65-derived peptide pools of overlapping pentadecapeptides. A total of 12 pentadecapeptides are contained within one peptide-pool (eg, pentadecapeptides 3, 15, 27, 39, 51, 63, 75, 87, 99, 111, 123, and 135 forming peptide pool 3) requiring a total of 24 pools overspanning the pp65 protein. Pentadecapeptides 123 and 124, containing the A*0201-restricted nonamer sequence NLVP MVATV, are found in peptide pools 3, 4, and 23.

To identify the sensitizing pentadecapeptide in the completepool, an analytic grid composed of 24 subpools of CMV pentadecapeptideswas constructed. (Figure 1B). Each subpool contains 12 pentadecapeptides(eg, pool 3 contains pentadecapeptides 3, 15, 27, 39, 51, 63,75, 87, 99, 111, 123, and 135; pool 15 contains pentadecapeptides25 through 36). To identify the immunogenic epitope, T cellssensitized with the complete pool were washed and aliquots restimulatedwith each of the 24 subpools. T cells accumulating interferon- ${gamma}$ (IFN- ${gamma}$ ) were quantitated by fluorescence-activated cell-sorterscanner (FACS) as described in the next paragraph. Immunogenicpeptides were identified by the responses of T cells to interceptingsubpools in the grid. For example, T cells from an HLA-A*0201⁺-seropositivedonor might be expected to respond to pentadecapeptides 123(AGILARNLVPMVATV) and 124 (ARNLVPMVATQGQN), each of which containNLVP MVATV, a known A*0201-restricted antigenic nonamer. Thesepentadecapeptides would be identified as immunogenic if theT cells responded to pools 3, 4, and 23, which share pentadecapeptides123 and 124 that contain this nonamer peptide.
Quantitation of antigen-specific T cells by intracellular IFN- ${gamma}$ –production assay
The intracellular IFN- ${gamma}$ –production assay was performedas previously described.¹⁷ T cells at a concentration of 1 x10⁶/mL were mixed with peptide-loaded or unmodified PBMCs orBLCLs at an effector-stimulator cell ratio of 5:1. Control tubescontaining effector cells, or APCs only, were incubated separatelyuntil the staining procedure. Brefeldin A (Sigma, St Louis,MO) was added to both nonstimulated and stimulated samples ata concentration of 10 µg/mL of cells. Tubes were incubatedovernight for 16 hours in a humidified 5% CO₂ incubator at 37°C.Staining and analyses were performed as previously described.¹⁷
Determination of peptide-specific CD8⁺ T cells by tetramer analyses
Major histocompatibility complex (MHC)–tetramer complexeswere generated in the MSKCC Tetramer Core Facility and usedas previously described.^17,20,21 The T cells were initiallyincubated with 25 µg/mL phycoerythrin (PE)–labeledtetrameric complex on ice for 30 minutes, washed, and then stainedwith 10 µL of monoclonal anti-CD3 allophycocyanin, 10µL of anti-CD8 peridin chlorophyll protein (PerCP), and10 µLof anti-CD62L fluorescein isothiocyanate (FITC) (BDBioscience, San Jose, CA) for 20 minutes on ice. The stainedcells were subsequently analyzed and quantitated with a FACSCaliburflow cytometer with dual lasers for 4-color capability (BD Biosciences).
Antigen-specific cytotoxic activity of CMV-specific T-cell lines
T-cell lines generated by sensitization with the entire pp65peptide pool, selected peptide pools, or single pentadecapeptidealso were assessed for their capacity to lyse peptide-pulsedor CMV-infected target cells using a standard ⁵¹Cr cytotoxicityassay as previously described.^17,18 Target cells included BLCLs,K562/A*0201 transfectants, HLA-A*0201⁺ MRC-5 fibroblasts, ordonor-derived skin fibroblasts, which were either pulsed withthe relevant peptide or peptide pools or infected with CMV viralsupernatant derived from the AD-169 strain. Targets either uninfectedor pulsed with irrelevant peptides were included as controls.
Virus and fibroblast cell lines
MRC-5 fibroblasts (CCL-171; American Type Culture Collection,Manassas, VA) and fibroblasts from donor-derived skin biopsieswere propagated in modified minimum essential media- ${alpha}$ (MEM- ${alpha}$ )supplemented with nonessential amino acids (NEAA), 10% FCS,and antibiotics. AD-169 CMV strain (VR-538; American Type CultureCollection) was propagated in MRC-5 fibroblasts, and infectedcultures were harvested when a cytopathic effect was evident.Cells were spun at 400g (1500 rpm) for 10 minutes, and aliquotsof supernatant were stocked at –80°C until used. Infectivityof viral supernatant was measured by standard CMV antigen testsof infected fibroblasts.

   Results

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Abstract
Introduction
Materials and methods
Results
Discussion
References

Pentadecapeptide-loaded autologous APCs can induce CMV-pp65 epitope-specific T-cell responses
We sensitized T cells from HLA-A*0201⁺-seropositive donors withDCs pulsed with pentadecapeptide 123, containing the known immunogenicHLA-A*0201-binding epitope sequence NLVPMVATV. After 2 weeks,we analyzed the percentage of NLVPMVATV-specific T cells byMHC tetramer analyses and by intracellular IFN- ${gamma}$ production inresponse to 2°C stimulation with NLVPMVATV peptide or pentadecapeptidescontaining or not containing this specific amino acid sequence.For restimulations, we initially used HLA-A*0201-transfectedK562 cells as APCs. In a representative experiment illustratedin Figure 2, 38% of CD8⁺ T cells were tetramer positive. Inaddition, 36% and 32% of the CD8⁺ T cells produced intracellularIFN- ${gamma}$ in response to restimulation with K562/A*0201 cells pulsedwith NLVPMVATV peptide or pentadecapeptide 123, respectively.In contrast, nonpulsed K562/A*0201 cells or cells pulsed withpentadecapeptide 121, not containing the amino-acid sequenceof the epitope, did not exhibit positive T-cell responses.

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Figure 2.. MHC tetramer analysis and intracellular IFN- ${gamma}$ analyses of pp65-derived CMV-specific T cells. CMV-specific T-cell lines of HLA-A*0201⁺ individuals were generated by stimulation of purified CD3⁺ cells with DCs pulsed with pentadecapeptide 123, containing the NLVPMVATV sequence. (A) Staining with HLA-A*0201–restricted MHC tetramer complexed with NLVPMVATV peptide. (B) Intracellular IFN- ${gamma}$ production after overnight stimulation with K562/A*0201 pulsed with NLVPMVATV peptide or the pentadecapeptides 123 or 121. The percentages of CD8⁺ CD69⁺ IFN- ${gamma}$ ⁺ cells or CD8⁺ tetramer⁺ cells are shown in the right upper quadrant.

Peptide pools of pentadecapeptides permit the generation of CMV epitope-specific T-cell lines
We tested whether pools containing up to 12 pentadecapeptides,which included 1 pentadecapeptide containing a known immunogenicnonamer, could also be used to generate CMV-specific T cellsand whether the responses to the pool would be comparable toresponses to the single pentadecapeptide containing the immunogenicnonamer.
Three T-cell lines were generated from HLA-A*0201⁺ individualsusing DCs pulsed with pentadecapeptide 123, peptide pool 23containing pentadecapeptide 123, or peptide pool 1, which servedas negative control. After 2 restimulations, aliquots of T cellsfrom each line were tested. As seen in Figure 3A, 50% of CD8⁺T cells sensitized with pentadecapeptide 123 and 80% of CD8⁺T cells sensitized with peptide pool 23 bound NLVPMVATV-HLA-A*0201tetramers. T cells sensitized with peptide pool 1 did not havetetramer-positive cells. Intracellular IFN- ${gamma}$ production in responseto NLVPMVATV nonamer-pulsed K562/A*0201 target cells was detectedin 36% and 53% of the CD8⁺ T cells sensitized with pentadecapeptide123 or peptide pool 23, respectively. In contrast, no IFN- ${gamma}$ wasnoted in T cells sensitized with peptide pool 1 (Figure 3B).Furthermore, as demonstrated in Figure 3C, T cells generatedby sensitization with pentadecapeptide 123 or with peptide pool23 containing the epitope effectively lysed peptide-pulsed K562/A*0201cells and CMV-infected MRC-5 fibroblasts. In contrast, nonpulsedor noninfected controls were not lysed. T cells sensitized withpeptide pool 1 did not induce lysis of either the infected orthe peptide-pulsed target cells, indicating the absence of CMVpeptides immunogenic for this individual in this pool.

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Figure 3.. Comparative MHC tetramer staining, intracellular IFN- ${gamma}$ , and cytotoxicity analyses of CMV-specific T cells after sensitization with pentadecapeptides or peptide pools of pentadecapeptides. T lymphocytes of HLA-A*0201⁺ individuals were sensitized with pentadecapeptide 123 or peptide-pools 23 or 1. (A) T cells were analyzed for their capacity to bind MHC tetramer complexed with NLVPMVATV peptide. (B) Intracellular IFN- ${gamma}$ production by T lymphocytes was assessed in response to peptide-pulsed K562/A*0201 cells. 50% of the CD8⁺ cells of T lymphocytes sensitized with pentadecapeptide 123 bound MHC tetramer and 36% produced intracellular IFN- ${gamma}$ . 80% of the CD8⁺ cells of the T-cell line sensitized with the peptide pool 23 stained with the tetramer and 53% produced IFN- ${gamma}$ . T cells sensitized with pool 1 failed to stain with the MHC tetramer or to produce intracellular IFN- ${gamma}$ . Irrelevant MHC tetramers and target cells pulsed with irrelevant peptides did not produce results above background (data not shown). (C) T lymphocytes sensitized with either pentadecapeptide 123 (CD3 + penta 123), peptide pool 23 (CD3 + pool 23), or pool 1 (CD3 + pool 1) were analyzed for their capacity to induce lysis of peptide-pulsed K561/A*0201 cells or CMV-infected MRC-5 fibroblasts. Target cells were plated in triplicates. Results represent percentage of lysis ± standard deviation.

Sensitization with overlapping peptides spanning the pp65 protein selectively induces HLA-restricted T-cell lines specific for immunogenic epitopes of CMV-pp65
We subsequently sensitized T cells from 12 CMV-seropositiveindividuals with autologous DCs pulsed with a pool containingall 138 pentadecapeptides overspanning the entire pp65 protein.The T cells were restimulated on day 7 and 14 of culture. Onday 18, these T cells were washed and restimulated with PBMCspulsed with 1 of each of the 24 pentadecapeptide pools or thecomplete pool. In Table 1, we summarize these results. As canbe seen, each donor had low but detectable frequencies of IFN- ${gamma}$ ⁺T cells at initiation of culture (0.15%-0.4%). By day 18, theproportion and absolute number of CMV-pp65–specific IFN- ${gamma}$ ⁺T cells had increased 60- to 110-fold. We subsequently evaluatedeach of these cultures for their responses to the analytic gridof pentadecapeptide subpools, identified the specific pentadecapeptideeliciting responses, and thereafter defined the immunogenicepitopes and their presenting HLA alleles. A representativeexperiment is shown in Figure 4A. When CD3⁺ T cells from thisdonor were analyzed, only pools 3, 4, 6, 7, 18, 23, and thecomplete pool stimulated T cells to produce IFN- ${gamma}$ productionabove background. The IFN- ${gamma}$ ⁺ cells also were uniformly CD69⁺.The majority of pentadecapeptide pools (pools 1, 2, 5, 8-17,19-22, 24) did not induce any T-cell response. Pools 3, 4, and23, which contain the known HLA-A*0201-binding epitope NLVPMVATV,induced intracellular IFN- ${gamma}$ production in 22% to 39% of the CD3⁺T cells. These T cells were CD8⁺. In subsequent analyses ofresponses to each of the single pentadecapeptides (121-132)contained within peptide pool 23, pentadecapeptides 123 and124, each of which contains the NLVPMVATV epitope, induced 37%and 23% IFN- ${gamma}$ ⁺ CD8⁺ cells, respectively (Figure 4B). Pentadecapeptide122, containing 5 amino acids of the nonamer, induced 7% IFN- ${gamma}$ ⁺CD8⁺ T cells, but the remaining pentadecapeptides of this pooldid not induce IFN- ${gamma}$ production above background. A similar patternof response to subpools 3, 4, and 23 and to pentadecapeptides123 and 124 was elicited from 5 HLA-A0201⁺ donors (Table 1).

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Table 1.. T-cell lines from 12 donors showing donor HLA type, yield of pp65 peptide-specific IFN ${gamma}$ ⁺ T cells, the pentadecapeptides eliciting responses, specific epitopes, and restricting HLA alleles

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Figure 4.. Analyses of CMV-specific T-cell line of an HLA-A*0201⁺ healthy seropositive donor after sensitization with the complete pool of pentadecapeptides overspanning the entire pp65 protein. (A) Capacity of T cells to produce intracellular IFN- ${gamma}$ in response to PBMCs pulsed with 1 of each of the 24 pentadecapeptide pools was analyzed. Percentages of CD8⁺ CD69⁺ IFN- ${gamma}$ ⁺ cells are shown in the right upper quadrant. Nonpulsed PBMCs and the majority of pentadecapeptide pools (pool 1, 2, 5, 9-17, 19-22, 24) did not induce intracellular IFN- ${gamma}$ production above background. In contrast, pools 3, 4, and 23, containing the known HLA-A*0201 binding epitope NLVPMVATV, induced intracellular IFN- ${gamma}$ production of 22% to 39% of CD8⁺ cells. In addition, pools 6, 7, and 18 induced intracellular IFN- ${gamma}$ production in 5% to 7.5% of CD8⁺ cells. (B) IFN- ${gamma}$ production in response to single pentadecapeptides (121-132) of peptide-pool 23. Pentadecapeptides 123 and 124, containing the full length of the NLVPMVATV epitope, induced intracellular IFN- ${gamma}$ production in 37% and 23% of the CD8⁺ cells, respectively. Pentadecapeptide 122, containing 5 amino acids of the nonamer, induced IFN- ${gamma}$ production by 7% of CD8⁺ cells. IFN- ${gamma}$ response was negative for the remaining pentadecapeptides of this pool. (C) Intracellular IFN- ${gamma}$ production in response to single pentadecapeptides (61-72) of peptide pool 18. Pentadecapeptides 66 and 67 induced intracellular IFN- ${gamma}$ production by 5.6% and 5.1% of CD8⁺ cells, respectively. The remaining pentadecapeptides did not induce IFN- ${gamma}$ production above background.

In addition to the intense responses to pools 3, 4, and 23,5% to 7.5% IFN- ${gamma}$ ⁺ CD8⁺ cells were detected in T cells from thedonor depicted in Figure 4A when restimulated with PBMCs pulsedwith pools 6, 7, and 18. From the analytical grid illustratedin Figure 1B, it was noted that pentadecapeptides 66 and 67are shared by these pools. When these T cells were analyzedafter secondary stimulation with individual pentadecapeptides61 through 72 (pool 18), 5.6% and 5.1% of CD8⁺ T cells producedIFN- ${gamma}$ in response to pentadecapeptide 66 and 67, respectively.The remaining pentadecapeptides of pool 18 did not induce IFN- ${gamma}$ response above background (Figure 4C). EBV-BLCL sharing singleHLA alleles with this donor (HLA-type A*0201, A*0301, B*4001,B*1501) were pulsed with pentadecapeptide 67, and T-cell responseswere evaluated that identified HLA-B*4001 as the presentingallele. The pattern of response further implicates the peptideHERNG FTVL, which is shared by pentadecapeptides 66 and 67 andcan be presented by HLA-B*4001 as the sensitizing antigen asfurther illustrated in Figure 6D.

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Figure 6.. Determination of sequence and HLA restriction of a pp65-derived epitope in a seropositive individual with uncommon HLA type after sensitization of T cells with the complete pool. T cells of an individual with the HLA-type A*6801, A*6601 and B*4002, B*5301 were generated as described. (A) Intracellular IFN- ${gamma}$ production in response to PBMCs pulsed with pools 6, 7, 18 and complete pool was significant. Pools 1 and 2, representative for all other pentadecapeptide pools, were negative for intracellular IFN- ${gamma}$ production. (B) Only pentadecapeptides 66 and 67 of pool 18 stimulated T cells effectively. IFN- ${gamma}$ response of neighboring pentadecapeptides 65 and 68, as well as all other pentadepeptides contained within the pool 18 (not shown), was negative. (C) Based on the overlapping principle, the amino acid sequence RPHER NGFTVL, represented within pentadecapeptide 66 and 67, likely contains the candidate nonameric peptide being recognized by the T cells. Three candidate nonamers were synthesized and tested. Only the peptide HERNG FTVL induced a significant T-cell response. (D) The HLA restriction of this nonamer was tested by pulsing BLCLs, each expressing one of the individual's HLA allele only. BLCLs encoding the HLA-B*4002 allele were effectively lysed after pulsing with the HERNG FTVL peptide, whereas BLCLs expressing other alleles, pulsed with the peptide, did not induce cytotoxic T-cell responses. T cells of an individual with HLA-type A*0201, A*0301 and B*4001, B*1501 demonstrated a response to HLA-A*0201-restricted NLVPMVATV peptide and a response to the pentadecapeptides 66 and 67 of the pool 18. (D) B*4001-expressing BLCLs of this individual pulsed with HERNG FTVL peptide also were effectively lysed by T cells of the B*4002-expressing individual above.

We also generated T cells from 2 seropositive HLA-A*0201- andHLA-A*2402-expressing individuals so as to determine whetherthe use of the complete pool of pentadecapeptides would induceT cells recognizing both the epitope presented by HLA-A*2402QYDPVAALF²² as well as the NLVPMVATV epitope presented by HLA-A*0201.In these experiments, separate T-cell lines from the same donoralso were generated simultaneously by stimulation with DCs pulsedwith either peptide pool 23, which includes peptides with theepitope sequence NLVPMVATV, or peptide pool 20, which includespeptides containing the sequence QYDPVAALF. After 3 weekly stimulationsintracellular IFN- ${gamma}$ production and tetramer binding by theseT cells were tested. Results were similar for both donors. Asshown in Figure 5A, 25%, 31%, and 1% of CD8⁺ T cells from oneof these donors sensitized with the complete pool, pool 23 andpool 20, respectively, bound to the NLVPMVATV-HLA-A*0201 tetramers.Of the CD8⁺ T cells sensitized with pool 23, 34% produced IFN- ${gamma}$ after secondary stimulation with PBMCs loaded with NLVPMVATVpeptide. PBMCs loaded with the QYDPVAALF peptide did not induceany response (0.3%). Conversely, 34% of the CD8⁺ T cells sensitizedwith pool 20 produced IFN- ${gamma}$ in response to PBMCs loaded withpeptide QYDPVAALF but had no response to NLVPMVATV peptide (0.4%).In contrast, of the T cells sensitized with the complete pool,22% produced IFN- ${gamma}$ in response to PBMCs loaded with the completepool, 33% in response to PBMCs loaded with NVLPMVATV, and 30%to PBMCs loaded with QYDPVAALF (Figure 5B-D).

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Figure 5.. Analyses of T cells of an HLA-A*0201⁺- and A*2402⁺-expressing seropositive donor after sensitization with peptide pools of pentadecapeptides or with the complete pool. T-cell cultures were generated simultaneously by stimulation with either peptide pool 23 (CD3 + pool 23), containing HLA-A*0201–restricted peptide NLVPMVATV, or with peptide pool 20 (CD3 + pool 20), containing HLA-A*2402–restricted peptide QYDPVAALF. A third T-cell line was generated with DCs pulsed with the complete pool (CD3 + all pools). (A) Staining with A*0201-restricted MHC tetramers, complexed with NLVPMVATV peptide. (B-D) Intracellular IFN- ${gamma}$ responses to A*0201-restricted NLVPMVATV, A*2402-restricted QYDPVAALF, or to the complete pool. (E) T cells sensitized with the complete pool effectively lysed targets pulsed with either NLVPMVATV or QYDPVAALF peptide. T cells sensitized with peptide pool 23 or peptide pool 20 selectively lysed the targets after pulsing with the corresponding A*0201 or A*2402-restricted peptide. All 3 T-cell lines recognized autologous CMV-infected fibroblasts but failed to lyse nonpulsed, noninfected target cells. All target cells were plated in triplicates. Results represent percentage of lysis ± standard deviation.

As illustrated in Figure 5E, T cells from pool 23 and pool 20lines selectively lysed only the targets pulsed with the appropriateA*0201- or A*2402-restricted peptide, respectively. In contrast,T cells sensitized with the complete pool effectively lysedautologous targets pulsed with either NLVPMVATV or QYDPVAALFpeptide. In addition, all 3 T-cell lines lysed CMV-infectedautologous fibroblasts, whereas nonpulsed and noninfected targetswere not recognized. Thus, T cells specific for immunogenicepitopes presented by both HLA-A*0201 and HLA-A*2402 could begenerated within a single culture by stimulating donor T cellswith the complete pool.
Peptide pools overspanning the pp65 protein permit generation of CMV-specific T-cell lines in individuals with uncommon HLA alleles and are useful for determination of sequence and HLA restriction of previously undescribed class I epitopes
T-cell lines from an individual with HLA-type A*6801/A*6601and B*4002/B*5301 were generated by pulsing DCs with the completepool. After 3 weeks of culture, CD8⁺ T cells producing intracellularIFN- ${gamma}$ were quantitated after restimulation with PBMCs pulsedwith individual pentadecapeptides pools 1 to 24 or with thecomplete pool. Only peptide pools 6, 7, 18, and the completepool induced significant frequencies of IFN- ${gamma}$ –producingT cells. T cells sensitized with the other pools were negativefor IFN- ${gamma}$ production (Figure 6A). When the single pentadecapeptidesfrom pool 18 were tested for their capacity to induce intracellularIFN- ${gamma}$ production, only pentadecapeptides 66 and 67, which alsoare contained in pools 6 and 7, induced IFN- ${gamma}$ ⁺ CD8⁺ T cells.The neighboring pentadecapeptides 65 and 68, as well as allother pentadecapeptides contained within pool 18 (not shown),did not induce IFN- ${gamma}$ ⁺ T cells (Figure 6B).
The amino acid sequence RPHER NGFTVL is represented within bothpentadecapeptides 66 and 67. We therefore hypothesized thatthe nonameric peptide being recognized by the T cells of thisindividual was contained within this sequence. Three candidatenonamers were generated, and their capacity to induce intracellularIFN- ${gamma}$ was assessed. Only the nonameric peptide HERNG FTVL induceda significant response (Figure 6C). The HLA allele presentingthis nonamer was analyzed by loading the peptide on a panelof EBV-BLCLs, each expressing only one of the individual's HLAalleles. As illustrated in Figure 6D, BLCLs encoding the HLA-B*4002allele were effectively lysed after pulsing with the HERNG FTVLpeptide, whereas peptide-pulsed BLCLs expressing other allelesdid not induce any cytotoxic T-cell responses. Strikingly, theseT cells also effectively lysed HERNG FTVL peptide-pulsed BLCLsfrom a donor with HLA type A*0201/A*0301 and B*4001/B*1501,strongly suggesting that the peptide can be recognized whenpresented by either the HLA-B*4002 or the HLA-B*4001 micro variantallele (see "Note added in proof").
HLA class II restriction pattern and peptide sequence of an epitope inducing CMVpp65-specific CD4⁺ T cells determined using the complete pool
T cells of an individual with the HLA-type A*26JV, A*29BD, andB*44CU, B*08DKG, DRB1*-1301, and DRB1*-1501 were generated bypulsing autologous DCs with the complete pool. After 3 weeksof culture these cells were tested for their capacity to produceIFN- ${gamma}$ in response to secondary stimulation with PBMCs pulsedwith individual pools 1 to 24 and to the complete pool. As shownin Figure 7A there was a predominant CD4⁺ T-cell response topools 8, 9, 23 and to the complete pool. There was some CD8⁺T-cell response noted to the same pools. All the other poolsdid not induce IFN- ${gamma}$ production. When the individual pentadecapeptidesin pool 23 were tested, only pentadecapeptides 128 and 129 induceda significant response. Based on the overlapping principle,the amino acid sequence F FWDAN DIYRI represented within pentadecapeptide128 and 129, likely contains the candidate peptide being recognizedby the T cells of this individual (Figure 7B). We analyzed theHLA restriction of this pentadecapeptide by pulsing EBV-BLCLseach expressing one of the individual's HLA allele only. Asillustrated in Figure 7C, only BLCL encoding the HLA-DRB1*-1301allele were lysed after pulsing with the KYQEF FWDAN DIRYI peptideor after infection with CMV virus, whereas the EBV-BLCLs expressingthe other alleles pulsed with the same peptide did not induceany cytotoxic T-cell responses.

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Figure 7.. HLA class II restriction pattern and peptide sequence of a pp65-derived epitope in a seropositive individual with uncommon HLA type after generation of CMV-specific T cells with complete pool. T cells of an individual with HLA-type A*26JV, A*29BD and B*44CU, B*O8DKG, DRB1*1301, DRB1*1501 were generated as previously described. (A) PBMCs pulsed with pentadecapeptide pools 8, 9, 23 and complete pool induced significant intracellular IFN- ${gamma}$ production of CD4⁺ cells in this individual. All other pentadecapeptide pools failed to induce a response. (B) Only pentadecapeptides 128 and 129, encoded in pool 23, stimulated T cells effectively. The neighboring pentadecapeptide pools 127 and 130, as well as all other pentadepeptides contained within pool 23 (not shown), did not induce intracellular IFN- ${gamma}$ production. Based on the overlapping principle, the amino acid sequence F FWDAN DIYRI represented within pentadecapeptide 128 and 129 likely contains the candidate peptide being recognized by the T cells of this individual. (C) HLA restriction of this pentadecapeptide was analyzed by pulsing EBV-BLCLs, each expressing one of the individual's HLA allele only. BLCLs encoding the HLA-DRB1*1301 allele were lysed after pulsing with the KYQEF FWDAN DIYRI peptide or after infection with CMV virus, whereas the EBV-BLCLs expressing the other alleles pulsed with the same peptide did not induce any cytotoxic T-cell responses.

   Discussion

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Abstract
Introduction
Materials and methods
Results
Discussion
References

In the last 5 to 10 years, results from several phase 1 andsmall phase 2 trials have provided evidence that adoptive transferof virus-specific T cells can prevent and effectively treatchemotherapy refractory monoclonal EBV lymphomas and preventthe development of clinically significant CMV infections.^8,9,11,23However, the techniques used to sensitize virus-specific T cellsin vitro have entailed culture of the T cells with virus-infectedautologous cells, such as CMV-virus–infected skin fibroblasts,⁹EBV-transformed B cells,¹⁰ or DCs transduced with retroviralor adenoviral vectors to express specific viral proteins orimmunogenic peptides.²⁴ Such approaches have proved to be bothtime- and labor-intensive and difficult to implement or sustain.Alternative sensitization strategies using DCs pulsed with lysatesof CMV-infected cells have shown promise, but such lysates aredifficult to standardize and have raised regulatory concernsthat they might contain and transmit live virus.¹²
Recently, Einsele et al¹³ have initiated trials of T cells sensitizedwith DCs loaded with a limited number of immunogenic nonapeptidesof CMV-pp65 selected on the basis of computerized estimatesof their capacity to bind to and be presented by common HLAclass I allele such as HLA-A*0201 inherited by both the donorand transplant recipient. However, a proportion of patients,such as individuals co-inheriting HLA-B*0701 and HLA-A*0201,may preferentially respond to epitope presented by an allelesuch as HLA-B*0701 and not respond to an immunogenic peptidespresented by HLA-A0201.²⁵ Also, current strategies for selectingpotentially immunogenic epitopes based on predicted bindingaffinities^26,27 are useful for only a limited number of HLAalleles. Furthermore, as demonstrated by Elkington et al,²⁸even for those peptides of CMV-pp65 predicted to bind to commonHLA alleles, only 40% elicited cytokine-producing T cells detectedby enzyme-linked immunospot (ELISPOT) assay, and only a subsetof the T-cell lines generated from HLA-A*0201⁺-seropositivedonors in response to these peptides actually lysed CMV-infectedcells.
To address several of these limitations, we have explored theuse of pools of overlapping pentadecapeptides spanning the entiresequence of CMV-pp65 for the generation of T cells for adoptivecell therapy. These peptides are synthetic, sterile, and canbe manufactured under good manufacturing practice (GMP) conditions.In prior studies, several investigators have used pools of overlapping11-20 mers to measure antigen-specific T-cell responses in theblood and to map viral epitopes recognized by T cells in vivoor in vitro following sensitization with virus-infected autologousfibroblasts or antigen-presenting dendritic cells and othercell lines transduced to express a specific viral protein.^29,30In particular, Kern et al¹⁶ analyzed frequencies of CMV-specificCD8⁺ T cells in CMV-seropositive healthy individuals by quantitatingT cells producing IFN- ${gamma}$ in isolated PBMCs stimulated for 6 hourswith overlapping pentadecapeptides spanning the entire HCMV-pp65protein. In their studies of randomly selected CMV-seropositivedonors, 83% had CD8⁺, and 63% had detectable CD4⁺ T-cell responses.IFN- ${gamma}$ ⁺ cells detected ranged from 0.03% to 2.7%. In a subsetof these donors, T cells responding to the complete pool weresubsequently stimulated with a set of subpools of the pentadecapeptidesarranged in the matrix design described in Figure 1B. By analysisof responses to intercepting subpools, specific pentadecapeptidescontaining immunogenic epitopes could be identified and theepitopes subsequently defined by testing responses to individualnonamer sequences contained in that pentadecapeptide.
In the present study, we tested whether repeated sensitizationof T cells from seropositive donors over 14 to 28 days in vitrowith autologous DCs loaded with the complete pool of overlappingpentadecapeptides spanning the sequence of CMV-pp65 could inducethe generation of large populations of CMV-pp65–reactiveCD8⁺ and CD4⁺ T cells of sufficient specificity and activityagainst CMV-infected targets to be considered for adoptive celltherapy.
T-cell lines containing high frequencies of CMV-pp65–reactiveIFN- ${gamma}$ ⁺ T cells were generated in response to the complete poolof pentadecapeptides from each of the 12 CMV-seropositive donorstested, including individuals inheriting uncommon HLA alleles.Initially, our principal concern was the possibility that Tcells, after extended culture in vitro, would react to manypeptides in the pool, including peptides not normally presentedby CMV-infected cells or peptides not specific to CMV, whichmight induce nonspecific background in vitro or unwanted tissuecross-reactions in vivo. In each case, however, significantpopulations of IFN- ${gamma}$ ⁺ CD3⁺ T cells were generated in responseto only a limited number of pentadecapeptides in the completepool, which could be easily identified by analysis of responsesto the grid of overlapping pentadecapeptide subpools (Figure 4).Responses to other pentadecapeptide subpools or individualpentadecapeptides were similar to background responses. Furtheranalysis of responses to individual peptides contained in thepentadecapeptide subpools demonstrated that the CD8⁺ T cellsgenerated from each of the 12 patients studied were respondingto, at most, 1 to 2 epitopes, each presented by a differentclass I HLA allele. Similarly, CD4⁺ IFN- ${gamma}$ ⁺ T-cell responses thusfar studied have been principally directed against one pentadecapeptidepresented by a single HLA class II allele. These studies thussuggest that T-cell lines generated in response to the completepool of pentadecapeptides spanning the sequence of CMVpp65 selectivelyreact against a very limited number of immunodominant epitopes.The limited spectrum of reactivity exhibited by these lineslikely reflects the repertoire already selected in the CMV-seropositivedonor rather than an artifact of in vitro selection, since studiesby Kern et al¹⁶ and others who have used overlapping peptidesto test for CMV-specific T cells in the blood of such donorsalso have documented immediate CD8⁺ and CD4⁺ IFN- ${gamma}$ ⁺ T-cell responsesat frequencies of less than 1%, specific for at most 2 to 4class I binding and 1 to 2 class II binding peptide epitopesin any given donor.
The specific epitopes presented by a given HLA allele that elicita response appear to be also highly selected. For example, whenT cells from 5 donors expressing the common HLA-A*0201 allelewere sensitized with the complete pool, the T-cell lines fromeach donor responded to pentadecapeptides 123 and 124 containingthe immunogenic peptide NLVPMVATV, known to bind to and be presentedby this allele (Figure 4A-B). These T cells specifically lysedboth HLA-A*0201⁺ targets loaded with the NLVPMATV peptide aswell as CMV-infected HLA-A*0201⁺ cell targets (Figure 5E). Noneof these T-cell lines responded to other pentadecapeptides containingpeptides predicted to bind to HLA-A*0201 and reported to elicitT-cell responses detectable by ELISPOT analyses when used individuallyto sensitize T cells in vitro such as _aa14-22VLGPISGHV (pentadecapeptide3, pool 13), _aa522-530RIFAELEGV (pentadecapeptide 130, pool10), or _aa20-128MLNIPSINV (pentadecapeptide 30, pool 15).²⁸It is possible that pentadecapeptides containing these potentiallyimmunogenic HLA-A*0201-binding sequences cannot be adequatelyor appropriately digested by the ectopeptidases in the cellcultures, which have been shown to trim off amino acid sequencesfrom the pentadecapeptides not fitting in the groove of thepresenting HLA allele.^31,32 Experiments to address this possibilityare in progress. However, it also is possible that these othersequences of CMVpp65 are not efficiently processed and presentedby CMV-infected cells and therefore do not elicit a major cytotoxicT-cell response. In this regard, it is of interest that of 6HLA-A0201-binding nonamer epitopes of CMVpp65 shown by Elkingtonet al²⁸ to induce significant frequencies of IFN- ${gamma}$ ⁺ T cells inELISPOT assays, only the _aa495-503NLVPMVATV peptide (containedin pentadecapeptides 123 and 124) and the 5 amino acid–overlappingsequence _aa491-499ILARNLVPM (contained in pentadecapeptide 123)elicited T cells capable of lysing CMV-infected targets.
We also analyzed the specificity and function of specific pentadecapeptidespresented by other HLA class I alleles, including HLA-A*2402,HLA-B*4001, HLA-B*4002, HLA-B*4201, and HLA-B*0701. In eachinstance, the pentadecapeptide-eliciting responses could berapidly ascertained by analysis of responses to the grid ofpentadecapeptide subpools. In each instance, we also were ableto identify a specific nonamer contained in the pentadecapeptideas the sensitizing epitope, including an unreported epitopepresented by HLA-B*4001 and HLA-B*4002 as very recently describedby Kondo et al³³ (see "Note added in proof"). Importantly, theseT cells only lysed targets loaded with the specific pentadecapeptide(or nonamer therein) that also expressed the restricting HLAallele. Furthermore, each of these T-cell lines also specificallylysed CMV-infected autologous fibroblasts. Thus, these studiesfurther support the possibility that T-cell lines generatedby this approach select for T cells reactive against epitopesthat can be processed and presented by CMV-infected autologoustargets. The potential for selection of functional T cells responsiveto immunodominant epitopes from seropositive donors of diverseHLA genotypes provided by this approach may thus improve theprobabilities of generating clinically active CMV-specific CD8⁺T cells for adoptive immunotherapy.
Sensitization of T cells with DCs loaded with the complete poolof pentadecapeptides also stimulates expansion of HLA classII–restricted CD4⁺ T cells. Indeed, while the APCs andculture conditions used have focused the expansion of CMV-pp65specific CD8⁺ T cells, significant populations of specific CD4⁺T cells also are regularly detected. In some donors, such asthe donor described in Figure 7, the peptide-specific IFN- ${gamma}$ ⁺T cells generated have been predominantly CD4⁺ T cells. Likethe peptide-specific CD8⁺ T cells, these CD4⁺ T cells have consistentlyexhibited cytotoxic activity against infected targets as wellas peptide-loaded cells expressing the restricting HLA classII allele. However, since most of the CMV-infected cells encounteredin vivo are likely not to express HLA class II, the principalcontribution of these CD4⁺ T cells would be expected to be basedon their capacity to recruit and maintain CD8⁺ T-cell effectorsthrough their helper functions.
In conclusion, synthetic overlapping pentadecapeptides spanningthe sequence of the immunodominant protein of CMV-pp65, whenloaded on DCs, can consistently stimulate the in vitro generationof CD8⁺ and CD4⁺ T-cell lines from seropositive donors of diverseHLA genotypes. These cell lines are selectively enriched forT cells specific for a limited number of immunodominant epitopes,each presented by a single HLA class I or class II allele. TheCMV-pp65–specific T cells generated by this approach areconsistently able to lyse autologous CMV-infected targets. Thisapproach, which exposes donor T cells to the gamut of potentiallyimmunogenic peptides from CMV-pp65, thus may promote expansionof precommitted T cells recognizing epitopes that have beenpreviously presented by CMV-infected cells of the donors inthe context of class I and II alleles selected as immunodominantby the donor. Thus, from both functional and regulatory perspectives,this approach may therefore have advantages for generation ofclinically active T cells for adoptive immunotherapy.
Note added in proof. During the review process of this manuscript,the HERNGFTVL epitope and the HLA restriction of this peptideto HLA-B*4001 and HLA-B*4002 have been published by Kondo etal.³³

   Acknowledgements

We would like to thank Dr Eric Pamer and Ingrid Leiner (MSKCCTetramer Core Facility) for the generation and supply of theMHC tetramers used in these studies; Dr Ekaterina Doubrovinafor supplying EBV-transformed B-cell lines; and Dr B. Dupontfor HLA typing of donor cells and BLCLs. We thank Drs W. Herrand C. Britten (Mainz, Germany) for providing the K562/A*0201-transfectedcell line.

   Footnotes

Submitted May 7, 2003; accepted October 25, 2004.
Prepublished online as Blood First Edition Paper, October 28,2004; DOI 10.1182/blood-2003-05-1433.

Supported in part by the National Cancer Institute (grants CA59350and CA23766), The Larry H. Smead Fund, The Aubrey Fund for PediatricCancer Research, The Vincent Astor Chair Clinical Research Fund,and a Translational Research Grant from the Leukemia and LymphomaSociety (G.K.).

The publication costs of this article were defrayed in partby page charge payment. Therefore, and solely to indicate thisfact, this article is hereby marked "advertisement" in accordancewith 18 U.S.C. section 1734.

Reprints: Guenther Koehne, Rush University Medical Center, 1653 Congress Parkway, Cohn Building, Suite 622, Chicago, IL 60612; e-mail: guenther_koehne{at}rush.edu.

   References

Top
Abstract
Introduction
Materials and methods
Results
Discussion
References

Ljungman P, Engelhard D, Link H, et al. Treatment of interstitial pneumonitis due to cytomegalovirus with ganciclovir and intravenous immunoglobulin: experience of European Bone Marrow Transplant Group. Clin Infect Dis. 1992;14: 831-835.[Medline] [Order article via Infotrieve]

Einsele H, Ehninger