Astrocytoma infiltrating lymphocytes include major T cell clonal expansions confined to the CD8 subset
Gaëlle Perrin1,
Valérie Schnuriger1,
Anne-Lise Quiquerez1,
Philippe Saas1,
Christophe Pannetier4,
Nicolas de Tribolet3,
Jean-Marie Tiercy2,
Jean-Pierre Aubry5,
Pierre-Yves Dietrich1 and
Paul R. Walker1,3
1 Laboratory of Tumor Immunology, Division of Oncology,
2 Transplantation Immunology Unit, and
3 Department of Neurosurgery, University Hospital, 1211 Geneva 14, Switzerland
4 Unit of Molecular Biology of the Gene, INSERM Unit 277, Department of Immunology, Pasteur Institute, 75724 Paris Cedex 15, France
5 Centre d'Immunologie Pierre Fabre, 74164 Saint-Julien-en-Genevois, France
Correspondence to:
P.-Y. Dietrich
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Abstract
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Anaplastic astrocytoma and glioblastoma are frequent and malignant brain tumors that are infiltrated by T lymphocytes. Whether these cells result from non-specific inflammation following bloodbrain barrier disruption or an antigen-driven specific immune response is unknown. In this study, an in-depth characterization of TCR diversity in tumor and blood RNA biopsies was performed in a series of 16 patients with malignant astrocytoma. Whilst there was no obvious restriction of the AV and BV gene segment usage, complementarity-determining region 3 size analysis and sequencing of amplified TCR transcripts revealed multiple T cell oligoclonal expansions in all astrocytomas analyzed. Unique T cell clones were present in different adjacent areas of a given tumor, but never detected in the blood. Quantification of the number of TCR clonal transcripts per µg of tumor RNA indicated that certain T cell clonal expansions may represent at least 300 cells/106 tumor cells. Furthermore, we demonstrated that the in vivo expanded clones were almost exclusively confined to the CD8+ subset. Overall, these data suggest that spontaneous antigen-driven immune responses may be elicited against human astrocytoma despite the immunosuppressive microenvironment generated by the brain and the tumor itself. However, the ultimate failure of the immune system to control tumor growth could be the consequence of a deficient CD4 Th component of the response. This observation could have important consequences for the development of immunotherapies for astrocytoma patients.
Keywords: brain, TCR, T lymphocytes, tumor immunity
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Introduction
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Several clinical and experimental observations now support the view that the immune system may exert some control over cancer development and growth. Direct demonstration came from immunization experiments in mice in which killed tumor cells or tumor cell lysates used as vaccines were shown to induce both tumor destruction and specific protective immunity (1). Detailed analysis of the effector mechanisms involved in tumor rejection revealed an essential role for T cells (2). There is also evidence for similar T cell-mediated anti-tumor responses in man, although this is more indirect. T lymphocytes with MHC-restricted specific recognition of autologous tumor cells were generated in vitro from peripheral blood mononuclear cells (PBMC), lymph nodes or the tumor site (3). Some of these T cells were detected in vivo in significant quantities (47), occasionally associated with spontaneous tumor regression (8). Moreover, therapies designed to augment T cell anti-tumor responses are now yielding interesting results in man. In melanoma, some clinical regressions have recently been achieved with peptidic tumor antigens (9,10) or dendritic cells loaded with specific peptides or tumor lysates (11), sometimes correlated with the detection of T cell effectors (10,11). The therapeutic potential of T cells is not limited to melanoma. Patients with relapsing leukemia or lymphoma after allogeneic bone marrow transplant can be rescued by the injection of donor lymphocytes (adoptive immunotherapy) (12,13).
Arising from astrocytes, astrocytomas are the most common primary brain neoplasms that represent 3% of human tumors. They are classified according to histological criteria. Malignant forms include anaplastic astrocytoma (grade III) and glioblastoma (grade IV). Although it is clear that immune reactions can and do occur in the central nervous system (CNS) (1417), this particular localization in a long thought immune privileged site may have consequences for putative anti-tumor immune responses. Indeed, special features of the brain microenvironment (e.g. absence of MHC molecules expression on the normal brain parenchyma and exclusion of components of the immune system by the bloodbrain barrier) suggest that the rules governing immune responses in the brain should not be directly extrapolated from those observed in other tissues.
Most astrocytomas are infiltrated by T lymphocytes (18), but these cells are poorly characterized and may have a reduced proliferative potential in culture (19,20). Therefore, looking for immune responses only by standard cellular approaches may significantly underestimate the frequency of specific cells (19,21,22). Here, to better appraise the global T cell immune response in astrocytoma, we take advantage of a high-resolution RT-PCR method based on the determination of the TCR ß chain complementarity determining region (CDR) 3 length. The CDR3 region carries the principal antigenic specificity of a T lymphocyte, a conclusion further validated by recent crystallography studies (23,24). VDJ recombination and the action of the terminal deoxynucleotidyl transferase give rise to CDR3 regions of variable sequences and lengths (515 amino acids) at the VJ junction. Therefore, the analysis of CDR3 size distribution among the different BV families is a powerful approach to study TCR diversity, and to evaluate the dynamics and specificity of immune responses taking place in vivo (25,26). TCR molecular analysis can also be performed on cell populations sorted according to expression of certain phenotypic markers (27,28), greatly enhancing the possible applications of this technique.
In the present study, TCR diversity was analyzed in the whole T cell infiltrate, and compared with that of sorted CD4+ and CD8+ T cell subpopulations in order to assess their relative importance in the response. Indeed, the question of the requirement for CD4+ T cells in the generation and function of CD8+ cytotoxic T lymphocytes (CTL) is an important issue in many immune responses. For viral clearance, contrasting results can be found depending on the source of the antigen and the experimental system used (2933). In the case of chronic infections, CD4+ help seems to be particularly important for the continued maintenance of CD8+ effector functions (34). In cancer, tumor cells genetically modified to express MHC class II molecules were more immunogenic than the parental cell lines, suggesting that an optimal anti-tumor response may depend on the recruitment of CD4+ T cells (35,36). Concerning the epitopes recognized by CD4+ T cells in man, some MHC class II-restricted tumor antigens have now been characterized (3739). In certain experimental conditions, CD8+ T cells alone can nevertheless mediate partial or complete anti-tumor effects (4042). Recent data indicate that the site of immunization may determine the requirement for CD4+ cells (43), an observation that may help to reconcile some of these conflicting data. In the CNS, several experimental results support the view that an efficient CD8+ response relies on appropriate CD4+ help (1417). For example, CD4-depleted mice infected with the neurotropic JHM strain of mouse hepatitis virus showed normal CTL effector function in peripheral tissues, but failed to clear virus in the CNS (14). Investigating the role of CD4+ and CD8+ T cells in human astrocytoma could be invaluable for understanding why the immune system fails to control the development and growth of these tumors.
In the present work, a fine characterization of TCR variability was undertaken in a large series of human astrocytomas. Our data demonstrate the presence of significant T cell clonal expansions in the tumor bed, strongly suggesting an immune response to as yet undefined astrocytoma antigens. Furthermore, we provide evidence that, in vivo, oligoclonality of T cells is confined to the CD8 population.
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Methods
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Patients and samples
Peripheral blood samples and tumor biopsies were collected during surgery from 16 Caucasian patients with grade III or grade IV malignant astrocytomas. Patients (four females and 12 males) were 3585 years old, mean ± SD: 57 ± 15 years. PBMC were separated by Ficoll-Hypaque (Pharmacia, Uppsala, Sweden) density gradient centrifugation. Small pieces of the tumor biopsy were washed with PBS. PBMC and tumor biopsies were frozen and cryopreserved in liquid nitrogen for subsequent RNA extraction. When sufficient material was available (patients Ge10, Ge20 and Ge123), the rest of the tumor sample was processed to obtain single-cell suspensions (see below). Patients' PBMC were characterized for their HLA alleles by serology, by PCR and subsequent oligonucleotide hybridization (44) or by PCR using sequence-specific primers (45).
TCRAV and TCRBV gene segment usage
TCRAV and TCRBV gene segment usage was determined by RT-PCR as previously described (46). Briefly, total RNA was prepared from tumor (0.20.5 g tissue) or PBMC (25x106 cells) using TRIzol (Gibco/BRL, Life Technologies, Paisley, UK) and converted to cDNA by standard methods using reverse transcriptase and an oligo(dT) primer. These cDNAs were amplified in non-saturating PCR conditions (30 cycles) with a panel of experimentally validated 5' sense primers specific for the 22 BV subfamilies or the 29 AV subfamilies and one 3' antisense primer specific for the BC gene segment or the AC gene segment. The specificity of the amplified products were assessed after Southern blotting and hybridization with a labeled BC or AC oligonucleotide, and also by verifying the length of the PCR products with values deduced from the 5' and 3' primer positions. The comparative analysis of each BV or AV product between the different samples was achieved by densitometric analysis of the signals on the autoradiographs.
CDR3 size analysis of TCRBV transcripts
The CDR3 region of the PCR-amplified TCRBV122 transcripts was analyzed using a run-off procedure, as previously described (26). Briefly, aliquots (2 µl) of BV122BC PCR products (40 cycles) were subjected to one to three cycle run-off reactions, using dye-labeled oligonucleotide primers, specific for either BC or one of the 13 human functional BJ segments. The run-off products were then run on an automated sequencer in the presence of fluorescent size markers. The length of the DNA fragments and the fluorescence intensity of the bands were analyzed with Immunoscope software (developed by C. Pannetier) or Genescan Analysis software (Applied Biosystems, Forster City, CA).
Sequencing of PCR products
TRCBV1BC PCR products derived from astrocytoma samples were cloned into pBS-SK+ vector (Stratagene, La Jolla, CA). Competent XL-1 blue Escherichia coli (Stratagene) were transformed and plated for blue/white color selection on media containing X-gal. Plasmid DNA was extracted from white colonies using the Qiagen Plasmid Mini-kit (Qiagen, Hilden, Germany) and sequenced using the Dye Terminator Cycle Sequencing kit (ABI PRISM; Perkin Elmer, Foster City, CA) according to the manufacturer's instructions.
Quantification of BV1 clonal expansions
To quantify the respective proportions of recurrent BV1 transcripts in the total BV1 mRNAs, we adopted the approach described elsewhere (27). Briefly, clonotypic primers hybridizing with the CDR3 region of the recurrent BV1 sequences found in the astrocytoma samples were synthesized and labeled with a 6-Fam fluorophore (GENSET, Paris, France). Primer sequences were 5'-ATAGGAATTGGACCAGGCTAC-3' for patient Ge10 and 5'-GTAAAGCCCCTGTGGATTTAC-3' for patient Ge22. cDNA samples were amplified using a BV1 and a BC primer, then aliquots of the BV1BC PCR products were subjected to an elongation (one cycle) with either a 6-Fam-labeled and nested BC primer (26) or with the clonotypic primer. The two run-off products were then mixed in equal amounts and size-fractionated in the automated sequencer. The proportion of the specific sequence in the total BV1 mRNA population was calculated by dividing the area under the curve (AUC) obtained with the clonotypic primer by the sum of the AUC obtained with the BC primer. The obtained ratio was corrected by the relative specific activity of the clonotypic primer, which was calculated by dividing the AUC obtained with the clonotypic primer by the AUC obtained with the BC primer when amplifying plasmid DNA encoding the recurrent BV1 sequence.
The frequency of clonal BV1 cells in tumors was then determined as previously described (47). Briefly, cDNA of astrocytoma samples of interest were co-amplified with serial dilutions of a standard plasmid (105102 copies). The standard plasmid used displayed >85% homology with the astrocytoma BV1 transcripts but with a shorter CDR3 size (8 amino acids). Regions for primer hybridization were totally identical. Mismatches were located in the CDR3 and BJ regions. The run-off reaction was performed as described. The ratio of the AUC for standard and AUC for astrocytoma samples was calculated in each CDR3 profile, and plotted against the number of standard DNA copies mixed with the cDNA samples. This allowed the determination of the number of specific clonal transcripts present in 1 µg of tumor RNA.
Purification of CD4+ and CD8+ T cells
Tumor tissue was enzymatically digested for 12 h at 37°C in RPMI medium containing 0.1% collagenase type IA, 0.002% DNase type II and 0.05% protease type I. The resulting cell suspensions were centrifuged over a Ficoll-Hypaque gradient (Pharmacia, Uppsala, Sweden) and incubated for 48 h in Iscove's medium to allow re-expression of CD4 and CD8 molecules degraded by the digestion procedure (G. Perrin, unpublished data). All enzymes were obtained from Sigma (St Louis, MO) and media were from Gibco/BRL, Life Technologies (Paisley, UK). Non-adherent cells were then subjected to triple staining with an FITCanti-CD3 (clone UCH-T1), a phycoerythrinanti-CD8 (clone LT8) and a biotinylated anti-CD4 antibody (clone B-B14) followed by streptavidinTriColor (Caltag, Burlingame, CA) and sorted on a FACS Vantage (Becton Dickinson, Mountain View, CA). mAb were purchased from Serotec (Oxford, UK). Equal numbers of sorted CD4+ and CD8+ T cells were loaded with 106 P815 cells and pelleted for RNA extraction with Qiagen Rneasy Mini-kits (Qiagen). After reverse transcription, CDR3 size analysis was performed on both populations as described above.
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Results
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Diverse TCR AV and BV gene segment usage in astrocytoma patients
TCR AV and BV gene segment usage was analyzed in PBMC and tumor samples from the first nine astrocytoma patients. The AV gene segment usage was not restricted (data not shown). Relative expression level of BV gene segments in the tumor biopsies generally did not reveal any significant deviation from the PBMC as illustrated for patient Ge22 in Fig. 1
. However, some BV were missing from the tumor sample of certain patients, showing a complete repertoire in the PBMC (e.g. Ge21 in Fig. 1
). Among these patients, there was no recurrent pattern of BV overexpression, making stimulation by a putative superantigen unlikely.

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Fig. 1. Relative TCR BV gene segment expression in astrocytoma and PBMC samples from patients Ge22 and Ge21. Total RNA from uncultured PBMC and tumor samples was reverse transcribed and amplified in non-saturating PCR conditions (30 cycles) using BV and BC primers. The DNA fragments amplified by each BVBC primer pair were hybridized with a BC oligonucleotide probe. Results are presented according to the new nomenclature (78). For each sample, the autoradiographic spots obtained by Southern blot of PCR amplified TCR BV gene segments were analyzed by densitometry, and each BV signal was calculated as a percentage of the sum of all BV spots and displayed in the histograms.
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Numerous T cell clonal expansions are detected in uncultured astrocytoma samples by CDR3 size analysis
Recurrent identical size transcripts of TCR ß chains are found after specific T cell clonal expansion in response to defined antigens (26,27,48,49). To further investigate the T cell response in uncultured astrocytoma samples, we used a high-resolution RT-PCR method based on the determination of the spectrum of sizes of the CDR3 regions. Polyclonal T cell populations give rise to a bell-shaped profile of CDR3 size distribution. In contrast, expansion of specific T cell clones over a polyclonal population can be detected by significant perturbations in the CDR3 distribution profiles induced by the accumulation of recurrent size transcripts. In a first step, the CDR3 size variability of TCR BV transcripts was studied in blood and tumor samples from eight astrocytoma patients. BV124BC products were copied with a nested fluorescent BC primer and the size of the fluorescent run-off products was determined by electrophoresis on an automated DNA sequencer. In the majority of astrocytoma samples, significant perturbations in CDR3 size distribution profiles were found among different BV subfamilies (Fig. 2
). In contrast, most (>90%) of the BVBC PCR products from PBMC displayed a bell-shaped profile with several 3-nucleotide-spaced peaks (see representative patterns from BV1 and BV13; Fig. 2
), as found in healthy human donors (50).

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Fig. 2. CDR3 size distribution profiles of selected TCR BVBC run-off products from PBMC and tumor RNA samples in eight patients. Total RNA from uncultured PBMC and tumor samples was extracted, reverse transcribed and amplified by PCR using BV and BC primers. Amplified cDNA was copied by a fluorescent BC primer in a run-off reaction and subjected to electrophoresis on an automated sequencer. The patterns obtained show the size and intensity distribution of in frame BV1BC, BV13BC, BV14BC and BV16BC amplification products. Horizontal axis: size in amino acids of the CDR3 region deduced from the fragment length. Vertical axis: relative fluorescence intensity. The graphs representing CDR3 size patterns were normalized to 100% for the most intense peak. The BV13 profile of Ge33 is reproduced from (19) with permission.
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To exclude the possibility that these peaks reflect stochastic PCR amplification, the reproducibility of the profiles was tested for several tumors, starting either from the same cDNA sample or from cDNA samples derived from different pieces of the tumor. Profiles obtained after different PCR from the same cDNAs yielded identical results (data not shown). Interestingly, CDR3 distribution profiles were highly reproducible in different tumor regions for most patients (as shown for Ge10, Ge03 and Ge87 in Fig. 3
), showing that the prominent peaks generally reflect dominant T cell clonal expansions widely represented in the tumor. In contrast, the important variations in CDR3 size profiles observed in Ge21 (Fig. 3
) may be a consequence of tumor heterogeneity.

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Fig. 3. CDR3 size distribution profiles of TCR BVBC run-off products from distinct tumor regions. For each of the four patients, total RNA was extracted from two different pieces of the tumor biopsy and analyzed as described in Fig. 2 . The patterns obtained show the size and intensity distribution of in frame BVBC amplification products. For each patient, BVBC profiles that are not represented either include multiple CDR3 lengths or were only at background levels.
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BV1 clonal expansions with identical CDR3 size in different astrocytoma samples
The recurrent transcripts inside each BV subfamily usually had different CDR3 sizes in the different samples tested (e.g. BV14 and BV16 in Fig. 2
), with the exception of the BV1 subfamily where the majority of overwhelming expansions were due to ß chains with the same CDR3 size of 10 amino acids (Ge3, Ge21, Ge22, Ge10, Ge14 and Ge24 in Fig. 2
). Further analysis of BV1 transcripts in eight additional malignant astrocytoma RNA samples revealed clonal expansions with a CDR3 size of 10 amino acids in eight of 16 of the patients (data not shown). To further define the clonality of BV1 transcripts and to determine the BJ usage, BV1BC PCR products from the first eight astrocytoma samples were copied in 13 different run-off reactions using the 13 BJ-specific labeled primers. In seven cases, a single BV1BJ rearrangement was responsible for the 10 amino acids CDR3 size peak detected at the previous level of analysis using the BC specific labeled primer (Ge22 and Ge21 as representative examples in Fig. 4
). However, there is also the possibility that two different BV1BJ rearrangements can contribute to create such a peak, as in the case of Ge10. The BJ usage was generally different from one sample to another (Fig. 4A
and data not shown). Results obtained with the run-off analysis were confirmed by sequencing the BV1BC PCR products of three astrocytoma samples (Fig. 4B
). Alignments of CDR3-encoded amino acids indicated the presence of predominant BV1 clonotypes with a CDR3 size of 10 amino acids. However, despite their length homogeneity, the CDR3 regions of recurrent sequences did not include conserved amino acids residues. Moreover, HLA typing of patients' PBMC did not reveal any obvious correlation with particular HLA haplotypes (Table 1
).

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Fig. 4. Clonal BV1BC transcripts with identical CDR3 size observed in astrocytoma samples display a variable BJ gene segment usage and different CDR3 sequences. (A) BV1BC run-off products from astrocytoma samples of patients Ge22, Ge10 and Ge21 are shown as in Fig. 2 . BV1BC PCR products were copied in 13 different run-off reactions using the 13 BJ-specific labeled primers and subjected to electrophoresis on an automated sequencer. Only the profiles of BVBJ rearrangements responsible for the 10 amino acids CDR3 peak are indicated. The profiles of other BVBJ combinations either include multiple CDR3 lengths or were only at background levels. (B) BV1BC PCR products derived from three astrocytoma samples were cloned and sequenced as described in Methods. CDR3-like boundaries were defined according to (79) and encompass residues 95106.
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Some T cell clones are highly expanded in astrocytoma
Despite the absence of sequence homology, the presence of clonal BV1 transcripts with the same CDR3 size in a high proportion of astrocytoma samples was an unexpected observation needing further investigation, particularly since multiple sampling of the same tumors suggested that many of these clones were quite widely distributed within the tumor. The proportion of infiltrating T cells bearing such a receptor among the total tumor infiltrating lymphocyte (TIL) population was determined in two steps using quantitative PCR assays (47). First, the proportion of the recurrent BV1 transcripts in the total BV1 mRNAs was determined for patients Ge10 and Ge22 using a clonotypic primer hybridizing with the CDR3 region of the recurrent BV1 sequence (Fig. 4B
) as previously described (27). The BV1 clone with a CDR3 size of 10 amino acids in patient Ge10 represented 53 and 41% of the total BV1 mRNAs in two independent samples from different regions of the tumor, whereas it was undetectable in autologous PBMC. In the case of Ge22, 70% of the total BV1 RNA population was accounted for by a T cell clonal expansion with a CDR3 size of 10 amino acids (data not shown).
Based on these latter data, we calculated the number of clonal BV1 transcripts per µg of astrocytoma RNA, using a competitive RT-PCR assay (47). Aliquots of cDNA corresponding to 20 ng tumor RNA were co-amplified with defined copies numbers of a standard BV1 plasmid displaying high homology (>90%) with the astrocytoma clonal BV1 transcripts. Both templates were distinguishable based on their six nucleotides difference in CDR3 length (Fig. 5A
). The ratio of the intensities of the two peaks (at different quantities of standard plasmid) yielded the number of BV1 transcripts with a CDR3 size of 10 amino acids (Fig. 5
). By integrating the percentage of the clonotype of interest among these transcripts, we found that 142,000 and 111,500 clonal BV1 transcripts were contained in 1 µg astrocytoma Ge22 and Ge10 RNA samples respectively. Assuming that a T cell contains ~400 TCR ß transcripts (51), we estimated 350 and 280 clonal BV1 T cells per µg RNA in the two samples tested respectively. Considering that 1 µg RNA corresponds to 105106 cells and that T cells represent 0.11% of the entire cell population as determined by FACS (G. Perrin, unpublished results), the BV1 clonal cells in Ge22 and Ge10 can be estimated to represent at least 3.5% (350/10,000) and 2.8% (280/10,000) of all TIL respectively.

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Fig. 5. Frequency of clonal BV1 T cells in Ge22 and Ge10 astrocytoma samples. (A) Copies (105) of the standard plasmid were amplified using BV1 and BC primers. PCR products were copied by a fluorescent BC primer in a run-off reaction (one cycle) and subjected to electrophoresis on an automated sequencer. The CDR3 size pattern obtained confirmed the clonality of the plasmid with a CDR3 size at 8 amino acids. The CDR3 profiles obtained for the astrocytoma samples Ge22 and Ge10 are shown as in Fig. 2 to facilitate the comparison. cDNA corresponding to 20 ng tumor RNA was co-amplified with serial dilutions of the standard plasmid (from 105 to 102 copies). Note the progressive appearance of the peak with a CDR3 size at 10 amino acids. (B) The ratio of AUC for standard and AUC for astrocytoma samples was calculated in each CDR3 profile, and plotted against the number of standard DNA copies mixed with Ge10 or Ge22 cDNA respectively.
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Most expanded clones in astrocytoma are CD8+ cells
We determined whether in vivo expanded T cell clones were of CD4+ or CD8+ phenotype by flow cytometric sorting of CD3+CD4+ and CD3+CD8+ T cell populations from dissociated tumors. CDR3 size analysis was performed on both populations and compared with results obtained from non-dissociated astrocytoma RNA samples. Figure 6
shows that, for patient Ge10, all predominant peaks detected in the tumor biopsy segregated with the CD8 marker. To definitively demonstrate that the expanded cells detected in the CD8+ population corresponded to the expanded clones detected in the unmanipulated biopsy, BV1, BV4 and BV14 transcripts from the tumor biopsy were sequenced, and clonotypic primers specific for the CDR3 region of the recurrent sequences identified were synthesized. cDNAs derived from CD4+ and CD8+ sorted cells were subjected to the run-off analysis with the clonotypic primers. All three clones clearly appeared in the CD8+ cells as shown for the BV1 clone in Fig. 7
. The same CD4/CD8 sorting experiment was performed in two other astrocytoma samples. With the exception of one minor peak found in CD4+ cells, the other five oligoclonal expansions analyzed in these two additional patients segregated with the CD8 marker (data not shown).

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Fig. 6. Oligoclonal expansions are preferentially found in the CD8 subset. CD4+ and CD8+ T cells were sorted from the tumor biopsy after enzymatic digestion as described in Methods. cDNAs derived from CD4+ and CD8+ T cells were amplified using appropriate BV primers and analyzed as described in Fig. 2 .
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Fig. 7. Expanded BV1 clone in patient Ge10 segregates with the CD8 marker. CD4+ and CD8+ T cells were sorted from the tumor biopsy after enzymatic digestion as described in Methods. cDNA derived from CD4+ and CD8+ T cells was amplified with the BV1 primer. Each product was separated in two equal aliquots: one was used as template for the elongation with the fluorescent BC primer, providing the peaks on the right part of each panel. The other was used in the elongation with the clonotypic primer, providing the single peak on the left. These two run-off products were then mixed and size-fractionated in an automated sequencer. Quantification of the clonotype was performed as described in Methods.
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Discussion
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T cell clonal expansions are detected in human malignant astrocytoma
In this work, we studied the TCR diversity of T lymphocytes in tumor and blood samples collected from Caucasian astrocytoma patients. By analyzing CDR3 size variability, several T cell (oligo)clonal expansions were observed within different BV subfamilies in all 16 astrocytoma biopsies tested, consistent with immune responses to astrocytoma antigens. In contrast to this local reaction seen in the tumor bed, a systemic immune response was not obvious, since only exceptional (oligo)clonal expansions were detected in PBMC. It is therefore unlikely that T cells clonally expanded in astrocytoma are the direct consequence of blood expansions, such as those observed in certain healthy people (28,50,52). This was further supported by data obtained with clonotypic primers, showing that T cell clones highly represented in the tumor were not detectable in autologous PBMC [below the threshold of detection of the PCR, estimated at 1 in 105 (50)]. The T cell clonal expansions found in our study showed conserved TCR structural features in certain cases (e.g. many BV1 expansions with identical CDR3 size), but never conserved CDR3 sequences. This contrasts with previous TCR molecular analysis of astrocytoma infiltrating lymphocytes (but of non-Caucasian patients) reporting preferential AV7 and BV13 gene segment usage, with an identical BV13 transcript in different astrocytoma samples (53,54). In our series of Caucasian patients, this recurrent BV13 sequence was never detected in eight astrocytoma samples, including two patients expressing HLA-A24, the haplotype commonly (but not exclusively) associated with the recurrent TCR previously described (54) (G. Perrin, unpublished observations).
Intratumoral T cell clonal expansions have been reported in various types of cancers (4,7,8,55,56). Their presence in a tumor arising in the brain (i.e. astrocytoma) is more surprising. Indeed, the immune response in the CNS is tightly regulated to avoid deleterious consequences (57,58) and astrocytomas may exert immunosuppressive effects via soluble factors (59) or intercellular interactions (60). It was therefore interesting to evaluate the magnitude of unique T cell clonal expansions present in astrocytoma. Quantification of clonal TCR transcripts revealed that each expanded T cell clone analyzed was important in terms of absolute cell number and its frequency among TIL. The estimation of the cell numbers was confirmed by an independent experiment in which a tumor RNA sample was mixed with a defined number of PBMC (G. Perrin, data not shown). Other experimental data substantiate the importance of these results. In vivo expanded T cells detected by molecular analysis were found in significant proportions among in vitro derived clones generated by direct cloning of TIL from the tumor digestion (G. Perrin, unpublished data). Furthermore, the reproducibility of the BVBC profiles and the detection of the same clonotypes in different areas of a given tumor (Fig. 2
and data not shown) indicate that such clones can be widely distributed within astrocytoma. Overall, even if lymphocytic infiltration is not as overwhelming as found in certain other tumors (e.g. melanoma, renal cell cancer), these data suggest that astrocytoma may induce specific immune responses despite their intracerebral location. The identification of the in vivo expanded T cell populations by TCR molecular analysis guides our choice of T cell clones for expansion in vitro, and subsequent testing of specificity and function. For instance, CD8+ BV1+, BV4+ and BV14+ clones from patient Ge10 are very attractive candidates to identify the antigens recognized (61), and have already been expanded in vitro (G. Perrin, unpublished data).
Significance of conserved CDR3 size
Structural conservation of the TCR critical region for peptide recognition might reflect repertoire selection by a common MHCpeptide complex. Indeed, although TCR repertoires against defined epitopes were shown to exhibit variable levels of diversity (62), the CDR3 length was conserved over primary and memory responses with a restricted T cell repertoire (49,63). In human diseases, some restriction in CDR3 size variability was also reported in CD8+ T cells specific for HIV (64). Moreover, in vitro stimulation of lymphocytes with autologous tumor cells in mixed lymphocyte tumor cell culture assays can generate T cell clones sharing common BV gene segments and CDR3 sizes but different CDR3 sequences (65). Overall, these observations suggest that CDR3 length homogeneity may be a useful indicator of specific cells to unknown peptidic antigens (49,63,64).
In this study, the CDR3 sizes of BV T cell clones were random, except those present in the BV1 subfamily in which a CDR3 size of 10 amino acids was found in 50% of the astrocytoma samples. However, the presence of these BV1 clones with conserved CDR3 size was apparently not correlated with a given HLA allele and we did not find any conserved amino acids motif in the different CDR3 sequences. We do not have a direct explanation for this intriguing result but it may be interesting to analyze whether it reflects a response driven by antigens presented by non-classical MHC molecules such as CD1 (66).
T cell clones detected ex vivo by molecular analysis are CD8+
Recent experimental data have highlighted the importance of a synergistic action of CD4+ and CD8+ T cells for the induction of protective immunity in the CNS (1417). In the second part of our study, we asked whether T cells of both subsets were clonally expanded in human astrocytoma. Previous studies have shown that both CD4+- and CD8+-specific T cell responses against defined antigens can be detected in vivo by the appearance of certain BV populations with restricted CDR3 size diversity (27,48,67). Consequently, the CD4/CD8 phenotype of the in vivo expanded T cell clones was defined by repeating the TCR molecular analysis on CD4+ and CD8+ T lymphocytes sorted from three dissociated astrocytomas. Although T cells of both subsets were found among TIL (CD8+ cells: 3055% ; CD4+ cells: 4570%), expanded T cell clones were almost exclusively confined to the CD8+ subset, as definitively assessed with clonotypic primers.
The lack of obvious CD4+ T cell clonal expansions might be the direct consequence of the low or absent constitutive MHC class II expression by the CNS cells (68). However, the expression of MHC molecules is a dynamic process and can be induced in vitro on several CNS cell types (e.g. microglial cells, endothelial cells, smooth muscle/pericyte cells, astrocytes) that may potentially exhibit antigen-presenting cell (APC) functions (58). Similar events may also take place in vivo under the influence of microenvironmental factors (e.g. cytokines, neuropeptides) and indeed, specific CD4+ T cells accumulate in the brain following infection or autoimmune disease (6972). It is therefore unlikely that low MHC class II expression is the sole explanation for our observations. Other hypotheses may be envisaged. Firstly, the presence of specific CD4+ cells with very broad CDR3 diversity that would have been undetectable by our approach cannot be formally excluded. Direct cloning of CD4+ TIL and subsequent testing of CD4+ clones for specificity is currently being performed to address this question. Secondly, the lack of CD4+ clonal expansions may suggest functionally deficient APC, as described for dendritic cells present in skin and colon cancers (73). Finally, the present results have to be considered in the light of the new `licensing' model proposed for CD4+ help (74), in which CD4+ T cells would be needed to activate inefficient APC (e.g. with low expression levels of MHC and co-stimulatory molecules). This model suggests that CD4+ and CD8+ cells could be sequentially primed at different sites. Therefore, an interesting question to address in the case of astrocytoma is whether oligoclonal expansions of CD4+ T cells can be found in cervical lymph nodes that have been proposed to be the site of CNS lymphatic drainage (75).
With our current understanding of the importance of CD4+ help for the generation of efficient immune responses in the CNS, it is tempting to speculate that the lack of CD4+ T cell clonal expansions infiltrating the tumors of these patients may play a role in the ultimate failure of the immune system to control tumor growth. This hypothesis is in accordance with recent data further emphasizing the critical role of CD4+ cells for maintaining CD8+ function. For example, in transgenic mice expressing ovalbumin in pancreatic ß cells, it was reported that the biological effects of specific CD8+ cells (i.e. induction of diabetes by destruction of islet cells) were strongly dependent upon the presence of CD4+ cells. One possible explanation is that the CD4+ T cells can activate APC (74) to induce immunity rather than tolerance (76,77). In a similar way, the oligoclonal CD8+ T cells in astrocytoma may reflect transiently expanded populations that are functionally compromised by insufficient CD4+ help. It may be interesting to extend this study to a broader panel of patients to see if a CD4+ deficiency is a common feature of all astrocytoma. Another interesting question is whether a similar defect is also observed in other human tumors progressing outside the CNS or is restricted to astrocytoma.
In summary, this work is the first in-depth characterization of the clonality, the quantity and the phenotype of human astrocytoma infiltrating T cells. The presence of highly expanded T cell clones in the tumor bed is a strong argument for a spontaneous immune response being initiated against putative astrocytoma antigens, even if insufficient for tumor rejection. Some of these clones are currently being tested for function and specificity, and should help to identify the antigens recognized. An additional new finding of this study is the apparent deficiency in the CD4+ response at the site of tumor growth. This observation made in human astrocytoma raises important questions concerning the site of antigen presentation and the cell types involved in this critical biological process. Resolving such questions in animal models may indicate the best ways to reinforce the CD4+ T cell help in novel treatment strategies designed to elicit an anti-tumor immune response against CNS tumors.
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Acknowledgments
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We would like to thank A. Lim for helpful discussions, C. Metral for her expert technical help, and Pierre Alberto and André-Pascal Sappino for continuous support and encouragement. We thank the Neurosurgery staff for providing tissue samples. We acknowledge the excellent secretarial assistance of Melissa Morawitz. This work was supported by the Swiss National Science Foundation (to P. Y. D.), la Ligue Genevoise contre le Cancer, les Ligues Suisse et Franciaise contre le Cancer, la Fondation Prevost-Martin, the Helmut Horton Stiftung and la Fondation pour la lutte contre le cancer et pour des recherches biologiques. G. P. was supported by la Fondation MEDIC.
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Abbreviations
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APC | antigen-presenting cell |
AUC | area under the curve |
CDR | complementarity determining region |
CNS | central nervous system |
CTL | cytotoxic T lymphocyte |
PBMC | peripheral blood mononuclear cell |
TIL | tumor infiltrating lymphocytes |
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Notes
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The last two authors share senior authorship
Transmitting editor: H. Robson MacDonald
Received 4 February 1999,
accepted 6 May 1999.
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