- Franz J. Gassner1,
- Nadja Zaborsky1,
- Daniel Neureiter2,
- Michael Huemer1,
- Thomas Melchardt1,
- Alexander Egle1,
- Stefan Rebhandl1,
- Kemal Catakovic1,
- Tanja N. Hartmann1,
- Richard Greil*,1⇑ and
- Roland Geisberger*,1
- 1Department of Internal Medicine III with Hematology, Medical Oncology, Hemostaseology, Infectious Diseases, Rheumatology, Oncologic Center, Laboratory for Immunological and Molecular Cancer Research, Paracelsus Medical University Salzburg, Austria
- 2Department of Pathology, Paracelsus Medical University Salzburg, Austria
While T-cell dysfunction occurring alongside chronic lymphocytic leukemia (CLL) is well documented (reviewed by Pleyer et al.1 and Hamblin et al.2), it was recently reported that also T-cell exhaustion is associated with CLL, reflected in the presence of PD-1+ CLL T cells and higher levels of PD-L1 on the surface of CLL cells.3–5 It was suggested that T-cell exhaustion might impede proper synapse formation of CLL-specific T cells and, hence, impair a cytolytic attack.6 Therefore, therapeutic interference with T-cell exhaustion in combination with chemotherapy has been proposed as a promising treatment option, aimed at restoring a functional cytotoxic T-cell pool to eradicate the malignant cells.
In this study, we assessed the level of T cells expressing the inhibitory surface markers PD-1 (programmed death receptor-1, CD279), 2B4 (natural killer cell receptor 2B4, CD244) and CD57 (human natural killer-1), which were previously associated with T-cell exhaustion and senescence as they counteract intracellular activation signals triggered upon recognition of target cells.7,8 CD57 expression is thereby associated to impaired proliferation of CD8+ but also CD4+ T cells,9 and PD-1 engagement counteracts T-cell receptor (TCR)/CD3-induced T-cell proliferation and cytokine production, while expression of 2B4 on CD8+ T cells correlates with PD-1 expression.10 We evaluated the expression of PD-1, 2B4 and CD57 in peripheral blood T cells from 131 unselected CLL patients and compared it to the expression levels of 14 age-matched healthy donors (median age 68.8 or 66.1 years, respectively) by flow cytometric analysis of whole blood samples. From the analyzed CLL patients, 82 were chemonaive (no prior CLL-related treatment) and 49 had received therapy, 10 of whom had been treated with a regimen including the immunomodulatory drug lenalidomide.11 Online Supplementary Tables S1 and S2 list detailed patients’ characteristics and treatment regimes. As summarized in Table 1, we observed that within the CD4+ T-cell subset of chemonaive patients, the percentage of cells expressing the analyzed individual markers (i.e. PD-1, 2B4, CD57) or expressing two or all three inhibitory receptors was comparable to age-matched healthy controls. While all analyzed markers were slightly increased within the CD8+ T-cell population, only the expansion of CD8+ T cells expressing CD57 alone or in combination reached statistical significance. Interestingly, we noted a significant increase in CD8+ T cells expressing PD-1 either alone or in combination with 2B4 and/or CD57 in chemonaive patients with advanced RAI stage and high leukocyte counts (Online Supplementary Tables S3). While RAI stage also had a significant impact on the frequency of CD4+ PD-1+ T cells, none of the other analyzed prognostic markers, i.e. CD38, Zap-70, IgVH mutations or cytogenetic aberrations in the malignant B cells was associated with PD-1, 2B4 or CD57 expression on CD4+ or CD8+ T cells. We found a significantly higher expression of 2B4 and CD57, but not PD-1 in CD4+ and CD8+ T cells of patients seropositive for human cytomegalovirus (HCMV) (data not shown). While data on the HCMV serostatus of the healthy donors in this study were not available, HCMV seroprevalence in healthy elderly has been suggested to be 50–80%,12 which is comparable to or even higher than the rate of seropositivity in our CLL cohort (53%). We, therefore, suppose that the impact of HCMV infection is comparable between healthy controls and CLL patients.
Furthermore, we observed that all of the T-cell subsets except CD8+ T cells expressing PD-1 alone or in combination were increased in samples from chemotherapy-treated patients (Table 1). Conversely, these T-cell subsets were significantly reduced in samples from patients receiving lenalidomide combinational treatment, leading to a reversion of T-cell numbers to levels found in-between healthy controls and chemonaive CLL patients. To further elucidate the functional exhaustion of T-cell subsets expressing the respective inhibitory receptors, we tested their proliferative capacity to T-cell receptor-dependent stimulation in vitro. Thereby, we found that CD57+ as well as 2B4+ T cells exhibited the most distinct reduction of proliferative potential upon CD3/CD28 stimulation (Figure 1). Interestingly, PD-1 expression has a different impact on proliferating CD4+ or CD8+ T cells. While PD-1+ CD4+ T cells showed no impaired proliferation, PD-1+ CD8+ T cells tended to be reduced in their proliferative potential, albeit not significantly.
Our results are consistent with recent studies which reported the association of the PD-1/PD-L1 axis and T-cell exhaustion with T-cell dysfunction and progressive disease in CLL.3–5 In our study, we confirm the phenotypic marker profile of exhausted T cells in CLL and beyond that show that an expanded subset of low-proliferative, CD57+ CD8+ T cells is observed in CLL patients, which was further increased upon treatment of patients with chemotherapeutic regimen.
We showed that T-cell dysfunction is not solely reflected by increased PD-1 levels, which were comparable in CLL patients and healthy donors in our study samples, but rather by expression of other inhibitory receptors such as 2B4 and CD57, which seem to be more closely related to functional inhibition of CLL T cells. This is particularly important, as we show that CD57+ as well as 2B4+, but not PD-1+ single positive T cells are significantly impaired in their proliferative response to TCR-dependent stimulation in vitro and might contribute to paralyzed immune surveillance towards the CLL clone. While patients receiving chemotherapy showed an increase in T-cell subsets expressing inhibitory receptors, combined treatment with lenalidomide induced a reduction of these T-cell compartments and, thus, most likely counteracts therapy-induced accumulation of silenced T cells. We have already shown a substantial shift in T-cell subset composition towards an antigen-experienced Th1 memory phenotype after fludarabine treatment.13 Reducing expression of inhibitory signaling molecules by immunomodulatory drugs may, therefore, represent an important factor for enduring tumor surveillance and contribute to maintaining long-term remissions. Our results corroborate recent findings on the improvement of T-cell immune synapse formation upon lenalidomide treatment in vitro and in vivo16,14 which also suggests lenalidomide-induced reversion of T-cell functionality.
In summary, our results show that chemotherapy may hamper the patients’ T-cell-mediated immune surveillance while a combined treatment with lenalidomide may contribute to establishment of a more robust tumor control. Future work will be necessary to assess CLL specificity of T cells expressing one or more of the inhibitory receptors analyzed in our study and to test whether lenalidomide treatment can improve cytotoxicity of CLL-specific T cells, in particular in combination with immune therapeutic antibodies specific for PD-1 or CTLA4, which also counteracts TCR/CD3 mediated signaling pathways.15
↵* RGr and RGe contributed equally to this work.
Funding: This work was supported by the Austrian Science Fund (FWF; Project SFB021 to R.Gr., Hertha Firnberg Grant T516-B13 to N.Z., Project P24100 to R.Gr., Project P24619 to R.Ge.), the Paracelsus Medical Private University (PMU Grant E-10/11/057-EGL to A.E.), the “Klinische Malignom- und Zytokinforschung Salzburg-Innsbruck GmbH,” the “Arbeitsgemeinschaft Medikamentöse Tumortherapie (AGMT)” and the Province of Salzburg.
Information on authorship, contributions, and financial & other disclosures was provided by the authors and is available with the online version of this article at www.haematologica.org.
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