After treatment with chimeric antigen receptor (CAR) T cells, interleukin-15 (IL-15) elevation and CAR T-cell expansion are associated with non-Hodgkin lymphoma (NHL) outcomes. However, the association of preinfusion CAR product T-cell functionality with clinical outcomes has not been reported. A single-cell analysis of the preinfusion CD19 CAR product from patients with NHL demonstrated that CAR products contain polyfunctional T-cell subsets capable of deploying multiple immune programs represented by cytokines and chemokines, including interferon-γ, IL-17A, IL-8, and macrophage inflammatory protein 1α. A prespecified T-cell polyfunctionality strength index (PSI) applied to preinfusion CAR product was significantly associated with clinical response, and PSI combined with CAR T-cell expansion or pretreatment serum IL-15 levels conferred additional significance. Within the total product cell population, associations with clinical outcomes were greater with polyfunctional CD4 T cells compared with CD8 cells. Grade ≥3 cytokine release syndrome was associated with polyfunctional T cells, and both grade ≥3 neurologic toxicity and antitumor efficacy were associated with polyfunctional IL-17A-producing T cells. The findings in this exploratory study show that a preinfusion CAR product T-cell subset with a definable polyfunctional profile has a major association with clinical outcomes of CAR T-cell therapy. This trial was registered at www.clinicaltrials.gov as #NCT00924326.
HSV-1 is the leading cause of sporadic encephalitis in humans. HSV infection of susceptible 129S6 mice results in fatal encephalitis (HSE) caused by massive inflammatory brainstem lesions comprising monocytes and neutrophils. During infection with pathogenic microorganisms or autoimmune disease, IgGs induce proinflammatory responses and recruit innate effector cells. In contrast, high dose intravenous immunoglobulins (IVIG) are an effective treatment for various autoimmune and inflammatory diseases because of potent anti-inflammatory effects stemming in part from sialylated IgGs (sIgG) present at 1–3% in IVIG. We investigated the ability of IVIG to prevent fatal HSE when given 24 h post infection. We discovered a novel anti-inflammatory pathway mediated by low-dose IVIG that protected 129S6 mice from fatal HSE by modulating CNS inflammation independently of HSV specific antibodies or sIgG. IVIG suppressed CNS infiltration by pathogenic CD11b+ Ly6Chigh monocytes and inhibited their spontaneous degranulation in vitro. FcγRIIb expression was required for IVIG mediated suppression of CNS infiltration by CD45+ Ly6Clow monocytes but not for inhibiting development of Ly6Chigh monocytes. IVIG increased accumulation of T cells in the CNS, and the non-sIgG fraction induced a dramatic expansion of FoxP3+ CD4+ T regulatory cells (Tregs) and FoxP3− ICOS+ CD4+ T cells in peripheral lymphoid organs. Tregs purified from HSV infected IVIG treated, but not control, mice protected adoptively transferred mice from fatal HSE. IL-10, produced by the ICOS+ CD4+ T cells that accumulated in the CNS of IVIG treated, but not control mice, was essential for induction of protective anti-inflammatory responses. Our results significantly enhance understanding of IVIG's anti-inflammatory and immunomodulatory capabilities by revealing a novel sIgG independent anti-inflammatory pathway responsible for induction of regulatory T cells that secrete the immunosuppressive cytokine IL-10 and further reveal the therapeutic potential of IVIG for treating viral induced inflammatory diseases.
Autoreactive pathogenic T cells (Tpaths) and regulatory T cells (Tregs) express a distinct gene profiles; however, the genes and associated genetic/signaling pathways responsible for the functional determination of Tpaths vs. Tregs remain unknown. Here we show that Skp2, an E3 ubiquitin ligase that affects cell cycle control and death, plays a critical role in the function of diabetogenic Tpaths and Tregs. Down-regulation of Skp2 in diabetogenic Tpaths converts them into Foxp3-expressing Tregs. The suppressive function of the Tpath-converted Tregs is dependent on increased production of TGF-β/IL-10, and these Tregs are able to inhibit spontaneous diabetes in NOD mice. Like naturally arising Foxp3 + nTregs, the converted Tregs are anergic cells with decreased proliferation and activation-induced cell death. Skp2 down-regulation leads to Tpath-Treg conversion due at least in part to up-regulation of several genes involved in cell cycle control and genes in the Foxo family. Down-regulation of the cyclin-dependent kinase inhibitor p27 alone significantly attenuates the effect of Skp2 on Tpaths and reduces the suppressive function of converted Tregs; its effect is further improved with concomitant down-regulation of p21, Foxo1, and Foxo3. In comparison, Skp2 overexpression does not change Tpath function, but significantly decreases Foxp3 expression and abrogates the suppressive function of nTregs. These findings support the critical role of Skp2 in functional specification of Tpaths and Tregs, and demonstrate an important molecular mechanism mediating Skp2 function in balancing immune tolerance during autoimmune disease development.type 1 diabetes | autoimmunity | autoreactive cells
This study is supported in part by funding from the Cooperative Research and Development Agreement (CRADA) between the National Cancer Institute and Kite Pharma Introduction: CAR-engineered autologous T-cell therapy has shown promising activity in relapsed/refractory B-cell malignancies in an ongoing phase 1 study (Kochenderfer et al. J Clin Oncol 2014). Lymphodepleting conditioning chemotherapy is critical for optimal CAR T-cell activity in animal models. We evaluated the effects of conditioning chemotherapy on cytokine and chemokine levels in patients dosed with anti-CD19 CAR T cells. Methods: In this National Cancer Institute clinical trial (NCT00924326), patients with relapsed/refractory B-cell malignancies received conditioning with cyclophosphamide and fludarabine daily for 3 days starting on day -5; followed by anti-CD19 CAR T cells engineered with a CAR comprising CD28 and CD3-zeta signaling domains. Forty one cytokines, chemokines and immune response related markers were measured in the blood of patients pre (day -5) and post conditioning (day 0) by using EMD Millipore Luminex® xMAP® multiplex assays. Data acquisition and analysis were performed using a Luminex 200™ instrument and xPONENT® 3.1 data analysis software. Increases in cytokine and chemokine levels were analyzed pre- and post- conditioning, and the fold-changes in cytokine and chemokine levels were analyzed relative to clinical outcome subsequent to infusion with anti-CD19 CAR T cells. Analyses were performed with the Wilcoxon rank sum test adjusted for multiplicity with a Bonferroni correction, using a nominal level of 0.006 for significance. Results: Samples from 15patients have been evaluated. There were significant increases pre- to post-conditioning in the levels of interleukin 15 (IL-15; p=0.001), interleukin 7 (IL-7; p=0.0002), and monocyte chemoattractant protein-1 (MCP-1; p<0.0025) in blood, five days after the initiation of conditioning chemotherapy. Levels of interferon-gamma induced protein 10 (IP-10) were elevated post-conditioning, but did not meet the threshold for significance (p=0.048). Compared with baseline, levels of IL-15 increased on average 13 fold and levels of IL-7, IP-10 and MCP-1, about 2 fold. Comparison of the fold-increases in IL-15 upon conditioning between responders and non-responders approached significance (p=0.01), but did not meet the threshold after multiplicity adjustment. Larger fold-change increases for responders versus non-responders were also observed with placental growth factor (PLGF) (median fold increase 2.6 v. 1.6, average fold increase 32 v 4.2), C-reactive protein (CRP) (median fold increase 3.5 v 2.4, average fold increase 6.6 v. 2.0), IP-10 (median fold increase 2.1 v. 0.7, average fold increase 2.6 v. 2.8), and interleukin 10 (IL-10) (median fold increase 1.8 v. 0.4, average fold increase 3.1 v. 2.0), but did not meet the threshold for significance. In addition to ongoing analysis of conditioning-mediated cytokine induction and clinical response, we are evaluating the impact of conditioning chemotherapy dose on cytokine levels, as well as the relationship between conditioning-related cytokines and CAR T-cell expansion and persistence. Conclusions: The data obtained to date support the hypothesis that cytokines such as IL-15 play a key role in the clinical outcomes to anti-CD19 CAR T-cell therapy. Our results demonstrate that conditioning chemotherapy significantly increases the levels of homeostatic cytokines known to regulate T-cell expansion, as well as specific pro-inflammatory cytokines and chemokines. Optimization of conditioning chemotherapy is critical to the activity of CAR T-cell therapies. Disclosures Bot: Kite Pharma: Employment, Equity Ownership. Rossi:Amgen: Equity Ownership; Kite Pharma: Employment, Equity Ownership. Jiang:Kite Pharma: Employment, Equity Ownership. Navale:Amgen: Equity Ownership; Kite Pharma: Employment, Equity Ownership. Shen:Kite Pharma: Employment, Equity Ownership. Sherman:Amgen: Equity Ownership; Kite Pharma: Employment, Equity Ownership. Mardiros:Kite Pharma: Employment, Equity Ownership. Yoder:Kite Pharma: Employment, Equity Ownership. Go:Amgen: Equity Ownership; Kite Pharma: Employment, Equity Ownership. Rosenberg:Kite Pharma: Other: CRADA between Surgery Branch-NCI and Kite Pharma. Wiezorek:Kite Pharma: Employment, Equity Ownership, Other: Officer of Kite Pharma. Chang:Kite Pharma: Employment, Equity Ownership, Other: Officer of Kite Pharma. Roberts:Kite Pharma: Employment, Equity Ownership, Other: Officer of Kite Pharma.
Foxp3+ regulatory T cells (Treg) play a crucial role in regulating immune tolerance. The use of Treg to restore immune tolerance is considered an attractive novel approach to inhibit autoimmune disease, including type 1 diabetes (T1D), and to prevent rejection of organ transplants. In view of the goal of developing autologous Treg-based cell therapy for patients with long-term (>15 years) T1D, it will be necessary to expand a sufficient amount of functional Treg in vitro in order to study and compare Treg from T1D patients and healthy subjects. Our results have demonstrated that there is a comparable frequency of Treg in the peripheral blood lymphocytes (PBLs) of patients with long-term T1D relative to those in healthy subjects; however, Th1 cells, but not Th17 cells, were increased in the T1D patients. Further, more Treg in PBLs from T1D patients than from healthy subjects expressed the CD45RO+ memory cell phenotype, suggesting they were antigen-experienced cells. After isolation, Treg from both T1D patients and healthy subjects were successfully expanded with high purity. Although there was no difference in Helios expression on Treg in PBLs, in vitro expansion led to fewer Helios-expressing Treg from T1D patients than healthy subjects. While more Th1-like Treg expressing IFN-γ or TNF-α were found in the PBLs of T1D patients than healthy controls, there was no such difference in the expanded Treg. Importantly, expanded Treg from both subject groups were able to suppress autologous or allogeneic CD8+ effector T cells equally well. Our findings demonstrate that a large number of ex vivo expanded functional Treg can be obtained from long-term T1D patients, although fewer expanded Treg expressed a high level of Helios. Thus, based on the positive outcomes, these potent expanded Treg from diabetic human patients may be useful in treating T1D or preventing islet graft rejection.
Anti-CD19 chimeric antigen receptor (CAR) T cells have powerful activity against B-cell lymphoma, but improvement is clearly needed. Toxicity, including cytokine-release syndrome (CRS) and neurologic toxicity, occurs after anti-CD19 CAR T cell infusions. Most CAR T-cell toxicity is caused, either directly or indirectly, by cytokines or other proteins that are secreted from CAR T cells. The structure of a CAR is an extracellular antigen-recognition domain connected by hinge and transmembrane (TM) domains to intracellular T-cell signaling moieties. In vitro, T cells expressing CARs with hinge and TM domains from the CD8-alpha molecule released significantly lower levels of cytokines compared with T cells expressing CARs with hinge and TM domains from CD28; however, T cells expressing CARs with hinge and TM domains from CD8-alpha retained sufficient functional capability to eradicate tumors from mice (Alabanza et al. Molecular Therapy. 2017. 25(11) 2452). To reduce cytokine production with a goal of reducing clinical toxicity, we incorporated CD8-alpha hinge and TM domains into an anti-CD19 CAR. The CAR also had a human antigen-recognition domain, a CD28 costimulatory domain, and a CD3-zeta domain. This CAR was designated Hu19-CD828Z and was encoded by a lentiviral vector. Hu19-CD828Z was different from the FMC63-28Z CAR that we used in prior studies. FMC63-28Z had hinge and TM domains from CD28 along with a CD28 costimulatory domain, a CD3-zeta domain, and murine-derived antigen-recognition domains. Twenty patients with B-cell lymphoma were treated on a phase I dose-escalation clinical trial of Hu19-CD828Z T cells (Table). Patients received low-dose cyclophosphamide and fludarabine daily for 3 days on days -5 to -3. Two days later, on day 0, CAR T cells were infused. The overall response rate (ORR) after 1st treatments with Hu19-CD828Z T cells was 70%, and the complete response (CR) rate 55%; the 6-month event-free survival was 55%. The anti-lymphoma activity of Hu19-CD828Z T cells in the current trial was comparable to the anti-lymphoma activity of FMC63-28Z T cells in a similar prior trial that also enrolled patients with advanced B-cell lymphoma. In the prior trial, we observed a 73% ORR, a 55% CR rate, and a 6-month event-free survival of 64% in 22 patients treated with FMC63-28Z T cells (Kochenderfer et al. Journ. Clin. Oncology. 2017 35(16) 1803). In our previous clinical trial of FMC63-28Z T cells, the rate of Grade 3 or 4 neurologic toxicity among 22 patients treated was 55%. Strikingly, in our trial of Hu19-CD828Z T cells, the rate of Grade 3 or 4 neurologic toxicity was only 5% (1/20 patients). In addition, the rate of Grade 2 or greater neurologic toxicity with FMC63-28Z T cells was 77.3% while the rate of Grade 2 or greater neurologic toxicity with Hu19-CD828Z T cells was 15%. To explore the mechanism for the difference in neurologic toxicity in patients receiving FMC63-28Z T cells versus Hu19-CD828Z T cells, we assessed serum levels of 41 proteins in patients treated with these CAR T-cells. This comparison is valid because the same Luminex methodology was used for the serum protein analysis for both trials, and controls of known amounts of each protein were assayed to ensure that protein levels were comparable on the different trials. Lower levels of several serum proteins that might be important in CAR toxicity were found in patients treated with Hu19-CD828Z T cells versus patients treated with FMC63-28Z T cells: Granzyme A (P<0.001), Granzyme B (P<0.001), interferon gamma (P=0.011), interleukin (IL)-15 (P=0.007), IL-2 (P=0.0034), and macrophage inflammatory protein-1A (P<0.001). Median peak patient blood CAR+ cell levels were 44 cells/µL for Hu19-CD828Z and 46.5 cells/µL for FMC63-28Z (P=not significant). We hypothesize that lower levels of potentially neurotoxic proteins in patients receiving Hu19-CD828Z T cells versus FMC63-28Z T cells led to a lower frequency of neurologic toxicity in patients receiving Hu19-CD828Z T cells. The lower levels of immunologically active proteins found in the serum of patients receiving Hu19-CD828Z T cells compared with patients receiving FMC63-28Z T cells is consistent with our in vitro experiments showing lower cytokine production by T cells expressing CARs with CD8 hinge and TM domains versus CD28 hinge and TM domains. Altering CAR hinge and TM domains can affect CAR T-cell function and is a promising approach to improve the efficacy to toxicity ratio of CAR T-cells. Disclosures Rossi: KITE: Employment. Shen:Kite, a Gilead Company: Employment. Xue:Kite, a Gilead Company: Employment. Bot:KITE: Employment. Rosenberg:Kite, a Gilead Company: Research Funding. Kochenderfer:Kite a Gilead Company: Patents & Royalties: CAR technology, Research Funding; Celgene: Research Funding.
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