Biomarker-driven management strategies for peripheral T cell lymphoma

CD30 is a tumor necrosis factor (TNF) receptor family transmembrane receptor with restricted expression in activated T and B cells in normal lymphoid tissues [13]. Across PTCL subtypes, systemic ALCLs universally express CD30 in membrane and golgi patterns, while approximately 50% of non-ALCL subtypes, including PTCL, NOS, AITL, ENKTL, ATLL, EATL, and HSTL, express CD30 at variable levels. CD30 expression in PTCL suggests a CD30-mediated pathogenic mechanism for potential therapeutic targeting with brentuximab vedotin (BV), an antibody-drug conjugate that combines cytotoxic monomethylauristatin E (MMAE) with an anti-CD30 antibody [14]. The level of CD30 expression may not always be predictive of response to BV due in part to tumor heterogeneity, variation in detection and reporting of CD30 expression, and proposed secondary mechanisms of action. Single-agent BV given at 1.8 mg/kg intravenously every 3 weeks for up to 16 cycles in 58 patients with relapsed or refractory (R/R) sALCL showed overall response rate (ORR) of 86% with 57% complete response (CR) in a pivotal phase 2 study, leading to approval in the USA, EU, and Japan for R/R sALCL [15]. Responses in sALCL appear to be durable: 5-year overall survival (OS) and progression-free survival (PFS) were 79% and 57%, respectively, in patients who achieved a CR. In patients who did not achieve a CR, the 5-year OS was 25% [15]. Grade 3 or 4 adverse events (AEs) experienced by ≥ 10% of patients were neutropenia (21%), thrombocytopenia (14%), and peripheral sensory neuropathy (12%). Overall, treatment was well tolerated. In non-ALCL, single-agent BV showed clinical antitumor activity in AITL and PTCL-NOS, with ORR of 41% (including 54% ORR in AITL with a median PFS of 6.7 months), although responses did not correlate with CD30 expression [16]. These results with single-agent BV paved the way for clinical development of BV-containing combinations in both relapsed and frontline settings.

CD52 is a glycosylphosphatidylinositol (GPI) anchored low molecular weight glycoprotein (21–28 kDa) expressed on the surface of B and T lymphocytes, natural killer cells, monocytes, macrophages, and some dendritic cells [17]. PTCL subtypes such as PTCL/NOS, AITL, ATLL, HSTL, and T-PLL were shown to have high frequency of CD52 expression (> 90%) by flow cytometry and IHC analysis, while CD52 expression was low in ALCL and ENT/NKCL [18, 19]. Although the variable and differential CD52 expression in T cell lymphoma tumor cells implies a rational role for anti-CD52 mAb alemtuzumab in the treatment of PTCL, persistent expression of CD52 by the background normal T- and B cell infiltrate limits therapeutic window of anti-CD52 therapy due to potential immuno-suppression, including increased risk of viral and other opportunistic infections [20].

Single-agent alemtuzumab has established treatment efficacy in T cell prolymphocytic leukemia (T-PLL). Phase I/II and retrospective studies have indicated response rates of up to 75% in patients with previously untreated disease, although relapse remains nearly universal with mOS of < 2 years. When given three times weekly at 3, 10, and 30 mg IV during week one, followed by 30 mg three times a week for up to 16 weeks, response rate was over 90% in 41 previously untreated T-PLL patients with 81% achieving CRs [21]. Prophylaxis against pneumocystis jiroveci (PJP) and herpes viruses together with regular monitoring for CMV reactivation are recommended to minimize the risk for serious infections [22].

CC chemokine receptor 4 (CCR4) promotes memory T cell homing to peripheral tissues and is preferentially expressed by Th2 and regulatory T cell subsets [24]. In addition to expression in most CD4+CD25+ ATLL, CCR4 is expressed in approximately 30–65% of PTCL tumor cells, including high expression (~ 65%) in ALK-negative ALCL, variable expression (30–40%) in PTCL/NOS, AITL, and transformed MF, while rarely expressed in ENKTL or ALK-positive ALCL [25]. Mogamulizumab (KW-0761) is a defucosylated, humanized, IgG1 monoclonal antibody directed against CCR4 that has direct cytotoxic effect on CCR4-positive lymphoma cells via ADCC, as well as immunomodulatory potential by depletion of regulatory T cells to enhance anti-tumor immunity. Mogamulizumab is approved in Japan for R/R CCR4+ ATLL and CTCL and has been approved in the USA for R/R MF and Sezary syndrome. In 28 Japanese patients with CCR4+ R/R ATLL treated with mogamulizumab at 1.0 mg/kg intravenously once weekly for 8 weeks demonstrated ORR of 50% with 30% CR, and median PFS and OS of 5.2 and 13.7 months, respectively [26]. The most common AEs were hematologic events, pyrexia, and skin reactions, all of which were reversible and manageable.

In preclinical studies using TCL cell lines, HDAC inhibitors were shown to induce cell-cycle arrest, apoptosis, and DNA damage and modulate a number of intracellular pathways [28]. Vorinostat, a pan HDAC, was the first drug of its class to be approved by the FDA in 2006 for the treatment of cutaneous T cell lymphoma. A single-arm open-label phase II trial enrolled 74 patients with stage IB or greater CTCL who had failed 2 or more lines of systemic therapy including bexarotene. Patients were treated with oral vorinostat at 300 mg daily or 300 mg 5 days a week and demonstrated favorable responses and an acceptable safety profile: ORR 30% and a median time to tumor progression 202 days [29]. This approval ushered in a still ongoing period of research and development of epigenetic therapy, particularly in TCL.

Romidepsin is a bicyclic class 1 selective HDAC inhibitor approved by the FDA for treatment in patients with R/R PTCL who have failed at least one prior systemic therapy. In a pivotal phase 2 study, 130 patients received romidepsin at 14 mg/m² on days 1, 8, and 15 every 28-day cycle, which showed ORR of 25% including 15% CR/unconfirmed CR (CRu), with durable median duration of response (DOR) of 28 months in responders [30, 31]. Adverse events were manageable and consistent with other HDAC inhibitors, with thrombocytopenia (24%), neutropenia (20%), and infections (all types, 19%) representing the most common grade ≥ 3 AEs. Given the promising results of this study, romidepsin has also been combined with other agents, such as lenalidomide [32], carfilzomib [33], or pralatrexate [34], in attempts to improve efficacy. A phase I/II trial, which included 11 patients with R/R PTCL, showed an ORR of 50% to the doublet of romidepsin given at MTD of 14 mg/m² IV on days 1, 8, and 15 and lenalidomide 25 mg orally on days 1–21 of 28-day cycles [32]. Romidepsin has additionally been combined with lenalidomide and carfilzomib as a triplet in a phase Ib/IIa study that included 16 patients with R/R PTCL. MTD was defined as romidepsin 8 mg/m² days 1 and 8, lenalidomide 15 mg days 1–15, and carfilzomib 36 mg/m² days 1 and 8, every 21-day cycle. The triplet demonstrated a 50% ORR with 30% CR, which seemed to be enriched among patients with AITL (4/5 patients) [33]. A phase I trial combining romidepsin 15 mg/m² and pralatrexate 25 mg/m² in 18 patients with R/R PTCL showed ORR of 71%, which has led to an ongoing phase II trial (NCT01947140) in PTCL [34].

Belinostat, a hydroxamic acid-derived pan-HDAC inhibitor, has also been approved by the FDA in 2014 based on the results of the pivotal phase 2 BELIEF trial [35]. A total of 129 patients with R/R PTCL were treated with 1000 mg/m² belinostat on days 1–5 in 21-day cycles. The ORR was 25.8% including 10.8% CRs. The ORR was 23% in patients with PTCL-NOS, 46% in patients with AITL, and 15% in patients with ALK− ALCL. The median DOR was 13.6 months, and median PFS and OS were 1.6 and 7.9 months, respectively. The most common grade 3 to 4 adverse events were anemia (10.8%), thrombocytopenia (7%), dyspnea (6.2%), and neutropenia (6.2%).

The oral class I/II HDAC inhibitor chidamide has been studied in 83 R/R PTCL patients in China in a phase II study, which included patients with PTCL NOS (34%), ALCL (22%), ENKTL, nasal type (20%), or AITL (13%). Patients received chidamide 30 mg orally twice per week. The ORR was 28% including 14% with CR/CRu. Median PFS and OS were 2.1 and 21.4 months, respectively. AITL patients tended to have higher ORR (50%) and CR/CRu rate (40%), as well as more durable responses to chidamide treatment, with a manageable toxicity profile [36].

5-Azacitidine (5-AZA) has shown efficacy in myeloid neoplasms where response rates appear to correlate with TET2, IDH1/2, and/or DNMT3A mutations which regulate DNA methylation levels [37]. It was hypothesized that hypomethylating agents could be effective in TFH-derived PTCL given the abundance of recurrent TET2, DNMT3A, and IDH2 mutations. A retrospective French LYSA cohort study reported clinical outcome of 12 patients with R/R AITL (41% with associated myeloid neoplasms) treated with subcutaneous daily injection of 75 mg/m² 5-AZA for 7 consecutive days every 28-day cycle. The treatment appeared to be promising: ORR was 75% including 50% CR, median PFS was 15 months, and median OS was 21 months. Molecular studies revealed TET2 mutation in 100% of patients, 33% with DNMT3A mutations, 41% with RHOA mutations, and one patient with IDH2^R172 mutation [38]. Currently, a global phase 3 study is ongoing to prospectively compare the efficacy and safety of oral azacitidine (CC486) to the investigator’s single-agent choice of either romidepsin, bendamustine, or gemcitabine in patients with R/R AITL (NCT03593018). Azacitadine has also been studied in combination with romidepsin in a multicenter phase I trial. Azacitadine was given orally at a MTD of 300 mg on days 1 to 14 with romidpesin 14 mg/m² given IV on days 8, 15, and 22 on a 35-day cycle in 31 patients with R/R lymphomas. This pair was particularly effective in PTCL, where it produced ORR of 73% with 55% CR and was well tolerated [39]. A phase II study with this combination is maturing to confirm the efficacy data in PTCL.

PD1 is a type I membrane protein that belongs to the immunoglobulin superfamily. It is a member of the extended CD28/CTLA-4 family of immune checkpoint that guards against autoimmunity by downregulating the immune system and promoting self-tolerance [40]. PD-1 is expressed on the surface of activated T cells, B cells, and macrophages and negatively regulates immune responses broadly. PD1 binds two ligands, PD-L1 and PD-L2. In PTCL, PD-1 expression was detected in atypical T lymphoma cells in the majority of AITL (> 90%), to a lesser extent in PTCL/NOS (30–60%), and rarely in other subtypes [41]. In AITL, both PD1 and CXCL13, a chemokine promoting B cell migration and survival in lymph node, showed a similar expression frequency highlighting follicular helper T cells (TFH) [42], which may share additional TFH markers including CD10, BCL6, and ICOS [43]. In NKTCL, PD-L1 expression in NK/T cell lymphoma cells ranged from 56 to 93% in various studies, while PD-1 level was low [44]. In ATLL, PD-L1 amplification was shown as a strong genetic predictor in both aggressive and indolent ATLL [45]. Anti-PD1 immune checkpoint blockade strategy has generated mixed results in PTCL to date due to the complexity that malignant T cell lymphoma cells can express PD-1. In such instances, immune checkpoint blockade has the potential to accelerate tumor growth in tumor cells with high PD-1 expression, as proposed in murine studies [46]. ATLL patients treated with nivolumab developed rapid disease progression after 1 cycle of nivolumab treatment [47], cautioning against the use of immune checkpoint blockade in ATLL without further understanding the complex mechanism of immune evasion and activation. In other subtypes, responses have been mixed. In patients with R/R T cell lymphoma, single-agent nivolumab produced ORR of 40% [48], while PD1 blockade with pembrolizumab showed high efficacy (100% ORR, 71% CR) in a case series of 7 R/R EBV-associated NK and T cell lymphoma [49]. A phase II multicenter trial of patients with R/R PTCL who were treated with pembrolizumab was halted early after a preplanned interim futility analysis [49]. Nevertheless, several trials are ongoing to further explore the efficacy of PD-1 blockade in PTCL. Pembrolizumab is being added to romidepsin (NCT03278782) and pralatrexate (NCT03598998) in ongoing phase I/II trials in patients with R/R PTCL. Pembrolizumab is also being combined with pralatrexate and the epigenic modifier decitabine in an ongoing phase I trial (NCT03240211). The PD-1 monoclonal antibody durvalumab is being studied alone and in combination with lenalidomide in patients with R/R PTCL and CTCL (NCT03011814) as well as in combination with pralatrexate, romidepsin, and/or azacitdine (NCT03161223). The novel PD-1 monoclonal antibodies avelumab (NCT03046953) and tislelizumab (NCT03493451) are being evaluated in R/R PTCL and R/R mature NK and T cell lymphomas, respectively.

Lenalidomide is a well-established immunomodulatory agent in B cell NHL and multiple myeloma, which has shown modest single-agent activity in PTCL in phase 2 studies. The EXPECT trial with lenalidomide 25 mg given once daily on days 1–21 of 28-day cycle showed ORR of 22% with 11% CR/Cru in various R/R PTCL subtypes, including ORR 31% with CR/Cru 15% in AITL [50]. Overall, 35% of patients experienced at least 1 AE that lead to study dose interruption or reduction, most commonly neutropenia or thrombocytopenia. Lenalidomide given at 25 mg daily continuously in a phase 2 study of Japanese patients with R/R ATLL showed ORR of 42% with 19% CR/CRu, and median PFS and OS at 3.8 and 20.3 months, respectively. Toxicities were manageable in this population with all serious AEs resolving or resolved by the end-of-study assessment [51].

Anaplastic lymphoma kinase (ALK) is a receptor tyrosine kinase known to be oncogenically activated in a subset of ALCL. Crizotinib is an ALK-ROS1-MET small molecule inhibitor which showed a high response rate (ORR 90%) in the Children’s Oncology Group study of 26 ALK+ ALCL patients [33, 52]. In this prospective phase I/II trial, patients were treated with crizotinib at 165 mg/m² or 280 mg/m² orally twice daily on days 1–28 of 28-day cycles. CR was observed in 83% (five of six) of ALCL165 and 80% (16 of 20) of ALCL280, with a median duration of therapy of 2.79 and 0.4 years, respectively. A retrospective study of 11 adult patients with R/R ALK+ lymphoma treated with crizotinib 250 mg twice daily until disease progression achieved 90.9% ORR with OS and PFS at 2 years of 72.7% and 63.7%, respectively [53]. Crizotinib-related toxicities were mild and manageable. These studies highlight the important role the ALK pathway plays in these diseases.

Phosphatidylinositol 3-kinase (PI3K) is a lipid kinase that is involved in intracellular signal transduction, with the PI3K-δ and PI3K-γ isoforms preferentially expressed in leukocytes where they modulate both innate and adaptive immune function by mediating pathways important for survival, proliferation, and differentiation [54, 55]. Specifically, inhibition of PI3K-δ and PI3K-γ isoforms blocks mitogenic and survival within tumor cells, disrupts interaction with the tumor microenvironment, and restores antitumor immune responses. The PI3K δ/γ inhibitor duvelisib was evaluated in a phase I dose-escalation trial in 16 patients with R/R PTCL at a MTD of 75 mg twice daily on a 28-day cycle where it resulted in a 50% ORR with 3 CRs. The median PFS was 8.3 months, with activity demonstrated across a number of subtypes [56], and a phase II trial is underway (NCT03372057). Duvelasib is also being studied in combination with romidepsin and bortezomib in a parallel phase I study in patients with PTCL and CTCL. Duvelasib is given at 75 mg twice daily on days 1–28 on 28-day cycles with either romidepsin 10 mg/m² on days 1, 8, and 15 (arm A) or with bortezomib 1 mg/m² on days 1, 4, 8, and 11 (arm B) [56, 57]. These combinations show activity with ORR and CR rates of 55% and 27% for patients with PTCL treated on arm A, and 36% and 21%, respectively, in patients treated on arm B. The median PFS and OS were 8.8 months and 9.1 months for PTCL patients on arm A and 3.5 months and 9.3 months for patients on arm B. Of note, 65% of patients treated on arm A experienced grade 3 or higher adverse events (AEs) with neutropenia (18%) and elevated transaminases (15%) being the most frequent. Among patients treated on arm B, 45% experienced grade 3 or higher AEs with neutropenia (18%) occurring in more than 10% of patients. A phase IB dose-escalation study is being planned to examine the combination of romidepsin with the PI3K α/δ inhibitor copanlisib (NCT04233697). The PI3K-δ inhibitor YY-20394 is being evaluated in an ongoing phase I trial in patients with R/R PTCL (NCT04108325).

Everolimus is an oral agent that inhibits the mammalian target of rapamycin (mTOR) pathway and has been shown to strongly inhibit malignant T cell proliferation in vitro [58]. Single-agent everolimus given at 10 mg daily continuously has been studied in a phase II trial including 16 patients with R/R PTCL with a variety of subtypes, including 4 PTCL-NOS, 2 ALCL, and 1 each had extranodal NK/T cell, AITL, and precursor TLL lymphoma. Everolimus resulted in an ORR of 44% with a median PFS of 8.5 months and an overall survival of 10.2 months. Among responders, the median DOR was 8.5 months [58]. Dose reduction to 5 mg daily was required in 35% of patients.

Aurora A kinase (AAK) is a mitotic oncogenic serine/threonine kinase that plays an essential role in progression through the cell cycle during mitosis and has been shown to be upregulated in aggressive lymphomas [59‐61]. Alisertib is an oral AAK inhibitor that was studied in the SWOG1108 phase II trial which included 37 patients with R/R PTCL or transformed mycoses fungoides [62]. Patients received alisertib 50 mg twice daily for 7 days every 21-day cycle, resulting in a 30% ORR with 7% CRs, and median PFS and OS of 3 months and 8 months respectively [64]. Consistent with earlier phase I data, myelosuppression was common (in up to 32% of patients) and was the most common reason for dose reductions. The phase III Lumiere trial compared single-agent alisertib to investigator’s choice of single-agent of pralatrexate, gemcitabine, or romidepsin [63]. Alisertib showed similar results with an ORR of 33% with 16% CR, a median PFS of 2.7 months, and a median OS of 9.9 months. Based on preclinical data suggesting synergism [64], alisertib was studied in combination with romidepsin in a phase I trial of R/R aggressive lymphomas including 4 patients with PTCL. While the primary endpoint of the study was to demonstrate safety and tolerability, this combination resulted in disappointing results in these heavily pretreated PTCL patients, with no CRs or PRs [65].

Pralatrexate, a folate analogue metabolic inhibitor that selectively enters cells through reduced folate carrier type 1 (RFC-1), was studied in the pivotal multicenter phase II PROPEL trial [66]. Patients with R/R PTCL were treated with weekly pralatrexate 30 mg/m² infusions for 6 weeks in 7-week cycles. The response rate among the 109 evaluable patients was 29%, including 12 complete responses (11%) and 20 partial responses (18%), with a median DoR of 10.1 months. Median PFS and OS were 3.5 and 14.5 months, respectively. Pralatrexate received FDA’s approval for R/R PTCL in 2009.

The feasibility of adding BV to CHOP in first-line setting was evaluated in a phase 1 study with BV 1.8 mg/kg administered either sequentially with standard-dose CHOP (BV × 2 cycles, followed by CHOP × 6 cycles) or in combination with CHP (CHOP without vincristine) for 6 cycles in patients with mostly CD30-expressing ALCL. Responders received single-agent brentuximab vedotin for 8–10 additional cycles (for a total of 16 cycles) [68]. The ORR was 85% (CR 62%) with sequential treatment, and ORR was 100% (CR 88%) with combination treatment. Safety profile was manageable. Durable remission at 5 years was noted in 50% of patients without subsequent anti-cancer therapy [69]. Based on this encouraging phase 1 data, a global double-blind, randomized phase 3 study (ECHELON-2, NCT01777152) was initiated in 2013 comparing BV-CHP with standard CHOP in untreated CD30-positive PTCL (targeting 75% ALCL) [70], and randomized 452 patients. BV-CHP was associated with higher CR rate (68% vs 56%, p = 0.0066) and superior survival. Median PFS was 48.2 months in the BV-CHP group, significantly improved compared to 20.8 months in the CHOP group. In addition, BV-CHP reduced the risk of death by 34% compared with CHOP. Adverse events, including febrile neutropenia and peripheral neuropathy, were similar between groups. ECHELON-2 is the first randomized phase 3 study establishing the superiority of BV-CHP over CHOP in untreated PTCL, which led to FDA approval in November 2018 of BV-CHP as frontline therapy for CD30-positive PTCL. Although the ECHELON-2 study included non-ALCL cases such as PTCL-NOS, AITL, ATLL, and EATL (~ 30% enrollment, 136 total), their small sample sizes precluded sufficient power analysis.

Given the variable expression of CD52 in PTCL subtypes, a prospective multicenter trial evaluated the feasibility and clinical efficacy of the combination of alemtuzumab with CHOP regimen (CHOP-C) as the primary treatment for 24 patients with peripheral T cell lymphoma (PTCL) that included PTCL/NOS, AITL, ALK-negative ALCL, and EATL [71]. Patients received 8 CHOP courses, with alemtuzumab given at 30 mg subcutaneously at day 1 prior to CHOP given at standard 21-day cycle. Complete remission (CR) was achieved in 17 (71%) patients, 2-yr OS was estimated at 53% and 2-yr PFS at 48%. Despite promising CR rate, alemtuzumab-containing therapy was accompanied by substantial immunosuppression and infectious complications. Similar findings were noted in more intensive combinations of alemtuzumab plus either CHOP-14 (HOVON) [72] or DA-EPOCH (etoposide, prednisone, vincristine, cyclophosphamide, and doxorubicin) [73]. Twenty patients were treated on the phase 2 HOVON alemtuzumab-CHOP14 study, which showed ORR of 90%; CR 60%; 2-year OS and EFS at 55% and 27%, respectively; high rates of neutropenic fever (40%); and CMV reactivation (35%), as well as secondary EBV-related lymphoma (15%) [72]. Thirty patients were treated on the phase 1/2 NCI alemtuzumab with DA-EPOCH study. CR was achieved in 17 (57%) patients, and ORR was 83%, with median OS and PFS at 20.2 and 6.6 months, respectively. There were five treatment-related deaths on study due to infectious complications [73]. Phase 3 studies comparing the addition of alemtuzumab to CHOP14 versus CHOP14 alone in younger (ACT-1, NCT00646854) and elderly (ACT-2, NCT00725231) patients could not reach planned sample sizes due to low recruitment, and combined analysis of ACT-1 and ACT-2 studies of 252 patients showed no significant difference in EFS, PFS, and OS, while alemtuzumab-CHOP was associated with more infections.

Lenalidomide in combination with CHOP-based chemotherapy was evaluated in 2 prospective phase 2 studies; both showed unexpectedly modest CR and PFS rates and high discontinuation rates due to substantial toxicities. The T cell Consortium study combined lenalidomide given 10 mg on days 1–10 with standard-dose CHOEP (cyclophosphamide, doxorubicin, etoposide, vincristine, and prednisone) every 21-day cycle for 6 cycles followed by either upfront ASCT or lenalidomide maintenance (NCT02561273). The phase 2 efficacy analysis showed ITT ORR of 68% with CR of 48% and 1-year PFS and OS at 68% and 89%, respectively. Serious AEs (SAEs) and AEs included 5 treatment-related deaths and significant grade > 3 cytopenias [76]. Lenalidomide (25 mg/day on days 1–14) plus CHOP was studied in AITL elderly patients by the French LYSA group (NCT01553786) [77]. ITT CR in the Len-CHOP study was 43.6%, with a 2-year PFS rate of 42.3% and a 2-year OS of 60.1%. Discontinuation rate was high at 28% due to toxicities and disease progression. Mutational analysis demonstrated TET2 mutations in 49 cases (77%), RHOA^G17V mutations in 34 patients (53%), DNMT3A mutations in 20 (31%) patients, and IDH2 mutations in 14 (22%).

The antifolate agent pralatrexate was incorporated into the front-line setting alternating with CEOP (cyclophosphamide, doxorubicin, vincristine, and prednisone) in a phase II T cell Consortium trial [78]. Of 33 patients, 21 had PTCL-not otherwise specified (64%), 8 had AITL (24%), and 4 had ALCL (12%). Fifty-two percent of patients achieved a CR. The 2-year PFS and OS were 39% and 60%, respectively. Overall, this approach did not improve outcomes compared to historical data using CHOP.