Moving things forward in Hodgkin lymphoma

Introduction

Classic Hodgkin lymphoma (HL) is a rather rare cancer of the lymphoid system and clinically presents with swollen lymph nodes or symptoms due to organ involvement of advanced-stage disease. It is one of the most common malignancies in young adults but occurs at all ages. Over the recent decades, a growing incidence in older people between 70 and 80 years of age in addition to the stable peak between 20 and 30 years of age was observed¹. In Western countries, HL occurs at an incidence of 2.5 new cases per 100,000 people per year, resulting in an expected 18,525 cases in Europe annually. Owing to high cure rates with risk-adapted first-line therapy, prevalence is high and an estimated 208,805 people were living with HL in the US in 2015².

Depending on disease extent and presence of constitutional symptoms such as fevers, night sweats, or weight loss, HL is classified as early-stage favorable, early-stage unfavorable, and advanced-stage disease for the purpose of treatment allocation³. Cure rates with multi-agent chemotherapy and often consolidative radiation therapy (RT) are high with long-term remission rates of 80% to 90%, depending on risk group, age, and treatment^4–7. In patients with primary progressive or refractory (1 to 3% of cases, depending on treatment regimen) as well as relapsed disease, high-dose chemotherapy (HDCT) followed by autologous stem cell transplantation is administered if feasible and can result in long-term remission in up to 50% of cases⁸. More recently, several targeted agents were investigated in this setting and the antibody-drug conjugate brentuximab vedotin (BV) and the checkpoint inhibitors nivolumab and pembrolizumab were approved for relapsed/refractory HL (rrHL)^9–11.

Despite reductions of intensity of both chemotherapy and RT in recent years, therapy-related short- and long-term morbidity constitutes considerable sequelae and these side effects surmount HL mortality over the years¹². Besides organ damage such as pulmonary or cardiovascular disease as well as infertility, second cancers and long-term fatigue are of particular clinical relevance to patients and caregivers^13–15. To minimize these complications, a major goal of current research is to further refine first-line treatment to develop equally effective but less intensive strategies. Ideally, those therapeutic approaches would also be feasible for the growing population of older or frail patients for whom prognosis is less favorable^16,17.

The present review summarizes recent advances in understanding and the current approach to managing HL. We also address remaining challenges and outline ongoing as well as future efforts to move things forward in HL over the next years.

Hodgkin lymphoma biology

Characterized by a paucity of the malignant Hodgkin and Reed–Sternberg (HRS) cells in an abundant (micro)environment of immune cells, HL is very distinct from most other cancers and lymphomas¹⁸. The B-cell precursor heritage of HRS cells was long acknowledged, whereas a critical influence of immune checkpoint inhibition via the programmed death 1 (PD1) and PD1-ligand (PD-L1) was only recently reported¹⁹. Owing to amplification or copy gain of 9p24.1²⁰ or mediated by Epstein–Barr virus (EBV) infection²¹, HRS cells frequently express PD-L1 and thereby evade a sustained anti-tumor response of the patients’ immune system. In addition, HRS cells frequently lack major histocompatibility class I (MHC I) expression because of mutations of beta-2-microglobulin (β2M)²². The HL microenvironment is characterized predominantly by T and natural killer cells as well as macrophages, and PD-1 expression occurs in the former²³. The latter are often PD-L1⁺ and associated with inferior outcomes with conventional therapies^24,25. A very recent characterization of tumor-associated T cells via a customized time-of-flight mass cytometry (CyTOF) revealed the presence of PD-1⁺ CD4⁺ effector and PD-1⁻ CD4⁺ regulatory T cells as potential complementary mechanisms of local immunosuppression²⁶. This rapidly growing understanding of the tumor composition is complemented by the possibility to identify and track cell-free tumor DNA in the blood²⁷. Although this technique potentially allows non-invasive monitoring of disease activity, it also constitutes the possibility to evaluate the genetic background of HL, which earlier was compromised by the low tumor cell content in biopsies. In summary, recent studies were able to shed light on the distinct biology underlying HL which will help to further develop targeted therapies and synergistic therapeutic concepts.

Recent developments in first-line treatment

Drugs beyond conventional chemotherapy

Over many decades, no new drugs were approved for the treatment of HL. That changed in 2011, when the anti-CD30 antibody drug conjugate BV was approved for the treatment of rrHL on the basis of a pivotal phase II trial showing an overall response rate (ORR) of 75% and complete response rate (CRR) of 34%¹⁰. Recent follow-up analyses revealed sustained remissions in patients achieving a CR with five-year PFS of 52%. Interestingly, 9% of all patients maintained a CR even without consolidative stem cell transplantation (SCT)⁴⁰.

To improve efficacy of ABVD in patients with advanced-stage HL, a combination of BV and AVD was investigated in the company-sponsored randomized phase III ECHELON-1 trial: With a superior two-year modified PFS of 82.1% versus 77.1%, 6x BV-AVD was considered superior to 6xABVD, but more mature follow-up or conventional PFS data have not yet been reported and concerns have been expressed over the risk-to-benefit ratio of BV-AVD given the higher toxicity of the novel regimen^41,42. In patients with early-stage HL, consolidative therapy with BV instead of RT after systemic therapy with ABVD was investigated in a phase II trial and associated with one-year PFS and OS rates of 91% and 95%, respectively, in an early analysis⁴³. A sequential approach with BV prior to and after AVD in elderly patients with treatment-naïve HL was tolerable and resulted in two-year PFS and OS rates of 84% and 93%, respectively⁴⁴.

More recently, the two checkpoint inhibitors nivolumab and pembrolizumab targeting PD1 on exhausted T and other immune cells were approved for rrHL. Nivolumab and pembrolizumab showed ORRs of 69% and 65%, respectively, and a CRR of 16% with long-lasting responses in patients achieving a partial remission (PR) in the pivotal phase II trials^9,11. Correlative studies revealed the prognostic relevance of PD-L1 and MHC II expression by HRS cells, shedding light on the mechanisms involved in responses in a heavily pretreated patient population⁴⁵. While increased PD-L1 expression was associated with improved PFS, patients with less PD-L1 expression benefited from nivolumab and hence checkpoint inhibition is administered irrespective of the expression profile. Early data of an ongoing trial investigating the combination of nivolumab with BV in rrHL show an ORR of 85% and CRR of 65% while, despite manageable infusion-related reactions, tolerability was good⁴⁶. In addition, the first results without relevant follow-up were recently reported for the combination of nivolumab and AVD in advanced-stage HL: Of 51 patients, 90% were able to complete the planned treatment with 4x nivolumab followed by 6x Nivo-AVD, and the ORR was 84% with a CRR of 67% by independent review committee⁴⁷.

In light of the changing therapeutic landscape, other agents such as bendamustine or lenalidomide experience a revival and—since they proved to be considerably active in rrHL— are increasingly used in clinical practice^48,49. In addition, drugs originally approved for other hematological cancers, such as the histone deacetylase inhibitors panobinstat or mocetinostat or the inhibitor of PI3Kδ idelalisib, have been investigated in rrHL with relevant efficacy and manageable toxicity^50–52. A welcomed side effect of the growing armory of effective drugs is the possibility to conduct both autologous and allogeneic SCT increasingly in patients with at least PR, which is associated with a more favorable prognosis³. Initial reports raised concerns due to toxicity and mortality associated with high-grade graft-versus-host disease associated with allogeneic stem cell transplantation (alloSCT) after reinduction therapy with an anti-PD1⁵³. More recent data indicate that alloSCT is feasible and associated with high CRR and prolonged remissions. The previously postulated prognostic impact of time between last dose of the anti-PD1 antibody could not be confirmed, and data from larger series are still unavailable⁵⁴.

Chimeric antigen receptor (CAR) T cells were recently approved for the treatment of other hematologic cancers such as acute lymphoblastic leukemia or B-cell non-HL. Two early-phase trials very recently reported manageable toxicities after infusion of autologous anti-CD30 CAR T cells in patients with rrHL. Investigators from Houston reported two patients with sustained CR (CRR of 29%) and stabilization of disease (SD) in another two of the seven patients treated⁵⁵. In a Chinese trial, PR was observed in seven and SD in six among 18 patients treated without any CRs documented yet⁵⁶. Aimed at the EBV antigen latent membrane proteins, another CAR construct from Houston was tolerable and effective as adjuvant or re-induction therapy in patients with EBV-associated lymphoma⁵⁷. Another construct is targeting CD19 in the HL tumor microenvironment and on circulating CD19-positive HRS precursor cells and among four patients treated, one CR and one PR with consecutive progressive disease were observed⁵⁸. Promising preclinical activity was additionally reported for CARs targeting CD123 to affect both the HRS cells and microenvironment⁵⁹.

Selected ongoing first-line trials

While numerous phase II trials investigate various combinations of novel agents with conventional chemotherapy or each other in rrHL, the trial landscape is scarcer in the first-line setting. Investigating innovative therapies for these patients is challenging since current approaches bear mostly excellent long-term outcome. Decreasing intensity within the controlled setting of prospective trials previously resulted in significantly inferior disease control. However, an impaired OS was not reported and this was likely due to effective salvage therapies and no increase in late reoccurrences of HL observed so far^4,31,60.

To improve results in patients with early-stage unfavorable HL without exposing them to the toxicity of “2+2”, two ongoing investigator-initiated phase II trials investigate innovative strategies. In the randomized GHSG NIVAHL trial, patients receive the combination of nivolumab and AVD as either 4xNivo-AVD or 4x nivolumab + 2xNivo-AVD + 2xAVD, each followed by consolidative 30 Gy IS-RT (ClinicalTrials.gov Identifier: NCT03004833). A combination of AVD with BV is investigated in a US-based trial with a focus on consolidative RT (ClinicalTrials.gov Identifier: NCT01868451). Assigned to one of four different cohorts, patients will receive 30 Gy IS-RT, 20 Gy IS-RT, 30.6 Gy consolidation volume RT, or no RT if PET negativity is achieved after 4xBV-AVD.

In advanced-stage disease, the multinational randomized phase III trial HD21 is comparing a modified BEACOPP-regimen incorporating BV, dacarbazine, and dexamethasone instead of bleomycin, vincristine, procarbazine, and prednisolone (BRECADD)⁶¹ versus BEACOPP_escalated. The trial is aiming to show non-inferiority in terms of efficacy and superiority in terms of treatment-related morbidity (ClinicalTrials.gov Identifier: NCT02661503), thereby better balancing risk and benefits of an intensified first-line treatment. As the CHOP (cyclophosphamide, doxorubicin, prednisone, and vincristine) regimen is well tolerated in elderly patients with non-HL⁶², the combination of BV with a CHOP-like regimen is being investigated in the phase-II B-CAP trial for elderly patients with advanced-stage HL (ClinicalTrials.gov Identifier: NCT02191930).

Future perspectives

First-line treatment of HL with multi-agent chemotherapy and often consolidative RT is well established and results in cure in the majority of patients eligible for intensive therapies. Nevertheless, prognosis is less favorable in frail or older patients, and long-term side effects such as second cancers, organ damage, or fatigue as well as rrHL constitute considerable sequelae. The approval of modern drugs such as BV, nivolumab, and pembrolizumab for rrHL allow ongoing and future research to develop at least equally effective but less toxic therapies. Increasing understanding of PET imaging also as a potential prognostic marker by assessment of the metabolic tumor volume allows increased patient stratification and individualization of the therapeutic sequence. A growing understanding of the underlying biology, as well as the possibility to evaluate genetic alterations and monitor activity of disease by cell-free tumor DNA, additionally helps in doing so. From this point forward, it is crucial to keep in mind the currently achieved outcomes with conventional approaches. Carefully refining HL therapy meeting the needs and primary goals of affected patients is challenging, and ideally changes in clinical routine should be informed by evidence from randomized phase III trials.

Abbreviations

ABVD, doxorubicin, bleomycin, vinblastine, dacarbazine; alloSCT, allogeneic stem cell transplantation; AVD, doxorubicin, vinblastine, dacarbazine; BEACOPP_escalated, bleomycin, etoposide, doxorubicin, cyclophosphamide, vinblastine, procarbazine, prednisone; BRECADD, brentuximab vedotin, etoposide, cyclophosphamide, doxorubicin, dacarbazine, dexamethasone; BV, brentuximab vedotin; CAR, chimeric antigen receptor; CHOP, cyclophosphamide, doxorubicin, prednisone, and vincristine; CR, complete response; CRR, complete response rate; EBV, Epstein–Barr virus; EN, extra-nodal; HL, Hodgkin lymphoma; HRS, Hodgkin and Reed–Sternberg; IF-RT, involved-field radiation therapy; IN-RT, involved-node radiation therapy; IS-RT, involved-site radiation therapy; LMM, large mediastinal mass; MHC, major histocompatibility class; Nivo, nivolumab; ORR, overall response rate; OS, overall survival; PD-1, programmed-death receptor 1; PD-L1, programmed-death receptor 1 ligand; PET, ¹⁸F-FDG positron emission tomography; PFS, progression-free survival; PR, partial remission; RF, risk factor; rrHL, relapsed or refractory Hodgkin lymphoma; RT, radiation therapy; SCT, stem cell transplantation; SD, stabilization of disease