In a pioneering breakthrough, researchers at Weill Cornell Medicine have unveiled unexpected insights into the cellular origins of Hodgkin lymphoma, a cancer predominantly affecting adolescents and older adults. This new understanding reframes Hodgkin lymphoma not merely as a disease characterized by unchecked cellular proliferation, but fundamentally as a disorder of arrested immune cell development. The study illuminates how the malignant Reed-Sternberg cells, distinctive for their “owl eyes” nuclear morphology, are actually immune cells caught in a liminal state—cells trapped midway through the differentiation process from B cells into plasma cells, thereby failing to complete their maturation.
Hodgkin lymphoma is relatively unique in its bimodal age distribution, peaking in teenagers aged 15 to 19 and adults over 55. Clinically, it presents primarily as painless swelling of lymph nodes located in the neck, chest, armpits, or groin. Advanced disease courses often necessitate aggressive therapies including chemotherapy and radiation. Despite significant advances in treatment, long-term toxicities remain a challenge, underscoring the need for targeted therapeutic strategies rooted in a deeper biological understanding of the disease.
The research team conducted comprehensive gene expression profiling of Hodgkin lymphoma samples derived from patients, alongside comparative analyses involving primary mediastinal B cell lymphoma (PMBL), a rarer lymphoma arising from related cellular origins. Their integrative approach revealed that the Reed-Sternberg cells exhibit a unique transcriptional landscape, distinct from typical B cells or other lymphoma cells, but notably resembling characteristics of plasma cell malignancies such as multiple myeloma. This suggests that the Hodgkin lymphoma cells are not simply B cells gone rogue, but cells arrested during plasma cell differentiation, possessing a hybrid identity that confers malignant properties.
Specifically, these malignantly transformed cells demonstrate a significant downregulation of classical B cell markers, signaling that they have lost typical B cell identity traits. Simultaneously, they engage gene programs typically activated in plasma cells, such as the unfolded protein response (UPR), which is critical for managing the cellular stress associated with producing large quantities of immunoglobulins. Intriguingly, although Hodgkin lymphoma cells trigger UPR pathways, they paradoxically lack the capacity to produce functional antibodies, indicating a survival adaptation to a state of chronic internal stress.
The UPR pathway’s aberrant activation suggests that malignant Hodgkin lymphoma cells continuously endure proteotoxic stress, potentially exploiting this mechanism to sustain their survival in a hostile microenvironment. This novel insight opens intriguing prospects for therapeutic interventions aimed at selectively disrupting UPR signaling, potentially undermining the cancer cells’ precarious state of equilibrium without impacting normal plasma cells.
Another striking discovery from the study sheds light on how Hodgkin lymphoma cells evade immune surveillance, a key barrier to effective anti-tumor immunity. Reed-Sternberg cells conspicuously suppress surface ligands from the SLAM family, including CD48, which are crucial for natural killer (NK) cells to recognize and kill malignant cells. The downregulation of these ligands hampers NK cell-mediated cytotoxicity, effectively cloaking the tumor cells from one of the immune system’s first lines of defense.
Moreover, the researchers observed a marked absence of NK cells within the tumor microenvironment itself, suggesting that Hodgkin lymphoma tumors may not only evade detection but actively repel these immune sentinels. This dual strategy of masking and exclusion highlights the sophisticated immune evasion tactics employed by Hodgkin lymphoma, enabling it to persist and thrive despite the innate immune system’s surveillance mechanisms.
Beyond evading innate immunity, Hodgkin lymphoma cells also utilize mechanisms to circumvent attack by T cells, the adaptive immune system’s main effectors. This dual arm immune evasion strategy facilitates tumor survival and progression, complicating therapeutic efforts that rely on immune-mediated tumor clearance. Understanding the molecular underpinnings of these immunoevasive properties offers critical opportunities to develop novel immunotherapies tailored to expose these malignant cells to immune destruction.
The study also identifies promising diagnostic biomarkers that could enable more precise differentiation of Hodgkin lymphoma from closely related lymphoma subtypes. For example, the PDIA6 protein, implicated in the UPR pathway and found to be specifically upregulated in Hodgkin lymphoma cells, emerges as a potential molecular signature. Such biomarkers hold immediate translational value, facilitating earlier and more accurate diagnosis, which is essential for guiding treatment decisions.
Commenting on the clinical potential of these findings, Dr. Ethel Cesarman, co-leader of the study, emphasizes the need for alternatives to conventional chemotherapy, which often results in debilitating long-term sequelae. Targeting the UPR pathway, given its selective activation in lymphoma cells, may represent a novel therapeutic avenue with fewer off-target effects, ultimately improving patient outcomes.
This landmark research advances the field’s comprehension of Hodgkin lymphoma by repositioning it as a disease rooted in developmental arrest rather than mere proliferation. It leverages cutting-edge molecular profiling to uncover the lineage and functional deficiencies of Reed-Sternberg cells, providing a conceptual framework that integrates cellular biology with clinical oncology. The implications for diagnostics, prognostics, and therapeutics are profound, promising to catalyze innovations in lymphoma care.
By elucidating how Hodgkin lymphoma cells hijack developmental pathways and evade immune destruction, this work sets the stage for future research efforts focused on disrupting these malignant processes. It exemplifies how a deeper understanding of cancer cell biology can directly inform the design of next-generation biomedical interventions, tailored to the unique vulnerabilities of these pathologic cells.
Ultimately, the study exemplifies the power of interdisciplinary collaboration, incorporating expertise in pathology, pediatrics, computational biology, and clinical oncology. Supported by multiple research grants and institutional partnerships, this work underscores the ongoing commitment to unraveling the complexities of cancer biology to drive meaningful clinical progress.
Subject of Research: Hodgkin lymphoma cellular origins and mechanisms of immune evasion
Article Title: Understanding the Origins of Hodgkin Lymphoma Cells Could Lead to Better Diagnostics
News Publication Date: 22-Apr-2026
Web References: https://www.nature.com/articles/s41408-026-01502-1#Ack1
Image Credits: National Cancer Institute
Keywords: Hodgkin lymphoma, Reed-Sternberg cells, B cell differentiation, plasma cells, unfolded protein response, immune evasion, natural killer cells, SLAM-family ligands, CD48, PDIA6, cancer diagnostics, lymphoma biology
Tags: adolescent Hodgkin lymphomaB cell to plasma cell maturationbimodal age distribution lymphomaHodgkin lymphoma cellular originsHodgkin lymphoma diagnostics advancementsimmune cell differentiation arrestlong-term chemotherapy toxicitieslymph node swelling symptomslymphoma gene expression profilingprimary mediastinal B cell lymphoma comparisonReed-Sternberg cell developmenttargeted Hodgkin lymphoma therapies
