Role of epigenetic regulator KMT2D inactivation in follicular lymphoma development

Les lymphomes sont des cancers du système immunitaire touchant majoritairement les ganglions. Le lymphome folliculaire est une maladie fréquente d’évolution lente. Au cours de cette maladie les cellules tumorales prolifèrent de façon anormale en s’accumulant dans les ganglions. Malgré les progrès thérapeutiques effectués, il s’agit d’une maladie incurable et chronique caractérisée par des phases de rémission plus ou moins longues. Notre travail a consisté à étudier le rôle de la mutation génétique la plus fréquente dans ce type de tumeur conduisant à l'inactivation d’un gène suppresseur de tumeur appelé KMT2D, codant pour une enzyme impliquée dans la régulation de l’expression des gènes. Ce travail s’inscrit dans un effort plus large visant à identifier le talon d’Achille de ce type de cancer afin de développer des traitements innovants. Nous montrons que cette mutation est non seulement associée à la dérégulation du programme d’expression génique soutenant le processus de cancérisation, mais aussi à la rééducation du système immunitaire favorisant la croissance tumorale.Lymphomas are cancers of the immune system that mainly affect the lymph nodes. Follicular lymphoma is a common disease that progresses slowly. During this disease, tumor cells proliferate abnormally and accumulate in the lymph nodes. Despite remarkable advances in treatment, FL remains a significant clinical challenge and a cure for FL has remained elusive. The aim of my thesis was to study the role of the most frequent genetic mutation in this type of tumor leading to the inactivation of a tumor suppressor gene called KMT2D, encoding an enzyme involved in gene expression regulation. This work is part of a broader effort to identify the Achilles heel of this type of cancer in order to develop innovative treatments. We show that this mutation is associated not only with the deregulation of the gene expression program supporting the carcinogenesis but also with the re-education of the immune system that promotes tumor growth

Human B Lymphomas Reveal Their Secrets Through Genetic Mouse Models

International audienceLymphomas are cancers deriving from lymphocytes, arising preferentially in secondary lymphoid organs, and represent the 6th cancer worldwide and the most frequent blood cancer. The majority of B cell Non-Hodgkin lymphomas (B-NHL) develop from germinal center (GC) experienced mature B cells. GCs are transient structures that form in lymphoid organs in response to antigen exposure of naive B cells, and where B cell receptor (BCR) affinity maturation occurs to promote B cell differentiation into memory B and plasma cells producing high-affinity antibodies. Genomic instability associated with the somatic hypermutation (SHM) and class-switch recombination (CSR) processes during GC transit enhance susceptibility to malignant transformation. Most B cell differentiation steps in the GC are at the origin of frequent B cell malignant entities, namely Follicular Lymphoma (FL) and GCB diffuse large B cell lymphomas (GCB-DLBCL). Over the past decade, large sequencing efforts have provided a great boost in the identification of candidate oncogenes and tumor suppressors involved in FL and DLBCL oncogenesis. Mouse models have been instrumental to accurately mimic in vivo lymphoma-specific mutations and interrogate their normal function in the GC context and their oncogenic function leading to lymphoma onset. The limited access of biopsies during the initiating steps of the disease, the cellular and (epi)genetic heterogeneity of individual tumors across and within patients linked to perturbed dynamics of GC ecosystems make the development of genetically engineered mouse models crucial to decipher lymphomagenesis and disease progression and eventually to test the effects of novel targeted therapies. In this review, we provide an overview of some of the important genetically engineered mouse models that have been developed to recapitulate lymphoma-associated (epi)genetic alterations of two frequent GC-derived lymphoma entities: FL and GCB-DLCBL and describe how those mouse models have improved our knowledge of the molecular processes supporting GC B cell transformation

The Premalignant Ancestor Cell of t(14;18)+ Lymphoma

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Human germinal center transcriptional programs are de-synchronized in B cell lymphoma

International audienceMost adult B cell lymphomas originate from germinal center (GC) B cells, but it is unclear to what extent B cells in overt lymphoma retain the functional dynamics of GC B cells or are blocked at a particular stage of the GC reaction. Here we used integrative single-cell analysis of phenotype, gene expression and variable-region sequence of the immunoglobulin heavy-chain locus to track the characteristic human GC B cell program in follicular lymphoma B cells. By modeling the cyclic continuum of GC B cell transitional states, we identified characteristic patterns of synchronously expressed gene clusters. GC-specific gene-expression synchrony was lost in single lymphoma B cells. However, distinct follicular lymphoma-specific cell states co-existed within single patient biopsies. Our data show that lymphoma B cells are not blocked in a GC B cell state but might adopt new dynamic modes of functional diversity, which opens the possibility of novel definitions of lymphoma identity

Single-Cell Longitudinal Characterization of FL Heterogeneity and Residual Disease in the Bone Marrow from Low-Tumor Burden FL Enrolled in the Flirt Clinical Trial

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Real-Word Experience of CAR T-Cells in Patients with Relapsed/Refractory Follicular Lymphoma : A Descart Registry Analysis from the Lysa

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Immunomodulatory drugs in multiple myeloma: Impact of the SCARMET (Self CARe and MEdication Toxicity) educational intervention on outpatients' knowledge to manage adverse effects.

Long-term multiple myeloma therapy by immunomodulatory drugs (IMiDs) raises the question of management of adverse effects. The aim of this study is to assess the impact of an educational session for patients on the acquisition of knowledge to manage hematologic and thromboembolic adverse effects of IMiDs. In this prospective single-center study, patients attended an educational session with a hospital clinical pharmacist and a nurse. The primary endpoint was the patient's level of knowledge for the management of IMiDs adverse effects, assess with a dedicated questionnaire administered before the session then 1 and 6 months after. Assessment of knowledge was combined with self-assessment of certainty. The secondary endpoints were adherence and IMiD treatment satisfaction. 50 patients were included. Patient knowledge increased at 1 month (p<0.001) despite a loss of knowledge at 6 months (p<0.05). Six months after the educational intervention, the number of patients with skills considered satisfactory by the pharmacist and nurse increased (p<0.01). Most patients showed satisfactory adherence, with medication possession ratio ≥ 80%. The Self CARe and MEdication Toxicity (SCARMET) study highlighted the impact of multidisciplinary follow-up in multiple myeloma patients to improve knowledge of toxicity self-management

A Phase 1 Study of PIT565, a First-in-Class, Anti-CD3, Anti-CD19, Anti-CD2 Trispecific Antibody in Patients with Relapsed and/or Refractory B-Cell Malignancies

Background and Significance: There is an unmet therapeutic need for patients with relapsed and/or refractory (R/R) B-cell non-Hodgkin lymphoma (B-NHL) and R/R B-cell acute lymphoblastic leukemia (B-ALL) who have failed multiple lines of therapy. PIT565 is an investigational, first-in-class, immunoglobulin G-like, trispecific antibody that targets CD19 on malignant B cells while engaging CD3 and CD2 (a costimulatory receptor) on T cells, leading to redirected T-cell cytotoxicity toward CD19-positive malignant B cells. CD2 signaling prevents transcriptional changes characteristic of exhaustion during persistent T-cell receptor stimulation of CD8 T cells. Furthermore, the loss of CD2 ligand, CD58, on tumor cells has been shown to mediate resistance to the antitumor activity by T cell-redirecting therapies, confirming the importance of CD2 activation in T cells. Findings from preclinical studies suggest that PIT565 mediates more potent and sustained antitumor T-cell responses compared with CD3 bispecifics (Lu H, ASH 2022). Study Design and Methods: This is an open-label, phase 1, multicenter study of PIT565 in patients with R/R B-NHL and R/R CD19-positive B-ALL who have relapsed/failed to respond to ≥2 lines of prior therapy (including an anti-CD20 monoclonal antibody-containing chemotherapy combination regimen for patients with R/R B-NHL) (NCT05397496). The study is ongoing with plans to enroll approximately 140 patients in Belgium, France, Israel, Italy, Japan, Singapore, Spain, and the USA. Eligible patients are ≥18 years with an Eastern Cooperative Oncology Group performance status ≤2 and have at least one bi-dimensionally measurable nodal lesion or one bi-dimensionally measurable extranodal lesion as measured via positron emission tomography-computed tomography for R/R B-NHL, and/ or morphologic disease in the bone marrow (³5% blasts) for R/R B-ALL. Patients with contraindication to tocilizumab; history of other malignant disease; active central nervous system involvement; autoimmune disease (other than patients with vitiligo, hypothyroidism only requiring hormone replacement, or psoriasis not requiring systemic treatment or conditions not expected to recur); or receiving systemic treatment with any immunosuppressive medication are not eligible. During the dose escalation part of the study, PIT565 is administered to patients with R/R B-NHL (Group A) and patients with R/R B-ALL (Group B). During the dose-expansion part, PIT565 is administered to patients with R/R large B-cell lymphoma (LBCL) who have received CD-19-directed chimeric antigen receptor (CAR)-T therapy (Group A1); patients with R/R LBCL who have not received CAR-T therapy (Group A2); and patients with R/R B-ALL (Group B1). PIT565 is administered either once weekly (Q1W) or once every 2 weeks (Q2W) with and without a priming dosing. Routes of administration (intravenous [IV] or subcutaneous [SC]) are explored in the dose-escalation phase. Patients initially receive PIT565 IV Q1W over a 28-day cycle. Q2W treatment in a 28-day cycle is explored if supported by preliminary pharmacokinetics (PK), pharmacodynamics, efficacy, and safety findings. The primary objective is to assess safety (including dose-limiting toxicities) and tolerability, and to identify the maximum tolerated dose (MTD) and/or recommended dose (RD), schedule, and route of administration for each indication. Secondary objectives include evaluation of preliminary antitumor activity (overall response rate, complete response rate, best overall response, duration of response, overall survival, and progression-free survival for B-NHL or event-free survival for B-ALL), assessment of PK and immunogenicity of PIT565 in R/R B-NHL and R/R B-ALL. The dose escalation phase is guided by an adaptive Bayesian logistic regression model following the escalation with overdose control principle. The MTD and/or RD are further explored during the dose-expansion phase