Germinal center development & regulation
Responsable: C. Le Coz
High-affinity, isotype-switched antibody production following pathogen infection or vaccination relies upon germinal centers (GCs); a structure that orchestrates interactions between T follicular helper (Tfh) cells and GC B cells. As illustrated by autoimmune disease or immunodeficiency syndrome, dysregulated GCs can lead to multiple immunopathologies and require complex regulation. Therefore, in need of a gatekeeper, GCs employ T follicular regulatory cells (Tfr), a Treg subset, to promote antibody production toward microbe/vaccine recognition while preventing self-reactivity. Originally described as affiliated exclusively to thymically-derived Tregs, this dogma has recently been challenged by the description in human of induced Tfr cells, descending from Tfh cells, expressing vaccine-specific TCRs and acquiring regulatory function. This heretofore unappreciated heterogeneity within the Tfr cell pool has already created a shift in the way the community is investigating the Tfr compartment and will probably reshuffle pre-established Tfr biology concepts both in physiological and pathological contexts.
The long-term objective of our study is to understand the molecular pathways responsible for preserving GC integrity in humans and how their disruption contributes to inflammation and autoimmune diseases.
Our working model describes nTfr cells as the first type of Tfr cells to develop, raising early during the humoral response, localizing close to the T-B border, and driving Tfh differentiation pathway. Therefore, in an ageing context, an abnormal accumulation of nTfr cells negatively impacts Tfh cell frequency and function. In contrast, iTfr cells form later during the humoral response, once GCs are already shaped, reside within this structure and mediate B-Tfh cells relationship. Excessive pressure from nTfr cells on Tfh differentiation pathway not only affect B-cell help but will dilute vaccine specific iTfr pool and affect GC derive antibody output of elderly subjects.
Nos Projets
Human T follicular regulatory cell biology
The organization and composition of the immune system change over time and vary depending on the tissue being studied. These changes can result from aging and hormonal influences or from adaptations to the cellular environment and antigenic challenges. Therefore, in this axe, our goal is to dissect the ancestor, location, and phenotype of the Tfr compartment across different age and human tissues (blood, tonsils, lymph nodes, GALT, BALT): our previous study indicates that the Tfr compartment is composed of two cell types with two reactivities, identifiable by clonal affiliation, phenotype, and location within the follicle. Experiments determine if circulating and lymph node-resident nTfr/iTfr cells are, as in tonsils, clonally, phenotypically, and locally distinct.
The biology of Tfr compartments across various tissues and ages are elucidated using cutting-edge technologies, such as single-cell omics, multiplex microscopy, and multicolor flow cytometry-areas in which our team has developed significant expertise.
Unravel Tfr compartment function and development.
In this axe, we aim to elucidate the biogenesis and biological role of the human Tfr compartment.
- Human Tfr cell function
For many years, Tfr cell role on humoral response has been limited to the control of GC reaction magnitude and the emergence of autoreactive B cell. Recently, a study has extended the role of IL-10+ Tfr cells to a positive regulatory function by promoting antigen-specific B cell response. Our data showed a suppressive function of tonsillar nTfr and iTfr cells on T-cell proliferation and a beneficial effect of iTfr cell on follicular B-cell, further supporting the observation from these recent studies. Therefore, Tfr cell diverse functional properties could be related to their polyclonal affiliation. Using in vitro co-culture approach, we characterize and compare nTfr and iTfr cell role(s) during the three main GC reaction steps: initiation, maintenance, and regression.
- Human Tfr cell development
During our previous study, we found in the Tfr pool, clones shared with Treg and Tfh population. Using in-silico transcriptomic trajectory projections, pseudotime projection and RNA velocity, we showed human Tfh cells are not terminally differentiated but some of them are predicted to feed the Tfr pool through a CD25hi Tfh cell intermediary stage. To explore Tfr cell developmental trajectories predicted by bioinformatics, we are modellingthe formation of the Tfr compartment using tonsillar organoids, a structure mimicking a secondary lymphoid organ created from tonsillar cells. Alternatively, to explore a possible transcriptional signature of cells known to contribute to the Tfr pool, we are taking advantage of the single cell TCR repertoire and transcriptome libraries previously generated to track down Treg and Tfh cells sharing clones with Tfr cells.
Impact of T follicular cell homeostasis on defective humoral response
Although the GC reaction is closely monitored, some exterior parameters, such as age, genetics, and/or the presence of pathogens, can alter its output and integrity. Indeed, systemic lupus erythematosus (SLE) or rheumatoid arthritis (RA), multifactorial autoimmune diseases, are prototypical example of a GC autoantibody-driven autoimmune disease. On the other hand, age-declined immune system, also described as immuno-senescence, is associated with an increased vulnerability to infectious diseases and lower benefits of vaccination. Although ageing and SLE immune systems refer to two opposite types of defective immune responses, both immunopathologies are linked to changes happening within GCs impacting its efficacy and integrity. The forces affecting the efficiency, and the regulation of aged and SLE GCs are still under investigation.
In this axe, we aim to characterize Tfr compartment impact on GC integrity and output, in immunopathologic contexts.dysregulated GCs is the common trait of many immunopathologies. Follicular cell assessment from patients affected by two different types of defective immune responses, such as autoantibody production (SLE, RA) and poor vaccine response (ageing), will be used to determine the cellular and molecular environment necessary to mimic and correct the impairment using in vitro models.
Autres informations
Notre équipe
Publications
Le Coz C, Trofa M, Butler DL, Yoon S, Tian T, Reid W, et al. The common variable immunodeficiency IgM repertoire narrowly recognizes erythrocyte and platelet glycans. J Allergy Clin Immunol. 2024 Apr 29;S0091-6749(24)00418-4.
Romberg N, Le Coz C. Common variable immunodeficiency, cross currents, and prevailing winds. Immunol Rev. 2023 Nov 28. doi: 10.1111/imr.13291. PMID: 38014621 (Review)
Le Coz C*, Oldridge DA, Herati RS, De Luna N, Garifallou J, Cruz Cabrera E, Belman JP, Pueschl D, Silva LV, Knox AVC, Reid W, Yoon S, Zur KB, Handler SD, Hakonarson H, Wherry EJ, Gonzalez M, Romberg N*. Human T follicular helper clones seed the germinal center-resident regulatory pool. Sci Immunol. 2023 Apr 14;8(82):eade8162. doi: 10.1126/sciimmunol.ade8162. Epub 2023 Apr 7. PMID: 37027481 (*co- corresponding author)