Mécanistique de la commutation de classe des immunoglobulines et production de classes rares (IgE, IgA2 et pseudo-IgG) / Mecanistic of immunoglobulins class switch recombination and production of rare classes (IgE, IgA2 and pseudo-IgG)

Dalloul, Zeinab

26 November 2018

Le processus de la commutation de classe ou commutation isotypique (CSR) des gènes d’immunoglobulines caractérise les cellules de la lignée B et implique principalement les régions switch précédant les gènes constants au sein du locus IgH. Des jonctions entre la région switch donneuse Sμ et celle acceptrice Sx sont crées pendant ce processus. Plusieurs études ont démontré que le destin des cellules de la lignée B était largement modulé en fonction de la classe de l’immunoglobuline qu’elles produisent et en particulier selon les signaux transmis par leur BCR (qui peuvent par exemple pour la classe IgE, comporter des signaux pro-apoptotiques). Nous avons utilisé plusieurs modèles visant à l’étude de la physiologie et de la mécanistique du switch vers différentes classes de BCR et d’immunoglobulines peu exprimées. Nous avons cherché à forcer l’expression de l’isotype IgA2 grâce à un modèle transgénique dédié, dans le but d’approfondir les spécificités du signal BCR transduit par cet isotype en comparaison avec le BCR IgA1. En outre, et d’une façon très intéressante, nous avons découvert l’existence (jusqu’ici ignorée et masquée par les 4 autres sous-classes plus abondantes) d’une cinquième sous-classe d’IgG humaine, l’IgG5 qui est codé par un gène jusqu’ici faussement classifié pseudo-gène. Ainsi nous avons étudié les modalités d’expression du gène correspondant après un switch non-canonique,le répertoire normal des IgG5, leur représentation parmi les IgG humaines monoclonales ainsi que leurs fonctions immunitaires grâce à un IgG5 fabriquée artificiellement portant une activité anti-CD20 humaine. Enfin, nous avons testé des produits pharmaceutiques (RHPS4 : stabilisant des structures G-quadruplex au niveau d’ADN et JQ1 : inhibiteur des facteurs de transcription à bromodomaines), montrant leur capacité à retarder ou inhiber la commutation de classe in vitro mais aussi in vivo dans des souris allergiques. / The process of class switch recombination (CSR) or isotypic switching of immunoglobulin genes characterizes the B cell lineage and primarily involves switch regions preceding the constant genes within the IgH locus. Junctions between donor switch region Sμ and acceptor Sx are generated during this process. Several studies have shown that the fate of B cells is largely modulated according to the class of immunoglobulin they produce and in particular the signals transmitted by their BCR « for example for IgE, BCRs can combine proapoptotic signals. We used several relevant mouse models to study the physiological aspect and the B cell compartment after switching to IgA2 (a dedicated transgenic model expressing IgA2) since IgA2 conveys a membrane signal different from tht of IgA1. In addition, we tested two pharmaceuticals drugs(RHPS4: stabilizer of G-quadruplex structures at the DNA level and JQ1: inhibitor of bromodomain proteins) showed their ability to delay or inhibit class switching towards IgE in vitro but also in vivo in allergic mice. Interestingly, we also demonstrated the existence (till now ignored and maybe masked by the other 4 more abundant IgG subclasses) of a fifth subclass of human IgG, IgG5 which is encoded by a gene classified as a pseudo-gene. We studied the expression modalities of the corresponding gene after a non-canonical switch, the normal IgG5 repertoire, their representation among the monoclonal human IgGs as well as their immune functions through an artificially synthesited IgG5 with human anti-CD20 activity.

Cellules B

Immunoglobulines (Igs)

Commutation de classe (CSR)

Locus IgH

G-quadruplexe G4

Protéines de bromodomaines

B cells

Immunoglobulins (Igs)

Class switching (CSR)

IgH locus

G-quadruplex (G4)

Bromodomain proteins

615.37

Studies of B cell development and V(D)J recombination

Chovanec, Peter

January 2019

The process of generating the vast diversity of immunoglobulin receptors and secreted antibodies begins with the recombination of the joining (JH), diversity (DH) and variable (VH) genes in the immunoglobulin heavy chain locus. The ability to produce antibodies is restricted to the B cell lineage and is tightly regulated, starting with the temporal separation of the recombination process, in which DH-JH precedes VH-DHJH recombination. Successful recombination of both heavy and light chain loci results in the expression of an antigen receptor on the cell surface. Subsequent selection stages remove non‑functional and autoreactivity receptors from the final pool of antigen responding B cells that ultimately give rise to antibody secreting plasma cells. Understanding the complexity of the recombination processes and the diversity of the resulting antibody repertoire has been a major focus of academic and industrial research alike. Therapeutic monoclonal antibodies have seen many successful applications within the clinic and they constitute a billion-dollar industry. However, limitations therein have resulted in the emergence of antibody engineering approaches and the use of natural sources of alternative heavy chain only antibodies (HCAbs/nanobodies). The biotechnology company Crescendo Biologics has taken the highly desired characteristics of HCAbs a step further with the creation of a mouse platform capable of producing fully humanized HCAbs. The Crescendo platform presents a unique opportunity to expand our understanding of how mouse B cell development functions by exploiting the features of heavy chain only antibody production. Furthermore, the platform enables the expansion of our limited knowledge of the epigenetic mechanisms involved in the recombination of the human immunoglobulin heavy chain locus. Using flow cytometry, with dimensionality reduction analysis approaches, I investigated B cell development in the context of HCAbs. These studies revealed a previously uncharacterised developmentally intermediate B cell population. Due to ethical and availability limitations to studies of human bone marrow, the primary pre-selection human B cell repertoire has not been studied in detail. The isolation of several B cell developmental stages and the use of our novel DNA-based high-throughput unbiased repertoire quantification technique, VDJ-seq, allowed me to study recombination of the human IGH locus sequence and observe HCAb repertoire selection within the mouse environment. The adaptation of next generation sequencing techniques to antigen receptor repertoire quantification has provided an unprecedented insight into repertoire diversity and the alterations it undergoes during infection or ageing. Our VDJ-seq assay is unique in its ability to interrogate DNA recombinants. To expand its capabilities, I investigated several limitations of the technique, including mispriming and PCR/sequencing errors, and implemented experimental and bioinformatics solutions to overcome them, which included the creation of a comprehensive analysis workflow. Finally, I have developed and applied a novel network visualisation method for genome-wide promoter interaction data generated by promoter capture Hi-C. The availability of high quality human pluripotent stem cell datasets allowed me to utilise the new techniques to further our understanding of the dynamics of genome organisation during early human embryonic development. This visualisation approach will be directly applicable to understanding B cell development.

Study of position effect as a mechanism arising from chromosomal translocations in leukaemia

Papucci, Chiara

January 2015

The chromosomal translocation of t(14;18)(14q32;18q21) is a characteristic aberration of follicular lymphoma and Diffuse Large B cells lymphoma. By PCR, it was proved that the rearrangement of chromosomes 14 and 18 leads to an overexpression of BCL2, an anti-apoptotic protein, which is one of the factors responsible for the maturation of the diseases. The translocation involves the promoter region of IGH gene and the transcriptional unit of BCL2 gene. Previous studies carried out in Dr Tosi’s lab showed a looping out of the BCL2 gene from its chromosome territory in 15% of the nuclei analysed. This looping out could be possibly responsible for the transcriptional activity of the gene. A further relevant finding concerns the spatial distribution of the genes involved in the translocation in the interphase nuclei. In the Pfeiffer cell line, harbouring the t(14;18) rearrangement, the translocated BCL2 gene was positioned in the cell nuclei according to a bimodal distribution. One could speculate that the distribution in the periphery and in the centre of the nuclei could divide the Pfeiffer cell line in two different subpopulations, consequently from the transcriptional activity. These preliminary data set the ground for more experimental work to test whether genes associated with the nuclear interior were transcriptionally active as opposed to the genes positioned towards the nuclear periphery, transcriptionally inactive. The work here presented focuses on this investigation using RNA-DNA FISH (Fluorescence in situ hybridization). My work enabled the detection of IGH, BCL2 and t(14;18) genes along with their transcripts inside of the nuclei of Pfeiffer cell line. Contrary to what had been hinted by previous work, my results showed multiple nuclear positions of transcriptionally active IGH/BCL2 translocation. The result will need to be further supported by software analysis in order to define its specific nuclear position and to ensure the perfect localization of the genes inside each nucleus.

616.99

A FUNCTIONAL ANALYSIS OF THE 3’ REGULATORY REGION OF THE IMMUNOGLOBULIN HEAVY CHAIN GENE

Snyder, Andrew David

30 August 2016

No description available.

Biology

Biomedical Research

Environmental Health

Genetics

Health Sciences

Immunology

Molecular Biology

Toxicology

B-cell

IGHRR

IGH

immunoglobulin

CRISPR

hs1,2

immunoglobulin regulatory region

TCDD

dioxin

The IM-9 cell line: a model for evaluating TCDD-induced modulation of the polymorphic human hs1,2 enhancer within the 3' immunoglobulin heavy chain regulatory region

Chambers-Turner, Ruth C.

26 March 2010

No description available.

Biochemistry

Biology

Biomedical Research

Cellular Biology

Environmental Science

Immunology

Microbiology

Molecular Biology

Pharmacology

Toxicology

3'IgHRR

3'alpha regulatory region

IgH

TCDD

2

3

7

8-tetrachlorodibenzo-p-dioxin

AhR

aryl hydrocarbon receptor

B cell

mouse hs1

2 enhancer

human hs1

2 enhancer

polymorphic

DRE

BSAP

IM-9

CH12.LX

CpG

R848

LPS