Refine
Has Fulltext
- yes (2)
Is part of the Bibliography
- yes (2)
Document Type
- Doctoral Thesis (2) (remove)
Language
- English (2) (remove)
Keywords
- Rituximab (2) (remove)
B cells play diverse roles in the immunopathogensis of autoimmune diseases several approaches targeting B cell directly or indirectly are in clinical practice in the treatment of autoimmunity. In this regard, temporal B cell depletion by rituximab (anti CD20 antibody) is being appreciated and gaining more importance in recent years. To date, little is known about the regeneration profile of B cells following B cell depletion. We wanted to investigate the early replenishing B cells and examine the dynamic changes in the repertoire. we studied the immunoglobulin receptor (IgR) modulation of Ig-VH4 genes as representative of the heavy chain family. Five patients were included in the study and therapy induced alterations were assessed. Three time points namely before therapy, early regeneration phase (ERP- the early time point during regeneration where just above 1% B cells were found in the peripheral lymphocyte pool) and later regeneration phase (LRP- which commenced 2-3 months following ERP) were chosen. In three patients (A-C), Ig-VH4 genes were amplified from total genomic DNA during the above-mentioned all time points and in another two patients (D and E), Ig genes during ERP were studied by single cell amplification technique. Firstly, B cell regeneration followed the characteristic regeneration pattern as reported by several groups, with a predominant circulation of CD38hi expressing plasma cells and immature B cells in the ERP. During LRP, the proportion of these cells reduced relatively and the levels of naïve B cells rose gradually. On a molecular level, Ig-VH4 variable gene usage prior and post B cell depletion was determined and it was noticed that a diverse set of Ig-VH4 genes were employed in the repertoire before and after therapy. Mini gene segments such as VH4-34 and VH-4-39, which were reported to be connected with autoimmunity, were over expressed in the B cell repertoire before therapy. Profound changes were noticed in the early reemerging repertoire with a relatively increased population of intensely mutated B cells. These B cells acquired >=9 mutations in the Ig genes. Immunophenotyping with specific surface markers revealed that these highly mutated B cells evolve from the isotype-switched memory compartment especially the plasma cells. To support the hypothesis that the highly mutated B cells observed during ERP were plasma cells we carried out single cell amplification of individual plasma cells in another two patients during ERP and compared the mutational load, which remained similar. Actually plasma cells do not express CD20 on their surface and are not eliminated by rituximab therapy. However they were not observed in the peripheral blood following B cell depletion. The earliest time point when plasma cells are found again in peripheral circulation is the early recovery period (ERP). Therefore, it was intriguing to ascertain if the plasma cells were also modulated by rituximab therapy although they were not directly targeted by the therapy. We investigated if there is a therapy mediated mutational modulation of the plasma cells though these are not directly targeted by the therapy. We examined the confinement of mutations to the pre-defined RGYW/WRCY hotspot motifs (R=purine, Y=pyrimidine, W=A/T) in the plasma cells, which provides information on the involvement of T cells in B cell somatic hypermutation (SHM). Plasma cells before rituximab manifested the characteristics of active disease, which was revealed by restricted mutational targeting to the RGYW/WRCY motifs. The reemerging plasma cells during ERP had an increased targeting of the RGYW/WRCY motifs which indicated for a more pronounced T cell mediated B cell mutations which is the scenario observed in the healthy subjects. To further support the hypothesis of rituximab-mediated plasma cell modulation, we delineated the replacement to silent mutations ratio (R/S) in the hypervariable regions (CDRs) of the plasma cell Ig sequences. Within our study, the mean R/S ratio in the plasma cell CDRs of the patient group was relatively low (1.87) before rituximab treatment and interestingly this ratio increased significantly in the recirculating plasma cells to values of 2.67 and 3.60 in ERP and LRP status respectively. The increase in R/S ratios in reemerging plasma cells can be interpreted as a shaping of the Ig-repertoire by positive antigen selection as seen in healthy individuals. To conclude, our study demonstrates temporal B cell depletion by rituximab therapy seems to modulate also the plasma cell compartment, which is not directly targeted by the therapy. Modulation of plasma cells in RA could be also used as a potential biomarker in studying the effective response in RA treatment. This needs to be further explored to gain deeper insights into the underlying processes, which may be influenced by future therapies.
Although the role of B-cells in autoimmunity is not completely understood, their importance in the pathogenesis of autoimmune diseases has been more appreciated in the past few years. It is now well known that they have roles in addition to (auto) antibody production and are involved by different mechanisms in the regulation of T-cell mediated autoimmune disorders. The evolution of an autoimmune disease is a dynamic process, which takes a course of years during which complex immunoregulatory mechanisms shape the immune repertoire until the development of clinical disease. During this course, the B-cell repertoire itself is influenced and a change in the distribution of immunoglobulin heavy and light chain genes can be observed. B-cell depletive therapies have beneficial effects in patients suffering from rheumatoid arthritis (RA), highlighting also the central role of B-cells in the pathogenesis of this disease. Nevertheless, the mechanism of action is unclear. It has been hypothesised that B-cell depletion is able to reset deviated humoral immunity. Therefore we wanted to investigate if transient B-cell depletion results in changes of the peripheral B-cell receptor repertoire. To address this issue, expressed immunoglobulin genes of two patients suffering from RA were analysed; one patient for the heavy chain repertoire (patient H), one patient for the light chain repertoire (patient L). Both patients were treated with rituximab, an anti-CD20 monoclonal antibody that selectively depletes peripheral CD20+ B-cells for several months. The B-cell repertoire was studied before therapy and at the earliest time point after B-cell regeneration in both patients. A longer follow-up (up to 27 months) was performed in patient H who was treated a second time with rituximab after 17 months. Heavy chain gene analysis was carried out by nested-PCR on bulk DNA from peripheral B-cells using family-specific primers, followed by subcloning and sequencing. During the study, patient H received two courses of antibody treatment. B-cell depletion lasted 7 and 10 months, respectively and each time was accompanied by a clinical improvement. Anti-CD20 therapy induced two types of changes in this patient. During the early phase of B-cell regeneration, we noticed the presence of an expanded and recirculating population of highly mutated B-cells. These cells expressed very different immunoglobulin VH genes compared before therapy. They were class-switched and could be detected for a short period only. The long-term changes were more subtle. Nevertheless, characteristic changes in the VH2 family, as well as in specific mini-genes like VH3-23, 4-34 or 1-69 were noticed. Some of these genes have already been reported to be biased in autoimmune diseases. Also in autoimmune diseases, in particular in RA, clonal B-cells have been frequently found in the repertoire. B-cell depletion with anti-CD20 antibody resulted in a long term loss of clonal B-cells in patient H. Thus, temporary B-cell depletion induced significant changes in the heavy chain repertoire. For the light chain gene analysis, the repertoire changes were analysed separately for naive (CD27-) and memory (CD27+) B-cells. Individual CD19+ B-cells were sorted into CD27- and CD27+ cells and single cell RT-PCR was performed, followed by direct sequencing. During the study, patient L received one course of antibody treatment. B-cell depletion lasted 10 months and the light chain repertoire was studied before and after therapy. Before therapy, some differences in the distribution of VL and JL genes were observed between naive and memory B-cells. In particular, the predominant usage of Jk-proximal Vk genes by the CD27- naive B-cells indicated that the receptor editing was less frequent in this population compared to memory cells. In VlJl rearrangements also, some evidence for decreased receptor editing was noticed, with the overrepresentation of the Jl2/3 gene segments. The CDR3 regions of naive and memory cells showed different characteristics: the activity of the terminal deoxynucleotidyl transferase and exonuclease in Vl(5’) side was greater in memory cells. Also in the light chain repertoire, we observed some changes induced by the B-cell depletive therapy. There was a tendency of a less frequent usage of Jk-proximal Vk genes in the naive population. Some Vl genes, previously described in autoimmune diseases and connected to rheumatoid factor activity, such as 3p, 3r, 1g, were not found after therapy. The different characteristics of the CDR3 regions of VlJl rearrangements were not observed anymore. Very significantly, the ratio Vk to Vl was shifted toward a greater usage of Vk genes in the naive population after therapy. Taken together, these results indicate that therapeutic transient B-cell depletion by anti-CD20 antibody therapy modulates the immunoglobulin gene repertoire in the two RA patients studied. Measurable changes were observed in the heavy chain as well as in the light chain repertoire, which may be relevant to the course of the disease. This also supports the notion that the composition of the B-cell repertoire is influenced by the disease and that B-cell depletion can reset biases that are typically found in autoimmune diseases.