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Donor CD4\(^+\)Foxp3\(^+\) regulatory T cells (T reg cells) suppress graft-versus-host disease (GvHD) after allogeneic hematopoietic stem cell transplantation (HCT allo-HCT]). Current clinical study protocols rely on the ex vivo expansion of donor T reg cells and their infusion in high numbers. In this study, we present a novel strategy for inhibiting GvHD that is based on the in vivo expansion of recipient T reg cells before allo-HCT, exploiting the crucial role of tumor necrosis factor receptor 2 (TNFR2) in T reg cell biology. Expanding radiation-resistant host T reg cells in recipient mice using a mouse TNFR2-selective agonist before allo-HCT significantly prolonged survival and reduced GvHD severity in a TNFR2-and T reg cell-dependent manner. The beneficial effects of transplanted T cells against leukemia cells and infectious pathogens remained unaffected. A corresponding human TNFR2-specific agonist expanded human T reg cells in vitro. These observations indicate the potential of our strategy to protect allo-HCT patients from acute GvHD by expanding T reg cells via selective TNFR2 activation in vivo.
Diverse roles of B cells in the pathophysiology of rheumatoid arthritis are now well established. B cells contribute to autoimmunity by producing autoantibodies, processing autoantigen and the production of different cytokines which are involved in the inflammatory cascade. Therefore approaches to target B lymphocytes directly or indirectly are developed for clinical practice to treat autoimmune diseases including rheumatoid arthritis. Transient B cell depletion by rituximab (anti-CD20 antibody) has gained prime importance in recent years. Meanwhile anti-CD20 mediated transient B cell depletion therapy is now used with clinical efficiency in the treatment of patients with rheumatoid arthritis. Rituximab induces noteworthy changes in the homeostasis of peripheral B cell subpopulations during the repletion phase with emerging immature B cells in peripheral blood followed by normalization of the naïve B cell pool and a longterm delay in memory B cell subsets in patients with rheumatoid arthritis. Particularly IgD+CD27+ memory B cells repopulate very slowly during B cell regeneration. In a prospective clinical study, our laboratory has shown that the overall number of memory B cells correlates well to the duration of clinical response to rituximab. Little is known about the particular molecular changes in the memory B cell repertoire after rituximab therapy. To better understand peripheral memory B cell subsets, we explored in detail the somatic mutational frequency and pattern of Ig-VH3 gene rearrangements by using a single B cell sorting technique followed by nested PCR before and up to 6 years after rituximab therapy in 18 RA patients. We compared rituximab inflicted dynamics of mutational acquisition to memory B cell repopulation in 4 healthy donors and 6 non RA patients undergoing high dose chemotherapy followed by autologous or allogeneic stem cell transplantation (SCT). Firstly we analyzed the peripheral composition of memory B cell subsets. The phenotypic analysis of peripheral pre-switch (IgD+CD27+) and post-switch (IgD-CD27+) memory B cells did not reveal any quantitative differences in RA patients prior to B cell depletion therapy compared to healthy donors. However extending those studies in directly analysing the B cell immunoglobulin receptor from individual B cells of RA patients and healthy controls brought interesting results. Pre-switched and post-switched memory B cells showed a highly significant difference in the amount of mutations/sequence. The population of IgD+CD27+ memory B cells is comprised of non-mutated, low and highly mutated (median= 9 mutations/ sequence) rearranged Ig receptors whereas the IgD-CD27+ memory B cell compartment shows quite uniformly highly mutated (median 18 mutations/ sequence) sequences indicating a significant difference between these two groups (mutational frequencies 3.83±0.19% vs. 7.1±0.53%; P=0.0001). Profound changes were noted in the re-emerging pre-switch memory B cells (IgD+/ CD27+) after transient B cell depletion with rituximab. These cells showed over a time period of 6 years after treatment with rituximab significantly delayed acquisition of mutations in Ig receptors on the single B cell level. One year after a single course of rituximab 84% of single repopulating IgD+/CD27+ B cells were unmutated and no highly mutated Ig-VH gene rearrangements were found(P=0.0001). Over time increasing numbers of mutations could be detected i-e 7.8% during 2nd year of regeneration (P=0.0001), 14% after 4 years (n=2). Nevertheless even 6 years after rituximab, VH mutations in IgD+ memory B cells were still reduced with 27% highly mutated sequences compared to 52% pre therapy(P=0.0001). Post-therapy analysis of CDR3 length of regenerated IgD+ memory B cells revealed increased CDR3 length which also correlates well with elevated number of non-mutated VH gene rearrangements observed during repletion phase. In comparison patients undergoing high dose chemotherapy followed by allogeneic stem cell transplantation repopulated IgD+ memory cells earlier with higher numbers of mutations in IgD+ memory B cells. One year after transplantation Ig receptors showed already 22% highly mutated and 42 % unmutated VH rearrangements. These findings indicated that anti-CD20 mediated B cell depletion seems not only to delay the production of pre-switch memory B cells but also significantly affects the acquisition of mutations in the IgD+ memory B cell pool. In contrary to the mutational pattern of IgD+ memory B cells after rituximab class switched memory B cells repopulate in the periphery with quantitatively normal mutations in their Ig receptors. Although the numeric replenishment of these recirculating class-switched memory B cells was also reduced after rituximab, we found no delay in quantitative acquisition of mutations also an increased proportion of IgA expressing B cells in this memory B cell subset was detected. Our data showed that post-therapy mutational targeting in RGYW/WRCY motifs were significantly increased as compared with that of pre-treatment (27% before rituximab vs. 43% after therapy, P=0.0003) indicating that affinity maturation may operate differently in class-switched memory B cells before and after B cell depletion. These results indicate a normal development process with an unimpaired mechanism of mutational acquisition in class-switched memory B cells. These data argue for different requirements to undergo somatic hypermutations in IgD+ memory B cells in comparison to class switched memory B cells. To conclude, our work has demonstrated for the first time a delayed acquisition of somatic hypermutations at single Ig receptor VH gene rearrangements of IgD+ memory B cells in comparison to class-switched memory B cells. These results demonstrate that IgD+ memory B cells are particularly susceptible to anti-CD20 treatment in patients with rheumatoid arthritis. In addition antigenic pressure and/or selection are substantially reduced by rituximab therapy which is basically not seen in the class-switched memory compartment. These data are in line with the hypothesis that IgD+ memory B cells have distinct requirements for activating their mutational machinery compared to class-switched memory B cells which recover normal mutations during regeneration phase. The results have implications in understanding the pathophysiology of memory B cell in rheumatoid arthritis and may be helpful in designing new targeted therapies.
Die zentrale Rolle von B- Zellen in der Pathogenese und Therapie von Autoimmunerkrankungen hat in den letzten Jahren zu unterschiedlichen therapeutischen Ansätzen geführt, B- Zellen direkt oder indirekt zu targetieren. Der bisher effektivste Ansatz stellt der monoklonale anti- CD20 Antikörper Rituximab dar. Nach Gabe von Rituximab kommt es zu einer passageren, in der Regel sechs bis neun Monate anhaltenden peripheren B- Zelldepletion. Die anti- CD20 vermittelte B- Zelldepletion stellt zwar ein vielversprechendes Therapieverfahren in der Behandlung der Rheumatoiden Arthritis dar, derzeit ist noch wenig über das Regenerationsverhalten von B- Zellen nach Therapie mit Rituximab bekannt. Daher wurde in dieser Arbeit die B-Zellrepopulation insbesondere hinsichtlich der Modulation des Mutationsmusters des B- Zellrezeptors untersucht. Dazu wurde die VH4- Familie des Immunglobulinrezeptors- prospektiv vor und nach anti- CD20 vermittelter B- Zelldepletion analysiert. Bei drei Patienten (A-C) wurden die Ig-VH4 Gene aus genomischer DNA peripherer B- Zellen amplifiziert, subkloniert und sequenziert. Die Analyse erfolgte zu drei verschiedenen Zeitpunkten: Vor Therapie, in der frühen Regenerationsphase mit einem B- Zellanteil von 1% bis 1,3% im peripheren Blut und in der späten Regenerationsphase, zwei bis drei Monate nach der frühen Regenerationsphase Mini Gene wie VH4-34 und VH4-39, die in Verbindung mit Autoimmunität stehen, waren vor Einleitung der Therapie relativ überexprimiert. Die Behandlung mit Rituximab führte bei allen drei Patienten zu einer Veränderung des Repertoires der regenerierenden B- Zellen mit einer reduzierten Benutzung der VH4-39 Gene, außerdem bei Patient A zusätzlich der VH4-34 Gene. Tief greifende Veränderungen fanden sich während der frühen Regenerationsphase durch den Nachweis einer rezirkulierenden Population hochmutierter B- Zellen, die in einer durchgeführten Immunophänotypisierung mit spezifischen Oberflächenmarkdern als Plasmazellen identifiziert wurden. Da Plasmazellen kein CD20 Molekül exprimieren, werden sie durch eine anti-CD20 vermittelte Therapie nicht direkt eliminiert. Sie zirkulieren während der Phase der B- Zelldepletion aber auch nicht im peripheren Blut. Interessanterweise sind sie in der frühen Regenerationsphase in der Peripherie als erste mit hohem relativem Anteil nachweisbar. Daher wurde untersucht, ob auch Plasmazellen durch die Therapie moduliert werden, obwohl sie durch Rituximab nicht direkt targetiert werden. Hierfür wurden die Sequenzen mit hochmutiertem Ig- Rezeptor (>9 Mutationen/Sequenz) im Verlauf einer detaillierten Analyse zugeführt. Dabei wurde insbesondere das Mutationsmuster in RGYW/WRCY Hotspot Motiven und in den CDR- Regionen untersucht. Die Analyse der Mutationshäufigkeit in RGYW/WRCY Hotspot Motiven erlaubt eine Abschätzung, in wieweit die somatische Hypermutation der B- Zellen durch T- Zell abhängige Differenzierung erfolgte. Die als Plasmazellen identifizierten hochmutierten Sequenzen zeigten vor der Therapie Charakteristika einer aktiven Erkrankung mit einem verminderten Targeting der RGYW/WRCY Motive. Dagegen zeigte sich in den rezirkulierenden Plasmazellen während der frühen Regenerationsphase ein zunehmendes Targeting der RGYW/WRCY Motive. Dies spricht für einen Repertoire Shift zu mehr T- Zell abhängigen B- Zell Mutationen. Ein Zustand, wie er bei Gesunden beobachtet wird. Um die Hypothese einer Rituximab- induzierten Modulation des Plasmazellkompartimentes weiter zu untermauern, wurde der R/S Quotient, d.h. das Verhältnis von Silent zu Replacement Mutationen in den hypervariablen Regionen (CDRs) der hochmutierten Plasmazell-Ig Sequenzen bestimmt. Interessanterweise fanden sich in der Regenerationsphase signifikant erhöhte R/S Ratios in den rezirkulierenden Plasmazellen.. Die signifikante Zunahme an Replacement Mutationen in den CDR- Regionen, welche sich in einer Zunahme des R/S Verhältnisses wiederspiegelt, kann als Entwicklung des Ig- Repertoires durch positive Antigenselektion interpretiert werden und weist somit eine Rituximab- induzierte Veränderung auf, wie man sie sonst bei gesunden Individuen findet. Zusammenfassend zeigt unsere Studie, dass die transiente anti- CD20 vermittelte B- Zelldepletion auch zu einer indirekten Modulation des Plasmazellkompartimentes führt. Insbesondere werden postrekombinatorische Imprints des B- Zell Rezeptors, wie somatische Hypermutation und Antigen Selektion, verändert, die mit hoher Wahrscheinlichkeit für die Entstehung von Autoimmunität bei der Rheumatoiden Arthritis eine Rolle spielen. Zusätzlich kann die Modulation des genetischen Imprints der Ig Rezeptoren bei der Rheumatoiden Arthritis eventuell als möglicher Biomarker entwickelt werden, um ein Ansprechen auf die Therapie vorherzusagen. Dies bedarf weiterer Untersuchungen, um tiefer greifende Einblicke in Prozesse zu erlangen, die durch zukünftige Therapien beeinflussbar werden.
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.