Academic literature on the topic 'Memory B cells'

B cells recognise antigens on micro-organisms through their B cell receptor (BCR) and via Toll-like receptors (TLRs), and thus respond in both innate and adaptive manners during the subsequent immune response. Innate recognition through TLRs has the potential to alter the behaviour of whole B cell populations. I show, here, that MyD88-dependent activation of B cells via TLR2 or TLR9 causes the rapid loss of expression of CD62L, by metalloproteinasedependent shedding, resulting in the exclusion of these cells from lymph nodes and Peyer’s patches, but not the spleen. Moreover, systemic infection with Salmonella typhimurium causes shedding of CD62L and the subsequent focussing of B cell migration to the spleen. I reveal that splenic B cells undergo further changes during S. typhimurium infection, including TLR-dependent differentiation of marginal zone B cells into IgM-secreting plasma cells. Together, these TLR-mediated alterations to B cells are likely to influence the development of immunity to pathogens carrying the appropriate ligands. In addition to these innate responses of B cells, endocytosis of cognate antigen through their BCR allows antigen presentation. This, together with their ability to secrete cytokines, means they have the potential to drive T helper cell responses. I investigate the role of B cells in such CD4+ T cell responses by following antigen-specific T cells in vivo, using both a peptide immunisation strategy and the S. typhimurium infection model. I use anti-CD20 B cell depletion antibodies to deplete B cells at various stages of the immune response, and analyse the effects on T follicular helper and memory cell populations. I show that both the generation and maintenance of T follicular helper cells is dependent on the presence of B cells. Furthermore, I demonstrate that B cells are necessary very early in immune responses, during the first 10 days, for efficient generation of memory T cells.

Background: The presence of B cells in early stage non-small cell lung cancer (NSCLC) is associated with longer survival, however, the role these cells play in the generation and maintenance of anti-tumor immunity is unclear. B cells differentiate into a variety of subsets with differing characteristics and functions. To date, there is limited information on the specific B cell subsets found within NSCLC. To better understand the composition of the B cell populations found in NSCLC we have begun characterizing B cells in lung tumors and have detected a population of B cells that are CD79A(+)CD27(-)IgD(-). These CD27(-)IgD(-)(double-negative) B cells have previously been characterized as unconventional memory B cells and have been detected in some autoimmune diseases and in the elderly population but have not been detected previously in tumor tissue. Methods: A total of 15 fresh untreated NSCLC tumors and 15 matched adjacent lung control tissues were dissociated and analyzed by intracellular flow cytometry to detect the B cell-related markers CD79A, CD27 and IgD. All CD79A(+) B cells subsets were classified as either naive (CD27(-)IgD(+)), affinity-matured (CD27(+)IgD(-)), early memory/germinal center cells (CD27(+)IgD(+)) or double-negative B cells (CD27(-)IgD(-)). Association of double-negative B cells with clinical data including gender, age, smoking status, tumor diagnosis and pathologic differentiation status were also examined using the logistic regression analysis for age and student's t-test for all other variables. Associations with other B cell subpopulations were examined using Spearman's rank correlation. Results: We observed that double-negative B cells were frequently abundant in lung tumors compared to normal adjacent controls (13 out of 15 cases), and in some cases made up a substantial proportion of the total B cell compartment. The presence of double-negative cells was also found to be inversely related to the presence of affinity-matured B cells within the tumor, Spearman's coefficient of -0.76. Conclusions: This study is the first to observe the presence of CD27(-)IgD(-)double-negative B cells in human NSCLC and that this population is inversely correlated with traditional affinity-matured B cell populations.

B-Lymphozyten leisten unterschiedliche Beiträge zur Pathophysiologie der Rheumatoiden Arthritis. Sie produzieren Autoantikörper, präsentieren Autoantigene und schütten verschiedene Zytokine, die am proinflammatorischen Prozess beteiligt sind, aus. Aufbauend auf diesen Ergebnissen wurden in den letzten Jahren Therapien entwickelt, die gezielt B-Lymphozyten ansteuern um direkt oder indirekt in den autoimmunen Krankheitsverlauf einzugreifen. Die zeitlich begrenzte B-Zell-Depletion mit Rituximab (anti CD20-Antikörper) hat dabei in den letzten Jahren einen hohen Stellenwert erlangt und wird im klinischen Alltag insbesondere bei der Behandlung von Patienten mit rheumatoider Arthritis angewandt. Rituximab induziert im peripheren Blut bemerkenswerte Veränderungen in der Homöostase der B-Zell-Subpopulationen. Nach Therapie mit dem anti-CD20 Antikörper Rituximab beginnt die Repletionsphase mit der peripheren Aussaat von transitionalen unreifen B-Zellen. Im weiteren Verlauf kommt es zu einer Normalisierung des naiven B-Zell-Pools. Das B-Zell Gedächtnis und in besonderem Maße die IgD+CD27+ Gedächtniszellen erholen sich nach Therapie nur langsam. In einer prospektiven klinischen Studie hat unsere Arbeitsgruppe gezeigt, dass die Gesamtzahl der Gedächtniszellen gut mit der Dauer der klinischen Antwort auf Rituximab korreliert. Es ist wenig über die speziellen molekularen Veränderungen innerhalb der Gedächtnis B-Zellen nach Rituximab Therapie bekannt. Um die Veränderungen im peripheren Blut zu verstehen untersuchten wir die somatische Mutationsfrequenz und das Muster der Ig-VH3 Gen Rearrangements, indem wir prä- und posttherapeutisch bei 18 Patienten einzelne B-Zellen isolierten und den individuellen B-Zellrezeptor durch eine Einzelzell RT-PCR amplifizierten und sequenzierten. Wir verglichen das Mutationsmuster nach erfolgreicher B-Zelldepletion in den neu rezirkulierenden Gedächtnis B-Zellen mit dem Mutationsmuster von vier Gesunden Blutspendern und sechs nicht-RA Patienten, die eine Hochdosis Chemotherapie mit anschließender autologer oder allogener Stammzelltransplantation erhalten hatten. Zunächst haben wir die Zusammensetzung der Gedächtniszellen im peripheren Blut analysiert. Der Phänotyp der peripheren prä-switch (IgD+CD27+) und post-switch (IgD-CD27+) Gedächtniszellen zeigte keine quantitativen Unterschiede in RA-Patienten im Vergleich zu Gesunden. Bei der direkten Analyse des B-Zell Immunglobulin Rezeptors fanden sich jedoch zwischen klassengeswitchten und ungeswitchten Gedächtnis B-Zellen signifikante Unterschiede in der Anzahl der Mutationen in der variablen Region der Ig Rezeptors. Die Population der IgD+CD27+ Gedächtniszellen beinhaltete sowohl nicht mutierte, wenig mutierte und stark mutierte (Median= 9 Mutationen pro Sequenz) rearrangierte Ig- Rezeptoren, wohingegen die IgD-CD27+ Gedächtniszellen einen durchgehend hoch mutierten (Median = 18 Mutationen pro Sequenz) Rezeptor aufwiesen. Der Unterschied zwischen beiden Gruppen war signifikant (Mutationsfrequenzen 3.83±0.19% vs. 7.1±0.53%; P=0.0001). Grundlegende Veränderungen wurden bei den rezirkulierenden ungeswitchten Gedächtniszellen (IgD+CD27+) nach vorübergehender B-Zell Depletion mit Rituximab festgestellt. Diese Zellen wurden bis 6 Jahre nach Rituximab beobachtet und zeigten eine stark verzögerte Zunahme an Mutationen im Ig-Rezeptor. Ein Jahr nach einmaliger Gabe von Rituximab waren 84% der einzelnen zirkulierenden IgD+/CD27+ B-Zellen unmutiert. Zu diesem Zeitpunkt fanden sich keine stark mutierten Ig-VH3 Gen Rearrangements (P=0.0001). Mit zunehmendem Abstand zur B-Zell depletierenden Therapie konnten in der Repopulationsphase zunehmende Zahlen an Mutationen in den B-Zell Ig Rezeptoren festgestellt werden. Beispielsweise waren während des 2. Jahres der Regeneration (P=0.0001) 7.8%, sowie nach 4 Jahren nur 14% der Ig Rezeptoren mutiert. Sogar 6 Jahre nach Behandlung, waren VH Mutationen in IgD+ Gedächtniszellen noch deutlich vermindert. Selbst nach dieser Zeit fanden sich in der prä-switch Gedächtnispopulation nur 27% hochmutierte Sequenzen während vor der passageren B-Zelldepletion 52% ein hohe Zahl an Mutationen trugen (P=0.0001). Die posttherapeutische Analyse der CDR3 Länge der regenerierten IgD+ Gedächtniszellen ergab eine erhöhte CDR3 Länge, die signifikant mit der Anzahl der nicht mutierten VH Genrearrangements während der Repletionsphase korreliert. Interessanterweise regenerierten Patienten nach Hochdosis Chemotherapie und allogener Stammzelltransplantation ihre IgD+ Gedächtniszellen mit einer deutlich höheren Anzahl an Mutationen. Ein Jahr nach Transplantation zeigten die Ig Rezeptoren schon 22% hoch mutierte und 42% unmutierte VH Rearrangements. Das zeigt, dass eine gegen CD20 gerichtete Behandlung nicht nur eine Verzögerung der Produktion der ungeswitchten Gedächtniszellen zur Folge hat, sondern darüber hinaus einen signifikanten Effekt auf die Mutationsrate im präswitch Gedächtnis B-Zellpool besitzt. Im Gegensatz zum Mutationsmuster der IgD+ Gedächtniszellen regenerierten die klassengeswitchten Gedächtniszellen nach anti-CD20 Depletion im peripheren Blut mit quantitativ normalen Mutationen im Ig Rezeptor. Interessanterweise fand sich allerdings eine Änderung der exprimierten Isotypen mit deutlicher Dominanz IgA exprimierender B Zellen. Weitere Analysen der klassengeswitchten Gedächtnis B-Zellen zeigen außerdem eine Therapie induzierte qualitative Veränderung dieses B-Zellpools. So waren posttherapeutisch die Mutationen in bestimmten T-Zell abhängigen Mutationshotspots, dem RGYW/WRCY Motiv, signifikant vermehrt (Mutationstargeting vor Therapie 27% vs. 43% nach Rituximab, P=0.0003). Dies weist darauf hin, dass die Mechanismen der Affinitätsreifung im klassengeswitchten B-Zellgedächtnis vor und nach B-Zelldepletion unterschiedlich funktionieren. Der Mutationsmechanismus selbst ist allerdings in diesen Zellen quantitativ nicht eingeschränkt. Zusammenfassend zeigt unsere Arbeit zum erstem mal, dass es nach einer passageren B-Zelldepletion mit anti-CD20 Antikörpern zu einer über Jahre hinweg nachweisbaren ausgeprägten Verzögerung in der Aquisition von somatischen Mutationen in rearrangierten VH Genen der IgD+ Gedächtniszellen kommt. Demgegenüber erholt sich das klassengeswitchte B-Zellgedächtnis mit uneingeschränkter Zahl von Mutationen im Ig Rezeptor. Diese Resultate zeigen, dass anti-CD20 gerichtete Therapien in besonderem Maße IgD+ Gedächtniszellen beeinflussen. Der Selektionsdruck durch Antigene und/oder die Selektion der Ig Rezeptoren erscheint unter diesen Bedingungen speziell bei IgD-Gedächtnis B-Zellen reduziert. Die Daten unterstützen die Hypothese, dass prä-switch Gedächtnis B-Zellen im Vergleich zu post-switch Gedächtnis B-Zellen andere Bedingungen für die Aktivierung der Mutationsmaschinerie benötigen. Die Resultate eröffnen neue Wege für das Verständnis der Pathophysiologie der B-Zell Gedächtnisentwicklung und können helfen neue zielgerichtete Therapien zur Behandlung von Autoimmunerkrankungen zu konzipieren
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

We found that IgM+IgD- memory (ME-M) B cells formed a large reservoir of intestinal antigen-selected IgM+ lymphocytes distinct from antigen-naïve IgM+ lymphocytes. Human ME-M B cells colonized the intestine early in life, persisted throughout adulthood and inhabited Peyer’s patches and isolated lymphoid follicles. Intestinal ME-M B cells shared some commonalities with splenic IgM+IgDlowCD27+ marginal zone B cells, including phenotypic traits, multiple IgVH gene families and a pronounced reactivity against microbial carbohydrates and lipids. However, ME-M B cells expressed a gut-specific gene signature and an IgVH gene mutation profile consistent with a germinal center origin from gut inductive sites. Accordingly, ME-M B cells showed strong reactivity against mucus-embedded commensal antigens. Furthermore, ME-M B cells generated IgM+ or IgA+ plasma cells (PC) in response to T cell-dependent or independent signals and organized clonally coordinated IgM and IgA responses in ileum and colon. IgM+ PC emerging from ME-M B cells released IgM antibodies that along with IgA, coated intestinal bacteria and fungi.
Hem descovert que les cèl·lules B de memòria IgM+IgD- (ME-M) formen una gran reserva intestinal de limfòcits preseleccionats diferents dels limfòcits verges. Les cèl·lules ME-M colonitzen l'intestí als inicis de la vida i hi perduren durant l’edat adulta en les plaques de Peyer i els fol·licles limfoides aïllats. Les cèl·lules ME-M comparteixen certes característiques amb les cèl·lules B IgM+IgDlleuCD27+ de la zona marginal esplènica, incloent trets fenotípics, famílies de gens IgVH i reactivitat pronunciada contra hidrats de carboni i lípids microbians. No obstant això, les cèl·lules ME-M expressen una signatura gènica específica del intestí i un perfil de mutació en els gens IgVH consistent amb un origen a centres germinals intestinals. En consequència, les cèl·lules ME-M mostren reactivitat enfront d'antígens comensals del moc intestinal. A més, les cèl·lules ME-M generen cèl·lules plasmàtiques (PC) IgM+ o IgA+ en resposta a senyals dependents i independents de cèl·lules T, i organitzen respostes clonals coordinades IgM i IgA en l'ili i el còlon. PC IgM+ derivades de cèl·lules ME-M, produeixen anticossos IgM que, juntament amb IgA, recobreixen bacteris i fongs del moc intestinal.

Gedächtnis-B-Zellen und Plasmazellen sind essentielle Komponenten der protektiven Immunität. Die Mechanismen ihrer Induktion, ihres Überlebens und der Gedächtnis-B-Zellreaktivierung sind allerding bisher nur unvollständig verstanden. Um unser Wissen diesbezüglich zu erweitern, wurden in der vorliegenden Arbeit zum einen Charakteristika von Primär- und Sekundärimmunantworten nach Immunisierung mit Keyhole Limpet Hemocyanin (KLH) untersucht und zum anderen das Vorkommen sowie der Phänotyp humaner Gedächtnis-B-Zellen in verschiedenen lymphatischen Geweben analysiert. Die primäre parenterale KLH Immunisierung führte auf serologischer und zellulärer Ebene zu einer Reihe unerwarteter Ergebnisse, welche u. a. das Auftreten von IgA Antikörpern und die gleichzeitige Präsenz von hoch- und wenig mutierten primären Plasmablasten beinhalteten. Die Untersuchung der Gedächtnis-B-Zellverteilung in verschiedenen lymphatischen Geweben ergab den größten Gedächtnis-B-Zellpool in der Milz. Blut-, Tonsillen-, Knochenmarks- und Milz-Gedächtnis-B-Zellen wiesen nur wenige phänotypische Unterschiede auf. Einer davon war die CD69 Expression auf tonsillären ruhenden Gedächtnis-B-Zellen, was darauf hindeutet, dass tonsilläre Gedächtnis-B-Zellen tatsächlich sessil sein könnten. Die hier erhaltenen Ergebnisse stellen neue Erkenntnisse über bisher unbeschriebene Mechanismen bei parenteralen Immunantworten wie zum Beispiel die Induktion von IgA Antikörpern sowie die potentielle Rekrutierung kreuzreaktiver Gedächtnis-B-Zellen dar. Es bleibt zu klären, wie die Reaktivierung solcher Gedächtnis-B-Zellen reguliert ist. Derartiges Wissen wäre insbesondere für Therapien von Erkrankungen des Immunsystems, wie Autoimmunität, von Bedeutung. Das potentiell patrouillierende Verhalten der Gedächtnis-B-Zellen ist ein markanter Unterschied zu den nischenabhängigen sessilen Plasmazellen und deutet weitestgehend darauf hin, dass Gedächtnis-B-Zellen nicht auf derartige Nischen angewiesen sind.
Memory B cells (mBC) and antibodies are major mediators of protective immune responses yet the mechanisms of their induction, maintenance and mBC reactivation are poorly understood. Therefore, to enhance knowledge in this regard this study comprehensively characterized a human primary and secondary B cell immune response to Keyhole Limpet Hemocyanin (KLH). Secondly, mBC maintenance was investigated by a systematic analysis of mBC presence, frequency and phenotype within different lymphoid organs. Parenteral primary KLH immunization yielded unexpected results on the serological and B cellular level, including KLH-specific IgA antibody induction, the simultaneous presence of low and highly mutated circulating KLH-specific primary plasmablasts and only little clonal overlap between the primary, memory and secondary KLH-specific B cell repertoires. With respect to the organ distribution of human mBC, the spleen was identified as a major mBC reservoir. Splenic, tonsillar, bone marrow and blood mBC pools exhibited a largely comparable phenotype. Yet, we found tonsillar mBC to express CD69. Due to their resting state tonsillar mBC could therefore constitute a tissue resident cell population. The observations described allow insights into hitherto unknown potential mechanisms behind primary immune responses, i.e. prominent IgA induction by parenteral challenge and inclusion of cross-reactive mBC. The so far unclear regulatory players involved deserve future investigation, as such knowledge may be crucial for therapeutic interventions in immune system disorders. Furthermore, strikingly different to the resident plasma cells in the bone marrow, mBC appear to distribute between lymphoid organs and continuously recirculate in peripheral blood indicative of their potential permanent screening activities, suggesting that human mBC do not require one dedicated niche for their principle survival.

Antikörper gegen Circumsporozoite protein (CSP), ein Oberflächenantigen von Plasmodium falciparum (Pf), können sterile Immunität hervorrufen und dadurch die Entwicklung von Malaria im Tierversuch verhindern. Im Menschen werden protektive B-Zell Gedächtnisantworten gegen CSP durch natürliche Malariaerkrankung bzw. Vakzinierung jedoch nur unzureichend erzeugt. - Für die Entwicklung von Gedächtnis-B-Zellen stellt die Affinitätsreifung, welche durch somatische Immungobulin Hypermutation sowie der nachfolgenden Selektion von B-Zellen mit verbesserter Antigenaffinität charakterisiert ist, eine Schlüsselfunktion in der Generierung von protektiven Immunantworten dar. Wie Affinitätsreifung gegen CSP im Menschen stattfindet ist jedoch nicht bekannt. In dieser Arbeit wird die Affinitätsreifung von CSP Gedächtnis B-Zellen auf Einzelzellebene im Menschen über drei kontrollierte Infektionen mit Pf Sporozoiten unter Chemoprophylaxe untersucht. Durch Hochdurchsatz-Einzelzell-Sequenzierung der Immunoglobulin (Ig) gene loci und der Produktion von rekombinanten monoklonalen Antikörpern gewährt diese Arbeit Einsicht in die Selektion und Affinitätsreifung von humanen Gedächtnis-B-Zell Antworten gegen komplexe Proteinantigene und identifiziert Keimbahn kodierte Immunglobulin Charakteristika, die mit hoher CSP-Affinität und Pf-Inhibition einhergehen. Überraschenderweise zeigen die Daten, dass initiale klonale Selektion von hochaffinen B Zellen eine weitaus wichtigere Rolle als Affinitätsreifung in dieser Infektion spielt. Diese Arbeit zeigt fundamentale Eigenschaften von humanen Gedächtnisantworten in einer komplexen Parasiteninfektion und liefert die Grundlage für ein mögliches Design von neuartigen Immunogenen um hoch-affine B-Zellen gegen CSP effizienter zu induzieren.
Antibodies against the major Plasmodium falciparum (Pf) sporozoite surface protein, circumsporozoite protein (CSP), can mediate sterile immunity thereby preventing malaria disease symptoms as shown by passive transfer in animal models. However, protective anti- CSP memory antibody responses are not efficiently induced by natural Pf exposure or vaccination. Affinity maturation, i.e. the diversification of antigen-activated naïve precursor B cells by a somatic immunoglobulin (Ig) gene mutation process and the subsequent selection of B cells expressing antigen receptors with improved antigen affinity in germinal center reactions is considered key to the formation of protective memory B cell responses. However, how the anti-PfCSP memory B cell response matures in humans is not known. To address this question, the clonal evolution of the human anti-Pf CSP memory B cell response over three successive controlled Pf infections under chemoprophylaxis was assessed at single cell level by high throughput paired full-length Ig gene sequencing and recombinant monoclonal antibody production. The work provides basic insights in the longitudinal development of human memory B cell responses and identified germline-encoded Ig gene features that were associated with high anti-CSP affinity and Pf inhibitory antibody activity. The clonal selection of germline B cells expressing such antibodies, rather than affinity maturation, was associated with high quality anti-PfCSP memory B cell responses. The data provide insights into the evolution of antibody response to a complex protein antigen during infection and a strong rational for the design of novel CSP immunogens to target naïve B cell precursors expressing potent anti-CSP antibodies for the induction of protective memory B cell responses by vaccination.

Streptococcus pneumoniae is a significant cause of mortality and morbidity in both children and older adults, with infection resulting in invasive disease, pneumonia and otitis media. The inclusion of pneumococcal conjugate vaccines in routine infant immunisation programmes has had a major impact on disease rates. Vaccine-induced protection against pneumococcal infection is thought to be mediated by the generation of persistent serotype-specific functional antibodies and antigen-specific memory B cells, the latter capable of generating a rapid secondary antibody response on re-exposure to antigen. Although many studies have investigated the immunogenicity of pneumococcal vaccines in different age groups by measuring serotype-specific antibodies, there is more limited information about the B cells underlying such an immune response. Important areas to investigate include the identity of the B cell subsets involved in antibody production and the potential link between memory B cells (B_MEM) and persistent antibody production by long-lived plasma cells. In this thesis I have investigated in detail the immune response to pneumococcal vaccines given to children and adults by a variety of different methods. By examining the variability of a B_MEM ELISpot method, it was shown that this assay is robust and reproducible and can be performed on fresh or frozen samples and in different laboratories. Using this technique, in a study of pre-school children, it was demonstrated for the first time that the level of pre-existing serotype 3-specific antibody is negatively correlated with, and may directly impair the B_MEM response to a booster dose of 13-valent pneumococcal conjugate vaccine (PCV-13) containing serotype 3 glycoconjugate. In the same study, it was shown that antibody persistence against most vaccine serotypes can be expected until the age of 3.5 years. A novel antigen-labelling technique was used in a detailed kinetics study of antigen-specific B cell subsets in response to either PCV-13 or 23-valent pneumococcal polysaccharide vaccine in adults. The results of this study revealed distinct B cell subset response patterns that were observed in all study participants indicating that IgM B_MEM seem to play a major role in the immune response to pneumococcal vaccines. In addition, in the same study, genome wide analysis of gene expression was performed and it was shown that vaccination with either a pneumococcal conjugate or polysaccharide vaccine results in a marked difference in numbers of differentially expressed genes 8 days following vaccination. A further tool likely to be of use in investigating B cell responses is the analysis of the antibody repertoire using next-generation sequencing techniques. In order to test the ability of these methods to detect vaccine responses, a large dataset of high-throughput B cell receptor sequences was analysed and revealed convergence of antigen-specific complementary-determining region (CDR)₃ amino acid (AA) sequences following vaccination and identified antigen-specific sequences. It was further demonstrated that for sequences directed against the H. influenzae type b (Hib) polysaccharide, diversity of immunoglobulin gene rearrangements is much greater than previously recognised. Frequencies of Hib-specific CDR₃ AA sequences were linked with anti-Hib avidity indices highlighting the potential of this method as an alternative (functional) measure of vaccine immunogenicity. These data suggest that studying the B cells and antibody repertoire post-vaccination can give novel insights into the biology that underlies the immune responses.

Les lymphocytes T CD8+ spécifiques de l'antigène sont impliqués dans la réponse immunitaire adaptative et jouent un rôle essentiel dans la protection de l'hôte contre l'infection par des pathogènes intracellulaires. Cette protection de longue durée dépend de la génération de réponses lymphocytaires T CD8+ mémoires, hautement fonctionnelles en termes de fréquence et de fonctionnalité, après réinfection.Après présentation de l'antigène, une cellule T CD8 naïve subit une forte expansion clonale, générant une population hétérogène de cellules activées qui est dominée, au sommet de l'expansion, par des effecteurs CD8 de courte durée (SLEC). Cette expansion est suivie d'une phase de contraction massive par apoptose. Quelques cellules survivent à cette phase de contraction et finissent par se différencier en cellules mémoire hautement compétentes. Les processus par lesquels et le moment où se différencient les précurseurs de mémoire (MPECs) restent largement inconnus, tout comme les étapes ultérieures de leur maturation en cellules mémoire pleinement fonctionnelles. Les signaux d'aide provenant des cellules T CD4+ sont clairement requis tout au long du processus de maturation des MPEC.Notre équipe a montré que les lymphocytes T CD4+ régulateurs FoxP3+ (Tregs) favorisent la maturation des MPEC en limitant l'exposition à l'IL-2 et en fournissant des signaux inhibiteurs, mais ce n'est probablement qu'une facette de l'aide complexe et multiforme apportée par les cellules T CD4+ au MPEC. Les Tregs agissent sur des MPEC préexistants. Les réponses mémoire B et CD8+ partagent des caractéristiques communes, telles que l'expression du facteur de transcription Bcl-6. Les lymphocytes T CD4+ folliculaires (Tfh) sont les principaux producteurs de la cytokine IL-21. Bien que les mécanismes par lesquels les Tfh induisent l’expression de Bcl-6 dans les cellules B doivent être clarifiés, ils pourraient inclure l’IL-21 et l’interaction CD40-CD40L.Dans ce projet de thèse, nous avons étudié le rôle potentiel des Tfh dans l'initiation de la différenciation mémoire T CD8+, dans des modèles de souris transgéniques permettant une déplétion transitoire et sélective des Tfh, infectées par la bactérie recombinante Listeria monocytogenes-OVA.Nous avons montré que dès 2 jours après l'infection, les MPECs très précoces peuvent être identifiés par l’expression du récepteur de chimiokine CXCR5. Ces précurseurs précoces, qui ont un phénotype effecteur, se développent et migrent temporairement à la jonction des zones T et B, où ils interagissent avec les Tfh puis perdent leur expression CXCR5.Cette interaction avec les Tfh, considérés jusqu'à présent comme des auxiliaires exclusifs des cellules B, est nécessaire pour que les MPECs CD8+ deviennent des cellules mémoire compétentes sensibles à l'IL-21, capables de générer des réponses effectrices secondaires efficaces.Cette étude dévoile les premières étapes cruciales dans la génération de la mémoire CD8+, identifie CXCR5 comme le premier marqueur connu des MPECs CD8+, révèle l’implication fondamentale des Tfh dans le CD4 help et indique une coordination possible, via les Tfh, entre les voies de différentiation mémoire CD8+ et B. Ces résultats peuvent avoir des implications pour la conception du vaccin et de l'immunothérapie
Antigen-specific CD8 T cells are involved in the adaptive immune response and play a critical role in protecting the host from infection by intracellular pathogens. This long-lasting protection depends on the generation of memory CD8+ T cell responses, which are highly functional in terms of frequency and functionality, after secondary infection.Following antigen activation, a naive CD8 T cell undergoes strong clonal expansion, generating a heterogeneous population of activated cells that is dominated, at the peak of expansion, by short-lived CD8 effectors (SLECs). This expansion is followed by a phase of drastic contraction through massive apoptosis. A few cells survive this contraction phase and eventually become highly competent memory cells. Precisely when and how these memory precursors (MPECs) are generated is largely unknown, and so are the subsequent steps of their maturation into fully functional memory cells. Help signals from CD4+ T cells are clearly required throughout the MPEC maturation process.Our team has previously shown that FoxP3+ regulatory CD4+ T cells (Tregs) favor MPECs maturation by limiting exposure to IL-2 and by providing inhibitory signals, but this is probably only one facet of the complex and multifaceted help provided by CD4+ T cells to MPEC, and Tregs act on pre-existing MPECs.B-cell memory and CD8+ T cell memory share some common features, such as the expression of the transcription factor Bcl-6. Tfh are major producers of the cytokine IL-21. The mechanisms by which Tfh induces Bcl-6 in B-cells need to be clarified, they might include IL-21 and CD40-CD40L.In this PhD project, we have investigated the potential role of Tfh on the initiation of CD8 memory differentiation, in transgenic mice models, allowing transient and selective depletion of Tfh cells, infected by recombinant Listeria monocytogenes-OVA.We have shown that as early as 2 days after infection, very early memory precursors can be identified by their expression of the chemokine receptor CXCR5. These early precursors, which have an effector phenotype, expand and temporarily migrate to the junction of T-cell and B-cell zones, where they interact with follicular CD4 T cells (Tfh) then lose their CXCR5 expression.Remarkably, this interaction with Tfh, hitherto considered as exclusive B-cell helpers, is required for memory precursors to become competent memory cells responsive to IL-21 and capable of mounting efficient cytotoxic secondary effector responses.This study thus unveils critical early steps in the generation of CD8 memory, identifies CXCR5 as the earliest known marker of CD8 memory precursors, reveals a major helper role for Tfh, and points to possible coordination, through Tfh, between the pathways of CD8 and B-cell memory generation. These findings may have implications for vaccine and immunotherapy design

B cells have gained interest in rheumatoid arthritis (RA) beyond being the precursors of antibody-producing plasma cells since they are also a broader component of the adaptive immune system. They are capable of functioning as antigen-presenting cells for T-cell activation and can produce an array of cytokines. Disturbances of peripheral B-cell homeostasis together with the formation of ectopic lymphoid neogenesis within the inflamed synovium appears to be a characteristic of patients with RA. Enhanced generation of memory B cells and autoreactive plasma cells producing IgM-RF and ACPA-IgG antibodies together with formation of immune complexes contribute to the maintenance of RA, whereas treatment with B-cell-directed anti-CD20 therapy provides clinical benefit.

In the chronic leukaemias, leukaemogenesis occurs in two different cell types (and possibly even two different anatomical sites), leading to two very different forms of the disease: chronic myeloid leukaemia and chronic lymphocytic leukaemia. Chronic myeloid leukaemia is best thought of as a myeloproliferative disorder. It is a clonal disorder of the haematopoietic stem cell, leading to overproduction of the myeloid cells: neutrophils and their precursors, basophils and eosinophils. By contrast, chronic lymphocytic leukaemia can be viewed as a low-grade lymphoma. It is a clonal disorder of mature B-lymphocytes (possibly memory B-cells). This chapter reviews the causes, diagnosis, and management of these two forms of chronic leukaemia.

The innate and the adaptive immune system efficiently cooperate to protect us from infections. The ancient innate immune system, dating back to the first multicellular organisms, utilizes phagocytic cells, soluble antimicrobial peptides, and the complement system for an immediate line of defence against pathogens. Using a limited number of germline-encoded pattern recognition receptors including the Toll-like, RIG-1-like, and NOD-like receptors, the innate immune system recognizes so-called pathogen-associated molecular patterns (PAMPs). PAMPs are specific for groups of related microorganisms and represent highly conserved, mostly non-protein molecules essential for the pathogens' life cycles. Hence, escape mutants strongly reduce the pathogen's fitness. An important task of the innate immune system is to distinguish between harmless antigens and potentially dangerous pathogens. Ideally, innate immune cells should activate the adaptive immune cells only in the case of invading pathogens. The evolutionarily rather new adaptive immune system, which can be found in jawed fish and higher vertebrates, needs several days to mount an efficient response upon its first encounter with a certain pathogen. As soon as antigen-specific lymphocyte clones have been expanded, they powerfully fight the pathogen. Importantly, memory lymphocytes can often protect us from reinfections. During the development of T and B lymphocytes, many millions of different receptors are generated by somatic recombination and hypermutation of gene segments making up the antigen receptors. This process carries the inherent risk of autoimmunity, causing most inflammatory rheumatic diseases. In contrast, inadequate activation of the innate immune system, especially activation of the inflammasomes, may cause autoinflammatory syndromes.

AbstractAntigen-specific B-cell ELISPOT and multicolor FluoroSpot assays, in which the membrane-bound antigen itself serves as the capture reagent for the antibodies that B cells secrete, inherently result in a broad range of spot sizes and intensities. The diversity of secretory footprint morphologies reflects the polyclonal nature of the antigen-specific B cell repertoire, with individual antibody-secreting B cells in the test sample differing in their affinity for the antigen, fine epitope specificity, and activation/secretion kinetics. To account for these heterogeneous spot morphologies, and to eliminate the need for setting up subjective counting parameters well-by-well, CTL introduces here its cutting-edge deep learning-based IntelliCount™ algorithm within the ImmunoSpot® Studio Software Suite, which integrates CTL’s proprietary deep neural network. Here, we report detailed analyses of spots with a broad range of morphologies that were challenging to analyze using standard parameter-based counting approaches. IntelliCount™, especially in conjunction with high dynamic range (HDR) imaging, permits the extraction of accurate, high-content information of such spots, as required for assessing the affinity distribution of an antigen-specific memory B-cell repertoire ex vivo. IntelliCount™ also extends the range in which the number of antibody-secreting B cells plated and spots detected follow a linear function; that is, in which the frequencies of antigen-specific B cells can be accurately established. Introducing high-content analysis of secretory footprints in B-cell ELISPOT/FluoroSpot assays, therefore, fundamentally enhances the depth in which an antigen-specific B-cell repertoire can be studied using freshly isolated or cryopreserved primary cell material, such as peripheral blood mononuclear cells.

Background: The role of B cells in multiple sclerosis (MS) is increasingly recognized. B cells undergo compartmentalized redistribution in blood and cerebrospinal fluid (CSF) during active MS, whereby memory B cells accumulate in the CSF. While B-cell trafficking across the blood– brain barrier has been intensely investigated, cellular diapedesis through the blood–CSF barrier (BCSFB) is incompletely understood. Objectives: To investigate how B cells interact with the choroid plexus to transmigrate into the CSF, we isolated circulating B cells from healthy donors (HC) and MS patients, utilized an inverted cell culture filter system of human choroid plexus papilloma (HIBCPP) cells to determine transmigration rates of B-cell subsets, immunofluorescence, and electron microscopy to analyze migration routes, and qRT-PCR to determine cytokines/chemokines mediating B-cell diapedesis. We also screened the transcriptome of intrathecal B cells from MS patients. Results: We found that spontaneous transmigration of HC- and MS-derived B cells was scant yet increased significantly in response to B-cell specific chemokines CXCL-12/CXCL-13, was further boosted upon pre-activation and occurred via paracellular and transcellular pathways. Migrating cells exhibited upregulation of several genes involved in B-cell activation/migration and enhanced expression of chemokine receptors CXCR4/CXCR5 and were predominantly of isotype class switched memory phenotype. This antigen-experienced migratory subset displayed more pronounced chemotactic activities in MS than in HC and was retrieved in intrathecal B cells from patients with active MS. Trafficking of class-switched memory B cells was downscaled in a small cohort of natalizumab-exposed MS patients and the proportions of these phenotypes were reduced in peripheral blood yet were enriched intrathecally in patients who experienced recurrence of disease activity after withdrawal of natalizumab. Conclusion: Our findings highlight the relevance of the BCSFB as an important gate for the entry of potentially harmful activated B cells into the CSF.