One reason for this might be a decreased bone marrow output. After these changes within the first years of life the absolute number of B cells remain stable while the shift from naive to memory B cells

continues. It has been suggested that the molecular pathways underlying the generation of memory B cells differ between CD27+IgD+ and CD27+IgD- memory B cells. Whereas CD27+IgD- memory B cells seem to represent post-germinal centre B cells, the development of CD27+IgD+ memory B cells (including the acquisition of somatic hypermutation) might be independent of germinal centre CX-4945 clinical trial reactions [8,24]. It has been suggested that CD27+IgD+ memory B cells represent a cellular surrogate of T cell-independent humoral immunity. Humoral immunity against encapsulated bacteria has been attributed to the presence of these memory B cells [25]. However, it is interesting to note that the age-dependent frequencies of both memory B cell subsets indicate comparable developmental stimuli (Figs 2 and 3). Recently, a B cell population lacking surface expression of CD27 but harbouring signs of memory

B cells (somatic hypermutation and immunoglobulin class switch) could be demonstrated in peripheral blood as well as in tonsils [9,10]. These memory B cells seem to be expanded in systemic autoimmunity (e.g. systemic lupus erythematosus) and chronic infectious diseases (e.g. human immunodeficiency selleck products virus, malaria) Protease Inhibitor Library research buy [10,26,27]. The role of these B cell subsets in a physiological context is not elucidated well. Although the frequency of CD27-IgD- B cells increased during the first 5 years of age, the frequency of these B cells remained stable afterwards (Fig. 2). This is in contrast to the other memory B cell subsets, which increased gradually during age. Whether the differentiation and expansion of this particular memory B cell subset underlies different molecular and cellular pathways is a matter of research. In most individuals CD24-CD38++ B cells, representing circulating plasmablasts, could be detected in low

frequencies. Frequencies of plasmablasts almost never exceeded 5% of total B cells and did not seem to show significant changes between age groups (Fig. 2). This observation seems to be worth mentioning, as expansion of plasmablasts in the peripheral blood seems to be a characteristic pattern in distinct systemic autoimmune diseases [18]. Therefore, sustained expansion of plasmablasts above this defined cut-off might be an indicator of systemic autoimmune diseases (e.g. systemic lupus erythematosus), and seems to correlate with disease activity in this disease [18]. As well as disturbed B cell homeostasis in autoimmune diseases, B cell development and differentiation is impaired in several immune deficiencies.