Human B cells accumulate immunoglobulin V gene somatic mutations in a cell contact-dependent manner in cultures supported by activated T cells but not in cultures supported by CD40 ligand

Peripheral blood CD27+ IgG+ B cells rapidly proliferate and differentiate into immunoglobulin-secreting cells after exposure to low CD154 interaction

In vitro CD40 stimulation of human B cells isolated from lymphoid organs is dominated by memory B cells undergoing faster proliferation and higher differentiation than naive B cells. In contrast, we previously reported that blood memory B cells mainly differentiate into immunoglobulin-secreting cells in response to CD40 stimulation. However, variations in CD40-CD154 interaction are now recognized to influence B-cell fate. In this study, we have compared the in vitro response of blood CD27(-) and CD27(-) IgG(-) to CD27(+) and CD27(+) IgG(+) B cells following low-density exposure to CD154 in the presence of a mixture of interleukin-2 (IL-2), IL-4 and IL-10. The evolution of these cell populations was monitored during initiation and following long-term stimulation. Over a 5-day period, CD27(+) B cells underwent differentiation into immunoglobulin-secreting cells more readily than CD27(-) cells, and CD27(+) IgG(+) B cells gave rise to a near homogeneous population of CD19(+) CD27(++) CD38(+) IgG(lo) cells capable of high immunoglobulin G (IgG) secretion. During the same period, CD27(-) IgG(-) B cells partially became CD19(++) CD27(-) CD38(-) IgG(++) cells but showed no IgG secretion. Long-term stimulation revealed that CD27(+) IgG(+) B cells retained a high expansion capacity and could maintain their momentum towards differentiation over naive B cells. In addition, long-term stimulation was driving CD27(-) IgG(-) and total CD19(+) B cells to evolve into similar CD27(+) and CD27(-) subsets, suggesting naive homeostatic proliferation. Overall, these results tend to reconcile memory B cells from blood and lymphoid organs regarding their preferential differentiation capacity compared to naive cells, and further suggest that circulating memory IgG(+) cells may be intrinsically prone to rapid activation upon appropriate stimulation.

Germinal center-independent affinity maturation in tumor necrosis factor receptor 1-deficient mice

Germinal centers (GCs) have been identified as site at which the somatic mutation of immunoglobulins occurs.However, somatic mutations in immunoglobulins have also been observed in animals that normally do not harbor germinal centers. This clearly indicates that somatic mutations can occur in the absence of germinal centers. We therefore attempted to determine whether or not GCs exist in TNFR1-deficient mice, and are essential for the somatic mutation of immunoglobulins, using (4-hydroxy-3-nitropheny)acetyl-ovalbumin (NP-OVA). Both wild-type and TNFR1-deficient mice were immunized with NPOVA, and then examined with regard to the existence of GCs. No typical B-cell follicles were detected in the TNFR1-deficient mice. Cell proliferation was detected throughout all splenic tissue types, and no in vivo immunecomplex retention was observed in the TNFR1-deficient mice. All of these data strongly suggest that no GCs were formed in the TNFR1-deficient mice. Although TNFR1-deficient mice are unable to form GCs, serological analyses indicated that affinity maturation had been achieved in both the wild-type and TNFR1-deficient mice. We therefore isolated and sequenced several DNA clones from wild-type and the TNFR1-deficient mice. Eight out of 12 wild-type clones, and 11 out of 14 clones of the TNFR-1-deficient mice contained mutations at the CDR1 site. Thus, the wild-type and TNFR1-deficient mice were not extremely different with regard to types and rates of somatic mutation. Also, high-affinity antibodies were detected in both types of mice. Collectively, our data appear to show that affinity maturation may occur in TNFR1-deficient mice, which completely lack GCs.

CD40 Stimulation of Human Peripheral B Lymphocytes: Distinct Response from Naive and Memory Cells

During secondary immune response, memory B lymphocytes proliferate and differentiate into Ig-secreting cells. In mice, the binding of CD40 by CD154 clearly enhances the activation and differentiation of memory B lymphocytes. In humans, the role of CD40-CD154 in the stimulation of memory B lymphocytes is not as obvious since in vitro studies reported positive and negative effects on their proliferation and differentiation in Ig-secreting cells. In this study, we examine the response of peripheral memory and naive cells in relation to the duration of CD40-CD154 interaction. We measured the proliferation and differentiation of both subsets stimulated with CD154 and IL-4 for short- (4-5 days) and long-term (>7 days) periods. Following short-term stimulation, memory B lymphocytes did not expand but represented the only subset differentiating into IgG- and IgM-secreting cells. A longer stimulation of this population led to cell death, while promoting naive B lymphocyte proliferation, expansion, and differentiation into IgM- or IgG-secreting cells. This prolonged CD40 stimulation also triggered naive B lymphocytes to switch to IgG and to express CD27 even in absence of somatic hypermutation, suggesting that these latter events could be independent. This study suggests that naive and memory B lymphocytes have distinct requirements to engage an immune response, reflecting their different roles in humoral immunity.

B-cell–autonomous somatic mutation deficit following bone marrow transplant

Hematopoietic stem cell transplantation is characterized by a prolonged period of humoral immunodeficiency. We have previously shown that the deficiencies are probably not due to the failure to utilize the appropriate V regions in the pre-immune repertoire. However, a striking observation, which correlated with the absence of immunoglobulin IgD− cells and was consistent with a defect in antigen-driven responses, was that rearrangements in bone marrow transplant (BMT) recipients exhibited much less somatic mutation than did rearrangements obtained from healthy subjects. In this paper, we present evidence suggesting that naive B cells obtained from BMT recipients lack the capacity to accumulate somatic mutations in a T-cell–dependent manner compared with healthy subjects. This appears to be a B-cell–autonomous deficit because T cells from some patients, which were not able to support the accumulation of mutations in autologous naive B cells, were able to support accumulation of mutations in heterologous healthy-subject naive B cells.

B-cell–autonomous somatic mutation deficit following bone marrow transplant

Hematopoietic stem cell transplantation is characterized by a prolonged period of humoral immunodeficiency. We have previously shown that the deficiencies are probably not due to the failure to utilize the appropriate V regions in the pre-immune repertoire. However, a striking observation, which correlated with the absence of immunoglobulin IgD− cells and was consistent with a defect in antigen-driven responses, was that rearrangements in bone marrow transplant (BMT) recipients exhibited much less somatic mutation than did rearrangements obtained from healthy subjects. In this paper, we present evidence suggesting that naive B cells obtained from BMT recipients lack the capacity to accumulate somatic mutations in a T-cell–dependent manner compared with healthy subjects. This appears to be a B-cell–autonomous deficit because T cells from some patients, which were not able to support the accumulation of mutations in autologous naive B cells, were able to support accumulation of mutations in heterologous healthy-subject naive B cells.

Neonatal immunity and somatic mutation

Neonatal animals are able to mount an effective immune response, both humoral and cellular, when immunized using conditions that maximize stimulation of antigen presenting cells, T cells, and B cells. In adults, somatic mutation is a key feature of the humoral immune response because it contributes to the generation of high affinity memory B cells. Recent evidence that B cells in neonatal mice and human infants can somatically mutate their immunoglobulin heavy chains suggests that neonates can utilize somatic mutation not only to diversify their restricted germline antibody repertoire, but also to improve upon this repertoire by the generation of B cells which can produce higher affinity antibodies. By extrapolation, if vaccination of children early in life resulted in somatic mutation and affinity maturation, this could provide a more protective antibody response to childhood diseases.