The role of nicotinic receptors in B-lymphocyte development and activation.

We studied the binding of [(3)H]-epibatidine and [(125)I-]alpha-bungarotoxin, as well as subunit-specific antibodies with purified B lymphocytes of C57Bl/6J mice and found that these cells contained 12,200+/-3200 of alpha4(alpha5)beta2 and 3130+/-750 of alpha7(alpha5beta4) nicotinic acetylcholine receptors per cell. According to flow cytometry data, the highest expression of alpha4(alpha5)beta2 receptors was observed in immature newly generated B lymphocytes of the bone marrow, while the number of alpha7(alpha5beta4) receptors grew up along with the B cell maturation in the spleen. By using alpha4, beta2 or alpha7 knockout and chimera mice, it was shown that both receptor subtypes supported the survival of B cell precursors and increased the size of B-lymphocyte population in the bone marrow. In contrast, propagation of mature B lymphocytes in the spleen was controlled by alpha7-containing subtype only. Moreover, mature B lymphocytes became sensitive to nicotine only in the absence of beta2-containing receptors. Knockout mice had less serum IgG, IgG-producing cells and natural IgG antibodies than their wild-type counterparts, while the absence of beta2-containing receptors resulted in increased B-lymphocyte activation and antibody immune response. The data obtained indicate that nicotinic receptors are involved in regulating B-lymphocyte development and activation, possibly, by affecting expression and/or signaling of CD40, the two subtypes playing different roles.

Peripheral B cell survival.

Recent findings suggest that lymphocyte survival is a continuous active process and support the role of B cell receptor engagement in B cell survival. In this context the conflict of survival interests between the diverse B cells gives rise to a pattern of interactions which mimics the behavior of complex ecological systems. In response to competition lymphocytes modify their survival requirements and diverge to occupy different immunological niches through differentiation. Thus naive and memory-activated B cell populations show independent homeostatic regulation. We discuss how niche differentiation allows the coexistence of different cell types and guarantees both repertoire diversity and efficient immune responses.

Transfer of small resting B cells into immunodeficient hosts results in the selection of a self-renewing activated B cell population.

We studied the role of bone marrow B cell production in the renewal of peripheral B cells and the feedback mechanisms that control the entry of newly formed B cells into the peripheral B cell pools. When resting lymph node B cells are injected into B cell-deficient hosts, a fraction of the transferred cells expands and constitutes a highly selected population that survives for prolonged periods of time by continuous cell renewal at the periphery. Although the number of donor B cells recovered is low, a significant fraction shows an activated phenotype, and the serum immunoglobulin (Ig)M levels are as in normal mice. This population of activated B cells is resistant to replacement by a new cohort of B cells and is able to feedback regulate both the entry of newly formed B cells into the peripheral pool and terminal differentiation. These findings suggest that peripheral B cell selection follows the first come, first served rule and that IgM-secreting cells are generated from a pool of stable activated B cells with an independent homeostasis.

Independent homeostatic regulation of B cell compartments.

In the present study we used mice with a developmental arrest of B cell production to study the ability of a limited number of normal B cell precursors to populate peripheral B cell pools. In chimeras reconstituted with mixtures of bone marrow (BM) cells from normal and B cell-deficient donors, we show that the rate of BM B cell production is a constant function of the number of BM pre-B cells and is not modified by the peripheral B cell pool size, i.e. there is no feedback regulation of the central pre-B cell compartment by the number of mature B cells. We also show that the physiological number of peripheral B cells requires a minimum continuous input of newly formed cells, but is not determined by the number of B cell precursors. Chimeras with a threefold reduced rate of BM B cell production have normal numbers of peripheral B cells. Parabiosis between normal and B cell-deficient mice showed that the BM B cell production of one mouse suffices to replenish the B cell pool of three mice. Finally, we show that the compartment of activated IgM-secreting B cells is homeostatically autonomous since the number of cells it comprises is regulated independently of the size of the mature B cell pool. The results presented here support a model of the immune system in which the size of the different B cell compartments, i.e. pre-B, resting B and IgM-secreting, is autonomously regulated.

Resource competition as a mechanism for B cell homeostasis.

Cellular competition for survival signals offers a cogent and appealing mechanism for the maintenance of cellular homeostasis [Raff, M. C. (1992) Nature (London) 356, 397-400]. We present a theoretical and experimental investigation of the role of competition for resources in the regulation of peripheral B cell numbers. We use formal ecological competition theory, mathematical models of interspecific competition, and competitive repopulation experiments to show that B cells must compete to persist in the periphery and that antigen forms a part of the resources over which B cells compete.

Lymphocyte homeostasis.

B- and T-lymphocyte populations have an independent homeostatic regulation of resting (B and T) and activated (B) or memory (T) cell compartments. This organization may provide an efficient mechanism to ensure simultaneously a first natural barrier of protection against common pathogens, the maintenance of immunological T-cell memory and a reservoir of repertoire diversity capable of dealing with new antigenic challenges.

Cellular competition modulates survival and selection of CD8+ T cells.

In this investigation we compare the repopulation of the CD8+ T cell compartments of bone marrow (BM) chimeras by either normal nontransgenic or T cell receptor (TcR) alpha beta-transgenic (TG) CD8+ T cells, the fate of TG and non-TG CD8+ T cells in different parabionts and the survival of TG and non-TG peripheral CD8+ T cells after transfer into athymic hosts. We found that cellular competition among CD8 T cells occurs at several steps of T cell differentiation including a) during the DN to DP transition, b) positive selection in the thymus, c) export from the thymus and d) in the periphery. Comparison of the results obtained in the BM chimeras and in the parabionts shows that an important step of T cell selection occurs during seeding of peripheral lymphoid tissues. Once established, peripheral T cells resist replacement by recent thymus migrants, i.e. in the periphery, selection of T cell repertoires follows the rule "first come, first served". Peripheral dominance correlates with T cell activation and division. Cell cycling and CD44 expression are more frequent among non-TG CD8 T cells than TG CD8 T cells and within the latter, more frequent among P14 TG CD8 T cells than anti-HYTG CD8 T cells. Thus, in the absence of intentional immunization, the frequencies of CD8+ T cells follow a hierarchy of selection in which non-TG > or = P14 TG > anti-HY TG. We also show that the equilibrium size and the fate of one CD8 T cell population differs according to the presence or absence of other CD8 T cell populations. Under these circumstances, selection of T cell repertoires and T cell survival and memory rely not only on the interactions of each T cell with their respective ligands, but also on the nature and number of other competing cells.