Juli P. Miller

Thymopoiesis independent of common lymphoid progenitors

Early T lineage progenitors (ETPs) in the thymus are thought to develop from common lymphoid progenitors (CLPs) in the bone marrow (BM). We compared thymic ETPs to BM CLPs in mice and found that they differed in several respects. Thymic ETPs were not interleukin 7 (IL-7)–responsive and generated B lineage progeny with delayed kinetics, whereas BM CLPs were IL-7–responsive and rapidly generated B cells. ETPs sustained production of T lineage progeny for longer periods of time than BM CLPs. Analysis of Ikaros-deficient mice that exhibit ongoing thymopoiesis without B lymphopoeisis revealed near-normal frequencies of thymic ETPs, yet undetectable numbers of BM CLPs. We conclude that ETPs can develop via a CLP-independent pathway.

The Decline in B Lymphopoiesis in Aged Mice Reflects Loss of Very Early B-Lineage Precursors

The primary age-related loss in B cell progenitors is thought to be at the pro- to pre-B cell transition. However, we show that the frequencies and absolute numbers of all progenitor populations for the B cell lineage, including B-lineage-committed pro-B cells and multipotent B-lymphoid progenitors, decline in aged C57BL/6 mice. Moreover, when derived from aged mice, lymphoid progenitors within every population examined exhibited suboptimal IL-7 responsiveness, demonstrating that age-associated suboptimal IL-7R signaling is a general property of all early B-lineage precursors. Collectively, these data indicate that aging results in a previously unappreciated decline in the earliest stages of B cell development.

The Earliest Step in B Lineage Differentiation from Common Lymphoid Progenitors Is Critically Dependent upon Interleukin 7

Little is known about the signals that promote early B lineage differentiation from common lymphoid progenitors (CLPs). Using a stromal-free culture system, we show that interleukin (IL)-7 is sufficient to promote the in vitro differentiation of CLPs into B220+ CD19+ B lineage progenitors. Consistent with current models of early B cell development, surface expression of B220 was initiated before CD19 and was accompanied by the loss of T lineage potential. To address whether IL-7 receptor (R) activity is essential for early B lineage development in vivo, we examined the frequencies of CLPs and downstream pre–pro- and pro-B cells in adult mice lacking either the α chain or the common gamma chain (γc) of the IL-7R. The data indicate that although γc −/− mice have normal frequencies of CLPs, both γc −/− and IL-7Rα−/− mice lack detectable numbers of all downstream early B lineage precursors, including pre–pro-B cells. These findings challenge previous notions regarding the point in B cell development affected by the loss of IL-7R signaling and suggest that IL-7 plays a key and requisite role during the earliest phases of B cell development.

Tonic B cell antigen receptor signals supply an NF-κB substrate for prosurvival BLyS signaling

The survival of transitional and mature B cells requires both the B cell antigen receptor (BCR) and BLyS receptor 3 (BR3), which suggests that these receptors send signals that are nonredundant or that engage in crosstalk with each other. Here we show that BCR signaling induced production of the nonclassical transcription factor NF-κB pathway substrate p100, which is required for transmission of BR3 signals and thus B cell survival. The capacity for sustained p100 production emerged during transitional B cell differentiation, the stage at which BCR signals begin to mediate survival rather than negative selection. Our findings identify a molecular mechanism for the reliance of primary B cells on continuous BR3 and BCR signaling, as well as for the gradual resistance to negative selection that is acquired during B cell maturation.

BLyS inhibition eliminates primary B cells but leaves natural and acquired humoral immunity intact

We have used an inhibiting antibody to determine whether preimmune versus antigen-experienced B cells differ in their requisites for BLyS, a cytokine that controls differentiation and survival. Whereas in vivo BLyS inhibition profoundly reduced naïve B cell numbers and primary immune responses, it had a markedly smaller effect on memory B cells and long-lived plasma cells, as well as secondary immune responses. There was heterogeneity within the memory pools, because IgM-bearing memory cells were sensitive to BLyS depletion whereas IgG-bearing memory cells were not, although both were more resistant than naïve cells. There was also heterogeneity within B1 pools, as splenic but not peritoneal B1 cells were diminished by anti-BLyS treatment, yet the number of natural antibody-secreting cells remained constant. Together, these findings show that memory B cells and natural antibody-secreting cells are BLyS-independent and suggest that these pools can be separately manipulated.

B Lineage-specific Regulation of V(D)J Recombinase Activity Is Established in Common Lymphoid Progenitors

Expression of V(D)J recombinase activity in developing lymphocytes is absolutely required for initiation of V(D)J recombination at antigen receptor loci. However, little is known about when during hematopoietic development the V(D)J recombinase is first active, nor is it known what elements activate the recombinase in multipotent hematopoietic progenitors. Using mice that express a fluorescent transgenic V(D)J recombination reporter, we show that the V(D)J recombinase is active as early as common lymphoid progenitors (CLPs) but not in the upstream progenitors that retain myeloid lineage potential. Evidence of this recombinase activity is detectable in all four progeny lineages (B, T, and NK, and DC), and rag2 levels are the highest in progenitor subsets immediately downstream of the CLP. By single cell PCR, we demonstrate that V(D)J rearrangements are detectable at IgH loci in ∼5% of splenic natural killer cells. Finally, we show that recombinase activity in CLPs is largely controlled by the Erag enhancer. As activity of the Erag enhancer is restricted to the B cell lineage, this provides the first molecular evidence for establishment of a lineage-specific transcription program in multipotent progenitors.

Mice deficient for testis-brain RNA-binding protein exhibit a coordinate loss of TRAX, reduced fertility, altered gene expression in the brain, and behavioral changes.

ABSTRACT Testis-brain RNA-binding protein (TB-RBP), the mouse orthologue of the human protein Translin, is a widely expressed and highly conserved protein with proposed functions in chromosomal translocations, mitotic cell division, and mRNA transport and storage. To better define the biological roles of TB-RBP, we generated mice lacking TB-RBP. Matings between heterozygotes gave rise to viable, apparently normal homozygous mutant mice at a normal Mendelian ratio. The TB-RBP-related and -interacting protein Translin-associated factor X was reduced to 50% normal levels in heterozygotes and was absent in TB-RBP-null animals. The null mice were 10 to 30% smaller than their wild-type or heterozygote littermates at birth and remained so to about 6 to 9 months of age, showed normal B- and T-cell development, and accumulated visceral fat. TB-RBP-null male mice were fertile and sired offspring but had abnormal seminiferous tubules and reduced sperm counts. Null female mice were subfertile and had reduced litter sizes. Microarray analysis of total brain RNA from null and wild-type mice revealed an altered gene expression profile with the up-regulation of 14 genes and the down-regulation of 217 genes out of 12,473 probe sets. Numerous neurotransmitter receptors and ion channels, including γ-aminobutyric acid A receptor α1 and glutamate receptor α3, were strongly down-regulated. Behavioral abnormalities were also seen. Compared to littermates, the TB-RBP-null mice appeared docile and exhibited reduced Rota-Rod performance.

The aging of early B-cell precursors

Summary:  B‐cell genesis in the bone marrow declines with advancing age. In this review, we discuss our current understanding of why B‐cell production rates decline with age with a special emphasis on why age‐related factors might target very early lymphoid precursors. We consider the impact of aging on cytokine responsiveness and how current models for lineage relationships for very early B‐ and T‐cell precursors might influence interpretations of experiments addressing age‐associated declines in B‐ and T‐cell differentiation. This discussion centers on the notion that aging affects events associated with the process by which hematopoietic stem cells are guided toward the B‐cell pathway. Finally, we present a model in which the age‐associated loss of early B‐cell precursors is linked to suboptimal function of key transcriptional regulators of very early B‐cell development.

B cells and aging: Balancing the homeostatic equation

The interplay of selective and homeostatic processes dominates the behavior of B lineage subsets following B cell antigen receptor (BCR) expression, and extends to determinants of immune response quality and the persistence of immunologic memory. A key concept emerging from these considerations is that primary events acting upstream of mature B lymphocyte pools can profoundly impact downstream populations as the system attempts homeostatic adjustments. Since, advancing age is accompanied by profound changes in B cell generation and homeostasis, establishing the relative contributions of primary lesions versus compensatory homeostatic processes is critical to understanding these perturbations. Exploration of this problem requires an understanding of: (1) the identity, dynamics, and progenitor/successor relationships of marrow and peripheral B cell subsets; (2) the nature and interactions of selective and homeostatic processes acting in these subsets; (3) how these change with age. Our data show that BLyS and its receptors mediate peripheral B cell homeostasis, and that the size, dynamics and behavior of all B cell subsets influenced by B Lymphocyte Stimulator change with age. These findings suggest that homeostatic processes mediated through B Lymphocyte Stimulator are altered with age, and that these perturbations may primarily reflect compensatory homeostatic adjustments to upstream reductions in B cell generation.

The biology of chronic myelogenous leukemia:mouse models and cell adhesion.

Chronic myelogenous leukemia (CML) is a biphasic neoplasm of the bone marrow that is precipitated by the Philadelphia chromosome, a t(9;22) balanced translocation that encodes a constitutively activated nonreceptor tyrosine kinase termed P210BCR-ABL. This oncoprotein has several intracellular functions; however, the most important effect of P210BCR-ABL leading to cell transformation is phosphorylation of signaling molecules through a constitutively active tyrosine kinase domain. Despite extensive knowledge of the structure and functional domains of BCR-ABL, its precise function in transformation is not known. Progress has been hampered, in part, by the lack of relevant CML models, as cell culture and in vitro assays do not mimic the pathogenesis of CML. Recently, there has been significant progress toward improving murine models that closely resemble human CML. This has allowed researchers to evaluate critical functions of BCR-ABL and has provided a model to test the efficacy of therapeutic medications that block these pathways. Our laboratory has developed two intersecting research programs to better understand the functioning of P210BCR-ABL in leukemogenesis. In one approach, we have developed a murine CML model by transferring HSCs that express BCR-ABL from a retroviral vector. All recipients develop a rapidly fatal MPD that shares several important features with CML. This model has been extremely useful for studying the function of BCR-ABL in the pathogenesis of CML. A second approach utilizes a quantitative cell detachment apparatus capable of measuring small changes in cell adhesion to investigate the mechanism by which P210BCR-ABL causes abnormal cell binding. Altered cell adhesion may contribute to the imbalance between proliferation and self-renewal in the hematopoietic progenitor compartment. To better understand the role abnormal adhesion may play in the development of leukemia, we have attempted to correlate the effects of functional P210BCR-ABL mutants in regulating adhesion and oncogenicity.