The Paf oncogene is essential for hematopoietic stem cell function and development.

Hematopoietic stem cells (HSCs) self-renew to maintain the lifelong production of all blood populations. Here, we show that the proliferating cell nuclear antigen-associated factor (Paf) is highly expressed in cycling bone marrow HSCs and plays a critical role in hematopoiesis. Mice lacking Paf exhibited reduced bone marrow cellularity; reduced numbers of HSCs and committed progenitors; and leukopenia. These phenotypes are caused by a cell-intrinsic blockage in the development of long-term (LT)-HSCs into multipotent progenitors and preferential loss of lymphoid progenitors caused by markedly increased p53-mediated apoptosis. In addition, LT-HSCs from Paf(-/-) mice had increased levels of reactive oxygen species (ROS), failed to maintain quiescence, and were unable to support LT hematopoiesis. The loss of lymphoid progenitors was likely due the increased levels of ROS in LT-HSCs caused by treatment of Paf(-/-) mice with the anti-oxidant N-acetylcysteine restored lymphoid progenitor numbers to that of Paf(+/+) mice. Collectively, our studies identify Paf as a novel and essential regulator of early hematopoiesis.

Identification and in vivo analysis of murine hematopoietic stem cells.

Hematopoietic stem cells (HSCs) can self-renew and give rise to all the cells of the blood and the immune system. As they differentiate, HSCs progressively lose their self-renewal capacity and generate lineage-restricted multipotential progenitor cells that in turn give rise to mature cells. The development of rigorous quantitative in vivo assays for HSC activity combined with multicolor flow cytometry and high-speed sorting have resulted in the phenotypic definition of HSCs to virtual purity. Here, we describe the isolation and identification of HSCs by flow cytometry and the use of competitive repopulation to assess HSC number and function.

Marginal zone B cell enrichment and strong follicular B cell reduction correlate with a delayed IgG response in a light chain diversity restricted mouse model.

Recently developed B6.kappa(-)lambda(SEG) mice (by crossing kappa(-) and C57BL/6 mice congenic for the wild Mus spretus SEG strain lambda locus lacking genes coding for lambda1 and lambda3) have a very reduced light chain diversity. B6.kappa(-)lambda(SEG) mice produce only lambda2 and lambdax light chains. Regardless of their Igh haplotype, B6.kappa(-)lambda(SEG) mice show a restricted B cell distribution by light chain subtype with lambdax dominance in all peripheral compartments except peritoneal cavity where lambda2 is dominant. This distribution suggests that selection mechanisms act differently in different B cell compartments on lambda2 and lambdax bearing B cells. Sequence analysis before or following immunization did not reveal unusual mechanisms of diversification. B6.kappa(-)lambda(SEG) mice still respond to various challenging antigens using new Ab patterns. In particular, regardless of Igh(a) or Igh(b) haplotypes, the anti-2,4-dinitrophenyl response is characterized by a restricted diversity for both heavy and light chains and a delayed IgG response when compared to B6 and B6.kappa(-) mice. We suggest that the delayed IgG response is due to the expansion of marginal zone B cells whereas follicular B cells are strongly reduced.

The Ig light chain restricted B6.kappa(-)lambda(SEG) mouse strain suggests that the IGL locus genomic organization is subject to constant evolution.

In laboratory mice, the different Ig lambda light chain subtypes (lambda 1, lambda 2, lambda x and lambda 3) are expressed on 60, 16, 16 and 8%, respectively, of the lambda-positive peripheral B cells. Eighteen years ago, our laboratory characterized a lambda 1(-) wild mouse strain: SPE ( Mus spretus). In this report, we describe the characterization of another wild-derived Mus spretus inbred strain, SEG, that presents the same characteristic, namely the absence of lambda 1 expression. An almost congenic strain, B6.lambda(SEG), was detected in a series of recombinant congenic strains carrying 2% of SEG/Pas genome in a C57BL/6J background. This B6.lambda(SEG) strain was crossed to Igh (a) C kappa (-) mice in order to derive two different additional congenic strains: B6.kappa(-)lambda(SEG) Igh (a) and B6.kappa(-)lambda(SEG) Igh (b). In this paper, we characterize the genomic organization and the expression of the SEG IGL locus. Altogether, our data show that the SEG IGL locus is constituted by a single functional IGLJ2SEG-IGLC2SEG, two pseudo IGLJ4SEG1/2-IGLC4SEG1/2 gene clusters and two V gene segments: IGLV2SEG and IGLVXSEG. In particular, we show the absence of IGLV1 and IGLVSD26 gene segments. IGLVSD26 was reported to be present in some Mus m. musculus mice and absent in BALB/c. Here, we confirm its presence not only in other Mus m. musculus mice but also in Mus spretus mice. Consequently, we propose that IGLVSD26-related gene segments define a new family that we name V lambda 4. The study of the organization of different IGL loci, in addition to the V lambda 4(+) reported here, could elucidate questions concerning the evolution of the lambda locus.