Many organs with a high cell turnover (for example, skin, intestine and blood) are composed of short-lived cells that require continuous replenishment by somatic stem cells1,2. Ageing results in the inability of these tissuesto maintain homeostasis and it is believed that somatic stem-cell ageing is one underlying cause of tissue attrition with age or age-related diseases. Ageing of haematopoietic stem cells (HSCs) is associated with impaired haematopoiesis in the elderly3–6. Despite a large amount of data describing the decline of HSC function on ageing, the molecular mechanisms of this process remain largely unknown, which precludes rational approaches to attenuate stem-cell ageing. Here we report an unexpected shift from canonical to non-canonical Wnt signalling in mice due to elevated expression of Wnt5a in aged HSCs, which causes stem-cell ageing. Wnt5a treatment of young HSCs induces ageing-associated stem-cell apolarity, reduction of regenerative capacity and an ageing-like myeloid–lymphoid differentiation skewing via activation of the small Rho GTPase Cdc42. Conversely, Wnt5a haploinsufficiency attenuates HSC ageing, whereas stem-cell-intrinsic reduction of Wnt5a expression results in functionally rejuvenated aged HSCs. Our data demonstrate a critical role for stem-cell-intrinsicnon-canonical Wnt5a signalling in HSC ageing.
In the past, studies on the relationships of the bacterial phyla Planctomycetes, Chlamydiae, Lentisphaerae, and Verrucomicrobia using different phylogenetic markers have been controversial. Investigations based on 16S rRNA sequence analyses suggested a relationship of the four phyla, showing the branching order Planctomycetes, Chlamydiae, Verrucomicrobia/Lentisphaerae. Phylogenetic analyses of 23S rRNA genes in this study also support a monophyletic grouping and their branching order-this grouping is significant for understanding cell division, since the major bacterial cell division protein FtsZ is absent from members of two of the phyla Chlamydiae and Planctomycetes. In Verrucomicrobia, knowledge about cell division is mainly restricted to the recent report of ftsZ in the closely related genera Prosthecobacter and Verrucomicrobium. In this study, genes of the conserved division and cell wall (dcw) cluster (ddl, ftsQ, ftsA, and ftsZ) were characterized in all verrucomicrobial subdivisions (1 to 4) with cultivable representatives (1 to 4). Sequence analyses and transcriptional analyses in Verrucomicrobia and genome data analyses in Lentisphaerae suggested that cell division is based on FtsZ in all verrucomicrobial subdivisions and possibly also in the sister phylum Lentisphaerae. Comprehensive sequence analyses of available genome data for representatives of Verrucomicrobia, Lentisphaerae, Chlamydiae, and Planctomycetes strongly indicate that their last common ancestor possessed a conserved, ancestral type of dcw gene cluster and an FtsZ-based cell division mechanism. This implies that Planctomycetes and Chlamydiae may have shifted independently to a non-FtsZ-based cell division mechanism after their separate branchings from their last common ancestor with Verrucomicrobia.
IntroductionAll mature blood cells derive from HSCs. These HSCs have been shown to reside mainly in specialized microenvironments, referred to as niches. It is thought that the niche regulates HSC quiescence (dormancy), self-renewal, and differentiation by expression of surface molecules and secretion of soluble factors. Which signals are provided by the niche and how exactly these signals affect HSCs still remains uncertain. 1 We have established a number of stromal cell clones from mid gestation embryonic sources, of which we identified 2 cell lines (EL08-1D2 and UG26-1B6) which maintain fetal as well as adult HSCs, even though they had no direct contact with the hematopoietic cells (noncontact cocultures). 2,3 In gene expression studies, we observed that, in comparison to a number of nonsupporting stromal cell lines, those 2 cell lines both expressed larger amounts of mRNA corresponding to a number of secreted molecules. We recently described that one of these factors, secreted frizzledrelated protein 1, is required for sustained self-renewal of HSCs in vivo and that this was because of extrinsic regulation of HSCs by the microenvironment, most probably, through regulating -catenin (Ctnnb1) and peroxisome proliferator-activated receptor ␥ (Pparg), both mediators of the Wnt signaling pathways. 4 One other overrepresented factor was the pleiotrophic cytokine pleiotrophin (Ptn). 3 Ptn was also found to be overexpressed by other HSC supportive cells, such as human brain endothelial cells 5,6 or the stromal cell line AFT024, 7 suggesting that high expression of Ptn may be a common feature among HSC-supportive stromal cells.Ptn, because of its pleiotrophic activities, is known under many alternative names, including heparin-binding growth-associated molecule and osteoblast-stimulating factor. Ptn is a highly conserved 17-kDa cytokine, 8 which, together with Midkine, forms a small family of low molecular weight factors. 9 Several receptors are known to bind Ptn as a ligand: receptor protein tyrosine phosphatase / (Rptpz1), 10 nucleolin, 11 and N-syndecan. 12 It was recently shown that Rptpz1 is expressed on BM-derived lineage Ϫ Ly6a ϩ Kit ϩ (LSK) cells. 6 Binding of Ptn to RPTP/ inactivates the phosphatase domain through dimerization of the receptor. This leads to an increasing phosphorylation status of the numerous targets of RPTP/, including -catenin, ALK, -adducin, CD81, c-Fyn, and others. 10,13 The effects of Ptn on proliferation and differentiation appear to converge in -catenin and its downstream factor Dlk1. 10,14 Interestingly, Dlk1 has previously been identified to be overrepresented in the Ptn-overexpressing HSC-maintaining cell line AFT024 and to promote cobblestone area formation by HSC-derived progeny. 15 Because it was shown that Rptpz1 is expressed on BM-derived LSK cells, 6 these pathways may well be relevant in HSC regulation.Ptn is known to play important roles in proliferation and differentiation in various cell types. It was shown that Ptn is mitogenic for fibroblasts, epithelial, and endo...
2330 Hematopoietic stem cells (HSCs) are characterized by their ability to self-renewal and multilineage differentiation. Since mostly HSCs exist in a quiescent state re-entry into cell cycle is essential for their regeneration and differentiation and the expression of numerous cell cycle regulators must be tightly controlled. We previously characterized NIPA (Nuclear Interaction Partner of ALK) as a F-Box protein that defines an oscillating ubiquitin E3 ligase targeting nuclear cyclin B1 in interphase thus contributing to the timing of mitotic entry. To examine the function of NIPA on vivo, we generated NIPA deficient animals, which are viable but sterile due to a defect in recombination and testis stem cell maintenance. To further characterize the role of NIPA in stem cell maintenance and self-renewal we investigated hematopoiesis in NIPA deficient animals. Peripheral blood counts taken at different ages revealed no apparent difference between NIPA knockout and wild type mice in numbers and differentiation. In contrast, looking at the hematopoietic stem cell pool, FACS analyses of bone marrow showed significantly decreased numbers of Lin-Sca1+cKit+ (LSK) cells in NIPA deficient animals, where LSKs were reduced to 40% of wild type littermates (p=0,0171). This effect was only apparent in older animals, where physiologically higher LSK numbers have to compensate for the exhaustion of the stem cell pool. Additionally, older NIPA deficient mice have only half the amount of multi myeloid progenitors (MMPs) in contrast to wild type animals. To examine efficient activation of stem cells to self-renew in response to myeloid depression, we treated young and old mice with the cytotoxic drug (5-FU) four days before bone marrow harvest. As expected, 5-FU activated hematopoietic progenitors in wild type animals, whereas NIPA deficient progenitors failed to compensate to 5-FU depression, e.g. LSKs of NIPA knockout mice were reduced to 50% of wild type levels (p<0.001), CD150+CD34+ Nipa deficient cells to 20% of wild type levels (p<0.0001). Interestingly, these effects were seen in all NIPA deficient animals independent of age, allowing us to trigger the self-renewal phenotype by activating the hematopoietic stem cell pool. Using competitive bone marrow transplantation assays, CD45.2 positive NIPA deficient or NIPA wild type bone marrow cells were mixed with CD45.1 positive wild type bone marrow cells and transplanted into lethally irradiated CD45.2 positive recipient mice. Thirty days after transplantation, FACS analysis of peripheral blood and bone marrow showed reduced numbers of NIPA knockout cells in comparison to NIPA wild type bone marrow recipient mice. This result was even more severe with aging of transplanted mice, where NIPA deficient cells were reduced to less than 10% of the level of wild type cells in bone marrow of sacrificed mice 6 months after transplantation, pointing to a profound defect in repopulation capacity of NIPA deficient HSCs. Taken together our results demonstrate a unique and critical role of NIPA in regulating the primitive hematopoietic compartment as a regulator of self-renewal, cycle capacity and HSC expansion. Disclosures: No relevant conflicts of interest to declare.
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