Project description:Repolarization of HSC attenuates HSCs failure in Shwachman-Diamond syndrome

Project description:Hematopoietic stem cells (HSCs) balance self-renewal and differentiation to maintain homeostasis. With aging, the frequency of polar HSCs decreases. Cell polarity in HSCs is controlled by the activity of the small RhoGTPase Cdc42. Here we demonstrate, using a comprehensive set of paired daughter cell analyses that include single cell 3D-confocal imaging, single cell transplants, single cell RNA-seq as well as single cell ATAC-seq, that the outcome of HSC divisions is strongly linked to the polarity status before mitosis, which is in turn determined by the level of the activity Cdc42 in stem cells. Aged apolar HSCs undergo preferentially self-renewing symmetric divisions, resulting in daughter stem cells with reduced regenerative capacity and lymphoid potential, while young polar HSCs undergo preferentially asymmetric divisions. Mathematical modeling in combination with experimental data implies a mechanistic role of the asymmetric sorting of Cdc42 in determining the potential of daughter cells via epigenetic mechanisms. Therefore, molecules that control HSC polarity might serve as modulators of the mode of stem cell division regulating the potential of daughter cells.

Project description:Hematopoietic stem cells (HSCs) balance self-renewal and differentiation to maintain homeostasis. With aging, the frequency of polar HSCs decreases. Cell polarity in HSCs is controlled by the activity of the small RhoGTPase Cdc42. Here we demonstrate, using a comprehensive set of paired daughter cell analyses that include single cell 3D-confocal imaging, single cell transplants, single cell RNA-seq as well as single cell ATAC-seq, that the outcome of HSC divisions is strongly linked to the polarity status before mitosis, which is in turn determined by the level of the activity Cdc42 in stem cells. Aged apolar HSCs undergo preferentially self-renewing symmetric divisions, resulting in daughter stem cells with reduced regenerative capacity and lymphoid potential, while young polar HSCs undergo preferentially asymmetric divisions. Mathematical modeling in combination with experimental data implies a mechanistic role of the asymmetric sorting of Cdc42 in determining the potential of daughter cells via epigenetic mechanisms. Therefore, molecules that control HSC polarity might serve as modulators of the mode of stem cell division regulating the potential of daughter cells.

Project description:The decline of hematopoietic stem cell (HSC) function upon aging contributes to the senescent immune remodeling and to leukemia pathogenesis. Aged HSCs show changes in their epigenome, like alterations in the global and local DNA/histone methylation and histone acetylation landscape. Previously, we showed a correlation between high Cdc42 activity and the loss of intra-nuclear epigenetic polarity (epipolarity), as indicated by the specific location of histone H4 lysine 16 acetylation (H4K16ac). Here, we show that not all histone modifications display a polar localization and that loss of H4K16ac amount and epipolarity is specific to aged HSCs. Increased levels of H4K16ac are insufficient to restore polarity in aged HSCs and for the restoration of HSC function. Changes in H4K16ac upon aging and rejuvenation of HSCs are correlated to a shift of chromosome 11 architecture and nuclear volume and shape. Surprisingly, by taking advantage of knock-out mouse models we demonstrate that increased Cdc42 activity levels correlate with the repression of LaminA/C expression, which control chromosome 11 distribution, H4K16ac polarity and the nuclear volume and shape of aged HSCs. These chromatin and epigenetic architecture changes are targeted by altering the activity of the small RhoGTPase Cdc42, that regulates LaminA/C. Collectively, our data show that chromatin architecture changes in stem cells are reversible by changing levels of Cdc42 activity, revealing an unanticipated way to pharmacologically target LaminA/C expression and revert alterations of the epigenetic architecture in aged HSCs.

Project description:Although anemia is common in Shwachman-Diamond syndrome (SDS), the underlying mechanism remains unclear. We asked whether SBDS, which is mutated in most SDS patients, is critical for erythroid development. We found that SBDS expression is high early during erythroid differentiation. Inhibition of SBDS in CD34+ hematopoietic stem cells and early progenitors (HSC/Ps) and K562 cells led to slow cell expansion during erythroid differentiation. Induction of erythroid differentiation resulted in markedly accelerated apoptosis in the knockdown cells; however, proliferation was only mildly reduced. The percentage of cells entering differentiation was not reduced. Differentiation also increased the oxidative stress in SBDS-knockdown K562 cells, and antioxidants enhanced the expansion capability of differentiating SBDS-knockdown K562 cells and colony production of SDS patient HSC/Ps. Erythroid differentiation also resulted in reduction of all ribosomal subunits and global translation. Furthermore, stimulation of global translation with leucine improved the erythroid cell expansion of SBDS-knockdown cells and colony production of SDS patient HSC/Ps. Leucine did not reduce the oxidative stress in SBDS-deficient K562 cells. These results demonstrate that SBDS is critical for normal erythropoiesis. Erythropoietic failure caused by SBDS-deficiency is at least in part related to elevated ROS levels and translation insufficiency since antioxidants and leucine improved cell expansion.

Project description:Monosomy 7 or deletion of 7q (del(7q)) frequently arise in inherited and acquired bone marrow failure, and are associated with progression to high grade Myelodysplastic Syndrome (MDS) and acute leukemia. Current non-transplant approaches to treat marrow failure may be complicated by potential stimulation of clonal outgrowth. To study the biological consequences of del(7q) within the context of a failing marrow, we utilized induced pluripotent stem cells (iPSCs) derived from patients with Shwachman Diamond Syndrome (SDS) and genomically engineered a deletion of (7q). Deletion of 7q failed to confer a relative fitness advantage in either pluripotent SDS iPSC or in iPSC-derived SDS CD34+ cells. The TGF-beta pathway was the top differentially regulated pathway in transcriptome analysis with the TGF pathway found activated in SDS-iPSCs, compared to SDS-del(7q) iPSCs. Increased phosphorylation of SMAD2 in SDS-iPSCs was reduced following del(7q) and increased upon restoration of 7q diploidy, in support of an effect of 7q dosage on the activation status of the TGF-beta pathway in SDS. Inhibition of the TGF-beta pathway rescued hematopoiesis in SDS-iPSCs and in primary bone marrow cells from SDS patients without improving hematopoiesis of the SDS-del(7q) cells. Together, these results utilizing an iPSC model of MDS in BMF identified a targetable vulnerability for potential therapeutic strategies to ameliorate bone marrow failure without promoting outgrowth of the del7q clone.

Project description:Monosomy 7 or deletion of 7q (del(7q)) frequently arise in inherited and acquired bone marrow failure, and are associated with progression to high grade Myelodysplastic Syndrome (MDS) and acute leukemia. Current non-transplant approaches to treat marrow failure may be complicated by potential stimulation of clonal outgrowth. To study the biological consequences of del(7q) within the context of a failing marrow, we utilized induced pluripotent stem cells (iPSCs) derived from patients with Shwachman Diamond Syndrome (SDS) and genomically engineered a deletion of (7q). Deletion of 7q failed to confer a relative fitness advantage in either pluripotent SDS iPSC or in iPSC-derived SDS CD34+ cells. The TGF-beta pathway was the top differentially regulated pathway in transcriptome analysis with the TGF pathway found activated in SDS-iPSCs, compared to SDS-del(7q) iPSCs. Increased phosphorylation of SMAD2 in SDS-iPSCs was reduced following del(7q) and increased upon restoration of 7q diploidy, in support of an effect of 7q dosage on the activation status of the TGF-beta pathway in SDS. Inhibition of the TGF-beta pathway rescued hematopoiesis in SDS-iPSCs and in primary bone marrow cells from SDS patients without improving hematopoiesis of the SDS-del(7q) cells. Together, these results utilizing an iPSC model of MDS in BMF identified a targetable vulnerability for potential therapeutic strategies to ameliorate bone marrow failure without promoting outgrowth of the del7q clone.

Project description:Mutations in the DNAJC21 gene were recently described in Shwachman-Diamond syndrome (SDS), a bone marrow failure syndrome with high predisposition for myeloid malignancies. To study the underlying biology in hematopoiesis regulation and disease, we generated the first in vivo model of Dnajc21 deficiency using zebrafish. Zebrafish dnajc21 mutants phenocopy key SDS patient phenotypes such as cytopenia, reduced growth and defective ribosome biogenesis. We show that cytopenia results from impaired hematopoietic differentiation and cell proliferation, and is accompanied by an expansion of hematopoietic stem and progenitor cells during both embryonic and adult hematopoiesis. The introduction of a tp53 point mutation in the dnajc21 mutants results in myelodysplastic syndrome with erythroid dysplasia as early as four months of age. Using transcriptomic and metabolomic analyses, we show that Dnajc21 regulates various metabolic pathways including nucleotide biosynthesis. Chemical modulation of the pyrimidine biosynthesis pathway in dnajc21 mutants reveals an association with neutrophil differentiation, suggesting a novel mechanism in dnajc21-mutant SDS biology.

Project description:One goal of regenerative medicine is to rejuvenate tissues and extend lifespan by restoring the function of endogenous aged stem cells. However, evidence that somatic stem cells can be targeted in vivo to extend lifespan is still lacking. Here, we demonstrate that after a short systemic treatment with a specific inhibitor of the small RhoGTPase Cdc42 (CASIN), transplanting aged hematopoietic stem cells (HSCs) from treated mice is sufficient to extend the healthspan and lifespan of aged immunocompromised mice without additional treatment. In detail, we show that systemic CASIN treatment improves strength and endurance of aged mice by increasing the myogenic regenerative potential of aged skeletal muscle stem cells. Further, we show that CASIN modifies niche localization and H4K16ac polarity of HSCs in vivo. Single cell profiling reveals changes in HSC transcriptome, which underlie enhanced lymphoid and regenerative capacity in serial transplantation assays. Overall, we provide proof-of-concept evidence that a short systemic treatment to decrease Cdc42 activity improves the regenerative capacity of different endogenous aged stem cells in vivo, and that rejuvenated HSCs exert a broad systemic effect sufficient to extend murine health- and lifespan.

Project description:With ageing, intrinsic hematopoietic stem cell (HSC) activity decreases, resulting in impaired tissue homeostasis, reduced engraftment following transplantation and increased susceptibility to diseases. However, whether ageing affects also the HSC niche impairing the capacity to support HSC function is still largely unknown. Here, by using in-vivo long-term label retention assays we demonstrate that aged labelling retaining (LR) HSCs, which are in the old mice the most quiescent HSC subpopulation with the highest regenerative capacity and cellular polarity, reside predominantly in perisinusoidal niches. Furthermore, we demonstrate that sinusoidal niches and perisinusoidal Nes-GFPlow cells are uniquely preserved in shape, morphology and number upon ageing. Finally, we show that myeloablative chemotherapy can selectively disrupt aged sinusoidal niches, which is linked to hematopoietic failure and decreased survival of aged mice. Overall, our data characterize for the first time the functional alterations of the aged HSC niche and unveil that perisinusoidal niches are uniquely preserved and protect HSCs from ageing.