Project description:Mesenchymal Stromal Cells (MSCs) have been employed in vitro to support HSPC expansion and in vivo to promote Hematopoietic Stem and Progenitor Cells (HSPCs) engraftment. Based on these studies, we developed an MSC-based co-culture system to optimize transplantation outcome of CRISPR-Cas9 gene-edited (GE) human HSPCs. We show that bone marrow (BM)-MSCs produce several hematopoietic supportive and anti-inflammatory factors capable to alleviate the proliferation arrest and mitigate the apoptotic and inflammatory programs activated in GE-HSPCs, improving their expansion and clonogenic potential in vitro. The use of BM-MSCs resulted in superior human engraftment and increased clonal output of GE-HSPCs contributing to the early phase of hematological reconstitution in the peripheral blood of transplanted mice. In conclusion, our work poses the biological bases for a novel clinical use of BM-MSCs to promote engraftment of GE-HSPCs and improve their transplantation outcome.

Project description:Mesenchymal Stromal Cells (MSCs) have been employed in vitro to support HSPC expansion and in vivo to promote Hematopoietic Stem and Progenitor Cells (HSPCs) engraftment. Based on these studies, we developed an MSC-based co-culture system to optimize transplantation outcome of CRISPR-Cas9 gene-edited (GE) human HSPCs. We show that bone marrow (BM)-MSCs produce several hematopoietic supportive and anti-inflammatory factors capable to alleviate the proliferation arrest and mitigate the apoptotic and inflammatory programs activated in GE-HSPCs, improving their expansion and clonogenic potential in vitro. The use of BM-MSCs resulted in superior human engraftment and increased clonal output of GE-HSPCs contributing to the early phase of hematological reconstitution in the peripheral blood of transplanted mice. In conclusion, our work poses the biological bases for a novel clinical use of BM-MSCs to promote engraftment of GE-HSPCs and improve their transplantation outcome.

Project description:Mesenchymal Stromal Cells (MSCs) have been employed in vitro to support HSPC expansion and in vivo to promote Hematopoietic Stem and Progenitor Cells (HSPCs) engraftment. Based on these studies, we developed an MSC-based co-culture system to optimize transplantation outcome of CRISPR-Cas9 gene-edited (GE) human HSPCs. We show that bone marrow (BM)-MSCs produce several hematopoietic supportive and anti-inflammatory factors capable to alleviate the proliferation arrest and mitigate the apoptotic and inflammatory programs activated in GE-HSPCs, improving their expansion and clonogenic potential in vitro. The use of BM-MSCs resulted in superior human engraftment and increased clonal output of GE-HSPCs contributing to the early phase of hematological reconstitution in the peripheral blood of transplanted mice. In conclusion, our work poses the biological bases for a novel clinical use of BM-MSCs to promote engraftment of GE-HSPCs and improve their transplantation outcome.

Project description:Clonal hematopoiesis (CH) is a common premalignant state in the blood and confers an increased risk of blood cancers and all-cause mortality. Identification of therapeutic targets in CH has been hindered by the lack of an ex vivo platform amenable for studying primary hematopoietic stem and progenitor cells (HSPCs) with and without CH-associated mutations. Here, we utilize an ex vivo co-culture system of primary murine HSPCs with bone marrow endothelial cells to perform CRISPR/Cas9 screens and identify vulnerabilities specific to mutant versus wild-type HSPCs. Our data reveal that loss of the histone demethylase family members KDM3B and JMJD1C specifically reduces the fitness of IDH2- and TET2- mutant HSPCs, but not wild-type HSPCs, including in TET2-mutant human HSPCs and Tet2-mutant murine leukemia cells with cooperating disease alleles. KDM3B loss in mutant cells leads to decreased expression of critical cytokine receptors including MPL, rendering mutant HSPCs preferentially susceptible to inhibition of downstream JAK2 signaling. Our study provides a scalable platform to identify genetic dependencies in mutant HSPCs and reveals an atlas of dependencies in normal and CH-mutant HSPCs. This study nominates an epigenetic regulator and an epigenetically regulated receptor signaling pathway as genotype-specific therapeutic targets in a subset of CH and myeloid malignancies.

Project description:Clonal hematopoiesis (CH) is a common premalignant state in the blood and confers an increased risk of blood cancers and all-cause mortality. Identification of therapeutic targets in CH has been hindered by the lack of an ex vivo platform amenable for studying primary hematopoietic stem and progenitor cells (HSPCs) with and without CH-associated mutations. Here, we utilize an ex vivo co-culture system of primary murine HSPCs with bone marrow endothelial cells to perform CRISPR/Cas9 screens and identify vulnerabilities specific to mutant versus wild-type HSPCs. Our data reveal that loss of the histone demethylase family members KDM3B and JMJD1C specifically reduces the fitness of IDH2- and TET2- mutant HSPCs, but not wild-type HSPCs, including in TET2-mutant human HSPCs and Tet2-mutant murine leukemia cells with cooperating disease alleles. KDM3B loss in mutant cells leads to decreased expression of critical cytokine receptors including MPL, rendering mutant HSPCs preferentially susceptible to inhibition of downstream JAK2 signaling. Our study provides a scalable platform to identify genetic dependencies in mutant HSPCs and reveals an atlas of dependencies in normal and CH-mutant HSPCs. This study nominates an epigenetic regulator and an epigenetically regulated receptor signaling pathway as genotype-specific therapeutic targets in a subset of CH and myeloid malignancies.

Project description:Clonal hematopoiesis (CH) is a common premalignant state in the blood and confers an increased risk of blood cancers and all-cause mortality. Identification of therapeutic targets in CH has been hindered by the lack of an ex vivo platform amenable for studying primary hematopoietic stem and progenitor cells (HSPCs) with and without CH-associated mutations. Here, we utilize an ex vivo co-culture system of primary murine HSPCs with bone marrow endothelial cells to perform CRISPR/Cas9 screens and identify vulnerabilities specific to mutant versus wild-type HSPCs. Our data reveal that loss of the histone demethylase family members KDM3B and JMJD1C specifically reduces the fitness of IDH2- and TET2- mutant HSPCs, but not wild-type HSPCs, including in TET2-mutant human HSPCs and Tet2-mutant murine leukemia cells with cooperating disease alleles. KDM3B loss in mutant cells leads to decreased expression of critical cytokine receptors including MPL, rendering mutant HSPCs preferentially susceptible to inhibition of downstream JAK2 signaling. Our study provides a scalable platform to identify genetic dependencies in mutant HSPCs and reveals an atlas of dependencies in normal and CH-mutant HSPCs. This study nominates an epigenetic regulator and an epigenetically regulated receptor signaling pathway as genotype-specific therapeutic targets in a subset of CH and myeloid malignancies.

Project description:Bone marrow-mesenchymal stromal cells (BM-MSCs) are key components of the BM niche, where they regulate hemato-poietic stem progenitor cells (HSPCs) homeostasis by direct contact and secreting soluble factors. BM-MSCs also protect the BM niche from excessive inflammation by releasing anti-inflammatory factors and modulating immune cell activity. Thanks to these proper-ties, BM-MSCs were successfully employed in pre-clinical HSPC transplantation models, increasing the rate of HSPC engraftment, accelerating the hematological reconstitution, and reducing the risk of graft failure. However, their clinical use requires extensive in vitro expansion, altering their biological and functional properties. In this work, we analyzed the transcriptomic profile of human BM-MSCs sorted as CD45neg, CD105+, CD73+, and CD90+ cells from the BM aspirates of heathy-donors and corresponding ex-vivo expanded BM-MSCs. We found the expression of immune and inflammatory genes downregulated upon cell culture and selected the transcription factor EGR1 to restore the MSC properties. We overexpressed EGR1 in BM-MSCs and performed in vitro tests to study the functional properties of EGR1-overexpressing BM-MSCs. We concluded that EGR1 increased the MSC response to inflam-matory stimuli and immune cell control and potentiated the MSC hematopoietic supportive activity in co-culture assay, suggesting that the EGR1-based reprogramming may improve the BM-MSC clinical use.

Project description:Purpose: Stanniocalcin 1 (STC1) is a secreted glycoprotein expressed in mesenchymal stroma cells (MSCs). STC1 expression is upregulated in response to acute myeloid leukemia (AML) co-culture. Recombinant STC1 has proliferation limiting effects on human hematopoietic stem/progenitors cells (HSPCs) and facilitiates the preservation of HSCs ex vivo. We hope to gain insight into the mechanism by exploring the transcriptome of stem/progenitors exposed to STC1.

Project description:Ex-vivo expanded mesenchymal stromal cells (MSCs) are increasingly used for paracrine support of hematopoietic stem cell (HSC) regeneration, but inconsistent outcomes have been the huddle for on-going clinical trials. Here, we hypothesized that the heterogeneity in the niche activity of manufactured MSCs can be a parameter for variable outcomes in MSC-based cell therapy. We first screened MSC culture medium and found that serum batches caused larger variations in colony forming unit-fibroblast (CFU-F) content of MSCs than individual donor variations. The culture conditions supporting high (stimulatory) and low (non-stimulatory) CFU-F caused distinct niche activity of MSCs; MSCs under stimulatory condition exhibited higher level expression of cross-talk molecules (Jagged-1 and CXCL-12) and higher support for HSCS during long-term culture than MSCs under non-stimulatory culture. Moreover, the effects of MSCs enhancing hematopoietic engraftment were only visible when HSCs were co-transplanted with MSCs expanded under stimulatory, but not non-stimulatory conditions. However, these differences of MSCs were readily reversed by switching the culture mediums, indicating their distinct functional state, rather than clonal heterogeneity. Accordingly, transcriptomic analysis showed distinct gene set enrichment between the different MSCs and revealed distinct upstream signaling pathways such as inhibition of P53 and activation of ATF4 for MSCs under stimulatory conditions. Taken together, our study shows that the heterogeneity in the niche activity of MSCs can be created during ex-vivo expansion to cause a difference in the hematopoietic engraftment and raise the possibility that MSCs can be pre-screened for more predictable outcomes in clinical trials of MSCs. Total RNA obtained from isolated human mesenchymal stromal cells. To compare stimulatory (SS) serum and non-stimulatory (NSS) serums, MSCs had been maintained in each serum media were sub-cultured for at least two passages before analysis.

Project description:Clonal haematopoiesis (CH) is a benign age-related condition occurring due to somatic genetic variation in haematopoietic stem and progenitor cells (HSPCs). In some individuals, CH is a precursor condition for haematologic malignancy, but the mechanisms driving progression of CH to malignancy are incompletely understood. Given that malignant cells reprogram their microenvironment to create a self-reinforcing niche, we hypothesized that HSPCs carrying CH mutations have microenvironment-remodelling properties that promote their clonal advantage and contribute to malignant progression. By single-cell RNA-seq profiling of the non-haematopoietic bone marrow microenvironment in a mouse model of DNMT3A-mutant CH, we identified strong enrichment of a cellular senescence signature in bone marrow mesenchymal stromal cells (MSCs). We find that Dnmt3a-mutant HSPCs induce markers of senescence including SA-b-gal, BCL-2, BCL-xL, Cdkn1a (p21), and Cdkn2a (p16) selectively in MSCs using ex vivo and in vivo assays. This senescence induction phenotype is cell contact-independent and reproduced by IL-6 and TNFa, both of which are soluble factors produced by Dnmt3a-mutant HSPCs. Removal of senescent MSCs using Navitoclax reduced the selective growth advantage of Dnmt3a-mutant hematopoietic cells and reduced myeloproliferation in a Dnmt3a;Npm1-mutant model of myeloid neoplasms. Together, our data demonstrate that Dnmt3a-mutant HSPCs produce specific factors that reprogram their microenvironment through senescence induction, and that this process creates a self-reinforcing niche favouring their growth advantage and progression to malignancy.