Population Of Non-hematopoietic Cells Research Articles

A Rapid Human Lung Tissue Dissociation Protocol Maximizing Cell Yield and Minimizing Cellular Stress.

The human lung is a complex organ that comprises diverse populations of epithelial, mesenchymal, vascular, and immune cells, which gains even greater complexity during disease states. To effectively study the lung at a single-cell level, a dissociation protocol that achieves the highest yield of viable cells of interest with minimal dissociation-associated protein or transcription changes is key. Here, we detail a rapid collagenase-based dissociation protocol (Col-Short) that provides a high-yield single-cell suspension that is suitable for a variety of downstream applications. Diseased human lung explants were obtained and dissociated through the Col-Short protocol and compared with four other dissociation protocols. Resulting single-cell suspensions were then assessed with flow cytometry, differential staining, and quantitative real-time PCR to identify major hematopoietic and nonhematopoietic cell populations, as well as their activation states. We observed that the Col-Short protocol provides the greatest number of cells per gram of lung tissue, with no reduction in viability when compared with previously described dissociation protocols. Col-Short had no observable surface protein marker cleavage as well as lower expression of protein activation markers and stress-related transcripts compared with four other protocols. The Col-Short dissociation protocol can be used as a rapid strategy to generate single cells for respiratory cell biology research.

Immunological synapse formation between T regulatory cells and cancer-associated fibroblasts promotes tumour development

Cancer-associated fibroblasts (CAFs) have emerged as a dominant non-hematopoietic cell population in the tumour microenvironment, serving diverse functions in tumour progression. However, the mechanisms via which CAFs influence the anti-tumour immunity remain poorly understood. Here, using multiple tumour models and biopsies from cancer patients, we report that α-SMA+ CAFs can form immunological synapses with Foxp3+ regulatory T cells (Tregs) in tumours. Notably, α-SMA+ CAFs can phagocytose and process tumour antigens and exhibit a tolerogenic phenotype which instructs movement arrest, activation and proliferation in Tregs in an antigen-specific manner. Moreover, α-SMA+ CAFs display double-membrane structures resembling autophagosomes in their cytoplasm. Single-cell transcriptomic data showed an enrichment in autophagy and antigen processing/presentation pathways in α-SMA-expressing CAF clusters. Conditional knockout of Atg5 in α-SMA+ CAFs promoted inflammatory re-programming in CAFs, reduced Treg cell infiltration and attenuated tumour development. Overall, our findings reveal an immunosuppressive mechanism entailing the formation of synapses between α-SMA+ CAFs and Tregs in an autophagy-dependent manner.

Instructive Interaction between Myelodysplastic Hematopoiesis and the Bone Marrow Microenvironment at Single Cell Level

Myelodysplastic Neoplasms (MDS) are hypothesized to re-model their bone marrow (BM) microenvironment to re-inforce conditions for their propagation. In this study, we investigated interactions between MDS cells and the BM niche at single cell level in a MDS patient-derived xenograft model (PDX) as well as primary human MDS and healthy (HY) bone marrow (BM samples in order to identify cues of disturbed crosstalk between MDS hematopoiesis and the BM microenvironment. In the PDX model, we analyzed >13,000 cells of n=15 different murine niche cell populations after long-term (>24 weeks) exposure to n=3 MDS patient samples versus n=2 age-matched HY human grafts. Subsequently, we analyzed over 24,000 primary human BM cells enriched for the non-hematopoietic compartment by using whole bone fragments from n=8 MDS patients and n=7 HY age-matched donors. All cells were analyzed with combined 10x single cell RNA sequencing and human “Cellular Indexing of the Transcriptome and Epitopes by Sequencing” (CITE Seq). Results were validated by flow cytometry and gene expression analyses. Mesenchymal cell (MSC) subpopulations from PDX mice exposed to MDS versus HY hematopoiesis could be subdivided into distinct “Cxcl12+ abundant reticular” (CAR) cells with osteogenic and adipogenic differentiation trajectories. Various CAR cell populations displayed an increased frequency in MDS transplanted mice as compared to PDX transplanted with HY grafts ( Panel A). Upon contact with hematopoietic MDS cells, CAR cell populations overexpressed numerous genes involved in extracellular matrix reorganization and hematopoietic supporting factors, such as Cxcl12, Il7, Lox and Loxl1 as compared to mice bearing HY grafts. In situ, BM cells from MDS patients showed highly heterogeneous MSC subpopulations with similar differentiation trajectories to the ones observed in our PDX models on a patient-individual level. We detected two non-hematopoietic cell populations, designated as endothelial cells (ECs) and MSCs characterized by expression of CXCL12, IGFBP5 or COL1A2 and quantification with epitope sequencing (CITE Seq) with mutually exclusive detection of CD31 and CD271 expression (n=581 cells in total, Panel B). In n=3 MDS patients, we identified an MDS-specific MSC subpopulation with high IGFPB4 and CXCL12 expression as well as overexpression of KITLG and IL7. This suggests that this altered specialized secretory mesenchymal state is present in a subset of MDS patients and may support the malignant hematopoietic clones by overexpression of key hematopoietic factors. Interactome analyses using spatial receptor:ligand bioinformatic tools such as CellphoneDB, RNAMagnet and omnipath further confirmed that stromal cells alter their cellular profile and secretory behavior in response to MDS hematopoiesis. In conclusion, we show that murine BM stroma is re-programmed by exposure to human MDS xenografts to upregulate extracellular matrix (ECM) re-modeling and HSC supporting factors. In native human MDS BM in vivo, rare primary mesenchymal cells are re-programmed to increase hematopoietic support in a patient-individual manner pointing to altered MSC subpopulations with increased growth factor expression profiles in a subgroup of MDS patients.

Characterization of adult human skeletal cells in different tissues reveals a CD90+CD34+ periosteal stem/progenitor population

The periosteum plays a crucial role in bone healing and is an important source of skeletal stem and progenitor cells. Recent studies in mice indicate that diverse populations of skeletal progenitors contribute to growth, homeostasis and healing. Information about the in vivo identity and diversity of skeletal stem and progenitor cells in different compartments of the adult human skeleton is limited. In this study, we compared non-hematopoietic populations in matched tissues from the femoral head and neck of 21 human participants using spectral flow cytometry of freshly isolated cells. High-dimensional clustering analysis indicated significant differences in marker distribution between periosteum, articular cartilage, endosteum and bone marrow populations, and identified populations that were highly enriched or unique to specific tissues. Periosteum-enriched markers included CD90 and CD34. Articular cartilage, which has very poor regenerative potential, showed enrichment of multiple markers, including the PDPN+CD73+CD164+CD146- population previously reported to represent human skeletal stem cells. We further characterized periosteal populations by combining CD90 with other strongly expressed markers. CD90+CD34+ cells sorted directly from periosteum showed significant colony-forming unit fibroblasts (CFU-F) enrichment, rapid expansion, and consistent multi-lineage differentiation of clonal populations in vitro. In situ, CD90+CD34+ cells include a perivascular population in the outer layer of the periosteum and non-perivascular cells closer to the bone surface. CD90+ cells are also highly enriched for CFU-F in bone marrow and endosteum, but not articular cartilage. In conclusion, our study indicates considerable diversity in the non-hematopoietic cell populations in different tissue compartments within the adult human skeleton, and suggests that periosteal progenitor cells reside within the CD90+CD34+ population.

Responses of hepatic sinusoidal cells to liver ischemia-reperfusion injury.

The liver displays a remarkable regenerative capacity in response to acute liver injury. In addition to the proliferation of hepatocytes during liver regeneration, non-parenchymal cells, including liver macrophages, liver sinusoidal endothelial cells (LSECs), and hepatic stellate cells (HSCs) play critical roles in liver repair and regeneration. Liver ischemia-reperfusion injury (IRI) is a major cause of increased liver damage during liver resection, transplantation, and trauma. Impaired liver repair increases postoperative morbidity and mortality of patients who underwent liver surgery. Successful liver repair and regeneration after liver IRI requires coordinated interplay and synergic actions between hepatic resident cells and recruited cell components. However, the underlying mechanisms of liver repair after liver IRI are not well understood. Recent technological advances have revealed the heterogeneity of each liver cell component in the steady state and diseased livers. In this review, we describe the progress in the biology of liver non-parenchymal cells obtained from novel technological advances. We address the functional role of each cell component in response to liver IRI and the interactions between diverse immune repertoires and non-hematopoietic cell populations during the course of liver repair after liver IRI. We also discuss how these findings can help in the design of novel therapeutic approaches. Growing insights into the cellular interactions during liver IRI would enhance the pathology of liver IRI understanding comprehensively and further develop the strategies for improvement of liver repair.

Inflammatory processes in the liver: divergent roles in homeostasis and pathology.

The hepatic immune system is designed to tolerate diverse harmless foreign moieties to maintain homeostasis in the healthy liver. Constant priming and regulation ensure that appropriate immune activation occurs when challengedby pathogens and tissue damage. Failure to accurately discriminate, regulate, or effectively resolve inflammation offsets this balance, jeopardizing overall tissue healthresulting from an either overly tolerant or an overactive inflammatory response. Compelling scientific and clinical evidence links dysregulated hepatic immune and inflammatory responses uponsterile injury to several pathological conditions in the liver, particularly nonalcoholic steatohepatitis and ischemia-reperfusion injury. Murine and human studies have described interactions between diverse immune repertoires and nonhematopoietic cell populations in both physiological and pathological activities in the liver, although the molecular mechanisms driving these associations are not clearly understood. Here, we review the dynamic roles of inflammatory mediators in responses to sterile injury in the context of homeostasis and disease, the clinical implications of dysregulated hepatic immune activity and therapeutic developments to regulate liver-specific immunity.

Regulation of Immune Responses by Nonhematopoietic Cells in Asthma

Nonhematopoietic cells are emerging as important contributors to many inflammatory diseases, including allergic asthma. Recent advances have led to a deeper understanding of how these cells interact with traditional immune cells, thereby modulating their activities in both homeostasis and disease. In addition to their well-established roles in gas exchange and barrier function, lung epithelial cells express an armament of innate sensors that can be triggered by various inhaled environmental agents, leading to the production of proinflammatory molecules. Advances in cell lineage tracing and single-cell RNA sequencing have expanded our knowledge of rare, but immunologically important nonhematopoietic cell populations. In parallel with these advances, novel reverse genetic approaches are revealing how individual genes in different lung-resident nonhematopoietic cell populations contribute to the initiation and maintenance of asthma. This knowledge is already revealing new pathways that can be selectively targeted to treat distinct forms of asthma.

Mapping Distinct Bone Marrow Niche Populations and Their Differentiation Paths

The bone marrow microenvironment is composed of heterogeneous cell populations of non-hematopoietic cells with complex phenotypes and undefined trajectories of maturation. Among them, mesenchymal cells maintain the production of stromal, bone, fat, and cartilage cells. Resolving these unique cellular subsets within the bone marrow remains challenging. Here, we used single-cell RNA sequencing of non-hematopoietic bone marrow cells to define specific subpopulations. Furthermore, by combining computational prediction of the cell state hierarchy with the known expression of key transcription factors, we mapped differentiation paths to the osteocyte, chondrocyte, and adipocyte lineages. Finally, we validated our findings using lineage-specific reporter strains and targeted knockdowns. Our analysis reveals differentiation hierarchies for maturing stromal cells, determines key transcription factors along these trajectories, and provides an understanding of the complexity of the bone marrow microenvironment.

Evaluating cooperative roles for STAT3 and Aiolos in lymphocyte mimicry associated with metastatic disease

Abstract Inappropriate expression and function of cytokine and chemokine receptors by both hematopoietic and non-hematopoietic cell populations have been linked to human disease. One example of this is the expression of lymphocytic genes by metastatic cancers, termed lymphocyte mimicry. Specifically, the aberrant expression of chemokine receptors by cancer cells allows for inappropriate responses to immune signals, migration, and increased ability to survive in circulation. The mechanisms that regulate lymphocyte mimicry are currently incompletely understood. Our laboratory recently identified a novel transcriptional complex composed of the Ikaros Zinc Finger transcription factor Aiolos and STAT3 that regulates gene expression in CD4+ T cells, including that of chemokine receptors. Interestingly, Aiolos and STAT3 have been independently implicated in multiple cancers, including metastatic breast cancer. We hypothesized that Aiolos and STAT3 may cooperate to induce chemokine receptor expression in metastatic breast cancer cells. Our study observed increased Aiolos expression and STAT3 activation in metastatic breast cancer cells as compared to non-tumorgenic and non-metastatic controls. This correlated with increased expression of the chemokine receptor CXCR4, which has been previously linked to metastatic cancer. Importantly, shRNA knockdown of Aiolos in metastatic cells resulted in decreased expression of CXCR4. Collectively, these data support a role for Aiolos, possibly in collaboration with STAT3, in the induction of a metastatic gene signature in human breast cancer.

Mapping Distinct Bone Marrow Niche Populations and Their Differentiation Paths

The bone marrow microenvironment is composed of heterogeneous cell populations of non-hematopoietic cells with complex phenotypes and undefined trajectories of maturation. Among them, mesenchymal cells maintain the production of stromal, bone, fat and cartilage cells. Resolving these unique cellular subsets within the bone marrow remains challenging. Here, we used single-cell RNA-sequencing of non-hematopoietic bone marrow cells to define specific subpopulations. Furthermore, by combining computational prediction of the cell state hierarchy with known expression of key transcription factors, we mapped differentiation paths to the osteocyte, chondrocyte, and adipocyte lineages. Finally, we validated our findings using lineage-specific reporter strains and targeted knockdowns. Our analysis reveals differentiation hierarchies for maturing stromal cells, determines key transcription factors along these trajectories, and provides an understanding of the complexity of the bone marrow microenvironment.

Liver immunology and its role in inflammation and homeostasis.

The human liver is usually perceived as a non-immunological organ engaged primarily in metabolic, nutrient storage and detoxification activities. However, we now know that the healthy liver is also a site of complex immunological activity mediated by a diverse immune cell repertoire as well as non-hematopoietic cell populations. In the non-diseased liver, metabolic and tissue remodeling functions require elements of inflammation. This inflammation, in combination with regular exposure to dietary and microbial products, creates the potential for excessive immune activation. In this complex microenvironment, the hepatic immune system tolerates harmless molecules while at the same time remaining alert to possible infectious agents, malignant cells or tissue damage. Upon appropriate immune activation to challenge by pathogens or tissue damage, mechanisms to resolve inflammation are essential to maintain liver homeostasis. Failure to clear ‘dangerous' stimuli or regulate appropriately activated immune mechanisms leads to pathological inflammation and disrupted tissue homeostasis characterized by the progressive development of fibrosis, cirrhosis and eventual liver failure. Hepatic inflammatory mechanisms therefore have a spectrum of roles in the healthy adult liver; they are essential to maintain tissue and organ homeostasis and, when dysregulated, are key drivers of the liver pathology associated with chronic infection, autoimmunity and malignancy. In this review, we explore the changing perception of inflammation and inflammatory mediators in normal liver homeostasis and propose targeting of liver-specific immune regulation pathways as a therapeutic approach to treat liver disease.

Identification of New Rat Bone Marrow‐Derived Population of Very Small Stem Cell with Oct‐4A and Nanog Expression by Flow Cytometric Platforms

Very small embryonic-like stem cells (VSELs) represent a unique rare population of adult stem cells (SCs) sharing several structural, genetic, biochemical, and functional properties with embryonic SCs and have been identified in several adult murine and human tissues. However, rat bone marrow- (BM-) derived SCs closely resembling murine or human VSELs have not been described. Thus, we employed multi-instrumental flow cytometric approach including classical and imaging cytometry and we established that newly identified population of nonhematopoietic cells expressing CD106 (VCAM-I) antigen contains SCs with very small size, expressing markers of pluripotency (Oct-4A and Nanog) on both mRNA and protein levels that indicate VSEL population. Based on our experience in both murine and human VSEL isolation procedures by fluorescence-activated cell sorting (FACS), we also optimized sorting protocol for separation of CD45−/Lin−/CD106+ rat BM-derived VSELs from wild type and eGFP-expressing rats, which are often used as donor animals for cell transplantations in regenerative studies in vivo. Thus, this is a first study identifying multiantigenic phenotype and providing sorting protocols for isolation VSELs from rat BM tissue for further examining of their functional properties in vitro as well as regenerative capacity in distinct in vivo rat models of tissue injury.

The formyl peptide receptor 1 exerts a tumor suppressor function in human gastric cancer by inhibiting angiogenesis.

N-formyl peptide receptors (FPR1, FPR2 and FPR3) are involved in innate immunity, inflammation and cancer. FPR expression, initially described in immune cells, was later observed in non-hematopoietic cell populations and tissues. Several studies suggested a role for FPRs in the progression of various tumor histotypes, including gastric cancer (GC), for which a positive association with a specific FPR1 polymorphism has recently been described. We previously showed that FPRs are expressed on gastric epithelium and are required for wound repair and restitution of barrier integrity. Here we assess the role of FPRs in GC. We characterized the functions of FPRs in GC epithelial cells (MKN28, AGS and MKN45) cultured in vitro by assessing migration, proliferation, resistance to apoptosis and activation of the epithelial-to-mesenchymal transition. Activation of each FPR induced the epithelial-to-mesenchymal transition, proliferation, resistance to apoptosis and migration of GC cells in culture. Blocking compounds or RNA interference of each FPR reverted these effects. We also defined the in vivo tumorigenic potential of GC epithelial cells silenced for FPRs by xenograft experiments in immunocompromised mice. Interestingly, FPR1 silencing in GC cells (shFPR1) significantly enhanced xenograft growth with respect to shCTR, shFPR2 and shFPR3 xenografts, because of augmented vessel density and cell proliferation. Accordingly, HIF-1α and VEGF mRNA levels were higher in shFPR1 xenografts than in controls. Moreover, the in vitro production of proangiogenic factors in response to FPR2/3 agonists (WKYMVm, LL-37, uPA, uPAR84-95, AnxA1) or to other proinflammatory mediators (IL-1α) was higher in shFPR1 GC cells than in shCTR, shFPR2 and shFPR3 cells, suggesting that FPR1 functions as an inhibitor of CG angiogenesis. Thus, we propose that FPR1 stimulation may represent a novel therapeutic approach to counteract tumor angiogenesis.

Rationale for the potential use of mesenchymal stromal cells in liver transplantation.

Mesenchymal stromal cells (MSCs) are multipotent and self-renewing cells that reside essentially in the bone marrow as a non-hematopoietic cell population, but may also be isolated from the connective tissues of most organs. MSCs represent a heterogeneous population of adult, fibroblast-like cells characterized by their ability to differentiate into tissues of mesodermal lineages including adipocytes, chondrocytes and osteocytes. For several years now, MSCs have been evaluated for their in vivo and in vitro immunomodulatory and 'tissue reconstruction' properties, which could make them interesting in various clinical settings, and particularly in organ transplantation. This paper aims to review current knowledge on the properties of MSCs and their use in pre-clinical and clinical studies in solid organ transplantation, and particularly in the field of liver transplantation. The first available clinical data seem to show that MSCs are safe to use, at least in the medium-term, but more time is needed to evaluate the potential adverse effects of long-term use. Many issues must be resolved on the correct use of MSCs. Intensive in vitro and pre-clinical research are the keys to a better understanding of the way that MSCs act, and to eventually lead to clinical success.

T Cell–Independent Modulation of Experimental Autoimmune Encephalomyelitis in ADAP-Deficient Mice

The adhesion- and degranulation-promoting adaptor protein (ADAP), expressed in T cells, myeloid cells, and platelets, is known to regulate receptor-mediated inside-out signaling leading to integrin activation and adhesion. In this study, we demonstrate that, upon induction of active experimental autoimmune encephalomyelitis (EAE) by immunization with the myelin oligodendrocyte glycoprotein35-55 peptide, ADAP-deficient mice developed a significantly milder clinical course of EAE and showed markedly less inflammatory infiltrates in the CNS than wild-type mice. Moreover, ADAP-deficient recipients failed to induce EAE after adoptive transfer of myelin oligodendrocyte glycoprotein-specific TCR-transgenic T cells (2D2 T cells). In addition, ex vivo fully activated 2D2 T cells induced significantly less severe EAE in ADAP-deficient recipients. The ameliorated disease in the absence of ADAP was not due to expansion or deletion of a particular T cell subset but rather because of a strong reduction of all inflammatory leukocyte populations invading the CNS. Monitoring the adoptively transferred 2D2 T cells over time demonstrated that they accumulated within the lymph nodes of ADAP-deficient hosts. Importantly, transfer of complete wild-type bone marrow or even bone marrow of 2D2 TCR-transgenic mice was unable to reconstitute EAE in the ADAP-deficient animals, indicating that the milder EAE was dependent on (a) radio-resistant nonhematopoietic cell population(s). Two-photon microscopy of lymph node explants revealed that adoptively transferred lymphocytes accumulated at lymphatic vessels in the lymph nodes of ADAP-deficient mice. Thus, our data identify a T cell-independent mechanism of EAE modulation in ADAP-deficient mice.

CD90+ Stromal Cells are Non-Professional Innate Immune Effectors of the Human Colonic Mucosa

Immune responses at the intestinal mucosa must allow for host protection whilst simultaneously avoiding inappropriate inflammation. Although much work has focused on the innate immune functionality of hematopoietic immune cells, non-hematopoietic cell populations – including epithelial and stromal cells – are now recognized as playing a key role in innate defense at this site. In this study we examined the innate immune capacity of primary human intestinal stromal cells (iSCs). CD90+ iSCs isolated from human colonic mucosa expressed a wide array of innate immune receptors and functionally responded to stimulation with bacterial ligands. iSCs also sensed infection with live Salmonella typhimurium, rapidly expressing IL-1 family cytokines via a RIPK2/p38MAPK-dependent signaling process. In addition to responding to innate immune triggers, primary iSCs exhibited a capacity for bacterial uptake, phagocytosis, and antigen processing, although to a lesser extent than professional APCs. Thus CD90+ iSCs represent an abundant population of “non-professional” innate immune effector cells of the human colonic mucosa and likely play an important adjunctive role in host defense and immune regulation at this site.

Basic Biology and Clinical Application of Multipotent Mesenchymal Stromal Cells: From Bench to Bedside

Basic Biology and Clinical Application of Multipotent Mesenchymal Stromal Cells: From Bench to Bedside

DNA Methylation Profile of Runx1 Regulatory Regions Is Correlated with Transition From Primitive to Definitive Hematopoietic Potential In Vitro and In Vivo

Abstract 389 Introduction:The Runt-related transcription factor Runx1 (AML1) is a central regulator of mammalian hematopoiesis and is required for the generation of hematopoietic stem cells (HSC) from hemogenic endothelium in the embryo. It has been shown that Runx1 is alternatively expressed from two promoters in a temporal fashion, and that their differential activities are influenced by a conserved intronic enhancer (+23) element. Intriguingly, promoter usage follows a pattern whereby the proximal (P2) initiates early in primitive hematopoiesis, while the distal (P1) becomes active later at the time of HSC emergence and is the predominant isoform expressed in fetal liver and adult HSC. While some transcription factor binding sites and cis-regulatory elements have been identified, an explanation for the alternative promoter usage remains elusive. We hypothesized that this regulation may be at the level of chromatin accessibility, and therefore investigated the DNA methylation status of Runx1 cis-elements. Methods/Results:We analyzed bisulfite-treated genomic DNA from E14.5 fibroblast (MEF), E8.5 yolk sac CD41+ (YS), E14.5 fetal liver Lin-Sca-1+CD48-CD150+ (FL), and adult marrow Lin-cKit+Sca-1+ (KLS); representing non-hematopoietic, primitive hematopoietic, and two stages of definitive HSC respectively. In addition, we also examined methylation in hematopoietic populations derived in vitro from murine embryonic stem cells (mESC). Initial exploratory analysis focused on classically defined CpG islands upstream of each promoter, however no significant differential methylation was observed within these regions. Subsequent analysis focused on CpGs near the transcription start site (TSS) and within the +23 enhancer. The P2 promoter was uninformative as it was unmethylated in all populations analyzed, whereas methylation within the +23 enhancer differentiated between hematopoietic and non-hematopoietic cell populations. At the P1 promoter, methylation status was remarkably correlated with primitive vs. definitive status. P1 was highly methylated in MEFs (77%), mESC embryoid body (EB) derived cKit+CD41+ (66%), and E8.5 YS CD41+ (58%); but significantly less methylated in vivo in FL HSC (8.1%) and adult KLS cells (18%). We are currently using this correlation of demethylation and definitive HSC potential to identify conditions that may drive definitive HSC generation from mESC-derived blood progenitors. Since overexpression of HoxB4 coupled with OP9 co-culture is the only confirmed method capable of producing definitive HSC from mESC, and HoxB4 has been shown to bind within the P1 promoter region of Runx1, we cultured HoxB4 or control EB-derived hematopoietic progenitors on OP9 stroma. We observed progressive demethylation in the HoxB4 arm: after 6 days of co-culture 47% vs. 71% in controls, and after 11 days 27% in the HoxB4 arm while the control population failed to proliferate past day 6. Isoform specific RT-PCR confirmed that HoxB4 overexpression resulted in Runx1 expression from the P1 promoter whereas the control vector did not. Within P1, we identify a single CpG that is most highly correlated with definitive HSC potential in vivo, and most significantly demethylated upon HoxB4 overexpression in vitro. Conclusions:These data indicate that differential methylation occurs at Runx1 regulatory regions during hematopoietic development in vitro and in vivo. The +23 enhancer is demethylated in cells with hematopoietic potential, whereas demethylation of the Runx1 P1 promoter is highly correlated with definitive HSPC populations and is promoted in vitro by HoxB4. These data are the first to identify a role for DNA methylation in the regulation of alternative promoter usage at the Runx1 locus, and may serve as a novel biomarker of HSC potential during embryonic development. Disclosures:No relevant conflicts of interest to declare.

Immunomodulatory effect of mesenchymal stem cells.

Mesenchymal stem cells represent an adult population of nonhematopoietic cells, which can differentiate into a variety of cell types such as osteocytes, chondrocytes, adipocytes, and myocytes. They display immunomodulatory properties that have led to the consideration of their use for the inhibition of immune responses. In this context, mesenchymal stem cells efficiently inhibit maturation, cytokine production, and the T cell stimulatory capacity of dendritic cells. They also can impair proliferation, cytokine secretion, and cytotoxic potential of T lymphocytes. Moreover, mesenchymal stem cells are able to inhibit the differentiation of B cells to plasma cells by inhibiting their capacity to produce antibodies. A variety of animal models confirm the immunomodulatory properties of mesenchymal stem cells. Clinical studies including patients with severe acute graft-versus-host disease have revealed that the administration of mesenchymal stem cells results in significant clinical responses. Therefore, mesenchymal stem cells improve acute graft-versus-host disease and represent a promising candidate for the prevention and treatment of immune-mediated diseases, due to their immunomodulatory capability and their low immunogenicity.

Interleukin-7 receptor alpha contributes to experimental autoimmune encephalomyelitis (148.24)

Abstract Multiple sclerosis (MS) is a neurodegenerative disease characterized by extensive inflammation, demyelination, and axonal damage. The interleukin-7 receptor alpha (IL7Rα) chain is an essential subunit for the signaling receptors of both interleukin-7 (IL7) and thymic stromal lymphopoietin (TSLP), which are involved in lymphocyte development, function, and homeostasis. Recently a mutation in the IL7Rα chain locus has been identified as a risk factor for MS. We show that mice with IL7Rα expression limited to thymic tissue (IL7RTgIL7R-/-) display a less severe form of experimental autoimmune encephalomyelitis (EAE), an animal model for MS. However, TSLPR-/- mice showed no protection from disease. Furthermore, anti-IL7Rα treatment in wild type (WT) mice after disease onset significantly decreased EAE severity and lymphocyte infiltration into the CNS, which was accompanied by a relative increase in resident microglia. Additionally, Rag-/- chimeric mice grafted with IL7RTgIL7R-/- or WT bone marrow cells displayed equivalent disease severity, implying that IL7Rα on a non-hematopoietic cell population contributes to EAE. Taken together, our data shows that systemic blockade of IL7Rα reduces EAE severity, and therefore serves as an optimal target for MS therapies.