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Item CD166 Engagement Augments Mouse and Human Hematopoietic Progenitor Function via Activation of Stemness and Cell Cycle Pathways(Oxford University Press, 2019) Zhang, Jing; Ghosh, Joydeep; Mohamad, Safa F.; Zhang, Chi; Huang, Xinxin; Capitano, Maegan L.; Gunawan, Andrea M.; Cooper, Scott; Guo, Bin; Cai, Qingchun; Broxmeyer, Hal E.; Srour, Edward F.; Microbiology and Immunology, School of MedicineHematopoietic stem (HSC) and progenitor (HPC) cells are regulated by interacting signals and cellular and noncellular elements of the hematopoietic niche. We previously showed that CD166 is a functional marker of murine and human HSC and of cellular components of the murine niche. Selection of murine CD166+ engrafting HSC enriched for marrow repopulating cells. Here, we demonstrate that CD166-CD166 homophilic interactions enhance generation of murine and human HPC in vitro and augment hematopoietic function of these cells. Interactions between cultured CD166+ Lineage- Sca-1+ c-Kit+ (LSK) cells and CD166+ osteoblasts (OBs) significantly enhanced the expansion of colony-forming units (CFUs). Interactions between CD166+ LSK cells and immobilized CD166 protein generated more CFU in short-term cultures than between these cells and bovine serum albumin (BSA) or in cultures initiated with CD166- LSK cells. Similar results were obtained when LSK cells from wildtype (WT) or CD166 knockout (KO) (CD166-/- ) mice were used with immobilized CD166. Human cord blood CD34+ cells expressing CD166 produced significantly higher numbers of CFUs following interaction with immobilized CD166 than their CD166- counterparts. These data demonstrate the positive effects of CD166 homophilic interactions involving CD166 on the surface of murine and human HPCs. Single-cell RNA-seq analysis of CD150+ CD48- (signaling lymphocyte activation molecule (SLAM)) LSK cells from WT and CD166-/- mice incubated with immobilized CD166 protein revealed that engagement of CD166 on these cells activates cytokine, growth factor and hormone signaling, epigenetic pathways, and other genes implicated in maintenance of stem cell pluripotency-related and mitochondria-related signaling pathways. These studies provide tangible evidence implicating CD166 engagement in the maintenance of stem/progenitor cell function.Item CD166 modulates disease progression and osteolytic disease in multiple myeloma(2016-03-16) Xu, Linlin; Xu, LinlinMultiple myeloma (MM) is an incurable malignancy characterized by the proliferation of neoplastic plasma cells in the bone marrow (BM) and by multiple osteolytic lesions throughout the skeleton. We previously reported that CD166 is a functional molecule on normal hematopoietic stem cells (HSC) that plays a critical role in HSC homing and engraftment, suggesting that CD166 is involved in HSC trafficking and lodgment. CD166, a member of the immunoglobulin superfamily capable of mediating homophilic interactions, has been shown to enhance metastasis and invasion in several tumors. However, whether CD166 is involved in MM and plays a role in MM progression has not been addressed. We demonstrated that a fraction of all human MM cell lines tested and MM patients’ BM CD138+ cells express CD166. Additionally, CD166+ cells preferentially home to the BM of NSG mice. Knocking-down (KD) CD166 expression on MM cells with shRNA reduced their homing to the BM. Furthermore, in a long-term xenograft model, NSG mice inoculated with CD166KD cells showed delayed disease progression and prolonged survival compared to mice receiving mock transduced cells. To examine the potential role of CD166 in osteolytic lesions, we first used a novel Ex Vivo Organ Culture Assay (EVOCA) which creates an in vitro 3D system for the interaction of MM cells with the bone microenvironment. EVOCA data from MM cells lines as well as from primary MM patients’ CD138+ BM cells demonstrated that bone osteolytic resorption was significantly reduced when CD166 was absent on MM cells or calvarial cells. We then confirmed our ex vivo findings with intra-tibial inoculation of MM cells in vivo. Mice inoculated with CD166KD cells had significantly less osteolytic lesions. Further analysis demonstrated that CD166 expression on MM cells alters bone remodeling by inhibiting RUNX2 gene expression in osteoblast precursors and increasing RANKL to OPG ratio in osteoclast precursors. We also identified that CD166 is indispensable for osteoclastogenesis via the activation of TRAF6-dependent signaling pathways. These results suggest that CD166 directs MM cell homing to the BM and promotes MM disease progression and osteolytic disease. CD166 may serve as a therapeutic target in the treatment of MM.Item Cell adhesion molecule CD166 drives malignant progression and osteolytic disease in multiple myeloma(American Association for Cancer Research, 2016-12-01) Xu, Linlin; Mohammad, Khalid S.; Wu, Hao; Crean, Colin; Poteat, Bradley; Cheng, Yinghua; Cardoso, Angelo A.; Machal, Christophe; Hanenberg, Helmut; Abonour, Rafat; Kacena, Melissa A.; Chirgwin, John; Suvannasankha, Attaya; Srour, Edward F.; Microbiology and Immunology, School of MedicineMultiple myeloma (MM) is incurable once osteolytic lesions have seeded at skeletal sites, but factors mediating this deadly pathogenic advance remain poorly understood. Here we report evidence of a major role for the cell adhesion molecule CD166, which we discovered to be highly expressed in MM cell lines and primary bone marrow (BM) cells from patients. CD166+ MM cells homed more efficiently than CD166− cells to the BM of engrafted immunodeficient NSG mice. CD166 silencing in MM cells enabled longer survival, a smaller tumor burden and less osteolytic lesions, as compared to mice bearing control cells. CD166 deficiency in MM cell lines or CD138+ BM cells from MM patients compromised their ability to induce bone resorption in an ex vivo organ culture system. Further, CD166 deficiency in MM cells also reduced formation of osteolytic disease in vivo after intra-tibial engraftment. Mechanistic investigation revealed that CD166 expression in MM cells inhibited osteoblastogenesis of BM-derived osteoblast progenitors by suppressing RUNX2 gene expression. Conversely, CD166 expression in MM cells promoted osteoclastogenesis by activating TRAF6-dependent signaling pathways in osteoclast progenitors. Overall, our results define CD166 as a pivotal director in MM cell homing to the BM and MM progression, rationalizing its further study as a candidate therapeutic target for MM treatment.Item ROLE OF CD166 IN MULTIPLE MYELOMA CELL HOMING TO THE BONE MARROW MICROENVIRONMENT AND DISEASE PROGRESSION(Office of the Vice Chancellor for Research, 2014-04-11) Xu, Linlin; Machal, Christophe; Wu, Hao; Poteat, Bradley; Crean, Colin; Cardoso, Angelo A; Chirgwin, John M; Hanenberg, Helmut; Mohammad, Khalid S; Suvannasankha, Attaya; Srour, Edward FMultiple myeloma (MM) is a plasma cell malignancy characterized by multiple lytic lesions throughout the skeleton, suggesting that trafficking of MM cells from the bone marrow (BM) and lodgment of these cells at secondary sites is important in disease progression. CD38+CD138- MM cells were previously characterized as putative MM stem cells (MMSC, Cancer Res. 2008; 68(1):190-7.). We analyzed CD38+CD138- cells contained within the MM cell line H929 and determined that a fraction of these cells (29.9%±1.4%) expresses CD166. CD166 is a member of the immunoglobulin superfamily capable of mediating both homophilic and heterophilic (CD6) interactions and has been shown to enhance metastasis and invasion in several tumors including breast cancer and melanoma. Studies from our laboratory suggest that CD38+CD138-CD166+ MM cells possess many functional properties commonly associated with MMSC including cell cycle quiescence, maintenance and propagation of daughter cells on a stromal substrate and gene expression profile. We hypothesized that CD166 promotes MM cell trafficking to the BM and is critical for disease progression. To test this hypothesis, H929-GFP myeloma cells were injected intravenously into NSG mice and GFP cells were recovered from the BM 14hr later. While only 3.3%±1.5% of total H929-GFP cells express the CD38+CD138- phenotype, the frequency of CD38+CD138- cells contained in BM-homed H929-GFP cells was significantly higher (53.4%±3.7%, n=3, p<0.01), suggesting a preferential homing of MMSC to the marrow microenvironment. Interestingly, whereas only 29.9%±1.4% of CD38+CD138- cells expressed CD166 prior to injection, 84.1%±10.8% of BM-homed H929-GFP CD38+CD138- cells expressed CD166 (n=3, p<0.01), suggesting that CD166 plays a critical role in directing homing of MM cells to the BM. Next, CD166 expression on H929-GFP cells was knocked down (KD) with shRNA in order to examine if reduced CD166 expression inhibit the homing of MM cells to the BM. The number of BM-homed GFP cells was significantly decreased for CD166KD cells (5658±904, n=6) compared to mock control (8551±848, n=6; p<0.05). Interestingly, cells in which suppression of CD166 expression was not achieved with shRNA homed preferentially to the BM (4.3%±0.3% CD166+cells in CD166 KD H929-GFP before injection versus 29.3%±3.6% in BM-homed GFP cells). Then we compared the progression of MM in NSG mice initiated with mock control or CD166 KD H929-GFP cells. Disease progression in mice receiving control cells was more rapid compared to that in mice receiving CD166KD cells as evidenced by serum levels of human IgA (kappa) at 4 weeks posttransplantation (240.5±67.1ng/ml versus 45.1±33.0ng/ml, n=3; p<0.05). We next examined the potential role of CD166 in osteolytic lesions using a novel Ex Vivo Organ Culture Assay (EVOCA) in which MM cells are co-cultured over calvariae from 10d-old pups for 7 days creating an in vitro 3D system for the interaction of MM cells with bone microenvironment. Data from EVOCA with H929 cells showed that bone osteolytic lesions are substantially reduced when CD166 is absent on either MM (CD166- fraction) or osteoblast lineage cells (calvariae from CD166-/- mice). Furthermore, co-culturing CD166+ or CD166- H929 cells with bone marrow stromal cells (BMSC) from WT or CD166-/- mice revealed that mRNA levels of receptor activator of NF-κB ligand (RANKL) are decreased when CD166 is absent on either MM or stromal cells while mRNA levels of osteoprotegerin (OPG), an important inhibitor of osteoclastogenesis, are not altered. This resulted in decreased RANKL/OPG ratios in cultures containing a CD166- component suggesting reduced MM-induced osteoclastogenesis in the absence of CD166. Interestingly, levels of M-CSF and IL-6 were similar in all these cultures suggesting that loss of CD166 may mediate suppression of osteolytic lesions through the downregulation of RANKL. Together, these results suggest that CD166 plays an important role in homing and retention of MM cells in the BM and promotes MM disease progression as well as bone-lytic disease and that CD166 may serve as a therapeutic target in the treatment of MM.Item The Role of Osteomacs in Regulating Stem Cell Function and the Hematopoietic Niche(2020-02) Mohamad, Safa F.; Srour, Edward F.; Bruzzaniti, Angela; Haneline, Laura S.; Pelus, Louis M.; Kacena, Melissa A.Maintenance of hematopoietic stem cell (HSC) function is an orchestrated event requiring the participation of multiple cell types within the hematopoietic niche. Among the key cellular components of the niche are a group of specialized bone-resident macrophages known as osteomacs (OM). Reported here is a detailed characterization of OM and description of discriminating phenotypic and functional properties that clearly distinguish OM from bone marrow-derived macrophages (BM Mφ). Furthermore, it was established that OM support hematopoiesis enhancing activity of osteoblasts and that this activity was augmented by megakaryocytes. Serial transplantation demonstrated that HSC repopulating potential was best maintained by in vitro cultures containing OM, osteoblasts and megakaryocytes. Interestingly, BM Mφ were unable to mediate the same hematopoiesis enhancing activity regardless of whether megakaryocytes were present in co-culture or not. Subsequently, to understand the importance of networking between the residents of the niche, 3D tissue cytometry was performed on fixed and stained unperturbed bone marrow sections. This approach identified the spatial relationships between OM, osteoblasts, megakaryocytes and HSC within the niche and defined parameters, under which these cell types coexist in undamaged bone marrow. In addition, single cell mRNAseq and CyTOF was performed to assess genetic and proteomic expression changes in OM following their interaction with megakaryocytes. These studies revealed the upregulation of CD166 and embigin on OM via osteoblast and megakaryocyte interactions. Clonogenic assays were conducted to examine the impact of these molecules in hematopoietic function. When these assays were initiated with CD166 KO OM or shRNA-mediated embigin knockdown OM, it was established that loss of these surface molecules on OM caused a decline in the normal OM-mediated hematopoietic enhancing activity. Conversely, recombinant CD166 and embigin partially substituted for OM activity thus identifying potential mediators through which OM maintain hematopoietic function. This data, for the first time, reveal intimate spatial interactions between OM, osteoblasts, megakaryocytes and HSC in the hematopoietic niche. They also illustrate the importance of crosstalk between OM, osteoblasts and megakaryocytes and reveal novel mediators such as CD166 and embigin that cooperate with other elements of the niche to support HSC function.