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Avaliação de aspectos regulatórios da hematopoese em desnutrição proteico-energética experimental: papel das células endoteliais derivadas das células tronco mesenquimais medulares / Evaluation of hematopoietic regulatory aspects in experimental protein-energy malnutrition: the role of endothelial cells derived from bone marrow mesenchymal stem cells.Hastreiter, Araceli Aparecida 22 September 2014 (has links)
A desnutrição proteico-energética (DPE) provoca anemia e leucopenia decorrente da redução de precursores hematopoéticos e comprometimento da produção de mediadores indutores da hematopoese, bem como alterações estruturais e ultra-estruturais na matriz extracelular medular. A hematopoese ocorre em nichos medulares distintos - endosteal e perivascular - que modulam os processos de diferenciação, proliferação e auto-renovação da célula tronco hematopoética (CTH). As células tronco mesenquimais (CTM) tem um papel importante na formação destes nichos, através da sua diferenciação nos diversos tipos celulares que os compõe. Adicionalmente, a CTM pode modular a função de outras células, como a CTH e a célula endotelial (CE) medular, através da liberação de diversos fatores de crescimento e citocinas. As CE expressam proteínas que regulam a diferenciação e movimentação das CTH na MO. Há sinais que a CTM pode ser a precursora da CE medulares, pois in vitro a CTM pode se diferenciar em CE-like. Desta forma, a CTM é um ponto chave no estudo das alterações causadas pela DPE no nicho perivascular e sobre a regulação da hematopoese. Neste trabalho, investigamos se a DPE afeta a diferenciação in vitro da CTM medular em CE-like e avaliamos se essas células apresentam diferentes capacidades em produzir alguns mediadores regulatórios da hematopoese (CXCL-12, SCF, Ang-1, IL-11, GM-CSF e TFG-β), bem como possíveis alterações no perfil de expressão gênica de marcadores de função das CTM e CE-like. Utilizamos camundongos C57BL/6 machos, divididos em grupos Controle e Desnutrido, sendo que o grupo Controle recebeu ração normoprotéica (12% caseína) e o grupo Desnutrido recebeu ração hipoprotéica (2% caseína), ambos durante 5 semanas. Após este período, os animais foram eutanasiados, foi realizada a avaliação nutricional e hematológica, caracterizando a DPE. As CTM foram isoladas, caracterizadas e diferenciadas in vitro em CE-like, o que foi evidenciado pela maior expressão gênica de NT5E, FLT1, KDR, PECAM1 e VCAM1. Avaliamos a expressão dos genes CDH5, CSPG4, LEPR, NES, CSF1, CSF2, CSF3, MCAM, PROM1, ANGPT1, CXCL12, ENG, IGF1, IL3, IL11, KITL, TGFB1, WNT3A, WNT5A, ICAM1, PDGFB1 e VWF. Encontramos alterações causadas pela DPE na expressão gênica e quantificação de CXCL-12, SCF e Ang-1, os quais mostraram que as células avaliadas do grupo Desnutrido encontram-se em um estado \"pró-proliferativo\", em um esforço para restabelecer a hematopoese na DPE. Entretanto, foi observado neste trabalho e nos demais trabalhos do grupo que há hipoplasia medular na DPE e, portanto, pode-se inferir que as alterações hematopoéticas observadas na DPE não são ocasionadas por alterações na síntese de SCF, CXCL-12 ou Ang-1. / Protein-energy malnutrition (PEM) causes anemia and leukopenia as it reduces hematopoietic precursors, impairs the production of mediators that induce hematopoiesis and alters structural and ultrastructural changes in bone marrow (BM) extracellular matrix. Hematopoiesis occurs in distinct BM niches - endosteal and perivascular - which modulate the processes of differentiation, proliferation and self-renewal of hematopoietic stem cell (HSC). Mesenchymal stem cells (MSC) play an important role in the formation of these niches through their differentiation in several cell types that compose them. Additionally, MSC can modulate the function of other cells, such as HSC and endothelial cells (EC), through the release of several growth factors and cytokines. The EC express proteins that regulate the differentiation and migration of HSC in the BM. MSC seem to be the precursor of medullary EC because in vitro MSC can differentiate into EC-like cells. Thus, MSC are a key point in the study of changes caused by DPE on the perivascular niche and on the regulation of hematopoiesis. In this study, we investigated whether PEM would affect BM-MSC in vitro differentiation into EC-like cells and evaluated whether these cells would have distinct capacities of producing some regulatory mediators of hematopoiesis (CXCL- 12, SCF, Ang-1, IL-11, GM -CSF and TFG-β), as well as analyzed possible changes in the gene expression profile of MSC function and EC-like cells related markers. C57BL/6 mice were divided into Control and Malnourished groups, which received for 5 weeks, respectively, a normal protein diet (12% casein) and a low protein diet (2% casein). After this period, animals were euthanized, nutritional and hematological evaluations were performed, featuring the PEM. MSC were isolated, characterized and differentiated in vitro into EC-like cells, which were evidenced by increased gene expression of NT5E, FLT1, KDR, PECAM1 and VCAM1. The expression of CDH5, CSPG4, LEPR, NES, CSF1, CSF2, CSF3, MCAM, PROM1, ANGPT1, CXCL12, ENG, IGF1, IL3, IL11, KITL, TGFB1, Wnt3a, WNT5A, ICAM1, PDGFB1 and VWF genes was also evaluated. Changes caused by PEM on gene expression and quantification of CXCL-12, SCF and Ang-1 were found, indicating that tested cells from the Malnourished group were in a \"pro-proliferative\" state in an effort to restore hematopoiesis. However, our results are in accordance to the literature regarding bone marrow hypoplasia as a consequence of PEM. Therefore, we infer hematopoietic changes observed in this work are not related to changes in the synthesis of SCF, 12 CXCL-12 or Ang-1.
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Avaliação de aspectos regulatórios da hematopoese em desnutrição proteico-energética experimental: papel das células endoteliais derivadas das células tronco mesenquimais medulares / Evaluation of hematopoietic regulatory aspects in experimental protein-energy malnutrition: the role of endothelial cells derived from bone marrow mesenchymal stem cells.Araceli Aparecida Hastreiter 22 September 2014 (has links)
A desnutrição proteico-energética (DPE) provoca anemia e leucopenia decorrente da redução de precursores hematopoéticos e comprometimento da produção de mediadores indutores da hematopoese, bem como alterações estruturais e ultra-estruturais na matriz extracelular medular. A hematopoese ocorre em nichos medulares distintos - endosteal e perivascular - que modulam os processos de diferenciação, proliferação e auto-renovação da célula tronco hematopoética (CTH). As células tronco mesenquimais (CTM) tem um papel importante na formação destes nichos, através da sua diferenciação nos diversos tipos celulares que os compõe. Adicionalmente, a CTM pode modular a função de outras células, como a CTH e a célula endotelial (CE) medular, através da liberação de diversos fatores de crescimento e citocinas. As CE expressam proteínas que regulam a diferenciação e movimentação das CTH na MO. Há sinais que a CTM pode ser a precursora da CE medulares, pois in vitro a CTM pode se diferenciar em CE-like. Desta forma, a CTM é um ponto chave no estudo das alterações causadas pela DPE no nicho perivascular e sobre a regulação da hematopoese. Neste trabalho, investigamos se a DPE afeta a diferenciação in vitro da CTM medular em CE-like e avaliamos se essas células apresentam diferentes capacidades em produzir alguns mediadores regulatórios da hematopoese (CXCL-12, SCF, Ang-1, IL-11, GM-CSF e TFG-β), bem como possíveis alterações no perfil de expressão gênica de marcadores de função das CTM e CE-like. Utilizamos camundongos C57BL/6 machos, divididos em grupos Controle e Desnutrido, sendo que o grupo Controle recebeu ração normoprotéica (12% caseína) e o grupo Desnutrido recebeu ração hipoprotéica (2% caseína), ambos durante 5 semanas. Após este período, os animais foram eutanasiados, foi realizada a avaliação nutricional e hematológica, caracterizando a DPE. As CTM foram isoladas, caracterizadas e diferenciadas in vitro em CE-like, o que foi evidenciado pela maior expressão gênica de NT5E, FLT1, KDR, PECAM1 e VCAM1. Avaliamos a expressão dos genes CDH5, CSPG4, LEPR, NES, CSF1, CSF2, CSF3, MCAM, PROM1, ANGPT1, CXCL12, ENG, IGF1, IL3, IL11, KITL, TGFB1, WNT3A, WNT5A, ICAM1, PDGFB1 e VWF. Encontramos alterações causadas pela DPE na expressão gênica e quantificação de CXCL-12, SCF e Ang-1, os quais mostraram que as células avaliadas do grupo Desnutrido encontram-se em um estado \"pró-proliferativo\", em um esforço para restabelecer a hematopoese na DPE. Entretanto, foi observado neste trabalho e nos demais trabalhos do grupo que há hipoplasia medular na DPE e, portanto, pode-se inferir que as alterações hematopoéticas observadas na DPE não são ocasionadas por alterações na síntese de SCF, CXCL-12 ou Ang-1. / Protein-energy malnutrition (PEM) causes anemia and leukopenia as it reduces hematopoietic precursors, impairs the production of mediators that induce hematopoiesis and alters structural and ultrastructural changes in bone marrow (BM) extracellular matrix. Hematopoiesis occurs in distinct BM niches - endosteal and perivascular - which modulate the processes of differentiation, proliferation and self-renewal of hematopoietic stem cell (HSC). Mesenchymal stem cells (MSC) play an important role in the formation of these niches through their differentiation in several cell types that compose them. Additionally, MSC can modulate the function of other cells, such as HSC and endothelial cells (EC), through the release of several growth factors and cytokines. The EC express proteins that regulate the differentiation and migration of HSC in the BM. MSC seem to be the precursor of medullary EC because in vitro MSC can differentiate into EC-like cells. Thus, MSC are a key point in the study of changes caused by DPE on the perivascular niche and on the regulation of hematopoiesis. In this study, we investigated whether PEM would affect BM-MSC in vitro differentiation into EC-like cells and evaluated whether these cells would have distinct capacities of producing some regulatory mediators of hematopoiesis (CXCL- 12, SCF, Ang-1, IL-11, GM -CSF and TFG-β), as well as analyzed possible changes in the gene expression profile of MSC function and EC-like cells related markers. C57BL/6 mice were divided into Control and Malnourished groups, which received for 5 weeks, respectively, a normal protein diet (12% casein) and a low protein diet (2% casein). After this period, animals were euthanized, nutritional and hematological evaluations were performed, featuring the PEM. MSC were isolated, characterized and differentiated in vitro into EC-like cells, which were evidenced by increased gene expression of NT5E, FLT1, KDR, PECAM1 and VCAM1. The expression of CDH5, CSPG4, LEPR, NES, CSF1, CSF2, CSF3, MCAM, PROM1, ANGPT1, CXCL12, ENG, IGF1, IL3, IL11, KITL, TGFB1, Wnt3a, WNT5A, ICAM1, PDGFB1 and VWF genes was also evaluated. Changes caused by PEM on gene expression and quantification of CXCL-12, SCF and Ang-1 were found, indicating that tested cells from the Malnourished group were in a \"pro-proliferative\" state in an effort to restore hematopoiesis. However, our results are in accordance to the literature regarding bone marrow hypoplasia as a consequence of PEM. Therefore, we infer hematopoietic changes observed in this work are not related to changes in the synthesis of SCF, 12 CXCL-12 or Ang-1.
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Prostaglandin E₂ promotes recovery of hematopoietic stem and progenitor cells after radiation exposureStilger, Kayla N. 11 July 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / The hematopoietic system is highly proliferative, making hematopoietic stem and progenitor cells (HSPC) sensitive to radiation damage. Total body irradiation and chemotherapy, as well as the risk of radiation accident, create a need for countermeasures that promote recovery of hematopoiesis. Substantive damage to the bone marrow from radiation exposure results in the hematopoietic syndrome of the acute radiation syndrome (HS-ARS), which includes life-threatening neutropenia, lymphocytopenia, thrombocytopenia, and possible death due to infection and/or hemorrhage. Given adequate time to recover, expand, and appropriately differentiate, bone marrow HSPC may overcome HS-ARS and restore homeostasis of the hematopoietic system. Prostaglandin E2 (PGE2) is known to have pleiotropic effects on hematopoiesis, inhibiting apoptosis and promoting self-renewal of hematopoietic stem cells (HSC), while inhibiting hematopoietic progenitor cell (HPC) proliferation. We assessed the radiomitigation potential of modulating PGE2 signaling in a mouse model of HS-ARS. Treatment with the PGE2 analog 16,16 dimethyl PGE2 (dmPGE2) at 24 hours post-irradiation resulted in increased survival of irradiated mice compared to vehicle control, with greater recovery in HPC number and colony-forming potential measured at 30 days post-irradiation. In a sublethal mouse model of irradiation, dmPGE2-treatment at 24 hours post-irradiation is associated with enhanced recovery of HSPC populations compared to vehicle-treated mice. Furthermore, dmPGE2-treatment may also act to promote recovery of the HSC niche through enhancement of osteoblast-supporting megakaryocyte (MK) migration to the endosteal surface of bone. A 2-fold increase in MKs within 40 um of the endosteum of cortical bone was seen at 48 hours post-irradiation in mice treated with dmPGE2 compared to mice treated with vehicle control. Treatment with the non-steroidal anti-inflammatory drug (NSAID) meloxicam abrogated this effect, suggesting an important role for PGE2 signaling in MK migration. In vitro assays support this data, showing that treatment with dmPGE2 increases MK expression of the chemokine receptor CXCR4 and enhances migration to its ligand SDF-1, which is produced by osteoblasts. Our results demonstrate the ability of dmPGE2 to act as an effective radiomitigative agent, promoting recovery of HSPC number and enhancing migration of MKs to the endosteum where they play a valuable role in niche restoration.
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Tsg-6 : an inducible mediator of paracrine anti-inflammatory and myeloprotective effects of adipose stem cellsXie, Jie 29 January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI). / Tumor necrosis factor-induced protein 6 (TSG-6) has been shown to mitigate inflammation. Its presence in the secretome of adipose stem / stromal cells (ASC) and its role in activities of ASC have been overlooked. This thesis described for the first time the release of TSG-6 from ASC, and its modulation by endothelial cells. It also revealed that protection of endothelial barrier function was a novel mechanism underlying the anti-inflammatory activity of both ASC and TSG-6. Moreover, TSG-6 was found to inhibit mitogen-activated lymphocyte proliferation, extending the understanding of its pleiotropic effects on major cell populations involved in inflammation.
Next, enzyme-linked immunosorbent assays (ELISA) were established to quantify secretion of TSG-6 from human and murine ASC. To study the importance of TSG-6 to specific activities of ASC, TSG-6 was knocked down in human ASC by siRNA. Murine ASC from TSG-6-/- mice were isolated and the down-regulation of TSG-6 was verified by ELISA. The subsequent attempt to determine the efficacy of ASC in ameliorating ischemic limb necrosis and the role of TSG-6, however, was hampered by the highly variable ischemic tissue necrosis in the BALB/c mouse strain.
Afterwards in a mouse model of cigarette smoking (CS), in which inflammation also plays an important role, it was observed, for the first time, that 3-day CS exposure caused an acute functional exhaustion and cell cycle arrest of hematopoietic progenitor cells; and that 7-week CS exposure led to marked depletion of phenotypic bone marrow stem and progenitor cells (HSPC). Moreover, a dynamic crosstalk between human ASC and murine host inflammatory signals was described, and specifically TSG-6 was identified as a necessary and sufficient mediator accounting for the activity of the ASC secretome to ameliorate CS-induced myelotoxicity. These results implicate TSG-6 as a key mediator for activities of ASC in mitigation of inflammation and protection of HSPC from the myelotoxicity of cigarette smoke. They also prompt the notion that ASC and TSG-6 might potentially play therapeutic roles in other scenarios involving myelotoxicity.
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