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The Characterization of Bovine Adipose-Derived Stem Cells in Conventional and Co-culture Environments for Tissue EngineeringZHAO, YIMU 10 March 2011 (has links)
Adipose-derived stem cells (ASCs) have been extensively investigated for their applicability in the field of tissue engineering due to their multi-lineage differentiation potential and the convenience of cell acquisition. To date, conventional inductive media have been used to induce lineage-specific differentiation of ASCs; however, this general approach has limitations in terms of high costs and unstable differentiation responses. In native tissues, mesenchymal stem cells (MSCs) interact with their surrounding cells (i.e. mature cells) through paracrine and autocrine signaling, which can regulate their metabolism and cell function. Therefore, the author developed in vitro co-culture models to study the interactions between ASCs and three different mature cell types: adipocytes, chondrocytes and osteoblasts.
In this work, bovine ASCs (bASCs) from the interdigital fat pad were first isolated and characterized, in terms of in vitro proliferation and multi-lineage (bone, cartilage, fat) differentiation with conventional inductive media and culture conditions. Doubling time calculations and gene expression analysis of stem cell markers indicated a threshold existed for stem cell degeneration at passage 5 (P5) for bASCs when expanded extensively in vitro. The multi-lineage differentiation potentials were compared between passage 2 (P2) and P5. Interestingly, while the P5 bASCs presented significantly lower levels of adipogenesis and chondrogenesis, osteogenesis was maintained or even improved with serial passaging.
In the designed indirect co-culture systems, adipogenesis and chondrogenesis were investigated in growth medium without key differentiation factors, whereas osteogenesis was induced in conventional osteogenic medium, to maintain the stable phenotype of the mature osteoblasts in culture. The results were used to demonstrate the general feasibility of mature cell-induced or -enhanced bASC differentiation through soluble, cell-secreted paracrine signaling. When compared to growth factor (GF)-stimulated differentiation, the bASCs in co-culture presented an earlier, but potentially stronger, level of differentiation.
Among these paracrine factors, Wnt proteins are known to play essential roles in mediating stem cell self-regulation and fate determination. In the current thesis, the Wnt inhibitors WIF-1 and DKK-1 were used to explore the involvement of the Wnt canonical and non-canonical signaling pathways in the designed co-culture environments. The data showed a strong correlation with the literature, indicating the canonical pathway was upregulated during osteogenesis, but inhibited during adipogenesis. The inhibition of chondrogenesis through the canonical pathway was suggested on a genetic level. / Thesis (Master, Chemical Engineering) -- Queen's University, 2011-03-09 13:39:14.553
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Matrix-Derived Microcarriers for Adipose Tissue EngineeringTURNER, ALLISON EUGENIA BOGART 01 December 2010 (has links)
In vivo, adipose tissue demonstrates only a limited capacity for self-repair, and the long-term treatment of subcutaneous defects remains an unresolved clinical problem. With the goal of regenerating healthy tissues, many tissue-engineering strategies have pointed to the potential of implementing three-dimensional (3-D), cell-seeded scaffolds for soft tissue augmentation and wound healing. In particular, microcarriers have shown promise as both cell expansion substrates and injectable cell-delivery vehicles for these applications. However, limited research has investigated the engineering of tissue-specific microcarriers, designed to closely mimic the native extracellular matrix (ECM) composition. In this work, methods were developed to fabricate microcarriers from decellularized adipose tissue (DAT) via non-cytotoxic protocols. Characterization by microscopy confirmed the efficacy of the fabrication protocols in producing stable beads, as well as the production of a microporous surface topography. The mean bead diameter was 934 ± 51 μm, while the porosity was measured to be 29 ± 4 % using liquid displacement. Stability and swelling behavior over 4 weeks indicated that the DAT-based microcarriers were effectively stabilized with the non-cytotoxic photochemical crosslinking agent rose bengal, with only low levels of protein release measured within a simulated physiological environment. In cell-based studies, the DAT-based microcarriers successfully supported the proliferation and adipogenic differentiation of human adipose-derived stem cells (hASCs) in a dynamic spinner flask system, with a more favorable response observed in terms of adhesion, proliferation, and adipogenesis on the DAT-based microcarriers relative to gelatin control beads. More specifically, dynamically-cultured hASCs on DAT-based microcarriers demonstrated greater lipid loading, as well as higher glycerol-3-phosphate dehydrogenase (GPDH) activity, a key enzyme involved in triacylglycerol biosynthesis, at 7 days and 14 days in culture in an inductive medium. Overall, the results indicated that the DAT-based microcarriers provided a uniquely supportive environment for adipogenesis. Established microcarrier sterility and injectability further support the broad potential of these tissue-specific microcarriers as a novel, adipogenic, clinically-translatable strategy for soft tissue engineering. / Thesis (Master, Chemical Engineering) -- Queen's University, 2010-12-01 14:28:14.628
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Optimizing harvesting for facial lipografting with a new photochemical stimulation concept: One STEP technique™Centurión, Patricio, Gamarra, Ronald, Caballero, Gonzalo, Kaufmann, Paul, Delgado, Pia 01 December 2020 (has links)
Background: Facial fat grafting for rejuvenation is one of the most popular facial aesthetic procedures in plastic surgery. It is always challenging and since there are a lot of techniques for adipose tissue (AT) harvesting, there are no standard procedures that guarantee natural and long-lasting results. We developed the selective tissue engineering photo stimulation technique (One STEP™) in which we used a novel infrared 1210-nm wavelength laser diode for fat preserved harvesting and direct fat injection that we named PicoGraft™, with no fat manipulation. Methods: This is a retrospective descriptive study in which we included all senior author’s patients that got facial fat grafting using the One STEP™ technique. We compared the AT aspirated, after laser emission (STEP-PicoGraft) and the standard assisted liposuction samples (SAL) in cultures. We study the mitochondrial activity of the ASC between STEP and SAL in fresh samples and after 24 h. The evaluation of the results included subjective changes regarding wrinkles, grooves, palpebral bags, hyperchromic spots, and fat hypotrophy of our patients. Results: Between July 2013 and May 2018, a total of 245 patients underwent facial fat grafting using this novel technique. We observed adipocytes preserved after STEP harvesting comparing morphologic changes in SAL samples with a high concentration of inflammatory particles in cultures. ASC mitochondrial activity shows an important difference of more than 7 times in STEP samples in fresh analysis that increase 12 times in 24 h. The subjective results show a good improvement in the periorbital area. The changes on the skin and subcutaneous tissue are seen from the second month and continue to improve up to 12 months. Conclusions: Facial fat grafting using the PicoGraft™ obtained by One STEP™ technique gives excellent volumetric and regenerative results in a single treatment without volumetric hypercorrection, and it is a good alternative for facial rejuvenation. The fat graft obtained with this novel technique is homogenous, without lumps, and has high concentration of viable stimulated ADSC and a high number of viable adipocytes. Level of evidence: Level III, therapeutic study. / Revisión por pares
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Efeitos da stanniocalcina 1 sobre a diferenciação osteogênica das células tronco adiposo-derivadas humanasTerra, Silvia Resende January 2016 (has links)
A stanniocalcina-1 (STC1) é uma glicoproteína caracterizada como um fator endócrino com ação anti-hipercalcêmica/hipocalcêmica originalmente descoberta em peixes. Em mamíferos, esse hormônio está expresso em praticamente todos os tecidos, regula diversas funções biológicas e atua como um fator autócrino/ parácrino. Diversas evidências demonstram o envolvimento da STC1 no desenvolvimento ósseo. Durante a embriogênese, a STC1 é expressa nos primeiros estágios de condensação mesenquimal e, posteriormente, se mantém restrita a preosteoblastos e osteoblastos maduros. Além disso, a STC1 estimula a mineralização óssea através do aumento da expressão de transportadores de fosfato e da osteopontina, uma sialoglicoproteína que atua na mineralização óssea. Células-tronco adultas simbolizam atualmente a fonte mais acessível de células progenitoras utilizadas em terapias celulares e engenharia de tecidos. O tecido adiposo contém uma população de células biológica e clinicamente interessantes denominada células tronco adiposo derivadas (CTADs). Atualmente as CTADs são a melhor fonte de células tronco adultas podendo ser obtidas através de procedimentos minimamente invasivos. Um grande número de estudos têm demonstrado o potencial osteogênico dessas células, no entanto, ainda é um desafio a compreensão dos mecanismos envolvidos na diferenciação osteogênica a partir das CTADs. Neste estudo, foi demonstrado que sete dias de indução osteogênica das CTADs na presença de 50 ng/mL de STC1 aumentaram significativamente a expressão gênica e proteica dos marcadores osteogênicos: fosfatase alcalina (FA), runt related gene 2 (RUNX2) e osteopontina (OPN) O aumento na atividade da enzima FAS foi relacionado diretamente com a maior expressão gênica e proteica. Além disso, a STC1 modula a via de sinalização pAKt/pGSK3-β/βcatenina em preosteoblastos de 7 dias sugerindo que seus efeitos sobre a osteogênese sejam mediados por essa via de sinalização. O peptídeo neuroendócrino CGRP (peptídeo relacionado ao gene da calcitonina) possui similaridades com STC1 e desempenha um importante papel nas fases iniciais da diferenciação dos osteoblastos. O CGRP ativa o receptor CALCRL, formando um dímero com a proteína transmembrana acessória RAMP1. Para elucidar o envolvimento da STC1 nas vias de sinalização relacionadas a receptores de calcitonina foi investigado o efeito desse hormônio na modulação 8 do receptor do CGRP e receptor de calcitonina (CTR) em CTADs diferenciadas para preosteoblastos e células Hek 293 superexpressoras de CALCRL/RAMP1 e CTR. A STC1 não alterou a expressão dos genes CALCRL e ramp1 durante a osteoblastogênese mas provocou alterações na distribuição espacial do complexo CALCRL/RAMP1 na membrana plasmática de preosteoblastos, induzindo a formação de clusters Além do efeito sobre a sinalização do CGRP a STC1 demonstrou inibir a sinalização da calcitonina diminuindo a produção de cAMP em células transfectadas com CTR. A STC1 não alterou os níveis intracelulares de cálcio e ATP. Esses resultados indicam que, embora não atue diretamente via os receptores CALCRL/RAMP1 e CTR, a STC1 modula a sinalização dos peptídeos CGRP e CT. Estudos mais detalhados sobre os efeitos da STC1 nas diferentes vias de sinalização são necessários para desvendar completamente os mecanismos de diferenciação osteogênicos das CTADs estimuladas por esse hormônio. / The stanniocalcin-1 (STC1) is a glycoprotein characterized as an endocrine factor with anti-hypercalcemic / hypocalcemic action, originally identified in fish. The hormone in mammals is expressed in virtually all tissues and regulates diverse biological functions, acting as an autocrine / paracrine factor. Many evidences demonstrate that STC1 is able to regulate bone development. During embryogenesis the STC1 is expressed in early stages of mesenchymal condensation and thereafter remains restricted to preosteoblast and mature osteoblast. Furthermore, STC1 stimulates bone mineralization by increasing the phosphate transporter expression and osteopontin, a sialoglycoprotein involved in bone mineralization. Adult stem cells currently symbolize the most accessible source of stem cells used in cell therapy and tissue engineering. Adipose tissue contains a population of biological cells clinically interesting called adipose derived stem cells (ASC). Currently, the ASCs are the best source of adult stem cells and can be harvested using minimally invasive procedures. A large number of studies had shown osteogenic potential of these cells, however, it is still a challenge to understand the mechanisms involved in osteogenic differentiation from ASCs This study demonstrated that 7-day preosteoblast in the presence of 50 ng / ml STC1 significantly increased gene and protein expression of osteogenic markers: alkaline phosphatase (ALP), runt related gene 2 (RUNX2), and osteopontin (OPN ). Also, there was an increase in the enzymatic activity of the ALP, possibly related to both gene and protein expression. Furthermore, STC1 modulates pAkt / pGSK3-β / βcatenina signaling in 7-day preosteoblast, suggesting that the STC1 effects on the osteogenesis is mediated by this pathway. The neuroendocrine peptide CGRP (calcitonin gene related peptide) has similarities to STC1 and plays an important role in the early stages of osteoblast differentiation. The active CGRP receptor form a dimer with the receptor activity-modifying protein 1 (RAMP1). To elucidate the involvement of STC1 in signaling pathways related to calcitonin receptors, it was investigated the STC1 effect on peptide receptor modulating the calcitonin gene related peptide (CGRP) and the calcitonin receptor (CTR) in 7-day preosteoblast, and in Hek 293 cells transfected with CALCRL / RAMP1 and CTR The STC1 did not change the expression of genes CALCRL and ramp1 during osteoblastogenesis but modified the plasma membrane spatial distribution of 10 CALCRL/RAMP1 in preosteoblast. Besides the effect on CGRP signaling, STC1 inhibited the calcitonin signaling by decreasing cAMP production in cells transfected with CTR. The STC1 did not alter intracellular calcium levels and ATP. These results indicated that STC1 does not act on the same receptors for calcitonin and CGRP, but modulates the action of these peptides. Studies on the effects of STC1 in different signaling pathways are necessary for understanding the mechanisms underlying the STC1 ability in enhancing osteoblastogenesis from hASCs.
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Efeitos da stanniocalcina 1 sobre a diferenciação osteogênica das células tronco adiposo-derivadas humanasTerra, Silvia Resende January 2016 (has links)
A stanniocalcina-1 (STC1) é uma glicoproteína caracterizada como um fator endócrino com ação anti-hipercalcêmica/hipocalcêmica originalmente descoberta em peixes. Em mamíferos, esse hormônio está expresso em praticamente todos os tecidos, regula diversas funções biológicas e atua como um fator autócrino/ parácrino. Diversas evidências demonstram o envolvimento da STC1 no desenvolvimento ósseo. Durante a embriogênese, a STC1 é expressa nos primeiros estágios de condensação mesenquimal e, posteriormente, se mantém restrita a preosteoblastos e osteoblastos maduros. Além disso, a STC1 estimula a mineralização óssea através do aumento da expressão de transportadores de fosfato e da osteopontina, uma sialoglicoproteína que atua na mineralização óssea. Células-tronco adultas simbolizam atualmente a fonte mais acessível de células progenitoras utilizadas em terapias celulares e engenharia de tecidos. O tecido adiposo contém uma população de células biológica e clinicamente interessantes denominada células tronco adiposo derivadas (CTADs). Atualmente as CTADs são a melhor fonte de células tronco adultas podendo ser obtidas através de procedimentos minimamente invasivos. Um grande número de estudos têm demonstrado o potencial osteogênico dessas células, no entanto, ainda é um desafio a compreensão dos mecanismos envolvidos na diferenciação osteogênica a partir das CTADs. Neste estudo, foi demonstrado que sete dias de indução osteogênica das CTADs na presença de 50 ng/mL de STC1 aumentaram significativamente a expressão gênica e proteica dos marcadores osteogênicos: fosfatase alcalina (FA), runt related gene 2 (RUNX2) e osteopontina (OPN) O aumento na atividade da enzima FAS foi relacionado diretamente com a maior expressão gênica e proteica. Além disso, a STC1 modula a via de sinalização pAKt/pGSK3-β/βcatenina em preosteoblastos de 7 dias sugerindo que seus efeitos sobre a osteogênese sejam mediados por essa via de sinalização. O peptídeo neuroendócrino CGRP (peptídeo relacionado ao gene da calcitonina) possui similaridades com STC1 e desempenha um importante papel nas fases iniciais da diferenciação dos osteoblastos. O CGRP ativa o receptor CALCRL, formando um dímero com a proteína transmembrana acessória RAMP1. Para elucidar o envolvimento da STC1 nas vias de sinalização relacionadas a receptores de calcitonina foi investigado o efeito desse hormônio na modulação 8 do receptor do CGRP e receptor de calcitonina (CTR) em CTADs diferenciadas para preosteoblastos e células Hek 293 superexpressoras de CALCRL/RAMP1 e CTR. A STC1 não alterou a expressão dos genes CALCRL e ramp1 durante a osteoblastogênese mas provocou alterações na distribuição espacial do complexo CALCRL/RAMP1 na membrana plasmática de preosteoblastos, induzindo a formação de clusters Além do efeito sobre a sinalização do CGRP a STC1 demonstrou inibir a sinalização da calcitonina diminuindo a produção de cAMP em células transfectadas com CTR. A STC1 não alterou os níveis intracelulares de cálcio e ATP. Esses resultados indicam que, embora não atue diretamente via os receptores CALCRL/RAMP1 e CTR, a STC1 modula a sinalização dos peptídeos CGRP e CT. Estudos mais detalhados sobre os efeitos da STC1 nas diferentes vias de sinalização são necessários para desvendar completamente os mecanismos de diferenciação osteogênicos das CTADs estimuladas por esse hormônio. / The stanniocalcin-1 (STC1) is a glycoprotein characterized as an endocrine factor with anti-hypercalcemic / hypocalcemic action, originally identified in fish. The hormone in mammals is expressed in virtually all tissues and regulates diverse biological functions, acting as an autocrine / paracrine factor. Many evidences demonstrate that STC1 is able to regulate bone development. During embryogenesis the STC1 is expressed in early stages of mesenchymal condensation and thereafter remains restricted to preosteoblast and mature osteoblast. Furthermore, STC1 stimulates bone mineralization by increasing the phosphate transporter expression and osteopontin, a sialoglycoprotein involved in bone mineralization. Adult stem cells currently symbolize the most accessible source of stem cells used in cell therapy and tissue engineering. Adipose tissue contains a population of biological cells clinically interesting called adipose derived stem cells (ASC). Currently, the ASCs are the best source of adult stem cells and can be harvested using minimally invasive procedures. A large number of studies had shown osteogenic potential of these cells, however, it is still a challenge to understand the mechanisms involved in osteogenic differentiation from ASCs This study demonstrated that 7-day preosteoblast in the presence of 50 ng / ml STC1 significantly increased gene and protein expression of osteogenic markers: alkaline phosphatase (ALP), runt related gene 2 (RUNX2), and osteopontin (OPN ). Also, there was an increase in the enzymatic activity of the ALP, possibly related to both gene and protein expression. Furthermore, STC1 modulates pAkt / pGSK3-β / βcatenina signaling in 7-day preosteoblast, suggesting that the STC1 effects on the osteogenesis is mediated by this pathway. The neuroendocrine peptide CGRP (calcitonin gene related peptide) has similarities to STC1 and plays an important role in the early stages of osteoblast differentiation. The active CGRP receptor form a dimer with the receptor activity-modifying protein 1 (RAMP1). To elucidate the involvement of STC1 in signaling pathways related to calcitonin receptors, it was investigated the STC1 effect on peptide receptor modulating the calcitonin gene related peptide (CGRP) and the calcitonin receptor (CTR) in 7-day preosteoblast, and in Hek 293 cells transfected with CALCRL / RAMP1 and CTR The STC1 did not change the expression of genes CALCRL and ramp1 during osteoblastogenesis but modified the plasma membrane spatial distribution of 10 CALCRL/RAMP1 in preosteoblast. Besides the effect on CGRP signaling, STC1 inhibited the calcitonin signaling by decreasing cAMP production in cells transfected with CTR. The STC1 did not alter intracellular calcium levels and ATP. These results indicated that STC1 does not act on the same receptors for calcitonin and CGRP, but modulates the action of these peptides. Studies on the effects of STC1 in different signaling pathways are necessary for understanding the mechanisms underlying the STC1 ability in enhancing osteoblastogenesis from hASCs.
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Efeitos da stanniocalcina 1 sobre a diferenciação osteogênica das células tronco adiposo-derivadas humanasTerra, Silvia Resende January 2016 (has links)
A stanniocalcina-1 (STC1) é uma glicoproteína caracterizada como um fator endócrino com ação anti-hipercalcêmica/hipocalcêmica originalmente descoberta em peixes. Em mamíferos, esse hormônio está expresso em praticamente todos os tecidos, regula diversas funções biológicas e atua como um fator autócrino/ parácrino. Diversas evidências demonstram o envolvimento da STC1 no desenvolvimento ósseo. Durante a embriogênese, a STC1 é expressa nos primeiros estágios de condensação mesenquimal e, posteriormente, se mantém restrita a preosteoblastos e osteoblastos maduros. Além disso, a STC1 estimula a mineralização óssea através do aumento da expressão de transportadores de fosfato e da osteopontina, uma sialoglicoproteína que atua na mineralização óssea. Células-tronco adultas simbolizam atualmente a fonte mais acessível de células progenitoras utilizadas em terapias celulares e engenharia de tecidos. O tecido adiposo contém uma população de células biológica e clinicamente interessantes denominada células tronco adiposo derivadas (CTADs). Atualmente as CTADs são a melhor fonte de células tronco adultas podendo ser obtidas através de procedimentos minimamente invasivos. Um grande número de estudos têm demonstrado o potencial osteogênico dessas células, no entanto, ainda é um desafio a compreensão dos mecanismos envolvidos na diferenciação osteogênica a partir das CTADs. Neste estudo, foi demonstrado que sete dias de indução osteogênica das CTADs na presença de 50 ng/mL de STC1 aumentaram significativamente a expressão gênica e proteica dos marcadores osteogênicos: fosfatase alcalina (FA), runt related gene 2 (RUNX2) e osteopontina (OPN) O aumento na atividade da enzima FAS foi relacionado diretamente com a maior expressão gênica e proteica. Além disso, a STC1 modula a via de sinalização pAKt/pGSK3-β/βcatenina em preosteoblastos de 7 dias sugerindo que seus efeitos sobre a osteogênese sejam mediados por essa via de sinalização. O peptídeo neuroendócrino CGRP (peptídeo relacionado ao gene da calcitonina) possui similaridades com STC1 e desempenha um importante papel nas fases iniciais da diferenciação dos osteoblastos. O CGRP ativa o receptor CALCRL, formando um dímero com a proteína transmembrana acessória RAMP1. Para elucidar o envolvimento da STC1 nas vias de sinalização relacionadas a receptores de calcitonina foi investigado o efeito desse hormônio na modulação 8 do receptor do CGRP e receptor de calcitonina (CTR) em CTADs diferenciadas para preosteoblastos e células Hek 293 superexpressoras de CALCRL/RAMP1 e CTR. A STC1 não alterou a expressão dos genes CALCRL e ramp1 durante a osteoblastogênese mas provocou alterações na distribuição espacial do complexo CALCRL/RAMP1 na membrana plasmática de preosteoblastos, induzindo a formação de clusters Além do efeito sobre a sinalização do CGRP a STC1 demonstrou inibir a sinalização da calcitonina diminuindo a produção de cAMP em células transfectadas com CTR. A STC1 não alterou os níveis intracelulares de cálcio e ATP. Esses resultados indicam que, embora não atue diretamente via os receptores CALCRL/RAMP1 e CTR, a STC1 modula a sinalização dos peptídeos CGRP e CT. Estudos mais detalhados sobre os efeitos da STC1 nas diferentes vias de sinalização são necessários para desvendar completamente os mecanismos de diferenciação osteogênicos das CTADs estimuladas por esse hormônio. / The stanniocalcin-1 (STC1) is a glycoprotein characterized as an endocrine factor with anti-hypercalcemic / hypocalcemic action, originally identified in fish. The hormone in mammals is expressed in virtually all tissues and regulates diverse biological functions, acting as an autocrine / paracrine factor. Many evidences demonstrate that STC1 is able to regulate bone development. During embryogenesis the STC1 is expressed in early stages of mesenchymal condensation and thereafter remains restricted to preosteoblast and mature osteoblast. Furthermore, STC1 stimulates bone mineralization by increasing the phosphate transporter expression and osteopontin, a sialoglycoprotein involved in bone mineralization. Adult stem cells currently symbolize the most accessible source of stem cells used in cell therapy and tissue engineering. Adipose tissue contains a population of biological cells clinically interesting called adipose derived stem cells (ASC). Currently, the ASCs are the best source of adult stem cells and can be harvested using minimally invasive procedures. A large number of studies had shown osteogenic potential of these cells, however, it is still a challenge to understand the mechanisms involved in osteogenic differentiation from ASCs This study demonstrated that 7-day preosteoblast in the presence of 50 ng / ml STC1 significantly increased gene and protein expression of osteogenic markers: alkaline phosphatase (ALP), runt related gene 2 (RUNX2), and osteopontin (OPN ). Also, there was an increase in the enzymatic activity of the ALP, possibly related to both gene and protein expression. Furthermore, STC1 modulates pAkt / pGSK3-β / βcatenina signaling in 7-day preosteoblast, suggesting that the STC1 effects on the osteogenesis is mediated by this pathway. The neuroendocrine peptide CGRP (calcitonin gene related peptide) has similarities to STC1 and plays an important role in the early stages of osteoblast differentiation. The active CGRP receptor form a dimer with the receptor activity-modifying protein 1 (RAMP1). To elucidate the involvement of STC1 in signaling pathways related to calcitonin receptors, it was investigated the STC1 effect on peptide receptor modulating the calcitonin gene related peptide (CGRP) and the calcitonin receptor (CTR) in 7-day preosteoblast, and in Hek 293 cells transfected with CALCRL / RAMP1 and CTR The STC1 did not change the expression of genes CALCRL and ramp1 during osteoblastogenesis but modified the plasma membrane spatial distribution of 10 CALCRL/RAMP1 in preosteoblast. Besides the effect on CGRP signaling, STC1 inhibited the calcitonin signaling by decreasing cAMP production in cells transfected with CTR. The STC1 did not alter intracellular calcium levels and ATP. These results indicated that STC1 does not act on the same receptors for calcitonin and CGRP, but modulates the action of these peptides. Studies on the effects of STC1 in different signaling pathways are necessary for understanding the mechanisms underlying the STC1 ability in enhancing osteoblastogenesis from hASCs.
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