Adipose-derived stromal cells (ASCs) have gained great attention in regenerative medicine. Progress in our understanding of adult neovascularization further suggests the potential of ASCs in promoting vascular regen...Adipose-derived stromal cells (ASCs) have gained great attention in regenerative medicine. Progress in our understanding of adult neovascularization further suggests the potential of ASCs in promoting vascular regeneration, although the specific cues that stimulate their angiogenic behavior remain controversial In this study, we established a three-dimensional (3D) angiogenesis model by co-culturing ASCs and endothelial cells (ECs) in collagen gel and found that ASC-EC-instructed angiogenesis was regulated by the canonical Wnt pathway. Furthermore, the angiogenesis that occurred in implants collected after injections of our collagen gel- based 3D angiogenesis model into nude mice was confirmed to be functional and also regulated by the canonical Wnt pathway. Wnt regulation of angiogenesis involving changes in vessel length, vessel density, vessel sprout, and connection numbers occurred in our system. Wnt signaling was then shown to regulate ASC- mediated paracrine signaling during angiogenesis through the nuclear translocation of β-catenin after its cytoplasmic accumulation in both ASCs and ECs. This translocation enhanced the expression of nuclear cofactor Lef-1 and cyclin D1 and activated the angiogenic transcription of vascular endothelial growth factor A (VEGFA), basic fibroblast growth factor (bFGF), and insulin-like growth factor 1 (IGF-1). The angiogenesis process in the 3D collagen model appeared to follow canonical Wnt signaling, and this model can help us understand the importance of the canonical Wnt pathway in the use of ASCs in vascular regeneration.展开更多
Vascular formation in vivo involves several processes and signal cascades subsequently occurring in the embryo. Several models by ES cells have been reported for analysis in vitro. We show here a 3D culture system usi...Vascular formation in vivo involves several processes and signal cascades subsequently occurring in the embryo. Several models by ES cells have been reported for analysis in vitro. We show here a 3D culture system using collagen gel (AteloCell) as a simple and useful system for investigating vascular formations and analyzing the roles of factors in vivo. Although VEGF and PDGF are growth factors with multi-potentials for vascular formation, their sequential roles have not been elucidated. We investigated the effects of VEGF and PDGF B signals for vascular formation by a 3D culture system that embedded embryoid bodies (EBs) from ES cells into a collagen gel. After embedding EBs in the collagen gel with a medium containing VEGF, EBs gave off CD105 immunopositive vessels as the initial step of vasculogenesis. When the factor in the culture medium for EBs was switched from VEGF to PDGF B after 5 days of culture, the morphological features of vessels varied, suggesting the occurrence of vascular-type differentiation. After 11 days of 3D culture, vessels in both groups cultured with VEGF alone and switching to VEGF B at day 5 showed Flk-1 immunoreactivity. Some blood vessels cultured with PDGF B after day 5 expressed either EphrinB2 (arteriole marker) or Flt-4 (lymphatic marker) immunoreactivity, but vessels cultured with VEGF alone exhibited neither of them. Vessels cultured with these two factors could not differentiate into a venous type. The present study indicates that VEGF is the initial signal for vasculogenesis, and that PDGF B is probably involved in vascular diversification.展开更多
该文通过体外构建三维(3D)细胞培养模型,探讨基于3D细胞模型的基因转染条件。实验选用甲基纤维素半固体培养体系,建立了体外3D细胞模型。并采用聚乙烯亚胺(PEI,25 k Da)介导荧光标记质粒和增强绿色荧光蛋白报告基因的转染,激光扫描共聚...该文通过体外构建三维(3D)细胞培养模型,探讨基于3D细胞模型的基因转染条件。实验选用甲基纤维素半固体培养体系,建立了体外3D细胞模型。并采用聚乙烯亚胺(PEI,25 k Da)介导荧光标记质粒和增强绿色荧光蛋白报告基因的转染,激光扫描共聚焦三维重构技术进一步分析基因在3D细胞模型中的传输及表达情况。结果表明,当PEI和质粒DNA的复合比为10时,PEI介导的基因在3D细胞模型中具有良好的传输能力和一定的表达能力。本研究结果可为3D细胞模型在基因转染方面的应用提供实验依据。展开更多
Pancreatic cancer carries a terrible prognosis,as the fourth most common cause of cancer death in the Western world.There is clearly a need for new therapies to treat this disease.One of the reasons no effective treat...Pancreatic cancer carries a terrible prognosis,as the fourth most common cause of cancer death in the Western world.There is clearly a need for new therapies to treat this disease.One of the reasons no effective treatment has been developed in the past decade may in part,be explained by the diverse influences exerted by the tumour microenvironment.The tumour stroma cross-talk in pancreatic cancer can influence chemotherapy delivery and response rate.Thus,appropriate preclinical in vitro models which can bridge simple 2D in vitro cell based assays and complex in vivo models are required to understand the biology of pancreatic cancer.Here we discuss the evolution of 3D organotypic models,which recapitulare the morphological and functional features of pancreatic ductal adenocarcinoma(PDAC).Organotypic cultures are a valid high throughput preclinical in vitro model that maybe a useful tool to help establish new therapies for PDAC.A huge advantage of the organotypic model system is that any component of the model can be easily modulated in a short timeframe.This allows new therapies that can target the cancer,the stromal compartment or both to be tested in a model that mirrors the in vivo situation.A major challenge for the future is to expand the cellular composition of the organotypic model to further develop a system that mimics the PDAC environment more precisely.We discuss how this challenge is being met to increase our understanding of this terrible disease and develop novel therapies that can improve the prognosis for patients.展开更多
基金funded by the National Natural Science Foundation of China(81771125,81471803,81671031)the Sichuan Province Youth Science and Technology Innovation Team(2014TD0001)
文摘Adipose-derived stromal cells (ASCs) have gained great attention in regenerative medicine. Progress in our understanding of adult neovascularization further suggests the potential of ASCs in promoting vascular regeneration, although the specific cues that stimulate their angiogenic behavior remain controversial In this study, we established a three-dimensional (3D) angiogenesis model by co-culturing ASCs and endothelial cells (ECs) in collagen gel and found that ASC-EC-instructed angiogenesis was regulated by the canonical Wnt pathway. Furthermore, the angiogenesis that occurred in implants collected after injections of our collagen gel- based 3D angiogenesis model into nude mice was confirmed to be functional and also regulated by the canonical Wnt pathway. Wnt regulation of angiogenesis involving changes in vessel length, vessel density, vessel sprout, and connection numbers occurred in our system. Wnt signaling was then shown to regulate ASC- mediated paracrine signaling during angiogenesis through the nuclear translocation of β-catenin after its cytoplasmic accumulation in both ASCs and ECs. This translocation enhanced the expression of nuclear cofactor Lef-1 and cyclin D1 and activated the angiogenic transcription of vascular endothelial growth factor A (VEGFA), basic fibroblast growth factor (bFGF), and insulin-like growth factor 1 (IGF-1). The angiogenesis process in the 3D collagen model appeared to follow canonical Wnt signaling, and this model can help us understand the importance of the canonical Wnt pathway in the use of ASCs in vascular regeneration.
文摘Vascular formation in vivo involves several processes and signal cascades subsequently occurring in the embryo. Several models by ES cells have been reported for analysis in vitro. We show here a 3D culture system using collagen gel (AteloCell) as a simple and useful system for investigating vascular formations and analyzing the roles of factors in vivo. Although VEGF and PDGF are growth factors with multi-potentials for vascular formation, their sequential roles have not been elucidated. We investigated the effects of VEGF and PDGF B signals for vascular formation by a 3D culture system that embedded embryoid bodies (EBs) from ES cells into a collagen gel. After embedding EBs in the collagen gel with a medium containing VEGF, EBs gave off CD105 immunopositive vessels as the initial step of vasculogenesis. When the factor in the culture medium for EBs was switched from VEGF to PDGF B after 5 days of culture, the morphological features of vessels varied, suggesting the occurrence of vascular-type differentiation. After 11 days of 3D culture, vessels in both groups cultured with VEGF alone and switching to VEGF B at day 5 showed Flk-1 immunoreactivity. Some blood vessels cultured with PDGF B after day 5 expressed either EphrinB2 (arteriole marker) or Flt-4 (lymphatic marker) immunoreactivity, but vessels cultured with VEGF alone exhibited neither of them. Vessels cultured with these two factors could not differentiate into a venous type. The present study indicates that VEGF is the initial signal for vasculogenesis, and that PDGF B is probably involved in vascular diversification.
文摘该文通过体外构建三维(3D)细胞培养模型,探讨基于3D细胞模型的基因转染条件。实验选用甲基纤维素半固体培养体系,建立了体外3D细胞模型。并采用聚乙烯亚胺(PEI,25 k Da)介导荧光标记质粒和增强绿色荧光蛋白报告基因的转染,激光扫描共聚焦三维重构技术进一步分析基因在3D细胞模型中的传输及表达情况。结果表明,当PEI和质粒DNA的复合比为10时,PEI介导的基因在3D细胞模型中具有良好的传输能力和一定的表达能力。本研究结果可为3D细胞模型在基因转染方面的应用提供实验依据。
文摘Pancreatic cancer carries a terrible prognosis,as the fourth most common cause of cancer death in the Western world.There is clearly a need for new therapies to treat this disease.One of the reasons no effective treatment has been developed in the past decade may in part,be explained by the diverse influences exerted by the tumour microenvironment.The tumour stroma cross-talk in pancreatic cancer can influence chemotherapy delivery and response rate.Thus,appropriate preclinical in vitro models which can bridge simple 2D in vitro cell based assays and complex in vivo models are required to understand the biology of pancreatic cancer.Here we discuss the evolution of 3D organotypic models,which recapitulare the morphological and functional features of pancreatic ductal adenocarcinoma(PDAC).Organotypic cultures are a valid high throughput preclinical in vitro model that maybe a useful tool to help establish new therapies for PDAC.A huge advantage of the organotypic model system is that any component of the model can be easily modulated in a short timeframe.This allows new therapies that can target the cancer,the stromal compartment or both to be tested in a model that mirrors the in vivo situation.A major challenge for the future is to expand the cellular composition of the organotypic model to further develop a system that mimics the PDAC environment more precisely.We discuss how this challenge is being met to increase our understanding of this terrible disease and develop novel therapies that can improve the prognosis for patients.