健脾方药提取物对小鼠小肠类器官的干预

目的探讨健脾方药四君子汤多糖提取物、黄芪甲苷对小鼠小肠类器官的干预作用。方法取4~6周龄小鼠小肠约20 cm,经过清洗、剪切、消化,分离出小肠隐窝细胞团后,接种于含有多种细胞因子的基质胶中,在基质胶3D结构支撑下,培养形成具有小肠上皮样形态的立体多叶结构,即小肠类器官。光镜下观察小肠类器官的形态特征;采用免疫荧光染色后在激光共聚焦显微镜下观察E-钙黏蛋白(E-cadherin)的表达;传代2天后的小鼠小肠类器官分为3组:对照组、四君子多糖组(终浓度为100 mg/L)以及黄芪甲苷组(终浓度为10μmol/L),继续培养48 h后观察四君子汤多糖提取物、黄芪甲苷对小肠类器官出芽生长及增殖细胞核核抗原Ki-67表达。结果分离出的小鼠隐窝细胞团1天类似囊状,中心具有单个内腔;2~3天开始出芽;4~5天出芽增多,管腔结构进一步清晰,形成小肠类器官,初步建立了小肠类器官培养模式;四君子多糖组(100 mg/L)小肠类器官出芽数量较对照组明显增多(2.31±1.60vs 4.15±1.91,P<0.05);黄芪甲苷组较对照组中小肠类器官Ki-67表达明显增高。结论小肠类器官模型的构建为探讨肠黏膜修复的病理生理机制及药物干预提供了更完善的体外研究模型。四君子汤多糖提取物、黄芪甲苷的肠黏膜保护作用可能与其促进隐窝干细胞更新能力有关。     

Development of a protocol for maintaining viability while shipping organoid‐derived retinal tissue

Retinal organoid technology enables generation of an inexhaustible supply of three‐dimensional retinal tissue from human pluripotent stem cells (hPSCs) for regenerative medicine applications. The high similarity of organoid‐derived retinal tissue and transplantable human fetal retina provides an opportunity for evaluating and modeling retinal tissue replacement strategies in relevant animal models in the effort to develop a functional retinal patch to restore vision in patients with profound blindness caused by retinal degeneration. Because of the complexity of this very promising approach requiring specialized stem cell and grafting techniques, the tasks of retinal tissue derivation and transplantation are frequently split between geographically distant teams. Delivery of delicate and perishable neural tissue such as retina to the surgical sites requires a reliable shipping protocol and also controlled temperature conditions with damage‐reporting mechanisms in place to prevent transplantation of tissue damaged in transit into expensive animal models. We have developed a robust overnight tissue shipping protocol providing reliable temperature control, live monitoring of the shipment conditions and physical location of the package, and damage reporting at the time of delivery. This allows for shipping of viable (transplantation‐competent) hPSC‐derived retinal tissue over large distances, thus enabling stem cell and surgical teams from different parts of the country to work together and maximize successful engraftment of organoid‐derived retinal tissue. Although this protocol was developed for preclinical in vivo studies in animal models, it is potentially translatable for clinical transplantation in the future and will contribute to developing clinical protocols for restoring vision in patients with retinal degeneration.     

CRIPTO promotes an aggressive tumour phenotype and resistance to treatment in hepatocellular carcinoma

Hepatocellular carcinoma (HCC) is the third leading cause of cancer‐related death worldwide. Despite increasing treatment options for this disease, prognosis remains poor. CRIPTO (TDGF1) protein is expressed at high levels in several human tumours and promotes oncogenic phenotype. Its expression has been correlated to poor prognosis in HCC. In this study, we aimed to elucidate the basis for the effects of CRIPTO in HCC. We investigated CRIPTO expression levels in three cohorts of clinical cirrhotic and HCC specimens. We addressed the role of CRIPTO in hepatic tumourigenesis using Cre‐loxP‐controlled lentiviral vectors expressing CRIPTO in cell line‐derived xenografts. Responses to standard treatments (sorafenib, doxorubicin) were assessed directly on xenograft‐derived ex vivo tumour slices. CRIPTO‐overexpressing patient‐derived xenografts were established and used for ex vivo drug response assays. The effects of sorafenib and doxorubicin treatment in combination with a CRIPTO pathway inhibitor were tested in ex vivo cultures of xenograft models and 3D cultures. CRIPTO protein was found highly expressed in human cirrhosis and hepatocellular carcinoma specimens but not in those of healthy participants. Stable overexpression of CRIPTO in human HepG2 cells caused epithelial‐to‐mesenchymal transition, increased expression of cancer stem cell markers, and enhanced cell proliferation and migration. HepG2‐CRIPTO cells formed tumours when injected into immune‐compromised mice, whereas HepG2 cells lacking stable CRIPTO overexpression did not. High‐level CRIPTO expression in xenograft models was associated with resistance to sorafenib, which could be modulated using a CRIPTO pathway inhibitor in ex vivo tumour slices. Our data suggest that a subgroup of CRIPTO‐expressing HCC patients may benefit from a combinatorial treatment scheme and that sorafenib resistance may be circumvented by inhibition of the CRIPTO pathway. Copyright © 2018 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Psychiatry in a Dish: Stem Cells and Brain Organoids Modeling Autism Spectrum Disorders

Autism spectrum disorders are a group of pervasive neurodevelopmental conditions with heterogeneous etiology, characterized by deficits in social cognition, communication, and behavioral flexibility. Despite an increasing scientific effort to find the pathophysiological explanations for the disease, the neurobiological links remain unclear. A large amount of evidence suggests that pathological processes taking place in early embryonic neurodevelopment might be responsible for later manifestation of autistic symptoms. This dysfunctional development includes altered maturation/differentiation processes, disturbances in cell–cell communication, and an unbalanced ratio between certain neuronal populations. All those processes are highly dependent on the interconnectivity and three-dimensional organizations of the brain. Moreover, in order to gain a deeper understanding of the complex neurobiology of autism spectrum disorders, valid disease models are pivotal. Induced pluripotent stem cells could potentially help to elucidate the complex mechanisms of the disease and lead to the development of more effective individualized treatment. The induced pluripotent stem cells approach allows comparison between the development of various cellular phenotypes generated from cell lines of patients and healthy individuals. A newly advanced organoid technology makes it possible to create three-dimensional in vitro models of brain development and structural interconnectivity, based on induced pluripotent stem cells derived from the respective individuals. The biggest challenge for modeling psychiatric diseases in vitro is finding and establishing the link between cellular and molecular findings with the clinical symptoms, and this review aims to give an overview over the feasibility and applicability of this new tissue engineering tool in psychiatry.     

The Potentials and Pitfalls of a Human Cervical Organoid Model Including Langerhans Cells

Three-dimensional cell culturing to capture a life-like experimental environment has become a versatile tool for basic and clinical research. Mucosal and skin tissues can be grown as “organoids” in a petri dish and serve a wide variety of research questions. Here, we report our experience with human cervical organoids which could also include an immune component, e.g., Langerhans cells. We employ commercially available human cervical keratinocytes and fibroblasts as well as a myeloid cell line matured and purified into langerin-positive Langerhans cells. These are then seeded on a layer of keratinocytes with underlying dermal equivalent. Using about 10-fold more than the reported number in healthy cervical tissue (1–3%), we obtain differentiated cervical epithelium after 14 days with ~1% being Langerhans cells. We provide a detailed protocol for interested researchers to apply the described “aseptic” organoid model for all sorts of investigations—with or without Langerhans cells.     

Newly-found functions of metformin for the prevention and treatment of age-related macular degeneration

AIM: To explore the temporal mitochondrial characteristics of retinal pigment epithelium (RPE) cells obtained from human embryonic stem cells (hESC)-derived retinal organoids (hEROs-RPE), to verify the optimal period for using hEROs-RPE as donor cells from the aspect of mitochondria and to optimize RPE cell-based therapeutic strategies for age-related macular degeneration (AMD). METHODS: RPE cells were obtained from hEROs and from spontaneous differentiation (SD-RPE). The mitochondrial characteristics were analyzed every 20d from day 60 to 160. Mitochondrial quantity was measured by MitoTracker Green staining. Transmission electron microscopy was adopted to assess the morphological features of the mitochondria, including their distribution, length, and cristae. Mitochondrial membrane potentials (MMPs) were determined by JC-1 staining and flow cytometry. ROS levels were evaluated by flow cytometry, and ATP levels were measured by a luminometer. Differences between two groups were analyzed by the independent-samples t-test, and comparisons among multiple groups were made using one-way ANOVA or Kruskal-Wallis H test when equal variance is not assumed. RESULTS: hEROs-RPE and SD-RPE cells from day 60 to 160 were successfully differentiated from hESCs and expressed RPE-specific markers (Pax6, mitf, Bestrophin-1, RPE65, Cralbp). RPE features, including a cobblestone-like morphology with tight junctions (ZO-1), pigments and microvilli, were also observed in both hERO-RPE and SD-RPE cells. The mitochondrial quantities peaked in both hEROs-RPE and SD-RPE cells at day 80. However, the cristae of hEROs mitochondria were less mature and abundant than those of SD mitochondria at day 80, with hEROs mitochondria becoming mature at day 100. Both hEROs-RPE and SD-RPE cells showed low ROS levels from day 100 to 140 and maintained a normal MMP during this period. However, hEROs mitochondria maintained a longer time to produce high levels of ATP (from day 120 to 140) than SD-RPE cells (only day 120). CONCLUSION: Mitochondria of hEROs-RPE cells develop slower and maintain a longer time to supply high-levels of energy than SD-RPE cells. From a mitochondrial aspect, hEROs-RPE cells from day 100 to 140 are an optimal cell source for treating AMD.