Catalase incorporation in freezing mixture leads to improved recovery of cryopreserved iPSC lines

Among the various types of stem cells, induced pluripotent stem cells (iPSCs) have gained much attention due to their pluripotent nature. iPSCs help us to understand the processes that regulate pluripotency and specialization. However, in order to use them in various applications in regenerative medicine, their efficient cryopreservation and recovery after the freezing injury is critical. Here we have used an antioxidant catalase, as an additive to the conventional freezing mixture containing 50% FBS and 10% DMSO. The hiPSCs were frozen as aggregates by using a programmable freezer and then stored in liquid nitrogen at −196 °C. It was seen that catalase improved the revival efficiency by reducing the late apoptotic populations and increasing the live cell fraction. Catalase also retained the pluripotent nature of iPSCs in a better way post revival. This improvement could be attributed to reduction of total ROS and apoptosis, which are the two main factors that cause damage during freezing. Our data suggest that catalase could be a useful additive while freezing hiPSCs.     

Post-gastrulation synthetic embryos generated ex utero from mouse naive ESCs

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Functionally distinct roles for TET-oxidized 5-methylcytosine bases in somatic reprogramming to pluripotency

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Diversity of dermal fibroblasts as major determinant of variability in cell reprogramming

Induced pluripotent stem cells (iPSCs) are adult somatic cells genetically reprogrammed to an embryonic stem cell‐like state. Notwithstanding their autologous origin and their potential to differentiate towards cells of all three germ layers, iPSC reprogramming is still affected by low efficiency. As dermal fibroblast is the most used human cell for reprogramming, we hypothesize that the variability in reprogramming is, at least partially, because of the skin fibroblasts used. Human dermal fibroblasts harvested from five different anatomical sites (neck, breast, arm, abdomen and thigh) were cultured and their morphology, proliferation, apoptotic rate, ability to migrate, expression of mesenchymal or epithelial markers, differentiation potential and production of growth factors were evaluated in vitro. Additionally, gene expression analysis was performed by real‐time PCR including genes typically expressed by mesenchymal cells. Finally, fibroblasts isolated from different anatomic sites were reprogrammed to iPSCs by integration‐free method. Intriguingly, while the morphology of fibroblasts derived from different anatomic sites differed only slightly, other features, known to affect cell reprogramming, varied greatly and in accordance with anatomic site of origin. Accordingly, difference also emerged in fibroblasts readiness to respond to reprogramming and ability to form colonies. Therefore, as fibroblasts derived from different anatomic sites preserve positional memory, it is of great importance to accurately evaluate and select dermal fibroblast population prior to induce reprogramming.     

诱导多能干细胞向雄性生殖细胞分化诱导物的研究进展

诱导多能干细胞(induced pluripotent stem cells,iPSCs)是利用细胞重编程技术人工获得的与胚胎干细胞(embryonic stem cells,ESCs)功能类似的细胞,能分化成包括三胚层在内的所有细胞类型,并且规避了ESCs的伦理学争议和移植后的免疫排斥问题,具有十分广阔的应用前景。对iPSCs体外诱导为生殖细胞所用的诱导物及其诱导效果进行了综述,生殖细胞发育机制的研究有望促进未来生殖和发育技术的进步。     

诱导多能干细胞在医学方面的应用

2006年,首次报道在体外简单的转录因子就可以使体细胞重编程为多能性细胞。自从这项技术诞生以来,人们为改善诱导多能干细胞(iPSCs)技术做出了巨大努力,发展各种方法用于将重编程因子导入体细胞制备诱导多能干细胞(iPSCs)。诱导多能干细胞(iPSCs)技术彻底改变了人类对疾病发病机制的探索和药物开发的进程。本文简述了诱导多能干细胞的来源及诱导策略、近年来iPSCs在疾病建模、药物研发、再生医学等方面的应用,同时探讨了该技术当前存在的问题,并对未来进行了展望。     

ToolBox: Live Imaging of intracellular organelle transport in induced pluripotent stem cell‐derived neurons

Induced pluripotent stem cells (iPSCs) hold promise to revolutionize studies of intracellular transport in live human neurons and to shed new light on the role of dysfunctional transport in neurodegenerative disorders. Here, we describe an approach for live imaging of axonal and dendritic transport in iPSC‐derived cortical neurons. We use transfection and transient expression of genetically‐encoded fluorescent markers to characterize the motility of Rab‐positive vesicles, including early, late and recycling endosomes, as well as autophagosomes and mitochondria in iPSC‐derived neurons. Comparing transport parameters of these organelles with data from primary rat hippocampal neurons, we uncover remarkable similarities. In addition, we generated lysosomal‐associated membrane protein 1 (LAMP1)‐enhanced green fluorescent protein (EGFP) knock‐in iPSCs and show that knock‐in neurons can be used to study the transport of endogenously labeled vesicles, as a parallel approach to the transient overexpression of fluorescently labeled organelle markers.     

Induced Pluripotency for Translational Research

The advent of induced pluripotent stem cells （iPSCs） has revolutionized the concept of cellular reprogramming and potentially will solve the immunological compatibility issues that have so far hindered the application of human pluripotent stem cells in regenerative medicine. Recent findings showed that pluripotency is defined by a state of balanced lineage potency, which can be artificially instated through various procedures, including the conventional Yamanaka strategy. As a type of pluripotent stem cell, iPSCs are subject to the usual concerns over purity of differen- tiated derivatives and risks of tumor formation when used for cell-based therapy, though they pro- vide certain advantages in translational research, especially in the areas of personalized medicine, disease modeling and drug screening, iPSC-based technology, human embryonic stem cells （hESCs） and direct lineage conversion each will play distinct roles in specific aspects of translational medi- cine, and continue yielding surprises for scientists and the public.