Electric pulses to prepare feeder cells for sustaining and culturing of undifferentiated embryonic stem cells

Current challenges in embryonic-stem cell (ESC) research include the inability of sustaining and culturing of undifferentiated ESCs over time. Growth-arrested feeder cells are essential to the culture and sustaining of undifferentiated ESCs, and they are currently prepared using gamma-radiation and chemical inactivation. Both techniques have severe limitations. In this study, we developed a new, simple and effective technique (pulsed electric fields, PEFs) to produce viable growth-arrested cells (RTS34st) and used them as high-quality feeder cells to culture and sustain undifferentiated zebrafish ESCs over time. The cells were exposed to 25 sequential 10-ns electric pulses (10nsEPs) of 25, 40 and 150 kV/cm with 1-s pulse interval, or 2 sequential 50-μs electric pulses (50μsEPs) of 2.83, 1.78 and 0.78 kV/cm with 5-s pulse interval, respectively. We found that the cellular effects of PEFs depended directly upon the duration, number and electric field strength of the pulses, showing the feasibility of tuning them to produce various types of growth-arrested cells for culturing undifferentiated ESCs. Both 10nsEPs of 40 kV/cm produced by a 10nsEP generator and 50μsEPs of 1.78 kV/cm provided by inexpensive and widely available conventional electroporators, generated high-quality growth-arrested feeder cells for proliferation of undifferentiated ESCs over time. PEFs can therefore be used to replace radiation and chemical inactivation methods for preparation of growth-arrested feeder cells for advancing ESC research.     

The art of cobbling a running pump—Will human embryonic stem cells mend broken hearts?

The heart is one of the least regenerative organs in the body, and highly vulnerable to the increasing incidence of cardiovascular diseases in an aging world population. Cell-based approaches aimed at cardiac repair have recently caused great public excitement. But clinical trials of patients’ own skeletal myoblasts or bone marrow cells for transplantation have been disappointing. Human embryonic stem cells (hESCs) form bona fide cardiomyocytes in vitro which are readily generated in mass culture and are being tested in animal models of heart damage. The early results, while encouraging, underscore that much remains to be done. This review focuses on the many challenges that remain before hESCs-mediated repair of the human heart becomes a reality.     

Human Pluripotent Stem Cells Have a Novel Mismatch Repair-dependent Damage Response

Human pluripotent stem cells (PSCs) are presumed to have robust DNA repair pathways to ensure genome stability. PSCs likely need to protect against mutations that would otherwise be propagated throughout all tissues of the developing embryo. How these cells respond to genotoxic stress has only recently begun to be investigated. Although PSCs appear to respond to certain forms of damage more efficiently than somatic cells, some DNA damage response pathways such as the replication stress response may be lacking. Not all DNA repair pathways, including the DNA mismatch repair (MMR) pathway, have been well characterized in PSCs to date. MMR maintains genomic stability by repairing DNA polymerase errors. MMR is also involved in the induction of cell cycle arrest and apoptosis in response to certain exogenous DNA-damaging agents. Here, we examined MMR function in PSCs. We have demonstrated that PSCs contain a robust MMR pathway and are highly sensitive to DNA alkylation damage in an MMR-dependent manner. Interestingly, the nature of this alkylation response differs from that previously reported in somatic cell types. In somatic cells, a permanent G₂/M cell cycle arrest is induced in the second cell cycle after DNA damage. The PSCs, however, directly undergo apoptosis in the first cell cycle. This response reveals that PSCs rely on apoptotic cell death as an important defense to avoid mutation accumulation. Our results also suggest an alternative molecular mechanism by which the MMR pathway can induce a response to DNA damage that may have implications for tumorigenesis.     

The human vocal cord surface

Summary The effect of phenylthiourea (PTU) on the pigment epithelium and the photoreceptor cells in the developing retina of Haplochromis burtoni was studied by electron microscopy. In the retinal pigment epithelium of 6-day old embryos, both types of melanin granule (spindle-shaped and rod-shaped) are already found. PTU inhibits the biosynthesis of melanin but does not influence the formation of premelanosomes so that in PTU-treated embryos there are no melanosomes, but an abundance of premelanosomes. The structure of the premelanosomes is described. It differs completely from that of all other vertebrates. Other changes: an increase in polysomes, retarded development of the inner segment of the photoreceptor cells and enlargement of the intercellular space between the inner and outer leaflet of the retina, may be due to a toxic effect of PTU.This investigation was supported by grants of the Deutsche Forschungsgemeinschaft     

胚胎干细胞源性表皮干细胞在肾被囊微环境中分化潜能的研究

目的 探讨胚胎干细胞源性表皮干细胞在肾被囊微环境中的分化情况,为研究其在不同微环境中的分化潜能和稳定性及寻找新的皮肤工程种子细胞奠定基础。方法129小鼠E14胚胎干细胞与人羊膜共培养4d,定向诱导其分化为呈β1整合素、CK15和CK19阳性的表皮样干细胞克隆,无菌手术下移植入129小鼠双侧肾被囊内,术后4周、6周和8周取材。对移植后细胞的分化情况进行形态学和CEA和CK18免疫组织化学观察。结果小鼠胚胎干细胞源性表皮干细胞在129小鼠肾被囊内4周,分化为由单层或复层上皮样细胞构成的管状和泡状结构,种植6周和8周,除上述结构外,可见角化复层扁平上皮、汗腺样、皮脂腺样及毛囊样等结构。免疫组化结果汗腺样结构呈CEA和CK18阳性。结论研究结果表明小鼠胚胎干细胞源性表皮干细胞在肾被囊微环境下,可具有分化为角化复层上皮、汗腺样、皮脂腺样及毛囊样结构的潜能。     

奥利亚罗非鱼与鳜杂交的受精细胞学及胚胎发育研究

通过对奥利亚罗非鱼(♀)和鳜(♂)杂交的受精细胞学观察发现:异源精子入卵后产生星光,并核化成雄性原核,与雌原核互相靠近,接触最终完全融合为一个合子核,合子核继续分裂。分析比较了奥利亚罗非鱼,鳜以及奥鳜杂种胚胎发育情况,发现杂种胚胎的发育速度在囊胚早期与母本奥利亚罗非鱼基本一致,到囊胚后期速度有所减慢,但与鳜胚胎发育速度相差很大。这表明奥利亚罗非鱼和鳜虽属不同科间的远缘杂交,但有正常的受精细胞学程序和常规的细胞分裂(卵裂)方式。