Efficient differentiation of mouse embryonic stem cells into motor neurons

Direct differentiation of embryonic stem (ES) cells into functional motor neurons represents a promising resource to study disease mechanisms, to screen new drug compounds, and to develop new therapies for motor neuron diseases such as spinal muscular atrophy (SMA) and amyotrophic lateral sclerosis (ALS). Many current protocols use a combination of retinoic acid (RA) and sonic hedgehog (Shh) to differentiate mouse embryonic stem (mES) cells into motor neurons. However, the differentiation efficiency of mES cells into motor neurons has only met with moderate success. We have developed a two-step differentiation protocol that significantly improves the differentiation efficiency compared with currently established protocols. The first step is to enhance the neuralization process by adding Noggin and fibroblast growth factors (FGFs). Noggin is a bone morphogenetic protein (BMP) antagonist and is implicated in neural induction according to the default model of neurogenesis and results in the formation of anterior neural patterning. FGF signaling acts synergistically with Noggin in inducing neural tissue formation by promoting a posterior neural identity. In this step, mES cells were primed with Noggin, bFGF, and FGF-8 for two days to promote differentiation towards neural lineages. The second step is to induce motor neuron specification. Noggin/FGFs exposed mES cells were incubated with RA and a Shh agonist, Smoothened agonist (SAG), for another 5 days to facilitate motor neuron generation. To monitor the differentiation of mESs into motor neurons, we used an ES cell line derived from a transgenic mouse expressing eGFP under the control of the motor neuron specific promoter Hb9. Using this robust protocol, we achieved 51 ± 0.8% of differentiation efficiency (n = 3; p < 0.01, Student's t-test). Results from immunofluorescent staining showed that GFP+ cells express the motor neuron specific markers, Islet-1 and choline acetyltransferase (ChAT). Our two-step differentiation protocol provides an efficient way to differentiate mES cells into spinal motor neurons.     

小鼠孤雌胚胎干细胞的建立及其向运动神经元分化的初探

文章采用小鼠的孤雌囊胚建立胚胎干细胞系,探究其向运动神经元分化的可能,为临床治疗以及研究基因组印记与神经分化的的关系提供理论基础。结果表明:卵母细胞孤雌激活率达到93.26%,成功建立了8个孤雌胚胎干细胞系,建系率达到23.53%。克隆表达多潜能标记Oct4及细胞表面标记SSEA-1,有高水平的碱性磷酸酶活性,在细胞第10代和第30代时核型分析检测显示为正常的40条染色体。体内、外均分化出三胚层来源的细胞。联合应用全反式维甲酸(RA)、音猬因子(Shh)及细胞外基质,小鼠孤雌胚胎干细胞可被诱导表达运动神经元的标志性标记HB9、Olig2。     

Ginsenoside Rg1 facilitates neural differentiation of mouse embryonic stem cells via GR-dependent signaling pathway

Ginsenoside Rg1, a steroidal saponin of high abundance in ginseng, possesses the neuroprotective effects. In this study, we tried to explore the effect of Rg1 on promoting differentiation of mouse embryonic stem (ES) cells towards the neuronal lineage and its potential role involved in glucocorticoid receptor (GR) activation. Rg1 treatment induced a remarkable increase in the population of neuron-like cells in a time-dependent manner. More than 80% of Rg1-treated embryoid bodies (EBs) differentiated into neuron-like cells on d 8 + 10. Furthermore, the gradually increased protein expression of neurofilament (NEFM) and β-tubulin III (a neuronal specific protein) was determined. GR expression gradually increased during the differentiation course. RU486, an antagonist of GR, could efficiently block the neurogenesis-promoting activity of Rg1. On the other side, Rg1 stimulated the phosphorylation of ERK1/2 and Akt at different time points through GR activation-dependent mechanisms. Treatment of both U0126 (an inhibitor of MEK) and LY294002 (an inhibitor of PI3 K), hampered the neuronal differentiation induced by Rg1. Meantime, U0126 further decreased Rg1-induced p-Akt expression. In conclusion, Rg1 possesses the effects on inducing differentiation of mouse ES cells into neurons in vitro via the GR-MEK-ERK1/2-PI3 K-Akt signaling pathway.     

Vitronectin promotes oligodendrocyte differentiation during neurogenesis of human embryonic stem cells

We demonstrate enhanced differentiation of oligodendrocytes during neurogenesis of human embryonic stem cells (hESCs) using an extracellular matrix protein, vitronectin (VN). We show that VN is expressed in the ventral part of the developing human spinal cord. Combined treatment of retinoic acid, sonic hedgehog, and noggin in the presence of VN allows hESCs to differentiate into O4-positive oligodendrocytes. Particularly, VN profoundly promotes the derivation of oligodendrocyte progenitors that proliferate and differentiate into oligodendrocytes in response to mitogenic and survival factors. These results support the beneficial effect of VN on oligodendrocytic differentiation of hESCs.     

Glial precursor cell transplantation therapy for neurotrauma and multiple sclerosis

Traumatic injury to the brain or spinal cord and multiple sclerosis (MS) share a common pathophysiology with regard to axonal demyelination. Despite advances in central nervous system (CNS) repair in experimental animal models, adequate functional recovery has yet to be achieved in patients in response to any of the current strategies. Functional recovery is dependent, in large part, upon remyelination of spared or regenerating axons. The mammalian CNS maintains an endogenous reservoir of glial precursor cells (GPCs), capable of generating new oligodendrocytes and astrocytes. These GPCs are upregulated following traumatic or demyelinating lesions, followed by their differentiation into oligodendrocytes. However, this innate response does not adequately promote remyelination. As a result, researchers have been focusing their efforts on harvesting, culturing, characterizing, and transplanting GPCs into injured regions of the adult mammalian CNS in a variety of animal models of CNS trauma or demyelinating disease. The technical and logistic considerations for transplanting GPCs are extensive and crucial for optimizing and maintaining cell survival before and after transplantation, promoting myelination, and tracking the fate of transplanted cells. This is especially true in trials of GPC transplantation in combination with other strategies such as neutralization of inhibitors to axonal regeneration or remyelination. Overall, such studies improve our understanding and approach to developing clinically relevant therapies for axonal remyelination following traumatic brain injury (TBI) or spinal cord injury (SCI) and demyelinating diseases such as MS.