Altering Fate of Hematopoietic and Neural Stem Cells

改变造血干细胞和神经干细胞的命运

• 批准号: 6580905
• 负责人: Dennis A. Steindler
• 金额: $ 30.38万
• 依托单位: UNIVERSITY OF FLORIDA
• 依托单位国家: 美国
• 财政年份: 2003
• 资助国家: 美国
• 起止时间: 2003-07-01 至 2007-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6580905
• 关键词: blood cells; brain cell; cell differentiation; cell proliferation; flow cytometry; genetically modified animals; green fluorescent proteins; hematopoietic stem cells; hematopoietic tissue transplantation; immunofluorescence technique; laboratory mouse; nerve stem cell; neural plasticity; polymerase chain reaction; stem cell transplantation

DESCRIPTION (provided by applicant): The notion of stem cell plasticity has been recently supported by numerous examples of so-called tissue specific stem calls being coaxed into other tissue phenotypes. Altering fate of tissue-specific stem cells, inducing transdifferentiation, has been reported in many different bioassays, using a variety of cell culture and in vivo conditions and manipulations, without a systematic and direct comparison of different stem cell populations from different tissues in the same study. This proposal sets up a "head-to-head" comparison of transdifferentiation abilities of hematopoietic and neuropoietic stem cells in three sets of experiments that will establish the ability to alter the fate of hematopoietic and neuropoietic stem cells In vitro, embryonic and adult mouse in vivo studies will test hypotheses related to epigenetic factors that control the choice of fate as well as terminal differentiation of stem cells isolated from hematopoietic and neuropoietic structures Their ability to transdifferentiate, both in vitro and in vivo, will be evaluated using sensitive phenotypic and functional analyses, to confirm their full conversion and integration into their new host environments Specific Aim 1 will determine whether a candidate stem cell from the postnatal and adult mouse brain in fact exhibits true stem cell behaviors, looking at established attributes of hematopoietic stem cells including self-renewal and long-term clonal, multilineage reconstitution. This starting population will be sorted and enriched using specific surface antigens in order to determine the affects of culturing on developmental potential. Specific Aim 2 will look at the ability of hematopoietic stem cells to respond to neural cues in vitro and in vivo, by contributing functional cells that integrate within the developing, and repopulating adult nervous system Finally, Aim 3 will test the hypothesis that neural stem cells are plastic enough to respond to hematopoietic cues, following their transplantation into embryoid bodies, fetal mice, and radiation-ablated bone marrow The "head-to-head" assay systems to be used here will determine the potential usefulness of transdifferentiation approaches for establishing new cell therapeutics for many different human diseases, including cell loss as well as hyperplasia in a variety of blood and brain disorders Before we can understand the potential of blood ceils to become brain cells, a profound example of transdifferentiation that offers numerous alternative approaches to current cell replacement therapies, it is necessary to establish sternness of starting cell populations, and also understand factors involved in blood/brain stem cell proliferation, commitment to fate, and differentiation.

描述（由申请人提供）：干细胞可塑性的概念最近得到了所谓的组织特异性干细胞被诱导到其他组织表型的许多例子的支持。改变组织特异性干细胞的命运，诱导转分化，已经在许多不同的生物测定中报道，使用各种细胞培养和体内条件和操作，而没有在同一研究中对来自不同组织的不同干细胞群体进行系统和直接的比较。该提议在三组实验中建立了造血干细胞和神经干细胞转分化能力的“头对头”比较，这些实验将建立改变造血干细胞和神经干细胞命运的能力。胚胎和成年小鼠体内研究将测试与控制从小鼠中分离的干细胞的命运选择以及终末分化的表观遗传因素有关的假设。造血和神经生成结构它们在体外和体内转分化的能力将使用灵敏的表型和功能分析来评估，以确认它们完全转化和整合到它们的新宿主环境中。特异性目的1将确定来自出生后和成年小鼠脑的候选干细胞是否实际上表现出真正的干细胞行为，研究造血干细胞的既定属性，包括自我更新和长期克隆、多谱系重建。将使用特异性表面抗原对该起始群体进行分选和富集，以确定培养对发育潜力的影响。具体目标2将着眼于造血干细胞在体外和体内对神经线索作出反应的能力，通过贡献功能细胞整合到发育中，并重新填充成人神经系统。最后，目标3将检验神经干细胞在移植到胚状体、胎鼠、和辐射消融的骨髓这里使用的“头对头”测定系统将确定转分化方法用于建立用于许多不同人类疾病的新细胞疗法的潜在有用性，包括各种血液和脑疾病中的细胞损失以及增生。在我们能够理解血细胞成为脑细胞的潜力之前，转分化的一个深刻的例子，为目前的细胞替代疗法提供了许多替代方法，有必要建立起始细胞群的干细胞性，并了解血液/脑干细胞增殖，命运承诺和分化中涉及的因素。