Hematopoietic progenitors express embryonic stem cell and germ layer genes

Cell therapy for tissue regeneration requires cells with high self-renewal potential and with the capacity to differentiate into multiple differentiated cell lineages, like embryonic stem cells (ESCs) and adult somatic cells induced to pluripotency (iPSCs) by genetic manipulation. Here we report that normal adult mammalian bone marrow contains cells, with the cell surface antigen CD34, that naturally express genes characteristic of ESCs and required to generate iPSCs. In addition, these CD34+ cells spontaneously express, without genetic manipulation, genes characteristic of the three embryonic germ layers: ectoderm, mesoderm and endoderm. In addition to the neural lineage genes we previously reported in these CD34+ cells, we found that they express genes of the mesodermal cardiac muscle lineage and of the endodermal pancreatic lineage as well as intestinal lineage genes. Thus, these normal cells in the adult spontaneously exhibit characteristics of embryonic-like stem cells.     

Aging within the Stem Cell niche

Decreased adult stem cell function is thought to play a primary role in organismal aging. Two recent papers in Cell Stem Cell demonstrate the importance of signaling from the stem cell niche in the aging of Drosophila germline stem cells.     

Committing to a hairy fate: epigenetic regulation of hair follicle stem cells

Chromatin modifications are important for embryonic stem cell (ESC) pluripotency, but their functions in adult stem cells are less clear. In this issue of Cell Stem Cell, Lien et?al. (2011) delineate histone methylation patterns in hair follicle stem cells and show that these marks differ from those of ESCs.     

主要干性基因与衰老相关基因表达水平的相互拮抗关系

目前广泛地利用传统的体细胞衰老理论和方法对成体干细胞衰老进行研究,忽视了成体干细胞特有的自我更新功能和相应的干性基因的作用.干性基因的下调可能是导致间充质干细胞衰老的主要原因.通过查阅相关资料发现主要干性基因与衰老相关基因表达水平的相互拮抗关系,这体现在以下4个方面:a.干细胞衰老伴随着干性基因的下调;b.干性基因表达抑制细胞的衰老;c.干性基因抑制衰老相关基因的表达;d.抑制衰老相关基因促进干性基因的表达.干性基因与衰老相关基因的表达水平存在相互拮抗关系,这为成体干细胞衰老可能源于成体干细胞的干性降低的观点提供了坚实的分子基础.     

Pluripotency takes off without Blimp1

The innate capacity of adult somatic cells has many potential applications in regenerative medicine. In this issue of Cell Stem Cell, Salero et al. (2012) describe an adult retinal stem cell population capable of generating neural and mesenchymal cell lineages.     

Adult neurogenesis: VCAM stems the tide

In this issue of Cell Stem Cell, Kokovay et?al. uncover that VCAM1 expression in neural stem cells regulates adult neurogenesis. Cerebrospinal fluid-borne IL-1β upregulates VCAM1 expression, which in turn regulates the architecture of the stem cell niche, redox homeostasis, and neurogenesis.     

Hope for a broken heart?

Heated debate has surrounded the issue of whether adult stem cells can differentiate into cardiac myocytes and contribute to the function of the heart. In this issue of Cell, demonstrate stem cells in the adult rat heart that differentiate into cardiac myocytes in vitro and, when injected into the adult rat heart, can reconstitute the injured myocardium and improve function. These findings should weigh heavily in future debates about the existence of stem cells in the adult heart and their capacity for functional repair after injury.     

An old drug for new ideas: metformin promotes adult neurogenesis and spatial memory formation

Identifying well-tolerated, oral medications that enhance adult neurogenesis is of great clinical interest. In this issue of Cell Stem Cell, Wang et?al. (2012) demonstrate that the diabetes medication metformin enhances spatial learning in mice by activating the atypical PKC/CBP pathway in adult neural stem cells.     

The pessimist's and optimist's views of adult neurogenesis

The reports by Bonaguidi et?al. (in this issue of Cell) and Encinas et?al. (in Cell Stem Cell) come to differing conclusions about whether and how the proliferation of radial glia-like stem cells of the adult hippocampus impacts their long-term potential for neurogenesis.     

Tracing the life of the kidney tubule- re-establishing dogma and redirecting the options

Renal pathology suggests that tubular repair results from tubular proliferation. In contrast, recent studies propose that postnatal kidney repair may involve renal stem cells. In this issue of Cell Stem Cell, Humphreys et al. (2008) use lineage tracing to genetically assess contribution of adult nontubular cells (potentially stem cells) to repair of damaged renal tubules.     

Home is where the heart is: via the FROUNT

In this issue of Cell Stem Cell, Belema-Bedada et al. (2008) describe a novel mechanism by which bone marrow-derived adult mesenchymal stem cells migrate to sites of damaged heart tissue. This process is dependent on the intracellular adaptor molecule FROUNT, which interacts with the chemokine receptor CCR2.     

Self-renewal in the fly kidney

Tissue stem cells are typically rare and located in niches that prescribe low rates of cell division and survival. In the latest issue of Cell Stem Cell, Singh et al. (2007) demonstrate that, in the adult fly, epithelial cells exist that are neither in niches nor in small numbers, divide at high rates, and are multipotent.     

Kinship and Descent: Redefining the Stem Cell Compartment in the Adult Hippocampus

Identifying multipotent, self-renewing neural stem cells (NSCs) within the adult hippocampus in vivo has been somewhat elusive. In this issue of Cell Stem Cell, Suh et al. (2007) show that Sox2-expressing cells in the subgranular zone (SGZ) of the dentate gyrus not only have NSC characteristics but also display an unexpected degree of heterogeneity.     

Glia-like stem cells sustain physiologic neurogenesis in the adult mammalian carotid body

Neurogenesis is known to occur in the specific niches of the adult mammalian brain, but whether germinal centers exist in the neural-crest-derived peripheral nervous system is unknown. We have discovered stem cells in the adult carotid body (CB), an oxygen-sensing organ of the sympathoadrenal lineage that grows in chronic hypoxemia. Production of new neuron-like CB glomus cells depends on a population of stem cells, which form multipotent and self-renewing colonies in vitro. Cell fate mapping experiments indicate that, unexpectedly, CB stem cells are the glia-like sustentacular cells and can be identified using glial markers. Remarkably, stem cell-derived glomus cells have the same complex chemosensory properties as mature in situ glomus cells. They are highly dopaminergic and produce glial cell line-derived neurotrophic factor. Thus, the mammalian CB is a neurogenic center with a recognizable physiological function in adult life. CB stem cells could be potentially useful for antiparkinsonian cell therapy.     

Genetic modification-free reprogramming to induced pluripotent cells: fantasy or reality?

Significant development in the reprogramming of somatic cells into induced pluripotent stem cells (iPSCs) has been achieved by retroviral infection of defined genes. Several recent reports, including one in this issue of Cell Stem Cell (Marson et al., 2008), have started to replace these genetic changes with specific chemical stimulation.