A Special Issue on Stem Cell Research

Stem cells possess the remarkable ability of extensive self-renewal and differentiation into specific celllineages,and they play essential roles in development and adult tissue homeostasis.Due to their criticalimportance in normal physiology and the promise for use in regenerative medicine to treat a variety ofdiseases,stem cells have attracted extensive research interest in recent years.As China's premium in-ternational journal with a broad scope in cell and molecular biology,Cell Research has witnessed moreand more submissions on stem cell research.Indeed,along with the traditional strengths of the journal inmolecular immunology,cancer biology,and plant molecular physiology,stem cell research has graduallyand naturally evolved into a new growth point of Cell Research.Reflecting the growing interest of bothour readers and authors in this exciting and expanding field,we are pleased to present this Special Issueon Stem Cell Research.     

p53 in stem cells

p53 is well known as a "guardian of the genome" for differentiated cells,in which it induces cell cycle arrest and cell death after DNA damage and thus contributes to the maintenance of genomic stability.In addition to this tumor suppressor function for differentiated cells,p53 also plays an important role in stem cells.In this cell type,p53 not only ensures genomic integrity after genotoxic insults but also controls their proliferation and differentiation.Additionally,p53 provides an effective barrier for the generation of pluripotent stem celllike cells from terminally differentiated cells.In this review,we summarize our current knowledge about p53 activities in embryonic,adult and induced pluripotent stem cells.     

No Intestinal Stem Cell Regeneration after Complete Progenitor Ablation in Drosophila Adult Midgut

<正>Adult stem cells or progenitors are essential for maintaining the normal structure and function of adult tissues(i.e.,homeostasis).One of the best examples is the adult intestinal epithelium which is constantly renewed by the progeny of intestinal stem cells(ISCs).The proliferation and differentiation of adult stem cells must be tightly controlled in order to maintain resident tissue homeostasis.Mis-regulation of stem     

Reconstitution of Gametogenesis In Vitro:Meiosis Is the Biggest Obstacle

Germ-line cells are responsible for transmitting genetic and epigenetic information across generations, and ensuring the creation of new individuals from one generation to the next. Gametogenesis process requires several rigorous steps, including primordial germ cell （PGC） specification, proliferation, migration to the gonadal ridges and differentiation into mature gametes such as sperms and oocytes. But this process is not clearly explored because a small number of PGCs are deeply embedded in the developing embryo. In the attempt to establish an in vitro model for understanding gametogenesis process well, several groups have made considerable progress in differen- tiating embryonic stem cells （ESCs） and adult stem cells （ASCs） into germ-like cells over the past ten years. These stem cell-derived germ cells appear to he capable of undergoing meiosis and generating both male and female gametes. But most of gametes turn out to be not fully functional due to their abnormal meiosis process compared to endogenous germ cells. Therefore, a robust system of differentiating stem cells into germ cells would enable us to investigate the genetic, epigenetic and environmental factors associated with germ cell development. Here, we review the stem cell-derived germ cell development, and discuss the potential and challenges in the differentiation of functional germ cells from stem cells.     

Niche regulation of corneal epithelial stem cells at the limbus

Among all adult somatic stem cells,those of the corneal epithelium are unique in their exclusive location in a definedlimbai structure termed Palisades of Vogt.As a result,surgical engraftment oflimbal epithelial stem cells with or withoutex vivo expansion has long been practiced to restore sights in patients inflicted with limbal stem cell deficiency.Neverthe-less,compared to other stem cell examples,relatively little is known about the limbal niche,which is believed to play apivotal role in regulating self-renewal and fate decision of limbal epithelial stem cells.This review summarizes relevantliterature and formulates several key questions to guide future research into better understanding of the pathogenesis oflimbal stem cell deficiency and further improvement of the tissue engineering of the corneal epithelium by focusing onthe limbal niche.     

Stem cells for spine surgery

In the past few years, stem cells have become the focus of research by regenerative medicine professionals and tissue engineers. Embryonic stem cells, although capable of differentiating into cell lineages of all three germ layers, are limited in their utilization due to ethical issues. In contrast, the autologous harvest and subsequent transplantation of adult stem cells from bone marrow, adipose tissue or blood have been experimentally utilized in the treatment of a wide variety of diseases ranging from myocardial infarction to Alzheimer’s disease. The physiologic consequences of stem cell transplantation and its impact on functional recovery have been studied in countless animal models and select clinical trials. Unfortunately, the bench to bedside translation of this research has been slow. Nonetheless, stem cell therapy has received the attention of spinal surgeons due to its potential benefits in the treatment of neural damage, muscle trauma, disk degeneration and its potential contribution to bone fusion.     

Adult stem cells in neural repair: Current options,limitations and perspectives

Stem cells represent a promising step for the future of regenerative medicine. As they are able to differentiate into any cell type, tissue or organ, these cells are great candidates for treatments against the worst diseasesthat defy doctors and researchers around the world. Stem cells can be divided into three main groups:(1) embryonic stem cells;(2) fetal stem cells; and(3) adult stem cells. In terms of their capacity for proliferation, stem cells are also classified as totipotent, pluripotent or multipotent. Adult stem cells, also known as somatic cells, are found in various regions of the adult organism, such as bone marrow, skin, eyes, viscera and brain. They can differentiate into unipotent cells of the residing tissue, generally for the purpose of repair. These cells represent an excellent choice in regenerative medicine, every patient can be a donor of adult stem cells to provide a more customized and efficient therapy against various diseases, in other words, they allow the opportunity of autologous transplantation. But in order to start clinical trials and achieve great results, we need to understand how these cells interact with the host tissue, how they can manipulate or be manipulated by the microenvironment where they will be transplanted and for how long they can maintain their multipotent state to provide a full regeneration.     

Microgravity may help future organ/tissue manufacture

正Stem cells are a group of multipotent or pluripotent cells which could differentiate into specialized cells or could self-renew to duplicate themselves.During the body developing period,stem cells differentiated into specialized cells to build the whole body.In the adult organisms,stem cells live in seclusion and are ready to repair the injuries of tis-     

ABC transporters, neural stem cells and neurogenesis--a different perspective

Stem cells intrigue. They have the ability to divide exponentially, recreate the stem cell compartment, as well as create differentiated cells to generate tissues. Therefore, they should be natural candidates to provide a renewable source of cells for transplantation applied in regenerative medicine. Stem cells have the capacity to generate specific tissues or even whole organs like the blood, heart, or bones. A subgroup of stem cells, the neural stem cells （NSCs）, is characterized as a self-renewing population that generates neurons and glia of the developing brain. They can be isolated, genetically manipulated and differentiated in vitro and reintroduced into a developing, adult or a pathologically altered central nervous system. NSCs have been considered for use in cell replacement therapies in various neurodegenerative diseases such as Parkinson＇s disease and Alzheimer＇s disease. Characterization of genes with tightly controlled expression patterns during differentiation represents an approach to understanding the regulation of stem cell commitment. The regulation of stem cell biology by the ATP-binding cassette （ABC） transporters has emerged as an important new field of investigation. As a major focus of stem cell research is in the manipulation of cells to enable differentiation into a targeted cell population; in this review, we discuss recent literatures on ABC transporters and stem cells, and propose an integrated view on the role of the ABC transporters, especially ABCA2, ABCA3, ABCB 1 and ABCG2, in NSCs＇ proliferation, differentiation and regulation, along with comparisons to that in hematopoietic and other stem cells.     

Progenitor cells as remote "bioreactors": neuroprotection via modulation of the systemic inflammatory response

Acute central nervous system(CNS)injuries such as spinal cord injury,traumatic brain injury,autoimmune encephalomyelitis,and ischemic stroke are associ- ated with significant morbidity,mortality,and health care costs worldwide.Preliminary research has shown potential neuroprotection associated with adult tissue derived stem/progenitor cell based therapies.While initial research indicated that engraftment and transdif- ferentiation into neural cells could explain the observed benefit,the exact mechanism remains controversial.A second hypothesis details localized stem/progenitor cell engraftment with alteration of the loco-regional milieu;however,the limited rate of cell engraftment makes this theory less likely.There is a growing amount of pre-clinical data supporting the idea that,after intravenous injection,stem/progenitor cells interact with immuno- logic cells located in organ systems distant to the CNS,thereby altering the systemic immunologic/inflammatory response.Such distant cell"bioreactors"could modulate the observed post-injury pro-inflammatory environment and lead to neuroprotection.In this review,we discuss the current literature detailing the above mechanisms of action for adult stem/progenitor cell based therapies in the CNS.     

Endothelial progenitor cells in debate

Adult stem/progenitor cells play important roles in tissue homeostasis and have important implications for regenerative medicine. It was once thought that formation of new blood vessels in adult only occurs through angiogenesis, a process whereby new vessels are formed from existing mature endothelial cells; while vasculogenesis, where new vessels are derived from differentiation of endothelial progenitor cells （EPCs）, was thought to occur exclusively in embryos. The discovery of adult EPCs a few years ago has changed this old paradigm; and subsequent studies showed that EPCs may be a promising tool for the treatment of vascular disorders. However, there have been conflicting reports on subtypes, surface markers, and functions of EPCs; and thus the exact origin and identity of EPCs remain to be defined. A common approach to obtain EPCs is to isolate and culture mononuclear cells from peripheral blood and to select adherent cells for further analyses. In the June issue of Cell Research, Zhang et al. attempted to isolate putative ＂EPCs＂ using this approach,     

Conversion of female germline stem cells from neonatal and prepubertal mice into pluripotent stern cells

Pluripotent stem cells derived from neonatal or adult testes are a useful tool to examine the mechanisms of pluripotency and a resource for cell-based therapies. However, therapies usingthese cells will only benefit males but not females. Recently, female germline stem cells （FGSCs） were discovered in ovaries. Whether FGSCs can be converted into pluripotent stem cells, similar to spermatogonial stem cells, is unknown. Here, we demonstrate that female embryonic stem-like cells （fESLCs） can be generated within 1 month from the stably proliferating FGSCs cultured in embryonic stem cell （ESC） medium, fESLCs exhibit properties similar to those of ESCs in terms of marker expression and differentiation potential. Thus, our findings suggest that generation of patient-specific fESLCs is feasible and provides a foundation for personalized regenerative applications.     

Regulation of hematopoiesis and the hematopoietic stem cell niche by Wnt signaling pathways

Hematopoietic stem cells （HSCs） are a rare population of cells that are responsible for life-long generation of blood cells of all lineages. In order to maintain their numbers, HSCs must establish a balance between the opposing cell fates of self-renewal （in which the ability to function as HSCs is retained） and initiation of hematopoietic differentiation. Multiple signaling pathways have been implicated in the regulation of HSC cell fate. One such set of pathways are those activated by the Wnt family of ligands. Wnt signaling pathways play a crucial role during embryogenesis and deregulation of these pathways has been implicated in the formation of solid tumors. Wnt signaling also plays a role in the regulation of stem cells from multiple tissues, such as embryonic, epidermal, and intestinal stem cells. However, the function of Wnt signaling in HSC biology is still controversial. In this review, we will discuss the basic characteristics of the adult HSC and its regulatory microenvironment, the ＂niche＂, focusing on the regulation of the HSC and its niche by the Wnt signaling pathways.     

Human adult pluripotency: Facts and questions

Cellular reprogramming and induced pluripotent stem cell(IPSC) technology demonstrated the plasticity of adult cell fate, opening a new era of cellular modelling and introducing a versatile therapeutic tool for regenerative medicine.While IPSCs are already involved in clinical trials for various regenerative purposes, critical questions concerning their medium-and long-term genetic and epigenetic stability still need to be answered. Pluripotent stem cells have been described in the last decades in various mammalian and human tissues(such as bone marrow, blood and adipose tissue). We briefly describe the characteristics of human-derived adult stem cells displaying in vitro and/or in vivo pluripotency while highlighting that the common denominators of their isolation or occurrence within tissue are represented by extreme cellular stress. Spontaneous cellular reprogramming as a survival mechanism favoured by senescence and cellular scarcity could represent an adaptative mechanism. Reprogrammed cells could initiate tissue regeneration or tumour formation dependent on the microenvironment characteristics. Systems biology approaches and lineage tracing within living tissues can be used to clarify the origin of adult pluripotent stem cells and their significance for regeneration and disease.     

Murine fertilized ovum, blastomere and morula cells lacking SP phenotype

In the field of stem cell research, SP (side population) phenotype is used to define the property that cells maintain a high efflux capability for some fluorescent dye, such as Hoechst 33342. Recently, many researches proposed that SP phenotype is a phenotype shared by some stem cells and some pro- genitor cells, and that SP phenotype is regarded as a candidate purification marker for stem cells. In this research, murine fertilized ova (including conjugate and single nucleus fertilized ova), 2-cell stage and 8-cell stage blastomeres, morulas and blastocysts were isolated and directly stained by Hoechst 33342 dye. The results show that fertilized ovum, blastomere and morula cells do not demonstrate any ability to efflux the dye. However, the inner cell mass (ICM) cells of blastocyst exhibit SP phenotype, which is consistent with the result of embryonic stem cells (ESCs) in vitro. These results indicate that the SP phenotype of ICM-derived ESCs is an intrinsic property and independent of the culture condition in vitro, and that SP phenotype is one of the characteristics of at least some pluripotent stem cells, but is not shared by totipotent stem cells. In addition, the result that the SP phenotype of ICM cells disap- peared when the inhibitor verapamil was added into medium implies that the SP phenotype is directly associated with ABCG2. These results suggest that not all the stem cells demonstrate SP phenotype, and that SP phenotype might act as a purification marker for partial stem cells such as some pluripo- tent embryonic stem cells and multipotent adult stem cells, but not for all stem cells exampled by the totipotent stem cells in the very early stage of mouse embryos.     

Neural stem cells could serve as a therapeutic material for age-related neurodegenerative diseases

Progressively loss of neural and glial cells is the key event that leads to nervous system dysfunctions and diseases. Several neurodegenerative diseases, for instance Alzheimer’s disease, Parkinson’s disease, and Huntington’s disease, are associated to aging and suggested to be a consequence of deficiency of neural stem cell pool in the affected brain regions. Endogenous neural stem cells exist throughout life and are found inspecific niches of human brain. These neural stem cells are responsible for the regeneration of new neurons to restore, in the normal circumstance, the functions of the brain. Endogenous neural stem cells can be isolated, propagated, and, notably, differentiated to most cell types of the brain. On the other hand, other types of stem cells, such as mesenchymal stem cells, embryonic stem cells, and induced pluripotent stem cells can also serve as a source for neural stem cell production, that hold a great promise for regeneration of the brain. The replacement of neural stem cells, either endogenous or stem cell-derived neural stem cells, into impaired brain is highly expected as a possible therapeutic mean for neurodegenerative diseases. In this review, clinical features and current routinely treatments of agerelated neurodegenerative diseases are documented. Noteworthy, we presented the promising evidence of neural stem cells and their derivatives in curing such diseases, together with the remaining challenges to achieve the best outcome for patients.     

Recent advances in bone regeneration using adult stem cells

Bone is a highly vascularized tissue reliant on the close spatial and temporal association between bloodvessels and bone cells. Therefore, cells that participate in vasculogenesis and osteogenesis play a pivotal role in bone formation during prenatal and postnatal periods. Nevertheless, spontaneous healing of bone fracture is occasionally impaired due to insufficient blood and cellular supply to the site of injury. In these cases, bone regeneration process is interrupted, which might result in delayed union or even nonunion of the fracture. Nonunion fracture is difficult to treat and have a high financial impact. In the last decade, numerous technological advancements in bone tissue engineering and cell-therapy opened new horizon in the field of bone regeneration. This review starts with presentation of the biological processes involved in bone development, bone remodeling, fracture healing process and the microenvironment at bone healing sites. Then, we discuss the rationale for using adult stem cells and listed the characteristics of the available cells for bone regeneration. The mechanism of action and epigenetic regulations for osteogenic differentiation are also described. Finally, we review the literature for translational and clinical trials that investigated the use of adult stem cells(mesenchymal stem cells, endothelial progenitor cells and CD34+ blood progenitors) for bone regeneration.     

The Drosophila ovary: an active stem cell community

Only a small number of cells in adult tissues (the stem cells) possess the ability to self-renew at every cell division,while producing differentiating daughter cells to maintain tissue homeostasis for an organism's lifetime.The Drosophilaovary harbors three different types of stem cell populations (germline stem cell (GSC),somatic stem cell (SSC) andescort stem cell (ESC)) located in a simple anatomical structure known as germarium,rendering it one of the best modelsystems for studying stem cell biology due to reliable stem cell identification and available sophisticated genetic toolsfor manipulating gene functions.Particularly,the niche for the GSC is among the first and best studied ones,and studieson the GSC and its niche have made many unique contributions to a better understanding of relationships between stemcells and their niche.So far,both the GSC and the SSC have been shown to be regulated by extrinsic factors originatingfrom their niche and intrinsic factors functioning within.Multiple signaling pathways are required for controlling GSCand SSC self-renewal and differentiation,which provide unique opportunities to investigate how multiple signals fromthe niche are interpreted in the stem cell.Since the Drosophila ovary contains three types of stem cells,it also providesoutstanding opportunities to study how multiple stem cells in a given tissue work collaboratively to contribute to tissuefunction and maintenance.This review highlights recent major advances in studying Drosophila ovarian stem cells andalso discusses future directions and challenges.