Clonal expansion of adult rat hepatic stem cell lines by suppression of asymmetric cell kinetics (SACK)

Adult stem cells have potential use for several biomedical applications, including cell replacement therapy, gene therapy, and tissue engineering. However, such applications have been limited due to difficulties encountered in expanding functional adult stem cells. We have developed a new approach to the problem of adult stem cell expansion based on the suppression of asymmetric cell kinetics (SACK). We postulated that asymmetric cell kinetics, required for adult stem cell function, were a major barrier to their expansion in culture. As such, conversion of adult stem cells from asymmetric cell kinetics to symmetric cell kinetics would promote their exponential expansion and longterm propagation in culture. The purine nucleoside xanthosine (Xs), which promotes guanine ribonucleotide biosynthesis, can be used to reversibly convert cells from asymmetric cell kinetics to symmetric cell kinetics. We used Xs supplementation to derive clonal epithelial cell lines from adult rat liver that have properties of adult hepatic stem cells. The properties of two Xs-derived cell lines, Lig-8 and Lig-13, are described in detail and compared to properties of adult rat hepatic cell lines derived without Xs supplementation. The Xs-derived cell lines exhibit Xs-dependent asymmetric cell kinetics and Xs-dependent expression of mature hepatic differentiation markers. Interestingly, Lig-8 cells produce progeny with properties consistent with hepatocyte differentiation, while Lig-13 progeny cells have properties consistent with bile duct epithelium differentiation. A stable adult cholangiocyte stem cell line has not been previously described. Consistent with the principles of their derivation, the SACK-derived hepatic cell lines exhibit neither senescence nor tumorigenic properties, and their differentiation properties are stable after longterm culture. These characteristics of SACK-derived stem cell lines underscore asymmetric cell kinetics as an essential adult stem cell property with potential to be the basis for a general approach to expansion and propagation of diverse adult stem cells.     

Potential of embryonic and adult stem cells in vitro

Recent developments in the field of stem cell research indicate their enormous potential as a source of tissue for regenerative therapies. The success of such applications will depend on the precise properties and potentials of stem cells isolated either from embryonic, fetal or adult tissues. Embryonic stem cells established from the inner cell mass of early mouse embryos are characterized by nearly unlimited proliferation, and the capacity to differentiate into derivatives of essentially all lineages. The recent isolation and culture of human embryonic stem cell lines presents new opportunities for reconstructive medicine. However, important problems remain; first, the derivation of human embryonic stem cells from in vitro fertilized blastocysts creates ethical problems, and second, the current techniques for the directed differentiation into somatic cell populations yield impure products with tumorigenic potential. Recent studies have also suggested an unexpectedly wide developmental potential of adult tissue-specific stem cells. Here too, many questions remain concerning the nature and status of adult stem cells both in vivo and in vitro and their proliferation and differentiation/transdifferentiation capacity. This review focuses on those issues of embryonic and adult stem cell biology most relevant to their in vitro propagation and differentiation. Questions and problems related to the use of human embryonic and adult stem cells in tissue regeneration and transplantation are discussed.     

Increased Lysis of Stem Cells but Not Their Differentiated Cells by Natural Killer Cells; De-Differentiation or Reprogramming Activates NK Cells

The aims of this study are to demonstrate the increased lysis of stem cells but not their differentiated counterparts by the NK cells and to determine whether disturbance in cell differentiation is a cause for increased sensitivity to NK cell mediated cytotoxicity. Increased cytotoxicity and augmented secretion of IFN-γ were both observed when PBMCs or NK cells were co-incubated with primary UCLA oral squamous carcinoma stem cells (UCLA-OSCSCs) when compared to differentiated UCLA oral squamous carcinoma cells (UCLA-OSCCs). In addition, human embryonic stem cells (hESCs) were also lysed greatly by the NK cells. Moreover, NK cells were found to lyse human Mesenchymal Stem Cells (hMSCs), human dental pulp stem cells (hDPSCs) and human induced pluripotent stem cells (hiPSCs) significantly more than their differentiated counterparts or parental lines from which they were derived. It was also found that inhibition of differentiation or reversion of cells to a less-differentiated phenotype by blocking NFκB or targeted knock down of COX2 in monocytes significantly augmented NK cell cytotoxicity and secretion of IFN-γ. Taken together, these results suggest that stem cells are significant targets of the NK cell cytotoxicity. However, to support differentiation of a subset of tumor or healthy untransformed primary stem cells, NK cells may be required to lyse a number of stem cells and/or those which are either defective or incapable of full differentiation in order to lose their cytotoxic function and gain the ability to secrete cytokines (split anergy). Therefore, patients with cancer may benefit from repeated allogeneic NK cell transplantation for specific elimination of cancer stem cells.     

Isolation, characterization, and mesodermic differentiation of stem cells from adipose tissue of camel (Camelus dromedarius)

Adipose-derived stem cells are an attractive alternative as a source of stem cells that can easily be extracted from adipose tissue. Isolation, characterization, and multi-lineage differentiation of adipose-derived stem cells have been described for human and a number of other species. Here we aimed to isolate and characterize camel adipose-derived stromal cell frequency and growth characteristics and assess their adipogenic, osteogenic, and chondrogenic differentiation potential. Samples were obtained from five adult dromedary camels. Fat from abdominal deposits were obtained from each camel and adipose-derived stem cells were isolated by enzymatic digestion as previously reported elsewhere for adipose tissue. Cultures were kept until confluency and subsequently were subjected to differentiation protocols to evaluate adipogenic, osteogenic, and chondrogenic potential. The morphology of resultant camel adipose-derived stem cells appeared to be spindle-shaped fibroblastic morphology, and these cells retained their biological properties during in vitro expansion with no sign of abnormality in karyotype. Under inductive conditions, primary adipose-derived stem cells maintained their lineage differentiation potential into adipogenic, osteogenic, and chondrogenic lineages during subsequent passages. Our observation showed that like human lipoaspirate, camel adipose tissue also contain multi-potent cells and may represent an important stem cell source both for veterinary cell therapy and preclinical studies as well.     

Fibroblast growth factor signaling in embryonic and cancer stem cells

Cancer stem cells are cancer cells that originate from the transformation of normal stem cells. The most important property of any stem cell is the ability to self-renew. Through this property, there are striking parallels between normal stem cells and cancer stem cells. Both cell types share various markers of “stemness”. In particular, normal stem cells and cancer stem cells utilize similar molecular mechanisms to drive self-renewal, and similar signaling pathways may induce their differentiation.The fibroblast growth factor 2 (FGF-2) pathway is one of the most significant regulators of human embryonic stem cell (hESC) self-renewal and cancer cell tumorigenesis. Here we summarize recent data on the effects of FGF-2 and its receptors on hESCs and leukemic stem/progenitor cells. Also, we discuss the similarities of these findings with stem cell renewal and differentiation phenotypes.     

Efficient generation of iPS cells from skeletal muscle stem cells

Reprogramming of somatic cells into inducible pluripotent stem cells generally occurs at low efficiency, although what limits reprogramming of particular cell types is poorly understood. Recent data suggest that the differentiation status of the cell targeted for reprogramming may influence its susceptibility to reprogramming as well as the differentiation potential of the induced pluripotent stem (iPS) cells that are derived from it. To assess directly the influence of lineage commitment on iPS cell derivation and differentiation, we evaluated reprogramming in adult stem cell and mature cell populations residing in skeletal muscle. Our data using clonal assays and a second-generation inducible reprogramming system indicate that stem cells found in mouse muscle, including resident satellite cells and mesenchymal progenitors, reprogram with significantly greater efficiency than their more differentiated daughters (myoblasts and fibroblasts). However, in contrast to previous reports, we find no evidence of biased differentiation potential among iPS cells derived from myogenically committed cells. These data support the notion that adult stem cells reprogram more efficiently than terminally differentiated cells, and argue against the suggestion that "epigenetic memory" significantly influences the differentiation potential of iPS cells derived from distinct somatic cell lineages in skeletal muscle.     

Nanomaterials modulate stem cell differentiation: biological interaction and underlying mechanisms

Stem cells are unspecialized cells that have the potential for self-renewal and differentiation into more specialized cell types. The chemical and physical properties of surrounding microenvironment contribute to the growth and differentiation of stem cells and consequently play crucial roles in the regulation of stem cells’ fate. Nanomaterials hold great promise in biological and biomedical fields owing to their unique properties, such as controllable particle size, facile synthesis, large surface-to-volume ratio, tunable surface chemistry, and biocompatibility. Over the recent years, accumulating evidence has shown that nanomaterials can facilitate stem cell proliferation and differentiation, and great effort is undertaken to explore their possible modulating manners and mechanisms on stem cell differentiation. In present review, we summarize recent progress in the regulating potential of various nanomaterials on stem cell differentiation and discuss the possible cell uptake, biological interaction and underlying mechanisms.     

Restrictins: stromal cell associated factors that control cell organization in hemopoietic tissues

Hemopoiesis is a sequence of events initiated by the self-renewal of pluripotent stem cells followed by a series of differentiation steps and completed in the formation of distinct tissue patterns. Differentiation and self-renewal are antagonistic processes. A mechanism that attenuates the differentiation flow is obligatory to prevent the exhaustion of the stem cell pool. We suggest that stromal cells from the bone marrow control stem cell renewal through a mechanism that does not require colony-stimulating factors. The organization of cells within the tissue and their specific localization is suggested to be directed by stromal cell activities other than differentiation inducers. These stromal cell activities restrict differentiation or accumulation of mature cells. They are therefore designated as 'Restrictins'.     

Spermatogenetic clones developing from repopulating stem cells surviving a high dose of an alkylating agent.

We investigated stem cell renewal and differentiation in 10- and 15-days-old spermatogonial clones developing in mouse seminiferous epithelium after an extremely large cell loss, inflicted by high doses of the alkylating agent Myleran. The spermatogonial clones arise from cells that resemble the Ais spermatogonia but have a larger nuclear diameter. In spite of their mitotic activity these 'repopulating stem cells' lie mainly isolated or in pairs. This explained by migration and differentiation. Migration appeared to occur at random in all directions along the basement membrane of the seminiferous tubule. After one or more divisions of the stem cells, a second type of cell appears, which is called the 'differentiating spermatogomium'. The time elapsing before this type of cell appears, depends on the dose of Myleran: the larger the dose the later differentiation starts. A relation could be demonstrated between the stage of the cycle of the seminiferous epithelium and the start of differentiation. Differentiating cells were found isolated or in groups of two, four, eight or sixteen cells. Hence we concluded that at least up to their fourth division differentiating cells divide synchronously without degenerations. Three types of division of repopulating stem cells were distinguished, producing (1) two repopulating stem cells, (2) one repopulating stem cell and one cell starting spermatogonial differentiation, or (3) two differentiating cells. Type 1 divisions were found most frequently.     

Embryonic Stem Cells: Spontaneous and Directed Differentiation

The specific structural features of embryonic stem cells and embryoid bodies and mechanisms of their differentiation in different cell types are considered. The mouse embryonic stem cells (line R1) formed multilayer colonies which enlarged as a result of fast cell division. Embryoid bodies that derived from embryonic stem cells consisted of an outer layer, an inner layer, and an internal cavity. The structure of cells of the outer and inner layers markedly differed. Spontaneous and directed differentiation of embryoid bodies is determined by some unspecific and specific factors (growth and differentiation factors and extracellular matrix proteins). Retinoic acid, the most commonly used inducer of differentiation of the embryonic stem cells, induces different types of differentiation when applied at different concentrations. The sequence of expression of tissue specific genes and proteins during differentiation of the embryonic stem cells in vitrois similar to that in vivo.     

单细胞转录组测序数据分析算法在干细胞研究中的应用

细胞的转录组决定其生理状态,每个细胞的转录组都是唯一的。借助单细胞转录组测序可分析单个干细胞的转录组特征,通过进一步的运算方法可以根据转录组特征对细胞进行细胞状态测定以及系谱分化特征的重建,在干细胞及组织发育研究中发挥了强大的作用,推动了其快速发展,加速了对干细胞分化及组织发育的相关过程及调控路径的认识。尤其是在干细胞领域的应用,得益于新算法的发展,单细胞转录组测序分析可用来阐述干细胞的起源、异质性,尤其是对干细胞的分化过程进行连续观察。本文主要对应用于干细胞分化相关研究的单细胞转录组测序数据新的算法及其应用进行了综述。     

干细胞向甲状旁腺细胞的分化及在甲状旁腺功能减退中的研究进展

干细胞是一类能够自我复制、自我更新,具有多向分化潜能,能产生多种分化细胞类型的细胞,由于它的自我复制和多向分化潜能,干细胞技术已经被广泛的应用于细胞移植治疗中。甲状旁腺功能减退作为一种内分泌疾病,目前的治疗方案都不能从根本上治疗该疾病。因此应用干细胞来源的甲状旁腺细胞移植治疗甲状旁腺功能减退越来越受到医学界的重视。目前,已有科研团队报道了应用胚胎干细胞（ESCs）、胸腺上皮细胞和扁桃体间充质细胞向甲状旁腺细胞分化及其在甲状旁腺功能减退中的治疗。本文将干细胞向甲状旁腺细胞的分化及在甲状旁腺功能减退治疗中的研究进展进行综述。     

SPERMATOGENETIC CLONES DEVELOPING FROM REPOPULATING STEM CELLS SURVIVING A HIGH DOSE OF AN ALKYLATING AGENT

We investigated stem cell renewal and differentiation in 10- and 15-days-old spermatogonial clones developing in mouse seminiferous epithelium after an extremely large cell loss, inflicted by high doses of the alkylating agent Myleran. The spermatogonial clones arise from cells that resemble the A_is spermatogonia but have a larger nuclear diameter. In spite of their mitotic activity these ‘re-populating stem cells’ lie mainly isolated or in pairs. This is explained by migration and differentiation. Migration appeared to occur at random in all directions along the basement membrane of the seminiferous tubule. After one or more divisions of the stem cells, a second type of cell appears, which is called the ‘differentiating spermatogonium’. The time elapsing before this type of cell appears, depends on the dose of Myleran: the larger the dose the later differentiation starts. A relation could be demonstrated between the stage of the cycle of the seminiferous epithelium and the start of differentiation. Differentiating cells were found isolated or in groups of two, four, eight or sixteen cells. Hence we concluded that at least up to their fourth division differentiating cells divide synchronously without degenerations. Three types of division of repopulating stem cells were distinguished, producing (1) two repopulating stem cells, (2) one repopulating stem cell and one cell starting spermatogonial differentiation, or (3) two differentiating cells. Type 1 divisions were found most frequently.     

Fat pad-derived mesenchymal stem cells as a potential source for cell-based adipose tissue repair strategies

Background: Mesenchymal stem cells are able to undergo adipogenic differentiation and present a possible alternative cell source for regeneration and replacement of adipose tissue. The human infrapatellar fat pad is a promising source of mesenchymal stem cells with many source advantages over from bone marrow. It is important to determine whether a potential mesenchymal stem‐cell exhibits tri‐lineage differentiation potential and is able to maintain its proliferation potential and cell‐surface characterization on expansion in tissue culture. We have previously shown that mesenchymal stem cells derived from the fat pad can undergo chondrogenic and osteogenic differentiation, and we characterized these cells at early passage. In the study described here, proliferation potential and characterization of fat pad‐derived mesenchymal stem cells were assessed at higher passages, and cells were allowed to undergo adipogenic differentiation. Materials and methods: Infrapatellar fat pad tissue was obtained from six patients undergoing total knee replacement. Cells isolated were expanded to passage 18 and proliferation rates were measured. Passage 10 and 18 cells were characterized for cell‐surface epitopes using a range of markers. Passage 2 cells were allowed to undergo differentiation in adipogenic medium. Results: The cells maintained their population doubling rates up to passage 18. Cells at passage 10 and passage 18 had cell‐surface epitope expression similar to other mesenchymal stem cells previously described. By staining it was revealed that they highly expressed CD13, CD29, CD44, CD90 and CD105, and did not express CD34 or CD56, they were also negative for LNGFR and STRO1. 3G5 positive cells were noted in cells from both passages. These fat pad‐derived cells had adipogenic differentiation when assessed using gene expression for peroxisome proliferator‐activated receptor γ2 and lipoprotein lipase, and oil red O staining. Discussion: These results indicate that the cells maintained their proliferation rate, and continued expressing mesenchymal stem‐cell markers and pericyte marker 3G5 at late passages. These results also show that the cells were capable of adipogenic differentiation and thus could be a promising source for regeneration and replacement of adipose tissue in reconstructive surgery.     

A Combination of Culture Conditions and Gene Expression Analysis Can Be Used to Investigate and Predict hES Cell Differentiation Potential towards Male Gonadal Cells

Human embryonic stem cell differentiation towards various cell types belonging to ecto-, endo- and mesodermal cell lineages has been demonstrated, with high efficiency rates using standardized differentiation protocols. However, germ cell differentiation from human embryonic stem cells has been very inefficient so far. Even though the influence of various growth factors has been evaluated, the gene expression of different cell lines in relation to their differentiation potential has not yet been extensively examined. In this study, the potential of three male human embryonic stem cell lines to differentiate towards male gonadal cells was explored by analysing their gene expression profiles. The human embryonic stem cell lines were cultured for 14 days as monolayers on supporting human foreskin fibroblasts or as spheres in suspension, and were differentiated using BMP7, or spontaneous differentiation by omitting exogenous FGF2. TLDA analysis revealed that in the undifferentiated state, these cell lines have diverse mRNA profiles and exhibit significantly different potentials for differentiation towards the cell types present in the male gonads. This potential was associated with important factors directing the fate of the male primordial germ cells in vivo to form gonocytes, such as SOX17 or genes involved in the NODAL/ACTIVIN pathway, for example. Stimulation with BMP7 in suspension culture resulted in up-regulation of cytoplasmic SOX9 protein expression in all three lines. The observation that human embryonic stem cells differentiate towards germ and somatic cells after spontaneous and BMP7-induced stimulation in suspension emphasizes the important role of somatic cells in germ cell differentiation in vitro.     

The stem cells of early embryos

Cells resident in an organism that possess the dual capacity for self-renewal and differentiation into a spectrum of subtypes are referred to as stem cells. In the past decade, basic research performed on stem cells has shed light on the molecular pathways operating in vivo which can be harnessed in vitro for the establishment of cell lines mirroring the stem cells in the organism. The attractiveness of stem cells as in vitro models of organotypic differentiation and their potential application in a clinical context holds great promise and is only beginning to be exploited. Stem cells can be broadly grouped into two categories based on their origin from either the embryonic or the adult. Only the early embryo possesses truly pluripotent cells that can give rise to all the cell types present in the embryo proper and adult. The adult, on the other hand, possesses specialized, tissue- or organ-specific stem cell types, which can give rise to the differentiated cell types of that specific organ and have in some instances been shown to transdifferentiate. However, no stem cell obtained from an adult organism has yet been shown to exhibit developmental potential matching the breadth of that of stem cells obtained from embryos. This review focuses on the different types of stem cells that are resident in early stage mammalian embryos, detailing their derivation and propagation in addition to highlighting their developmental potential and opportunities for future applications.     

Stemness,fusion and renewal of hematopoietic and embryonic stem cells

Development of replacement cell therapies awaits the identification of factors that regulate nuclear reprogramming and the mechanisms that control stem cell renewal and differentiation. Once such factors and signals will begin to be elucidated, new technologies will have to be envisaged where uniform differentiation of adult or embryonic stem cells along one differentiation pathway can be induced. Controlled differentiation of stem cells will require the engineering of niches and extracellular signal combinations that would amplify a particular signaling network and allow uniform and selective differentiation. Three recent advances in stem cell research open the possibility to approach engineering studies for cell replacement therapies. Fusion events between stem cells and adult cells or between adult and embryonic stem cells have been shown to result in altered fates and nuclear reprogramming of cell hybrids. Hematopoietic stem cells were shown to require Wnt signaling in order to renew. The purification of Wnt proteins would allow their use as exogenous purified cytokines in attempts to amplify stem cells before bone marrow transplantation. The homeodomain protein Nanog has been shown to be crucial for the embryonic stem cell renewal and pluripotency. However, the cardinal question of how stemness is preserved in the early embryo and adult stem cells remains opened.