Hepatic progenitor cells, stem cells, and AFP expression in models of liver injury

Adult hepatocytes and liver-cell progenitors play a role in restoring liver tissue after injury. For the study of progenitor cells in liver repair, experimental models included (a) surgical removal of liver tissue by partial hepatectomy; (b) acute injury by carbontetrachloride; (c) acute injury by d-galactosamine (GalN) and N-nitrosomorpholine (NNM); and (d) chemical hepatocarcinogenesis by feeding NNM in low and high doses. Serological and immunohistological detection of alpha-fetoprotein gene expression served to follow pathways of cellular differentiation. Stem cells were not required in models of surgical removal of parenchyma and in carbon tetrachloride intoxication of adult hepatocytes. In contrast, regeneration of liver occurred through biliary epithelial cells in injuries induced by GalN and NNM. These biliary epithelial cells, collectively called oval cells, are most probably derived from the canals of Hering. Proliferating bile duct cells reached a level of differentiation with reactivation of foetal genes and significant alpha-1-fetoprotein (AFP) synthesis signalling a certain degree of retrodifferentiation with potential stemness. Due to the same embryonic origin of bile ducts and hepatocytes, biliary epithelium and its proliferating progeny (oval cells) have a defined role in liver regeneration as a transit and amplification compartment. In their early proliferation stage, oval cells were heavily engaged in DNA synthesis ([3H]thymidine labelling). Pulse-chase experiments during experimental hepatocarcinogenesis exhibited their development into hepatocytes with high risk for transformation and leading to foci of altered hepatocytes. Hepatocellular carcinomas may arise either from proliferating/differentiating oval cells or from adult hepatocytes; both cell types have stem-like properties. AFP-positive and AFP-negative carcinomas occurred in the same liver. They may represent random clonal origin. The heterogeneity of phenotypic marker (AFP) correlated with a process of retrodifferentiation.     

Of mice and men: the riddle of tubular regeneration

Regeneration can occur through multiple distinct mechanisms, such as pluripotent stem cells, lineage‐committed progenitors or dedifferentiation. The respective contribution of each of these regenerative strategies in every organ or tissue may be different. Recent results indicate that dedifferentiation contributes less than previously thought, and that stem or progenitor cells seem to be the main drivers of regenerative processes. Our views of regeneration in the kidney are undergoing the same process of revision. Indeed, studies in humans have established the existence of a scattered population of tubular progenitors in the adult kidney. Renal progenitors have been discovered also in other animal classes such as fish and insects. In contrast, in rodents a tubular progenitor phenotype seems to be induced only after tubular injury, suggesting some differences may exist. Is this difference really related to a distinct regenerative strategy or is it simply a matter of the type and modality of cellular markers expressed? It may also be possible that progenitor cells, as well as tubular cell dedifferentiation, act in concert to allow regeneration of a complex organ like the adult mammalian kidney, as recently proposed also for the liver. Further studies are needed to resolve the riddle of tubular regeneration. However, beyond the controversial results obtained from humans and rodents, identification of tubular progenitors in humans can move the field forward and provide a novel perspective for understanding tubular regeneration. Copyright © 2013 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

NK cells can generate from precursors in the adult human liver

Hepatic NK cells constitute ≈ 40% of hepatic lymphocytes and are phenotypically and functionally distinct from blood NK cells. Whether hepatic NK cells derive from precursors in the BM or develop locally from hepatic progenitors is still unknown. Here, we identify all five known sequential stages of NK-cell development in the adult human liver and demonstrate that CD34(+) hepatic progenitors can generate functional NK cells. While early NK-cell precursors (NKPs) were similar in liver and blood, hepatic stage 3 NKPs displayed immunophenotypical differences, suggesting the onset of a liver-specific NK-cell development. Hepatic stage 3 NKPs were RORC(neg) and did not produce IL-17 or IL-22, excluding them from the lymphoid tissue-inducer (LTi) subset. In vitro culture of hepatic NKPs gave rise to functional NK cells exhibiting strong cytotoxicity against K562 targets. To determine whether hepatic NKPs are stably residing in the liver, we analyzed donor and recipient-derived cells in transplanted livers. Shortly after liver transplantation all donor NKPs in liver grafts were replaced by recipient-derived ones, indicating that hepatic NKPs are recruited from the bloodstream. Together, our results show that NKPs are continuously recruited from peripheral blood into the liver and can potentially differentiate into liver-specific NK cells.     

Liver repair by intra- and extrahepatic progenitors

Despite its remarkable capacity for endogenous regeneration, the mammalian liver is vulnerable to a number of chronic or acute conditions that exceed or circumvent the proliferative capabilities of its mature cell complement. Bipotential hepatic progenitors, or “oval cells,” have been shown to contribute to organ regeneration under such circumstances, both in human patients and in animal models. These progenitors are attractive agents for cell therapy, but have thus far proven challenging to isolate and manipulate. New reports indicating that transplanted bone marrow cells (BMCs) can also generate hepatocytes and contribute to liver repair have attracted considerable attention, because these cells are familiar and accessible to both clinicians and scientists. Recently, the issue of whether nuclear transfer (via cell fusion between donor BMC and recipient hepatocyte) or previously unrecognized differentiation potential (i.e., plasticity/transdifferentiation of BMC) is the primary origin of donor-derived hepatocytes has generated considerable controversy. In the liver, most evidence supports cell fusion as the key agent in the reversal of hepatopathology. However, regardless of their origin, the frequency of hepatocyte correction events is low. As is the case for the delivery of intrahepatic progenitors, substantial improvements in the understanding of this process will be needed before clinical application becomes practical.     

A Novel Population of Mesenchymal Progenitors with Hematopoietic Potential Originated from CD14- Peripheral Blood Mononuclear Cells

Hemopoietic system derived progenitor cells with mesenchymal features have been identified including CD14⁺ monocyte-derived progenitors. However, it is unclear whether there are mesenchyme derived progenitors with hematopoietic potential. Herein, we identified a novel CD14^- cell-derived population with both mesenchymal and hematopoietic features in rat peripheral blood, and this cell population is different from the CD14⁺ monocyte-derived progenitors but designated peripheral blood multipotential mesenchymal progenitors (PBMMPs). Phenotype analysis demonstrated expression of mesenchymal markers in PBMMPs including BMPRs, Endoglin/CD105, Fibronectin (Fn), Vimentin (Vim), Collagen (Col) I/II/III along with hematopoietic marker CD34. CD14⁺ cell-derived population shared the same characteristics with CFs. In mixed culture of CD14⁺ and CD14^- cells, PBMMPs were a predominant component and expressed CD29^high, CD73^high, CD34^high, CD45^low and CD90. Except for the value of mixed T lymphocytes and CD14⁺ cell-derived population, hematopoietic characters of cultured PBMMPs were indicated by CD14^-/CD34⁺/CD45^-/CD90⁺. The mesenchymal origin was further confirmed by comparing PBMMPs with bone marrow stromal cells. Finally, we transplanted PBMMPs into a skin wound model, and results showed the specific potential of PBMMPs in not only extracellular matrix secretion but epidermal regeneration. This study provides evidence that peripheral blood contains common hematopoietic-mesenchymal progenitors from both hematopoietic and mesenchymal lineages, and CD34⁺ mesenchymal progenitors are a possible alternative source of epidermal cells in wound healing.     

Pluripotent and committed haemopoietic progenitor cells in rat peripheral blood

The assay system for determination of haemopoietic progenitors in peripheral blood of rats is essen tial for potential studies on mobilisation and transplantation of circulating progenitor cells in a rat experimental model. This paper demonstrates the possibility of detection and quantification of pluripotent progenitors (Colony Forming Units-Spleen day 8-CFU-Sd8) and committed progenitors (Colony Forming Units Granulocyte Macrophage-CFU-GM and Burst Forming Units-Erythroid-BFU-E) in peripheral blood of rats in a steady state. For determination of CFU-Sd8 the rat to mouse in vivo assay was used, and for committed progenitors in vitro assays on methylcellulose were employed. The CFU-Sd8 incidence ranged from 7.3 to 11.6/ml of rat blood, similar to that reported in literature for mice. The incidence of CFU-GM was found to be 59.7 ± 9.4/ml which is in the range of the literature data for mice, rabbits, dogs and humans. The incidence of BFU-E in rat peripheral blood was 4.3 ± 1/ml, which was relatively low, but could be also considered as comparable with some literature data for dogs and humans. The CFU-E were not detected by the technique used. These results confirmed the existence of circulatory blood pluripotent progenitors (CFU-Sd8) and committed (CFU-GM and BFU-E) progenitors in rat, as has been established for some other mammalian species.     

IL-6 attenuates apoptosis, while neither IL-6 nor IL-10 affect the numbers or protease phenotype of fetal liver-derived human mast cells

BACKGROUND: The combination of recombinant human stem cell factor (rhSCF), rh interleukin (IL)-6 and rhIL-10 was reported to be optimal for mast cell development from cord blood progenitors and to induce chymase expression in all such mast cells earlier in their development than tryptase. OBJECTIVE: The effects of rhIL-6 and rhIL-10 in various combinations on the rhSCF-dependent development of human mast cells from fetal liver progenitors were examined in serum-free media. METHODS: Dispersed fetal liver cells were cultured in serum-free AIM-V medium with rhSCF alone, or with combinations of rhIL-6 and rhIL-10. Tryptase and chymase expression, surface Kit expression, metachromasia with toluidine blue and apoptosis were measured. RESULTS: Neither rhIL-6 nor rhIL-10 nor the two interleukins together, when included from day 0 of culture, affected the number or protease phenotype of mast cells at 1 or 3 weeks. Expression of tryptase paralleled the appearance of metachromasia and surface Kit, both of which preceded chymase expression, regardless whether a rabbit polyclonal or mouse monoclonal anti-chymase antibody preparation was used. On the other hand, rhIL-6 markedly attenuated baseline levels of apoptosis in the presence of rhSCF as well as apoptosis occurring after withdrawal of rhSCF, whereas rhIL-10 had no effect. CONCLUSION: RhIL-6 protected fetal liver-derived mast cells from apoptosis, particularly after withdrawal of rhSCF, but neither rhIL-6 nor rhIL-10 nor the combination of these interleukins affected the numbers or protease phenotype of these mast cells.     

Spermatogonial stem cells: questions, models and perspectives

This review looks into the phylogeny of spermatogonial stem cells and describes their basic biological features. We are focusing on species-specific differences of spermatogonial stem cell physiology. We propose revised models for the clonal expansion of spermatogonia and for the potential existence of true stem cells and progenitors in primates but not in rodents. We create a new model for the species-specific arrangements of spermatogenic stages which may depend on the variable clonal expansion patterns. We also provide a brief overview of germ cell transplantation as a powerful tool for basic research and its potential use in a clinical setting.     

Proliferation and hepatic differentiation of adult-derived progenitor cells

Hepatic progenitor cells, capable of maturing into hepatocytes and biliary cells, are hypothesized to be involved in all forms of liver regeneration and may prove clinically useful at reconstituting damaged livers. A murine hepatic progenitor cell population from young adult liver tissue has been isolated and characterized to establish a model for the development of liver cell therapies and for analysis of immune responses after transplantation. Hepatic progenitor cells were isolated from 3- to 6-week-old C57BL/6 mice using modifications of a two-stage liver perfusion technique followed by low speed centrifugation. Cellular analysis by phase contrast, fluorescent and confocal microscopy demonstrated that the hepatic progenitors (1) formed ex vivo colonies with a morphological appearance similar to committed hepatocytic progenitors isolated from embryonic mice and rats; (2) they are smaller than mature hepatocytes; (3) in culture they demonstrated peak expression of an oval cell marker at day 14, whereas albumin expression continued to increase beyond day 21 of culture, and (4) a subset of the progenitors phenotypically differentiated into mature hepatocytes or biliary cells. The unique antigenic profile of these hepatic progenitor cells and their ability to differentiate suggests that purification of the cells should allow for their potential use in transplantation.     

Differential effects of saliency: an event-related brain potential study

The fate of neural stem/progenitor cells (NSCs/NPCs) in vivo lies on the local microenvironment. Whether the denervated hippocampus provides a stimulative role on the survival and differentiation of the anterior subventricular zone (SVZa) progenitors was investigated in the present study. In vivo the SVZa progenitors were transplanted into the denervated hippocampus and the contralateral side, and were found migrating along the subgranular layer. More implanted cells were found survived and differentiated into the Neurofilament 200 (NF-200) or beta-Tubulin-III positive neurons in the denervated than in the normal hippocampus at all points studied. In vitro the extracts from the denervated and normal hippocampus were used to induce differentiation of the SVZa progenitors. More progenitors incubated with the denervated hippocampal extract differentiated significantly into the MAP-2 or AChE positive neurons than those incubated with the normal hippocampal extract (P<0.05). We concluded that the deafferented hippocampus provided proper microenvironment for the survival and neuronal differentiation of neural progenitors.     

Regulation of cell growth by Notch signaling and its differential requirement in normal vs. tumor-forming stem cells in Drosophila

Cancer stem cells (CSCs) are postulated to be a small subset of tumor cells with tumor-initiating ability that shares features with normal tissue-specific stem cells. The origin of CSCs and the mechanisms underlying their genesis are poorly understood, and it is uncertain whether it is possible to obliterate CSCs without inadvertently damaging normal stem cells. Here we show that a functional reduction of eukaryotic translation initiation factor 4E (eIF4E) in Drosophila specifically eliminates CSC-like cells in the brain and ovary without having discernable effects on normal stem cells. Brain CSC-like cells can arise from dedifferentiation of transit-amplifying progenitors upon Notch hyperactivation. eIF4E is up-regulated in these dedifferentiating progenitors, where it forms a feedback regulatory loop with the growth regulator dMyc to promote cell growth, particularly nucleolar growth, and subsequent ectopic neural stem cell (NSC) formation. Cell growth regulation is also a critical component of the mechanism by which Notch signaling regulates the self-renewal of normal NSCs. Our findings highlight the importance of Notch-regulated cell growth in stem cell maintenance and reveal a stronger dependence on eIF4E function and cell growth by CSCs, which might be exploited therapeutically.     

分子影像学方法示踪胚胎干细胞移植治疗急性肝损伤

背景：胚胎干细胞具有多向分化潜能,已被用于急性肝损伤的治疗,但其在体内治疗过程中的增殖迁移情况尚不清楚。 目的：利用分子影像技术监测移植胚胎干细胞在急性肝损伤修复过程中的行为。 方法：利用慢病毒载体,将萤火虫荧光素酶、红色荧光蛋白以及单纯疱疹病毒胸苷激酶三融合基因转入小鼠胚胎干细胞(D3)中,筛选得到稳定整合3个报告基因的D3胚胎干细胞系。将上述胚胎干细胞或分化了6 d的拟胚体细胞通过脾脏注射到急性肝损伤SV129模型小鼠体内,利用生物发光成像技术监测移植的细胞。 结果与结论：RT-PCR结果显示,三融合基因的转入并未影响胚胎干细胞Oct-4和Nanog的表达。利用小动物活体成像系统可以观察到移植细胞从脾脏迁移到肝脏的过程。移植的胚胎干细胞和拟胚体细胞都在肝脏处形成畸胎瘤,由于单纯疱疹病毒胸苷激酶同时也是自杀基因,可以与更昔洛韦作用诱导转基因细胞死亡,通过注射更昔洛韦来抑制畸胎瘤的生长并逐步将其杀死。组织学分析显示,畸胎瘤里包含来自于3个胚层的组织。提示三融合基因的转入并未影响胚胎干细胞的多向分化潜能,且胚胎干细胞用于细胞治疗有潜在的成瘤风险,影响了对肝损伤的修复,治疗策略有待进一步改进,并需要实时监控其在体内的行为。     

Stem cells in nephrology: present status and future

Stem cell biology is currently developing rapidly because of the potential therapeutic utility of stem cells. The ability to acquire any desired phenotype raises hope for regenerative therapies. Manipulation of these cells is a potentially valuable tool; however, the mechanisms of stem cell differentiation and plasticity are currently beyond our control. In the field of nephrology, the presence of adult kidney stem cells has been debated. Renal adult stem cells may be descendants of some early kidney progenitors, or may be derived from bone marrow. Evidence of a hematopoietic stem-cell contribution to renal repair encourages the possibility of bone marrow or stem cell transplantation as a means of treating autoimmune glomerulopathies. The transplantation of fetal kidney tissue containing renal progenitors, which then develop into functional nephrons, is a step towards renal regeneration. According to recent reports, the development of functional nephrons from human mesenchymal stem cells in rodent whole-embryo culture is possible. Establishing in vitro self organs from autologous stem cells would be a promising therapeutic solution in light of the shortage of allogenic organs and the unresolved problem of chronic allograft rejection.     

The B lineage potential of thymus settling progenitors is critically dependent on mouse age

The nature and lineage potential, particularly that for B cells, of thymus settling progenitors (TSP) in the adult mouse has been the subject of considerable debate. Lack of B cell potential would suggest pre-thymic, whereas its presence would suggest intra-thymic loss of B cell potential. Using limiting dilution analysis (LDA) in vitro and transfer experiments in vivo, we show that the B cell potential of TSP is critically dependent on mouse age, reaching a maximum of about 1 in 20 cells at birth, decreasing 50-fold in adult mice. Cells with a TSP phenotype can be found in the neonatal blood. Furthermore, using LDA, we show that Notch ligand signaling of TSP results in the loss of B cell potential with a half-life of approximately 12 h. Taken together, these results indicate that loss of B cell potential by TSP is an intra-thymic event and highlight the developmental pressure acting on the immune system to rapidly colonize primary lymphoid organs with functional progenitors. This critical time coincides with birth in the mouse. In the adult mouse, we estimate than only about 5 TSP cells/day would be required to maintain steady-state thymopoiesis.     

人胚胎发育过程中间充质干祖细胞与造血细胞间的起源关系探讨

目的探讨人胚胎发育过程中间充质干祖细胞(MSPCs)与造血细胞间的起源关系。方法取发育不同时间药流胚胎,分离不同造血组织消化成单个细胞,于高增殖潜能集落形成细胞(HPP-CFC)培养体系培养10~14 d,倒置显微镜下挑取直径大于0.5 mm的HPP-CFC集落于液体培养体系进行二次培养,对二次培养中出现的贴壁细胞进行扩增并鉴定其细胞表面分子的表达,于不同分化体系鉴定其是否具有MSPCs的分化特性。结果本研究总结了胚胎发育不同时期主动脉-性腺-中肾(AGM)区、卵黄囊、胎肝等不同部位包括HPP-CFC在内的各类造血前体细胞的发育动态,发现从28体节开始,一定比例的AGM区HPP-CFC除能够分化产生造血细胞外,其来源的贴壁细胞具有MSPCs的分化功能,贴壁细胞在淋巴母细胞转化实验中可抑制T细胞的增殖。结论人胚胎AGM区内,部分MSPCs和造血细胞起源于共同前体。     

Reconstitution of a human immune system in immunodeficient mice: models of human alloreaction in vivo

Rodents have been widely used for studies in transplantation immunology because of their short reproduction period and the relative ease of generating inbred mutant or transgenic strains. However, although many biological mechanisms are similar between rodents and humans, several features clearly distinguish the immune system in these species. Consequently, it is rarely possible to extrapolate observations from rodent models directly into clinical practice. In vitro studies with human cells are useful for elucidation of basic mechanisms, but in order to study complex biological phenomena, in vivo studies are indispensable. In later years, a number of interesting models have been described where immunodeficient mice have been reconstituted with human cells, so-called humanized mice, in order to study human immune responses in vivo. This has opened a new field of experimental immunology that has been applied to areas such as cancer, autoimmunity, allergy, infections, and transplantation biology. In this review, we shall concentrate on the use of severe combined immunodeficient mice reconstituted with human immune or stem cells for studies of human alloreaction in vivo.     

Hierarchization of myogenic and adipogenic progenitors within human skeletal muscle

Skeletal muscle cells constitute a heterogeneous population that maintains muscle integrity through a high myogenic regenerative capacity. More unexpectedly, this population is also endowed with an adipogenic potential, even in humans, and intramuscular adipocytes have been found to be present in several disorders. We tested the distribution of myogenic and adipogenic commitments in human muscle-derived cells to decipher the cellular basis of the myoadipogenic balance. Clonal analysis showed that adipogenic progenitors can be separated from myogenic progenitors and, interestingly, from myoadipogenic bipotent progenitors. These progenitors were isolated in the CD34(+) population on the basis of the expression of CD56 and CD15 cell surface markers. In vivo, these different cell types have been found in the interstitial compartment of human muscle. In vitro, we show that the proliferation of bipotent myoadipogenic CD56(+)CD15(+) progenitors gives rise to myogenic CD56(+)CD15(-) progenitors and adipogenic CD56(-)CD15(+) progenitors. A cellular hierarchy of muscle and fat progenitors thus occurs within human muscle. These results provide cellular bases for adipogenic differentiation in human skeletal muscle, which may explain the fat development encountered in different muscle pathological situations.     

Small epithelial cells in extrahepatic biliary atresia: electron microscopic and immunoelectron microscopic findings suggest a close relationship to liver progenitor cells

AIMS: It is still unclear whether hepatic stem cells that give rise to both biliary epithelial cells and hepatocytes exist in the human liver. The aim of this study was to investigate whether cells with ultrastructural and immunophenotypical features similar to those of the oval cells of rodents or the small epithelial cells (SEC) described recently in hepatoblastoma, i.e. putative hepatic progenitor cells, are found in the liver of patients with extrahepatic biliary atresia. METHODS AND RESULTS: Liver biopsies from 10 infants with extrahepatic biliary atresia were investigated by transmission electron microscopy. Single and double immunolabelling for cytokeratin 7, a marker of biliary differentiation, and albumin, a marker of hepatocytic differentiation, was investigated by immunoelectron microscopy. Electron microscopy revealed SEC that were ultrastructurally similar to the oval cells and coexpressed albumin and cytokeratin 7. The SEC exhibited a spectrum of differentiation that, in addition to relatively undifferentiated cells, included cells that exhibited morphological and immunophenotypical signs of differentiation towards biliary epithelial cells and hepatocytes. CONCLUSIONS: The findings demonstrate that SEC with morphological and immunophenotypical features of the oval cells of rodents and the SEC described in hepatoblastoma are found in the liver of patients with extrahepatic biliary atresia. The data further support the hypothesis that the SEC represent possible candidates for hepatic progenitor cells.     

Human mast cell progenitors in peripheral blood from atopic subjects with high IgE levels.

BACKGROUND: It remains unclear whether the number of circulating mast cell progenitors is increased in patients with atopic diseases. Distinct genotypes are reported to affect mast cell/basophil activation. OBJECTIVE: We compared the number and function of mast cell progenitors present in the peripheral blood from donors with normal IgE (IgE < 400 U/mL) and those with atopic dermatitis accompanied by high serum IgE (IgE > 5000 U/mL). METHODS: Purified peripheral blood cells were cultured in serum-free methylcellulose containing stem cell factor (SCF), IL-6 plus IL-3. Fresh methylcellulose containing the cytokines was layered over every 2 weeks. The cultured mast cells were retrieved from the methylcellulose and were functionally analysed. RESULTS: Mast cell colonies were distinguished at 6 weeks of culture as other colony types had been degenerated. The number of mast cell colony-forming cells varied depending on donors and was not significantly increased in peripheral blood from the hyper-IgE atopic patients. A significant inversed correlation was found between the number of mast cells per one colony and the ages of donors. The cultured mast cells derived from atopic patients and those from normal IgE donors equally expressed Fc epsilon RI and released histamine through Fc epsilon RI, although IL-4 priming in vitro markedly enhanced the function of mast cells regardless of donors. CONCLUSIONS: These results indicate that the number of circulating mast cell progenitors may be regulated by unknown individual factors unrelated to IgE levels. Mast cell function may be regulated largely by environmental factors, such as IL-4, but not determined by their progenitors' genotypes.