Differential transcriptional regulation of the NANOG gene in chicken primordial germ cells and embryonic stem cells

Background:NANOG is a core transcription factor(TF)in embryonic stem cells(ESCs)and primordial germ cells(PGCs).Regulation of the NANOG gene by TFs,epigenetic factors,and autoregulatory factors is well characterized in ESCs,and transcriptional regulation of NANOG is well established in these cells.Although NANOG plays a key role in germ cells,the molecular mechanism underlying its transcriptional regulation in PGCs has not been studied.Therefore,we investigated the mechanism that regulates transcription of the chicken NANOG(cNANOG)gene in PGCs and ESCs.Results:We first identified the transcription start site of cNANOG by 5′-rapid amplification of cDNA ends PCR analysis.Then,we measured the promoter activity of various 5′flanking regions of cNANOG in chicken PGCs and ESCs using the luciferase reporter assay.cNANOG expression required transcriptional regulatory elements,which were positively regulated by POU5F3(OCT4)and SOX2 and negatively regulated by TP53 in PGCs.The proximal region of the cNANOG promoter contains a positive transcriptional regulatory element(CCAAT/enhancer-binding protein(CEBP)-binding site)in ESCs.Furthermore,small interfering RNA-mediated knockdown demonstrated that POU5F3,SOX2,and CEBP played a role in cell type-specific transcription of cNANOG.Conclusions:We show for the first time that different trans-regulatory elements control transcription of cNANOG in a cell type-specific manner.This finding might help to elucidate the mechanism that regulates cNANOG expression in PGCs and ESCs.

Developmental potency of mouse primitive ectoderm cells, embryonic ectoderm cells and primordial germ cells after blastocyst injection

Developmental potency of primitive and embryonic ectoderm cells from 4.50-day to 6.25-day post-coitum (p.c.) mouse embryos and primordial germ cells from 12.50-day p.c.male genital ridges of fetal mice were studied by direct introducing them into 3.50-day p.c.blastocysts.Sixteen (61.5) overt chimaeras out of 26(50%) offsprings were obtained after transfer of 52 blastocysts injected with 4.50-day primitive ectoderm cells;four (16.0%) overt chimaeras were obtained out of 25 (51.0%) offsprings with 4.75-day primitive ectoderm cells from 49 transferred blastocysts.However,no overt chimaera was obtained with either 5.25-day or 6.25-day embryonic ectoderm cells or 12.50-day male primordial germ cells.GPI analysis of mid-gestation conceptuses developed from injected blastocysts showedthat 5.25-day embryonic ectoderm cells could only contributed to yolk sac of conceptus.Results suggested that implantation acts as a trigger for the determination of primitive ectoderm cells,and their developmental potency becomes limited within a short period of time in normal development.

Targeting lentiviral vectors to primordial germ cells(PGCs):An efficient strategy for generating transgenic chickens

Recent advances in avian transgenic studies highlight the possibility of utilizing lentiviral vectors as tools to generate transgenic chickens. However, low rates of gonadal chimerism and germ line transmission efficiency still limit the broad usage of this method in creating transgenic chickens. In this study, we implemented a simple strategy using modified lentiviral vectors targeted to chicken primordial germ cells(PGCs) to generate transgenic chickens. The lentiviral vectors were pseudotyped with a modified Sindbis virus envelope protein(termed M168) and conjugated with an antibody specific to PGC membrane proteins. We demonstrated that these optimized M168-pseudotyped lentiviral vectors conjugated with SSEA4 antibodies successfully targeted transduction of PGCs in vitro and in vivo. Compared with the control, 50.0%–66.7% of chicken embryos expressed green fluorescent protein(GFP) in gonads transduced by the M168-pseudotyped lentivirus. This improved the targeted transduction efficiency by 30.0%–46.7%. Efficient chimerism of exogenous genes was also observed. This targeting technology could improve the efficiency of germ line transmission and provide greater opportunities for transgenic poultry studies.

Improved Isolation and Culture of Embryonic Germ Cells from Guanzhong Dairy Goat

A total of 219 embryonic-germ-cell-like （EG-like） clumps were derived from 15 selected goat fetuses. Isolation of primordial germ cells （PGCs） based on co-culture with primary goat embryonic fibroblast showed no difference from traditional feeder layer-based culture method used in mouse and human. The putative primary EG colonies were multilayer clumps of compact cells with unclear cell-cell boundaries. Three subculture methods of goat EG-like colony, traditional enzymatic digestion, mechanical cutting and combination of the both, were compared in this study. As a result, EG-like colonies traditionally disassociated with collagenase 1V could be subcultured for up to 4 passages. And the mechanically disaggregated EG-like colonies were successfully maintained 9-12 passages with or without enzymatic treatment. The pluripotency of the EG-like colonies was identified by their specific marker staining, spontaneous differentiation and embryoid bodies （EBs） formation in vitro. Most goat EG-like colonies （〉 80%） were AKP positive and immunocytochemically characterized with positive SSEA-1, Oct-4 and c-kit staining but SSEA-4. Under the condition of delaying passage, goat EG-like cells could differentiate into fibroblast-like, epithelium-like, and neuron-like cells. In addition, EBs could be obtained successfully in routine hanging drop culture. The serum free culture system （feeder layer-based） used in this study was suitable for keeping PGCs and EG-like cells in their undifferentiated condition, but failed to converse them to immortal cells. These results indicated that mechanical cutting is an effective method for passaging goat EG cell colonies. However, the microenvironment of conversing EG cells to immortal cells is still unclear.

α-ketoglutarate promotes the specialization of primordial germ cell-like cells through regulating epigenetic reprogramming

There is growing evidence that cellular metabolism can directly participate in epigenetic dynamics and consequently modulate gene expression.However,the role of metabolites in activating the key gene regulatory network for specialization of germ cell lineage remains largely unknown.Here,we identified some cellular metabolites with significant changes by untargeted metabolomics between mouse epiblast-like cells(EpiLCs)and primordial germ cell-like cells(PGCLCs).More importantly,we found that inhibition of glutaminolysis by bis-2-(5-phenylacetamido-1,3,4-thiadiazol-2-yl)ethyl sulfide(BPTES)impeded PGCLC specialization,but the impediment could be rescued by addition ofα-ketoglutarate(αKG),the intermediate metabolite of oxidative phosphorylation and glutaminolysis.Moreover,adding aKG alone to the PGCLC medium accelerated the PGCLC specialization through promoting H3 K27 me3 demethylation.Thus,our study reveals the importance of metabolite aKG in the germ cell fate determination and highlights the essential role of cellular metabolism in shaping the cell identities through epigenetic events.

Chicken Mesenchymal Stem Cells as Feeder Cells Facilitate the Cultivation of Primordial Germ Cells from Circulating Blood and Gonadal Ridge

Long-term maintenance of chicken primordial germ cells (PGCs) in vitro has tremendous potential for transgenic chicken production. Feeder cells are essential for the establishment and culture of chicken PGCs in vitro. Buffalo rat liver (BRL) cells are the most commonly used feeder cells for PGCs culture;however, this feeder layers from other animal species usually cause immunogenic contaminations, compromising the potential of PGCs in applications. Therefore, we tested chicken source mensenchymal stem cell (MSCs) derived from bone marrow as feeder cells to further improve PGC culture conditions. MSCs derived from chicken bone marrow have a powerful capacity to proliferate and secrete cytokines. We found chicken primordial germ cells derived from circulating blood (cPGCs) and gonads (gPGCs) can be maintained and proliferated with MSCs feeder layer cells. PGCs co-cultured on MSCs feeder retained their pluripotency, expressed PGCs specific genes and stemness markers, and maintained undifferentiated state. Our study indicated that the xeno-free MSCs-feeders culture system is a good candidate for growth and expansion of PGCs as the stepping stone for transgenic chicken research.

The culture and establishment of embryonic germ(EG)cell lines from Chinese mini swine

As a part of a basic research project on Xeno-transplantion, we have been engaged in the derivation ofembryonic stem cell lines from Chinese mini swine. Here, we reported for the first time the establishmentof two porcine EG cell lines (BPEG1 and BPEG2) from primordial germ cells of genital ridges of a 28 anda 27 d embryos respectively. Their pluripotent nature has been identified by colony morphology, markercharacterization as well as by in vitro and in vivo differentiation. These porcine EG cells are potentiallyuseful for further basic studies.

Primordial germ cell-mediated transgenesis and genome editing in birds

Transgenesis and genome editing in birds are based on a unique germline transmission system using primordial germ cells(PGCs), which is quite different from the mammalian transgenic and genome editing system. PGCs are progenitor cells of gametes that can deliver genetic information to the next generation. Since avian PGCs were first discovered in nineteenth century, there have been numerous efforts to reveal their origin, specification, and unique migration pattern, and to improve germline transmission efficiency. Recent advances in the isolation and in vitro culture of avian PGCs with genetic manipulation and genome editing tools enable the development of valuable avian models that were unavailable before. However, many challenges remain in the production of transgenic and genome-edited birds,including the precise control of germline transmission, introduction of exogenous genes, and genome editing in PGCs.Therefore, establishing reliable germline-competent PGCs and applying precise genome editing systems are critical current issues in the production of avian models. Here, we introduce a historical overview of avian PGCs and their application, including improved techniques and methodologies in the production of transgenic and genome-edited birds, and we discuss the future potential applications of transgenic and genome-edited birds to provide opportunities and benefits for humans.

Effects of 17beta-estradiol on cell migration in male chicks distribution of primordial germ

Aim： To assess whether exogenous estradiol has any effect on migration of primordial germ cells （PGCs） in the chick. Methods： Fertilized eggs were treated with 17beta-estradiol （E2） （80 lag/egg） at stage X （day 0 of incubation）, stages 8-10 （incubation 30 h） and 13-15 （incubation 55 h）. Controls received vehicle （emulsion） only. Changes in PGC number were measured on different days according to developmental stages. Results： In male right gonads, but not in female left gonads, at stages 28-30 （incubation 132 h） significant decreases in the mean number of PGCs aggregating were observed compared with the controls （P 〈 0.05） while the total PGC number in the right and left gonads at each stage did not change （P 〉 0.05）. Conclusion： The present study provides evidence that E2 has significant effects on the localization of PGCs in male right, but not female left, gonads of chicken embryos at stages 28-30, compared with controls. （Asian J Andro12008 Mar; 10： 243-248）

Establishment of Germ-line Competent C57BL/6J Embryonic Stem Cell Lines

Objective To establish C57BL/6J embryonic stem （ES） cell lines with potential germ- line contribution Methods ES cells were isolated from blastocyst inner cell mass of C5 7BL/6J mice, and cultured for 15 passages, and then injected into blastococels of ICR mice blastocysts to establish chimeric mice. Results Three ES cell lines （mC57ES1,mC57ES3, mC57ES7） derived from the inner cell mass of C57BL/6J mice blastocysts were established. They were characteristic of undifferentiated state, including normal XY karyotype, expression of a specific cell surface marker “stage-specific embryonic antigen-I” and alkaline phosphatase in continuous passage. When injected into immunodeficient mice, mC57ES1 cells consistently differentiated into derivatives of all three embryonic germ layers. When mC57ES1 cells were transferred into ICR mice blastocysts, 4 chimeric mice have been obtained. One male of them revealed successful germ-line transmission. Conclussion We have obtained C57BL/6J ES cell lines with a potential germ-line contribution, which can be used to generate transgenic and gene knock-out mice.

Reprogramming of germ cells into pluripotency

Primordial germ cells(PGCs) are precursors of all gametes, and represent the founder cells of the germline. Although developmental potency is restricted to germ-lineage cells, PGCs can be reprogrammed into a pluripotent state. Specifically, PGCs give rise to germ cell tumors, such as testicular teratomas, in vivo, and to pluripotent stem cells known as embryonic germ cells in vitro. In this review, we highlight the current knowledge on signaling pathways, transcriptional controls, and post-transcriptional controls that govern germ cell differentiation and de-differentiation. These regulatory processes are common in the reprogramming of germ cells and somatic cells, and play a role in the pathogenesis of human germ cell tumors.

Amniotic fluid stem cell-based models to study the effects of gene mutations and toxicants on male germ cell formation

Male infertility is a major public health issue predominantly caused by defects in germ cell development. In the past, studies on the genetic regulation of spermatogenesis as well as on negative environmental impacts have been hampered by the fact that human germ cell development is intractable to direct analysis in vivo. Compared with model organisms including mice, there are fundamental differences in the molecular processes of human germ cell development. Therefore, an in vitro model mimicking human sperm formation would be an extremely valuable research tool. In the recent past, both human embryonic stem （ES） cells and induced pluripotent stem （iPS） cells have been reported to harbour the potential to differentiate into primordial germ cells and gametes. We here discuss the possibility to use human amniotic fluid stem （AFS） ceils as a biological model. Since their discovery in 2003, AFS cells have been characterized to differentiate into cells of all three germ layers, to be genomically stable, to have a high proliferative potential and to be non-tumourigenic. In addition, AFS cells are not subject of ethical concerns. In contrast to iPS cells, AFSs cells do not need ectopic induction of pluripotency, which is often associated with only imperfectly cleared epigenetic memory of the source cells. Since AFS cells can be derived from amniocentesis with disease-causing mutations and can be transfected with high efficiency, they could be used in probing gene functions for spermatogenesis and in screening for male reproductive toxicity.

Molecular and epigenetic pathogenesis of germ cell tumors

The development of germ cell tumors(GCTs)is a unique pathogenesis occurring at an early developmental stage during specification,migration or colonization of primordial germ cells(PGCs)in the genital ridge.Since driver mutations could not be identified so far,the involvement of the epigenetic machinery during the pathogenesis seems to play a crucial role.Currently,it is investigated whether epigenetic modifications occurring between the omnipotent two-cell stage and the pluripotent implanting PGCs might result in disturbances eventually leading to GCTs.Although progress in understanding epigenetic mechanisms during PGC development is ongoing,little is known about the complete picture of its involvement during GCT development and eventual classification into clinical subtypes.This review will shed light into the current knowledge of the complex epigenetic and molecular contribution during pathogenesis of GCTs by emphasizing on early developmental stages until arrival of late PGCs in the gonads.We questioned how misguided migrating and/or colonizing PGCs develop to either type Ⅰ or type Ⅱ GCTs.Additionally,we asked how pluripotency can be regulated during PGC development and which epigenetic changes contribute to GCT pathogenesis.We propose that SOX2 and SOX17 determine either embryonic stem cell-like(embryonal carcinoma)or PGC-like cell fate(seminoma).Finally,we suggest that factors secreted by the microenvironment,i.e.BMPs and BMP inhibiting molecules,dictate the fate decision of germ cell neoplasia in situ(into seminoma and embryonal carcinoma)and seminomas(into embryonal carcinoma or extraembryonic lineage),indicating an important role of the microenvironment on GCT plasticity.

Derivation of Putative Porcine Embryonic Germ Cells and Analysis of Their Multi-Lineage Differentiation Potential

Embryonic germ （EG） cells are cultured pluripotent stem cells derived from the primordial germ cells （PGCs） that migrate from the dorsal mesentery of the hindgut to the developing genital ridge. In this study, the morphology of the porcine genital ridge was assessed in embryos harvested on days 22-30 of pregnancy. PGCs from embryos at these stages were cultured to obtain porcine EG cell lines, and EG-like cells were derived from PGCs from embryos harvested on days 24-28 of pregnancy. The EG-like cells expressed Oct4, Sox2, Nanog, SSEA-3, SSEA-4 and alkaline phosphatase （AP）. These cells were able to form embryoid bodies （EBs） in suspension culture and differentiate into cells representative of the three germ layers as verified by a-fetoprotein （AFP）, s-smooth muscle actin （^-SMA）, and Nestin expression. Spontaneous differentiation from the porcine EG-like cells of delayed passage in vitro showed that they could differentiate into epithelial-like cells, mesenchymal-like cells and neuron-like cells. In vitro directed differentiation generated osteocytes, adipocytes and a variety of neural lineage cells, as demonstrated by alizarin red staining, oil red O staining, and immunoftuorescence for neuronal class III [3-tubulin （Tuj 1）, glial fibrillary protein （GFAP） and galactosylceramidase （GALC）, respectively. These results indicate that porcine EG-like cells have the potential for multi-lineage differentiation and are useful for basic porcine stem cell research.

Efficient generation of zebrafish maternal-zygotic mutants through transplantation of ectopically induced and Cas9/gRNA targeted primordial germ cells

The clustered regularly interspaced short palindromic repeats(CRISPR)/Cas9 technology has been widely utilized for knocking out genes involved in various biological processes in zebrafish. Despite this technology is efficient for generating different mutations, one of the main drawbacks is low survival rate during embryogenesis when knocking out some embryonic lethal genes. To overcome this problem, we developed a novel strategy using a combination of CRISPR/Cas9 mediated gene knockout with primordial germ cell(PGC) transplantation(PGCT) to facilitate and speed up the process of zebrafish mutant generation, particularly for embryonic lethal genes. Firstly, we optimized the procedure for CRISPR/Cas9 targeted PGCT by increasing the efficiencies of genome mutation in PGCs and induction of PGC fates in donor embryos for PGCT. Secondly, the optimized CRISPR/Cas9 targeted PGCT was utilized for generation of maternal-zygotic(MZ) mutants of tcf7l1a(gene essential for head development), pou5f3(gene essential for zygotic genome activation) and chd(gene essential for dorsal development) at F1 generation with relatively high efficiency. Finally, we revealed some novel phenotypes in MZ mutants of tcf7l1 a and chd, as MZtcf7l1 a showed elevated neural crest development while MZchd had much severer ventralization than its zygotic counterparts. Therefore, this study presents an efficient and powerful method for generating MZ mutants of embryonic lethal genes in zebrafish. It is also feasible to speed up the genome editing in commercial fishes by utilizing a similar approach by surrogate production of CRISPR/Cas9 targeted germ cells.

Reprogramming of the pig primordial germ cells into pluripotent stem cells: a brief review

Primordial germ cells(PGCs) are regarded as unipotent cells that can produce only either spermatogonia or oocytes. However, PGCs can be converted into the pluripotent state by ?rst dedifferentiation to embryonic germ cells and then by reprogramming to induce them to become pluripotent stem cells(iPSCs). These two stages can be completely implemented with mouse cells. However, authentic porcine iPSCs have not been established.Here, we discuss recent advances in the stem cell ?eld for obtaining iPSCs from PGCs. This knowledge will provide some clues which will contribute to the regulation of reprogramming to pluripotency in farm species.

Study on Transplanting Germ Like Cells Differentiated from Embryonic Stem Cell into Mouse Seminiferous Tubules

Objective To investigate whether germ like cells isolated from embryoid body formed by mouse embryonic stem cells could survive and initiate spermatogenesis in seminiferous tubules of adult mice. Methods SSEA-1＋ cells were isolated from embryoid bodies prepared from mouse EGFP-ES cells, after retinoic acid treatment, the cells were detected for the expression of alkaline phosphatase, Rnh2, stella, fragilis, Tex14, Sry, Hsp90-a, Stra8 and integrin a6, and then, the cells were transplanted into seminiferous tubules of busulfan-treated adult mice. Results Six days after retinoic acid treatment, alkaline phosphatase expressing cells could still be found in embryoid body （EB） derived cells, indicating the existence of retinoic acid-resistant primordial germ cells. When the SSEA-1＋ cells isolated from embryoid bodies were stimulated with retinoic acid for 6 days, some of these cells expressed cell markers of Hsp90-a, Stra8 and integrin a6, resembling the expression profile of spermatogonial stem cells. Forty-five days after cell transplantation, a little amount of GFP-expressing cells attached to the basement membrane of seminiferous tubule and formed small colonies; Three months later, these cells started amplification in the form of cell chains with varied length, and moving towards the lumen of the seminiferous tubules. Five months after the transplantation, multilayered cell mass was found in seminiferous tubules of two, out of four recipient mice. There was no GFP-expressing cells existed in non-cell-transplanted seminiferous tubules. Conclusion In our study, although full-termed spermatogenesis was not observed in all of the recipients, the results did indicate that the embryoid body contains germ like cells, and these cells can survive and initiate amplification in seminiferous tubules of adult mouse.

Stem cells of the reproductive tract of women

Research in stem cells is one of the most rapidly evolving fields of investigation in medicine today. Stem cells are defined as cells that have the capacity to both generate daughter cells identical to the cell of origin (self-renewal) and to produce progeny with more restricted, specialized potential (differentiated cells). This dual ability to self-renew and differentiate offers great promise for expanding our understanding of organ systems, elucidating disease pathophysiology, and creating therapeutic approaches to difficult diseases. The goal of this review is to offer an overview of the different types of stem cells and to provide an introduction to the applications of stem cells to the field of obstetrics and gynecology.

Types of Human Stem Cells and Their Therapeutic Applications

The present review examines in the first place various kinds of naturally occurring stem cells, including germ cells and embryonic stem cells (ES cells), as well as haemopoietic stem cells, which are historically the first to be used for medical treatment. Attention is also given to cancer stem cells, as a source of perseverant malignant disease. The main interest is now represented by the variety of somatic cells, which can be re-programmed to different types of differentiated cells, the so-called induced pluripotent stem cells (IPSC’s). Focus is now directed not only to the factors which make such events possible like de-differentiation and reconversion but also to the stages involved in this process. It is actually postulated that the transition from differentiated cells to pluripotent cells follows a definite sequence with evidence of two waves of gene regulations. Main applications of stem cell therapy are reviewed, from the established use of haemopoietic stem cells for clinical transplantation in a variety of haematological disorders to the initial attempts to employ stem cells for the treatment of other disparate conditions. Problems related to stem cell treatment with both ES and IPS cells, like the necessity of a large in vitro expansion to provide sufficient amounts of cells and the related risk of genomic abnormalities are illustrated. The necessity of safe procedures for the development of this venture is also outlined.