Your search keyword '"Transplantation Chimera embryology"' showing total 38 results

1. Genetic developmental timing revealed by inter-species transplantations in fish.

Author

Fuhrmann JF, Buono L, Adelmann L, Martinez-Morales JR, and Centanin L

Subjects

Animals, Heterografts, Retina cytology, Blastula embryology, Blastula transplantation, Oryzias embryology, Retina embryology, Transplantation Chimera embryology, Zebrafish embryology

Abstract

The path from a fertilised egg to an embryo involves the coordinated formation of cell types, tissues and organs. Developmental modules comprise discrete units specified by self-sufficient genetic programs that can interact with each other during embryogenesis. Here, we have taken advantage of the different span of embryonic development between two distantly related teleosts, zebrafish ( Danio rerio ) and medaka ( Oryzias latipes ) (3 and 9 days, respectively), to explore modularity principles. We report that inter-species blastula transplantations result in the ectopic formation of a retina formed by donor cells - a module. We show that the time taken for the retina to develop follows a genetic program: an ectopic zebrafish retina in medaka develops with zebrafish dynamics. Heterologous transplantation results in a temporal decoupling between the donor retina and host organism, illustrated by two paradigms that require retina-host interactions: lens recruitment and retino-tectal projections. Our results uncover a new experimental system for addressing temporal decoupling along embryonic development, and highlight the presence of largely autonomous but interconnected developmental modules that orchestrate organogenesis., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2020. Published by The Company of Biologists Ltd.)

Published

2020

2. Lengthening Neurogenic Period during Neocortical Development Causes a Hallmark of Neocortex Expansion.

Author

Stepien BK, Naumann R, Holtz A, Helppi J, Huttner WB, and Vaid S

Subjects

Animals, Animals, Newborn, Cell Line, Cell Proliferation, Embryo Transfer, Embryo, Mammalian, Female, Male, Mice, Neocortex cytology, Neural Stem Cells physiology, Neural Stem Cells transplantation, Neurons physiology, Pregnancy, Rats, Time Factors, Transplantation Chimera embryology, Biological Evolution, Embryonic Development physiology, Neocortex embryology, Neurogenesis physiology

Abstract

A hallmark of the evolutionary expansion of the neocortex is a specific increase in the number of neurons generated for the upper neocortical layers during development. The cause underlying this increase is unknown. Here, we show that lengthening the neurogenic period during neocortical development is sufficient to specifically increase upper-layer neuron generation. Thus, embryos of mouse strains with longer gestation exhibited a longer neurogenic period and generated more upper-layer, but not more deep-layer, neurons than embryos with shorter gestation. Accordingly, long-gestation embryos showed a greater abundance of neurogenic progenitors in the subventricular zone than short-gestation embryos at late stages of cortical neurogenesis. Analysis of a mouse-rat chimeric embryo, developing inside a rat mother, pointed to factors in the rat environment that influenced the upper-layer neuron generation by the mouse progenitors. Exploring a potential maternal source of such factors, short-gestation strain mouse embryos transferred to long-gestation strain mothers exhibited an increase in the length of the neurogenic period and upper-layer neuron generation. The opposite was the case for long-gestation strain mouse embryos transferred to short-gestation strain mothers, indicating a dominant maternal influence on the length of the neurogenic period and hence upper-layer neuron generation. In summary, our study uncovers a hitherto unknown link between embryonic cortical neurogenesis and the maternal gestational environment and provides experimental evidence that lengthening the neurogenic period during neocortical development underlies a key aspect of neocortical expansion., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

3. Pig Chimeric Model with Human Pluripotent Stem Cells.

Author

Zhong C, Wu J, and Izpisua Belmonte JC

Subjects

Animals, Blastocyst cytology, Heterografts, Humans, Pluripotent Stem Cells cytology, Swine, Blastocyst metabolism, Models, Biological, Pluripotent Stem Cells metabolism, Stem Cell Transplantation, Transplantation Chimera embryology

Abstract

Interspecies chimera formation provides a unique platform for studying donor cell developmental potential, modeling disease in vivo, as well as in vivo production of tissues and organs. The derivation of human pluripotent stem cells (hPSC) from either human embryos or somatic cell reprogramming facilitates our understanding of human development, as well as accelerates our exploration of regenerative medicine for human health. Due to similar organ size, close anatomy, and physiology between pig and human, human-Pig interspecies chimeric model in which pig serves as the host species may open new avenues for studying human embryogenesis, disease pathogenesis, and generation of human organ for transplantation to solve the worldwide donor organ shortage. Our previous study demonstrated chimeric competency of different types of human PSCs in pig host. In this chapter, we introduce our workflow for the generation of human PSCs and analysis of its chimeric contribution to pre- and postimplantation pig embryos.

Published

2019

4. Generation of chimeric minipigs by aggregating 4- to 8-cell-stage blastomeres from somatic cell nuclear transfer with the tracing of enhanced green fluorescent protein.

Author

Ji H, Long C, Feng C, Shi N, Jiang Y, Zeng G, Li X, Wu J, Lu L, Lu S, and Pan D

Subjects

Animals, Animals, Genetically Modified, Cell Aggregation, Embryo Culture Techniques methods, Embryo Transfer methods, Female, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Histocompatibility Antigens Class I genetics, Microsatellite Repeats, Recombinant Proteins genetics, Recombinant Proteins metabolism, Skin Pigmentation genetics, Swine, Transplantation Chimera metabolism, Blastomeres cytology, Nuclear Transfer Techniques, Swine, Miniature embryology, Swine, Miniature genetics, Transplantation Chimera embryology, Transplantation Chimera genetics

Abstract

Background: Blastocyst complementation is an important technique for generating chimeric organs in organ-deficient pigs, which holds great promise for solving the problem of a shortage of organs for human transplantation procedures. Porcine chimeras have been generated using embryonic germ cells, embryonic stem cells, and induced pluripotent stem cells; however, there are no authentic pluripotent stem cells for pigs. In previous studies, blastomeres from 4- to 8-cell-stage parthenogenetic embryos were able to generate chimeric fetuses efficiently, but the resulting fetuses did not produce live-born young. Here, we used early-stage embryos from somatic cell nuclear transfer (SCNT) to generate chimeric piglets by the aggregation method. Then, the distribution of chimerism in various tissues and organs was observed through the expression of enhanced green fluorescent protein (EGFP)., Methods: Initially, we determined whether 4- to 8- or 8- to 16-cell-stage embryos were more suitable to generate chimeric piglets. Chimeras were produced by aggregating two EGFP-tagged Wuzhishan minipig (WZSP) SCNT embryos and two Bama minipig (BMP) SCNT embryos. The chimeric piglets were identified by coat color and microsatellite and swine leukocyte antigen analyses. Moreover, the distribution of chimerism in various tissues and organs of the piglets was evaluated by EGFP expression., Results: We found that more aggregated embryos were produced using 4- to 8-cell-stage embryos (157/657, 23.9%) than 8- to 16-cell-stage embryos (100/499, 20.0%). Thus, 4- to 8-cell-stage embryos were used for the generation of chimeras. The rate of blastocysts development after aggregating WZSP with BMP embryos was 50.6%. Transfer of 391 blastocysts developed from 4- to 8-cell-stage embryos to five recipients gave rise to 18 piglets, of which two (11.1%) were confirmed to be chimeric by their coat color and microsatellite examination of the skin. One of the chimeric piglets died at 35 days and was subsequently autopsied, whereas the other piglet was maintained for the following observations. The heart and kidneys of the dead piglet showed chimerism, whereas the spinal cord, stomach, pancreas, intestines, muscle, ovary, and brain had no chimerism., Conclusions: To our knowledge, this is the first report of porcine chimeras generated by aggregating 4- to 8-cell-stage blastomeres from SCNT. We detected chimerism only in the skin, heart, and kidneys. Collectively, these results indicate that aggregation using 4- to 8-cell-stage SCNT embryos offers a practical approach for producing chimeric minipigs. Furthermore, it also provides a potential platform for generating interspecific chimeras between pigs and non-human primates for xenotransplantation., (© 2017 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published

2017

5. Generation of Cynomolgus Monkey Chimeric Fetuses using Embryonic Stem Cells.

Author

Chen Y, Niu Y, Li Y, Ai Z, Kang Y, Shi H, Xiang Z, Yang Z, Tan T, Si W, Li W, Xia X, Zhou Q, Ji W, and Li T

Subjects

Animals, Blastocyst cytology, Cell Differentiation, Cells, Cultured, Embryonic Stem Cells metabolism, Embryonic Stem Cells transplantation, Female, Humans, Male, Models, Animal, Morula cytology, Pregnancy, Testis cytology, Testis embryology, Transcriptome, Embryonic Stem Cells cytology, Macaca fascicularis embryology, Transplantation Chimera embryology

Abstract

Because of their similarity to humans, non-human primates are important models for studying human disease and developing therapeutic strategies. Establishment of chimeric animals using embryonic stem cells (ESCs) could help with these investigations, but has not so far been achieved. Here, we show that cynomolgus monkey ESCs (cESCs) grown in adjusted culture conditions are able to incorporate into host embryos and develop into chimeras with contribution in all three germ layers and in germ cell progenitors. Under the optimized culture conditions, which are based on an approach developed previously for naive human ESCs, the cESCs displayed altered growth properties, gene expression profiles, and self-renewal signaling pathways, suggestive of an altered naive-like cell state. Thus our findings show that it is feasible to generate chimeric monkeys using ESCs and open up new avenues for the use of non-human primate models to study both pluripotency and human disease., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

6. HINTW, a W-chromosome HINT gene in chick, is expressed ubiquitously and is a robust female cell marker applicable in intraspecific chimera studies.

Author

Nagai H, Sezaki M, Bertocchini F, Fukuda K, and Sheng G

Subjects

Animals, Chick Embryo, Chickens, Female, Genetic Markers, Male, Polymerase Chain Reaction, Sex Chromosomes, Sex Factors, Chimera genetics, Hydrolases genetics, Hydrolases metabolism, Transplantation Chimera embryology

Abstract

Grafting and transplantation experiments in embryology require proper distinction between host and donor tissues. For the avian model this has traditionally been achieved by using two closely related species (e.g., chick and quail) followed by species-specific antibody staining. Here, we show that an in situ hybridization probe against the HINTW gene is a robust and reliable marker for female-derived chicken cells. At all pre-circulation stages tested, all cells in female embryos, independently confirmed by PCR analysis, were strongly positive for HINTW, whereas all male embryos were negative. This probe is broadly applicable in intra-specific chick/chick chimera studies, and as a proof of principle, we utilized this probe to detect female cells in three experimental settings: (1) to mark female donor cells in a node transplantation assay; (2) to distinguish female cells in male/female twins generated by the Cornish pasty culture; and (3) to detect female half of the embryo in artificially generated bilateral gynandromorphs. A rapid, PCR based pre-screening step increases the efficiency of obtaining desired donor/host sex combination from 25% to 100%. For most avian chimera studies, this female-specific in situ probe is a low cost alternative to the commonly used QCPN antibody and to ubiquitous-GFP chicken strains which are not widely available to the research community., (© 2014 Wiley Periodicals, Inc.)

Published

2014

7. Production of chimeras between the Chinese soft-shelled turtle and Peking duck through transfer of early blastoderm cells.

Author

Zhang W, Rui L, Zhang J, Yu X, Yuan F, Yan L, Zhang Z, Wan Z, Shao Q, Qi C, and Li Z

Subjects

Animals, Blood Vessels cytology, Cell Movement, China, Embryo, Nonmammalian blood supply, Embryo, Nonmammalian cytology, Fluorescence, Gene Expression Profiling, Gonads cytology, Organ Specificity genetics, Polymerase Chain Reaction, Trypsin metabolism, Animal Shells embryology, Blastoderm cytology, Ducks embryology, Embryo Transfer, Transplantation Chimera embryology, Turtles embryology

Abstract

Chimeras are useful models for studies of developmental biology and cell differentiation. Intraspecies and interspecies germline chimeras have been produced in previous studies, but the feasibility of producing chimeras between animals of two different classes remains unclear. To address this issue, we attempted to produce chimeras between the Chinese soft-shelled turtle and the Peking duck by transferring stage X blastoderm cells to recipient embryos. We then examined the survival and development of the PKH26-labeled donor cells in the heterologous embryos. At early embryonic stages, both turtle and duck donor cells that were labeled with PKH26 were readily observed in the brain, neural tube, heart and gonads of the respective recipient embryos. Movement of turtle donor-derived cells was observed in the duck host embryos after 48 h of incubation. Although none of the hatchlings presented a chimeric phenotype, duck donor-derived cells were detected in a variety of organs in the hatchling turtles, particularly in the gonads. Moreover, in the hatched turtles, mRNA expression of tissue-specific duck genes MEF2a and MEF2c was detected in many tissues, including the muscle, heart, small and large intestines, stomach and kidney. Similarly, SPAG6 mRNA was detected in a subset of turtle tissues, including the gonad and the small and large intestines. These results suggest that duck donor-derived cells can survive and differentiate in recipient turtles; however, no turtle-derived cells were detected in the hatched ducks. Our findings indicate that chimeras can be produced between animals of two different classes.

Published

2013

8. Neural development is dependent on the function of specificity protein 2 in cell cycle progression.

Author

Liang H, Xiao G, Yin H, Hippenmeyer S, Horowitz JM, and Ghashghaei HT

Subjects

Animals, Brain cytology, Brain embryology, Brain metabolism, Cell Count, Cell Proliferation, Crosses, Genetic, Embryo Implantation, Embryo, Mammalian cytology, Embryo, Mammalian metabolism, Embryonic Stem Cells cytology, Embryonic Stem Cells metabolism, Eye Proteins genetics, Eye Proteins metabolism, Female, Genetic Markers, Homeodomain Proteins genetics, Homeodomain Proteins metabolism, Homologous Recombination, Intermediate Filament Proteins genetics, Intermediate Filament Proteins metabolism, Mice, Mice, Inbred C57BL, Mice, Knockout, Nerve Tissue Proteins genetics, Nerve Tissue Proteins metabolism, Nestin, Neural Stem Cells cytology, Neurons cytology, Neurons metabolism, PAX6 Transcription Factor, Paired Box Transcription Factors genetics, Paired Box Transcription Factors metabolism, Repressor Proteins genetics, Repressor Proteins metabolism, Sp2 Transcription Factor genetics, Stem Cell Niche, Transplantation Chimera embryology, Transplantation Chimera metabolism, Cell Cycle, Neural Stem Cells metabolism, Neurogenesis, Sp2 Transcription Factor metabolism

Abstract

Faithful progression through the cell cycle is crucial to the maintenance and developmental potential of stem cells. Here, we demonstrate that neural stem cells (NSCs) and intermediate neural progenitor cells (NPCs) employ a zinc-finger transcription factor specificity protein 2 (Sp2) as a cell cycle regulator in two temporally and spatially distinct progenitor domains. Differential conditional deletion of Sp2 in early embryonic cerebral cortical progenitors, and perinatal olfactory bulb progenitors disrupted transitions through G1, G2 and M phases, whereas DNA synthesis appeared intact. Cell-autonomous function of Sp2 was identified by deletion of Sp2 using mosaic analysis with double markers, which clearly established that conditional Sp2-null NSCs and NPCs are M phase arrested in vivo. Importantly, conditional deletion of Sp2 led to a decline in the generation of NPCs and neurons in the developing and postnatal brains. Our findings implicate Sp2-dependent mechanisms as novel regulators of cell cycle progression, the absence of which disrupts neurogenesis in the embryonic and postnatal brain.

Published

2013

9. Germ cells are not the primary factor for sexual fate determination in goldfish.

Author

Goto R, Saito T, Takeda T, Fujimoto T, Takagi M, Arai K, and Yamaha E

Subjects

Animals, Aromatase genetics, Aromatase metabolism, DNA Primers genetics, Female, Forkhead Transcription Factors genetics, Forkhead Transcription Factors metabolism, Gene Expression Regulation, Developmental genetics, Gonads cytology, In Situ Hybridization, Male, Morpholinos genetics, Receptors, Peptide genetics, Receptors, Peptide metabolism, Receptors, Transforming Growth Factor beta genetics, Receptors, Transforming Growth Factor beta metabolism, Reverse Transcriptase Polymerase Chain Reaction, Sex Determination Processes genetics, Transplantation Chimera embryology, Gene Expression Regulation, Developmental physiology, Germ Cells physiology, Goldfish embryology, Gonads embryology, Sex Determination Processes physiology

Abstract

The presence of germ cells in the early gonad is important for sexual fate determination and gonadal development in vertebrates. Recent studies in zebrafish and medaka have shown that a lack of germ cells in the early gonad induces sex reversal in favor of a male phenotype. However, it is uncertain whether the gonadal somatic cells or the germ cells are predominant in determining gonadal fate in other vertebrate. Here, we investigated the role of germ cells in gonadal differentiation in goldfish, a gonochoristic species that possesses an XX-XY genetic sex determination system. The primordial germ cells (PGCs) of the fish were eliminated during embryogenesis by injection of a morpholino oligonucleotide against the dead end gene. Fish without germ cells showed two types of gonadal morphology: one with an ovarian cavity; the other with seminiferous tubules. Next, we tested whether function could be restored to these empty gonads by transplantation of a single PGC into each embryo, and also determined the gonadal sex of the resulting germline chimeras. Transplantation of a single GFP-labeled PGC successfully produced a germline chimera in 42.7% of the embryos. Some of the adult germline chimeras had a developed gonad on one side that contained donor derived germ cells, while the contralateral gonad lacked any early germ cell stages. Female germline chimeras possessed a normal ovary and a germ-cell free ovary-like structure on the contralateral side; this structure was similar to those seen in female morphants. Male germline chimeras possessed a testis and a contralateral empty testis that contained some sperm in the tubular lumens. Analysis of aromatase, foxl2 and amh expression in gonads of morphants and germline chimeras suggested that somatic transdifferentiation did not occur. The offspring of fertile germline chimeras all had the donor-derived phenotype, indicating that germline replacement had occurred and that the transplanted PGC had rescued both female and male gonadal function. These findings suggest that the absence of germ cells did not affect the pathway for ovary or testis development and that phenotypic sex in goldfish is determined by somatic cells under genetic sex control rather than an interaction between the germ cells and somatic cells., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

10. Identification of a novel developmental mechanism in the generation of mesothelia.

Author

Winters NI, Thomason RT, and Bader DM

Subjects

Animals, Animals, Genetically Modified, Cell Lineage, Chick Embryo, Coturnix, Embryonic Stem Cells cytology, Embryonic Stem Cells metabolism, Epithelial Cells cytology, Epithelial Cells metabolism, Epithelium metabolism, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Intestinal Mucosa metabolism, Intestines cytology, Recombinant Proteins genetics, Recombinant Proteins metabolism, Transplantation Chimera embryology, Transplantation Chimera genetics, Transplantation Chimera metabolism, Epithelium embryology, Intestines embryology

Abstract

Mesothelium is the surface layer of all coelomic organs and is crucial for the generation of their vasculature. Still, our understanding of the genesis of this essential cell type is restricted to the heart where a localized exogenous population of cells, the proepicardium, migrates to and envelops the myocardium supplying mesothelial, vascular and stromal cell lineages. Currently it is not known whether this pattern of development is specific to the heart or applies broadly to other coelomic organs. Using two independent long-term lineage-tracing studies, we demonstrate that mesothelial progenitors of the intestine are intrinsic to the gut tube anlage. Furthermore, a novel chick-quail chimera model of gut morphogenesis reveals these mesothelial progenitors are broadly distributed throughout the gut primordium and are not derived from a localized and exogenous proepicardium-like source of cells. These data demonstrate an intrinsic origin of mesothelial cells to a coelomic organ and provide a novel mechanism for the generation of mesothelial cells.

Published

2012

11. Analysis of neural crest migration and differentiation by cross-species transplantation.

Author

Griswold SL and Lwigale PY

Subjects

Animals, Cell Tracking methods, Chick Embryo, Quail, Cell Differentiation physiology, Cell Movement physiology, Neural Crest cytology, Neural Crest transplantation, Transplantation Chimera embryology, Transplantation, Heterologous methods

Abstract

Avian embryos provide a unique platform for studying many vertebrate developmental processes, due to the easy access of the embryos within the egg. Chimeric avian embryos, in which quail donor tissue is transplanted into a chick embryo in ovo, combine the power of indelible genetic labeling of cell populations with the ease of manipulation presented by the avian embryo. Quail-chick chimeras are a classical tool for tracing migratory neural crest cells (NCCs). NCCs are a transient migratory population of cells in the embryo, which originate in the dorsal region of the developing neural tube. They undergo an epithelial to mesenchymal transition and subsequently migrate to other regions of the embryo, where they differentiate into various cell types including cartilage, melanocytes, neurons and glia. NCCs are multipotent, and their ultimate fate is influenced by 1) the region of the neural tube in which they originate along the rostro-caudal axis of the embryo, 2) signals from neighboring cells as they migrate, and 3) the microenvironment of their ultimate destination within the embryo. Tracing these cells from their point of origin at the neural tube, to their final position and fate within the embryo, provides important insight into the developmental processes that regulate patterning and organogenesis. Transplantation of complementary regions of donor neural tube (homotopic grafting) or different regions of donor neural tube (heterotopic grafting) can reveal differences in pre-specification of NCCs along the rostro-caudal axis. This technique can be further adapted to transplant a unilateral compartment of the neural tube, such that one side is derived from donor tissue, and the contralateral side remains unperturbed in the host embryo, yielding an internal control within the same sample. It can also be adapted for transplantation of brain segments in later embryos, after HH10, when the anterior neural tube has closed. Here we report techniques for generating quail-chick chimeras via neural tube transplantation, which allow for tracing of migratory NCCs derived from a discrete segment of the neural tube. Species-specific labeling of the donor-derived cells with the quail-specific QCPN antibody allows the researcher to distinguish donor and host cells at the experimental end point. This technique is straightforward, inexpensive, and has many applications, including fate-mapping, cell lineage tracing, and identifying pre-patterning events along the rostro-caudal axis. Because of the ease of access to the avian embryo, the quail-chick graft technique may be combined with other manipulations, including but not limited to lens ablation, injection of inhibitory molecules, or genetic manipulation via electroporation of expression plasmids, to identify the response of particular migratory streams of NCCs to perturbations in the embryo's developmental program. Furthermore, this grafting technique may also be used to generate other interspecific chimeric embryos such as quail-duck chimeras to study NCC contribution to craniofacial morphogenesis, or mouse-chick chimeras to combine the power of mouse genetics with the ease of manipulation of the avian embryo.

Published

2012

12. Zebrafish germline chimeras produced by transplantation of ovarian germ cells into sterile host larvae.

Author

Wong TT, Saito T, Crodian J, and Collodi P

Subjects

Animals, Female, Larva physiology, Male, Germ Cells transplantation, Sex Differentiation physiology, Transplantation Chimera embryology, Zebrafish

Abstract

High frequency production of zebrafish germline chimeras was achieved by transplanting ovarian germ cells into sterile Danio hybrid recipients. Ovarian germ cells were obtained from 3-mo-old adult Tg(vasa:DsRed2-vasa);Tg(bactin:EGFP) double transgenic zebrafish by discontinuous Percoll gradient centrifugation. An average of 755 ± 108 DsRed-positive germ cells was recovered from each female. For transplantations, a total of approximately 620 ± 242 EGFP-positive cells of which 12 ± 4.7 were DsRed-positive germ cells were introduced into the abdominal cavity under the swim bladder of 2-wk-old sterile hybrid larvae. Six weeks after transplantation, a total of 10 recipients, obtained from 2 different transplantations, were examined, and 2 individuals (20%) were identified that possessed a large number of DsRed- and EGFP-positive cells in the gonadal region. The transplanted ovarian germ cells successfully colonized the gonads and differentiated into sperm in the male hybrid recipients. Of 67 adult recipients, 12 (18%) male chimeric fish reproduced and generated normal offspring when paired with wild-type zebrafish females. The fertilization efficiency ranged from 23% to 56%. Although the fertile male chimeras were generated by transplantation of ovarian germ cells, the F1 generation produced by the male chimeras contained both male and female progeny, indicating that male sex determination in zebrafish is not controlled by sex chromosome heterogamy. Our findings indicate that a population of ovarian germ cells that are present in the ovary of adult zebrafish can function as germline stem cells, able to proliferate and differentiate into testicular germ cells and functional sperm in male recipients. The high frequency of germline chimera formation achieved with the ovarian germ cells and the convenience of identifying the chimeras in the sterile host background should make this transplantation system useful for performing genetic manipulations in zebrafish.

Published

2011

13. Dechorionation of medaka embryos and cell transplantation for the generation of chimeras.

Author

Porazinski SR, Wang H, and Furutani-Seiki M

Subjects

Animals, Oryzias genetics, Transplantation Chimera genetics, Zebrafish embryology, Zebrafish genetics, Cell Transplantation methods, Chorion surgery, Oryzias embryology, Oryzias surgery, Transplantation Chimera embryology

Abstract

Medaka is a small egg-laying freshwater fish that allows both genetic and embryological analyses and is one of the three vertebrate model organisms in which genome-wide phenotype-driven mutant screens were carried out (1). Divergence of functional overlap of related genes between medaka and zebrafish allows identification of novel phenotypes that are unidentifiable in a single species (2), thus medaka and zebrafish are complementary for genetic dissection of the vertebrate genome functions. Manipulation of medaka embryos, such as dechorionation, mounting embryos for imaging and cell transplantation, are key procedures to work on both medaka and zebrafish in a laboratory. Cell transplantation examines cell autonomy of medaka mutations. Chimeras are generated by transplanting labeled cells from donor embryos into unlabeled recipient embryos. Donor cells can be transplanted to specific areas of the recipient embryos based on the fate maps (3) so that clones from transplanted cells can be integrated in the tissue of interest during development. Due to the hard chorion and soft embryos, manipulation of medaka embryos is more involved than in zebrafish. In this video, we show detailed procedures to manipulate medaka embryos.

Published

2010

14. The occipital lateral plate mesoderm is a novel source for vertebrate neck musculature.

Author

Theis S, Patel K, Valasek P, Otto A, Pu Q, Harel I, Tzahor E, Tajbakhsh S, Christ B, and Huang R

Subjects

Animals, Animals, Genetically Modified, Avian Proteins genetics, Biological Evolution, Chick Embryo, Coturnix, Gene Expression Regulation, Developmental, Mice, Mutation, Neural Crest embryology, Paired Box Transcription Factors genetics, Somites embryology, Transplantation Chimera embryology, Transplantation Chimera genetics, Mesoderm embryology, Muscle Development genetics, Neck Muscles embryology

Abstract

In vertebrates, body musculature originates from somites, whereas head muscles originate from the cranial mesoderm. Neck muscles are located in the transition between these regions. We show that the chick occipital lateral plate mesoderm has myogenic capacity and gives rise to large muscles located in the neck and thorax. We present molecular and genetic evidence to show that these muscles not only have a unique origin, but additionally display a distinct temporal development, forming later than any other muscle group described to date. We further report that these muscles, found in the body of the animal, develop like head musculature rather than deploying the programme used by the trunk muscles. Using mouse genetics we reveal that these muscles are formed in trunk muscle mutants but are absent in head muscle mutants. In concordance with this conclusion, their connective tissue is neural crest in origin. Finally, we provide evidence that the mechanism by which these neck muscles develop is conserved in vertebrates.

Published

2010

15. Tissue targeted embryonic chimeras: zebrafish gastrula cell transplantation.

Author

Deschene ER and Barresi MJ

Subjects

Animals, Embryo, Nonmammalian transplantation, Fluorescent Dyes chemistry, Fluorescent Dyes metabolism, Gastrula metabolism, Microinjections methods, Microscopy, Confocal, Organic Chemicals chemistry, Organic Chemicals metabolism, Transplantation Chimera embryology, Cell Transplantation methods, Embryo Transfer methods, Gastrula cytology, Zebrafish embryology

Abstract

Certain fundamental questions in the field of developmental biology can only be answered when cells are placed in novel environments or when small groups of cells in a larger context are altered. Watching how one cell interacts with and behaves in a unique environment is essential to characterizing cell functions. Determining how the localized misexpression of a specific protein influences surrounding cells provides insightful information on the roles that protein plays in a variety of developmental processes. Our lab uses the zebrafish model system to uniquely combine genetic approaches with classical transplantation techniques to generate genotypic or phenotypic chimeras. We study neuron-glial cell interactions during the formation of forebrain commissures in zebrafish. This video describes a method that allows our lab to investigate the role of astroglial populations in the diencephalon and the roles of specific guidance cues that influence projecting axons as they cross the midline. Due to their transparency zebrafish embryos are ideal models for this type of ectopic cell placement or localized gene misexpression. Tracking transplanted cells can be accomplished using a vital dye or a transgenic fish line expressing a fluorescent protein. We demonstrate here how to prepare donor embryos with a vital dye tracer for transplantation, as well as how to extract and transplant cells from one gastrula staged embryo to another. We present data showing ectopic GFP+ transgenic cells within the forebrain of zebrafish embryos and characterize the location of these cells with respect to forebrain commissures. In addition, we show laser scanning confocal timelapse microscopy of Alexa 594 labeled cells transplanted into a GFP+ transgenic host embryo. These data provide evidence that gastrula staged transplantation enables the targeted positioning of ectopic cells to address a variety of questions in Developmental Biology.

Published

2009

16. Generating chimeric zebrafish embryos by transplantation.

Author

Kemp HA, Carmany-Rampey A, and Moens C

Subjects

Animals, Blastula transplantation, Embryo Transfer, Embryo, Nonmammalian cytology, Female, Gastrula transplantation, Zebrafish genetics, Cell Transplantation methods, Transplantation Chimera embryology, Zebrafish embryology

Abstract

One of the most powerful tools used to gain insight into complex developmental processes is the analysis of chimeric embryos. A chimera is defined as an organism that contains cells from more than one animal; mosaics are one type of chimera in which cells from more than one genotype are mixed, usually wild-type and mutant. In the zebrafish, chimeras can be readily made by transplantation of cells from a donor embryo into a host embryo at the appropriate embryonic stage. Labeled donor cells are generated by injection of a lineage marker, such as a fluorescent dye, into the one-cell stage embryo. Labeled donor cells are removed from donor embryos and introduced into unlabeled host embryos using an oil-controlled glass pipette mounted on either a compound or dissecting microscope. Donor cells can in some cases be targeted to a specific region or tissue of the developing blastula or gastrula stage host embryo by choosing a transplantation site in the host embryo based on well-established fate maps.

Published

2009

17. Human immature dental pulp stem cells' contribution to developing mouse embryos: production of human/mouse preterm chimaeras.

Author

Siqueira da Fonseca SA, Abdelmassih S, de Mello Cintra Lavagnolli T, Serafim RC, Clemente Santos EJ, Mota Mendes C, de Souza Pereira V, Ambrosio CE, Miglino MA, Visintin JA, Abdelmassih R, Kerkis A, and Kerkis I

Subjects

Adult Stem Cells transplantation, Animal Structures cytology, Animal Structures embryology, Animal Structures metabolism, Animals, Blastocyst cytology, Cell Differentiation physiology, Chromosomes, Human, Y chemistry, Embryo Transfer, Embryo, Mammalian embryology, Epithelial Cells cytology, Epithelial Cells metabolism, Epithelium embryology, Epithelium metabolism, Female, Fetus embryology, Fetus metabolism, Humans, In Situ Hybridization, Fluorescence, Male, Mice, Mice, Inbred Strains, Muscle Cells cytology, Muscle Cells metabolism, Muscles cytology, Muscles embryology, Muscles metabolism, Transplantation Chimera metabolism, Adult Stem Cells cytology, Dental Pulp cytology, Embryo, Mammalian cytology, Embryonic Development physiology, Fetus cytology, Transplantation Chimera embryology

Abstract

Objectives: In this study, we aimed at determining whether human immature dental pulp stem cells (hIDPSC) would be able to contribute to different cell types in mouse blastocysts without damaging them. Also, we analysed whether these blastocysts would progress further into embryogenesis when implanted to the uterus of foster mice, and develop human/mouse chimaera with retention of hIDPSC derivates and their differentiation., Materials and Methods: hIDPSC and mouse blastocysts were used in this study. Fluorescence staining of hIDPSC and injection into mouse blastocysts, was performed. Histology, immunohistochemistry, fluorescence in situ hybridization and confocal microscopy were carried out., Results and Conclusion: hIDPSC showed biological compatibility with the mouse host environment and could survive, proliferate and contribute to the inner cell mass as well as to the trophoblast cell layer after introduction into early mouse embryos (n = 28), which achieved the hatching stage following 24 and 48 h in culture. When transferred to foster mice (n = 5), these blastocysts with hIDPSC (n = 57) yielded embryos (n = 3) and foetuses (n = 6); demonstrating presence of human cells in various organs, such as brain, liver, intestine and hearts, of the human/mouse chimaeras. We verified whether hIDPSC would also be able to differentiate into specific cell types in the mouse environment. Contribution of hIDPSC in at least two types of tissues (muscles and epithelial), was confirmed. We showed that hIDPSC survived, proliferated and differentiated in mouse developing blastocysts and were capable of producing human/mouse chimaeras.

Published

2009

18. Directing pathfinding along the dorsolateral path - the role of EDNRB2 and EphB2 in overcoming inhibition.

Author

Harris ML, Hall R, and Erickson CA

Subjects

Animals, Animals, Genetically Modified, Base Sequence, Body Patterning genetics, Body Patterning physiology, Cell Movement, Cell Survival, Chick Embryo, Coturnix, DNA Primers genetics, Gene Expression Regulation, Developmental, Melanocytes cytology, Melanocytes physiology, Models, Neurological, Neural Crest cytology, Proto-Oncogene Proteins c-kit genetics, Proto-Oncogene Proteins c-kit physiology, RNA, Small Interfering genetics, Receptor, EphB2 genetics, Receptors, Endothelin genetics, Signal Transduction, Transplantation Chimera embryology, Neural Crest embryology, Receptor, EphB2 physiology, Receptors, Endothelin physiology

Abstract

Neural crest cells that become pigment cells migrate along a dorsolateral route between the ectoderm and the somite, whereas most other neural crest cells are inhibited from entering this space. This pathway choice has been attributed to unique, cell-autonomous migratory properties acquired by neural crest cells when they become specified as melanoblasts. By shRNA knockdown and overexpression experiments, we investigated the roles of three transmembrane receptors in regulating dorsolateral pathfinding in the chick trunk. We show that Endothelin receptor B2 (EDNRB2) and EphB2 are both determinants in this process, and that, unlike in other species, c-KIT is not. We demonstrate that the overexpression of EDNRB2 can maintain normal dorsolateral migration of melanoblasts in the absence of EphB2, and vice versa, suggesting that changes in receptor expression levels regulate the invasion of this pathway. Furthermore, by heterotopic grafting, we show that neural crest cell populations that do not rely on the activation of these receptors can migrate dorsolaterally only if this path is free of inhibitory molecules. We conclude that the requirement for EDNRB2 and EphB2 expression by melanoblasts is to support their migration by helping them to overcome repulsive or non-permissive cues in the dorsolateral environment.

Published

2008

19. Reproduction of wild birds via interspecies germ cell transplantation.

Author

Kang SJ, Choi JW, Kim SY, Park KJ, Kim TM, Lee YM, Kim H, Lim JM, and Han JY

Subjects

Animals, Animals, Wild, Chick Embryo, Embryo, Nonmammalian cytology, Female, Galliformes embryology, Male, Spermatozoa cytology, Transplantation, Heterologous, Breeding methods, Galliformes physiology, Germ Cells transplantation, Reproductive Techniques, Assisted, Transplantation Chimera embryology

Abstract

The present study was conducted to apply an interspecies germ cell transfer technique to wild bird reproduction. Pheasant (Phasianus colchicus) primordial germ cells (PGCs) retrieved from the gonads of 7-day-old embryos were transferred to the bloodstream of 2.5-day-old chicken (Gallus gallus) embryos. Pheasant-to-chicken germline chimeras hatched from the recipient embryos, and 10 pheasants were derived from testcross reproduction of the male chimeras with female pheasants. Gonadal migration of the transferred PGCs, their involvement in spermatogenesis, and production of chimeric semen were confirmed. The phenotype of pheasant progenies derived from the interspecies transfer was identical to that of wild pheasants. The average efficiency of reproduction estimated from the percentage of pheasants to total progenies was 17.5%. In conclusion, interspecies germ cell transfer into a developing embryo can be used for wild bird reproduction, and this reproductive technology may be applicable in conserving endangered bird species.

Published

2008

20. Neonatal chimerization with human glial progenitor cells can both remyelinate and rescue the otherwise lethally hypomyelinated shiverer mouse.

Author

Windrem MS, Schanz SJ, Guo M, Tian GF, Washco V, Stanwood N, Rasband M, Roy NS, Nedergaard M, Havton LA, Wang S, and Goldman SA

Subjects

Adult Stem Cells metabolism, Agenesis of Corpus Callosum, Animals, Animals, Newborn abnormalities, Animals, Newborn embryology, Cell- and Tissue-Based Therapy, Corpus Callosum embryology, Corpus Callosum metabolism, Demyelinating Diseases congenital, Demyelinating Diseases therapy, Humans, Immunocompromised Host, Mice, Myelin Sheath genetics, Neural Conduction, Neuroglia metabolism, Ranvier's Nodes metabolism, Ranvier's Nodes transplantation, Tissue Distribution, Transplantation Chimera embryology, Adult Stem Cells transplantation, Corpus Callosum transplantation, Myelin Sheath metabolism, Myelin Sheath transplantation, Neuroglia transplantation, Stem Cell Transplantation

Abstract

Congenitally hypomyelinated shiverer mice fail to generate compact myelin and die by 18-21 weeks of age. Using multifocal anterior and posterior fossa delivery of sorted fetal human glial progenitor cells into neonatal shiverer x rag2(-/-) mice, we achieved whole neuraxis myelination of the engrafted hosts, which in a significant fraction of cases rescued this otherwise lethal phenotype. The transplanted mice exhibited greatly prolonged survival with progressive resolution of their neurological deficits. Substantial myelination in multiple regions was accompanied by the acquisition of normal nodes of Ranvier and transcallosal conduction velocities, ultrastructurally normal and complete myelination of most axons, and a restoration of a substantially normal neurological phenotype. Notably, the resultant mice were cerebral chimeras, with murine gray matter but a predominantly human white matter glial composition. These data demonstrate that the neonatal transplantation of human glial progenitor cells can effectively treat disorders of congenital and perinatal hypomyelination.

Published

2008

21. Persistence of allografts in the peritoneal cavity after prenatal transplantation in mice.

Author

Chen JC, Chang ML, and Muench MO

Subjects

Animals, Bone Marrow Transplantation methods, Female, Fetus surgery, Graft Survival physiology, Injections, Intraperitoneal, Male, Mice, Mice, Inbred C57BL, Mice, Inbred DBA, Mice, Inbred Strains, Pregnancy, Transplantation Chimera embryology, Peritoneal Cavity, Transplantation Chimera physiology, Transplantation, Homologous physiology

Abstract

Background: In utero transplantation (IUT) is usually performed by intraperitoneal injection, but there is little information regarding the fate of intraperitoneally transplanted cells in the first weeks after transplantation., Study Design and Methods: Fetal transplantation was performed in a B6D2F(1) (C57BL/6 x DBA/2, H-2(b)/(d)) into C57BL/6 (H-2(b)) murine strain combination at the gestational age of 13 days by intraperitoneal injection of light-density marrow cells. Adult C57BL/6 mice were used as the postnatal transplantation group. Donor cell levels in the peritoneum, peripheral blood, and various hematopoietic tissues were examined by flow cytometry., Results: After fetal transplantation, peritoneal chimerism could be detected for 4 weeks, ranging from 0.02 to 23.2 percent with the highest median chimerism at 2 weeks after transplantation. Donor cells in the peripheral blood, spleen, marrow, liver, and thymus were usually low (<0.2%) with a tendency for higher donor cell levels at 2 weeks after transplantation. Engraftment in fetal peritoneum was primarily by myeloid and B cells with few T cells. In contrast, adult mice transplanted with haplogeneic marrow cleared nearly all donor cells from the peritoneum within a week of transplant. There was no evidence showing that donor cells had ever migrated to any hematopoietic tissues after adult transplantation., Conclusion: Despite limited engraftment in hematopoietic tissues, donor cells persisted in the peritoneum for 2 weeks or longer after fetal transplantation. The fetal peritoneum may serve as a sanctuary for foreign cells in the fetus, which may aid the development of novel cellular therapies for birth defects.

Published

2008

22. Extensive contribution of embryonic stem cells to the development of an evolutionarily divergent host.

Author

Xiang AP, Mao FF, Li WQ, Park D, Ma BF, Wang T, Vallender TW, Vallender EJ, Zhang L, Lee J, Waters JA, Zhang XM, Yu XB, Li SN, and Lahn BT

Subjects

Animals, Animals, Genetically Modified, Base Sequence, Biological Evolution, Blastocyst cytology, Cell Differentiation, DNA Primers genetics, Embryonic Development genetics, Embryonic Stem Cells transplantation, Female, Germ Cells, Green Fluorescent Proteins genetics, Male, Mice, Murinae embryology, Murinae genetics, Organ Specificity, Phylogeny, Polymerase Chain Reaction, Pregnancy, Recombinant Proteins genetics, Species Specificity, Teratoma genetics, Teratoma pathology, Transplantation Chimera embryology, Transplantation, Heterologous, Embryonic Stem Cells cytology, Transplantation Chimera genetics

Abstract

The full potential of embryonic stem (ES) cells to generate precise cell lineages and complex tissues can be best realized when they are differentiated in vivo-i.e. in developing blastocysts. Owing to various practical and ethical constraints, however, it is impossible to introduce ES cells of certain species into blastocysts of the same species. One solution is to introduce ES cells into blastocysts of a different species. However, it is not known whether ES cells can contribute extensively to chimerism when placed into blastocysts of a distantly related species. Here, we address this question using two divergent species, Apodemus sylvaticus and Mus musculus, whose genome sequence differs by approximately 18% from each other. Despite this considerable evolutionary distance, injection of Apodemus ES cells into Mus blastocysts led to viable chimeras bearing extensive Apodemus contributions to all major organs, including the germline, with Apodemus contribution reaching approximately 40% in some tissues. Immunostaining showed that Apodemus ES cells have differentiated into a wide range of cell types in the chimeras. Our results thus provide a proof of principle for the feasibility of differentiating ES cells into a wide range of cell types and perhaps even complex tissues by allowing them to develop in vivo in an evolutionarily divergent host-a strategy that may have important applications in research and therapy. Furthermore, our study demonstrates that mammalian evolution can proceed at two starkly contrasting levels: significant divergence in genome and proteome sequence, yet striking conservation in developmental programs.

Published

2008

23. Prenatal tolerance induction: relationship between cell dose, marrow T-cells, chimerism, and tolerance.

Author

Chen JC, Chang ML, Huang SF, Chang PY, Muench MO, Fu RH, Ou LS, and Kuo ML

Subjects

Animals, Cell Count, Clonal Deletion, Female, Graft Survival immunology, Lymphocyte Depletion, Mice, Mice, Inbred BALB C, Mice, Inbred C57BL, Predictive Value of Tests, Pregnancy, T-Lymphocytes cytology, Transplantation Chimera embryology, Transplantation Immunology, Bone Marrow Transplantation immunology, Immune Tolerance, Skin Transplantation immunology, T-Lymphocytes immunology, Transplantation Chimera immunology, Transplantation Conditioning

Abstract

It was reported that the dose of self-antigens can determine the consequence of deletional tolerance and donor T cells are critical for tolerance induction in mixed chimeras. This study aimed at assessing the effect of cell doses and marrow T cells on engraftment and tolerance induction after prenatal bone marrow transplantation. Intraperitoneal cell transplantation was performed in FVB/N (H-2K(q)) mice at gestational day 14 with escalating doses of adult C57BL/6 (H-2K(b)) marrows. Peripheral chimerism was examined postnatally by flow cytometry and tolerance was tested by skin transplantation. Transplantation of light-density marrow cells showed a dose response. High-level chimerism emerged with a threshold dose of 5.0 x 10(6) and host leukocytes could be nearly replaced at a dose of 7.5-10.0 x 10(6). High-dose transplants conferred a steady long-lasting donor-specific tolerance but were accompanied by >50% incidence of graft-versus-host disease. Depletion of marrow T cells lessened graft-versus-host disease to the detriment of engraftment. With low-level chimerism, tolerance was a graded phenomenon dependent upon the level of chimerism. Durable chimerism within 6 months required a threshold of > or = 2% chimerism at 1 month of age and predicted a 50% chance of long-term tolerance, whereas transient chimerism (<2%) only caused hyporesponsiveness to the donor. Tolerance induction did not succeed without peripheral chimerism even if a large amount of injected donor cells persisted in the peritoneum. Neither did an increase in cell doses or donor T-cell contents benefit skin graft survivals unless it had substantially improved peripheral chimerism. Thus, peripheral chimerism level can be a simple and straightforward test to predict the degree of prenatal immune tolerance.

Published

2008

24. Quail-chick transplantations.

Author

Le Douarin N, Dieterlen-Lièvre F, Creuzet S, and Teillet MA

Subjects

Animals, Electroporation methods, Models, Biological, Species Specificity, Staining and Labeling instrumentation, Staining and Labeling methods, Transplantation, Heterologous instrumentation, Transplantation, Heterologous veterinary, Chick Embryo transplantation, Coturnix embryology, Transplantation Chimera embryology, Transplantation, Heterologous methods

Published

2008

25. Other chimeras: quail-duck and mouse-chick.

Author

Lwigale PY and Schneider RA

Subjects

Animals, Chick Embryo, Cleavage Stage, Ovum cytology, Coturnix surgery, Ducks surgery, Embryo, Mammalian surgery, Embryo, Nonmammalian surgery, Mice surgery, Models, Biological, Transplantation Chimera growth & development, Coturnix embryology, Ducks embryology, Mice embryology, Transplantation Chimera embryology, Transplantation, Heterologous methods

Published

2008

26. Pre-/post-otic rhombomeric interactions control the emergence of a fetal-like respiratory rhythm in the mouse embryo.

Author

Borday C, Coutinho A, Germon I, Champagnat J, and Fortin G

Subjects

Action Potentials physiology, Animals, Body Patterning physiology, Brain Tissue Transplantation methods, Branchial Region physiology, Chick Embryo, Cranial Nerves embryology, Cranial Nerves physiology, Efferent Pathways physiology, Embryonic Development physiology, Mice, Respiratory Center physiology, Rhombencephalon physiology, Species Specificity, Spinal Cord physiology, Transplantation Chimera embryology, Transplantation Chimera physiology, Branchial Region embryology, Efferent Pathways embryology, Respiration, Respiratory Center embryology, Rhombencephalon embryology, Spinal Cord embryology

Abstract

How regional patterning of the neural tube in vertebrate embryos may influence the emergence and the function of neural networks remains elusive. We have begun to address this issue in the embryonic mouse hindbrain by studying rhythmogenic properties of different neural tube segments. We have isolated pre- and post-otic hindbrain segments and spinal segments of the mouse neural tube, when they form at embryonic day (E) 9, and grafted them into the same positions in stage-matched chick hosts. Three days after grafting, in vitro recordings of the activity in the cranial nerves exiting the grafts indicate that a high frequency (HF) rhythm (order: 10 bursts/min) is generated in post-otic segments while more anterior pre-otic and more posterior spinal territories generate a low frequency (LF) rhythm (order: 1 burst/min). Comparison with homo-specific grafting of corresponding chick segments points to conservation in mouse and chick of the link between the patterning of activities and the axial origin of the hindbrain segment. This HF rhythm is reminiscent of the respiratory rhythm known to appear at E15 in mice. We also report on pre-/post-otic interactions. The pre-otic rhombomere 5 prevents the emergence of the HF rhythm at E12. Although the nature of the interaction with r5 remains obscure, we propose that ontogeny of fetal-like respiratory circuits relies on: (i) a selective developmental program enforcing HF rhythm generation, already set at E9 in post-otic segments, and (ii) trans-segmental interactions with pre-otic territories that may control the time when this rhythm appears., ((c) 2006 Wiley Periodicals, Inc.)

Published

2006

27. p63 regulates commitment to the prostate cell lineage.

Author

Signoretti S, Pires MM, Lindauer M, Horner JW, Grisanzio C, Dhar S, Majumder P, McKeon F, Kantoff PW, Sellers WR, and Loda M

Subjects

Animals, Epithelial Cells metabolism, Epithelial Cells physiology, Female, Histocytochemistry, Male, Mice, Mice, Knockout, Prostate embryology, Stem Cells physiology, Transplantation Chimera embryology, Urothelium embryology, beta-Galactosidase, Cell Differentiation physiology, Cell Lineage physiology, Phosphoproteins physiology, Prostate cytology, Trans-Activators physiology

Abstract

Molecular mechanisms underlying prostate and urothelial development remain unclear. This situation presents major limitations in identifying the cell type(s) and molecular events involved in the development of prostate and bladder cancer. It has been shown that mice lacking the basal cell marker p63 present several epithelial defects, including epidermis and prostate buds agenesis and urothelial abnormalities. Here, we use the p63-/- mouse as a tool to define cell lineages in the prostate epithelium and urothelium. By complementing p63-/- blastocysts with p63+/+ beta-galactosidase (beta-gal)-positive ES cells, we show that secretory cells of the prostate originate from p63-positive basal progenitor cells. Importantly, our urogenital sinus transplantation studies demonstrate that p63 prevents intestinal differentiation of the urogenital sinus endoderm and is therefore required to maintain commitment to the prostate cell lineage. Finally, in contrast with the prostate findings, analysis of the urothelium from rescued p63-/- chimeras shows that umbrella (superficial) cells can develop and be maintained independently from p63-positive basal and intermediate cells.

Published

2005

28. In utero hematopoietic stem cell transplantation with haploidentical donor adult bone marrow in a canine model.

Author

Blakemore K, Hattenburg C, Stetten G, Berg K, South S, Murphy K, and Jones R

Subjects

Animals, Antigens, CD34 immunology, Dogs, Female, Graft Survival, Humans, Male, Pregnancy, Fetal Diseases diet therapy, Hematopoietic Stem Cell Transplantation methods, Models, Animal, Transplantation Chimera embryology

Abstract

Objective: Chimerism can be achieved in a canine model of in utero bone marrow transplantation with > or =1 x 10(8) CD34(+) haploidentical donor cells per kilogram without graft-versus-host disease., Study Design: In utero bone marrow transplantation was performed by ultrasound-guided intraperitoneal infusion in 30- to 41-day-old canines with CD34(+) selected cells from paternal bone marrow at doses of 1.3 x 10(8) to 2.5 x 10(10) CD34(+) cells/kg. A method for marking control littermates was developed with intraperitoneal ethiodol. Postnatal studies included histologic, fluorescent in situ hybridization canine Y probe, and polymerase chain reaction-based chimerism analyses., Results: Term survival was 86% to 100% for transplantations > or =34 days versus 14% and 43% at 30 and 31 days. Microchimerism (<1%) was demonstrated in tissues from 4 informative litters that included thymus, liver, skin, spleen, and intestine. Neither gestational age nor donor CD34 cell dosage altered the level of engraftment in these experiments. There was no evidence of graft-versus-host disease., Conclusion: In utero bone marrow transplantation in a canine model achieves microchimerism with high CD34(+) cell doses.

Published

2004

29. Green fluorescent protein gene-transfected peafowl somatic cells participate in the development of chicken embryos.

Author

Xi Y, Nada Y, Soh T, Fujihara N, and Hattori MA

Subjects

Animals, Birds embryology, Cell Fusion, Cells, Cultured, Chick Embryo, DNA Primers, DNA, Mitochondrial genetics, Electroporation, Green Fluorescent Proteins, Immunohistochemistry, Lewis X Antigen, Polymerase Chain Reaction, Transfection, Transplantation Chimera genetics, Birds genetics, Luminescent Proteins genetics, Transplantation Chimera embryology

Abstract

This study was performed to investigate whether the embryonic somatic cells are capable of reconstituting and participating in the embryonic development of chickens to produce chimeras. In order to track the migration behavior of the donor cells, a cell line, originally isolated from an Indian peafowl embryo, was fluorescent-labeled by transfection of the cells with enhanced Green Fluorescent Protein (GFP) and Neomycin resistant (Neo) genes prior to injection into the stage X blastoderm of White Leghorn chickens. The injection was performed with a medium in the presence of 1-5% polyethylene glycol. The development of putative chimeric embryos between the stages three and 24 was examined for GFP expression under fluorescent light. To trace the peafowl cells in the developing chicken embryos, both a species-specific genetic marker originating from the mitochondrial DNA cytochrome b (cyt b) gene and a DNA fragment of GFP gene were used. Of the 185 fertile eggs manipulated, 173 developed into embryos. Fifty-five of them showed positive GFP patches in extra-embryonic tissues, and 15 expressed GFP in intra-embryonic tissues such as those of the head, heart, and gonad. PCR analysis revealed that PCR fragments for the peafowl mitochondrial DNA cyt b and GFP genes were detected in the samples of the GFP positive extra- and intra-embryonic tissues of the chimeras. The present results provide evidence that fluorescent-labeled peafowl embryonic cells carrying GFP and Neo genes are able to participate in the development of chicken embryos to generate chimeras., (Copyright 2004 Wiley-Liss, Inc.)

Published

2004

30. Neural crest cells provide species-specific patterning information in the developing branchial skeleton.

Author

Tucker AS and Lumsden A

Subjects

Animals, Endoderm physiology, Histological Techniques, Immunohistochemistry, Neural Crest physiology, Species Specificity, Transplantation Chimera embryology, Body Patterning, Branchial Region embryology, Coturnix embryology, Ducks embryology, Neural Crest embryology

Abstract

The skeletal elements of the branchial region are made by neural crest cells, following tissue interactions with the pharyngeal endoderm. Previous transplantation experiments have claimed that the cranial neural crest is morphogenetically prespecified in respect of its branchial skeletal derivatives, that is, that information for the number, size, shape, and position of its individual elements is already determined in these cells when they are still in the neural folds. This positional information would somehow be preserved during delamination from the neural tube and migration into the branchial arches, before being read out as a spatial pattern of chondrogenesis and osteogenesis. However, it now appears that signals from the endoderm are able to specify not only the histogenic differentiation state of neural crest cells but also the identity and orientation of the branchial skeletal elements. It is therefore important to ask whether fine details of branchial skeletal pattern such as those that exist between different species are also governed by extrinsic factors, such as the endoderm, or by the neural crest itself. We have grafted neural crest between duck and quail embryos and show that the shape and size of the resulting skeletal elements is donor derived. The ability to form species-specific patterns of craniofacial skeletal tissue thus appears to be an inherent property of the neural crest, expressed as species-specific responses to endodermal signals.

Published

2004

31. Complete allogeneic hematopoietic chimerism achieved by a combined strategy of in utero hematopoietic stem cell transplantation and postnatal donor lymphocyte infusion.

Author

Hayashi S, Peranteau WH, Shaaban AF, and Flake AW

Subjects

Animals, Animals, Newborn, Female, Graft Survival, Immune Tolerance, Mice, Mice, Inbred BALB C, Models, Animal, Pregnancy, Thymus Gland embryology, Thymus Gland immunology, Transplantation, Homologous methods, Fetal Diseases therapy, Hematopoietic Stem Cell Transplantation methods, Lymphocyte Transfusion, Transplantation Chimera embryology

Abstract

In utero hematopoietic stem cell transplantation (IUHSCTx) can achieve mixed hematopoietic chimerism and donor-specific tolerance without cytoreductive conditioning or immunosuppression. The primary limitation to the clinical application of IUHSCTx has been minimal donor cell engraftment, well below therapeutic levels for most target diseases. Donor lymphocyte infusion (DLI) has been used in postnatal circumstances of mixed chimerism as targeted immunotherapy to achieve a graft-versus-hematopoietic effect and to increase levels of donor cell engraftment. In this report we demonstrate in the murine model that a combined approach of IUHSCTx followed by postnatal DLI can convert low-level, mixed hematopoietic chimerism to complete donor chimerism across full major histocompatibility complex barriers with minimal risk for graft-versus-host disease (GVHD). Time-dated embryonic day 14 (E14) to E15 Balb/c (H-2K(d), CD45.2) fetuses underwent intraperitoneal injection of 5 x 10(6) T-cell-depleted B6 (H-2K(b), CD45.2) bone marrow cells. Chimeric recipients then received transplants at either 4 or 8 weeks of age with 1 of 3 doses (5, 15, or 30 x 10(6) cells) of donor congenic splenocytes (B6-Ly5.2/Cr, H-2K(b), CD45.1). The response to DLI was dose dependent, with conversion to complete donor peripheral blood chimerism in 100% of animals that received high-dose (30 x 10(6) cells) DLI. Only 1 of 56 animals receiving this dose succumbed to GVHD. This study directly supports the potential therapeutic strategy of prenatal tolerance induction to facilitate nontoxic postnatal cellular therapy and organ transplantation, and it has broad implications for the potential treatment of prenatally diagnosed genetic disorders.

Published

2002

32. Neuroectodermal origin of brain pericytes and vascular smooth muscle cells.

Author

Korn J, Christ B, and Kurz H

Subjects

Actins metabolism, Animals, Blood Vessels metabolism, Blood Vessels ultrastructure, Body Patterning physiology, Brain blood supply, Brain Tissue Transplantation methods, Chick Embryo, Coturnix, Ectoderm metabolism, Ectoderm transplantation, Fluorescent Antibody Technique, Graft Survival physiology, Head blood supply, Head embryology, Limb Buds blood supply, Limb Buds embryology, Limb Buds transplantation, Mesoderm metabolism, Mesoderm transplantation, Mesoderm ultrastructure, Microscopy, Confocal, Microscopy, Electron, Muscle, Smooth, Vascular metabolism, Muscle, Smooth, Vascular transplantation, Neural Crest embryology, Neural Crest transplantation, Neural Crest ultrastructure, Pericytes metabolism, Pericytes transplantation, Stem Cell Transplantation, Stem Cells metabolism, Stem Cells ultrastructure, Sulfotransferases metabolism, Transplantation, Heterotopic methods, Blood Vessels embryology, Brain embryology, Cell Differentiation physiology, Cell Lineage physiology, Ectoderm ultrastructure, Muscle, Smooth, Vascular ultrastructure, Pericytes ultrastructure, Transplantation Chimera embryology

Abstract

The origin of vascular pericytes (PCs) and smooth muscle cells (vSMCs) in the brain has hitherto remained an open question. In the present study, we used the quail-chick chimerization technique to elucidate the lineage of cranial PCs/vSMCs. We transplanted complete halves of brain anlagen, or dorsal (presumptive neural crest [NC]) or ventral cranial neural tube. Additional experiments included transplantations of neuroectoderm into limb mesenchyme, and of head mesoderm or limb mesenchyme into paraxial head mesoderm. After interspecific transplantation of quail brain rudiment, graft-derived vSMCs were found in the vessel walls of the grafted brain. Notably, transplanted ventral neural tube also gave rise to vSMCs. After grafting of quail head mesoderm, quail endothelial cells were found in the host brain, but no vSMCs of donor origin. Grafting of quail whole or ventral neural tube into the limb bud led to endowment of graft and host vessels with graft-derived vSMCs. Quail limb bud mesenchyme contributed to vSMCs in the ectopic neural graft, but, when transplanted into paraxial head mesenchyme, it did not form intraneural vSMCs. After orthotopic transplantation of cranial NC, graft-derived vSMCs were not only found in meninges and brain of the operated side, but also on the contralateral side. Our results show that 1) avian cranial neuroectoderm is able to differentiate into vSMCs of the brain; 2) this potential is not restricted to the prospective NC; and 3) neither cranial mesoderm nor cranially transplanted limb bud mesoderm can give rise to brain vSMC., (Copyright 2002 Wiley-Liss, Inc.)

Published

2002

33. Monkey embryonic stem cell lines expressing green fluorescent protein.

Author

Takada T, Suzuki Y, Kondo Y, Kadota N, Kobayashi K, Nito S, Kimura H, and Torii R

Subjects

Animals, Biomarkers, Cell Culture Techniques trends, Cell Differentiation physiology, Cell Line cytology, Cell Line transplantation, Embryo, Mammalian cytology, Embryo, Mammalian metabolism, Germ Layers cytology, Germ Layers metabolism, Green Fluorescent Proteins, Macaca fascicularis, Mice, Mice, SCID, Myocytes, Cardiac cytology, Myocytes, Cardiac metabolism, Neurons cytology, Neurons metabolism, Pluripotent Stem Cells cytology, Pluripotent Stem Cells transplantation, Stem Cell Transplantation trends, Teratoma metabolism, Teratoma pathology, Transplantation Chimera embryology, Transplantation Chimera metabolism, Cell Culture Techniques methods, Cell Line metabolism, Luminescent Proteins biosynthesis, Pluripotent Stem Cells metabolism, Stem Cell Transplantation methods

Abstract

The major limitation of nonhuman primate (NHP) embryonic stem (ES) cell research is inefficient genetic modification and limited knowledge of differentiation mechanisms. A genetically modified NHP-ES cell with biomarkers, such as green fluorescent protein (GFP), that allow noninvasive monitoring of transgenic cells, is a useful tool to study cell differentiation control during preimplantation and fetal development, which also plays a crucial role in the development of cell transplantation medicine. Here we report the establishment of transgenic NHP-ES cell lines that express GFP without jeopardizing their pluripotency, which was confirmed by in vitro and in vivo differentiation. These GFP-expressing ES cells reproducibly differentiated into embryoid bodies, neural cells, and cardiac myocytes. They formed teratoma composed of tissues derived from the three embryonic germ layers when transplanted into severe combined immunodeficient disease (SCID) mice. GFP expression was maintained in these differentiated cells, suggesting that these cells were useful for cell transplantation experiments. Furthermore, we showed that these ES cells have the ability to form chimeric blastocysts by introducing into the early preimplantation stage NHP embryo.

Published

2002

34. Fate map of the avian anterior forebrain at the four-somite stage, based on the analysis of quail-chick chimeras.

Author

Cobos I, Shimamura K, Rubenstein JL, Martínez S, and Puelles L

Subjects

Animals, Brain Tissue Transplantation, Cell Differentiation, Cell Movement, Chick Embryo, Diencephalon cytology, Diencephalon embryology, Gene Expression Regulation, Developmental, Immunohistochemistry, In Situ Hybridization, Morphogenesis, RNA, Messenger analysis, RNA, Messenger genetics, Retina cytology, Retina embryology, Telencephalon cytology, Telencephalon embryology, Cell Lineage, Prosencephalon cytology, Prosencephalon embryology, Quail embryology, Somites cytology, Transplantation Chimera embryology

Abstract

To better understand the topological organization of the primordia within the anterior forebrain, we made a fate map of the rostral neural plate in the chick. Homotopic grafts at the four-somite stage were allowed to survive for up to 9 days to enable an analysis of definitive brain structures. In some cases, the topography of the grafted neuroepithelia was compared with gene expression patterns. The midpoint of the anterior neural ridge maps upon the anterior commissure in the closed neural tube, continuing concentrically into the preoptic area and optic field. Non-neural epithelium just in front of this median ridge gives rise to the adenohypophysis. Areas for the presumptive pallial commissure, septum, and prosencephalic choroidal tissue lie progressively more posteriorly along the ridge, peripheral to the telencephalic entopeduncular and striatopallidal primordia (the subpallium), and the pallium (olfactory bulb, dorsal ventricular ridge, and cortical domains). Subpallial structures lie topologically anterior to the pallial formations, and both are concentric to the septum. Within the pallium, the major cortical domains (Wulst and caudolateral, parahippocampal, and hippocampal cortices) appear posterior to the dorsal ventricular ridge. The amygdaloid region appears concentrically across both the subpallial and pallial regions. This fate map shows that the arrangement of the prospective primordia in the neural plate is basically a flattened representation of topological relationships present in the mature brain, though marked phenomena of differential growth and selective tangential migration of some cell populations complicate the histogenetic constitution of the mature telencephalon., (Copyright 2001 Academic Press.)

Published

2001

35. The avian telencephalic subpallium originates inhibitory neurons that invade tangentially the pallium (dorsal ventricular ridge and cortical areas).

Author

Cobos I, Puelles L, and Martínez S

Subjects

Animals, Brain Tissue Transplantation, Calbindins, Cell Count, Cell Differentiation, Cell Survival, Cerebral Cortex cytology, Cerebral Cortex embryology, Cerebral Cortex transplantation, Chick Embryo, Epithelial Cells cytology, Immunochemistry, Interneurons cytology, Phenotype, S100 Calcium Binding Protein G analysis, Telencephalon transplantation, Time Factors, Transplantation Chimera embryology, gamma-Aminobutyric Acid analysis, Cell Lineage, Cell Movement, Neurons cytology, Quail embryology, Telencephalon cytology, Telencephalon embryology

Abstract

Recent data on the development of the mammalian neocortex support that the majority of its inhibitory GABAergic interneurons originate within the subpallium (ganglionic eminences). Support for such tangential migration into the pallium has come from experiments using fluorescent tracers or lineage analysis with retrovirus, and the phenotypes of mutant mice with different abnormalities in the developing subpallium. In the present study, we describe tangential migration of subpallial-derived neurons in the developing chick telencephalon. Using quail-chick grafts, we precisely identified the neuroepithelial origin, time-course, and pathways of migration, as well as the identity and relative distribution of the diverse tangentially migrated neurons. The analysis of selective grafts of the pallidal and striatal primordia allowed us to determine the relative contribution of each primordium to the population of migrating neurons. Moreover, we found that, like in mammals, the vast majority of the GABAergic and calbindin-immunoreactive neurons within the pallium (dorsal ventricular ridge and cortical areas) have an extracortical, subpallial origin. Our results suggest that the telencephalon of birds and mammals share developmental mechanisms for the origin and migration of their cortical interneurons, which probably first evolved at an earlier stage in the radiation of vertebrates than was thought before., (Copyright 2001 Academic Press.)

Published

2001

36. Developmental origin of avian Merkel cells.

Author

Grim M and Halata Z

Subjects

Animals, Hindlimb embryology, Microscopy, Electron, Neural Crest embryology, Transplantation Chimera embryology, Chick Embryo embryology, Coturnix, Merkel Cells ultrastructure, Quail embryology

Abstract

We have investigated the developmental origin and ultrastructure of avian Merkel cells by electron microscopy and chick/quail transplantation experiments. On embryonic day 3, chick leg primordia were homotopically grafted onto Japanese quail host embryo. Fourteen days later, quail cells that had migrated into grafted chick legs were identified according to the masses of heterochromatin associated with the nucleolus that are characteristic for quail. Both in chick and quail, Merkel cells are usually located in the dermis just below the epidermis. They are placed between nerve terminals either individually or in small groups wrapped in sheaths that are formed by glial cell processes. Occasionally, some Merkel cells appear in nerve fascicles and within Herbst corpuscles. Merkel cells, as well as glial cells, in grafted chicken legs were of quail origin. This finding provides evidence against the epidermal origin of avian Merkel cells and indicates that Merkel cells are derived from neural crest cells that colonise, together with glial cells and melanocytes, the developing limb primordium.

Published

2000

37. Contribution of single somites to the skeleton and muscles of the occipital and cervical regions in avian embryos.

Author

Huang R, Zhi Q, Patel K, Wilting J, and Christ B

Subjects

Animals, Transplantation Chimera embryology, Chick Embryo embryology, Muscle, Skeletal embryology, Quail embryology, Skull embryology, Somites physiology

Abstract

Controversy has surrounded the process of resegmentation of cervico-occipital somites. We have reinvestigated this topic by grafting single somites of quail embryos homotopically into chick embryos. Somites one to five contribute to the skull. Somites one and two contribute to the parasphenoid, which develops by direct ossification in a non-segmental fashion. All cartilaginous derivatives of the somites are segmental. Somite two forms a stripe of cells in the basioccipital, exoccipital and supraoccipital. Somites three to five give rise to the subsequent caudal parts of the basioccipital and exoccipital. Somite five forms the first motion segment including the occipital condyle, the cranial part of the atlas and the tip of the dens axis. Therefore, the border between head and neck is in the centre of somite five, and corresponds to the expression boundary of Choxb-3. Somite six forms the caudal part of the atlas and the cranial part of the axis. Somites two to eight all contribute to the cranio-cervical muscles with the exception of the Mm. rectus capitis dorsalis and ventralis and the M. biventer cervicis, which do not receive contributions from somite two. In contrast, the M. cucullaris capitis is exclusively formed by myogenic cells from somite two, which parallels its exclusive innervation by the accessory nerve. Our data confirm the segmental nature of the occiput, and show that resegmentation is a very regular process involving all except the four cranialmost somites. Except for somites one and two, all of the somites contribute to the muscles located at the appropriate levels.

Published

2000

38. Facial visceral motor neurons display specific rhombomere origin and axon pathfinding behavior in the chick.

Author

Jacob J and Guthrie S

Subjects

Animals, Axons ultrastructure, Branchial Region embryology, Cell Differentiation physiology, Cell Movement physiology, Chick Embryo, Embryonic Structures innervation, Embryonic Structures transplantation, Facial Muscles innervation, Facial Nerve anatomy & histology, Immunohistochemistry, Motor Neurons ultrastructure, Quail, Rhombencephalon cytology, Rhombencephalon embryology, Transplantation Chimera anatomy & histology, Transplantation Chimera embryology, Transplantation, Heterotopic, Axons physiology, Branchial Region cytology, Branchial Region innervation, Facial Nerve embryology, Motor Neurons physiology

Abstract

In the chick embryo, facial motor neurons comprise branchiomotor and visceral motor subpopulations, which innervate branchial muscles and parasympathetic ganglia, respectively. Although facial motor neurons are known to develop within hindbrain rhombomere 4 (r4) and r5, the precise origins of branchiomotor and visceral motor neuron subpopulations are unclear. We investigated the organization and axon pathfinding of these motor neurons using axonal tracing and rhombomere transplantation in quail-chick chimeras. Our results show that a large majority of branchiomotor neurons originate in r4 but that a cohort of these neurons undergoes a caudal migration from r4 into r5. By contrast, visceral motor neurons develop exclusively in r5. We found that a striking property of facial visceral motor neurons is the ability of their axons to navigate back to appropriate ganglionic targets in the periphery after heterotopic transplantation. These results complement previous studies in which heterotopic facial branchiomotor neurons sent axons to their correct, branchial arch, target. By contrast, when trigeminal branchiomotor neurons were transplanted heterotopically, we found that they were unable to pathfind correctly, and instead projected to an inappropriate target region. Thus, facial and trigeminal motor neuron populations have different axon pathfinding characteristics.

Published

2000