Establishment of an in vitro culture system for chicken preblastodermal cells

To develop an alternative source for chicken pluripotent cells, we examined (1) whether undifferentiated preblastodermal cells could be subcultured in vitro for an extended period and (2) how subculturing affected the physiological properties of preblastodermal cells. The average number of preblastodermal cells was 2,397 in stage V embryos and 36,345 in stage VII embryos; stage X embryos had an average of 53,857 blastodermal cells. The average cell size decreased significantly (70.63-18.83 microm in diameter; P < 0.0001) as the embryo grew; this was closely related to a reduction in the size and number of lipid vesicles in the cell cytoplasm. The culture conditions were optimized for the stage V preblastodermal cells and the control stage X blastodermal cells. On STO feeder cells, the preblastodermal cells achieved stable growth in vitro only in HES medium or a mixed medium of the Knockout DMEM and HES media. However, more than 10 passages of preblastodermal cells at intervals of 3-4 days was possible only by using the Knockout/HES mixed medium and BRL cell-conditioned HES medium for the primary cultures and subcultures, respectively. Colony-forming preblastodermal cells had well-delineated cytoplasm, which was positively stained for stem cell-specific markers by anti-stage-specific embryo antigen-1 antibody, periodic acid-Schiff's solution, and alkaline phosphatase. When preblastodermal cells with or without culturing were transferred into the blastodermal cavity of stage X embryos, only in vitro-cultured preblastodermal cells at stage V (4/5 = 80%) and stage VII (2/8 = 25%) induced somatic chimerism in recipient chickens. In conclusion, undifferentiated preblastodermal cells could be subcultured, and only the colony-forming preblastodermal cells that stained positively for stem cell markers could induce somatic chimerism.

Early steps in neural development

We studied early neurulation events in vitro by transplanting quail Hensen's node, central prenodal regions (before the nodus as such develops), or upper layer parts of it on the not yet definitively committed upper layer of chicken anti-sickle regions (of unincubated blastoderms), eventually associated with central blastoderm fragments. We could demonstrate by this quail-chicken chimera technique that after the appearance of a pronounced thickening of the chicken upper layer by the early inductive effect of neighboring endophyll, a floor plate forms by insertion of Hensen's node-derived quail cells into the median part of the groove. This favors, at an early stage, the floor plate "allocation" model that postulates a common origin for notochord and median floor plate cells from the vertebrate's secondary major organizer (Hensen's node in this case). A comparison is made with results obtained after transplantation of similar Hensen's nodes in isolated chicken endophyll walls or with previously obtained results after the use of the grafting procedure in the endophyll walls of whole chicken blastoderms.

Survival capacity of haploid-diploid goldfish chimeras

In teleosts, haploidy has been considered to be inviable due to the expression of abnormalities during embryogenesis, but the recent report of live haploid-diploid mosaic fish suggests the probable improvement of survival capacity by adding diploid cells or tissues to haploid embryos. In order to examine such possibilities, two types of haploid-diploid goldfish chimeric embryos were produced by transplantation of blastoderm between the normally fertilized diploid and the artificially induced gynogenetic haploid: the haploid-base chimera with the diploid upper half on the haploid lower half blastoderm and the diploid-base chimera with the haploid upper half on the diploid lower half blastoderm. Fluorescent detection of FITC-labeled cells, subsequent histochemical detection of biotin-labeled haploid cells and flow-cytometrical detection of both haploid and diploid cells proved successful induction of the haploid-diploid chimera. Both types of chimeric embryos demonstrated much better survival capacity than pure haploid individuals, but all the haploid-base chimeras died before 10 days after fertilization due to the expression of edema, whereas several diploid-base chimeras survived until 16 months after fertilization when the experiment was ended. This concluded diploid-base chimeras became viable by adding diploid cells to haploid embryos. However, the proportion of transplanted haploid cells was reduced and the distribution of these cells was limited to certain organs because survivors exhibited haploid cells only in brain, eye and/or skin. These results suggest possible elimination of haploid cells from the organs originated from ectoderm.

Recovery of fertility in male hybrids of a cross between goldfish and common carp by transplantation of PGC (primordial germ cell)-containing graft

In germ-line chimera, gametes originate from both the donor and recipient. In order to increase the proportion of gametes from the donor, the elimination or reduction of primordial germ cells (PGCs) from the recipient is required. In the present study, histological and genetic analyses were performed in the chimeric fish obtained when sterile goldfish x common carp hybrid and fertile goldfish embryos were used as a recipient and donor, respectively. Chimerism was induced by transplantation of the lower part of the goldfish blastoderm into the hybrid blastoderm at the blastula stage. Neither spermatid nor spermatozoa were observed in the testis of the male hybrid. Motile sperm were obtained from 15 chimeric males by human chorionic gonadotropin (HCG) injection. When the sperm of chimeric fish were genetically analyzed, only goldfish-specific repetitive DNA sequences were detected. These results revealed that chimeric fish of the cross between a sterile male hybrid and fertile goldfish produced sperm exclusively derived from the donor goldfish.

[Dorsoventral differences of morphogenetic potencies of the loach blastoderm in experiments with alteration of the mass of explanted fragments]

We studied the influence of doubling the mass of explanted fragments of the dorsal and ventral loach blastoderm at the early gastrula stage on their capacity for differentiation of axial structures. The dorsoventral differences are as follows: the differentiation of somites correlates, according to the results of factor analysis, with the shape complication only in double dorsal explants, while the notochord is more differentiated in the ventral fragments, if it is present, than in the dorsal ones. Doubling of the mass of dorsal fragments of the blastoderm enhances their morphogenetic potencies and shifts differentiation towards the formation of trunk axial structures. The increased mass of ventral fragments does not affect their differentiation and morphogenesis, but disturbs the correlation of these processes.

Production of duck-chicken chimeras by transferring early blastodermal cells

Duck blastodermal cells isolated from Stage X embryos of Maya ducks were injected into subgerminal cavity of recipient Stage X chicken embryos treated with gamma-irradiation or untreated. Eleven somatic chimeras were obtained based on plumage color and were raised to sexual maturity. To test for germline chimerism, progeny tests were performed by mating the chimeras with Maya ducks. A total of 622 eggs was collected and incubated. Fertility rate and hatchability were 2.9% (18/622) and 1.0% (6/622), respectively. The six duck hatchlings were from Chimera 9801 and were considered to be derived from the germ cells developed from the donor Maya blastodermal cells, indicating that Chimera 9801 is a germline chimera.

Reconstitution of a chicken breed by inter se mating of germline chimeric birds

Blastoderm cells from chicken embryos of a donor breed (Green-legged Partridgelike; GP) were transferred to embryos of a recipient breed (White Leghorn; WL) to form chimeric progeny that, after inter se mating, permitted successful reconstitution of the donor breed. Among 23 chimeric chicks hatched from WL embryos injected with GP cells, 20 (87%) were raised until maturity, and progeny were tested by mating with GP birds to determine the ability of blastodermal cells to form germline chimeras. Six of the tested birds (30%) produced recipient-derived and donor-derived offspring, indicating that they were germline chimeras. The mean percentages of donor-derived germ cells in these birds were 21.1 (17.6 to 50.0%) and 16.9 (5.3 to 23.1%) in males and females, respectively. Among 477 chicks, resulting from mating the germline chimeric male with four germline chimeric females, 10 chicks (2.1%) exhibited a GP phenotype, indicating that the original donor stock had been reconstituted. Only one germline chimeric hen produced GP offspring, but the expected and calculated percentages of GP offspring were similar (2.99 and 2.08, respectively). Two methods of DNA analyses (RFLP and PCR amplification of polymorphic microsatellite loci) of chimeras and their offspring indicated that through mating of a relatively small number of chimeras it is possible to reconstitute a highly diverse population.

Germ-line chimera by lower-part blastoderm transplantation between diploid goldfish and triploid crucian carp

Germ-line chimerism was successfully induced by blastoderm transplantation from donor triploid crucian carp, which reproduces gynogenetically, to recipient diploid goldfish, which reproduces bisexually. Lower part of donor blastoderm including primordial germ cells (PGCs) was sandwiched between recipient blastoderm at the mid- to late-blastula stage. When donor grafts were prepared from intact embryos or ventralized ones by removing vegetal yolk hemisphere at the 1- to 2-cell stage, malformations including double axes were observed in the resultant chimeras transplanted with grafts from intact embryos at the hatching stage, while a few malformations in those from ventralized embryos. PGCs originated from donor grafts were observed around the gonadal anlage at 10 days post-fertilization in chimeras. When ploidy of erythrocytes and epidermal cells in chimeric fish was examined by flow-cytometry, no triploid cells were detected at 1- and 5-year-old chimeras. Three-year-old chimeric fish (n = 5) laid eggs originated from the donor together with those from the recipient. The frequency of eggs from the donor crucian carp blastoderm varied from 3.1 to 89.3% between chimeras.

Morphogenesis of gut and distribution of the progenitors of gut endocrine cells at cranial somite levels of the chick embryo

The primary objective of this study was to establish the distribution of the progenitors of selected gut endocrine cell types at cranial somite levels. In addition, analysis of the material has provided new information about the location of the presumptive territories of certain gut regions and of the pancreas. Narrow transverse strips of full-thickness blastoderm two or three somites in length were excised at the levels of somites 1 to 5 of 8.5- to 18-somite chick embryos and cultured as chorioallantoic grafts to an age equivalent to 20 days of incubation. The grafts were analysed by immunocytochemistry, and their morphology was evaluated. Individual grafts exhibited up to five different types of gut morphology, including those of oesophagus, proventriculus, gizzard, pyloric region, small intestine, and pancreas. The morphologic survey yielded new information about the location, extent, or both, of the territories of the pyloric region, the small intestine, and the pancreas. In general, the progenitors of gut endocrine cell types identified were those expected for the different morphologic regions: in only a few instances were ectopic endocrine cell types detected. The available evidence points to the progenitors of bombesin/gastrin-releasing peptide cells being located cranial to somite 5 at the stages studied. Based on the morphology and the proportion of insulin cells, the development of pancreas in grafts appeared compromised compared with grafts of the intact dorsal pancreatic bud: this may relate to the likely exclusion of dorsal pancreatic bud mesoderm from the graft area. The results show that presumptive small intestinal endoderm in grafts can differentiate in the absence of homologous (i.e., small intestinal) mesoderm: this accords with the view that the primary source of positional information in the gut is in the endoderm.

Localization of primordial germ cells or their precursors in stage X blastoderm of chickens and their ability to differentiate into functional gametes in opposite-sex recipient gonads

This study was performed to determine the distribution of primordial germ cells and their precursors in stage X blastoderm of chickens. The blastoderm (Barred Plymouth Rock chickens) isolated from the yolk was separated into three portions: the central disc, the marginal zone and the area opaca. The dissociated blastodermal cells derived from the central disc, marginal zone and area opaca were transferred into a recipient blastoderm (White Leghorn chicken) from which a cell cluster was removed from the centre of the central disc. The manipulated embryos were cultured in host eggshells until hatching. The chicks were raised until sexual maturity and test mated with Barred Plymouth Rock chickens to assess the donor cell contribution to the recipient germline. Germline chimaeric chickens were produced efficiently (46.7%, 7/15) when the blastodermal cells derived from the central disc were transferred into recipient embryos of the same sex, whereas no germline chimaeric chickens were produced when the blastodermal cells derived from the marginal zone or area opaca were transferred into recipient embryos of the same sex (0/12). Germline chimaeric chickens were also produced by transfer of blastodermal cells derived from the central disc (6.7%, 1/15), marginal zone (10.0%, 1/10) or area opaca (11.1%, 1/9) into recipient embryos of the opposite sex. It is concluded that primordial germ cells are induced during or shortly after stage X and that the cells derived from the central disc have the highest potential to give rise to germ cells. Cells derived from the marginal zone and area opaca can also give rise to germ cells, although the frequency is low.

Production of chicken chimeras by fusing blastodermal cells with electroporation

AIM

To establish techniques for producing somatic and germline chimeric chicken by transferring blastodermal cells fused with electroporation.

METHODS

Stage-X blastodermal cells isolated from freshly laid fertile unincubated white Leghorn and Rhode Island red chicken eggs were fused with electroporation. The treated cell suspension was transferred to the recovery medium (DMEM containing 10% FBS) and was injected into the subgerminal cavity of recipient unincubated embryos (stage X).

RESULTS

Of 177 recipient embryos injected with the fusing blastodermal cells, 6 (3.4%) survived to hatching. Somatic chimerism was examined in the melanocyte of the feather. The presence of feathers originating from the donor cell was observed in 1 bird (16.7%) out of the 6 hatched birds. After 21 days of incubation two birds out of five embryos were subjected to polymerase chain reaction (PCR) analysis for W-chromosome-specific DNA for each tissue. One bird possessed W-chromosome-specific DNA in the stomach, and the other exhibited the same DNA in the left and right gonads and other tissues, but not the stomach.

CONCLUSION

Recipient embryo having electrofused blastodermal cells yields somatic and germline chimeric chickens more successfully.

Dorsal specification in blastoderm at the blastula stage in the goldfish, Carassius auratus

The teleost dorsoventral axis cannot be morphologically distinguished before gastrulation. Previous studies by the current authors have shown that localized dorsalizing activity in the yolk cell (YC) induces the dorsal tissues in the overlying blastoderm. In order to examine whether or not dorsal blastomeres are committed to their dorsal fate before the gastrula stage, a variety of transplant operations were performed in goldfish blastoderms at the mid- to late-blastula stages. When the blastoderm was cut from the YC, rotated horizontally at 180 degrees, and recombined with the YC, the blastoderm frequently developed two axes, indicating that dorsal blastomeres of the blastula had already acquired the ability to differentiate into the organizer in the absence of dorsalizing signals from the YC. This result was further confirmed by experiments using ventralized embryos in which no dorsal structures formed: the axis formation was frequently observed in the normal blastoderm combined with the ventralized YC at the blastula stage. However, the axes formed in the absence of dorsal information from the YC exhibited a lower dorso-anterior index. Furthermore, the dorsal specification was not stably maintained when the dorsal cells were located far from the YC. These results suggest that the inductive and permissive influence of the YC may be required for the blastoderm to undergo full dorsal differentiation.

Distribution of blastodermal cells transferred to chick embryos for chimera production using windowed eggs

1. To improve the production of chimeras, the distribution of donor blastodermal cells after transferring into recipient embryos was examined morphologically. 2. Donor blastodermal cells were distributed near the site of injection in the epiblast and in the subgerminal cavity and yolk. Some filled the hole made by the micropipette and were distributed outside the epiblast. Many were buried in yolk. In some cases, more donor blastodermal cells were located in the yolk than in the subgerminal cavity and some were located 800 microm below the under-surface of the epiblast. 3. It is recommended that injection should be as shallow as possible to increase the proportion of chimeras produced, and that some means is needed to prevent blastodermal cells from escaping from the hole produced by injection.

Map of the Anlage fields in the avian unincubated blastoderm

By excision at different sites of rectangular fragments from unincubated chicken blastoderms and replacement by isotopic fragments from unincubated quail blastoderms, we could make the first complete map of the Anlage fields in the freshly laid avian blastoderm. All the Anlage fields (Fig. 11) are found in the upper layer (UL) of the caudal half of the area centralis (bordered by the Rauber-Koller's sickle). In the UL of the area marginalis, peripheral to Rauber-Koller's sickle, neither gastrulation nor neurulation phenomena could be observed. Similar heterotopic replacement experiments indicate that before incubation, the different parts of the UL of the area centralis are still uncommitted or reversibly committed. The Anlage fields of chordamesoblast and definitive endoderm (gut endoderm) in unincubated avian blastoderms appeared to be disposed caudally in the caudal half of the area centralis. As far as we know we are the first to demonstrate that the Anlage field of the definitive gut endoderm (which is derived from the upper layer: Hunt, 1937; Vakaet, 1962b) is localized in the most caudal upper layer part of the area centralis just centrally to the Rauber-Koller's sickle. The Anlage field of the neural plate is localized in the upper layer over the more cranial endophyll. The Anlage of the brain is shield-shaped, whilst the other Anlage fields are sickle-shaped, parallel with the Rauber-Koller's sickle. Their general hemicircular disposition and form still seem to reflect (together with the Rauber-Koller's sickle) the original ooplasmic radial symmetry (Callebaut, 1972) combined with the eccentricity of the deep layer components, which was observed during early symmetrization by gravitational orientation of the egg yolk (Callebaut, 1993a,b). The Rauber-Koller's sickle might be homologous with the vegetal dorsalizing cells or centre of Nieuwkoop (1973) in amphibian blastulas.

Characterizing the zebrafish organizer: microsurgical analysis at the early-shield stage

The appearance of the embryonic shield, a slight thickening at the leading edge of the blastoderm during the formation of the germ ring, is one of the first signs of dorsoventral polarity in the zebrafish embryo. It has been proposed that the shield plays a role in fish embryo patterning similar to that attributed to the amphibian dorsal lip. In a recent study, we fate mapped many of the cells in the region of the forming embryonic shield, and found that neural and mesodermal progenitors are intermingled (Shih, J. and Fraser, S.E. (1995) Development 121, 2755–2765), in contrast to the coherent region of mesodermal progenitors found at the amphibian dorsal lip. Here, we examine the fate and the inductive potential of the embryonic shield to determine if the intermingling reflects a different mode of embryonic patterning than that found in amphibians. Using the microsurgical techniques commonly used in amphibian and avian experimental embryology, we either grafted or deleted the region of the embryonic shield. Homotopic grafting experiments confirmed the fates of cells within the embryonic shield region, showing descendants in the hatching gland, head mesoderm, notochord, somitic mesoderm, endoderm and ventral aspect of the neuraxis. Heterotopic grafting experiments demonstrated that the embryonic shield can organize a second embryonic axis; however, contrary to our expectations based on amphibian research, the graft contributes extensively to the ectopic neuraxis. Microsurgical deletion of the embryonic shield region at the onset of germ ring formation has little effect on neural development: embryos with a well-formed and well-patterned neuraxis develop in the complete absence of notochord cells. While these results show that the embryonic shield is sufficient for ectopic axis formation, they also raise questions concerning the necessity of the shield region for neural induction and embryonic patterning after the formation of the germ ring.

Mesodermal patterning during avian gastrulation and neurulation: experimental induction of notochord from non-notochordal precursor cells

The cells that are normally fated to form notochord occupy a region at the rostral tip of the primitive streak at late gastrula/early neurula stages of avian and mammalian development. If these cells are surgically removed from avian embryos in culture, a notochord will nonetheless form in the majority of cases. The origin of this reconstituted notochord previously had not been investigated and was the objective of this study. Chick embryos at late gastrulal early neurula stages were cultured, and the rostral tip of the primitive streak including Hensen's node was removed and replaced with non-node cells from quail epiblast to ensure that the cells normally fated to be notochord would be absent and that healing of the blastoderm would occur. Embryos were allowed to develop for 24 hr, and the presence and origin (host or graft) of the notochord were assessed using antibodies against notochord or quail cells. Two notochords typically developed; both were almost exclusively of host origin. The primitive streak, and in some cases adjacent tissues, was removed from another group of embryos in an attempt to estimate the mediolateral position and extent of the cells required to form reconstituted notochord. Additional experimental embryos with and without grafts were transected at various rostrocaudal levels in an attempt to estimate the rostrocaudal extent of the cells required to form reconstituted notochord. Finally, various levels of the primitive streak either were placed in a neutral environment (the germ cell crescent) or were grafted in place of the node. Collective results from all experiments indicate that the areas lateral to the rostral portion of the primitive streak, estimated to have a rostrocaudal span of less than 500 microns and a mediolateral extent of less than 250 microns, are critical for formation of the reconstituted notochord. Fate mapping and histological examination of this region identify 4 possible precursor cell populations. Further studies are underway to determine which of the 4 possible precursor cell types forms or induces the reconstituted notochord, and which tissue interactions underlie this change in cell fate.

Rauber's (Koller's) sickle: the early gastrulation organizer of the avian blastoderm

A fragment of Rauber's (Koller's) sickle of an unincubated quail blastoderm grafted on the ventral side of an unincubated chicken blastoderm (stage 1, Vakaet, 1962) cultured in vitro evokes the formation of a normal secundary primitive streak (PS), mesoderm and definitive (gut) endoderm, derived from the chicken host. The graft itself (containing gamma and/or beta ooplasm, Callebaut 1987) differentiates into the V-shaped junctional endoblast in continuity medially via a transitional endoblast with the median sickle endoblast (Vakaet, 1970). A PS developed also often after grafting of the caudal part of the endophyll, close to Rauber's sickle. However after grafting of the central part of the endophyll (containing delta ooplasm, Callebaut, 1987) no PS appeared. Our study indicates that material from the sickle or its derivatives represent the organizer in the early avian embryo. Comparison with the development in vivo indicated that in the avian gastrula an anchor-shaped connection area exists, situated between the sickle derived deep layer and the structures evoked in the upper layer. Our results suggest the existence of a homology between the avian Rauber's sickle and the blastoporus in amphibians and some reptiles.

Axis development in avian embryos: the ability of Hensen's node to self-differentiate, as analyzed with heterochronic grafting experiments

A series of experiments consisting of transplantation of Hensen's nodes has been conducted to examine axis development in avian embryos. In the first group of experiments, Hensen's nodes from quail embryos were transplanted homotopically and either isochronically or heterochronically to chick embryos, and the structures derived form the grafted nodes were assessed. The grafted Hensen's nodes typically self-differentiated structures appropriate for their stages, and the host embryos developed normally; the structures formed from grafted tissue usually merged caudally with the comparable host structures. Thus, even when the stages of the donor and host tissues were significantly mismatched (e.g., stage 3 donors and stage 9 hosts or vice versa), the graft was unable to repattern the host's neuraxis, and the host was unable to respecify the types of structures derived from the graft. In the second group of experiments, Hensen's nodes from quail embryos were transplanted to sites located just lateral to Hensen's nodes of host chick embryos, thereby providing the potential for development of additional axes. A single axis always resulted in each case in which further development occurred, with the graft self-differentiating its typical stage-specific structures, all of which merged caudally with comparable host structures. A final group of experiments served principally as a control and tested the ability of a part of Hensen's node, when it was transplanted to the extraembryonic germ cell crescent, to organize an ectopic embryo. In these experiments, the entire thickness and length of each Hensen's node, but only the central one-third to one-half of its width, was transplanted to host blastoderms, yet ectopic embryos, complete with induced neuraxes, were formed. Therefore, a part of Hensen's node has the ability to function fully as an organizer when placed in a conducive environment. Collectively, these results provide further documentation of the strong ability of Hensen's node to self-differentiate, and they suggest that once morphogenetic movements are under way, neuraxial structures can form, and characteristic rostrocaudal patterning of the neuraxis can occur, without sustained influence from Hensen's node.

Germline chimeric chickens from dispersed donor blastodermal cells and compromised recipient embryos

Stage-X blastoderms, within intact eggs from White Leghorn hens, were exposed to 500–700 rads of gamma radiation from a 60Co source prior to injection, into the subgerminal cavity, of approximately 100 or 200–400 dispersed cells from stage-X blastoderms isolated from eggs laid by Barred Plymouth Rock hens. Embryos developing past day 14 of incubation and hatched chicks were assessed for donor and recipient cell contribution to the melanocyte population through examination of black and yellow down pigmentation, respectively (Barred Plymouth Rocks have a recessive allele at the I locus while the White Leghorns have a dominant allele at the I locus). Of the 809 embryos injected with approximately 100 cells, 192 developed past day 14 and black pigmentation, indicating somatic chimerism, was observed on 118 of the 192 (58%) embryos and chicks. Of the 296 embryos injected with 200–400 donor cells, 86 developed past day 14 of incubation. Somatic chimerism was observed on 55 of the 86 (64%) embryos and chicks. To test for germline chimerism, birds surviving to maturity were mated to Barred Plymouth Rocks. Five somatically chimeric females were produced when approximately 100 cells were injected, and one was a germline chimera. Six somatic female chimeras were produced following the injection of 200–400 cells, three of which proved to be germline chimeras by the presence of Barred Rock chicks among their offspring. Two of the nine males produced by injecting approximately 100 cells were germline chimeras.(ABSTRACT TRUNCATED AT 250 WORDS)

The fate of female donor blastodermal cells in male chimeric chickens

In previous experiments in our laboratories, chickens that are chimeric in their gamete, melanocyte, and blood cell populations have been produced by injection of dispersed stage X blastodermal donor cells into the subgerminal cavity of stage X recipient embryos. In some experiments, donor cells were transfected with reporter gene constructs prior to injection as a preliminary step in the production of transgenic birds. Chimerism was assessed by test mating, observation of plumage, and DNA fingerprinting. Methods were sought that would provide a relatively rapid analysis of the spatial distribution of descendants of donor cells in chimeras to assess the efficacy of various methods of chimera construction. To date, the sex of donor and recipient embryos was not known and, therefore, numerous mixed sex chimeras must have been constructed by chance, since donor cells were usually collected from several embryos rather than from individual embryos. The presence of female-derived cells was determined by in situ hybridization using a W-chromosome-specific DNA probe, using smears of washed erythrocytes from 16 phenotypically male chimeric chickens ranging in age from 4 days to 42 months posthatching. The proportion of female cells detected in the erythrocyte samples was zero (eight samples) or very low (0.020-0.083%), although 1% of the erythrocytes from a phenotypically male chick that was killed 4 days after hatch were female-derived. The low proportions of female-derived cells were surprising, considering that most of these chimeras had been produced by the injection of cells pooled from several donor embryos and most recipients had been exposed to gamma irradiation prior to injection, thus dramatically enhancing the level of incorporation of donor cells into the resulting chimeras. By contrast, 0-100% of the erythrocytes were female-derived in blood samples taken at 10 days of incubation from the chorioallantois of seven phenotypically normal male embryos that resulted from the injection of blastodermal cells pooled from five embryos into irradiated recipient embryos. Approximately 70% of the erythrocytes in a blood sample from a phenotypically normal female chimeric embryo were female-derived, and 100% of the erythrocytes examined from an intersex embryo bearing a right testis and a left ovary were female-derived. These results indicate that female-derived cells can contribute to the formation of erythropoietic tissue during the early development of what will become a phenotypically male chimeric embryo. It would appear, therefore, that female-derived cells are blocked in development or destroyed, or certain male-female combinations of cells may be lethal prior to hatching.(ABSTRACT TRUNCATED AT 400 WORDS)

Distribution analysis of transferred donor cells in avian blastodermal chimeras

Blastodermal chimeras were constructed by transferring quail cells to chick blastoderm. Contribution of donor cells to host were histologically analyzed utilizing an in situ cell marker. Of the embryos produced by injection of stage XI-XIII quail cells into stage XI-2 chick blastoderm, more than 50 percent were definite chimeras. The restriction on the spatial arrangement of donor cells was induced by varying the stage of host. Ectodermal chimerism was limited to the head region and no mesodermal chimerism was shown when the quail cells were injected into stage XI-XIII blastoderm. Mesodermal and ectodermal chimerisms were limited to the trunk, not to the head region, when the quail cells were injected into the stage XIV-2 blastoderm. In these chimeras, however, some of the injected quail cells formed ectopic epidermal cysts. Consequently, the stage XIV-2 blastoderm may become intolerant of the injected cells. Our results suggest that it is possible to obtain chimeras that have chimerism limited to a particular germ layer and region by varying the stage of donor cell injection. Injected quail cells contributed to endodermal tissues and primordial germ cells regardless of the injection site. The quail-chick blastodermal chimeras could be useful in the production of a transgenic chicken and in the investigation of immunological tolerance.

Efficient transfection of chicken cells by lipofection, and introduction of transfected blastodermal cells into the embryo

Chicken blastodermal cells (CBCs) and primary chicken fibroblasts (PCFs) have been lipofected with a variety of lacZ constructs encoding Escherichia coli beta-galactosidase (beta-gal). A reporter construct (phspPTlacZpA) containing a mouse heat-shock protein 68 gene (hsp 68) promoter was used to establish conditions for efficient lipofection. The construct, in circular or linear plasmid form or as reporter sequences alone, was transferred efficiently by incubating the cells for 3.5 h in a mixture of 6.2 micrograms Lipofectin (a cationic liposome preparation from Bethesda Research Laboratories) and 1.55-3.1 micrograms DNA per mL DMEM. These lipofection conditions were used to transfer a reporter construct (pCBcMtlacZ) containing a Zn(2+)-inducible chicken metallothionein (cMt) promoter, and constructs showing constitutive expression due to Rous sarcoma virus plus chicken beta-actin (pmiwZ) or cytomegalovirus (pMaori3) promoters. Endogenous chicken beta-gal and transferred bacterial beta-gal activity could be distinguished clearly by incubating the cells with the substrate, Xgal, at pH 4.3 or 7.4, respectively. Expression of phspPTlacZpA in chicken cells did not appear to require specific induction of the mouse hsp68 promoter, whereas expression of pCBcMtlacZ required treatment of the cells for 6-12 h with 150 microM ZnCl2. Bacterial beta-gal activity was observed following lipofection of CBCs that were cultured in suspension or plated. The efficiency of lipofection was at least 1 in 25 for CBCs, judging by the proportion of cells shown to have beta-gal activity 16-24 h after lipofection treatment began; these events could represent transient or stable incorporation of the construct.(ABSTRACT TRUNCATED AT 250 WORDS)

Production of quail-chick chimaeras by blastoderm cell transfer

1. Quail-chick chimaeras were produced by injecting dissociated quail blastoderm cells into chick embryos. 2. Quail blastoderms were removed from the yolk and the cells were dispersed by trypsin treatment or pipetting. The cell suspension (1 to 5 microliters) was injected into the subgerminal cavity of unincubated chick embryos. The chick embryos were then cultured in recipient eggshells. 3. Quail blastoderm cells injected into the chick embryos adhered to the chick embryonic cells. The rates of hatching were 8.6% (38 chicks from 441 eggs) and 40.3% (48 chicks from 119 eggs) when the volumes of the cell suspension injected were 3 to 5 microliters and 1 microliter, respectively. 4. Seven out of 86 hatched birds were clearly identified as being chimaeric because part of the feather colouring was of quail specificity. In addition to these chimaeric birds, there were 8 chimaeric embryos which died before hatching. The distribution patterns of the quail feathers were varied among the chimaeric birds and embryos. 5. This technique provides a basis for the investigation of chick embryo cryopreservation, genetic transformation and analysis of cell lineage of chickens.

The chick's marginal zone and primitive streak formation. I. Coordinative effect of induction and inhibition

A variety of transplantation experiments of posterior and lateral marginal zone fragments at stages X, XI, and XII have been carried out in order to test their relevance to the development of a primitive streak (PS). At the stages studied the marginal zone (MZ) was shown to behave as a ring-like gradient field, the maximal value of which was at the posterior end (PM). The PM was found to be capable at the same time of promoting the development of a PS and of suppressing the inductive potential of other regions of the MZ. By systematically evaluating inductive and suppressive capacities of PMs, at different developmental stages, it was found that both features are maximal at stage X. During stages XI and XII, both properties gradually decrease in the MZ and build up in the forming hypoblast.

The chick's marginal zone and primitive streak formation. II. Quantification of the marginal zone's potencies--temporal and spatial aspects

When a posterior fragment of the chick's marginal zone (PM) was exchanged with equal sized lateral marginal zone fragment (LM), of the same blastoderm, its capacity to initiate an ectopic primitive streak (PS) was found to be both size and stage dependent. Good correlation was demonstrated between the areas of PM fragments and the number of cells they contained. In stage X blastoderms, PM fragments containing less than 1200 cells were incapable of initiating an ectopic PS. Transplanted PMs containing between 1200 and 1500 cells initiated a lateral ectopic PS in 50% of the cases, while in the other 50% a posterior PS developed from the original posterior side. PMs containing 1500 cells or more in all cases initiating an ectopic PS and inhibited the formation of a posterior PS. At stage XI, laterally transplanted PMs containing less than 1800 cells were not effective. Stage XI PMs containing 1800-2300 cells in some cases succeeded in initiating a lateral ectopic PS, in addition to the posterior one. Stage XI PMs containing 2300 cells or more invariably promoted the development of an ectopic PS, but were unable to suppress the formation of a posterior PS, so that two PSs developed in the same blastoderm, one posterior and one ectopic. When a stage XI PM fragment was laterally transplanted into a younger, stage X blastoderm, the minimal effective cell number needed to initiate an ectopic PS increased to at least 3000 cells, again without inhibiting the formation of a posterior PS. The inductive potential of a stage X PM is therefore at least twice that of a stage XI PM. The marginal zone belt of stage X blastoderms was checked for the decrease in its developmental potential from the posterior to the lateral side by evaluating its effect on the developmental expression of two competing stage X PMs, one located posteriorly and the other inserted laterally. The developmental expression of the laterally inserted PM was consistently inferior to that of the posterior PM. The developmental expression of each PM was not related to absolute size, but depended on the size ratio of lateral PM/posterior PM. When the ratio was 1.2 or less, only posterior PSs developed. When the ratio was 1.3-1.4, three different results were encountered: (1) only a posterior PS, (2) posterior plus lateral, and (3) only lateral PS. When the ratio was 1.5 or more, only a lateral PS developed, which suppressed the posterior PS.

Autoradiographic demonstration of the penetration of albumen-derived material through the vitelline membrane into the egg yolk, exterior to the avian blastoderm

A method enabling in ovo transplantation and cultivation of fertilized, unincubated quail yolks is described. By this technique, nonradioactive yolks were transferred into nonradioactive egg shells filled with in vivo radioactively labeled albumen. With autoradiography it was demonstrated that during early avian blastoderm development, albumen-derived material can penetrate through the vitelline membrane of the acellular rimzone distal to the margin of over-growth.

When does determination occur in Drosophila embryos?

Small groups of blastoderm cells were transplanted from wild-type donor embryos into genetically marked host embryos of the same age. Donor cells were injected either into an homologous or an ectopic region of the recipient, and both donor and recipient embryos were allowed to develop. Donor flies were examined for defects in external structures. Recipients were scored for patches of donor-type marked tissue derived from the injected cells. After ectopic transfer, the donor cells recovered in chimaeric recipients differentiated structures consistent with the donor site of cell removal. No apparent fate change was observed. In the rare cases when both individuals of a donor/host pair survived, a direct correspondence could be made between the deleted region in the donor and the chimaeric patch in the host. The results show that blastoderm cells are stably determined to within a segment.

Differentiation of the epiblastic part of chick Hensen's node in coelomic cavity

When implanted into the coelomic cavity the epiblastic, non-invaginated part of Hensen's node of chick blastoderm at Hamburger--Hamilton stage 3 to 3+ can differentiate into various tissues. These include neural, mesodermal, and endodermal ones, which are not essentially different from those derived from a complete node in similar conditions.

Differentiation of quail Hensen's node in chick coelomic cavity

Quail Hensen's nodes were cultured in the chick coelomic cavity. They differentiated into various tissues, intimately mixing with host cells, which in many cases formed the supporting mesoderm of graft epithelial or nervous tissue.

Studies on cell differentiation: inducing capacity of sulfhydryl-containing amino acids on post-nodal pieces of chick blastoderms

The inducing capacity of sulfhydryl (SH)-containing amino acids (cysteine and glutathione) on post-nodal pieces (PNPs) of stage 4 chick blastoderms was investigated. PNPs were treated for different lengths of time with chick Ringer's solution (control group) or chick Ringer's solution containing cysteine or glutathione, followed by culturing for 2-10 days on Spratt-Haas agar medium or on the chorioallantoic membrane of 8-day chick embryos. Control PNPs rarely showed differentiation, but those treated with the amino acids for six hours or longer developed structures such as neural tissue, notochord, somite mesoderm, and nephric tubules. The pulsatile tissue was only seen in the PNPs cultured for four days or longer. Two-four hours of treatment was too short to provoke induction in a statistically significant number of PNPs. The highest frequency of induction was noted in those pretreated with glutathione (8 mug/ml) for eight hours, followed by culturing for four days. The magnitude of the inducing capacity and toxicity of the amino acids were concentration dependent: a deleterious effect was observed at 14 mug/ml; the highest frequency of induction occurred at 8 mug/ml, but the frequency decreased as the concentration decreased; at 2 mug/ml all PNPs remained viable, but only a few (9-14%) showed differentiation. The inducing capacity of the amino acids was counteracted by equimolar concentrations of rho-chloromercuribenzoic acid or omega-chloroacetophenone. The effects of glutathione (8 mug/ml) differed from those of Hensen's node grafts in that the former caused sublethal cytolysis and inhibited H-3-uridine uptake in competent ectodermal cells during the first 18 hours of cultivation.