Efficient incorporation of transfected blastodermal cells into chimeric chicken embryos.

The formation of transgenic chimeric chickens for use in developmental studies and as intermediates in the production of transgenic chickens requires the incorporation of stably transfected blastodermal cells into a chimera. To obtain blastodermal cells, area pellucidae of stage X (Eyal-Giladi and Kochav, Dev. Biol. 49:321-337, 1976:E.-G.&K.) embryos were collected from unincubated, freshly oviposited Barred Plymouth Rock eggs and dissociated in 0.25% trypsin/0.04% EDTA (w/v) and 2% (v/v) chicken serum in phosphate-buffered saline (Ca2+ and Mg2+ free) at 4 degrees C for 10 min. The blastodermal cells were suspended in Dulbecco's Modified Eagle's Medium (DMEM) and transfected by lipofection with superhelical pmiwZ, a plasmid containing a hybrid lacZ gene encoding bacterial beta-galactosidase (beta-gal) under the control of a chicken beta-actin/Rous sarcoma virus promoter. A mixture of 2.5 micrograms Lipofectin and 1.56 micrograms pmiwZ in 250 microliters DMEM was incubated for 30 min at 37 degrees C and added to 500 microliters of 20-40,000 cells in suspension. Cells incubated with the transfection reagents in the presence or absence of pmiwZ were either plated and cultured for 48 h at 37 degrees C in 5% CO2/95% air, or injected through a shell window into the subgerminal cavity of White Leghorn stage X (E.-G.&K.) embryos previously exposed to 500-600 rads from a 60Co source, after which the window was sealed and the egg incubated at 38 +/- 1 degrees C for 72 h.(ABSTRACT TRUNCATED AT 250 WORDS)

Chimeric chickens and their use in manipulation of the chicken genome.

Germline chimeric chickens can be made by injecting dispersed cells from Stage X blastoderms into recipient embryos at an equivalent stage of development. Colonization of the chimera by donor-derived cells is facilitated when the recipient embryo is compromised by exposure to irradiation prior to injection of the donor cells. Donor cells can be genetically manipulated by lipofection-mediated gene transfer before they are introduced into the recipient. The genetic modification is expressed in the ectoderm, mesoderm, and endoderm of the chimera after incubation for 96 h. Donor cells can also be cultured as dispersed cells in a monolayer or as whole-embryo explants for at least 48 h before transfer into recipients and retain the ability to enter both somatic and germline tissues in the resulting chimera. A strategy is proposed for the production of transgenic chickens using lipofection-mediated gene transfer to blastoderm cells isolated from Stage X embryos, which are subsequently injected into compromised recipients to yield a germline chimera.

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)

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)