Effects of the Brachyury (T) mutation on morphogenetic movement in the mouse embryo

$\text{T}\text{T}$ embryos have been first distinguishable at 8 days post coitum by their gross morphological abnormalities. By quantitative morphometry of histological sections, anomalies in the homozygotes were expressed numerically. At 8 days p.c., morphologically identifiable T-homozygotes had an increased number of ectodermal and a reduced number of mesodermal cells compared to the wild type. At 7 days p.c., embryos with a low mesoderm/ectoderm ratio were found only in litters of $\text{T}\text{+}\text{×}\text{T}\text{+}$ matings at the expected frequency. At 6 days p.c., one-fourth of the embryos in $\text{T}\text{+}\text{×}\text{T}\text{+}$ litters showed a delay in the transition from cuboidal to squamous endoderm. No such embryos were found in the +/+ × +/+ matings. In 6-, 7-, and 8-day mutant embryos, cells proliferated at statistically normal rates. Therefore, it may be said that advanced morphological irregularities of 8-day homozygotes cannot be accounted for by anomalies in cell proliferation. When the total cell number was 5 × 10⁴/embryo (8 days), a sudden change was observed in the regional distribution of mesodermal and ectodermal cells along the anteroposterior axis of $\text{T}\text{T}$ embryos. Since no regional difference in the cell cycle time was observed, these abnormalities may best be explained by anomalies in cell migration. These results strongly suggest abnormal morphology of $\text{T}\text{T}$ mutants resulting from defects in morphogenetic movement.     

Inhibition of DNA synthesis in embryonic mouse retina as a result of gene interaction.

It has been shown by autoradiography using ³H-thymidine that 11-day mouse embryos doubly homozygous for the autosomal recessive genes fidget (gene symbol fi) and ocular retardation (or), have three to five times fewer labelled nuclei in their retina anlages as do normal (genotype +/+ +/+) embryos singly homozygous for fidget (+/+ $\text{fi}\text{fi}$) or ocular retardation (+/+ $\text{or}\text{or}$). In 11-day embryos of +/+ +/+, +/+ $\text{fi}\text{fi}$ and +/+ $\text{or}\text{or}$ genotypes the labelled nuclei are localized mainly in the inner zone of the retina anlage. However, in double homozygotes the indices of labelled nuclei were not significantly different in the inner and outer zones of the retina anlage. The retina anlage of 12-day double homozygote, $\text{fi}\text{fi}\text{or}\text{or}$, has practically no nuclei synthesizing DNA. Consequently, the mutant genes fi and or which prolong the G₁ period of the cell cycle in single homozygotes, act synergetically to stop DNA synthesis in the retina anlage cells of 12-day $\text{fi}\text{fi}\text{or}\text{or}$ embryos.     

Early appearance in neural crest and crest-derived cells of an antigenic determinant present in avian neurons

A monoclonal antibody (“$\text{E}\text{C8}$”) against chicken dorsal root ganglion cells has been produced. The epitope (antigenic determinant) to which this antibody binds appears in neuronal cells—of both the peripheral and central nervous systems—and in a limited number of nonneuronal cell types in avian embryos. The epitope is intracellular and is probably part of a protein as judged by its susceptibility to proteases. This epitope appears very early in neuronal development. It may be detected in brain, spinal cord, and ventral root nerve fibers of Hamburger-Hamilton stage 16 chicken embryos (51–56 hr of incubation). At this same age, $\text{E}\text{C8}\text{-}\text{immunoreactive}$ cells can be found in the neural crest migratory space between the neural tube and the somite about a day before dorsal root ganglia begin to coalesce. Since some cultured neural crest cells (but not somitic mesenchymal cells) also express this epitope, we propose that the $\text{E}\text{C8}$ monoclonal antibody identifies an early differentiating subpopulation of neural crest cells which express this putative neuronal trait soon after the time of cessation of migration in vivo.     

Development of teratomas from yolk sac of genetically sterile embryos

Yolk sac-derived teratomas are composed of various well-differentiated tissues. These tissues must be derived from multipotent cells. To exclude a germ cell origin for these teratomas we used $\text{Steel}\text{-}\text{Sl}\text{+}$ females copulated with $\text{Sl}\text{+}$ males. The embryos generated from such mating comprise 25% $\text{Sl}\text{Sl}$ sterile embryos, deficient in primordial germ cells, 25% normal embryos (+/+), and 50% heterozygotes ($\text{Sl}\text{+}$). The results indicate that the genotype of the embryos does not influence the development of teratomas. Displaced yolks sacs belonging to genetically sterile embryos developed into teratomas as frequently as those from heterozygotes and from genetically normal embryos.     

Temperature dependence of active K+ transport in cation dimorphic sheep erythrocytes

Arrhenius diagrams of K⁺ pump fluxes measured between 15°C and 41°C were discontinuous in high K⁺ but not in low K⁺ sheep red cells. Exposure of low K⁺ cells to anti-L caused a bimodal temperature response of K⁺ pump flux with a transition temperature, $\text{T}\text{c}$, similar to that found in high K⁺ cells but with comparatively higher activation energies above $\text{T}\text{c}$.     

Effect of removing the zona pellucida on development of hamster and bovine embryos invitro and invivo

Uterine stage embryos collected from the hamster (8-cell) and cow (morula, early blastocyst) were monitored for development $\text{in}$$\text{vitro}$ (embryo culture) and $\text{in}$$\text{vivo}$ (embryo transfer) following premature removal of the zona pellucida.Removal of the zona pellucida did not significantly affect $\text{in}$$\text{vitro}$ development to the blastocyst stage of (1) 8-cell hamster embryos (zonae removed by a combined enzymic-mechanical procedure), (2) bovine morulae (zonae removed by mechanical means only) (3) early bovine blastocysts (zonae removed by the enzymic-mechanical technique).Zona-free hamster embryos formed significantly fewer viable fetuses than did zona-intact embryos. The lower incidence of fetal development observed following transfer of zona-free 8-cell hamster embryos may have resulted in part from the formation of chimeras by fusion of these embryos $\text{in}$$\text{utero}$. Such fusion was observed to occur $\text{in}$$\text{vitro}$ between zona-free embryos placed in close proximity. The proportion of pregnancies resulting from transfer of bovine blastocysts cultured from zona-free morulae was similar to that of zona-intact embryos.In this study we have demonstrated that (1) enzymic and mechanical procedures used to remove zonae pellucidae from uterine-stage hamster and bovine embryos do not adversely affect subsequent development of these embryos $\text{in}$$\text{vitro}$ and $\text{in}$$\text{vivo}$ and (2) zonae pellucidae are not required for normal development of these embryos. These findings have implications for microsurgery of mammalian embryos and for embryo transfer.     

The effect of experimentally induced triploidy on the lethal expression of the t12 mutation in mouse embryos

Diploid embryos which are homozygous for the t¹² mutation die at the morula stage. In the current studies, ova from heterozygous ($\text{+}\text{t}{}^{12}$) females were fertilized in vitro with spermatozoa from $\text{+}\text{t}{}^{12}$ males. The fertilized ova were immediately placed into media containing cytochalasin B to prevent second polar body formation, producing +/+/+, +/+/t¹², +/t¹²/t¹², and t¹²/t¹²/t¹² embryos. The subsequent development of these triploid embryos was compared with that of diploid +/+, $\text{+}\text{t}{}^{12}$, and $\text{t}{}^{12}\text{t}{}^{12}$ embryos developing from ova which were also fertilized in vitro with spermatozoa from $\text{+}\text{t}{}^{12}$ males but which were not treated with cytochalasin B immediately following gamete coincubation. The data show that those triploid embryos which possess a wild-type allele and two mutant alleles are phenotypically wild type while those possessing three mutant alleles are not phenotypically distinguishable from their diploid ($\text{t}{}^{12}\text{t}{}^{12}$) counterparts. Like $\text{t}{}^{12}\text{t}{}^{12}$ embryos, t¹²/t¹²/t¹² embryos die at the morula stage, prior to blastocoelic cavity formation.     

Cell surface glycosyltransferase activities during normal and mutant (TT) mesenchyme migration

Migrating cells possess surface glycosyltransferase activity toward extracellular substrates, and the appearance of enzyme activity coincides with the onset of cellular migration (Shur, 1977a, Shur, 1977b, Develop. Biol.58, 23–39, 40–55; E. A. Turley and S. Roth, 1979, Cell17, 109–115). In this paper, surface glycosyltransferases were examined during normal and $\text{T}\text{T}$ mutant mesenchyme migration. Of six glycosyltransferases that were assayed, only galactosyltransferase was present at significant levels on the cell surface, despite the presence of a variety of intracellular glycosyltransferases. All controls have been performed to show clearly the enzyme activity was cell surface localized. In both normal and $\text{T}\text{T}$ embryos, surface galactosyltransferase activity was localized, by autoradiography, primarily to migrating mesenchymal cells, and to a lesser degree, to presumptive neural epithelium. During primitive streak formation, putative $\text{T}\text{T}$ embryos were devoid of surface galactosyltransferase activity. However, as development progressed, the $\text{T}\text{T}$ level of activity eventually exceeded wild-type levels by two- to sixfold and was evident in $\text{T}\text{T}$ tissues prior to the onset of microscopic pathology. Other surface enzymes assayed did not show any $\text{T}\text{T}\text{-}\text{dependent}$ increase in activity. The extracellular galactosyl acceptors were not chloroform:methanol soluble, and glycopeptides prepared by exhaustive Pronase digestion were excluded from Sephadex G-50. This large galactosylated glycoconjugate was readily digestable with endo-β-galactosidase, and, therefore, is similar to the poly-N-acetyllactosamine chains previously identified on early embryonic tissues (A. Kapadia, T. Feizi, and M. J. Evans, 1981, Exp. Cell. Res.131, 185–195; T. Muramatsu, G. Gachelin, M. Damonneville, C. Delarbre, and F. Jacob, 1979, Cell18, 183–191; A. Heifetz, W. J. Lennarz, B. Libbus, and Y. -C. Hsu, 1980, Develop. Biol.80, 398–408). These results support an involvement of surface galactosyltransferases in mesenchyme formation and during migration on poly-N-acetyllactosamine substrates.     

Abnormalities of neural tube formation in pre-spina bifida splotch-delayed mouse embryos

The splotch-delayed homozygous mutant (Spd/Spd) develops spina bifida with or without exencephaly, has spinal ganglia abnormalities, and delays in posterior neuropore closure and neural crest cell emigration. The heterozygote (Spd/+) has a pigmentation defect, and occasionally neural tube defects. To investigate the underlying mechanisms, we compared the neuroepithelium in the posterior neuropore region of cytogenetically identified 15-18 somite pair Spd/Spd, Spd/+, and +/+ mouse embryos by transmission electron and light microscopy. The notochordal area and cell number in the non-fused neuroepithelium region of Spd/Spd and Spd/+ embryos were significantly reduced compared to those of normal (+/+) embryos, which suggests an abnormality in notochord elongation. In the mesoderm, the mean cell number and mean ratio of cell number to area in the non-fused region were significantly lower in the Spd/Spd compared with +/+ embryos. The distance of exposed neuroepithelium above the mesoderm in the just-fused region was significantly lower in the Spd/Spd versus +/+ embryos, which may indicate an insufficient force exerted by the mesoderm during neural tube closure. Within the neuroepithelium, significantly more intercellular space was found in Spd/Spd than in +/+ embryos indicating disorganization. The basal lamina was poorly organized and the formation delayed around the neural tube in Spd/Spd and Spd/+ embryos. All together, these results suggest an early abnormality in interactions among the neuroepithelium, mesoderm, and notochord, which may lead to the delay or inhibition of neural tube closure observed in Spd/Spd mutants.     

The cell cycle and retinal histogenesis fidget mutant mice.

The autoradiographic method using [³H]thymidine has shown that the autosomal recessive mutant gene fidget (gene symbol fi) prolonging the presynthetic period of the cell cycle in the retinal anlage in homozygotes retards the transition of retinal cells to the differentiated state. Some retinal cells of normal embryos (+/+) start their transition to the differentiated state on the 11th day of embryogenesis, while in $\text{fi}\text{fi}$ embryos this process starts only on the 12th day. An active transition of retinal cells to the differentiated state especially in the peripheral zone of the mutant retina takes place 2 days later as compared to normal embryos. The number of differentiating cells in the retina of mutants at the stages of development studied is considerably lower as compared to the norm. The analysis of the cell cycle parameters in 15-day embryos has shown that in the mutants the retina is less mature as compared to +/+ embryos. The sequence of transition of various cell types to the differentiated state in the retina of $\text{fi}\text{fi}$ embryos is the same as in the norm. Gene fidget seems to interfere with proliferative rather than critical (quantal) cell cycles in the developing mouse retina.     

Lactose transport in Escherichia coli cells Dependence of kinetic parameters on the transmembrane electrical potential difference

We determine the kinetic parameters $\text{V}$ and $\text{K}{}_{\mathrm{<mtext>T</mtext>}}$ of lactose transport in Escherichia coli cells as a function of the electrical potential difference (Δψ) at pH 7.3 and $\text{Δ}\text{pH}\text{= 0}$. We report that transport occurs simultaneously via two components: a component which exhibits a high $\text{K}{}_{\mathrm{<mtext>T</mtext>}}$ (larger than 10 mM) and whose contribution is independent of Δψ, a component which exhibits a low $\text{K}{}_{\mathrm{<mtext>T</mtext>}}$ independent of Δψ (0.5 mM) but whose $\text{V}$ increases drastically with increasing Δψ. We associate these components of lactose transport with facilitated diffusion and active transport, respectively. We analyze the dependence upon Δψ of $\text{K}{}_{\mathrm{<mtext>T</mtext>}}$ and $\text{V}$ of the active transport component in terms of a mathematical kinetic model developed by Geck and Heinz (Geck, P. and Heinz, E. (1976) Biochim. Biophys. Acta 443, 49–63). We show that within the framework of this model, the analysis of our data indicates that active transport of lactose takes place with a H⁺/lactose stoichiometry greater than 1, and that the lac carrier in the absence of bound solutes (lactose and proton(s)) is electrically neutral. On the other hand, our data relative to facilitated diffusion tend to indicate that lactose transport via this mechanism is accompanied by a H⁺/lactose stoichiometry smaller than that of active transport. We discuss various implications which result from the existence of H⁺/lactose stoichiometry different for active transport and facilitated diffusion.     

Experimental studies on a mutant gene (e) preventing the differentiation of eye and normal hypothalamus primordia in the axolotl

The phenotype of axolotls (Ambystoma mexicanum) homozygous for the mutant gene e (“eyeless”) is different from normal in that (1) no optic vesicles develop in $\text{e}\text{e}$ embryos, (2) $\text{e}\text{e}$ larvae from posthatching onward are darker than normal white larvae, and (3) fully grown $\text{e}\text{e}$ animals are sterile.Experiments reported here show that eyelessness in $\text{e}\text{e}$ embryos results from a direct effect of the gene on presumptive forebrain ectoderm; not on the mesoderm that induces the ectoderm to form eyes. Homotopic grafts of normal presumptive ectoderm on $\text{e}\text{e}$ blastula hosts differentiated complete eyes, but reciprocally grafted embryos were always eyeless. Similarly, grafts of either $\text{e}\text{e}$ or normal presumptive prechordal mesoderm into normal hosts gave normal eyes, but in the mutant hosts no eyes developed. Thus the e gene affects only the ectodermal component of the inductive system for eye formation.Genetically eyeless (pigmented) cells, when interspersed prior to gastrulation among genetically eyed (albino) cells in the eye preprimordium, are induced to form clones of pigmented retinal epithelium in the albino host eye.The sterility of $\text{e}\text{e}$ larvae appears also to be due to a direct effect of the e gene on the ectodermal (neural plate) primordium of the hypothalamus. Grafts of normal cells which included the hypothalamic, but not the optic or anterior pituitary primordia, always restored fertility to $\text{e}\text{e}$ recipients.The mutant pigmentation phenotype was demonstrated to be a consequence of eyelessness and, therefore, an indirect effect of the gene. The pigment pattern of normal embryos from which both optic vesicles were removed resembles that of the mutants. In addition, implantation of a single full-sized, functional eye was able to restore the normal pigmentation, but not fertility, to $\text{e}\text{e}$ recipients.     

The effect of embryo quality at freezing on subsequent development of thawed cow embryos

Day 7 to 9 embryos were frozen by a rapid two-step method to ?38°C before being plunged into liquid nitrogen. Glycerol was used as the cryoprotectant and, following thawing, the embryos were cultured for 12 – 24 hours in PBS + 15% heat-treated steer serum. In Experiment 1, embryos were frozen in 2.0 ml glass ampoules or 0.5 ml Cassou straws. Two levels of glycerol (1.0M and 1.4M) gave comparable $\text{in vitro}$ survival rates ($\text{12}\text{20}$ and $\text{13}\text{25}$, respectively). A greater proportion of embryos developed in culture after freezing in straws. In Experiment 2, embryos were classified morphologically before and after freezing into 5 grades (1 = excellent; 2 = good; 3 = fair; 4 = poor; 5 = degenerate). Only embryos of grade 1, 2 and 3 were frozen. The post-thaw survival rates for embryos graded 1, 2 and 3 before freezing were 100% ($\text{11}\text{11}$), 86% ($\text{24}\text{28}$) and 83% ($\text{20}\text{24}$), respectively. Furthermore, the porportion of surviving embryos estimated to be of poor quality (grade 4) was greater for embryos graded 3 before freezing ($\text{13}\text{20}$) than for embryos graded 2 ($\text{6}\text{24}$) or 1 ($\text{1}\text{11}$). The percentage of embryos which developed normally after $\text{in vitro}$ culture for each of the pre-freezing grades 1, 2 and 3 was 91% ($\text{10}\text{11}$), 50% ($\text{14}\text{28}$) and 29% ($\text{7}\text{24}$), respectively. Of the total number of frozen-thawed embryos which developed in culture, $\text{5}\text{31}$ (16%) were of poor quality. The proportion of poor quality developing embryos was greater inembryos graded 3 before freezing ($\text{3}\text{7}$) than those graded 2 ($\text{2}\text{14}$). All of the embryos graded 1 before freezing and which developed in culture were of good quality. Results indicate that, if high post-thaw survival rates are to be obtained, stringent embryo selection processes will be required.     

Phase transition characteristics of diphosphatidylglycerol (cardiolipin) and stereoisomeric phosphatidyldiacylglycerol bilayers: Mono- and divalent metal ion effects

Synthesis and phase transition characteristics of aqueous dispersions of the homologous (12 : 0, 14 : 0, 16 : 0) diphosphatidylglycerols (cardiolipins) and phosphatidyldiacylglycerols are reported. Electron microscopy of the negatively stained aqueous dispersions reveals a characteristic lamellar structure suggesting that these phospholipid molecules are organized as bilayers in the aqueous dispersions. The phase transition temperature ($\text{T}{}_{\mathrm{<mtext>m</mtext>}}$) and the enthalpy of transition ($\text{ΔH}$) increase monotonically with chain length in the cardiolipin and phosphatidyldiacylglycerol series; $\text{T}{}_{\mathrm{<mtext>m</mtext>}}$ for phosphatidyldiacylglycerol is higher than that for cardiolipin of the same chain-length. The transition temperatures for the enantiomeric $\text{sn-3,3-}\text{and}\text{sn-1,1-}\text{phosphatidyldiacylglycerol}$ and for the diastereomeric, $\text{meso}\text{-sn-1,3-}\text{phosphatidyldiacylglycerol}$ are approximately the same. The molar enthalpy for the transition of cardiolipin-NH₄⁺ bilayers is approximately twice the value for the phosphatidylcholines of the same chain length, i.e., the molar enthalpy per acyl chain is approximately the same in the two systems. The transition temperatures for metal ion salts of C_{1 6}-cardiolipin exhibit a biphasic dependence upon the unhydrated ionic radii, i.e. the highest $\text{T}{}_{\mathrm{<mtext>m</mtext>}}$ is observed for Ca²⁺- cardiolipin and decreases for the salts of ions with smaller and larger ionic radii than that of Ca²⁺. The lowest $\text{T}{}_{\mathrm{<mtext>m</mtext>}}$ is observed for Rb⁺-cardiolipin. Monovalent metal salts of cardiolipin exhibit two phase transitions. This effect may result from different conformational packing of the four acyl chains due to differences in metal-phosphate binding.     

Site of gene action in the development of hair pigment in recessive yellow (ee) mice

The site of gene action of the extension (e) locus in the mouse was investigated through the use of the neural tube-skin recombination grafting technique. Recessive yellow ($\text{e}\text{e}\text{,}\text{a}\text{a}$) neural tubes were grown with nonyellow ($\text{E}{}^{\mathrm{+}}\text{E}{}^{\mathrm{+}}\text{,}\text{a}\text{a}$) skin, and nonyellow neural tubes with recessive yellow skin. It was found that the production of phaeomelanin was controlled by the genotype of the melanocyte and that the skin genotype had no influence on the type of pigment synthesized. However, recessive yellow melanocytes synthesized phaeomelanin only in the hair follicle environment. Eumelanin is produced in all extrafollicular environments. The action of the extension and agouti loci therefore differ in determining the production of phaeomelanin in the mouse.     

Aggregation of homozygous Brachyury (T) cells in the culture supernatant of wild-type or mutant embryos

Dissociated cells from wild-type or homozygous mutant (T/T) embryos of mice were cultured in the culture supernatant of +/+ or T/T embryos on a gyratory shaker. The aggregation was promoted by the culture supernatant in the following combinations; +/+ cells in +/+ culture supernatant, +/+ cells in T/T supernatant and T/T cells in +/+ supernatant. When T/T cells were cultured in T/T supernatant, however, only a slight promotion of the aggregation was observed.     

Ultraviolet effects on presumptive primordial germ cells (pPGCs) in Xenopus laevis after the cleavage stage

The presumptive primordial germ cell (pPGC) number with development after the cleavage stage and the fate of pPGCs damaged by uv irradiation were studied in successive Epon sections (0.5 μm thick) with the light microscope in both uv-irradiated and unirradiated Xenopus embryos. taking survival rate and sterility into consideration. The pPGCs of the uv-irradiated embryos occupy nearly the same location in the embryos as those of the unirradiated embryos at stages 12, 17, 23, and 28 [see Ikenishi, K., and Kotani, M. (1975). Develop. Growth Different. 17, 101–110]. At stage $\text{33}\text{34}$ they are found in the central part of the endoderm cell mass in the uv-irradiated embryos, while they are situated in the lateral or dorsal part of the endoderm cell mass in the unirradiated. In the uv-irradiated embryos, a cavity which was never found in the unirradiated embryos was observed in the endoderm cell mass beneath the archenteron cavity and in the almost-median part of the posterior endoderm cell mass at stages 17 and 23, respectively, and some vacuoles in pPGCs as well as in somatic cells around those pPGCs were noticed at stages $\text{17–}\text{33}\text{34}$. The number of pPGCs of the unirradiated enbryos increases about three- or fourfold during stages 12–46, while the pPGCs of the uv-irradiated embryos slowly increase in number from stage 17 to stage 28, indicating that the division occurs in pPGCs, then decrease with development and finally disappear from the tadpole.     

Evidence for dosage compensation of an X-linked gene in the 6-day embryo of the mouse.

The time at which dosage compensation of an X-linked gene in the mouse is established has been estimated by measuring the activity levels of two glycolytic enzymes, phosphoglycerate kinase (EC 2.7.2.3) and triosephosphate isomerase (EC 5.3.1.1), during early development of embryos from $\text{X}\text{X}$ and $\text{X}\text{O}$ mice. During preimplantation development the level of phosphoglycerate kinase in embryos from $\text{X}\text{X}$ mice was constant for the first 48 hr of development (2.55–2.71 nmoles/hr/embryo) and then dropped to one-half the earlier level (1.44 nmoles/hr/embryo) by 72 hr of development. The general developmental profile of phosphoglycerate kinase was similar in embryos from $\text{X}\text{O}$ mice; however, the absolute level of enzyme activity was reduced to approximately 1.4 nmoles/hr/embryo during the first 48 hr of development and to 0.9 nmoles/hr/embryo by 72 hr of development. These differences in phosphoglycerate kinase levels between embryos from $\text{X}\text{X}$ and $\text{X}\text{O}$ mice disappeared between the blastocyst and egg cylinder stages (150 hr postplug) during which time the activity levels had increased to 183 and 193 nmoles/hr/egg cylinder for embryos from $\text{X}\text{O}$ and $\text{X}\text{X}$ mice, respectively.The activity level for triosephosphate isomerase in embryos from $\text{X}\text{X}$ and $\text{X}\text{O}$ mothers did not differ at any stage of development; this suggests that the gene coding for triosephosphate isomerase is autosomal. In addition the level of activity remained constant during preimplantation development (approximately 3 nmoles/hr/embryo) and then, like phosphoglycerate kinase, increased 100-fold between the blastocyst and egg cylinder stages.The frequency distribution of the activity ratio (triosephosphate isomerase to phosphoglycerate kinase) in the egg cylinder of individual embryos from both $\text{X}\text{X}$ and $\text{X}\text{O}$ mothers was determined in order to detect differences among $\text{X}\text{X}\text{,}\text{X}\text{O}$ and $\text{X}\text{Y}$ embryos. These frequency distributions were unimodal, and hence these results coupled with the gene dosage differences observed during preimplantation development indicate that dosage compensation for an X-linked gene has been established in the 6-day mouse embryo.     

Embryonic development in repeat breeder and virgin heifers seven days after insemination

The aim of this study was to compare the development of embryos from repeat breeder heifers with that of embryos from virgin heifers at 7 days after standing heat. A total of 23 repeat breeder heifers (RBH) and 18 virgin heifers (VH) were utilized. The heifers were between 16 and 30 months of age and most of them were of the Swedish Red and White Breed. Two RBH were heterozygous for the $\text{1}\text{29}$ chromosome translocation, one RBH was a trisomy X and all the other heifers had normal karyotypes. All heifers were inseminated with frozen semen from the same bull and all inseminations were performed by the author. The fertility of the bull was above the average for the AI association to which it belonged. Embryos were collected by a non-surgical technique (89) or after slaughter (19). The morphology of the embryos was examined under a phase-contrast microscope and they were classified as being normal (N), morphologically deviating (MD) or degenerated (D). Thirteen embryos from RBH and 15 from VH were examined for total cell numbers after examination of their morphology.There was no significant difference in recovery rates of embryos between RBH (68%) and VH (76%) but independent of collection method the recovery rate of embryos from VH was numerically higher. The fertilization rate was high in both RBH (89%) and VH (97%). Seventyfour percent of the embryos collected from VH were normal ($\text{23}\text{31}$) while only 28% ($\text{11}\text{40}$) of the embryos collected from RBH had a normal morphology. The difference in number of normal embryos recovered from the two groups of heifers was highly significant (P < 0.005). Exclusion of the RBH heifers with deviating karyotype did not influence this difference. However, there was a tendency to a higher incidence of fertilization failure and morphologically deviating embryos in these heifers. The N embryos had significantly higher total cell numbers (P < 0.005) than the MD embryos but there was no significant difference in total cell numbers between N embryos from RBH or VH.The results of this study strongly indicate a higher incidence of abnormal embryos in RBH than in VH. It is likely that these deviations are followed by an increased incidence of early embryonic death.     

In vitro development of early postimplantation rat embryos

Rat embryos explanted at $\text{7}\text{1}\text{2}$ or $\text{8}\text{1}\text{2}$post coitum were cultured throughout the major stages of organogenesis in a system of rotating bottles containing heat-inactivated, immediately centrifuged (I.C.) serum. About 80% of the $\text{8}\text{1}\text{2}\text{-}\text{day}$ explants and 50% of the $\text{7}\text{1}\text{2}\text{-}\text{day}$ explants developed a blood circulation in the yolk sac; in these embryos, organogenesis and growth rates were similar to those of embryos in vivo. In cultures continued for 4 or 5 days, many of the embryos developed 30–40 somites. There was little difference in the subsequent development of embryos cultured in maternal serum or male serum during the egg-cylinder stage except for a possible decrease in the frequency of normal axial rotation in embryos from the male serum. Development in rotator bottles was much better than in watchglass cultures.