Perfluorocarbon-based medium for culture of the early chick embryo heart

Summary In an attempt to prolong the survival of the explanted early chick embryo heart, hearts at stages 10 to 28 were cultured in supplemented Dulbecco's modified Eagle's medium with or without the perfluorocarbon, perfluorotributylamine. The perfluorocarbon was added to the standard culture medium in a 50∶50 (vol/vol) mixture. Explants were evaluated daily and were harvested for light microscopy after 2 to 10 d in culture. The tubular shape of the explants was generally maintained for 2 d in culture, after which the hearts became dilated or spherical. Beating was noted in some of the explants on Day 2 in culture but not thereafter. Microscopic evaluation showed patchy areas of necrosis in all explants by Day 3, although large areas of viable epithelioid cells were documented as long as 7 d after explantation. State 16 to 18 hearts cultured in the presence of perfluorocarbon were more likely to maintain tubular architecture on microscopy than hearts cultured in standard medium. Hearts cultured from later stages showed no improvement in appearance with the presence of perfluorocarbon and there was a suggestion of increased necrosis in later-stage explants cultured with pefluorocarbon for 4 d. Further modification of the culture system will be required to prolong explant survival and development beyond 2 d.     

The effects of retinoic acid on heart formation in the early chick embryo.

The vitamin A derivative retinoic acid has previously been shown to have teratogenic effects on heart development in mammalian embryos. The craniomedial migration of the precardiac mesoderm during the early stages of heart formation is thought to depend on a gradient of extracellular fibronectin associated with the underlying endoderm. Here, the effects of retinoic acid on migration of the precardiac mesoderm have been investigated in the early chick embryo. When applied to the whole embryo in culture, the retinoid inhibits the craniomedial migration of the precardiac mesoderm resulting in a heart tube that is stunted cranially, while normal or enlarged caudally. Similarly, a local application of retinoic acid to the heart-forming area disrupts the formation of the cardiogenic crescent and the subsequent development of a single mid-line heart tube. This effect is analogous to removing a segment of endoderm and mesoderm across the heart-forming area and results in various degrees of cardia bifida. At higher concentrations of retinoic acid and earlier developmental stages, two completely separate hearts are produced, while at lower concentrations and later stages there are partial bifurcations. The controls, in which the identical operation is carried out except that dimethyl sulphoxide (DMSO) is used instead of the retinoid, are almost all normal. We propose that one of the teratogenic effects of retinoic acid on the heart is to disrupt the interaction between precardiac cells and the extracellular matrix thus inhibiting their directed migration on the endodermal substratum.     

Ventilatory response to hyperoxia in the chick embryo

In the avian embryo at term we measured the ventilatory response to hyperoxia, which lowers the chemoreceptor activity, to test the hypothesis that the peripheral chemoreceptors are tonically functional. Measurements of pulmonary ventilation (VE) were conducted in chicken embryos during the external pipping phase, at 38 degrees C, during air and hyperoxia, and during hypercapnia in air or in hyperoxia. Hyperoxia (95% O2) maintained for 30 min lowered VE by 15-20%, largely because of a reduction in breathing frequency (f). The oxygen consumption and carbon dioxide production of the embryo were not altered. The hyperoxic drop of VE was more marked in those embryos, which had higher values of normoxic VE. Hypercapnia, whether 2 or 5% CO2, increased VE, almost exclusively because of the increase in tidal volume (VT). The increase in VT was less pronounced when hypercapnia was associated with hyperoxia, and f slightly decreased. Hence, in hyperoxia, the VE response to CO2 was less than in air. The results are in support of the hypothesis that in the avian embryo, after the onset of breathing, the peripheral chemoreceptors exert a tonic facilitatory input on . This differs from neonatal mammals, where the chemoreceptors have minimal or no activity at birth, presumably because the increased arterial oxygenation with the onset of air breathing is a much more sudden phenomenon in mammals than it is in birds.     

Glycosaminoglycans in early chick embryo

The developmental profile of glycosaminoglycans (GAGs) were examined by cellulose acetate electrophoresis and high performance liquid chromatography in the early chick embryo from late blastula (stage XIII+) to early somite developmental stages (stage HH7-9). Sulphated GAGs were present from the earliest stages. They were more abundant than the non-sulphated forms and showed stage-related changes. Chondroitin sulphate and especially dermatan sulphate appeared to be the predominant GAGs in embryos at stage XIII+. Dermatan sulphate was about three times as abundant as chondroitin sulphate at stage XII+. In contrast, embryos at the definitive streak stage (stage HH4) produced about twice as much chondroitin sulphate as dermatan sulphate. At the head process stage (stage HH5), the level of chondroitin sulphate was reduced and its relative content in the embryo was about the same as dermatan sulphate. Levels of dermatan sulphate were more than five times those of heparan sulphate from stage XIII through to stage HH5 and three times more at stage HH7-9. The 4- and 6- sulphation of chondroitin sulphate increased 14- and 10-fold respectively, from stage XIII+ to stage HH 7-9. The sulphation pattern of chondroitin sulphate had a delta(di)-4S:delta(di)-6S molar ratio ranging from 4 to 8:1 and a delta(di)-4S:delta(di)-OS molar ratio ranging from 9 to 16:1 and was developmentally regulated. Thus, chondroitin sulphate in the early chick embryo was sulphated predominately in the 4-position in all stages studied. The presence of both 4- and 6-sulphated disaccharides in chondroitin sulphate indicated that both 4 and 6 sulfotransferases were active in the early embryo. Hyaluronate and sulphated GAG content increased markedly at gastrulation when the first major cellular migrations and tissue interactions begin.     

Method for electroporation for the early chick embryo

In vitro whole-embryo culture of chick embryos, originally invented by New, has been widely used for studies of early embryogenesis. Here, a method for electroporation using the New culture and its derivatives is described, to achieve misexpression of exogenous gene in a temporally and spatially controlled manner in gastrulating chick embryos. Detailed information for the devices and procedures, and some experimental examples are presented.     

Limbness in the early chick embryo lateral plate

In order for the limb to be useful in the evaluation of early determinants of morphogenesis, it is necessary to understand some of the characteristics associated with "limbness" and, more importantly at the beginning at least, it is necessary to know what regions of the early embryo exhibit limbness qualities. Previous investigators have assumed, without direct experimental evidence, that the flank does not have limbness qualities, even at early stages of development. However, there are a few studies suggesting that the early flank does possess limbness qualities. The purpose of the present study was to determine how extensively the qualities of limbness exist in the early chick embryo. Tissues from the future neck, wing, flank, and leg regions were grafted to host celoms and evaluated for their abilities to form limbs. Limbs developed from all four regions of stage 11-14 embryos, but after stage 14 only grafts from the wing and leg regions formed limbs.     

Serum protein synthesis in the early chick embryo

Isolated yolk-sacs of chick embryos secreted serum proteins when incubated in buffered chick Ringer's solution. The presence of serum transferrin, two embryo-specific alpha-globulins, and a prealbumin were demonstrated by acrylamide gel analysis. Yolk-sacs from embryos explanted at 11-13 somites (40 hr preincubation) and cultured for 48 hr secreted in addition a protein with the mobility of serum albumin. Incubation of yolk-sacs in the presence of radioactive valine indicated that serum proteins were synthesized as early as the primitive streak stage. By incubating isolated yolk-sacs and embryos from 48-hr explants in the presence of radioactive valine, the synthesis of serum proteins was found to be restricted to the yolk-sac at this stage of development. Culturing explants on various nutrient proteins as well as protein starvation medium altered the relative synthesis of several serum proteins. We have proposed that morphological and biochemical changes in embryos resulting from altered nutrition may be mediated by the proteins of the serum.     

Translocation of glucose transporters in response to anoxia in heart

We tested whether translocation of glucose transporters between subcellular membrane fractions is involved in the stimulation of glucose transport by anoxia by perfusing rat hearts in the presence or absence of oxygen. The hearts were then fractionated by a modification of the procedures of Watanabe, et al. (Watanabe, T., Smith, M. M., Robinson, F. W., and Kono, T. (1984) J. Biol. Chem. 259, 13117-13122), who previously demonstrated translocation in response to insulin in heart, to give plasma membrane and high-speed pellet fractions. The contents of glucose transporters in the two fractions were determined by reconstitution of transport activity, D-glucose-reversible binding of cytochalasin B, and labeling with antibodies against the erythrocyte transporter. The heart transporter was also recognized by antibodies against the COOH-terminal peptide of the glucose transporter. All three types of assays revealed a decrease (20-30%) in the high-speed pellet fraction and an increase (20-70%) in the plasma membranes in response to anoxia. Treatment of hearts with insulin produced a similar extent of translocation and a similar stimulation (about 2-fold) of glucose uptake, indicating that translocation plays a role of similar importance in the stimulation of transport by both of these effectors.     

Concanavalin A-binding by cells of the early chick embryo

The surfaces of cells from the early embryo of the chick were examined using electron microscope techniques for the visualization of concanavalin A-binding sites. Horseradish peroxidase and Ferritin labelled concanavalin A were used to determine the distribution of the binding sites. All surfaces of the epiblast and hypoblast layers which were accessible to concanavalin A showed the presence of binding sites in stage 1 embryos. The ventral surface of the epiblast showed a high lectin affinity which may reflect the development of a basal lamina on this surface. The individual hypoblast cells at this stage showed a non-uniform distribution of binding sites, having a greater affinity on the dorsal surface than the ventral. By the time of primitive streak formation (stage 4-5) the dorsal surface of the epiblast displayed increased binding sites, while the frequency of sites on the ventral surface of the endoblast was reduced. The latter may reflect a change from one cell population to another, which occurs in the lower layer of the embryo at this time. No consistent correlation could be drawn between changes in motility of cells actually invaginating through the primitive streak and changes in affinity for concanavalin A. An overall increase in affinity of the dorsal surface of the epiblast was revealed by Ferritin and may reflect the changes in surface structure occurring in readiness for the morphogenetic migrations of gastrulation.