Changes in tropomyosin during primary culture of embryonic myocardiocytes.

We chose the Hamburger and Hamilton's stage 29 (HH 29) to investigate the expression of tropomyosin in chick myocardiocytes during 14 days on culture. Throughout 14 days of cell culture, changes in cell morphology were accompanied by a redistribution of tropomyosin in different cell compartments. We used FACScan, SDS-PAGE and densitometric analysis to quantify total cell tropomyosin and concentrations of this protein in different cell fractions. Tropomyosin was found mostly in the cytoskeletal fraction than in the cytoplasmic. When we compared the densitometric values from SDS-PAGE of cells in different stages of development we found that in HH 19, tropomyosin was more abundant in the cytoplasmic than in the cytoskeletal fraction. By HH 29, the two fractions had become inverted, and in HH 39, tropomyosin was clearly more abundant in the cytoskeletal than in the cytoplasmic fraction. In the IFI analysis, tropomyosin was found to label the Stress fiber-like structures (SFL) in different patterns depending on the area of the cell which expressed this protein.     

Temporospatial patterns of apoptosis in chick embryos during the morphogenetic period of development

We examined the temporospatial pattern of naturally occurring apoptosis in chick embryos to five days of incubation (H.H. stages 1-25; Hamburger and Hamilton, 1951) using TUNEL labeling. The initial TUNEL-positive structure was the embryonic shield at stage 1. Apoptotic cells became ubiquitously present within embryos by stage 3, which is early in gastrulation. Until stage 6, TUNEL-positive cells were restricted to the headfold region. In embryos of stages 7-8, most cell death was localized at the most anterior neural plate. TUNEL-positive neural plate, notochord and somites appeared at stage 9. Otic and optic regions became TUNEL-positive at stage 11. The aggregation of cells from which the tail bud arises contains apoptotic cells from stage 11 onwards. At stage 16, scattered TUNEL-positive cells appeared in the branchial arches. Three streams of apoptotic neural crest cells in the cranial region became most clearly visible at stage 18. The secondary neural tube from which caudal structures develop contains apoptotic cells at stage 14. Apoptotic cells are present in the branchial arches and lateral body wall for extended periods, stages 16-25 and 25 respectively. At stages 24-25, intense positive regions of cell death were confined to the caudal regions of the arches, to limb and tail buds and to the lateral body wall, the latter in relation to body wall closure. The new findings in this study are discussed along with past studies to provide the temporospatial pattern of cell death during early chick development.     

Immunomagnetic purification of viable primordial germ cells of Japanese quail (Coturnix japonica).

Immunomagnetic cell sorting (MACS) with the monoclonal antibody (mAb) QCR1 was compared with the Ficoll density-gradient centrifugation system (FICS) in terms of the efficiency of enrichment of quail (Coturnix japonica) primordial germ cells (PGCs) from blood. The purified PGCs were tested for their ability to settle in the chick (Gallus domesticus) embryonic gonad. Blood containing 60-100 PGCs microliter-1 was taken from the dorsal aorta of quail embryos at Hamburger and Hamilton's stages 14-16. The amount and concentration of PGCs in the PGC-rich fraction purified by MACS were greater than in the fraction purified by FICS. Purified quail PGCs were transfused into chick embryos at stages 14-16 and immunohistochemically stained with mAb QCRI on day 8 of chick development. Transfused PGCs purified by either MACS or FICS were positively stained in the chick embryonic gonads.     

Ectodermal ablation of the third branchial arch in chick embryos and the morphogenesis of the parathyroid III gland.

The parathyroid glands have been classically considered to be derivatives of the third and fourth pharyngeal pouches in most species, including humans. Furthermore, the presence of neural crest-derived cells in the parathyroid glands connective tissue has been apparently established. However, our previous studies have provided a new hypothesis on the origin of these glands in human and chick embryos. To determine the origin of the parathyroid III (P3) gland, ectoderm of the third branchial arch was cauterized in chick embryos at Hamburger and Hamilton's stage 19 (embryonic day 3). Cauterization of the ventral half of the ectoderm was followed by the non-formation, on the same side, of the P3 gland. When the dorsal half of the ectoderm was cauterized, both the right and left P3 glands formed. Our observations suggest that the ectoderm of the ventral half of the third branchial arch is necessary for the organization of the P3 gland.     

Teratogenic effects of retinoic acid and dimethylsulfoxide on embryonic chick wing and somite

In order to document the stage(s) at which the embryonic chick wing bud is sensitive to vitamin A teratogenesis and the kinds of defects produced by vitamin A insult to the embryonic chick wing, 1-microgram doses of retinoic acid (1 microliter RA in 90% DMSO at a concentration of 1 microgram/microliter) were locally applied to the right wing bud of chick embryos at stages 17-23 (Hamburger and Hamilton: J. Morphol., 88:49-92, '51), and the resulting limb skeleton anatomy was observed at 10 days of incubation. Local application of RA at stages 17-20 resulted in distal wing skeleton defects. There were significantly more wing skeleton defects among embryos treated at these stages with RA solution than among solvent (DMSO)-treated control embryos and than among untreated control embryos. Wings of embryos treated with RA at stages 21-23 were always normal. Scapular and vertebral defects were seen at 10 days of incubation among embryos which had been treated prior to stage 21 with both the RA solution and the solvent control. Statistical analysis and histological data suggest that scapular and vertebral defects were caused by DMSO-induced damage to somites.     

In vitro reformation of the perichondrium from perichondrial-free Meckel's cartilages of the embryonic chick

Perichondria were removed from Meckel's cartilages of chick embryos of Hamburger and Hamilton stages 34, 38, or 39 (8, 12, or 13 days of incubation) and cultured, either at the air-medium interface or submerged, under standard organ culture conditions, for 7 to 21 days. Meckel's cartilages formed a new fibrous perichondrium by the 10th day of culture. Perichondria both formed earlier and were thicker in those cartilages cultured at the air-medium interface than in those cultured submerged. Histological and ultrastructural analysis indicated that the outermost layer of Meckelian chondrocytes dedifferentiated into fibrous cells to form the new fibrous perichondrium; i.e., the fibrous perichondrium can arise from superficial chondrocytes.     

Mean weights of chick embryos correlated with the stages of Hamburger and Hamilton

A total of 1125 normal chick embryos, representing 25 each of the 45 stages of Hamburger and Hamilton, were removed, fixed in Bouin's solution, stored in 70% ethanol and weighed with a semi-micro analytical balance. Entire blastoderms of stages 1–8 were weighed, whereas only embryos-proper were weighed in stages 9–45. As a consequence, results constituted two groups, each of which showed a geometric rate of growth marked only by minor deviations which were related to specific events of normal growth and development.     

Stage-related capacity for limb chondrogenesis in cell culture.

Cells from wing buds of varying-stage chick embryos were dissociated and grown in culture to test their capacity for cartilage differentiation. Micro-mass cultures were initiated with a cell layer greater than confluency, which occupied a restricted area of the culture dish surface (10–13 mm²). Cells from stage 24 chick embryo wing buds (prior to the appearance of cartilage in vivo) undergo cartilage differentiation in such cultures. Typically, during the first 1–2 days of culture, cells form aggregates (clusters of cells with a density 1.5 times greater than that of the surrounding nonaggregate area). By Day 3, virtually all aggregates differentiate into cartilage nodules which are easily recognized by their Alcian blue staining (pH 1.0) extracellular matrix. Subsequently, nodules increase in size, and adjacent nodules begin to coalesce. Micro-mass cultures were used to test the chondrogenic capacity of wing bud cells from chick embryos representing the different stages of limb development up to the appearance of cartilage in vivo (stages 17–25). Cells from embryo stages 21–24 form aggregates which differentiate into cartilage nodules in vitro with equal capacity (scored as number of nodules per culture). In contrast, cells from embryo stages 17–19 form aggregates in similar numbers, but these aggregates never differentiate into nodules under routine conditions. However, aggregates which form in cultures of stage 19 wing bud cells do differentiate into cartilage nodules if exposed to dibutyryl cyclic AMP and theophylline. Cells from stage 20 embryos manifest a varying capacity to form cartilage nodules; apparently, this is a transition stage. Cells from stage 25 embryos produce cartilage in vitro without forming either aggregates or nodules. Based on the results presented in this paper, the authors propose a model for cartilage differentiation from embryonic mesoderm cells involving: (1) aggregation, (2) acquisition of the ability to respond to the environment in the aggregate, (3) elevated intracellular cyclic AMP levels, and (4) stabilization and expression of cartilage phenotype.     

Studies on the mechanisms of neurulation in the chick: interrelationship of contractile proteins, microfilaments, and the shape of neuroepithelial cells

Electron microscopy and indirect immunofluorescence were employed to correlate the distribution patterns of major contractile proteins (actin and myosin) with 1) the organizational state of microfilaments, 2) the apical cell surface topography, 3) the shape of the neuroepithelial cells, and 4) the degree of bending of the neuroepithelium during neurulation in chick embryos at Hamburger and Hamilton stages 5-10 of development. Both actin and myosin are present at these developmental stages and colocalize in the neural plate as well as in later phases of neurulation. During elevation of neural folds, actin- and myosin-specific fluorescence is always most intense in regions where the greatest degree of bending of the neuroepithelium takes place [e.g., the midline of the V-shaped neuroepithelium (early neural fold stage) and the midlateral walls of the "C"-shaped neuroepithelium (mid-neural-fold stage)]. This intense fluorescence coincides with 1) a particularly dense packing of microfilaments and 2) highly constricted cell apices. After neural folds make contact, there is an overall reduction in both the intensity of apical fluorescence and the thickness of apical microfilament bundles, especially in the roof and floor of the neural tube. The remaining fluorescence in the contact area is apparently related to cellular movements during fusion of neural folds.     

Compatibility of chick embryo eye anlagen with the ectoderm of the early amphibian gastrula in vitro

Eye vesicles were isolated from the early chick embryos (stage 9+ after Hamburger and Hamilton, 1951) and combined with the Rana temporaria early gastrula ectoderm (EGE) in vitro. The tissues were jointly incubated in medium 199 diluted twice with deionized water at 22 +/- 1 degree for 7-8 days or the eye vesicles were removed from the EGE ectoderm within 16-18 h. At the joint long-term incubation of these tissues, a toxic effect of the chick embryonic tissues on the EGE cells was noted. In none of the experiments, the inducing effect of the eye vesicle on the EGE was found. Similar data were obtained when the EGE was jointly cultivated with the brain (stage 9-10) and retina (stage 15) of chick embryos. The brain of the chick embryos at stage 15 exerted a weak neuralizing effect on the EGE. In the control experiments, the eye vesicles explanted with the chick embryonic ectoderm remained viable till the end of cultivation but no lentoids formed in the ectoderm. The absence of lens-inducing effect at the joint cultivation of the chick embryonic eye vesicles with the EGE is considered as a result of disturbance of the synthesis or secretion of the corresponding agents rather than a sequence of the species "incompatibility" of the inductor and reacting tissue. Hence, the use of "xenogenic" tissue recombinants is not justified when analyzing the lens-inducing activity of the eye vesicles.     

Development of chicken epidermis cultured with embryo extract

The epidermis from 11-day-old chick embryo shank skin was cultured with 11-day-old chick embryo extract. The growth and the differentiation of the epidermis in culture were studied histologically, electron microscopically and with polyacrylamide gel electrophoresis of keratin proteins. The epidermis cultured with the chick embryo extract proliferated and stratum structures developed simultaneously with the increase in epidermal cell layers. Finally, a keratinized layer was observed after 10 days in culture. Electron microscopic observations revealed that tonofilaments were produced after 2 days in culture and increased thereafter with culture time, becoming condensed with desmosomes. Keratohyaline granules were observed in 7-day cultures. These keratinization characteristics occurring during culture showed the general characteristics of the alpha stratum observed in the skin of in ovo embryos during the early stages of development. However, the development of peridermal and subperidermal granules was poor and the stratum granulosum, which develops at the late stages between the stratum intermedium and the stratum corneum, was not observed. Polyacrylamide gel electrophoresis of S-carboxymethylated keratin proteins showed that the keratin protein band patterns of the culture differed from those of in ovo skin epidermis.     

Lack of either chondrocyte hypertrophy or osteogenesis in Meckel's cartilage of the embryonic chick exposed to epithelia and to thyroxine in vitro

Osteogenesis was not initiated when Meckel's cartilages from embryonic chicks of Hamburger and Hamilton (H. H.) stages 38 and 39 were recombined with mandibular epithelia obtained from embryos of H. H. stage 22 (a stage when an epithelial-mesenchymal interaction elicits osteogenesis from mandibular mesenchyme) and grafted to the chorioallantoic membranes of host embryos for 7 to 21 days. Failure of osteogenesis was not because the cartilage inhibited or blocked the osteogenesis-initiating capabilities of mandibular epithelium for mandibular epithelia could still elicit osteogenesis when removed from Meckel's cartilages and recombined with mandibular mesenchyme. Chondrocyte hypertrophy is associated with osteogenesis in other cartilages, including Meckel's cartilage from rodent embryos. However, Meckel's cartilages from chick embryos of H. H. stages 34, 38, and 39 failed to hypertrophy when cultured in the presence of 7.5 nM thyroxine (3,3',5-triiodo-L-thyroxine), although H. H. stage 28 tibial chondrocytes cocultured with Meckel's cartilage did hypertrophy. Therefore, avian Meckelian chondrocytes fail to hypertrophy or to produce osteoprogenitor cells in response to stimuli known to evoke these events in other skeletal cells.     

Contribution of the superior atrioventricular cushion to the left ventricular infundibulum. Experimental study on the chick embryo

The role of the superior atrioventricular cushion in the normal development of the left ventricular infundibulum was experimentally studied in the chick embryo. 178 embryos at stages 19-24 of Hamburger and Hamilton were selectively labeled using gelatin-india ink; afterward embryos were reincubated until the mature heart stage, in which the final location of the labels was determined. In addition, anatomical microscopic studies were carried out on the chick embryo heart at different stages of the development. 91 embryos were obtained at the mature heart stage, 46 of which were normal. In 82,6% of these 46 embryos labels were found in the left ventricular infundibulum and were distributed in the following regions: (1) base of the free portion of the anteroseptal mitral leaflet (mitroaortic continuity); (2) the same region plus the left surface of the anterior basal portion of the ventricular septum, and (3) the left surface of the anterior basal portion of the ventricular septum. Anatomical microscopic studies showed that the superior atrioventricular cushion appears at stage 18, fusing with the inferior cushion at stage 28. Our results permit us to conclude that the superior atrioventricular cushion plays an important role in the normal development of the left ventricular infundibulum, and it contributes in the posterolateral and anteromedial wall formation.     

Developmental changes in vitamin A level and lack of retinyl palmitate in chick lungs

1. Developmental changes in retinol and retinyl palmitate contents in lungs of chick embryos and posthatch chicks were investigated. 2. Remarkable changes in the lung retinol levels were found during development of chicks. Embryonic lungs 5 days prior to hatching contained the highest content of retinol. The level then declined rapidly and was lowest on 1 day before hatching. 3. Its level then rose substantially within 7 days after hatching. 4. No retinyl palmitate in chick lungs was detectable at any of the developmental stages examined, nor even in adult hen. 5. Serum retinol level changed in parallel with the lung retinol. 6. The patterns of changes in liver retinol and retinyl palmitate were remarkably different from that occurring in the lung retinol. In chick embryonic livers, the levels of them were low, followed by a rapid increase after hatching. 7. The high level and its rapid decrease of lung retinol content during development of chick embryos may be functionally connected with retinol action in embryonic lungs for cellular differentiation and maturation.     

In vitro development of individually cultured whole mouse embryos from blastocyst to early somite stage.

The sequential processes of in vitro development of whole mouse embryos were classified by stages according to the in vivo criteria of E. Witschi (1972, “Biology Data Book,” Part II: “Rat,” L. Altman and D. S. Dittmer, eds., 2nd ed., Vol. 1, pp. 178–180, Federation of American Societies for Experimental Biology, Bethesda, Md.) and K. Theiler (1972, “The House Mouse,” Springer-Verlag, Berlin/New York). The mouse embryos which developed in vitro in each day of culture were then classified into stages according to the characteristics of mouse embryos developed in vivo. A series of 10 blastocysts were inoculated into 35-mm plastic culture dishes (30–50 blastocysts per experiment). Developing embryos were scored on the fourth, sixth, and eighth days and classified into stages. Among the total of 118 blastocysts cultured in three repeated experiments, 100 mouse embryos had attached and developed in culture dishes. Ninety-four percent of the attached mouse embryos developed to the early egg cylinder stage after 4 days of incubation, and 87% grew to the stage of late egg cylinder after 6 days of culture. An average of 62% of the embryos reached the early somite stage with heart beating after 8 days in culture with frequent medium change. In two separate experiments single mouse blastocysts were placed individually in culture dishes in 2 ml of culture medium. The development of each embryo was followed every day. Each of 10 blastocysts had attached in its respective culture dish and had developed to the early egg cylinder stage after 4 days of culture. About 50 to 70% of each of these 20 individually isolated mouse embryos developed in vitro to the early somite stage after 8 days of culture.     

Influence of continuous electromagnetic fields on the stage, weight and stature of the chick embryo.

The influence of continuous electromagnetic fields (0, 181 or 361 Gs/cm2) on the development of chick embryo (n = 144) was studied. Several parameters were determined at days 5, 10 and 15 of incubation: stage (following Hamburger and Hamilton), vertex-coccyx length (size) and weight. At 5 days of incubation, all embryos showed a similar stage. However, at days 10 and 15, the embryos exposed to 181 Gs/cm2 showed a stage significantly superior to that of the others. There were no differences between the exposed embryos and the control ones with regard to weight and stature, except at 15 days when the embryos exposed to 361 Gs/cm2 showed greater weight and stature than those of the controls.     

Recovery of the acetylcholinesterase activity in a monolayer culture of chick myoblasts after irreversible inhibition by an organophosphorus inhibitor

The recovery of the acetylcholine esterase (AChE) activity after the irreversible inhibition with an organophosphorus inhibitor B-156 was studied in a developing monolayer culture of chick myoblasts. The culture was obtained from muscles of posterior limbs of the 11 day old chick embryos. The AChE activity was estimated by the modified Ellman method from the moment of inoculation to the stage of spontaneous contractions of muscle fibres. After the B-156 treatment the AChE activity of muscle cells decreased, then started to increase and the maximum recovery of activity, below the initial level, was attained within roughly 2 days after the treatment. The AChE activity in the treated culture somewhat decreased thereafter. The lower the inhibitor concentration, i.e. the lower the value of the initial AChE inhibition, the higher the starting rate and degree of recovery of the AChE activity. The results obtained suggest that, unlike the multilayer culture of muscle tissue at later stages of differentiation no compensatory enhancement of AChE biosynthesis after irreversible inhibition of this enzyme by an organophosphorus inhibitor is observed in the monolayer culture of chick myoblasts at the early stages of myogenesis.