Biochemical characterization of [3H]norepinephrine uptake in dissociated brain cell cultures from chick embryos

The uptake of [³H]norepinephrine ([³H]NE) was studied in dissociated brain cell cultures prepared from 8-day-old chick embryos using the whole brain (minus optic lobes). Uptake of [³H]NE, 5×10^–9 M, 10 min incubation, in freshly dissociated noncultured embryonic chick brain cells, was detected in 6-day-old embryos; it was temperature and drug (cocaine, metanephrine) sensitive and increased with brain development. In cultured cells, which were assayed at various days in culture, the increase in [³H]NE accumulation per culture was less than that seen in freshly dissociated noncultured embryonic cells. When [³H]NE uptake was expressed per mg protein, a decrease with days in culture was observed, reflecting perhaps a dilution of growth or proliferation of cells not accumulating NE. Metanephrine, 5×10^–6 M, an inhibitor of extraneuronal uptake, inhibited [³H]NE in 5-day-old cultures whereas desmethylimipramine, an inhibitor of neuronal uptake, inhibited [³H]NE uptake in 15- and 20-day-old cultures. Cocaine, another neuronal inhibitor, inhibited [³H]NE at 10 and 15 days only. We interpret these findings to suggest that during early growth in culture most neuroblasts accumulate NE nonspecifically and, as neuronal maturation proceeds, NE accumulation becomes specific.     

Cell Kinetic Studies of Chick Brain Cells In Culture: an Autoradiographic Study With [3H]- and [14C]-Thymidine

Labelling index, S-phase duration and cell-cycle time of proliferating brain cells from 6-day-old chick embryos in culture were investigated autoradiographically after labelling with [³H]- and/or [¹⁴C]-thymidine. the dissociated cells were cultured in the absence or in the presence of brain extract from 8-day-old chick embryos. Cultures contained essentially two cell types, which could be easily distinguished by the size of their nuclei: small nuclei identified as belonging to precursor cells of neurons and large nuclei corresponding to astroglial cells. the labelling index of astroglial cells (16.4%) was about 2 times higher than that of the neuronal cells (9.9%). Under the influence of brain extract the labelling index of neuroblasts was nearly doubled while that of the astroglial cells remained nearly unchanged. From double-labelling experiments with [³H]- and [¹⁴C]-thymidine, the same S-phase duration of about 7 hr was found for both cell types cultured with or without brain extract. A cell-cycle duration of 39 hr for neuronal and of 29 hr for astroglial cells was found. the cycle times remained constant under the influence of brain extract. From the measured data mentioned above, a growth fraction of 50% (neuroblasts) and 68% (astroglial cells) was calculated in control cultures without brain extract. After addition of brain extract, the growth fraction increased for both cell types (neuroblasts: 92%; astroglial cells: 80%). the results demonstrate that more cells proliferate in the presence of brain extract, but the durations of the S-phase and the cell cycle remain unchanged.     

Germ line chimera produced by transfer of cultured chick primordial germ cells.

Intrinsic primordial germ cells (PGCs) from stage 27 (5-day-old) chick embryonic germinal ridges were cultured in vitro for a further 5 days, and shown to proliferate on stroma cells derived from the germinal ridge. To determine whether these cultured PGCs could colonize and contribute to the germ-line, PGCs were isolated by gentle pipetting, labeled with PKH26 fluorescent dye and injected into the blood stream of stage 17 (2.5-day-old) chick embryos. The recipient embryos were incubated until they reached stage 28. Thin sections of these embryos were analysed by fluorescent confocal laser microscopy. These analyses showed that the labeled donor PGCs had migrated into the germinal ridges of the recipient embryos, and transplanted PGCs had undergone at least 3-7 divisions. These results suggest that PGCs that had passed far beyond the migration stage in vivo were still able to migrate, colonize and proliferate in recipient chick embryonic gonads.     

Differentiation of lens and pigment cells in cultures of neural retinal cells of early chick embryos

Dissociated cells of neural retinas of 3.5-day-old chick embryos (stages 20–21) were cultured as a monolayer in order to examine their differentiation in vitro. These cells started to grow actively soon after inoculation and formed a confluent sheet within which neuroblast-like cells with long cytoplasmic processes were differentiated by 8 days. At about 16 days the differentiation of both lentoid bodies and foci of pigment cells was observed, while neuronal structure disappeared. The numbers of lentoid bodies and foci of pigmented cells continued to increase up to 30 days, when primary cultures were terminated. The increase in δ-crystallin content, as measured by quantitative immunoelectrophoresis assay using rabbit antiserum against δ-crystallin, was consistent with the increase in the number of lentoid bodies in cultures. The amount of α-crystallin per culture, estimated by the same technique as above, reached a maximum at 16 days and decreased slightly during further culture. The differentiation of both lentoid bodies and pigment cells was observed also in cultures of the second generation. The results demonstrate that cells of the undifferentiated neuroepithelium of 3.5-day-old embryonic retinas can achieve at least three differentiations, neuronal, lens, and pigment cells, in vitro. We discuss several differences between the present results and the previous ones from in vitro cultures of 8- to 9-day-old embryonic neural retinas.     

Characteristics of choline acetyltransferase and cholinesterases in two types of cultured cells from embryonic chick brain

Cells that were mechanically dissociated from the brains of 7-day-old chick embryos were grown in culture for 7–8 days. Two major cell populations were observed: (1) cells that aggregated and sent out processes, (2) flat cells that proliferated rapidly and formed a confluent layer by day 4 of culture. Many of the cells of the first type had the morphological, histochemical and biochemical attributes of neurons. They possessed choline acetyltransferase (ChAc) and acetylcholinesterase (AChEs) activities. The flat cells possessed neither of the activities, but did have butyrylcholinesterase (BuChEs) activity and a choline independent acetylase activity (CIA) that may be carnitine acetyltransferase.The activities of ChAc and AChEs in the cultured neurons increased approximately 9-fold and 5-fold, respectively, over an 8-day period. The patterns of change of these enzymes were not unlike those seen in vivo in intact developing chick brain.The addition of thyroxine (10^?6M) to these cultures increased the activities of neuronal AChEs and flat cell BuChEs by 30–70%.     

SENSITIVITY OF EARLY EMBRYONIC THYMIC LYMPHOID DEVELOPMENT TO 3H-THYMIDINE OF HIGH SPECIFIC ACTIVITY

The pulse technique, using high specific activity ³H-TdR to selectively kill cells in cell cycle, was applied to the thymic anlagen of chick embryos. With optimal specific and total ³H-TdR activities and pulse times of 2–4 hr the subsequent lymphoid development in organ culture of the thymic anlagen of 10-day-old chick embryos could be almost completely inhibited. The most important effect of the ³H-TdR was on the lymphoid precursor cells of the anlagen. The thymic epithelium appeared more resistant to ³H-TdR and allowed a lymphoid development of pulsed anlagen grafted to the chorioallantoic membrane of chick embryos when new lymphoid precursor cells were provided. The lymphoid precursor cells of the thymic anlagen of 10-day-old chick embryos therefore appeared to be in cell cycle with short generation time. The thymic anlagen of 8-, 9- and 10-day-old but not 7-day-old embryos showed a lymphoid development in organ culture. They did not differ with respect to the sensitivity to hot pulses of ³H-TdR. Thus no evidence of a lag in the onset of lymphoid precursor cell proliferation during the development of the early embryonic chick thymus was noted.     

Chick endogenous lectin enhances chondrogenesis of cultured chick limb bud cells

We have studied the effect of β-d-galactoside-specific lectin purified from 14-day-old chick embryos on the differentiation of the mesenchymal cells dissociated from the limb buds of stage 24 chick embryos, using the micro-mass culture method described previously. When the cells were incubated with the lectin during the initial 12 hr of culture, cell proliferation became slightly activated. The lectin-treated cells formed a greater number of cartilage nodules and incorporated about twice as much as [³⁵S]sulfate per cell than the control cultures. The results of this study show that the chick endogenous lectin promotes cartilage differentiation in vitro and that endogenous lectin may possibly be involved in chondrogenesis in vivo.     

Pyrophosphate stimulation of calcium uptake into cultured embryonic bones. Fine structure of matrix vesicles and their role in calcification

The onset of mineralization in embryonic chick femurs was studied as a model for the initiation of biological calcification. Electron microscopy confirmed the presence of calcifying matrix vesicles within newly formed bone, and showed that these vesicles were the initial site of crystal deposition. Matrix vesicles were first seen on day 6 of embryonic development, and already were present in considerable numbers on day 7, at which time mineral deposition was just beginning. As a reflection of initial mineralization the uptake of ⁴⁵Ca and ⁴⁰Ca into 7-day-old bones was studied during 2 days in organ culture. A control level of uptake was established using a defined culture medium, P-6. Addition of inorganic pyrophosphate (PP_i) to this medium caused a marked increase in calcium uptake into areas of matrix which normally calcify in vivo. The maximal ⁴⁵Ca uptake, greater than 4-fold, was achieved with 4 μg of P per milliliter of PP_i and was partially heat-inhibitable. Since the matrix vesicles are known to be rich in inorganic pyrophosphatase, it is proposed that mineralization is promoted in vesicles by the enzymatic hydrolysis of pyrophosphate. The membrane-bounded matrix vesicles appear to provide the necessary enzymes and environment to concentrate calcium and phosphate for initiating crystal formation.     

Neuronal cell-surface specific antigen(s) is expressed during the terminal mitosis of cells destined to become neuroblasts

By immunizing mice with cells from embryonic chick motoneuron cultures, an antiserum was produced which recognizes an antigen(s) restricted to cell surfaces of most, or all, neurons. With the use of this antiserum, the appearance of neuron-specific antigenicity in cells of the embryonic spinal cord was examined by indirect immunofluorescence microscopy. The antigen or set of antigens reacting with this antiserum was first detectable in the neural tube of chick embryos at stage 15–16 (V. Hamburger and H. L. Hamilton, 1951, J. Morphol.88, 49–92). In addition to the neuroblasts located in the mantle layer, some mitotic cells as well as some spindle-shaped cells in the germinal layer were antigen positive. Immunofluorescence microscopy combined with autoradiography revealed that none of the antigen-positive cells could be labeled with [³H]thymidine; thus they do not synthesize DNA, and none of the cells in the DNA synthetic phase expressed the antigen(s). As the neuroblasts do not synthesize DNA after they have differentiated from the germinal cells, we believe that the antigen-positive cells are differentiated elements and that the differentiation of membranes specific for neurons begins already before or during the terminal mitosis of cells which will be defined as neuroblasts.     

Effects of chick brain extract on the proliferation of chick neuroblasts cultured in media supplemented with low and high serum concentrations

The proliferative activity of chick neuroblasts cultured in a medium containing a low (5%) or a high (20%) concentration of fetal calf serum (FCS) was analyzed and the influence of a chick brain extract was investigated. Morphological observations and tritiated thymidine incorporation measurements have shown that neuroblasts from 6 day-old chick embryo cerebral hemispheres proliferate more actively in the medium with 5% FCS compared to the medium with 20% FCS. The medium containing 5% FCS favoured the maintenance of neuronal cells in a neuroblast stage as shown by electron microscopy. The stimulatory effect of brain extract on the proliferation of neuroblasts is stronger in the low serum culture condition. These findings indicate that a low serum-containing medium is an adequate condition to study neuronal proliferation and effects of growth factors on these cells.     

PRODUCTION OF GERMLINE CHIMERIC CHICKENS BY TRANSFER OF CULTURED PRIMORDIAL GERM CELLS

Primordial germ cells (PGCs) from stage 27 (5.5-day-old) Korean native ogol chicken embryonic germinal ridges were cultured in vitro for 5 days. As in in vivo culture, these cultured PGCs were expected to have already passed beyond the migration stage. Approximately 200 of these PGCs were transferred into 2.5-day-old white leghorn embryonic blood stream, and then the recipient embryos were incubated until hatching. The rate of hatching was 58.8% in the manipulated eggs. Six out of 60 recipients were identified as germline chimeric chickens by their feather colour. The frequency of germline transmission of donor PGCs was 1.3–3.1% regardless of sex. The stage 27 PGCs will be very useful for collecting large numbers of PGCs, handling of exogenous DNA transfection during culture, and for the production of desired transgenic chickens.     

The importance of cell contact for the proliferation of neuroblasts in culture and its stimulation by meningeal extract

The influence of cell density and cell contacts on the proliferation of neuroblasts in culture and its stimulation by meningeal extract were investigated. Dissociated brain cells from 6-day-old chick embryos were cultured under 3 different culture conditions to obtain dense or sparse brain cell cultures, as well as cultures of isolated neuronal cells. The proliferation of neuroblasts, shown by morphological observations, cell counts, determinations of DNA content and measurements of [³H]thymidine incorporation, was found to be the highest in cultures where cell density and cellular contacts were greatest. The addition of meningeal extract stimulated the multiplication of neuroblasts only in cultures where the cells were in closer contact with each other. The results suggested, therefore, that cell density and cell-cell interactions are of importance and favored neuroblast proliferation.     

Muscle development in vitro following X irradiation

Myogenic cells obtained from 12-day-old embryonic chicken hind limb and breast muscle were exposed to 5000 rads of X irradiation. Although 10% of the initial cell dissociates were killed by irradiation, the remaining cells were comparable to controls in plating efficiency and light microscopic morphology. Moreover, there was no increase or loss of cells for at least 72 hr in vitro when plated at a density of 2 × 10⁶ cells/60-mm plate. It was found that muscle cell fusion after irradiation proceeded at the same rate and to the same relative extent as in control cultures. Myotubes developed normally; cross-striations were prominent by 5 to 7 days of culture and the cells maintained a well-differentiated state for periods of at least 3 weeks in vitro. In control cultures continuously labeled with 1 μCi/ml of [³H]TdR, 75% of the nuclei within myotubes were heavily labeled by 118 hr; less than 15% of the nuclei within syncytia of irradiated cultures were labeled. Quantitative microphotometry of Feulgen-stained cultures demonstrated that all nuclei within control and irradiated myotubes contained the 2C complement of DNA. Similar experiments conducted with cells released from limbs and breasts of 10-day-old embryos revealed lower absolute levels of cytoplasmic fusion in both control and irradiated samples, however, there was slightly more cell death after exposure to X rays in 10-day-old than 12-day-old material. Nevertheless, considerable cell fusion occurred in irradiated limb and breast cell cultures, consistent with the conclusion that the commitment to myogenesis of prefusion myoblasts is extremely stable even in the face of massive ionizing radiation and that neither cell division nor replication of DNA is an obligatory prerequisite for the in vitro fusion and subsequent differentiation of skeletal muscle obtained from 10- and 12-day-old chick embryos.     

Development of the enteric nervous system in chick embryonic duodenum in terms of the distribution of tubulin

An immunohistochemical method that uses anti-tubulin was utilized to observe the development of the enteric nervous system in chick embryonic duodenum. Neural crest cells, and enteric neuroblasts, or enteric ganglia, which derive from neural crest cells were clearly shown as sharp immunoreactive regions of tubulin. The distributions of enteric neuroblasts and enteric ganglia in chick duodena were in agreement with results of previous reports in which different techniques were used. The initial stage at which cells of neural crest origin were present in the duodenal walls (4-day-old embryos) was earlier than the initial stage (about 6-day-old embryos) reported earlier. This was verified by transmission electron microscopy. Also, the tubulin that is a component of the enteric nervous system was shown to be stable at a low temperature. This tubulin-immunostaining method provides a useful histochemical technique with which to study the development of the enteric ganglion and the function of tubulin as a component of the enteric nervous system.     

Cell kinetic studies of chick brain cells in culture: an autoradiographic study with [3H]- and [14C]-thymidine

Labelling index, S-phase duration and cell-cycle time of proliferating brain cells from 6-day-old chick embryos in culture were investigated autoradiographically after labelling with [3H]- and/or [14C]-thymidine. The dissociated cells were cultured in the absence or in the presence of brain extract from 8-day-old chick embryos. Cultures contained essentially two cell types, which could be easily distinguished by the size of their nuclei: small nuclei identified as belonging to precursor cells of neurons and large nuclei corresponding to astroglial cells. The labelling index of astroglial cells (16.4%) was about 2 times higher than that of the neuronal cells (9.9%). Under the influence of brain extract the labelling index of neuroblasts was nearly doubled while that of the astroglial cells remained nearly unchanged. From double-labelling experiments with [3H]- and [14C]-thymidine, the same S-phase duration of about 7 hr was found for both cell types cultured with or without brain extract. A cell-cycle duration of 39 hr for neuronal and of 29 hr for astroglial cells was found. The cycle times remained constant under the influence of brain extract. From the measured data mentioned above, a growth fraction of 50% (neuroblasts) and 68% (astroglial cells) was calculated in control cultures without brain extract. After addition of brain extract, the growth fraction increased for both cell types (neuroblasts: 92%; astroglial cells: 80%). The results demonstrate that more cells proliferate in the presence of brain extract, but the durations of the S-phase and the cell cycle remain unchanged.     

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.     

Rates of protein synthesis in explanted embryonic chick lens epithelia: differential stimulation of delta-crystallin synthesis.

Cells in the central region of 6-day-old embryonic chick lens epithelia display morphological and biochemical changes, when cultured in medium supplemented with fetal calf serum, comparable to those of lens fiber cells differentiating in vivo. In the present study the rates of synthesis of total protein and of δ-crystallin were quantitated during the first day of culture by measuring (1) ³H-valine incorporation into bulk proteins and into δ-crystallin (isolated by quantitative immunoprecipitation), (2) the specific radioactivity of picomolar amounts of intracellular valine (determined by analysis of the ¹⁴C-dansyl-derivative of ³H-valine), (3) the amount of protein degradation occurring during the labeling period (estimated by “pulse-chase” experiments with cycloheximide), and (4) the number of cells in the explants (counted following dispersal with trypsin-EDTA). The results showed that total protein synthesis increased 1.7-fold per cell during the first 24 hrs in vitro. In contrast, δ-crystallin synthesis increased 2.8-fold per cell during this time. These experiments establish that δ-crystallin synthesis is differentially stimulated in epithelia cultured in serum-supplemented medium, and provide the basis for quantitative analysis of the mechanism controlling differential protein synthesis during lens fiber differentiation in vitro.