Reaggregation of fetal rat brain cells in a stationary culture system II: Ultrastructural characterization

Summary Ultrastructural characteristics of fetal rat brain cell aggregates in a three-dimensional stationary culture system are described. Transmission electron microscopy showed immature cells which developed into mature astrocytes, oligodendrocytes, and neurons during 20 d in culture. This was accompanied by the development of a neuropil where myelinated axons and synaptic complexes were observed. In addition to confirming earlier ultrastructural investigations on fetal rat brain cell aggregates, the stationary culture system also showed the presence of histiotypic regions within the aggregates. These regions consisted of ependymal cells where cilia were observed on the cell surfaces. Structures resembling subependymal basement membrane labyrinths were also observed. Macrophages seemed to be more numerous in the stationary cultures as compared to other culture systems. The stationary culture system may provide aggregates that are ultrastructurally more complex than those obtained by rotation mediated systems. This investigation was supported by The Norwegian Cancer Society.     

Some effects of trypsin dissociation on the inhibition of reaggregation among embryonic chicken neural retina cells by cycloheximide

The effects of cycloheximide on the reaggregation of trypsin-dispersed, embryonic chicken, neural retina cells were investigated. The cells were used either immediately after isolation (F-cells), or after 24 hr prior culture under conditions not permitting reaggregation (V-cells). The parameters of aggregation used were the size of aggregates formed in gyrotatory shaker cultures, and the concentration of single cells in these cultures. At both 24 and 48 hr, following treatment with cycloheximide, the mean diameters of the aggregates of F-cells showed a greater reduction than the V-cells, when compared with their corresponding controls. In addition, cycloheximide resulted in a higher concentration of single cells, that is less cell/cell adhesion, than in comparable controls. A higher proportion of single cells were present in the F-cell cultures in the presence of cycloheximide than in the V-cell cultures. Thus, the degree of inhibition of cell adhesion by one inhibitor of protein synthesis differed in F-cells and V-cells. These experiments may serve to focus attention on some secondary effects of tryptic dissociation, which is an often overlooked factor in subsequent studies of reaggregating embryonic cells, particularly in those experiments involving the use of metabolic inhibitors.     

Oxidative stress decreases antioxidant enzyme activities in reaggregation cultures of rat brain cells

The brain has been suggested to be especially sensitive to damage by reactive oxygen species. In this study, we examined the effects of hyperoxic conditions on the activities and mRNA levels of antioxidant enzymes in reaggregation cultures of rat forebrain cells. Cultures were exposed to 80% oxygen for 12–60 h starting on Days 17 and 33 in culture. Superoxide dismutase activities and mRNA levels were not affected by hyperoxia, whereas catalase activity was slightly decreased after 24 h in 80% oxygen at Day 17. Glutathione peroxidase activity was markedly decreased already after 12 h of hyperoxia, and decreased activities of glutathione reductase and glucose-6-phosphate dehydrogenase were also noted. The glutathione peroxidase mRNA levels were increased in hyperoxic cultures at Day 17 but not at Day 33. These results suggest that the enzymatic defense mechanisms against reactive oxygen species in the brain are rather weak and deteriorate during oxidative stress but that a potential for compensatory upregulation exists at least during the first postnatal weeks.     

Visualization of cellular aggregates cultured on a three dimensional collagen sponge matrix

Summary A one-step vital stain is described for the macroscopic visualization of histotypic cell aggregates in fetal rat lung organotypic cultures. Organotypic cultures are incubated in 0.05-0.1% 2,3,5′-triphenyl tetrazolium chloride (TTC) in culture medium (37°C). Living cells reduce the tetrazole to a water-insoluble red colored formazan. Cell aggregates appear as densely stained foci against the lighter background of the Gelfoam substrate. Stained cultures may be scanned macroscopically to determine the degree of reaggregation and assess cell viability. Identification of aggregates by TTC staining improves the efficiency of tissue processing for electron microscopy and does not alter the ultrastructural appearance of the cultured cells. This work was funded in part by the United Cerebral Palsy Research and Educational Foundation, Inc. and the National Heart, Lung, and Blood Institute (Grants 1ROHL19513 and 1 R01HL21008).     

Early variations of the disialoganglioside GD3 in chicken embryonic brain support its role in cell migration

In the present study a primary culture system of chicken embryo brain neurons was used in the early period of chicken brain development from day 6 until day 8, which was shown to be a suitable model of neuritogenesis, cell migration and reaggregation. Dissociated chicken optic tectum cells from embryonic stage 31 were cultured on polylysine-coated dishes under serum-free conditions up to 3 days. Freshly dissociated neurons developed short processes, which contacted one another and formed fasciculated bundles. Cell somata migrated along the neurite bundles, similar to migrating neurons in vivo, forming three-dimensional tissue-like clusters. This system was used to study the possible functions of the disialoganglioside GD3 for these neuronal differentiation steps. GD3 represents the predominant ganglioside of embryonic neurons before neuritogenesis in vitro and in vivo. Its biosynthesis is followed during day 6 until day 8 of embryonic brain development. Incubation of dissociated neurons with the monoclonal antibody R-24, recognising the GD3 on the cell surface, led to a total blocking of neurite outgrowth. Accordingly, neither cell migration nor reaggregation could be found. These results indicate that the disialoganglioside GD3 plays a central role in neuronal differentiation and development in the embryonic chicken brain.     

In-vitro development and degeneration of stromal cells from the uterus of the rat at three stages of pregnancy

On Days 6, 11 or 16 of pregnancy, endometrial tissue (Day 6) or decidual tissue (Days 11 and 16) were removed from rat uteri, dissociated into single cells and grown in culture. At intervals during the culture period, the cells were examined and the cell density was calculated. The cells from Days 11 and 16 of pregnancy were similar in appearance, being very large and flattened. Initially, cells from Day 6 were much smaller, but showed an increase in size and came to resemble cells from the later stages of pregnancy. Growth curves for cells from each of the three stages of pregnancy over the first 16 days of culture differed. Cells from Day 6 of pregnancy increased exponentially in number. In cultures of cells from Day 11, cell numbers were stable, and in cultures of cells from Day 16, an exponential decline was seen. Cells from Days 6 and 11 of pregnancy were cultured for 42 days, by which time only a few cells remained viable. Cultures of cells from Day 16 degenerated within 3 weeks. These results indicate that, in vivo, decidual cells are not controlled solely by a 'programmed lifespan'. Changes occurring during pregnancy, however, limit the potential of the cells for division and survival in culture.     

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.     

Formation of chondrous and osseous tissues in micromass cultures of rat frontonasal and mandibular ectomesenchyme

Rat frontonasal and mandibular mesenchyme was isolated from day-12 1/2 (stage-22) rat embryos and cultured at high density for up to 12 days. The stage chosen was based on the observation that mandibular mesenchyme at this stage became independent of its epithelium with respect to the production of both cartilage and bone. Frontonasal cultures developed aggregates of anastomosing columns of cells within 2 days. These grew as the cells enlarged, laying down an Alcian-blue-positive matrix by day 3 of culture. Significant mineral was detected by von Kossa staining by day 5 at which time the aggregates covered a large portion of the culture, eventually covering the entire micromass by day 10-12. Mandibular cultures developed centrally located nodular aggregates by 3 days of culture. These nodules increased in number, spreading outwards as the cells enlarged, laying down an Alcian-blue-positive matrix by day 4 and mineral by days 6-7. At this time the nodules began to elongate and coalesce, but never covered the entire culture over the 12-day period. Antibody staining revealed that in both cultures the cells were initially positive for type I collagen. Subsequently, the aggregates began expressing type II collagen, followed by type X, which coincided with the onset of mineralization. At this time some cells were negative for these cartilage markers, but positive for osteoblast markers, bone sialoprotein II, osteocalcin and type I collagen. In addition osteonectin and alkaline phosphatase were demonstrable in all of the aggregate cells late in the culture period. This provided clear evidence that chondroblast and osteoblast differentiation was proceeding within these cultures. The culture of rat facial mesenchyme should prove very useful, not only for the analysis of bone and cartilage induction and lineage relationships, but also in furthering our knowledge of craniofacial differentiation, growth and pattern formation by extending our analysis to a mammalian system.     

Scanning electron microscopy of aggregating embryonic neural retina cells.

Scanning electron microscopy of in vitro reaggregation of trypsin-dissociated neural retina cells from 10-day chick embryos revealed that filopodial projections participate in the assembly of the dispersed cells into clusters. Freshly dissociated cells displayed numerous elongated, randomly projecting filopodia. With the onset of cell reaggregation these filopodia bridged and connected distant cells becoming shorter as the cells came together and formed aggregates. In 24-h cell aggregates only short microvilli were seen, mostly on cell surfaces facing the periphery of the aggregate. Cells dissociated from retina tissue pre-treated with inhibitors of protein synthesis, or cells exposed to these inhibitors immediately after dissociation were mostly devoid of filopodial projections; such cells failed to re-aggregate histotypically. Thus, metabolic and biosynthetic processes are required for the changes in the cell periphery which result in formation or maintenance of filopodia, and which enable trypsin-dissociated cells to reform histotypic associations. Possible relationships between the formation of filopodia and histotypic reaggregation of cells is discussed.     

Reaggregates of cells from rat testis resemble developing gonads

Reaggregates prepared from newborn rat testis cells in Moscona-type rotation cultures were analyzed and compared with normal fetal (12-21 days) and newborn testes at the light and electron microscope level. After 25 h of culture, the aggregates resembled normal testicular tissue. The cells of the surface layer were spindle-shaped and connected by adherent junctions. The epithelial cords were composed exclusively of Sertoli cells and were surrounded by elongated cells resembling the developing myoid cells in newborn testes. The basal aspect of the cords was covered by a layer of flocculent material which, in places, was organized like an ordinary basement membrane. Individual spermatogonia with pseudopodes were observed in the interstitial tissue. Some Leydig cells were organized into small clusters like those typical in newborn testes. The present observations indicate that, histologically, the reaggregation of separated testicular cells resembles the differentiation of embryonic male gonads.     

Contribution of maternal mRNA for maintenance of Ca2+-dependent reaggregating activity in dissociated cells of Xenopus laevis embryos

Dissociated Xenopus laevis blastula cells, where reaggregation was inhibited in Ca2+-free medium, reaggregated immediately after the addition of Ca2+. This reaggregation was not inhibited by cordycepin or actinomycin D treatment during culture, although cycloheximide and puromycin were inhibitory. The reaggregation was not inhibited even when fertilized eggs were microinjected with cordycepin and their RNA synthesis was continuously inhibited through cleavage to blastula stages. In neurula cells, cordycepin treatment induced significant reduction in sizes of aggregates formed. These results suggest that the Ca2+-dependent reaggregating activity of blastula cells is maintained by the translation of maternal, rather than newly synthesized, mRNA.     

A Brief Contact with Early Embryonic Cells Induces the Differentiation of Embryonal Carcinoma Cells

An assay system was developed to detect a switch of mouse embryonal carcinoma (EC) cells to the pathway for normal cell differentiation after a brief contact with normal embryonic cells. The system consisted of (1) the mixed aggregation of AT805 EC cells with 8-cell stage mouse embryos, (2) the stationary culture of the mixed aggregates into blastocysts and (3) the cell culture of inner cell masses isolated from chimeric blastocysts containing EC cells at 2, 3 and 4 days after the initiaion of chimeric aggregation. The number of foci of EC cells which appeared in the cultures of inner cell masses was decreased with a length of contact of EC cells with normal embryos as the mixed aggregates. After 4 days' contact, only fibroblastic and epithelial cells appeared in most cultures of inner cell masses. Examination of isozyme markers of GPI revealed that such cell cultures consisting of nonmalignant cells contained cells of tumor origin. Thus, it was concluded that a brief exposure to the environment of normal embryos can regulate the tumor cells to differentiate into non-malignant cells. This conclusion was substantiated by comparing the pattern of protein spots of the tumor cells with that of non-malignant cells of the tumor origin by two dimensional gel electrophoresis.     

Neurons in primary cultures from five defined rat brain regions--cellular composition and morphological appearance

Primary cultures from 15-17 days old fetal rat cerebral cortex, striatum, hippocampus, substantia nigra and brain stem were grown for ten days. Cell aggregates were formed one to two days after seeding. The cell bodies migrated peripherally from the clusters during development and networks of processes were formed. The cultures from the different brain regions contained predominantly neurons, stained by an antiserum against the neuron-specific enolase (NSE). There were differences in morphological appearance of the aggregates and also of the single neuronal cells cultivated from the various brain regions. On the bottom of the culture dishes a monolayer was formed of predominantly undifferentiated (mesenchymal-like) cells. Some cells of the monolayer stained for the astrocyte markers glial fibrillary acidic protein (GFAp) or S-100. The majority of the cells were, however, unstained to these markers. Very few endothelial cells and macrophages were observed.     

Studies of the Levamisole inhibitory effect on rat stromal-cell commitment to mineralization

The ability of Levamisole to decrease mineralization in skeletal tissue is usually related to its effect on alkaline phosphatase (ALP). However, Levamisole is also suspected to diminish mineralization by an additional mechanism which is unrelated to the ALP control of apatite crystal growth. To delineate the time in differentiation during which Levamisole inhibits mineralization, a tissue culture model system of bone marrow stromal cells was used. Secondary cultures of stromal cells were propagated in osteoprogenitor cell (OPC) induction medium for three weeks, followed by measurement of calcium precipitation. In situ ALP assays at pH 7.6 were also performed. When cells were cultured with 0.2 mM Levamisole for three weeks, Day 20 values of calcium precipitates were lower than in controls, but Day 20 ALP values were paradoxically higher. The correlation between calcium and ALP within each group was low. The correlation slightly improved, in uninhibited cultures, when Day 21 calcium values were matched with earlier Day 12 ALP values. This suggested the existence of a Levamisole-sensitive mechanism for mineralization inhibition effective prior to the culture's mineralization stage. To focus on this early effect on mineralization Levamisole was added to stromal cultures on different days and removed on Day 12. Levamisole decreased Day 21 mineralization when added on Days 0, 3, 5, and 7, but not when added on Day 9. The Levamisole-induced inhibition of mineralization was accompanied by an increase in Day 12 ALP specific activity, compared to controls, when added from Day 5 and thereafter. The results indicate that part of the ability of stromal cells to mineralize is determined during the first week of culture. The early inhibitory effect of Levamisole on mineralization was associated with increased Day 12 ALP activity.     

Characterization of oligodendrocytes in primary cultures from brain hemispheres of newborn rats

Characterization of putative oligodendrocytes obtained in primary cultures of brain hemispheres from newborn rats is reported. Most of the oligodendrocytes are scattered in the culture dish until around 20 days after seeding, the time at which they start to form aggregates made up of one to three layers of cells upon the astrocytes. At the electron microscopic level the oligodendrocytes ultrastructure appears undifferentiated but very different from that of the underlying astrocytes. These oligodendrocytes do not react to W1 Wolfgram protein and myelin basic proteins antisera until the sixth day after seeding. On Day 8, a few oligodendrocytes give a positive reaction; after 4 weeks most of them react. These results represent a further step in the identification of oligodendrocytes in culture and in the characterization of their development in vitro.     

Serum proteins enhance aggregate formation of dissociated fetal rat brain cells in an aggregating culture

Summary Dissociated fetal rat brain cells (Day 14.5 of gestation) reaggregated into small cell clusters and formed large aggregates in a medium supplemented with serum or dialyzed serum in an aggregating culture. In contrast, only small aggregates were produced in a serum-free medium. The present results indicated that albumin, fetuin, transferrin, and {ie1031-1}-antitrypsin enhanced the aggregate formation. Small aggregates produced in a serum-free medium elongated neurites when they were cultured within a collagen gel matrix. Total DNA per flask was almost the same in small and large aggregates. Thus, these serum proteins may well play an important role in the adhesion of small cell clusters and cause the formation of large aggregates in this short-term aggregating culture.     

Selective adherence of neurons and glial cells from dissociated cerebral and spinal cord microcarrier cultures.

In stationary cultures of dissociated brain and spinal cord grown on microcarriers (MCs), the neuronal and ependymal cells attached to the MCs forming floating aggregates in which they grow in a three-dimensional pattern. The glial and meningeal elements on the contrary, tend to dissociate from the aggregates and adhere to the plastic dish where they divide to form a monolayer. This different behavior of CNS components is not observed in rotating cultures in which all CNS cells remain attached to the MCs and develop into mature floating structures. This cell separation in stationary MC-cultures which is documented here by SEM and immunocytochemistry, may be useful for analysis and evaluation of the metabolic biochemical events of each of the cellular components derived from the same culture.     

Isolation and characterization of mouse neural precursor cells in primary culture

Summary Primary cultures of mouse neural precursor cells were established by enzymatic dissociation of embryonic Day 10 fetal heads followed by negative selection of non-neural contaminating cells. The latter were allowed to attach and spread on a plastic substrate under conditions that permitted neural precursor cells to remain suspended in the culture medium. The resulting neuroepithelial cell enriched suspension then was plated on dishes coated with poly-d-lysine. Growth of fibroblastic cells was inhibited in a selective medium. Cell proliferation was measured by immunoperoxidase staining of nuclei after bromodeoxyuridine labeling. The proportion of labeled cells declined from 50% on Day 1 until Day 5 when it approached zero, and after 7 days in culture a fourfold increase in cell number was achieved in medium containing 1% fetal bovine serum, transferrin, insulin, cholera toxin, and sodium selenite. Differentiation of neural precursor cells was studied by indirect immunofluorescence microscopy for the appearance of neuron- and astrocyte-specific cytoskeletal proteins at successive intervals in culture. Cells bearing neuritic processes and expressing neurofilaments as well as microtubule-associated protein 2 were present in low numbers on Day 1, increasing through Day 14. Stellate cells with morphologic features of astrocytes and immunoreactive for glial fibrillary acidic protein were not detected until Day 5 and did not become abundant until Day 11. No differences in morphology or immunocytochemical staining characteristics were found between neural precursor cells processed by enzymatic dissociation of whole fetal heads and those recovered by manual dissection of fetal neuroepithelia. The large number of neural precursor cells obtained by this rapid, simple method makes possible the production of mass cultures for molecular analysis of the regulatory factors that control proliferation and differentiation during early development of the mouse central nervous system. This study was entrusted to the Institute of Physical and Chemical Research (RIKEN) by the Science and Technology Agency (STA) and was financially supported by the Special Coordination Funds for Promoting Science and Technology. R. Shiurba is a recipient of a STA fellowship award from the Japanese Union of Scientists and Engineers.     

Distinct myogenic programs of embryonic and fetal mouse muscle cells: expression of the perinatal myosin heavy chain isoform in vitro.

Early embryonic and late fetal mouse myogenic cells showed distinct patterns of perinatal myosin heavy chain (MHC) isoform expression upon differentiation in vitro. In cultures of somite or limb muscle cells isolated from Day 9 to Day 12 embryos, differentiated cells that expressed perinatal MHC were rare and perinatal MHC was not detectable by immunoblotting. In cultures of limb muscle cells isolated from Day 13 to Day 18 fetuses, in contrast, the perinatal MHC isoform was easily detected and was expressed in a substantial percentage of myocytes and myotubes. Analyses of clonally derived muscle colonies and cytosine arabinoside-treated fetal muscle cell cultures suggested that different fetal muscle cell nuclei initiated perinatal MHC expression at different times. In both embryonic and fetal cell cultures, the embryonic MHC isoform was expressed by all differentiated cells examined. A small number of myotubes in fetal muscle cell cultures showed a mosaic distribution of MHC isoform accumulation in which the perinatal MHC isoform accumulated in a restricted region of the myotube near particular nuclei, whereas the embryonic MHC isoform accumulated throughout the myotube. Thus, the myogenic program of fetal, but not embryonic, mouse myogenic cells includes expression of the perinatal MHC isoform upon differentiation in culture.     

Nutrition and fetal brain maturation : I. Responses in vitro and in vivo

The glycolytic enzyme enolase increases during the perinatal period of brain development and was utilized as a marker for examining the effect of culture environment on differentiation of cells from 20-day fetal rat brain. Enolase activity in cell cultures increased from 0.91 +/- 0.03 (Day 0) to 2.11 +/- 0.10 mumol/min/mg protein (Day 6). Comparable levels were not reached in vivo until neonatal pups were 15 days old. The in vitro increase was inhibited by both cycloheximide and actinomycin D. Enolase activity in the cells responded to alterations in both incubation media and homologous serum. After 6 days in culture, cells incubated in rat serum (10%) added to MEM or RPMI produced twice as much enolase activity as cells incubated similarly in Ham's medium, i.e., 1.96 +/- 0.09 and 1.85 +/- 0.21 vs 1.02 +/- 0.09, P less than 0.001. Results of a comparable magnitude were obtained when fetal calf serum replaced adult rat serum, but enolase production was somewhat lower when newborn calf serum replaced adult rat or fetal calf serum. When cells were incubated for 6 days with graded concentrations of adult rat serum (2.5-15%), enolase activity increased progressively. The pattern of enolase response suggests that the fetal rat brain cell model described herein will provide a sensitive probe with which to gain insight into nutrition and fetal brain development.