Epithelial cell proliferation and migration in the developing rat gastric mucosa

To investigate cell proliferation in developing gastric antrum and fundus, proliferating gastric epithelial cells were labeled in fetal rats by intravenously injecting mothers with [³H]thymidine. In addition 14-day postnatal (dPN) rats were given [³H]thymidine intraperitoneally. Tissue was removed 1.5 hr later, and autoradiographs were prepared to identify proliferating cells. Total epithelial labeling indices (L.I.) reached a peak at 20 days gestation (dG), coincident with the appearance of pit/glands, then declined again by 22 dG (gestation end). At 18 dG, labeled cells were distributed throughout all levels of the stratified epithelia. Between 20 and 22 dG, as pit/gland development proceeded, labeled cells became concentrated in the gland bases and were only rarely seen on the surface (L.I. of surface cells <1% at 22 dG). By 14 dPN, proliferating cells were entirely absent from the epithelial surface. Approximately 15% of the endocrine cells were labeled at 22 dG, compared to only 2% at 14 dPN; zymogen cells were labeled (～6%) at 14 dPN; parietal cells did not label at any age studied. In addition, cell migration to the epithelial surface was studied in rats labeled at 22 dG, 14 dPN, or 28 dPN, and killed 1–20 days later. Migration times were slightly shorter in the 28 dPN group and were longer in fundus than antrum in all groups.     

An autoradiographic study of the origin of intestinal blastemal cells in the newt, Notophthalmus viridescens.

Fifty adult newts were used in this investigation; in 44 animals, the intestine was transected perpendicular to its longitudinal axis approximately midway between pylorus and rectum. The free ends of the intestine were held in apposition with a single suture and replaced into the coelom. The animals were injected intraperitoneally with [³H]thymidine from 0 to 35 days after transection of the intestine and killed 6 hr later. In nontransected, control intestines, the only tissue that incorporated [³H]thymidine was the mucosal epithelium. In transected intestines, only the mucosal epithelium labeled in animals which had been injected with [³H]thymidine from 0 to 4 days after the intestine was incised. Later on, serosal cells and smooth muscle cells of the intestinal stump underwent morphological alteration, initiated the incorporation of [³H]thymidine into DNA, and began replication. At 6 days after transection, serosal cells adjacent to the plane of transection were incorporating [³H]thymidine and, at 12 days, smooth muscle cells at the transected surface were labeling. It seems probable that they both furnished cells to the intestinal blastema; the lining epithelium of the mucosa, however, did not appear to contribute to the blastema proper.     

Growth factor requirements for DNA synthesis by Leydig cells from the immature rat.

Puberty in the male is dependent upon the elevated production of testosterone by the Leydig cells. LH affects this increase in testosterone output by increasing the total number of Leydig cells in the testis and by stimulating the steroidogenic pathway in these cells. Since Leydig cell proliferation is a prerequisite for the onset of puberty, we have examined the ability of LH and growth factors known to be present in the testis to promote DNA synthesis. Leydig cells were isolated from 21-day-old rats, cultured in serum-free medium for 48 h to become quiescent, and then treated with LH and growth factors for 18 h. [3H]Thymidine incorporation into DNA was assessed over the subsequent 4-h incubation period. Cells in control cultures incorporated low levels of [3H]thymidine into DNA and were stimulated after treatment with LH (100 ng/ml). Insulin/insulin-like growth factor-1 (IGF-1) and transforming growth factor-alpha (TGF-alpha), previously localized in Leydig cells by immunohistochemistry, also stimulated [2H]thymidine incorporation into DNA. The responses of the Leydig cells to maximum levels of insulin and TGF-alpha were dependent on the cell density. Insulin and TGF-alpha alone and in combination increased the number of cells labeled with [3H]thymidine, as assessed by autoradiography. TGF-beta, known to be secreted by Sertoli cells, also stimulated DNA synthesis under basal conditions, but the maximum response was significantly lower than that achieved in the presence of TGF-alpha.(ABSTRACT TRUNCATED AT 250 WORDS)     

Developmental changes in myelin-induced proliferation of cultured Schwann cells

Schwann cell proliferation induced by a myelin-enriched fraction was examined in vitro. Although nearly all the Schwann cells contained material that was recognized by antisera to myelin basic protein after 24 h, only 1% of the cells were synthesizing DNA. 72 h after the addition of the mitogen a maximum of 10% of the cells incorporated [3H]thymidine. If the cultures were treated with the myelin-enriched fraction for 24 h and then washed, the number of proliferating Schwann cells decreased by 75% when compared with those cells that were incubated with the mitogen continuously. When Schwann cells were labeled with [14C]thymidine followed by a pulse of [3H]thymidine 24 h later, every Schwann cell labeled with [3H]thymidine was also labeled with [14C]thymidine. Although almost every Schwann cell can metabolize the myelin membranes within 24 h of exposure, a small population of cell initially utilizes the myelin as a mitogen, and this population continues to divide only if myelin is present in the extracellular media. The percentage of the Schwann cells that initially recognize the myelin-enriched fraction as a mitogen is dependent upon the age of the animal from which the cells were prepared.     

The effects of ethylene dimethane sulphonate (EDS) on rat Leydig cells: evidence to support a connective tissue origin of Leydig cells

Ethylene dimethane sulphonate (DS) administered to adult male rats in a single dose of 75 mg/kg body weight results in a rapid destruction of Leydig cells which, in turn, is associated with a marked decline in levels of serum testosterone. For 24-72 h after treatment with EDS (post-EDS) the Leydig cells undergo degenerative changes consisting of chromatin condensation and cytoplasmic vacuolation, and testicular macrophages progressively remove Leydig cells from the intertubular tissue by phagocytosis. This results in the total absence of Leydig cells on Days 7-14 and the absence of any detectable specific 125I-hCG binding to testis homogenates. Associated with the low levels of serum testosterone, levels of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) in serum rise, LH to levels found in castrate rats. Morphometric and 125I-hCG binding studies indicate that a new generation of Leydig cells develop from Day 21 and reach control levels by Day 49. Morphologic observations suggest that the Leydig cells arise by differentiation from a pool of connective tissue cells that includes fibroblasts, lymphatic endothelial cells and pericytes. The new Leydig cells, which appear around Day 21 post-EDS, have the features of fetal Leydig cells. The latter appear to transform into Leydig cells typical of normal adult rats between 35-49 days post-EDS. The differentiation of new Leydig cells is associated with a reestablishment of normal levels of testosterone 21 days post-EDS. Serum LH and FSH return to normal at 28 days and 49 days respectively.     

Monoclonal antibodies against rat Leydig cell surface antigens

Monoclonal antibodies (MAbs) directed against the Leydig cell surface may be used to identify this cell in testicular preparations. Collagenase-dispersed adult rat interstitial cells were fractionated on Percoll density gradients, and Leydig cell-enriched fractions were used to prepare MAbs. Hybridomas were screened by enzyme-linked immunosorbent assay (ELISA), indirect immunofluorescence assay (IIF) on isolated testicular cells and immunocytochemical localization on paraffin sections of adult testes. In density gradient fractions, immunoglobulin (Ig) M MAbs (LC-1C6 and LC-6H6) labeled the surface of cells possessing the morphological characteristics of Leydig cells. The density gradient profiles of MAb-binding activity observed by IIF and ELISA were parallel with the Leydig cell distribution as determined by [125I]-human chorionic gonadotropin (hCG) binding, testosterone response to hCG in vitro, 3 beta-hydroxysteroid dehydrogenase histochemistry and electron microscopy. The MAbs prominently labeled most interstitial cells in sections, but there was little or no labeling of connective tissue, endothelial or seminiferous tubule cells. Both MAbs recognized components of Mr 58,000 in Western blots of Leydig cell-enriched extracts. The results indicate that LC-1C6 and LC-6H6 recognize antigens on the Leydig cell surface that are not present on other isolated testicular cells from the adult rat. These MAbs are specific markers of the Leydig cell in situ and in vitro.     

Clonal distribution of osteoprogenitor cells in cultured chick periostea: Functional relationship to bone formation

Folded explants of periosteum from embryonic chick calvaria form bone-like tissue when grown in the presence of ascorbic acid, organic phosphate, and dexamethasone. All osteoblast-like cells in these cultures arise de novo by differentiation of osteoprogenitor cells present in the periosteum. To study the spatial and functional relationships between bone formation and osteoprogenitor cells, cultures were continuously labeled with [3H]thymidine for periods of 1-5 days. Radioautographs of serial 2-microns plastic sections stained for alkaline phosphatase (AP) showed maximal labeling of 30% of fibroblastic (AP-negative) cells by 3 days while osteogenic cells (AP-positive) exhibited over 95% labeling by 5 days. No differential shifts in labeling indices, grain count histograms of fibroblastic and osteogenic cells or numbers of AP-positive cells were observed, indicating no significant recruitment of cells from the fibroblastic to the osteogenic compartment. Despite the continuous presence of [3H]thymidine, less than 35% of both osteoblasts and osteocytes were labeled at 5 days, indicating that only one-third of the osteoprogenitor cells had cycled prior to differentiation. Spatial clustering of [3H]thymidine-labeled cells was measured by computer-assisted morphometry and application of the Poisson distribution to assess contagion. Cluster size and number of labeled cells per cluster did not vary between 1-3 days, but the number of clusters increased 20-fold between Day 1 and Day 3. Clusters were predominantly AP-positive and located close to bone. Three-dimensional reconstruction from serial sections showed that clusters formed long, tubular arrays of osteogenic cells up to eight cells in length and located within 2-3 cell layers from the bone surface. Selective killing of S-phase cells with two pulse labels of high specific activity [3H]thymidine at 1 and 2 days of culture completely blocked bone formation. These data indicate that a very small population of cycling osteoprogenitor cells is essential for bone formation in vitro and give rise to relatively small numbers of clonally distributed progenitors with limited proliferative capacity. The progeny of these clusters undergo restricted migration and differentiate into osteoblasts.     

The fate of Meckel's cartilage chondrocytes in ocular culture

Modulation of the chondrocyte phenotype was observed in an organ culture system using Meckel's cartilage. First branchial arch cartilage was dissected from fetal rats of 16- and 17-day gestation. Perichondrium was mechanically removed, cartilage was split at the rostral process, and each half was grafted into the anterior chamber of an adult rat eye. The observed pattern of development in nonirradiated specimens was the following: hypertrophy of the rostral process and endochondral-type ossification, fibrous atrophy in the midsection, and mineralization of the malleus and incus. A change in matrix composition of the implanted cartilage was demonstrated with immunofluorescence staining for cartilage-specific proteoglycan (CSPG). After 15 days of culture, CSPG was found in the auricular process but not in the midsection or rostral process. In order to mark the implanted cells and follow their fate, cartilage was labeled in vitro with [3H]thymidine [3H]TdR). Immediately after labeling 20% of the chondrocytes contained [3H]TdR. After culturing for 5 days, 20% of the chondrocytes were still labeled and 10% of the osteogenic cells also contained radioactive label. The labeling index decreased in both cell types with increased duration of culture. Multinucleated clast-type cells did not contain label. Additional cartilages not labeled with [3H]TdR were exposed to between 20000 and 6000 rad of gamma irradiation before ocular implantation. Irradiated cartilage did not hypertrophy or form bone but a fibrous region developed in the midsection. Cells of the host animal were not induced to form bone around the irradiated cartilage. Our studies suggest that fully differentiated chondrocytes of Meckel's cartilage have the capacity to become osteocytes, osteoblasts, and fibroblasts.     

Sertoli cell-secreted protein(s) stimulates DNA synthesis in purified rat Leydig cells in vitro

We have examined the effects of Sertoli cell-secreted proteins (SCSP) on [3H]thymidine incorporation by purified preparations (greater than 96%) of rat Leydig cells to determine whether Sertoli cells influence DNA synthesis in these cells in vitro. Incubation of Leydig cells isolated from testes of rats of ages 16 to 90 days with SCSP (Mr greater than 10,000) induced significant dose-, time- and age-related increases in [3H]thymidine incorporation by the cells. A dose-response curve to SCSP showed that as little as 0.2 micrograms SCSP/ml consistently induced a small but significant increase (31% and 10% above control; P less than 0.001) in [3H]thymidine incorporation by Leydig cells isolated from immature (26 days) and mature (70 days) rats, respectively. The maximum response (230% and 48% above control) was obtained with a concentration of 18 micrograms SCSP/ml in cells isolated from immature and mature rats, respectively. Hydroxyurea, a specific inhibitor of replicative DNA synthesis, significantly (P less than 0.001) inhibited both basal and SCSP-induced [3H]thymidine incorporation in Leydig cells from immature and adult rats without affecting the viability of the cells. Incubation of immature rat Leydig cells in SCSP for 48 h also stimulated a 3-fold increase in cell number. The component of the crude SCSP which stimulated Leydig cell [3H]thymidine incorporation is trypsin-sensitive, heat-stable, and adsorbs to a heparin-agarose affinity column but not to concanavalin A-Sepharose. The secretion of this factor(s) by Sertoli cells is stimulated independently by FSH and testosterone. These results demonstrate for the first time that cultured Sertoli cells secrete a protein(s) which, in vitro, stimulates rat Leydig cell replicative DNA synthesis.     

The effect of culture density and proliferation rate on the expression of ouabain-sensitive Na/K ATPase pumps in cultured human retinal pigment epithelium

The number and activity of ouabain-sensitive Na/K ATPase pumps expressed by many cell types in vitro, including human retinal pigment epithelial cells (RPE), have been shown to decline with increasing culture density. Cell proliferation also declined as cultures became dense so it was unclear if pump number was modulated by cell proliferation or culture confluency. By exposing RPE cultures to various feeding regimens, using culture medium containing or lacking serum, it was possible to produce RPE cultures with a range of culture densities and growth rates. These were analyzed for proliferative activity by quantifying [3H]thymidine incorporation and for Na/K ATPase pump number by measuring specific [3H]ouabain binding. The results suggest that pump number is modulated by culture density and, further, that the density-dependent regulation of pump number requires serum. Although density-dependent modulation of culture growth is also serum requiring, cell proliferation and pump number did not appear to be related; cultures of similar density which differed significantly in growth rate had similar numbers of pumps. The view that elevated numbers of pumps were not necessarily found in proliferating cells was further supported by qualitative examination of radioautographs of cells dually labeled with [3H]thymidine and [3H]ouabain. Cycling cells which had [3H]thymidine-labeled nuclei did not have notably higher labeling with [3H]ouabain. However, [3H]ouabain labeling, as an indicator of pump site number and distribution, did vary among cells in an RPE population and also within individual cells. This latter observation suggests that unpolarized RPE cells in sparse cultures may have regionally different requirements for ionic regulation.     

Origin of regenerating Leydig cells in the testis of the adult rat

Summary Ethane dimethanesulphonate (EDS) was used as a specific cytotoxin to eliminate the Leydig cell population of the adult rat testis. Ultrastructural, morphometric and serum gonadotrophin and testosterone analysis was used to study the response of the intertubular tissue of the testis from 1 day to 10 weeks after EDS treatment. In control animals, the testis contained approximately 28 million Leydig cells and 8 million macrophages. Three to seven days after EDS treatment, Leydig cells were absent and serum testosterone was undetectable. Macrophage numbers increased three-fold by 3 days and returned to pretreatment values thereafter. At 2 and 3 weeks post-EDS, foetal-type Leydig cells (1–2 million per testis) appeared in proximity to perivascular and peritubular tissues, a feature also observed at 4 weeks when numerous such cells (15 million per testis) formed prominent clusters in perivascular and peritubular locations. Between 6 and 10 weeks after EDS treatment, the foetal-type Leydig cells were transformed morphologically into adult-type Leydig cells, they occupied central intertubular positions and their numbers were restored to pretreatment values. Regeneration of Leydig cells was reflected by elevated serum testosterone levels which returned towards the normal range. The results demonstrate the regenerative capacity of the testicular intertubular tissue and indicate a dual site of origin of Leydig cells which initially resemble foetal-type Leydig cells prior to establishing the adult-type Leydig cell population. The morphological pattern of Leydig cell regeneration suggests that in addition to gonadotrophic stimulation, local testicular factors from the seminiferous tubules may stimulate Leydig cell growth.     

Temporal and Quantitative Expression of the Myelin-Associated Lipids,Ethanolamine Plasmalogen,Galactocerebroside, and Sulfatide,in the Differentiating CG-4 Glial Cell Line

We determined the expression of three myelin-typical lipids in the continuous CG-4 glial cell line of oligodendrocyte progenitor cells, as the cells differentiated into oligodendrocytes. On 6 different days during the first 9 days of oligodendrocyte development, cells were labeled for 24 h with [³H]ethanolamine to label ethanolamine plasmalogens or with [³H]galactose to label the galactocerebroside and sulfogalactocerebroside; and the amount of labeled lipid expressed on each day was determined. Each labeled lipid was expressed with its own specific time course and in a defined amount on each day of differentiation. Increased labeling of plasmalogens and sulfogalactocerebroside started at early developmental stages, and increased labeling of galactocerebroside started at later stages. The results indicate that the differentiating CG-4 cell line provides a valuable system to investigate factors affecting the early time course of myelin-lipid expression and the amounts expressed.     

RENEWAL OF TASTE BUD CELLS IN RAT CIRCUMVALLATE PAPILLAE

The life span of taste bud cells in rat circumvallate papillae was measured by autoradiography after labeling them with a pulse of [³H]thymidine. Specimens of circumvallate papillae were taken daily 1·5-18·5 days after the isotope was administered; thereafter, specimens were taken on alternate days until 25·5 days. For each time interval, the number of labeled cell nuclei was counted in 200-450 taste buds and plotted as the ratio of labeled cells/taste bud v. time after injection of [³H]TdR. In all, 6958 taste buds were counted. The total number of labeled cells (dark plus light) per taste bud reached peaks at 6·5, 13·5 and 20·5 days. The curve for the number of labeled dark cells/bud had essentially the same shape as that for total cells. The number of labeled light cells/bud reached a modest peak at 6·5 days and slowly declined to a plateau for the remainder of the experiment. The data show that an average of 2 days elapsed after injection before labeled dark cells entered the bud and they spent an average of 7 days in the non-proliferating taste bud compartment; thus, the life span of the dark cell was 9 days. The life span of the light cell was difficult to estimate quantitatively, but this cell type was labeled at a much slower rate than dark cells and is assumed to have a significantly longer tenure in the taste bud.     

Differential spermatogonial stem-cell survival and mutation frequency

One group of adult C3H×101 hybrid male mice was given 3 injections of 12.5 μCi of [³H]thymidine at 9-h intervals and irradiated 24 h after the last injection with X-ray doses of 100, 300, 500, 600, 1000 R or the first fraction of a split 1000-R dose given as two 500-R exposures 24 h apart. Mice were killed 207 and 414 h after irradiation. A second group of mice was given a single injection of 12.5 μCi of [³H]thymidine 1 h before irradiation with single exposures of 300, 500, 600, 1000 R, or the first fraction of a 1000-R exposure given as two 500-R fractions 24 h apart. Mice were killed 120 and 207 h after irradiation. In both experiments, parallel groups of mice were given X-ray only as a control for the effect of [³H]thymidine. Two sets of slides were prepared for each mouse receiving [³H]thymidine: one set was not autoradiographed and was used for scoring cell survival; the second set was coated with emulsion and used for scoring percentage of labeled cells. The dose-response curves for survival at 120 and 207 h were curvilinear, with no evidence of discontinuity over the 100–1000-R range. After multiple injections of [³H]thymidine and irradiation 24 h later, percentage of labeled cells at 207 h was comparable for controls, 100, 300, and 600 R; significantly lower than controls for 1000 R; and significantly above controls after 500 + 500 R. Thus the surviving stem-cell population was qualitatively the same for that portion of the dose-response curve giving a linear increase in mutation rate but was different for both 1000-R and 500 + 500-R exposures, and the single and fractionated 1000-R exposures differed from each other. This parallelism between survival of labeled cells and mutation frequency in spermatogonial stem cells suggests that a stage in the cell cycle 24–42 h after DNA synthesis is resistant to cell killing but sensitive to mutation induction. The mutation rate after a single 1000-R exposure is low because labeled, mutation-sensitive cells have been selectively killed. Mutation frequency after the 500 + 500-R dose is increased because of synchronization induced by the first dose combined with selective killing of unlabeled cells by the second fraction. Irradiation 1 h after labeling with [³H]-thymidine demonstrated that the S phase of the spermatogonial stem-cell cycle is sensitive to radiation-induced cell killing.     

Use of a double-label method to detect rapid changes in the rate of cell proliferation.

We developed a double-label method to directly measure the rate at which cells enter S-phase of the cell cycle. All cells in S-phase were first labeled with a short pulse of [3H]-thymidine. This was followed by a longer incubation in bromodeoxyuridine (BrdU), a thymidine analogue. Nuclei labeled with [3H]-thymidine were detected by autoradiography and those labeled with BrdU by immunocytochemistry. Cells labeled only with BrdU must have entered S-phase at some time after the end of the [3H]-thymidine pulse. Thus, the rate of entry of cells into S-phase could be determined. This method was shown to be more accurate and more sensitive than determining changes in the rate at which cells entered S-phase with a continuous labeling protocol. It was possible to detect changes in proliferative activity that occurred in less than 1 hr. We used this double-label technique to study changes in the cell cycle during the terminal differentiation of chicken embryo lens fiber cells. These studies revealed differences in the effects of several treatments known to stimulate fiber cell differentiation. They also demonstrated the presence in the embryonic eye of factors that stimulate and prevent lens cell proliferation and differentiation.     

HUMAN VASCULAR ENDOTHELIAL CELLS IN CULTURE : Growth and DNA Synthesis

Human endothelial cells, obtained by collagenase treatment of term umbilical cord veins, were cultured using Medium 199 supplemented with 20% fetal calf serum. Small clusters of cells initially spread on plastic or glass, coalesced and grew to form confluent monolayers of polygonal cells by 7 days. Cells in primary and subcultures were identified as endothelium by the presence of Weibel-Palade bodies by electron microscopy. A morphologically distinct subpopulation of cells contaminating some primary endothelial cultures was selectively subcultured, and identified by ultrastructural criteria as vascular smooth muscle. Autoradiography of endothelial cells after exposure to [³H]thymidine showed progressive increases in labeling in growing cultures beginning at 24 h. In recently confluent cultures, labeling indices were 2.4% in central closely packed regions, and 53.2% in peripheral growing regions. 3 days after confluence, labeling was uniform, being 3.5 and 3.9% in central and peripheral areas, respectively. When small areas of confluent cultures were experimentally "denuded," there were localized increases in [³H]thymidine labeling and eventual reconstitution of the monolayer. Liquid scintillation measurements of [³H]thymidine incorporation in primary and secondary endothelial cultures in microwell trays showed a similar correlation of DNA synthesis with cell density. These data indicate that endothelial cell cultures may provide a useful in vitro model for studying pathophysiologic factors in endothelial regeneration.     

Selective control of fibroblast proliferation and its effect on cardiac muscle differentiation in vitro

The stability of the differentiated state of cardiac myocytes in vitro was examined under culture conditions which selectively stimulated or inhibited proliferation of fibroblasts. Regulation of fibroblast proliferation in cultures of myocardial cells from 8-day embryonic chicks was achieved by adjustment of the glutamine (Gln) concentration in the culture medium (Ham's F-12 medium containing 2 x amino acids and 5% fetal calf serum). Myocardial cells, when plated at 80 cells/mm2 in Gln- medium, maintained a stable density of approximately 40% of the plating density for more than 30 days. When Gln was added to the medium (292 micrograms/ml) fibroblast proliferation was stimulated, and by 5-6 days after this addition cell densities had increased to confluency. The selective action of glutamine on fibroblast proliferation was determined by labeling cultures with tritiated thymidine ([3H]TdR) and scoring its incorporation into myocytes and fibroblasts by radioautography. After 2 weeks in Gln- medium, the mitotic index was 0.3% and the [3H]TdR-labeling index (1.5-hr pulse) was 6.4%. In addition, the proportion of myocytes in the population was constant at 64.2% for at least 30 days in vitro, and contractile activity was observed for up to 6 months. After 5 days of Gln replacement, the cells exhibited a labeling index of 25%, the proportion of myocytes decreased to less than 10% and contractile activity was rarely observed. Although the [3H]TdR-labeling index of fibroblasts and myocytes was nearly identical in Gln- medium, the addition of Gln produced a fivefold stimulation in the fibroblast labeling index, but did not affect myocyte proliferation or DNA synthesis. A unique phenomenon of myocyte congregation was observed only in Gln- medium which resulted in the formation of myocyte colonies from which fibroblasts were largely absent. It is suggested that this process with the resultant establishment of a functional electrical syncytium plays a significant role in the development and stabilization of myocyte differentiation in vitro.     

Retention of bone cell viability in mouse calvarial explants after cryopreservation

Newborn mouse calvaria, cyropreserved at -196 degrees C in serum-free medium containing dimethyl-sulfoxide, were compared to unpreserved explants for bone cell viability by [3H]thymidine uptake. Other explants were studied using autoradiography to compare the histological appearance of the cryopreserved and control unpreserved explant sites of cellular localization of [3H]thymidine. After short-term cryopreservation, calvarial bone cells, including less differentiated osteoprogenitor cells, survived as indicated by their incorporation of the DNA precursor. With culture continuing for up to 24 hr after thawing and in the continuous presence of [3H]thymidine, additional labeled thymidine was incorporated, indicating that the proliferative ability of explant cells persists after cryopreservation. Cryopreserved bone explants did not, however, incorporate the same amount of labeled thymidine as did controls at each time point studied. These events, as measured quantitatively and observed by autoradiography of the tissue, indicate that newborn calvarial bone cell proliferation in vitro continues after cryopreservation. The large surface:mass ratio of the tissue and its proportionate volume of calcified matrix apparently permits it to behave as an isolated cell population with regard to the diffusion of the cryoprotectant and thermal conductivity, thus permitting the retention of explant viability.     

Culture of mouse germ cells isolated from fetal gonads

Mouse germ cells isolated from male or female genital ridges at 121/2 days post coitum were cultured at room temperature for up to 6 days, with [3H]thymidine present in the culture medium for either the first 24 h or the last 24 h of each culture period. Germ cells were also isolated 131/2-161/2 days post coitum and cultured for 24 h in the presence of [3H]thymidine. The proportion of cells in metaphase, and the proportion of labelled interphase and metaphase nuclei, was recorded. The labelling index declined from 131/2 days onwards, after development either in vivo or in vitro. No labelled metaphase plates were seen after 24 h in the presence of [3H]thymidine, suggesting that under these culture conditions the duration of the G2 phase exceeded 24 h. The results showed that the culture system, in spite of the low temperature, allowed the germ cells to replicate their DNA and undergo mitosis for up to 6 days. Addition of db-cAMP to the culture medium proved highly toxic to male germ cells, and did not markedly increase the proliferation rate of female germ cells.     

Turnover of Acinar and Islet Cells in the Pancreas of Monosodium Glutamate‐Treated Obese Mice

Objective: Subcutaneous administrations of monosodium glutamate (MSG) to neonatal animals result in obesity and induce the toxicity on the central nervous system, and furthermore, have an effect on entero‐pancreatic hormone. The effect of MSG on the cell turnover of organs, especially the pancreas, has received little attention until now. This study was designed to examine the effect of MSG on pancreatic cell turnover by immunohistochemistry and [³H]thymidine autoradiography. Research Methods and Procedures: Male JcI‐ICR strain mice were SC injected with MSG (2 mg/g body weight daily) for 5 days after birth, received 112 repeated injections of [³H]thymidine at 6‐hour intervals for 28 days after birth, and then were killed immediately thereafter, or 30, 60, or 120 days after the last injection. Autoradiography was performed on sections immunostained for glucagon, insulin, and somatostatin. Results: After continuous labeling, most pancreatic cells were labeled, and thereafter, labeling of cells decreased in control and MSG‐treated mice. The mean grain counts of acinar cells in MSG‐treated mice decreased more slowly than those in control mice. On the other hand, those of islet cells, including glucagon, insulin, and somatostatin cells, decreased more rapidly in MSG‐treated mice than those in control mice. Discussion: Cell turnover of acinar cells was decelerated and that of islet cells including glucagon, insulin, and somatostatin cells was accelerated in MSG‐treated mice pancreas. MSG‐induced hypothalamic lesions exert the contrary influences on the cell turnover of acinar and islet cells.