DNA-synthesizing cells in oral epithelium have a range of cell cycle durations: evidence from double-labelling studies using tritiated thymidine and bromodeoxyuridine

Abstract Mouse tongue epithelium is characterized by a circadian variation in the number of DNA-synthesizing cells (labelling index, LI). Cells undergoing DNA synthesis were labelled with tritiated thymidine ([³H]TdR) at 0300 (peak LI) or 1200 h (low LI). The fate of these cells was assessed by injecting animals with bromodeoxyuridine (BrdU) at intervals from 12–48 h after [³H]TdR, to follow them from one cell cycle to the next. Labelling was revealed by combining [³H]TdR autoradiography with immunoperoxidase detection of BrdU in the same sections.
A single peak in the appearance of double-labelled cells was seen at 44 h, if [³H]TdR was given at 1200 h; following [3H]TdR at 0300 h, a peak of double labelling was seen at 48 h with the possibility of smaller peaks at 24 h and 36 h.
These results show that the 24 h periodicity in LI in this tissue is associated with a predominant cell cycle duration of 44–48 h, but that a few cells cycle more quickly. Double labelling with [³H]TdR and BrdU provides a useful method for establishing cell cycle duration by labelling S-phase cells in successive cell cycles.     

Spermatogonial multiplication in the Chinese hamster. IV. Search for long cycling stem cells

In the Chinese hamster, 17 days, i.e. one cycle of the seminiferous epithelium, after two injections of [3H]TdR given 24 hr apart, labelled cells were found among all types of spermatogonia, including stem cells (As). These labelled As spermatogonia derive from one or more self-renewing divisions of the stem cells that originally incorporated [3H]TdR. In the steady state, half of the divisions of the As will be self-renewing and the other half will give rise to Apr spermatogonia that will ultimately become spermatozoa. Theoretically, the labelling index (LI) after 17 days will be similar to that after 1 hr, and in this study twice as high as for the 1-hr interval since only one injection was given. However, experimental values only half that of the theoretical LI were found after 17 days. The following causes for the loss of labelled stem cells are discussed: (1) dilution of label because of division; (2) influx of unlabelled components of false pairs (i.e. newborn stem cells that still have to migrate away, mostly during G1, from their sister cells and are scored as Apr spermatogonia) between 1 hr and 17 days; (3) the existence of long- and short-cycling stem cells, probably combined with preferential differentiation of the short-cycling elements; (4) selective segregation of DNA at stem cell mitosis; and (5) irradiation death of radiosensitive labelled stem cells. As it is not impossible that factors 1, 2, 4 and 5 together account for the total loss of labelled stem cells, LI results do not provide evidence for the existence of separate classes of short- and long-cycling stem cells. The distributions of the LIs of the As, Apr and Aal spermatogonia over the stages of the epithelial cycle at 17 days are similar to those at 1 hr after injection. Hence the regulatory mechanisms that govern the stimulation and inhibition of proliferation of As that give rise to new As for the next epithelial cycle are similar to those of the As that will divide into Apr spermatogonia during the same epithelial cycle. Grain counts revealed that more [3H]TdR is incorporated into As, Apr and Aal spermatogonia that are in S phase during epithelial stages X-IV than in stages V-IX.     

Double labelling of cells with tritiated thymidine and bromodeoxyuridine reveals a circadian rhythm-dependent variation in duration of DNA synthesis and S phase flux rates in rodent oral epithelium

Abstract. We describe a double labelling method for estimating the duration of DNA synthesis (Ts) and the flux of cells into and from the S phase of the cell cycle, based on labelling with tritiated thymidine ([³H]TdR) followed by bromodeoxyuridine (BrdU) and combining immunohistological detection of BrdU with conventional autoradiography. In practice, the change in size of a window of double labelled cells occurs as the time interval between the two labels increases. In mouse tongue epithelium there is a marked circadian variation in the number of cells in DNA synthesis. From 0900 to 1500 h this labelling index (LI) falls, but from 2100 to 0300 h it increases. Our results show that the circadian decrease in LI is associated with a short Ts (5·8 ± 0·3 h), a high S phase efflux and an initially low influx of cells from G_: into S. Conversely, the rising circadian LI is associated with a longer Ts (9.4 ± 0.1 h), an initially low efflux and a moderate to high influx. Two time-points exist on the circadian LI curve when influx and efflux rates change abruptly. At 0100 h the efflux rate rises from low (5 cells %/h) to high (15–16 cells %/h) and simultaneously the influx rate changes from high to low. Similarly at 1300–1400 h, efflux rate falls from high (19–20 cells %/h) to low (4–8 cells %/h) values and influx rates change from low to high. This double labelling method has revealed that the duration of DNA synthesis varies across the circadian cycle, as do influx and efflux values which generally fall within a discrete range of high or low values. The timing of the changes in flux suggests the presence of two 'control' points on the circadian LI cycle that were previously unrecognized.     

In vivo labelling with halogenated pyrimidines of squamous cell carcinomas and adjacent non-involved mucosa of head and neck region

The frequency and distribution of labelled cells were studied immunohistochemically in 37 squamous cell carcinomas (SCC) of head and neck after in vivo infusion of IdUrd and BrdUrd. Tumours were classified according to their labelling patterns. Low and moderate grade SCC consisted of tumour islands separated by interstitial tissue. In some tumours labelled cells only appeared near the basal layer while in others proliferative cells were evenly distributed within the neoplastic island. In anaplastic carcinomas labelled cells were distributed either randomly or around blood vessels (cord structures). While the basal layer in adjacent normal epithelium contained very few labelled cells (LI = 1.6 ± 0.2%), the LI of basal cells in tumour islands were much higher than the average LI of the tumour (47.2 ± 2.8% and 23.8 ± 1.6%, respectively). In patients who had received cytotoxic therapy up to two months before the biopsy, the LI in the basal layer of normal epithelium was 19.0 ± 3.5%. In sequential biopsies obtained 1–2 weeks after the infusion of IdUrd and BrdUrd some labelled tumour cells were found in necrotic foci and in pearl structures. Additionally, in six tumours, we found areas of cells labelled with IdUrd alone, even though the IdUrd infusion had been followed by a BrdUrd infusion 1 h later. This is in agreement with the phenomenon of intermittent tumour blood flow described earlier in experimental tumours.     

Streaming of labelled cells in the conjunctival epithelium

This study examines epithelial cell streaming and turnover in normal rat bulbar conjunctiva. Twenty seven male adult random-bred Hebrew rats weighing between 250–300 g, were injected i.p. with [³H]-thymidine. Three rats were killed at various times, thereafter from 1 h to 28 days. The enucleated eyes were fixed in formalin, cut into 5 μ thick sections, dipped into liquid emulsion, exposed for three weeks and stained with haematoxylin and eosin. Conjunctival epithelium was scanned from the limbus and outward, using an ocular micrometer grid with 10 x 10 divisions. In each consecutive field the grid was positioned along the basement membrane which was defined as the x-axis. The y-axis extended from the basement membrane outward. The x, y coordinate of each nucleus with three grains or more and its grain content were recorded along the entire epithelium. Conjunctival epithelium is divided into two cell kinetic compartments: a progenitor (P), along the basal and supra basal layer, in which cells proliferate, and a non proliferating Q-compartment, in the layers above. One hour after labelling most of the labelled cells were in the basal and supra basal layers. From then onward labelled cells streamed along both axes. Their x-velocity was 10·5±2·4 μ/day and the y-velocity 9·3 ± 5·4 μ/day. Cells are eliminated at the epithelial surface which is the outer Q-compartment boundary. Basal cell turnover was estimated from grain count dilution curves. The time it takes for the grains in a cell to reach half of their initial value was 8·3 days. It is closely related to the cell's generation time. The present study demonstrates that conjunctival epithelium in the rat streams along two axes, x, and y: 1 The x-axis extends along the basal layer, from the limbus and outward. 2 The y-axis extends from the basal layer into the layers above it. Cells first stream along the x-direction and then turn y-ward. Since cells are ultimately exfoliated from the conjunctival surface, and since the conjunctiva maintains steady state, we propose that stem cells located in the limbus generate transitional cells that stream along the two axes. Macroscopically the limbus is circular, and the stem cells are situated around the cornea. Each stem cell and its streaming progeny can be viewed as a conjunctival epithelial unit. We propose that conjunctival and corneal epithelium, are the descendants of an uncommitted stem cell that generates two differentiation pathways, a corneal and a conjunctival.     

Acute lethal graft-versus-host disease stimulates cellular proliferation in the adult rat liver

Abstract. The present investigation was designed to analyse the effects of acute lethal graft-versus-host disease (GVHD) in adult (DA x LEW)F₁ rats on cellular proliferation within the liver. The influence of the host thymus on GVHD-induced proliferation was also assessed. From 1–28 days after initiation of GVHD [³H]thymidine ([³H]-TdR) was injected i.v. and rats were killed one hour later. Percentage labelled cells (LI) of periportal infiltrating cells (PIC), hepatocytes (H), and sinusoidal lining cells (SC) were counted. Mean values for control rats were 0.3 ± 0.1% (H), 0.4 ± 0.1% (SC) and 0.2 ± 0.1% (PIC). GVHD rats demonstrated a significant increase in LI of PIC (days 1–21), SC (days 2–17) and H (days 2–17). Most labelled cells in PIC were large lymphocytes. Peak LI values were 7.0 ± 1.0% PIC (day 17), 6.8 ± 0.9% SC (day 17), and 5.2 ± 0.9% H (day 7), with all cellular compartments returning to near normal LI values by day 28. Stimulation of cellular proliferation occurred in all three liver cell compartments in neonatally thymectomized (TXM) rats. The intensity of GVHD-induced cell proliferation was significantly decreased at day 7 in all compartments and PIC was dramatically decreased at day 21 in TXM-GVHD rats as compared to non-TXM-GVHD rats. It is hypothesized that the general stimulation of hepatocyte cell proliferation in GVHD is related to the secretion of lymphokines by primarily donor and secondarily host T cells in the periportal infiltrate.     

Stereo architecture of the interface of the epithelial cell layer and connective tissue core of the foliate papilla in the rabbit tongue.

The three-dimensional relationship between the epithelial cell layer and the underlying connective tissue core (CTC) of the foliate papilla of the rabbit tongue was studied by scanning electron microscopy after removal of the epithelial cell layer. The foliate papillae were fixed in Karnovsky's fixative, and the epithelial cell layers were exposed to long-term hydrochloric acid treatment (3.5 N HCl for 2-3 weeks at room temperature). The foliate papillae consisted of ridges and grooves located on the posterolateral margin of the tongue. They appeared as linear projections or ridges of lingual mucosa roughly perpendicular to the longitudinal axis of the tongue. These projections or ridges were parallel to one another and separated by grooves. After removal of the epithelium, two kinds of CTC folds appeared: one was the septal fold of CTC which runs in the central portion under each linear projection or ridge, and the other consisted of two sheets of groove side folds of CTC which run along both sides of the former and face the groove side epithelium. It was revealed that there are two sheets of septal epithelial processes, and each of them fits in between each septal fold and groove side fold of CTC. Numerous taste buds were located in the groove side epithelia, and their pores faced the surface of the groove. On the hollow surfaces that appeared on the surface of the groove side fold of CTC after removal of the epithelial cells with taste buds, nerve-terminal-like structures were encountered. Some openings of the ducts of small lingual glands were arranged linearly on the underside of the basal portion of each groove side epithelium.     

REGENERATION OF UTERINE EPITHELIUM AFTER EXPERIMENTAL ABLATION IN THE RAT

Regeneration of the uterine luminal epithelium was studied after its mechanical removal in progesterone-primed rats, leaving one control horn intact. Pulse labelling with [³H]TdR during regeneration, showed a rapid peak of labelling index in remaining glands. A differentiated and highly labelled luminal epithelium reappeared at 34 hr, thereafter showing a rapidly declining LI. After initial depletion, the glandular cell population size was restored within 64 hr, whereas luminal epithelium cell numbers became stabilized at about half normal level. Grain counts after prelabelling showed more rapid dilution in gland cells of stripped uterine horns, indicating accelerated cycling of previously dividing cells. Thymidine labelling indices also showed that, after removal of the epithelium, almost all gland cells became rapidly committed to divide. On average, less than two cell cycles were necessary to restore stable glandular and epithelial population sizes. Numbers of labelled cells were also drastically increased in myometrium and serosa of treated horns. This suggests a non-specific mechanism for stimulation of mitotic activity after ablation of epithelium.     

The bovine desmocollin family: a new gene and expression patterns reflecting epithelial cell proliferation and differentiation

We have discovered a third bovine desmocollin gene, DSC3, and studied expression of all three desmocollin genes, DSC1, 2, and 3, by Northern blotting, RT-PCR and in situ hybridization. DSC1 is strongly expressed in epidermis and tongue papillae, showing a "skin"-type pattern resembling that previously described for keratins 1 and 10. Expression is absent from the epidermal basal layer but appears in the immediate suprabasal layers and continues uniformly to the lower granular layer. In tongue epithelium, expression is suprabasal and strictly localized to papillae, being absent from interpapillary regions. In other epithelial low level DSC1 expression is detectable only by RT-PCR. The distribution of Dsc1 glycoproteins, detected by an isoform-specific monoclonal antibody, closely reflects mRNA distribution in epidermis and tongue. DSC2 is ubiquitously expressed in epithelia and cardiac muscle. In stratified epithelia, expression appears immediately suprabasal, continuing weakly to the lower granular layer in epidermis and to just above half epithelial thickness in interpapillary tongue, oesophageal, and rumenal epithelia. DSC3 expression is restricted to the basal and immediately suprabasal layers in stratified epithelia. In deep rete ridges DSC expression strikingly resembles the distribution of stem, transit-amplifying, and terminally differentiating cells described by others. DSC3 expression is strongly basal, DSC2 is strong in 5-10 suprabasal layers, and then weakens to be superseded by strong DSC1. These results suggest that desmocollin isoform expression has important functional consequences in epithelial proliferation, stratification, and differentiation. The data also provide a standard for nomenclature of the desmocollins.     

Patterns of epithelial expression of Fos protein suggest important role in the transition from viable to cornified cell during keratinization

An antibody directed against the DNA-binding region of c-fos was used to localize the distribution of cells positive for Fos protein in epithelial tissues. The antibody consistently bound to the nuclei of epithelial cells in the late stages of differentiation, just prior to cornification. The epidermis, palate, buccal mucosa, gingiva, tongue, forestomach and vagina in estrus all produced this type of labelling, suggesting a burst of expression immediately before cell death and cornification. The differentiating cells of the hair follicle, including the hair and inner root sheath, were also labelled. Non-keratinized tissues including junctional epithelium, embryonic epidermis and diestrus vaginal epithelium showed little or no Fos labelling. With the onset of keratinization at 18 days gestation or with induction of estrus in ovariectomized mice with estradiol benzoate, the epidermis and vagina expressed Fos protein in the manner typical for keratinized tissues. The Er/Er mutant epidermis, a tissue that is blocked in its ability to keratinize, overexpresses Fos with Fos-positive cells appearing in virtually every cell layer. Gel shift analysis demonstrates the presence of a functional AP-1 complex in epidermal extracts that is recognized by our antibody. Our data suggest that the expression of Fos is intricately related to epithelial cell differentiation, specifically in relation to the process of cornification and cell death.     

Culture of endodermal stem/progenitor cells of the mouse tongue

The tongue represents a very accessible source of tissue-specific epithelial stem cells of endodermal origin. However, little is known about the properties of these cells and the mechanisms regulating their proliferation and differentiation. Foxa2, an endodermal marker, is expressed throughout the tongue epithelium during embryonic development but becomes confined to a minority of basal cells and some taste bud sensory cells in the adult tongue. Using a previously described line of transgenic mice in which enhanced green fluorescent protein (eGFP) is expressed under the control of a human keratin 5 promoter region (Krt5-eGFP), we have isolated a subpopulation of cells in the basal epithelial layer of the mouse tongue with a high efficiency of generating holoclones of undifferentiated cells in culture with a feeder layer. Krt5-GFP(hi) cells can both self renew and give rise to differentiated stratified keratinized epithelial cells when cultured on an air-liquid interface.     

Spermatogonial Multiplication In the Chinese Hamster. Iv. Search For Long Cycling Stem Cells

ABSTRACT In the Chinese hamster, 17 days, i. e. one cycle of the seminiferous epithelium, after two injections of [³H]TdR given 24 hr apart, labelled cells were found among all types of spermatogonia, including stem cells (A_s). These labelled A_s spermato-gonia derive from one or more self-renewing divisions of the stem cells that originally incorporated [³H]TdR. In the steady state, half of the divisions of the A_s will be self-renewing and the other half will give rise to A_pr spermatogonia that will ultimately become spermatozoa. Theoretically, the labelling index (LI) after 17 days will be similar to that after 1 hr, and in this study twice as high as for the 1-hr interval since only one injection was given. However, experimental values only half that of the theoretical LI were found after 17 days. the following causes for the loss of labelled stem cells are discussed: (1) dilution of label because of division; (2) influx of unlabelled components of false pairs (i. e. newborn stem cells that still have to migrate away. mostly during G₁, from their sister cells and are scored as A_pr spermatogonia) between 1 hr and 17 days; (3) the existence of long- and short-cycling stem cells, probably combined with preferential differentiation of the short-cycling elements; (4) selective segregation of DNA at stem cell mitosis; and (5) irradiation death of radiosensitive labelled stem cells. As it is not impossible that factors 1, 2, 4 and 5 together account for the total loss of labelled stem cells, LI results do not provide evidence for the existence of separate classes of short- and long-cycling stem cells. The distributions of the LIs of the A_s, A_pr and A_al spermatogonia over the stages of the epithelial cycle at 17 days are similar to those at 1 hr after injection. Hence the regulatory mechanisms that govern the stimulation and inhibition of proliferation of A_s that give rise to new A_s for the next epithelial cycle are similar to those of the A_s that will divide into A_pr spermatogonia during the same epithelial cycle. Grain counts revealed that more [³H]TdR is incorporated into A_s, A_pr and A_al spermatogonia that are in S phase during epithelial stages X-IV than in stages V-IX.     

CIRCADIAN RHYTHMS OF PRESUMPTIVE STEM CELLS IN THREE DIFFERENT EPITHELIA OF THE MOUSE

Variation in the percentage of labelled cells (LI), mitoses (MI) and apoptosis (AI: i.e. shrinkage necrosis) have been studied throughout a 24 hr period (40 min after labelling with ³H-TdR) for tongue epithelium, epidermis and intestinal epithelium in the mouse. A room with reversed light cycle was used to obtain data for half of the 24 hr period. All three tissues showed marked variations in LI with peak values between 24.00 and 03.00 hours. In the intestine a maximum value for MI was observed 3-6 hr after that for LI and with a maximum value for AI slightly later. In all three epithelia the circadian rhythm was most striking in cells at positions which can be correlated with presumptive stem cell activity; e.g. in the crypts the labelling and mitotic peaks reflecting a circadian rhythm were most clearly distinguishable at the basal part of the crypts. These observations are discussed in relation to the validity of various proliferative models.     

DNA-synthesizing cells in oral epithelium have a range of cell cycle durations: evidence from double-labelling studies using tritiated thymidine and bromodeoxyuridine

Mouse tongue epithelium is characterized by a circadian variation in the number of DNA-synthesizing cells (labelling index, LI). Cells undergoing DNA synthesis were labelled with tritiated thymidine [( 3H]TdR) at 0300 (peak LI) or 1200 h (low LI). The fate of these cells was assessed by injecting animals with bromodeoxyuridine (BrdU) at intervals from 12-48 h after [3H]TdR, to follow them from one cell cycle to the next. Labelling was revealed by combining [3H]TdR autoradiography with immunoperoxidase detection of BrdU in the same sections. A single peak in the appearance of double-labelled cells was seen at 44 h, if [3H]TdR was given at 1200 h; following [3H]TdR at 0300 h, a peak of double labelling was seen at 48 h with the possibility of smaller peaks at 24 h and 36 h. These results show that the 24 h periodicity in LI in this tissue is associated with a predominant cell cycle duration of 44-48 h, but that a few cells cycle more quickly. Double labelling with [3H]TdR and BrdU provides a useful method for establishing cell cycle duration by labelling S-phase cells in successive cell cycles.     

A long-lived thymidine pool in epithelial stem cells

Abstract. The labelling index (LI) of the individual basal cell positions of the anterior column of mouse tongue filiform papillae was assessed with time after an injection of [³H]TdR at 12.00 hours (the minimum point in the circadian LI rhythm). An initial doubling of the LI in the stem cell zone due to cell division was followed by a second rise of 14–16% 16 hr after injection and this occurred even in the presence of vincristine. Although the uptake of [³H]TdR and the initial LI doubling were largely prevented by a preceding injection of hydroxyurea, the 14–16% LI rise was still observed. The possible explanations are discussed, the favoured one being that an average of one of the six or seven cells (the stem cell) in each stem cell zone can store [³H]TdR in a long-lived precursor pool for at least 16 hr before being utilized for DNA synthesis. This complements previously published work which suggested that one cell in each stem cell zone may selectively segregate DNA at mitosis.     

The epithelium of the dorsal marginal zone of Xenopus has organizer properties.

We have investigated the properties of the epithelial layer of the dorsal marginal zone (DMZ) of the Xenopus laevis early gastrula and found that it has inductive properties similar to those of the entire Spemann organizer. When grafts of the epithelial layer of the DMZ of early gastrulae labelled with fluorescein dextran were transplanted to the ventral sides of unlabelled host embryos, they induced secondary axes composed of notochord, somites and posterior neural tube. The organizer epithelium rescued embryos ventralized by UV irradiation, inducing notochord, somites and posterior neural tube in these embryos, while over 90% of ventralized controls showed no such structures. Combinations of organizer epithelium and ventral marginal zone (VMZ) in explants of the early gastrula resulted in convergence, extension and differentiation of dorsal mesodermal tissues, whereas similar recombinants of nonorganizer epithelium and the VMZ did none of these things. In all cases, the axial structures forming in response to epithelial grafts were composed of labelled graft and unlabelled host cells, indicating an induction by the organizer epithelium of dorsal, axial morphogenesis and tissue differentiation among mesodermal cells that otherwise showed non-axial development. Serial sectioning and scanning electron microscopy of control grafts shows that the epithelial organizer effect occurs in the absence of contaminating deep cells adhering to the epithelial grafts. However, labelled organizer epithelium grafted to the superficial cell layer contributed cells to deep mesodermal tissues, and organizer epithelium developed into mesodermal tissues when deliberately grafted into the deep region. This shows that these prospective endodermal epithelial cells are able to contribute to mesodermal, mesenchymal tissues when they move or are moved into the deep environment. These results suggest that in normal development, the endodermal epithelium may influence some aspects of the cell motility underlying the mediolateral intercalation (see Shih, J. and Keller, R. (1992) Development 116, 901-914), as well as the tissue differentiation of mesodermal cells. These results have implications for the analysis of mesoderm induction and for analysis of variations in the differentiation and morphogenetic function of the marginal zone in different species of amphibians.     

Adhesion to porcine squamous epithelium of saccharide and protein moieties of Lactobacillus fermentum strain 104-S.

The mechanism by which Lactobacillus fermentum strain 104-S adheres to porcine squamous epithelium was investigated by studying the adsorption to epithelial cells, and control surfaces, of radioactively labelled material released from the bacterial cells by water extraction. The released material was fractionated by gel filtration and the adsorption of pronase-sensitive and -resistant material in the various fractions to porcine gastric tissue and the control surfaces of polystyrene and immobilized bovine serum albumin (BSA) was determined. The fraction with affinity for the epithelium was characterized by enzymic degradation, periodate oxidation, lipid extraction, and protein and carbohydrate analyses. The adsorption pattern of radioactively labelled crude released material mimicked the adhesion of whole labelled cells to polystyrene and to gastric squamous tissue pieces. On fractionation, the pattern of adsorption to polystyrene and BSA was different from that obtained for the tissue pieces. Considerably less labelled pronase-stable material bound to surfaces of polystyrene and BSA, as compared with the tissue, suggesting that the pronase-resistant component has a tissue-specific affinity. After pronase treatment of the fraction of M(r) about 20,000 (20 K) containing labelled components with affinity for the epithelium, only saccharides were detected. Radioactivity was lost after hydrolysis with HCl, and therefore this pronase-resistant labelled component must be a saccharide. It is concluded that protein moieties in the extract have an affinity for several surfaces, including polystyrene, and that saccharide moieties have a specific affinity for the gastric squamous epithelium.     

Development of an in vitro colony formation assay for the evaluation of in vivo chemotherapy of a rat brain tumor.

An in vitro colony formation assay for the evaluation of in vivo brain tumor therapy has been developed. When plated, disaggregated cells derived from solid tumors proliferated to form relatively homogeneous colonies after a latency period of 2 to 6 days. Increasing concentrations of fetal calf serum enhanced colony-forming efficiency (CFE) with a plateau between 7 and 16%. Supplementation with either irradiated feeder cells (10(3) to 10(5) cells per dish), or medium conditioned by 1 to 3 days of in vitro incubation with the same cell line, doubled the CFE. The density of tumor cells (untreated or previously treated with chemotherapeutic agents) did not affect the CFE when a minimum of 10(4) total cells (tumor plus feeder) were plated. Therefore, in this system the optimal experimental conditions for evaluating chemotherapy and radiotherapy require incubation of disaggregated tumor cells for 12 days in medium containing 10% of fetal calf serum and enough feeder cells to provide a minimum of 10(4) cells per dish. The CFE for untreated tumors was 18 +/- 10% (+/-S.D.), demonstrating that there is significant biological variation. The assay appeared sensitive, with reproducible results, when applied to individual chemically treated tumors. An estimate of the percentage of clonogenic cells affected by in vivo chemotherapy may be obtained by comparing the CFE of cells from treated and untreated tumors. This assay can measure up to a 5 log(10) cell kill, and it should prove to be valuable in developing more effective regimens for the treatment of solid tumors in animals and man.     

Optical and scanning electron microscopy observation of the mucosa of human fetal tongue

The structural features of the human foetal tongue have been studied in foetuses from 8th to 20th week of pregnancy. The characteristics of the developing papillae as well as of epithelial and mesenchymal layers have been pointed out. An early differentiation of the mesenchymal tissue has been observed, concerning phenomena of cellular condensation and reticular fibers organization both in superficial and deep layers. The hypothesis of the existence of straight interactions between epithelium and mesenchyme also in the developing human tongue mucosa has been suggested. Also the observations at SEM demonstrate that from the 8th to the 20th week the epithelial surface of the tongue reaches a stable structural pattern. From 11th week a characteristic cellular polymorphism occurs: cells with microvilli that diminish progressively, ciliated cells that disappear almost completely at the 20th week and cells whose free surface show microplicae, definitive stage of the tongue cell evolution.