The presence of G1 and G2 populations in normal epithelium of rat urinary bladder

The cell population kinetics of transitional epithelium of the rat urinary bladder was analysed by (3H) thymidine autoradiography and pararosanilin Feulgen DNA cytofluorometry. By flash and 72 h continuous DNA labelling, the generative cells of the transitional epithelium were found to be well localized in the basal layer, and it was postulated that che cells produced by cell proliferation in the basal layer would migrate towards the surface, maintaining direct attachment to the basement membrane by anchorage of a cellular process. Analyses of normal and wounded transitional epithelium revealed that 58.8% of all basal cells are G0 cells in G1 phase (G1-population), and 59.0% of the remaining basal cells reside in prolonged (75.1-108.0 h) G2 phase, preserving the ability to divide (G2-population). The cell cycle time of the generative basal cells including the long G2 phase was calculated as 129.1-162 h. All the cells existing in upper layers were found to be also G0 cells in G1 phase, with the DNA amounts of 2C class. No polyploid cells could be detected except for 2C-2C binucleated cells in the superficial layer. The existence of a G2-population may serve for the urgent need of cell incrementation to repair cell loss as the cells in G2 phase can divide without the time-delay needed for DNA synthesis. The rat transitional epithelium, which is composed exclusively of proliferating and potentially proliferative cells, will have much greater capability to repair damage than stratified squamous epithelia.     

Flow cytometric DNA analysis of corneal epithelium

We have modified an existing technique in order to perform DNA analysis by flow cytometry (FCM) of corneal epithelium from the mouse, rat, chicken, rabbit, and human. This protocol permitted an investigation of human corneal scrapings from several categories: normal, aphakic bullous keratopathy (ABK), keratoconus (KC), Fuch's dystrophy, edema, epithelial dysplasia, and lipid degeneration. No abnormal characteristic cell-kinetic profile was detected when averaged DNA histograms were compared statistically between the normal and either ABK, KC, edema, or Fuch's dystrophy groups. Abnormal DNA histograms were recorded for cell samples that were taken 1) from three individuals who had epithelial dysplasia and 2) from one individual diagnosed with lipid degeneration. The former condition was characterized by histograms that had a subpopulation of cells with an aneuploid amount of DNA or had higher than normal percentages of cells in the S and G2 + M phases of the cell cycle. Corneal cells from the patient who had lipid degeneration had an abnormally high percentage of cells in the G2 + M phases of the cell cycle. The availability of accurate DNA flow cytometric analysis of corneal epithelium allows further studies on this issue from both experimental and clinical situations.     

DNA ploidy and proliferative activity of human pulmonary epithelium

DNA ploidy and distribution has been determined in normal and abnormal bronchial, bronchiolar and alveolar epithelium from 22 patients, aged between 0 and 85 years, 9 of whom had received chemotherapy for malignant disease. The DNA ploidy was diploid in all the specimens examined. The S + G2/M fraction was significantly greater in diseased than normal bronchial trees. In the bronchial epithelium, mean values ± the standard deviation (SD) were 5.5 + 2.2% vs 1.1±0.6%, in bronchiolar epithelium 4.6 ± 1.6% vs 1.0 ± 0.9% and in alveolar epithelium 4.6 ± 1.6% vs 0.8 ± 0.5%. The highest S + G2/M value of 8.9% was obtained from inflamed bronchial epithelium. Polyploid cells up to the octaploid range occurred infrequently but their incidence was slightly increased to between 0.16% and 0.9% in diseased lungs and in patients who had received chemotherapeutic drugs. It was concluded that (1) non-cancerous pulmonary epithelium is diploid, that (2) pulmonary epithelium shows steady-state renewal at all ages and polyploid cells are rare under normal conditions and that (3) the S + G2/M fraction increases up to approximately 10% in reactive proliferative states.     

DNA ploidy and proliferative activity of human pulmonary epithelium

DNA ploidy and distribution has been determined in normal and abnormal bronchial, bronchiolar and alveolar epithelium from 22 patients, aged between 0 and 85 years, 9 of whom had received chemotherapy for malignant disease. The DNA ploidy was diploid in all the specimens examined. The S + G2/M fraction was significantly greater in diseased than normal bronchial trees. In the bronchial epithelium, mean values +/- the standard deviation (SD) were 5.5 +/- 2.2% vs 1.1 +/- 0.6%, in bronchiolar epithelium 4.6 +/- 1.6% vs 1.0 +/- 0.9% and in alveolar epithelium 4.6 +/- 1.6% vs 0.8 +/- 0.5%. The highest S + G2/M value of 8.9% was obtained from inflamed bronchial epithelium. Polyploid cells up to the octaploid range occurred infrequently but their incidence was slightly increased to between 0.16% and 0.9% in diseased lungs and in patients who had received chemotherapeutic drugs. It was concluded that (1) non-cancerous drugs. It was concluded that (1) non-cancerous pulmonary epithelium is diploid, that (2) pulmonary epithelium shows steady-state renewal at all ages and polyploid cells are rare under normal conditions and that (3) the S + G2/M fraction increases up to approximately 10% in reactive proliferative states.     

Circadian variations in the DNA synthesis of the rat corneal epithelium. A study using double labelling with tritiated thymidine

A prominent circadian rhythm was found in the labelling indices (LI) of the peripheral rat corneal epithelium and of the adjacent conjunctival epithelium, while almost no diurnal variation was found in the central area. Application of a double labelling technique indicated that there are rhythmic pulses of high and low influx of cells into the S phase and similar pulses of efflux of cells from the S phase. Results of the study indicate that there are different cohorts of cycling cells all over the rat corneal epithelium. Cells belonging to a rapidly proliferating cohort are observed in the peripheral cornea. There is a gradual reduction in the fraction of labelled DNA-synthesizing cells towards the centre. The considerably lower fraction of cells taking up tritiated thymidine (3H)TdR in the central cornea may be due to a higher fraction of basal cells having reached higher levels of differentiation. This may result in a shift from the salvage to the de novo pathway. The slowly proliferating cohort seems to have a prolonged S phase duration and displays practically no diurnal variation in the LI. The DNA-synthesizing cells belonging to this latter cohort probably use the salvage pathway for DNA synthesis resulting in uptake of (3H)TdR all over the cornea. The LI is thus not a reliable indicator of cell proliferation in the corneal epithelium, due both to the heterogeneity of the cell proliferation, and in particular due to the lack of labelling of the centrally located DNA-synthesizing cells. To what extent these properties may also be present in other proliferating tissues with different levels of differentiations, may be questioned.     

DNA synthesis in Bloom's syndrome fibroblasts

The relationship between relative rates of DNA synthesis and DNA content in Bloom's syndrome fibroblasts (BS cells) was investigated by flow cytometry. The cells were pulse labelled with 5-bromo-2'-deoxyuridine (BrdU). The BrdU content and cellular DNA content of individual BS cells were simultaneously measured by flow cytometry in which the cells were double-stained by a FITC-conjugated anti BrdU monoclonal antibody (mAb) for the BrdU content (green) and by PI (propidium iodide) (red) for total DNA content. Their red fluorescence histograms were analysed by a microcomputer to evaluate the cell fractions of each S compartment. The BrdU uptake in the early S phase of BS cells was lower than that of normal cells (fibroblasts from skin of a normal human), whereas the uptake in the middle and late S phase was essentially the same as that of normal cells. The early S phase in BS cells accounted for over 50% of the S phase cells. These findings suggest that, in comparison with normal cells, the rate of DNA synthesis in the early S phase of BS cells is lower, but is identical to controls in the middle and late S phases.     

DNA synthesis in Bloom's syndrome fibroblasts

Abstract. The relationship between relative rates of DNA synthesis and DNA content in Bloom's syndrome fibroblasts (BS cells) was investigated by flow cytometry. The cells were pulse labelled with 5-bromo-2'-deoxyuridine (BrdU). The BrdU content and cellular DNA content of individual BS cells were simultaneously measured by flow cytometry in which the cells were double-stained by a FITC-conjugated anti BrdU monoclonal antibody (mAb) for the BrdU content (green) and by PI (propidium iodide) (red) for total DNA content. Their red fluorescence histograms were analysed by a microcomputer to evaluate the cell fractions of each S compartment. The BrdU uptake in the early S phase of BS cells was lower than that of normal cells (fibroblasts from skin of a normal human), whereas the uptake in the middle and late S phase was essentially the same as that of normal cells. The early S phase in BS cells accounted for over 50% of the S phase cells. These findings suggest that, in comparison with normal cells, the rate of DNA synthesis in the early S phase of BS cells is lower, but is identical to controls in the middle and late S phases.     

Cyclin gene expression and growth control in normal and neoplastic human breast epithelium

Recent advances in defining the molecular mechanisms of cell cycle control in eukaryotes provide a basis for beter understanding the hormonal control of cell proliferation in normal and neoplastic breast epithelium. It is now clear that a number of critical steps in cell cycle progression are controlled by families of serine/threonine kinases, the cdks. These kinases are activated by interactions with various cyclin gene products which form the regulatory subunits of the kinase complexes. Several families of cyclins control cell cycle progression in G₁ phase, cyclins C, D and E, or in S, G₂ and mitosis, cyclins A and B. Recent studies have defined the expression and regulation of cyclin genes in normal breast epithelial cells and in breast cancer cell lines. Following growth arrest of T-47D breast cancer cells by serum deprivation restimulation with insulin results in sequential induction of cyclin genes. Cyclin D1 mRNA increases within 1 h of mitogenic stimulation and is followed by increased expression of cyclins D3 and E in G₁ phase, cyclin A in late G₁/early S phase and cyclin B1 in G₂. Similar results were observed following epidermal growth factor stimulation of normal breast epithelial cells. Other hormones—oestrogens and progestins—and growth factors—insulin-like investigated for their effects on G₁ cyclin gene expression. In all cases there was an excellent correlation between the induction of cyclin D1 mRNA and subsequent entry into S phase. Furthermore, growth inhibition by antioestrogens and concurrent G₁ arrest were preceded by an acute decrease in cyclin D1 gene expression. These observations suggest a likely role for cyclin D1 in mediating many of the known hormonal effects on cell proliferation in breast epithelial cells.     

The labelling index is not always reliable. Discrepancies between the labelling index and the mitotic rate in the rat corneal epithelium after intraperitoneal and topical administration of tritiated thymidine and colcemid

Many cell kinetic studies are based on the assumption that tritiated thymidine injected into an animal is available for incorporation into DNA for only a short time, and that it labels all cells in the S phase. The present study indicates that this is not the fact for the rat corneal epithelium. The labelling index (LI) declines considerably from the limbal area to the central cornea, while the mitotic rate is almost constant all over the corneal epithelium. The LI should therefore not be used as the only criterion in the assessment of proliferation rate.     

Ciliated cells in vitamin A-deprived cultured hamster tracheal epithelium do divide

Summary The pseudostratified tracheal epithelium, composed of a heterogeneous phenotypically varying cell population, was studied with respect to the in vitro cell proliferative activity of differentiated epithelial cells. Ciliated tracheal epithelial cells so far have been considered to be terminally differentiated, nonproliferating cells. Tracheal organ cultures obtained from vitamin A-deprived Syrian Golden hamsters were cultured in a vitamin A-deficient, serum-free, hormone-supplemented medium. In vitamin A-deprived tracheal epithelium treated with physiologically active all-trans retinol and low cigarette-smoke condensate concentrations it is possible to stimulate the cell proliferation of both basal and columnar cells. Therefore, the probability of finding proliferating columnar cells was increased compared with the in vivo and the vitamin A-deprived situation in which cell proliferative activity is relatively low. In the presence of cigarette-smoke condensate in a noncytotoxic concentration, basal, small mucous granule, ciliated, and indifferent tracheal epithelial cells incorporated [methyl-³H]-thymidine into the DNA during the S phase. The finding that ciliated cells were labeled was supported by serial sections showing the same labeled ciliated cell in two section planes separated by 2 to 3 μm, without labeled epithelial cells next to the ciliated cell. Furthermore, a ciliated tracheal epithelial cell incorporating [methyl-³H]thymidine into DNA was also seen in tracheal cultures of vitamin A-deprived hamsters treated with all-trans retinol in a physiologic concentration. The present study was financially supported by the Scientific Advisory Committee on Smoking and Health (Dutch Cigarette Industry Foundation) and the Ministry of Welfare, Health and Cutural Affairs.     

Lectin binding to cell surfaces: comparisons between normal and migrating corneal epithelium

Comparisons were made between cell surfaces of normal and migrating corneal epithelium of the rat by localizing and/or quantifying concanavalin A (Con A) and wheat germ agglutinin (WGA) binding. Our results indicate that apical cell surfaces of the leading edge of a migrating sheet of epithelium differ from those of normal epithelium and that the various cell layers within the stratified normal epithelium have different lectin-binding characteristics. Three methods of monitoring lectin binding to cell surfaces were employed. Based on ferritin-conjugated Con A, ferritin-conjugated WGA, and [3H]Con A binding, apical cell membranes of migrating epithelia bind more Con A and WGA than do apical membranes of superficial cells of normal stratified epithelia. With both fluorescein isothiocyanate (FITC)-Con A and -WGA, membranes of all the cells of the leading edge of the migrating sheet fluoresce intensely. FITC-Con A binding of normal stratified epithelium is relatively uniform through all cell layers with no discernible staining of the apical membrane of superficial cells. With FITC-WGA, however, fluorescence is present only on basal cell layers but not on superficial cells. These data demonstrate that apical cell surface sugars on a sheet of epithelium migrating to cover a wound differ from the apical cell surface sugars of normal epithelium. As indicated by FITC-WGA binding, cells of the migrating sheet have cell surface characteristics similar to basal cells of normal epithelia. Perhaps, upon wounding, the leading edge of the migrating sheet is derived from the basal cell population of the normal stratified epithelium, or perhaps there is an alteration in cell surface glycoproteins as the cells become migratory.     

Circadian variation in cell proliferation and maturation. A hypothesis for the growth regulation of the rat corneal epithelium.

The rat corneal epithelium has been chosen as a model for studying growth regulation. In this epithelium a large single cohort of cells enters the S phase during a fairly short time period once a day. The factor responsible for this wave of cell proliferation is unknown, but it may be a chemical signal from the central nervous system (the suprachiasmatic nucleus or the corpus pineale). The mature cell compartment of the corneal epithelium is assumed to produce a negative feedback factor (chalone), counteracting the effect of the circadian proliferative factor on the local cell proliferation. When no circadian factor is being produced, during most of the 24 h, the chalone seems to enhance the maturation process. During diminished chalone production (e.g. after cell injury and subsequent regeneration), we will get a more or less unrestricted cell proliferation in the tissue with a delayed maturation process prolonging the chalone depletion. This interaction between the circadian proliferative factor and the negative feedback factor for regulation of proliferation with its accompanying stimulatory effect on maturation, may represent a general mechanism in the regulation of cell proliferation in any tissue. Since in at least some organs virtually all cells entering the S phase do this as a single wave once a day, this mechanism may be enough to explain the regulation of cell proliferation during both normal and regenerative conditions.     

Expression of retinoblastoma gene product in respiratory epithelium and sinonasal neoplasms: relationship with p16 and cyclin D1 expression

Transition from G1 to S phase of the cell cycle is mediated by interactions between the Retinoblastoma gene product (pRb), p16, and cyclin D1. To determine the expression of these proteins in the sinonasal mucosa immunohistochemistry was carried out on archived tissue sections from 46 patients (37 men, 9 women, age range 17 to 82 years, median 55 years). Nuclear immunostaining for these proteins was assessed and the expression rates (percentages of immunoreactive nuclei) in normal respiratory epithelium, inverted sinonasal papillomas, cylindrical (oncocytic) sinonasal papillomas, and squamous cell carcinomas were compared. Normal respiratory epithelium showed significantly higher pRb expression in surface cells compared to basal cells (p < 0.05). In contrast, abundant pRb expression in surface and basal cells was detected in columnar differentiation in sinonasal papillomas and adjacent mucosa. Cuboidal and squamous metaplasia in inverted papillomas showed significantly reduced pRb expression in surface cells compared to columnar epithelium in inverted papillomas (p < 0.05, respectively). Expression of p16 was detected in all epithelial cell layers of normal respiratory epithelium, sinonasal papillomas, and adjacent mucosa. Cuboidal and squamous metaplasia in inverted papillomas showed increased p16 expression in surface cells compared to columnar epithelium in inverted papillomas (p < 0.05 between squamous metaplasia and columnar epithelium). Sinonasal squamous cell carcinomas showed the coexpression of pRb and p16. Expression rates of cyclin D1 higher than 10% were detected only in invasive carcinomas but not in carcinoma in situ, sinonasal papillomas or respiratory epithelium. Conclusively, pRb expression accompanies terminal differentiation in columnar surface cells. Expression of pRb in proliferating basal cells is present in sinonasal papillomas and adjacent mucosa but not in normal respiratory epithelium. Cuboidal and squamous metaplasia in inverted papillomas involves downregulation of pRb expression along with increased p16 expression in surface cells. Sinonasal squamous cell carcinomas coexpress pRb and p16. Overexpression of cyclin D1 in sinonasal lesions is confined to invasive squamous cell carcinomas.     

Over-replication of DNA in S phase Chinese hamster ovary cells after DNA synthesis inhibition

Agents that inhibit DNA synthesis increase the frequency of methotrexate resistance and gene amplification in cultured mammalian cells. Chinese hamster ovary cells blocked with hydroxyurea rereplicated dihydrofolate reductase gene sequences within a single cell cycle upon release from the block (Mariani, B.D., and Schimke, R.T. (1984) J. Biol. Chem. 259, 1901-1910). Perturbation of DNA synthesis was postulated to result in misfiring of replicon initiation, subsequent over-replication of DNA sequences, and amplification of specific genes. To test this hypothesis, we have exposed Chinese hamster ovary cells pulsed with bromodeoxyuridine to three agents that inhibit DNA synthesis and enhance gene amplification: UV irradiation, hydroxyurea, and aphidicolin. After release from the block, the progression of cells throughout the cell cycle was analyzed by flow cytometry through simultaneous measurement of total cellular DNA content and bromodeoxyuridine-labeled DNA. Although the cell cycle effects varied depending on the agent used for the block, in all cases a subset of cells that were in S phase at the time of the block exhibited DNA histograms with greater than 4C DNA content at various times after release and prior to cell division. Cells with the excess DNA were approximately 10-fold more resistant to methotrexate compared to treated cells with normal DNA content or untreated cells. Therefore, cells in S phase at the time of the block produce excess DNA per cell prior to division, and this over-replicated DNA may be relevant to gene amplification and drug resistance.     

Circadian variations in influx and efflux of the S phase in a partially synchronized cell system Double-labelling with [3H]thymidine in the epithelium of the hamster cheek pouch

Abstract. By means of a double-labelling experiment, circadian variations in the kinetic parameters of the S phase of the hamster cheek pouch epithelium were studied. The evaluation of the experiment included a recently developed correction for deviations from the strict pulse interpretation of the labelling technique.
Pronounced circadian variations were found in S phase influx and efflux; the diurnal mean of both was estimated as 0.5%/hr, when based on measurements of all nucleated epithelial cells. Variations in S phase influx seem mainly responsuble for the diurnal variation in cell proliferation, although diurnal variation in DNA synthesis rate, and thus in mean transit time, was also found. The increases in LI and influx were closely correlated and related to the beginning of the dark period.
A circadian variation in cell number was also observed.     

Circadian-stage dependence of methotrexate in a keratinized epithelium. An in-vivo study using flow cytometry on the hamster cheek pouch epithelium

The partially synchronized cell system of the hamster cheek pouch epithelium shows a characteristic diurnal rhythm of cell proliferation. Bolus injections of methotrexate (Mtx) in both lethal (10 g/m2) and non-lethal (2 g/m2) doses were found to inhibit cell-cycle progression primarily by impairing the G1/S transition. The results were obtained by flow cytometric DNA analysis. The inhibitory effect of Mtx manifested itself as a relative decrease of the S fraction (drug-effector phase), and was found to be dependent both on the dose and on the time of the day it was given. A bolus injection of Mtx was given either at 1200 hr (when a minimal number of cells are in S phase) or at 0200 hr (when a maximum number of cells are in S phase). The greatest cumulative decrease in S fraction was seen when the injection was given at 1200 hr. The time between injection and the effect (seen as a decrease in S fraction) was independent of the time of the Mtx injection, but seemed instead to be related to the natural diurnal period of increasing flux from G1 to S phase (at the onset of the dark period). The main effect (the relative decrease in S fraction) was repeated during the following 24-hr period, pointing to a protracted effect of Mtx on G1 cells. G1 cells affected by the initial high Mtx plasma concentration seem to be responsible for the reduced influx into S phase in both the first and second 24-hr period. In earlier toxicological studies, the survival rate of hamsters was dependent on the time of injection and was highest after injection at 1200 hr. Thus maximum cytokinetic effect on epithelial cells was found at the time of the day when there was a minimum lethal effect on the animal.     

Estrogen-independent growth of mouse vaginal epithelium in organ culture.

A serum-free vaginal explant culture system was established to investigate the in vitro effect of estrogen on the growth of mouse vaginal epithelium. Vaginal explants were isolated from 40-day-old, ovariectomized BALB/cCrgl mice and cultured in a basal unsupplemented medium or in basal medium plus various doses of 17 beta-estradiol. Explants were processed for histology at the end of culture periods or were given 4-hour pulses of tritiated thymidine at various times and processed for autoradiography. Vaginal epithelium increased 3- to 5-fold in thickness and 2-fold in the number of epithelial cell layers during 72 hours of culture without estrogen; addition of estrogen did not significantly influence epithelial growth. Keratinization of vaginal epithelium occurred within 48 hours of culture in the absence of estrogen, and again addition of estrogen did not accelerate its appearance. Covering the explants with collagen decreased the estrogen-independent growth of vaginal epithelium. Autoradiography showed that ca. 70-90% of basal epithelial cells entered S phase during the initial 4 hours of culture and that this number declined rapidly after 48 hours to ca. 20%. Addition of 1.8 nM 17 beta-estradiol significantly decreased the labelling index of basal cells at 48 hours, but did not affect the labelling index at 24 and 72 hours. Stromal cells were not labelled at any time. Thus, DNA synthesis, cellular proliferation, and differentiation (keratinization) of vaginal epithelium in organ culture occurred without estrogen and were not stimulated by the addition of estrogen.     

Multipotential stem cells in adult mouse gastric epithelium

Previous studies of chimeric animals demonstrate that multipotential stem cells play a role in the development of the gastric epithelium; however, despite much effort, it is not clear whether they persist into adulthood. Here, chemical mutagenesis was used to label random epithelial cells by loss of transgene function in adult hemizygous ROSA26 mice, a mouse strain expressing the transgene lacZ in all tissues. Many clones derived from such cells contained all the major epithelial cell types, thereby demonstrating existence of functional multipotential stem cells in adult mouse gastric epithelium. We also observed clones containing only a single mature cell type, indicating the presence of long-lived committed progenitors in the gastric epithelium. Similar results were obtained in duodenum and colon, showing that this mouse model is suitable for lineage tracing in all regions of the gastrointestinal tract and likely useful for cell lineage studies in other adult renewing tissues.     

Cell cycle synchrony in the developing chicken lens epithelium.

Synchronous oscillations of DNA synthesis and histone 2B mRNA expression occur during normal development of 13- to 16-day-old embryonic chicken lens epithelium. At least four cycles were observed with peak values of DNA synthesis and histone 2B mRNA 5 to 10 times greater than baseline values. Fourier analysis of DNA synthesis identified a statistically significant oscillatory period of 18 hr, the approximate length of the cell cycle at this age. Minor components of 7-9 and 12 hr were also identified in the data sets. Lenses labeled with 3H-thymidine and analyzed by autoradiography at 13.8 days of embryogenesis revealed more than twice the number of labeled nuclei at this time than in lenses labeled 9 hr later; histone 2B mRNA followed this same pattern. These findings demonstrate that a significant population of cells is synchronized with respect to the cell cycle in the developing lens epithelium in ovo. The temporal pattern of mitosis may be the basis of the fiber cell architecture and consequent lens transparency.     

Sertoli cell ectoplasmic specializations in the seminiferous epithelium of the testosterone-suppressed adult rat

The Sertoli cell ectoplasmic specialization is a unique junctional structure involved in the interaction between elongating spermatids and Sertoli cells. We have previously shown that suppression of testicular testosterone in adult rats by low-dose testosterone and estradiol (TE) treatment causes the premature detachment of step 8 round spermatids from the Sertoli cell. Because these detaching round spermatids would normally associate with the Sertoli cell via the ectoplasmic specialization, we hypothesized that ectoplasmic specializations would be absent in the seminiferous epithelium of TE-treated rats, and the lack of this junction would cause round spermatids to detach. In this study, we investigated Sertoli cell ectoplasmic specializations in normal and TE-treated rat testis using electron microscopy and localization of known ectoplasmic specialization-associated proteins (espin, actin, and vinculin) by immunocytochemistry and confocal microscopy. In TE-treated rats where round spermatid detachment was occurring, ectoplasmic specializations of normal morphology were observed opposite the remaining step 8 spermatids in the epithelium and, importantly, in the adluminal Sertoli cell cytoplasm during and after round spermatid detachment. When higher doses of testosterone were administered to promote the reattachment of all step 8 round spermatids, newly elongating spermatids associated with ectoplasmic specialization proteins within 2 days. We concluded that the Sertoli cell ectoplasmic specialization structure is qualitatively normal in TE-treated rats, and thus the absence of this structure is unlikely to be the cause of round spermatid detachment. We suggest that defects in adhesion molecules between round spermatids and Sertoli cells are likely to be involved in the testosterone-dependent detachment of round spermatids from the seminiferous epithelium.