INNER ENAMEL EPITHELIUM CELL PRODUCTION RATES

Crowning of all four rat incisors slows down their eruption rate, leading to a diminution of cell production by the inner enamel epithelium (IEE). The production rate by 100 progenitor cells is dominated as production rate %. The normal IEE in rats weighing 200 g produces daily 67 cells %. In the crowned incisor this rate drops to 15 cells % while during accelerated eruption the IEE produces daily 152 cells %. In all three conditions the ratio between eruption rate and IEE cell production rate remains unchanged and an eruption of 6.4 μm reflects a production of 1 cell % by the IEE. A method which relates labelled cell displacement along the IEE with its cell production rate is described and its applicability to other cell renewal systems discussed.     

On the progenitor cell migration velocity

An attempt is presented to extract cell kinetic information from histomorphological features. It is applicable to rapidly proliferating tissues like the intestinal epithelium. Each replicating tissue has an origin where cells are formed and a periphery toward which cells migrate. The migration path along which they move is denominated as tissue radius on which all cell positions are mapped. Cell migration on the radius is associated with cell proliferation at tissue origin. Each mitosis there is associated with the displacement of all cells distal to it by one cell position. The more mitoses positioned between a cell and tissue origin, the greater its migration velocity. It is possible therefore to derive the cell migration velocity v(x) from the cumulative mitotic distribution on the radius, N(x). v(x) = N(x)/tm (tm = mitotic time). In this form v(x) represents also cell production at any point on the radius and may serve for the computation of other cell kinetic parameters like generation time. These arguments are illustrated on the rat incisor tooth inner enamel epithelium which has been studied in the normal and rapidly erupting tooth.     

Inner enamel epithelia synthesize and secrete enamel proteins during mouse molar occlusal "enamel-free area" development

Mesenchyme-derived instructions for odontogenic epithelial differentiation into ameloblasts and the production of enamel matrix has been well established. However, it is not known how position-specific differences within the enamel organ of rodent molar tooth organs regulate the enamel-forming vs. the enamel free areas in the developing cusp. Light microscopy, transmission electron microscopy, and immunocytochemistry using a rabbit anti-mouse amelogenin antibody, were used to map the position-specific patterns within the enamel organ. In the enamel-forming area, ameloblasts were associated with stratum intermedium. In the enamel-free area, another cell type was interposed between inner enamel epithelia (IEE) and stratum intermedium. IEE in the enamel-free area did not have Tomes' processes and secreted enamel matrix not only toward dentin but also between IEE cells. IEE became confluent with stellate reticulum; at this position stratum intermedium cells were no longer detected. The thickness and orientation of dentin matrix collagen fibers in the enamel-free area were different from the fibers in the enamel-forming area. These results suggest that the patterns of epithelial cell-cell and cell-matrix associations during position-specific enamel organ epithelial differentiation may regulate ameloblast matrix synthesis and/or the matrix secretion pathway.     

Stratum intermedium lineage diverges from ameloblast lineage via Notch signaling

The stratum intermedium develops as flattened cell layers on the proximal side of the ameloblast layer during tooth development. However, little information is available regarding the origin and the role. In this study, we indicate that some stratum intermedium cells originate from the inner enamel epithelium (IEE) in rat incisor organ cultures using DiI as a tracer. Immunohistochemical and in situ hybridization studies showed that the stratum intermedium cells express the Notch1 protein and Hes1 mRNAs, while the IEE and ameloblasts express the Jagged1. Further, we examined the role of Notch signaling using the dental epithelial cell line HAT-7. Recombinant Jagged1 protein enhanced the appearance of stratum intermedium cells in HAT-7 cultures and neutralization with an anti-Jagged1 antibody inhibited these effects. Additionally, overexpression of the Notch1 internal domain increased the number of stratum intermedium cells. We hypothesize that the stratum intermedium lineage differentiates from the ameloblast lineage via Notch signaling.     

Proliferative and functional stages of rat ameloblast differentiation as revealed by combined immunocytochemistry against enamel matrix proteins and bromodeoxyuridine

Summary A double-staining immunocytochemical technique was used for the simultaneous detection, at the light- and electron-microscopical level, of proliferating bromodeoxyuridine (BrdU)-labelled cells and enamel protein (EP)-producing cells in the inner enamel epithelium (IEE) of rat tooth germ. BrdU-positive cells were found in the region of the IEE close to the cervical loop and never displayed EP-like immunoreactivity. BrdU-immunoreactivity was confined to the nucleus of replicating cells. In contrast, epithelial cells displaying EP-like immunoreactivity were found in the region of the forming dental cusp and were consistently BrdU-negative. EP-like immunoreactivity was detectable in the cytoplasmic compartments involved in the exocrine secretion pathway and in the extra-cellular matrix close to EP-immunoreactive cells. These data support the view that withdrawal from the cell cycle in the IEE is a temporal prerequisite for acquiring the functional competence of secreting EP. Moreover, cycling cells and secretory cells in the IEE constitute two separate compartments that are spatially defined, and that exhibit clear-cut staining patterns with respect to BrdU- and EP-immunoreactivity, respectively. We thus propose that BrdU-incorporation and EP-production may be used as specific markers of the differentiation of the IIE cells in studies of the possible role of growth factors, their receptors and oncoproteins in this tissue.     

ON THE PROGENITOR CELL MIGRATION VELOCITY

An attempt is presented to extract cell kinetic information from histomorphological features. It is applicable to rapidly proliferating tissues like the intestinal epithelium. Each replicating tissue has an origin where cells are formed and a periphery toward which cells migrate. The migration path along which they move is denominated as tissue radius on which all cell positions are mapped. Cell migration on the radius is associated with cell proliferation at tissue origin. Each mitosis there is associated with the displacement of all cells distal to it by one cell position. The more mitoses positioned between a cell and tissue origin, the greater its migration velocity. It is possible therefore to derive the cell migration velocity v(x) from the cumulative mitotic distribution on the radius, N(x). v(x) = N(x)/t_m (t_m= mitotic time). In this form v(x) represents also cell production at any point on the radius and may serve for the computation of other cell kinetic parameters like generation time. These arguments are illustrated on the rat incisor tooth inner enamel epithelium which has been studied in the normal and rapidly erupting tooth.     

KINETICS OF THE INNER ENAMEL EPITHELIUM IN THE ADULT RAT INCISOR DURING ACCELERATED ERUPTION

Inner enamel epithelial (IEE) cell production was compared in accelerated and normal eruption (control). Each group consisting of thirty rats received 1 μCi/g tritiated thymidine. The animals were sacrificed at short time intervals up to 14 hr after injection. The excised incisors were cut mid-sagittally and processed autoradiographically.
The fast growing incisor produces twice as many cells as the control. Increased cell production is achieved in two ways: proliferative pool expansion (by 25.5%) and generation time ( t _c) shortening to 16 hr ( t _c= 23 hr in the control). Generation time shortening resulted mainly from a diminution in t _g1= 8.6 hr ( t _g1= 14.1 hr in the control) and t _s which equaled 5.5 hr ( t _s= 7 hr in control). Mitotic times which equaled 0.4 hr and t _g2, 1.5 hr were identical in both groups.
The eruption/IEE cell production ratio equals 1.1 in both groups.     

Ultrastructural studies of midgut epithelium formation in Lepisma saccharina L. (Insecta, Zygentoma)

At the end of embryogenesis of Lepisma saccharina L. (Insecta, Zygentoma), when the stomodaeum and proctodaeum are completely formed, the midgut epithelium is replaced by the primary midgut, a yolk mass is surrounded by a cell membrane. Midgut epithelium formation begins in the 1st larval stage. Energids migrate toward the yolk periphery and aggregate just beneath the cell membrane. They are gradually enclosed by cell membrane folds of the primary midgut. Single cells are formed. Succeeding energids join just formed cells. Thus, groups of cells, regenerative cell groups, are formed. Their number gradually increases. The external cells of the regenerative cell groups transform into epithelial cells and their basal regions spread toward the next regenerative cell groups. Epithelial cells of neighboring regenerative cell groups join each other to form the epithelium. At the end of the 2nd larval stage, just before molting, degeneration of newly the formed epithelium begins. Remains of organelles and basal membrane occur between the regenerative cell groups. The new epithelium is formed from the regenerative cell groups, which are now termed stem cells of the midgut epithelium.     

细胞衰老和凋亡相关蛋白表达在宫颈鳞癌变中的意义

目的：许多细胞周期调控因子和衰老相关标志物如p14ARF、p15INK4b、p16INK4a 和p53 在G1 细胞周期阻滞和癌基因诱导的衰老中意义重大。这些关键的调节蛋白在多种恶性肿瘤中经常发生突变或是缺失。在本研究中将探讨这些因子在宫颈癌发生中的意义。方法：在本研究中在正常宫颈上皮、宫颈上皮内瘤变和宫颈鳞癌中,应用免疫组织化学方法检测p14ARF、p15INK4b、p16INK4a、Bcl-2、p53 表达,并分析它们的表达与宫颈癌变的相关性。结果：p16INK4a 在正常宫颈鳞状上皮10%（2/20）表达阴性,在大部分CIN 和宫颈鳞癌中表达阳性,其中在85%（17/20）CIN 和75%（15/20）鳞癌中呈弥漫性强阳性表达,CIN 和宫颈鳞癌中的阳性表达率显著高于正常上皮（P〈0.01）,CIN 和宫颈鳞癌的间表达率无显著差异。p15INK4b 在正常宫颈鳞状上皮中65%（13/20）表达弱阳性,在100% （20/20）CIN 和95%（19/20）宫颈鳞癌中表达弥漫性阳性,各组之间阳性表达率无显著性差异（P〉0.05）。p14ARF在40%（8/20）正常宫颈上皮细胞中表达呈弱阳性（1＋）,在宫颈鳞癌中表达呈弥漫性强阳性90%（18/20）,在45%（9/20）CIN中表达阳性,各组之间阳性表达率无显著性差异（P〉0.05）。Bcl-2 在20%（4/20）正常宫颈上皮表达呈弱阳性,在18/20CIN中其表达强度和比率均增加,阳性表达率为90%（18/20）,Bcl-2 在鳞癌中700%（14/20）呈强阳性和弥漫阳性,CIN 和宫颈鳞癌中的阳性表达率显著高于正常上皮（P〈0.01）,CIN 和宫颈鳞癌的间表达率无显著差异。P53 免疫组化染色显示在正常宫颈上皮为表达为20%（4/20）,在大多数CIN25%（5/20）和鳞癌中核阳性85%（17/20）,在鳞癌中的阳性表达率显著高于正常宫颈上皮和CIN 病变（P〈0.05）。结论：宫颈鳞癌变涉及包括细胞凋亡和细胞衰老在内的多种信号分子表达异常,这些分子可能在宫颈鳞癌发生发挥重要作用并在宫颈癌早期诊断中有重要意义。     

A new method for the estimation of cell cycle phases.

A method is described, which is applicable to cell renewal systems with an anatomical structure in which all cell locations may be uniquely mapped. Its use is demonstrated on the rat incisor inner enamel epithelium, which forms a one cell thick column in the sagittally sectioned tooth. Cells born in the apical part of the column migrate toward the distal end of the tooth, where they mature. As the cells migrate along the column, they traverse the various cell cycle phases. The present study has been designed to estimate the probability of a cell being in a given phase; all cells touching the basement membrane were numbered, and the number of cells separating any two cells was taken as a measure of distance. Since generally all cells move in one direction (lateral cell migration may occur), it is possible to solve the problem with the aid of functions describing the renewal counting stochastic process in which cell distance serves as an independent variable. The method predicts labelled cell and mitotic rates which agree with those estimated in the usual way. It was then utilized to estimate the fraction of cells in G2.     

Maintenance of Functional Stem Cells in Isolated and Cultured Adult Intestinal Epithelium

We have previously described a method for the primary culture of adult large intestinal epithelium, suggesting that stem cells had survived both the isolation and the culture procedures. However, as no markers for such cells exist, confirmation of stem cell survival is difficult-only the functional properties can be used to define them. Unfortunately, many of these (e.g., differentiation, crypt regeneration) do not occur in culture, probably due to suboptimal conditions. To address this problem both freshly isolated and cultured small and large intestinal crypts were grown subcutaneously in an immunocompromized mouse. All initially formed cysts lined by a simple epithelium which gradually became multicellular and formed invaginations containing many mitoses and apoptoses. Epithelial differentiation, as assayed by Goblet cell mucin production, was also apparent. Mucin maturation was also typical of the normal intestine. The lumen was frequently filled with mucin and apoptotic bodies. Interestingly, in grafts displaying pronounced crypt-like morphology the regions of proliferation were situated toward the base of the structure and the Goblet cells toward the lumen, i.e., a typical crypt-like morphology. Hence, functional adult stem cells appear to survive isolation and tissue culture, permitting organotypic regeneration, possibly involving homeobox gene expression. This may now allow direct stem cell characterization and experimental manipulation, such as transfection, and may ultimately permit transplantation and therapeutic gene therapy.     

Neurogenesis in the vomeronasal epithelium of adult garter snakes: 3. Use of H3-thymidine autoradiography to trace the genesis and migration of bipolar neurons

Use of H3-thymidine autoradiography and unilateral vomeronasal (VN) axotomy has permitted us to demonstrate directly the existence of VN stem cells in the adult garter snake and to trace continuous bipolar neuron development and migration in the normal VN and deafferentated VN epithelium in the same animal. The vomeronasal epithelium and olfactory epithelium of adult garter snakes are both capable of incorporating H3-thymidine. In the sensory epithelium of the vomeronasal organ, H3-thymidine-labeled cells were initially restricted to the base of the undifferentiated cell layer in animals surviving 1 day following H3-thymidine injection. With increasing survival time, labeled cells progressively migrated vertically within the receptor cell column toward the apex of the bipolar neuron layer. In both the normal and denervated VN epithelium, labeled cells were observed through the 56 days of postoperative survival. In the normal epithelium, labeled cells were always located within the matrix of the intact receptor cell columns. However, labeled cells of the denervated epithelium were always located at the apical front of the newly formed cell mass following depletion of the original neuronal cell population. In addition, at postoperative days 28 and 56, labeled cells of the denervated VN epithelium achieved neuronal differentiation and maturation by migrating much farther away from the base of the receptor cell column than the labeled cells on the normal, unoperated contralateral side. This study directly demonstrates that basal cells initially incorporating H3-thymidine are indeed stem cells of the VN epithelium in adult garter snakes.(ABSTRACT TRUNCATED AT 250 WORDS)     

The Distribution of BrdU- and TUNEL-positive Cells During Odontogenesis in Mouse Lower First Molars

This study investigated the minute distribution of both proliferating and non-proliferating cells, and cell death in the developing mouse lower first molars using 5-bromo-2-deoxyuridine (BrdU) incorporation and the terminal deoxynucleotidyl transferase-mediated deoxyuridine-5-triphosphate (dUTP)-biotin nick end labeling (TUNEL) double-staining technique. The distribution pattern of the TUNEL-positive cells was more notable than that of the BrdU-positive cells. TUNEL-positive cells were localized in the following six sites: (1) in the most superficial layer of the dental epithelium during the initiation stage, (2) in the dental lamina throughout the period during which tooth germs grow after bud formation, (3) in the dental epithelium in the most anterior part of the antero-posterior axis of the tooth germ after bud formation, (4) in the primary enamel knot from the late bud stage to the late cap stage, (5) in the secondary enamel knots from the late cap stage to the late bell stage, and (6) in the stellate reticulum around the tips of the prospective cusps after the early bell stage. These peculiar distributions of TUNEL-positive cells seemed to have some effect on either the determination of the exact position of the tooth germ in the mandible or on the complicated morphogenesis of the cusps. The distribution of BrdU-negative cells was closely associated with TUNEL-positive cells, which thus suggested cell arrest and the cell death to be essential for the tooth morphogenesis.     

A NEW METHOD FOR THE ESTIMATION OF CELL CYCLE PHASES

A method is described, which is applicable to cell renewal systems with an anatomical structure in which all cell locations may be uniquely mapped. Its use is demonstrated on the rat incisor inner enamel epithelium, which forms a one cell thick column in the sagittally sectioned tooth. Cells born in the apical part of the column migrate toward the distal end of the tooth, where they mature. As the cells migrate along the column, they traverse the various cell cycle phases. The present study has been designed to estimate the probability of a cell being in a given phase; all cells touching the basement membrane were numbered, and the number of cells separating any two cells was taken as a measure of distance. Since generally all cells move in one direction (lateral cell migration may occur), it is possible to solve the problem with the aid of functions describing the renewal counting stochastic process in which cell distance serves as an independent variable. The method predicts labelled cell and mitotic rates which agree with those estimated in the usual way. It was then utilized to estimate the fraction of cells in G₂.     

Localization of type IV collagen a 1 to a 6 chains in basement membrane during mouse molar germ development.

The dental basement membrane (BM) putatively mediates epithelial-mesenchymal interactions during tooth morphogenesis and cytodifferentiation. Type IV collagen alpha chains, a major network-forming protein of the dental BM, was studied and results disclosed distinct expression patterns at different stages of mouse molar germ development. At the dental placode and bud stage, the BM of the oral epithelium expressed alpha 1, alpha 2, alpha 5 and alpha 6 chains while the gubernaculum dentis, in addition to the above four chains, also expressed a 4 chain. An asymmetrical expression for alpha 4, alpha 5 and alpha 6 chains was observed at the bud stage. At the early bell stage, the BM associated with the inner enamel epithelium (IEE) of molar germ expressed alpha 1, alpha 2 and alpha 4 chains while the BM of the outer enamel epithelium (OEE) expressed only alpha 1 and a 2 chains. With the onset of dentinogenesis, the collagen a chain profile of the IEE BM gradually disappeared. Howeverfrom the early to late bell stage, the gubernaculum dentis consistently expressed alpha 1, alpha 2, alpha 5 and a 6 chains resembling fetal oral mucosa. These findings suggest that stage- and position-specific distribution of type IV collagen alpha subunits occur during molar germ development and that these changes are essential for molar morphogenesis and cytodifferentiation.     

Fate of the Molar Dental Lamina in the Monophyodont Mouse

The successional dental lamina (SDL) plays an essential role in the development of replacement teeth in diphyodont and polyphyodont animals. A morphologically similar structure, the rudimental successional dental lamina (RSDL), has been described in monophyodont (only one tooth generation) lizards on the lingual side of the developing functional tooth. This rudimentary lamina regresses, which has been proposed to play a role in preventing the formation of future generations of teeth. A similar rudimentary lingual structure has been reported associated with the first molar in the monophyodont mouse, and we show that this structure is common to all murine molars. Intriguingly, a lingual lamina is also observed on the non-replacing molars of other diphyodont mammals (pig and hedgehog), initially appearing very similar to the successional dental lamina on the replacing teeth. We have analyzed the morphological as well as ultrastructural changes that occur during the development and loss of this molar lamina in the mouse, from its initiation at late embryonic stages to its disappearance at postnatal stages. We show that loss appears to be driven by a reduction in cell proliferation, down-regulation of the progenitor marker Sox2, with only a small number of cells undergoing programmed cell death. The lingual lamina was associated with the dental stalk, a short epithelial connection between the tooth germ and the oral epithelium. The dental stalk remained in contact with the oral epithelium throughout tooth development up to eruption when connective tissue and numerous capillaries progressively invaded the dental stalk. The buccal side of the dental stalk underwent keratinisation and became part of the gingival epithelium, while most of the lingual cells underwent programmed cell death and the tissue directly above the erupting tooth was shed into the oral cavity.     

Epithelial ultrastructure and the distribution of an estradiol sensitive antigen in the vagina of adult mice

Summary The distribution of an antigenic material specific for the cervicovaginal epithelium (CVA) was studied in the vaginal epithelium of the adult mouse with immunofluorescence and immunoferritin techniques. The antigen localization has been correlated to the fine structure of the vaginal epithelium in various states of functional activity. The antigen distribution in adult ovariectomized mice and in ovariectomized mice treated with estradiol was compared with that in normal cycling mice. CVA was found to be associated with the exterior of the cell membrane of vaginal epithelium cells, being part of the glycocalyx.Two cell types, mucous or keratinized, are derived from the germinative cell layer of the vaginal epithelium, depending on the hormonal environment. Mucous cells with morphological features that characterize cells about to cornify have been demonstrated. Fluorescence as well as ferritin particles, indicating the presence of antigen-antibody complexes, were seen within the mucous droplets of the mucous cells. The CVA production is apparently connected with vaginal mucus formation. The CVA distribution in the adult vaginal epithelium is discussed in relation to the distribution demonstrated earlier in the cervicovaginal epithelium of neonatal mice.This investigation was supported by grants from the Norwegian Cancer Society (Landsforeningen mot Kreft) and the Norwegian Research Council.     

Gene deployment for tooth replacement in the rainbow trout (Oncorhynchus mykiss): a developmental model for evolution of the osteichthyan dentition

Repeated tooth initiation occurs often in nonmammalian vertebrates (polyphyodontism), recurrently linked with tooth shedding and in a definite order of succession. Regulation of this process has not been genetically defined and it is unclear if the mechanisms for constant generation of replacement teeth (secondary dentition) are similar to those used to generate the primary dentition. We have therefore examined the expression pattern of a sub-set of genes, implicated in tooth initiation in mouse, in relation to replacement tooth production in an osteichthyan fish (Oncorhynchus mykiss). Two epithelial genes pitx2, shh and one mesenchymal bmp4 were analyzed at selected stages of development for O. mykiss. pitx2 expression is upregulated in the basal outer dental epithelium (ODE) of the predecessor tooth and before cell enlargement, on the postero-lingual side only. This coincides with the site for replacement tooth production identifying a region responsible for further tooth generation. This corresponds with the expression of pitx2 at focal spots in the basal oral epithelium during initial (first generation) tooth formation but is now sub-epithelial in position and associated with the dental epithelium of each predecessor tooth. Co-incidental expression of bmp4 and aggregation of the mesenchymal cells identifies the epithelial-mesenchymal interactions and marks initiation of the dental papilla. These together suggest a role in tooth site regulation by pitx2 together with bmp4. Conversely, the expression of shh is confined to the inner dental epithelium during the initiation of the first teeth and is lacking from the ODE in the predecessor teeth, at sites identified as those for replacement tooth initiation. Importantly, these genes expressed during replacement tooth initiation can be used as markers for the sites of "set-aside cells," the committed odontogenic cells both epithelial and mesenchymal, which together can give rise to further generations of teeth. This information may show how initial pattern formation is translated into secondary tooth replacement patterns, as a general mechanism for patterning the vertebrate dentition. Replacement of the marginal sets of teeth serves as a basis for discussion of the evolutionary significance, as these dentate bones (dentary, premaxilla, maxilla) form the restricted arcades of oral teeth in many crown-group gnathostomes, including members of the tetrapod stem group.     

Plant community responses to long-term fertilization: changes in functional group abundance drive changes in species richness

Declines in species richness due to fertilization are typically rapid and associated with increases in aboveground production. However, in a long-term experiment examining the impacts of fertilization in an early successional community, we found it took 14 years for plant species richness to significantly decline in fertilized plots, despite fertilization causing a rapid increase in aboveground production. To determine what accounted for this lag in the species richness response, we examined several potential mechanisms. We found evidence suggesting the abundance of one functional group—tall species with long-distance (runner) clonality—drove changes in species richness, and we found little support for other mechanisms. Tall runner species initially increased in abundance due to fertilization, then declined dramatically and were not abundant again until later in the experiment, when species richness and the combined biomass of all other functional groups (non-tall runner) declined. Over 86 % of the species found throughout the course of our study are non-tall runner, and there is a strong negative relationship between non-tall runner and tall runner biomass. We therefore suggest that declines in species richness in the fertilized treatment are due to high tall runner abundance that decreases the abundance and richness of non-tall runner species. By identifying the functional group that drives declines in richness due to fertilization, our results help to elucidate how fertilization decreases plant richness and also suggest that declines in richness due to fertilization can be lessened by controlling the abundance of species with a tall runner growth form.