Localization of Beclin1 in mouse developing tooth germs: possible implication of the interrelation between autophagy and apoptosis

Our previous study identified the appearance of autophagy in developing tooth germs, and suggested its possible association with apoptosis in odontogenesis. Beclin1 was recently indicated to play a central role in bridging autophagy and apoptosis, and occupied a key position in the process of development. This study hypothesized that Beclin1 may be involved, and act as the molecular basis of the connection between autophagy and apoptosis in odontogenesis. Immunohistochemical analysis showed the spatiotemporal expression pattern of Beclin1 in odontogenesis from embryonic (E) day 13.5 to postnatal (P) day 5.5. At E stages, Beclin1 was mainly immunolocalized in the cytoplasm of the cells in the enamel organ. Meanwhile, the nucleus localization of Beclin1 was detected in part of the stellate reticulum, outer and inner enamel epithelium, especially at E16.5 and E18.5. At P stages, Beclin1 was detected in the cytoplasm of the odontoblasts, besides the dental epithelium cells. Triple immunofluorescence analysis showed the partial colocalization of Beclin1, autophagic marker LC3, or activated caspase-3 in the E14.5 tooth germs, especially the Beclin1⁺LC3⁺Caspase-3⁺ cells in the PEK. Furthermore, western blot analysis revealed that the full-length (60 kDa) and/or cleaved (50, 37, and 35 kDa) Beclin1 in the developing tooth germs. Taken together, our findings indicate that Beclin1 is involved, and might be responsible for the crosstalk between autophagy and apoptosis in mouse odontogenesis.     

FGF8-mediated signaling regulates tooth developmental pace during odontogenesis

The developing human and mouse teeth constitute an ideal model system to study the regulatory mechanism underlying organ growth control since their teeth share highly conserved and well-characterized developmental processes, and their developmental tempo varies notably. In the current study, we manipulated heterogenous recombination between human and mouse dental tissues and demonstrated that the dental mesenchyme dominates the tooth developmental tempo and FGF8 could be a critical player during this developmental process. Forced activation of FGF8 signaling in the dental mesenchyme of mice promoted cell proliferation, prevented cell apoptosis via p38 and perhaps PI3K-Akt intracellular signaling, and impelled the transition of the cell cycle from G1- to S-phase in the tooth germ, resulting in the slowdown of the tooth developmental pace. Our results provide compelling evidence that extrinsic signals can profoundly affect tooth developmental tempo, and the dental mesenchymal FGF8 could be a pivotal factor in controlling the developmental pace in a non-cell-autonomous manner during mammalian odontogenesis.     

Proliferation and apoptosis in early molar morphogenesis-- voles as models in odontogenesis

Proliferation and apoptosis play crucial roles in the development of multicellular organisms. Their precise balance is necessary for tissue homeostasis throughout life. The developing dentition is a suitable model to study proliferation and apoptosis during embryogenesis, but the corresponding studies have been carried out principally in the mouse. The present study aimed to examine proliferation and apoptosis in the vole (Microtus sp., Rodentia) during the early morphogenesis of the first upper molar and compare it to what is known from the mouse. To this end, apoptosis and proliferation were investigated using histology and computer-aided 3D reconstruction. Mitoses accumulated predominantly in the developing cervical loop. Apoptosis during early odontogenesis showed highly specific spatio-temporal patterns in the dental epithelium. Apoptotic bodies were localised in non-dividing cell populations. They accumulated in the same places as described in the mouse: antemolar vestiges (ED 12.5 15.5), enamel knot (ED 14.5 15.5), stalk and palatally along the whole first molar tooth germ longitudinal axis (ED 15 - 15.5). Early tooth development in the field vole, including the distribution of apoptosis and mitosis, is very similar to that reported in the mouse, with the exception of the antemolar region. The microtine antemolar vestige is preserved longer than the murine one. It is conceivable that additional distinct differences in morphogenetic processes appear later in tooth development.     

The presence of rudimentary odontogenic structures in the mouse embryonic mandible requires reinterpretation of developmental control of first lower molar histomorphogenesis

In the mouse embryonic maxilla, rudimentary tooth primordia have been identified, which can be mistaken for the first upper molar. In order to determine whether such a situation might exist in the lower jaw as well, tooth development was investigated in the mouse mandibular cheek region during ED 12.5-15.0. A combination of histology, morphometry and computer-aided 3D reconstructions demonstrated the existence of rudimentary dental structures, whose gradual appearance and regression was associated with the segmental progress of odontogenesis along the mesio-distal axis of the jaw: 1) At ED 12.5, the mesial segment (MS) was the most prominent part of the dental epithelial invagination. It included an asymmetrically budding dental lamina. The MS, although generally mistaken for the lower first molar (M1, primordium, regressed and did not finally participate in M1 cap formation. 2) At ED 13.5, a wide dental bud (called segment R2) appeared distally to the MS. Although the R2 segment transiently represented the predominant part of the dental epithelium at ED13.5, it participated only in the formation of the mesial end of the M1 cap. 3) The top of the R2 segment at ED13.5 was not the precursor of the enamel knot (EK), contrary to what has been assumed. 4) The central segment of the M1 cap as well as the EK developed later and distally to the R2 segment. 5) Time-space specific apoptosis correlated with the retardation in growth of the R2 segment as well as with strong regressive changes in the epithelium situated mesially to it. These highlight the need to reinterpret current molecular data on early M1 development in the mouse in order to correlate the expression of signalling molecules with specific morphogenetic events in the appropriate antemolar or molar segments of the embryonic mandible.     

Molar tooth development in caspase-3 deficient mice

Tooth morphogenesis is accompanied by apoptotic events which show restricted temporospatial patterns suggesting multiple roles in odontogenesis. Dental apoptosis seems to be caspase dependent and caspase-3 has been shown to be activated during dental apoptosis.Caspase-3 mutant mice on different genetic backgrounds were used to investigate alterations in dental apoptosis and molar tooth morphogenesis. Mouse embryos at E15.5 were analyzed to reveal any changes in enamel knots, which are transient structures eliminated by apoptosis. In caspase-3(-/-) mice on the B57BL/6 background, disorganization of the epithelium was found in the original primary enamel knot area and confirmed by altered expression of Shh. Despite this early defect in molar tooth development, these mutants showed correct formation of secondary enamel knots as indicated by Fgf-4 expression. Analyses of adult molar teeth did not reveal any major alterations in tooth shape, enamel structure or pattern when compared to heterozygote littermates. In caspase-3(-/-) mice on the 129X1/SvJ background, no defects in tooth development were found except the position of the upper molars which developed more posteriorly in the oral cavity. This is likely, however, to be a secondary defect caused by a physical squashing of the face by the malformed brain. The results suggest that although caspase-3 becomes activated and may be essential for dental apoptosis, it does not seem fundamental for formation of normal mineralised molar teeth.     

Regulation of proliferation in developing human tooth germs by MSX homeodomain proteins and cyclin-dependent kinase inhibitor p19INK4d

Before the secretion of hard dental tissues, tooth germs undergo several distinctive stages of development (dental lamina, bud, cap and bell). Every stage is characterized by specific proliferation patterns, which is regulated by various morphogens, growth factors and homeodomain proteins. The role of MSX homeodomain proteins in odontogenesis is rather complex. Expression domains of genes encoding for murine Msx1/2 during development are observed in tissues containing highly proliferative progenitor cells. Arrest of tooth development in Msx knockout mice can be attributed to impaired proliferation of progenitor cells. In Msx1 knockout mice, these progenitor cells start to differentiate prematurely as they strongly express cyclin-dependent kinase inhibitor p19^INK4d. p19^INK4d induces terminal differentiation of cells by blocking the cell cycle in mitogen-responsive G1 phase. Direct suppression of p19^INK4d by Msx1 protein is, therefore, important for maintaining proliferation of progenitor cells at levels required for the normal progression of tooth development. In this study, we examined the expression patterns of MSX1, MSX2 and p19^INK4d in human incisor tooth germs during the bud, cap and early bell stages of development. The distribution of expression domains of p19^INK4d throughout the investigated period indicates that p19^INK4d plays active role during human tooth development. Furthermore, comparison of expression domains of p19^INK4d with those of MSX1, MSX2 and proliferation markers Ki67, Cyclin A2 and pRb, indicates that MSX-mediated regulation of proliferation in human tooth germs might not be executed by the mechanism similar to one described in developing tooth germs of wild-type mouse.     

Enhanced Wnt/β-catenin signalling during tooth morphogenesis impedes cell differentiation and leads to alterations in the structure and mineralisation of the adult tooth

BACKGROUND INFORMATION: Previous studies have indicated that over-activation of the wingless interaction site (Wnt)/β-catenin signalling pathway has important implications for tooth development, at the level of cell differentiation and morphology, as well as for the production of supernumerary teeth. Here, we provide evidence for a crucial role of this signalling pathway during the stage of tooth morphogenesis. We have developed an in vitro model consisting of 14.5-day-old mouse embryo first molars, in which the Wnt pathway is overactivated by the glycogen synthase kinase-3 inhibitor 6-bromoindirubin-3'-oxime (BIO; 20 μM). RESULTS: We found that over-activation of the Wnt/β-catenin pathway delayed the differentiation and growth of the inner dental epithelium. In addition, in contrast to controls in which Nestin protein expression was restricted to differentiated odontoblasts, in BIO-treated molars, Nestin expression spread through sub-odontoblastic cellular layers. This alteration appears to be related to: (i) the over-expression of Bmp4 in the same region, (ii) the delay in odontoblast precursor cell differentiation and (iii) increased proliferation of mesenchymal cells. Furthermore, treatments longer than 6 days induced the malformation of typical dental structures and led to a total lack of cell differentiation. Finally, over-activation of the Wnt route during odontogenesis resulted in adult teeth which presented altered size, morphology and mineralisation. CONCLUSIONS: Our results indicate that Wnt/β-catenin over-activation during tooth morphogenesis is sufficient to cause dramatic alterations in the adult tooth, by delaying cellular differentiation and stimulating proliferation of the dental mesenchyme of developing teeth.     

miR‐34c works downstream of p53 leading to dairy goat male germline stem‐cell (mGSCs) apoptosis

Objectives

Recent lines of evidence have indicated that miR‐34c can play important roles in regulation of the cell cycle, cell senescence and apoptosis of mouse and human tumour cells, spermatogenesis, and male germ‐cell apoptosis. However, there is little information on the effects of miR‐34c on proliferation and apoptosis of livestock male germ cells. The dairy goat is a convenient domestic species for biological investigation and application. The purpose of this study was to investigate the effects of miR‐34c on apoptosis and proliferation of dairy goat male germline stem cells (mGSCs), as well as to determine the relationship between p53 and miR‐34c in this species.

Materials and methods

Morphological observation, miRNA in situ hybridisation (ISH), bromodeoxyuridine staining, flow cytometry, quantitative‐RT‐PCR (Q‐RT‐PCR) and western blotting were utilized to ascertain apoptosis and proliferation of mGSCs, through transfection of miR‐34c mimics (miR‐34c), miR‐34c inhibitor (anti‐miR‐34c), miR‐34c mimics and inhibitors co‐transfected (mixture) compared to control groups.

Results

Results manifested that miR‐34c over‐expression promoted mGSCs apoptosis and suppressed their proliferation. Simultaneously, a variety of apoptosis‐related gene expression was increased while some proliferation‐related genes were downregulated. Accordingly, miR‐34c promoted apoptosis in mGSCs and reduced their proliferation; moreover, expression of miR‐34c was p53‐dependent.

Conclusions

This study is the first to provide a model for study of miRNAs and mechanisms of proliferation and apoptosis in male dairy goat germ cells.

     

Cranial neural crest-derived mesenchymal proliferation is regulated by Msx1-mediated p19(INK4d) expression during odontogenesis

Neural crest cells are multipotential progenitors that contribute to various cell and tissue types during embryogenesis. Here, we have investigated the molecular and cellular mechanism by which the fate of neural crest cell is regulated during tooth development. Using a two- component genetic system for indelibly marking the progeny of neural crest cells, we provide in vivo evidence of a deficiency of CNC-derived dental mesenchyme in Msx1 null mutant mouse embryos. The deficiency of the CNC results from an elevated CDK inhibitor p19(INK4d) activity and the disruption of cell proliferation. Interestingly, in the absence of Msx1, the CNC-derived dental mesenchyme misdifferentiates and possesses properties consistent with a neuronal fate, possibly through a default mechanism. Attenuation of p19(INK4d) in Msx1 null mutant mandibular explants restores mitotic activity in the dental mesenchyme, demonstrating the functional significance of Msx1-mediated p19(INK4d) expression in regulating CNC cell proliferation during odontogenesis. Collectively, our results demonstrate that homeobox gene Msx1 regulates the fate of CNC cells by controlling the progression of the cell cycle. Genetic mutation of Msx1 may alternatively instruct the fate of these progenitor cells during craniofacial development.     

Apoptosis distribution in the first molar tooth germ of the field vole (Microtus agrestis)

Apoptosis represents an important process in organ and tissue morphogenesis and remodeling during embryonic development. A role for apoptosis in shape formation of developing teeth has been suggested. The field vole is a useful model for comparative studies in odontogenesis, particularly because of its contrasting molar morphogenesis when compared to the mouse. However, little is known concerning apoptosis in tooth development of this species. Morphological (cellular and nuclear alterations) and biochemical (specific DNA breaks--TUNEL staining) characteristics of apoptotic cells were used to evaluate the temporal and spatial occurrence of apoptosis in epithelial and mesenchymal tissues of the developing first molar tooth germs of the field vole. Apoptotic cells were found in non-proliferating areas (identified previously) throughout bud to bell stages, particularly in the epithelium, however, scattered also in the mesenchyme. A high concentration of TUNEL positive cells was evident in primary enamel knots at late bud stage with increasing density of apoptotic cells until ED 16 when the primary enamel knot in the field vole disappears and mesenchyme becomes protruded in the middle axes of the bell forming two shallow areas with zig-zag located secondary enamel knots. Distribution of TUNEL positive cells corresponded with localisation of secondary enamel knots as shown using histological and 3D analysis. Apoptosis was shown to be involved in the first molar development of the field vole, however, exact mechanisms and roles of this process in tooth morphogenesis require further investigation.     

鸟类仍保留牙齿发生定位的分子机制(英文)

众所周知现代鸟类不长牙齿,而其侏罗纪和白垩纪的祖先则长有牙齿。然而,在发育中鸡胚口腔中却残留着牙齿发生的原基,在形态上与哺乳动物臼牙牙原基极为相似。现代鸟类的胚胎组织是否具有牙齿发育的潜能,目前已有不少研究者对这一问题进行了探讨。Kollar和Fisher 等人将鸡胚胎下颌靠近口腔面的上皮与小鼠的牙间充质进行组织重组实验,并植入小鼠眼球中作intraocular grafting培养。他们的实验结果表明重组后的组织块可以发育形成牙齿的结构,包括形成成釉细胞(ameloblast),并能分泌釉质。Kollar等认为在进化过程中鸟类牙齿的消失并非由于口腔上皮中有关釉质合成的遗传信息的丢失,而是牙齿发育过程中的组织之间所必须的相互作用(次级诱导)受阻而造成的。Lemus和Fuenzalida等人的实验结果进一步证实了这一结论。他们用鹌鹑胚胎躯体的上皮组织与蜥蚁或兔子的牙间充质重组后,用鸡胚绒毛膜法进行培养,得到了发育很好的牙齿结构。发现鹌鹑的上皮细胞也可以分化形成釉质细胞,并分泌牙釉质。Cummings 将鹌鹑胚胎的牙上皮组织与小鼠胚胎的牙间充质组织重组后也得到类似的结果。根据小白鼠牙齿发育中已知的调控分子信号通路,我们曾对鸟类不长牙齿的分子机制进行了研究。我们的研究发现鸟类牙胚组织仍保留     

Apoptotic signaling in mouse odontogenesis

Apoptosis is an important morphogenetic event in embryogenesis as well as during postnatal life. In the last 2 decades, apoptosis in tooth development (odontogenesis) has been investigated with gradually increasing focus on the mechanisms and signaling pathways involved. The molecular machinery responsible for apoptosis exhibits a high degree of conservation but also organ and tissue specific patterns. This review aims to discuss recent knowledge about apoptotic signaling networks during odontogenesis, concentrating on the mouse, which is often used as a model organism for human dentistry. Apoptosis accompanies the entire development of the tooth and corresponding remodeling of the surrounding bony tissue. It is most evident in its role in the elimination of signaling centers within developing teeth, removal of vestigal tooth germs, and in odontoblast and ameloblast organization during tooth mineralization. Dental apoptosis is caspase dependent and proceeds via mitochondrial mediated cell death with possible amplification by Fas-FasL signaling modulated by Bcl-2 family members.     

Transient and recurrent expression of the Egr-1 gene in epithelial and mesenchymal cells during tooth morphogenesis suggests involvement in tissue interactions and in determination of cell fate.

We have analyzed the expression of early growth response gene (Egr-1) by mRNA in situ hybridization during mouse embryonic tooth development and in experimental recombinations of dental epithelium and mesenchyme. Egr-1 was transiently and recurrently expressed both in epithelial and mesenchymal cells starting from day 13 of gestation and up to 4 days after birth. The expression correlated with developmental transition points of dental mesenchymal and epithelial cells suggesting a role for Egr-1 in sequential determination and differentiation of cells. In recombination cultures of early dental epithelium and mesenchyme Egr-1 RNA was localized at the epithelial-mesenchymal interface in mesenchymal cells, and in two cases also in epithelial cells. These data indicate that Egr-1 expression may be regulated by epithelial-mesenchymal interactions when they are specific enough to initiate differentiation. We have also analyzed by in situ hybridization whether Wilms' tumour-1 gene (wt-1) is expressed in the developing tooth as it was proposed on the bases of in vitro studies that it may inhibit Egr-1 expression. No wt-1 expression was detected at any stage of tooth development showing that wt-1 is not obligatory for regulation of Egr-1 expression.     

Odontogenesis and neuronal differentiation characteristics of periodontal ligament stem cells from beagle dog

Periodontal ligament stem cells (PDLSCs) from beagle dogs had the characteristics of multi‐directional differentiation and had great application potential in tissue engineering and cell regenerative medicine. In this study, we analysed the odontogenesis and neuronal differentiation characteristics of PDLSCs in vitro. Results showed that the calcined tooth powder (CTP) and silver nanoparticles (AgNPs) additives could induce the PDLSCs into odontogenesis differentiation; besides, the immunofluorescence staining identified that the high dosage calcined tooth powder (400 μg/mL) significantly facilitated the odontogenesis associated with BMP4 expression. While the nutritional factor (L‐glutamine, NGF (nerve growth factor), bFGF (basic fibroblast growth factor), IGF‐1 (insulin‐like growth factor‐1) and EGF (epidermal growth factor)) additives were prior to induce the PDLSCs into neuronal differentiation. Simultaneously, PDLSCs had high proliferation ability with the different supplemented additives. Importantly, the Western blot results also proved the BMP4 and SMAD1 proteins were highly expressed in the induced odontoblast, while the SOX1, NCAM1, GFAP and VEGFA proteins were all obviously expressed in the induced neurons. Hence, PDLSCs had characteristics of both odontogenesis and neuronal differentiation.     

Odontogenic capability: bone marrow stromal stem cells versus dental pulp stem cells

Background information. Although adult bone‐marrow‐derived cell populations have been used to make teeth when recombined with embryonic oral epithelium, the differences between dental and non‐dental stem‐cell‐mediated odontogenesis remain an open question. Results. STRO‐1⁺ (stromal precursor cell marker) DPSCs (dental pulp stem cells) and BMSSCs (bone marrow stromal stem cells) were isolated from rat dental pulp and bone marrow respectively by magnetic‐activated cell‐sorting techniques. Their odontogenic capacity was compared under the same inductive microenvironment produced by ABCs (apical bud cells) from 2‐day‐old rat incisors. Co‐cultured DPSCs/ABCs in vitro showed more active odontogenic differentiation ability than mixed BMSSCs/ABCs, as indicated by the accelerated matrix mineralization, up‐regulated alkaline phosphatase activity, cell‐cycle modification, and the expression of tooth‐specific proteins and genes. After cultured for 14 days in the renal capsules of rat hosts, recombined DPSC/ABC pellets formed typical tooth‐shaped tissues with balanced amelogenesis and dentinogenesis, whereas BMSSC/ABC recombinants developed into atypical dentin—pulp complexes without enamel formation. DPSC and BMSSC pellets in vivo produced osteodentin‐like structures and fibrous connective tissues respectively. Conclusions. DPSCs presented more striking odontogenic capability than BMSSCs under the induction of postnatal ABCs. This report provides critical insights into the selection of candidate cells for tooth regeneration between dental and non‐dental stem cell populations.