Multipotency of FBD-103a, a neural progenitor cell line from the p53-deficient mouse

A clonal stem cell line established from a mouse mammary placode with ability to generate functional mammary glands

The mammary gland develops from the placode at ectodermal invagination. The rudimentary parenchyma (mammary bud) develops mammary trees and alveolar structures, suggesting that the mammary bud consists of stem/progenitor cells. Here, we established a clonal stem cell line from a mammary bud of a p53 null female embryo at day 14.5. FP5-3-1 line was a homogeneous cell population with polygonal epithelial morphology and spontaneously became heterogeneous during passages. Recloning gave rise to four sublines; three sublines have basal epithelial property and one subline has luminal epithelial property. The former sublines generate functional mammary glands when injected into cleared fat pads and the latter subline does not. The cell lines also express many stemness-related genes. The clonal cell lines established in the present study are shown to be mammary stem cells and not tumorigenic. They provide useful models for normal and tumor biology of the mammary gland in vivo and in vitro.

Successful reconstruction of tooth germ with cell lines requires coordinated gene expressions from the initiation stage

Tooth morphogenesis is carried out by a series of reciprocal interactions between the epithelium and mesenchyme in embryonic germs. Previously clonal dental epithelial cell (epithelium of molar tooth germ (emtg)) lines were established from an embryonic germ. They were odontogenic when combined with a dental mesenchymal tissue, although the odontogenesis was quantitatively imperfect. To improve the microenvironment in the germs, freshly isolated dental epithelial cells were mixed with cells of lines, and germs were reconstructed in various combinations. The results demonstrated that successful tooth construction depends on the mixing ratio, the age of dental epithelial cells and the combination with cell lines. Analyses of gene expression in these germs suggest that some signal(s) from dental epithelial cells makes emtg cells competent to communicate with mesenchymal cells and the epithelial and mesenchymal compartments are able to progress odontogenesis from the initiation stage.

Attempt to develop taste bud models in three-dimensional culture

Taste buds are the end organs of taste located in the gustatory papillae, which occur on the surface of the oral cavity. The goal of the present study was to establish a culture model mimicking the lingual taste bud of the mouse. To this end, three cell lines were employed: taste bud-derived cell lines (TBD cell lines), a lingual epithelial cell-derived cell line (20A cell line), and a mesenchymal cell-derived cell line (TMD cell line). TBD cells embedded in collagen gel formed three-dimensional clusters, which had an internal cavity equipped with a tight junction-like structure, a microvilluslike structure, and a laminin-positive layer surrounding the cluster. The cells with this epitheliumlike morphology expressed marker proteins of taste cells: gustducin and NCAM. TBD cells formed a monolayer on collagen gel when they were co-cultured with TMD cells. TBD, 20A, and TMD cell lines were maintained in a triple cell co-culture, in which TBD cells were pre-seeded as aggregates or in suspension on the collagen gel containing TMD cells, and 20A cells were laid over the TBD cells. TBD cells in the triple cell co-culture expressed NCAM. This result suggests that co-cultured TBD cells exhibited a characteristic of Type III taste cells. The culture model would be useful to study morphogenesis and functions of the gustatory organ.

Establishment of clonal cell lines of taste buds from a p53(-/-) mouse tongue

A taste bud is a sensory organ and consists of 50-100 spindle-shaped cells. The cells function as taste acceptors. They have characteristics of both epithelial and neuronal cells. A taste bud contains four types of cells, type I, type II, type III cells, and basal cells. Taste buds were isolated from a tongue of a p53-deficient mouse at day 12, and 11 clonal taste bud (TBD) cell lines were established. In immunochemical analysis, all cell lines expressed cytokeratin 18, gustducin, T1R3, and neural cellular adhesion molecule, but not GLAST. In RT-PCR analysis, shh was not expressed in any of the cell lines. Further analysis with RT-PCR was conducted on four cell lines. They expressed G protein-coupled taste receptors; T1R3, T2R8 for sweet, bitter, umami. And they also expressed α-ENaC for salty taste. While, a candidate for sour receptor HCN4 was expressed in TBD-a1 and TBD-a7 lines. And another candidate for sour receptor PKD1L3 was slightly expressed in TBD-a1 and TBD-c1.

Follistatin-like-1, a diffusible mesenchymal factor determines the fate of epithelium

Mesenchyme is generally believed to play critical roles in "secondary induction" during organogenesis. Because of the complexity of tissue interactions in secondary inductions, however, little is known about the precise mechanisms at the cellular and molecular levels. We have demonstrated that, in mouse oviductal development, the mesenchyme determines the fate of undetermined epithelial cells to become secretory or cilial cells. We have established a model for studying secondary induction by establishing clonal epithelial and mesenchymal cell lines from perinatal p53(-/-) mouse oviducts. The signal sequence trap method collected candidate molecules secreted from mesenchymal cell lines. Naive epithelial cells exposed to Follistatin-like-1 (Fstl1), one of the candidates, became irreversibly committed to expressing a cilial epithelial marker and differentiated into ciliated cells. We concluded that Fstl1 is one of the mesenchymal factors determining oviductal epithelial cell fate. This is a unique demonstration that the determination of epithelial cell fate is induced by a single diffusible factor.

Tooth regeneration from newly established cell lines from a molar tooth germ epithelium

In order to investigate tooth development, several cell lines of the dental epithelium and ectomesenchyme have been established. However, no attempt has been reported to regenerate teeth with cell lines. Here, we have established several clonal cell lines of the dental epithelium from a p53-deficient fetal mouse. They expressed specific markers of the dental epithelium such as ameloblastin and amelogenin. A new method has been developed to bioengineer tooth germs with dental epithelial and mesenchymal cells. Reconstructed tooth germs with cell lines and fetal mesenchymal cells were implanted under kidney capsule. The germs regenerated teeth with well-calcified structures as seen in natural tooth. Germs without the cell lines developed bone. This is the first success to regenerate teeth with dental epithelial cell lines. They are useful models in vitro for investigation of mechanisms in morphogenesis and of cell lineage in differentiation, and for clinical application for tooth regeneration.

Molecular genetic analysis of the REST/NRSF gene in nervous system tumors

The gene for RE1-silencing transcription factor (REST) alias neuron-restrictive silencer factor NRSF, acts as a transcriptional repressor in the neuronal differentiation pathways in non-neuronal cells, and plays an important role in neuronal development. Inactivating mutations or overexpression of REST have previously been reported in various types of cancer, but no data is available for the role of REST alterations in gliomas. REST gene was screened for mutations in 161 nervous system tumors consisting of astrocytomas, glioblastomas, oligodendrogliomas, oligoastrocytomas, medulloblastomas, meningiomas and schwannomas. REST exons 1-3 were analyzed using denaturing high-performance liquid chromatography (DHPLC) and direct sequencing. The gene copy numbers of REST were investigated by chromogenic (CISH) and fluorescence in situ hybridization (FISH) techniques. Non-synonymous SNPs (P797L, P815S) were found in eight different brain tumor samples. No truncating or activating novel mutations of REST were discovered. Since REST is located at 4q12, a chromosome region implicated in brain tumorigenesis, we conducted gene copy number analyses in medulloblastomas and gliomas. The majority of gliomas (67%) demonstrated low-level amplifications of REST, and only one oligodendroglioma showed high-level amplification of the gene. In medulloblastomas, 38% of samples were determined as aneuploidic, no high-level amplifications were found. Our data suggests that REST is neither activated nor inactivated via mutations in gliomas, while high-level amplification may rarely occur.