Tissue engineering of teeth using adult stem cells.

Tooth development, a process which occurs in the developing embryo, involves the reciprocal and sequential signalling between epithelial and mesenchymal tissue of the developing first branchial arch. The oral epithelium produces the first inductive signals for odontogenesis at around E10.0, which trigger off a cascade of events that result in the formation of a tooth. We have engineered a tooth in vitro by harnessing the basic principles of odontogenesis and the inductive capability of the oral epithelium of the developing embryo. We replaced the mesenchymal portion of the developing mandibular primordium with aggregates of stem cells from embryos as well as stem cells taken from adult mice. The cell aggregates were covered with embryonic epithelium from E10.0 mouse embryos to form recombinant explants. In vitro culture of these recombinant explants resulted in the induction of early tooth marker genes in the cell aggregates, indicating that the cells were able to respond to the odontogenic signals produced by the oral epithelium. In vivo culture of explants resulted in the induction of Dspp within the cell aggregates indicating that tooth tissue was present. Three recombinant explants, where the cell aggregates consisted of adult bone marrow cells, produced teeth. To determine whether the oral cavity would be able to sustain the growth of an implanted tooth germ, E14.5 molar rudiments were implanted into the diastema region of the maxilla of adult mice. The resulting teeth appeared to be normal in size and were connected to the underlying bone. These experiments are an indication that it is possible to induce odontogenesis and engineer a tooth using adult cells of non-dental origin. They also indicate that developing tooth germs could be successfully implanted into the gingiva of patients.

Trf1 is not required for proliferation or functional telomere maintenance in chicken DT40 cells.

The telomere end-protection complex prevents the ends of linear eukaryotic chromosomes from degradation or inappropriate DNA repair. The homodimeric double-stranded DNA-binding protein, Trf1, is a component of this complex and is essential for mouse embryonic development. To define the requirement for Trf1 in somatic cells, we deleted Trf1 in chicken DT40 cells by gene targeting. Trf1-deficient cells proliferated as rapidly as control cells and showed telomeric localization of Trf2, Rap1, and Pot1. Telomeric G-strand overhang lengths were increased in late-passage Trf1-deficient cells, although telomere lengths were unaffected by Trf1 deficiency, as determined by denaturing Southern and quantitative FISH analysis. Although we observed some clonal variation in terminal telomere fragment lengths, this did not correlate with cellular Trf1 levels. Trf1 was not required for telomere seeding, indicating that de novo telomere formation can proceed without Trf1. The Pin2 isoform and a novel exon 4, 5-deleted isoform localized to telomeres in Trf1-deficient cells. Trf1-deficient cells were sensitive to DNA damage induced by ionizing radiation. Our data demonstrate that chicken DT40 B cells do not require Trf1 for functional telomere structure and suggest that Trf1 may have additional, nontelomeric roles involved in maintaining genome stability.

An aneuploid mouse strain carrying human chromosome 21 with Down syndrome phenotypes.

Aneuploidies are common chromosomal defects that result in growth and developmental deficits and high levels of lethality in humans. To gain insight into the biology of aneuploidies, we manipulated mouse embryonic stem cells and generated a trans-species aneuploid mouse line that stably transmits a freely segregating, almost complete human chromosome 21 (Hsa21). This "transchromosomic" mouse line, Tc1, is a model of trisomy 21, which manifests as Down syndrome (DS) in humans, and has phenotypic alterations in behavior, synaptic plasticity, cerebellar neuronal number, heart development, and mandible size that relate to human DS. Transchromosomic mouse lines such as Tc1 may represent useful genetic tools for dissecting other human aneuploidies.