7 research outputs found
Cell Reprogramming, IPS Limitations, and Overcoming Strategies in Dental Bioengineering
The procurement of induced pluripotent stem cells, or IPS cells, from adult differentiated animal cells has the potential to revolutionize future medicine, where reprogrammed IPS cells may be used to repair disease-affected tissues on demand. The potential of IPS cell technology is tremendous, but it will be essential to improve the methodologies for IPS cell generation and to precisely evaluate each clone and subclone of IPS cells for their safety and efficacy. Additionally, the current state of knowledge on IPS cells advises that research on their regenerative properties is carried out in appropriate tissue and organ systems that permit a safe assessment of the long-term behavior of these reprogrammed cells. In the present paper, we discuss the mechanisms of cell reprogramming, current technical limitations of IPS cells for their use in human tissue engineering, and possibilities to overcome them in the particular case of dental regeneration
Cell Reprogramming, IPS Limitations, and Overcoming Strategies in Dental Bioengineering
The procurement of induced pluripotent stem cells, or IPS cells, from adult differentiated animal cells has the potential to revolutionize future medicine, where reprogrammed IPS cells may be used to repair disease-affected tissues on demand. The potential of IPS cell technology is tremendous, but it will be essential to improve the methodologies for IPS cell generation and to precisely evaluate each clone and subclone of IPS cells for their safety and efficacy. Additionally, the current state of knowledge on IPS cells advises that research on their regenerative properties is carried out in appropriate tissue and organ systems that permit a safe assessment of the long-term behavior of these reprogrammed cells. In the present paper, we discuss the mechanisms of cell reprogramming, current technical limitations of IPS cells for their use in human tissue engineering, and possibilities to overcome them in the particular case of dental regeneration
Liver osteopontin is required to prevent the progression of age-related nonalcoholic fatty liver disease
[EN] Osteopontin (OPN), a senescence-associated secretory phenotype factor, is increased
in patients with nonalcoholic fatty liver disease (NAFLD). Cellular senescence
has been associated with age-dependent hepatosteatosis. Thus, we investigated the
role of OPN in the age-related hepatosteatosis. For this, human serum samples, animal
models of aging, and cell lines in which senescence was induced were used.
Metabolic fluxes, lipid, and protein concentration were determined. Among individuals
with a normal liver, we observed a positive correlation between serum OPN levels
and increasing age. This correlation with age, however, was absent in patients with
NAFLD. In wild-type (WT) mice, serum and liver OPN were increased at 10 months
old (m) along with liver p53 levels and remained elevated at 20m. Markers of liver
senescence increased in association with synthesis and concentration of triglycerides
(TG) in 10m OPN-deficient (KO) hepatocytes when compared to WT hepatocytes.
These changes in senescence and lipid metabolism in 10m OPN-KO mice liver were
associated with the decrease of 78 kDa glucose-regulated protein (GRP78), induction
of ER stress, and the increase in fatty acid synthase and CD36 levels. OPN deficiency in senescent cells also diminished GRP78, the accumulation of intracellular TG, and
the increase in CD36 levels. In 20m mice, OPN loss led to increased liver fibrosis.
Finally, we showed that OPN expression in vitro and in vivo was regulated by p53.
In conclusion, OPN deficiency leads to earlier cellular senescence, ER stress, and TG
accumulation during aging. The p53-OPN axis is required to inhibit the onset of agerelated
hepatosteatosis.This work was supported by Ayudas para apoyar grupos de investigación del sistema Universitario Vasco (IT971‐16 to P.A.), MINECO‐FEDER (SAF2017‐87301‐R to M.L.M‐Ch) MCIU/AEI/FEDER, UE (RTI2018‐095134‐B‐100 to P.A. and RTI2018‐099413‐B‐I00 to RN, Asociación Española contra el Cáncer, Canceres raros (M.L.M‐Ch), La Caixa Foundation (to M.L.M‐Ch), Ayudas Fundación BBVA a equipos de Investigación Científica 2018 (to M.L.M‐Ch), Xunta de Galicia (RN: 2015‐CP080 and 2016‐ PG057), Fundación BBVA (RN), and European Foundation for the Study of Diabetes (RN). ISCIII‐FEDER PI17/00535 (to C.G‐M.), ISCIII‐FEDER CP14/00181 and PI16/00823 (to A.G‐ R.), and Francisco Cobos Foundation (to A.G‐R.). CiC bioGUNE thanks MINECO for the Severo Ochoa Excellence Accreditation (SEV‐2016‐ 0644
Neural Crest Stem Cells from Dental Tissues: A New Hope for Dental and Neural Regeneration
Several stem cell sources persist in the adult human body, which opens the doors to both allogeneic and autologous cell therapies. Tooth tissues have proven to be a surprisingly rich and accessible source of neural crest-derived ectomesenchymal stem cells (EMSCs), which may be employed to repair disease-affected oral tissues in advanced regenerative dentistry. Additionally, one area of medicine that demands intensive research on new sources of stem cells is nervous system regeneration, since this constitutes a therapeutic hope for patients affected by highly invalidating conditions such as spinal cord injury, stroke, or neurodegenerative diseases. However, endogenous adult sources of neural stem cells present major drawbacks, such as their scarcity and complicated obtention. In this context, EMSCs from dental tissues emerge as good alternative candidates, since they are preserved in adult human individuals, and retain both high proliferation ability and a neural-like phenotype in vitro. In this paper, we discuss some important aspects of tissue regeneration by cell therapy and point out some advantages that EMSCs provide for dental and neural regeneration. We will finally review some of the latest research featuring experimental approaches and benefits of dental stem cell therapy
Epiprofin-Sp6. A new player in the regulation of tooth development
Odontogenesis is governed by a complex
network of intercellular signaling events between the
dental epithelium and mesenchyme. This network leads
to the progressive determination of tooth shape, and to
the differentiation of these tissues into enamel-producing
ameloblasts and dentin-producing odontoblasts
respectively. Among the main signaling pathways
involved in the regulation of tooth development, Bone
Morphogenetic Protein (BMP), Sonic hedgehog (Shh)
and Wingless-type MMTV integration site (Wnt)
pathways have been reported to play significant roles.
Recently, the phenotype of mice deficient in
Epiprofin/Sp6 (Epfn) has been found to present striking
dental abnormalities, including a complete lack of
differentiated ameloblasts and consequently no enamel,
highly altered molar cusp patterns and the formation of
multiple supernumerary teeth. In this article, we review
the interaction of Epfn with the BMP, Shh and Wnt
pathways in the regulation of tooth development, based
on the data obtained from the study of several
genetically modified mice
Epiprofin/Sp6 regulates Wnt-BMP signaling and the establishment of cellular junctions during the bell stage of tooth development
Epiprofin/Specificity Protein 6 (Epfn) is a Krüppel-like family (KLF) transcription factor that is critically involved in tooth morphogenesis and dental cell differentiation. However, its mechanism of action is still not fully understood. We have employed both loss-of-function and gain-of-function approaches to address the role of Epfn in the formation of cell junctions in dental cells and in the regulation of junction-associated signal transduction pathways. We have evaluated the expression of junction proteins in bell-stage incisor and molar tooth sections from Epfn(-/-) mice and in dental pulp MDPC-23 cells overexpressing Epfn. In Epfn(-/-) mice, a dramatic reduction occurs in the expression of tight junction and adherens junction proteins and of the adherens-junction-associated β-catenin protein, a major effector of canonical Wnt signaling. Loss of cell junctions and β-catenin in Epfn(-/-) mice is correlated with a clear decrease in bone morphogenetic protein 4 (BMP-4) expression, a decrease in nestin in the tooth mesenchyme, altered cell proliferation, and failure of ameloblast cell differentiation. Overexpression of Epfn in MDPC-23 cells results in an increased cellular accumulation of β-catenin protein, indicative of upregulation of canonical Wnt signaling. Together, these results suggest that Epfn enhances canonical Wnt/β-catenin signaling in the developing dental pulp mesenchyme, a condition that promotes the activity of other downstream signaling pathways, such as BMP, which are fundamental for cellular induction and ameloblast differentiation. These altered signaling events might underlie some of the most prominent dental defects observed in Epfn(-/-) mice, such as the absence of ameloblasts and enamel, and might throw light on developmental malformations of the tooth, including hyperdontia