Recent advances in bone regeneration using adult stem cells

Bone is a highly vascularized tissue reliant on the close spatial and temporal association between bloodvessels and bone cells. Therefore, cells that participate in vasculogenesis and osteogenesis play a pivotal role in bone formation during prenatal and postnatal periods. Nevertheless, spontaneous healing of bone fracture is occasionally impaired due to insufficient blood and cellular supply to the site of injury. In these cases, bone regeneration process is interrupted, which might result in delayed union or even nonunion of the fracture. Nonunion fracture is difficult to treat and have a high financial impact. In the last decade, numerous technological advancements in bone tissue engineering and cell-therapy opened new horizon in the field of bone regeneration. This review starts with presentation of the biological processes involved in bone development, bone remodeling, fracture healing process and the microenvironment at bone healing sites. Then, we discuss the rationale for using adult stem cells and listed the characteristics of the available cells for bone regeneration. The mechanism of action and epigenetic regulations for osteogenic differentiation are also described. Finally, we review the literature for translational and clinical trials that investigated the use of adult stem cells(mesenchymal stem cells, endothelial progenitor cells and CD34+ blood progenitors) for bone regeneration.     

Intracellular segregation of phosphatidylinositol-3,4,5-trisphosphate by insulin-dependent actin remodeling in L6 skeletal muscle cells

Insulin stimulates glucose uptake by recruiting glucose transporter 4 (GLUT4) from an intracellular pool to the cell surface through a mechanism that is dependent on phosphatidylinositol (PI) 3-kinase (PI3-K) and cortical actin remodeling. Here we test the hypothesis that insulin-dependent actin filament remodeling determines the location of insulin signaling molecules. It has been shown previously that insulin treatment of L6 myotubes leads to a rapid rearrangement of actin filaments into submembrane structures where the p85 regulatory subunit of PI3-K and organelles containing GLUT4, VAMP2, and the insulin-regulated aminopeptidase (IRAP) colocalize. We now report that insulin receptor substrate-1 and the p110alpha catalytic subunit of PI3-K (but not p110beta) also colocalize with the actin structures. Akt-1 was also found in the remodeled actin structures, unlike another PI3-K effector, atypical protein kinase C lambda. Transiently transfected green fluorescent protein (GFP)-tagged pleckstrin homology (PH) domains of general receptor for phosphoinositides-1 (GRP1) or Akt (ligands of phosphatidylinositol-3,4,5-trisphosphate [PI-3,4,5-P(3)]) migrated to the periphery of the live cells; in fixed cells, they were detected in the insulin-induced actin structures. These results suggest that PI-3,4,5-P(3) is generated on membranes located within the actin mesh. Actin remodeling and GLUT4 externalization were blocked in cells highly expressing GFP-PH-GRP1, suggesting that PI-3,4,5-P(3) is required for both phenomena. We propose that PI-3,4,5-P(3) leads to actin remodeling, which in turn segregates p85alpha and p110alpha, thus localizing PI-3,4,5-P(3) production on membranes trapped by the actin mesh. Insulin-stimulated actin remodeling may spatially coordinate the localized generation of PI-3,4,5-P(3) and recruitment of Akt, ultimately leading to GLUT4 insertion at the plasma membrane.     

Beta‐barrel models of soluble amyloid beta oligomers and annular protofibrils

Both soluble and membrane‐bound prefibrillar assemblies of Abeta (Aβ) peptides have been associated with Alzheimer's disease (AD). The size and nature of these assemblies vary greatly and are affected by many factors. Here, we present models of soluble hexameric assemblies of Aβ42 and suggest how they can lead to larger assemblies and eventually to fibrils. The common element in most of these assemblies is a six‐stranded β‐barrel formed by the last third of Aβ42, which is composed of hydrophobic residues and glycines. The hydrophobic core β‐barrels of the hexameric models are shielded from water by the N‐terminus and central segments. These more hydrophilic segments were modeled to have either predominantly β or predominantly α secondary structure. Molecular dynamics simulations were performed to analyze stabilities of the models. The hexameric models were used as starting points from which larger soluble assemblies of 12 and 36 subunits were modeled. These models were developed to be consistent with numerous experimental results. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Tyrphostin-induced differentiation of mouse erythroleukemia cells

Inhibitors of protein-tyrosine kinases (TPKs) from the tyrphostins family induce terminal erythroid differentiation of mouse erythroleukemia (MEL) cells. The most potent tyrphostin was found to be AG-568 which was therefore investigated in more detail. Just prior to differentiation the inhibition of tyrosine phosphorylation of a pp⁹⁷ protein band was noted. We also found that AG-568 treatment induces the appearance of a putative differentiation factor which could induce tyrphostin-independent differentiation in untreated cells. Our study suggests that the inhibition of tyrosine phosphorylation by AG-568 leads to the production of differentiating factor(s) which induce the MEL cells to differentiate.     

Type I Interferons Control Proliferation and Function of the Intestinal Epithelium

Wnt pathway-driven proliferation and renewal of the intestinal epithelium must be tightly controlled to prevent development of cancer and barrier dysfunction. Although type I interferons (IFN) produced in the gut under the influence of microbiota are known for their antiproliferative effects, the role of these cytokines in regulating intestinal epithelial cell renewal is largely unknown. Here we report a novel role for IFN in the context of intestinal knockout of casein kinase 1α (CK1α), which controls the ubiquitination and degradation of both β-catenin and the IFNAR1 chain of the IFN receptor. Ablation of CK1α leads to the activation of both β-catenin and IFN pathways and prevents the unlimited proliferation of intestinal epithelial cells despite constitutive β-catenin activity. IFN signaling contributes to the activation of the p53 pathway and the appearance of apoptotic and senescence markers in the CK1α-deficient gut. Concurrent genetic ablation of CK1α and IFNAR1 leads to intestinal hyperplasia, robust attenuation of apoptosis, and rapid and lethal loss of barrier function. These data indicate that IFN play an important role in controlling the proliferation and function of the intestinal epithelium in the context of β-catenin activation.