We generated Prx1CreER-GFP transgenic mice that express tamoxifen-inducible Cre recombinase and GFP under the control of a 2.4 kb Prx1 promoter. The transgene is expressed in osteochondro progenitor cells in the developing limb buds and in a subpopulation of periosteal cells that is closely associated with the cortical bone. GFP-expressing cells isolated from the diaphyses of long bones by cell sorting express multiple markers of periosteal cells, including Prx-1, Fgf18, Tenascin-W, Periostin, and Thrombospondin 2. In addition, these cells undergo chondrogenic and osteogenic differentiation in culture upon induction. Cell fate analysis using the Rosa26 LacZ reporter indicated that transgene-expressing cells give rise to some of the chondrocytes and osteoblasts in the fracture callus. Collectively, these observations strongly suggest that the transgene-expressing cells are osteochondro progenitor cells in the periosteum. The established Prx1CreER-GFP mice would offer novel approaches for analyzing the functions of periosteal cells in vitro and in vivo.
Extracellular Signal-Regulated Kinase 1 (ERK1) and ERK2 Play Essential Roles in Osteoblast Differentiation and in Supporting Osteoclastogenesis
Osteoblasts and chondrocytes arise from common osteo-chondroprogenitor cells. We show here that inactivation of ERK1 and ERK2 in osteo-chondroprogenitor cells causes a block in osteoblast differentiation and leads to ectopic chondrogenic differentiation in the bone-forming region in the perichondrium. Furthermore, increased mitogen-activated protein kinase signaling in mesenchymal cells enhances osteoblast differentiation and inhibits chondrocyte differentiation. These observations indicate that extracellular signal-regulated kinase 1 (ERK1) and ERK2 play essential roles in the lineage specification of mesenchymal cells. The inactivation of ERK1 and ERK2 resulted in reduced beta-catenin expression, suggesting a role for canonical Wnt signaling in ERK1 and ERK2 regulation of skeletal lineage specification. Furthermore, inactivation of ERK1 and ERK2 significantly reduced RANKL expression, accounting for a delay in osteoclast formation. Thus, our results indicate that ERK1 and ERK2 not only play essential roles in the lineage specification of osteo-chondroprogenitor cells but also support osteoclast formation in vivo.The extracellular signal-regulated kinase/mitogen-activated protein kinase (ERK MAPK) pathway is activated by various stimuli, including a number of growth factors and cytokines. The activation of the Raf members of MAPK kinase kinase leads to the activation of the MAPK kinase, MEK1, and MEK2. MEK1 and MEK2 then phosphorylate and activate MAPK, ERK1, and ERK2. ERK1 and ERK2 phosphorylate various cytoplasmic and nuclear target proteins, ranging from cytoplasmic adaptor proteins and transcription factors to kinases, including ribosomal S6 kinase (RSK) (4,17,18,23,36,46). In this pathway, multiple mutations that cause syndromes with various skeletal manifestations have recently been identified. Missense-activating mutations in KRAS, BRAF, MEK1, and MEK2 have been identified in Costello, Noonan, LEOPARD, and Cardio-facio-cutaneous syndromes, while loss-of-function mutations in RSK2, a kinase downstream of ERK1 and ERK2, cause Coffin-Lowry syndrome (2, 42). These observations highlight the importance of the ERK MAPK pathway in human skeletal development.Both chondrocytes and osteoblasts arise from common osteo-chondro progenitor cells. Bone growth is achieved through two major ossification processes, endochondral ossification and intramembranous ossification, in which chondrocytes and osteoblasts are involved (5,13,30,31,38). In normal endochondral ossification, the skeletal element is formed as a cartilaginous template that is subsequently replaced by bone. Condensed mesenchymal cells differentiate into chondrocytes. Chondrocytes first proliferate in columnar stacks to form the growth plate and then exit the cell cycle and differentiate into hypertrophic chondrocytes. Hypertrophic chondrocytes are removed by apoptotic cell death, and the cartilaginous matrix is resorbed by chondroclasts/osteoclasts and replaced by trabecular bone. Chondroclast/osteoclast formation is supported by receptor activator of nucl...
FGFR3 promotes synchondrosis closure and fusion of ossification centers through the MAPK pathway
Activating mutations in FGFR3 cause achondroplasia and thanatophoric dysplasia, the most common human skeletal dysplasias. In these disorders, spinal canal and foramen magnum stenosis can cause serious neurologic complications. Here, we provide evidence that FGFR3 and MAPK signaling in chondrocytes promote synchondrosis closure and fusion of ossification centers. We observed premature synchondrosis closure in the spine and cranial base in human cases of homozygous achondroplasia and thanatophoric dysplasia as well as in mouse models of achondroplasia. In both species, premature synchondrosis closure was associated with increased bone formation. Chondrocyte-specific activation of Fgfr3 in mice induced premature synchondrosis closure and enhanced osteoblast differentiation around synchondroses. FGF signaling in chondrocytes increases Bmp ligand mRNA expression and decreases Bmp antagonist mRNA expression in a MAPK-dependent manner, suggesting a role for Bmp signaling in the increased bone formation. The enhanced bone formation would accelerate the fusion of ossification centers and limit the endochondral bone growth. Spinal canal and foramen magnum stenosis in heterozygous achondroplasia patients, therefore, may occur through premature synchondrosis closure. If this is the case, then any growth-promoting treatment for these complications of achondroplasia must precede the timing of the synchondrosis closure.
Bones consist of a number of cell types including osteoblasts and their precursor cells at various stages of differentiation. To analyze cellular organization within the bone, we generated Col1a1CreER-DsRed transgenic mice that express, in osteoblasts, CreER and DsRed under the control of a mouse 3.2 kb Col1a1 promoter. We further crossed Col1a1CreER-DsRed mice with Prx1CreER-GFP mice that express CreER and GFP in osteochondro progenitor cells under the control of a 2.4 kb Prx1 promoter. Since the 3.2 kb Col1a1 promoter becomes active in osteoblasts at early stages of differentiation, and Prx1CreER-GFP-expressing periosteal cells show endogenous Col1a1 expression, we expected to find a cell population in which both the 2.4 kb Prx1 promoter and the 3.2 kb Col1a1 promoter are active. However, our histological and flow cytometric analyses demonstrated that these transgenes are expressed in distinct cell populations. In the periosteum of long bones, Col1a1CreER-DsRed is expressed in the innermost layer directly lining the bone surface, while Prx1CreER-GFP-expressing cells are localized immediately outside of the Col1a1CreER-DsRed-expressing osteoblasts. In the calvaria, Prx1CreER-GFP-expressing cells are also localized in the cranial suture mesenchyme. Our experiments further showed that Col1a1CreER-DsRed-expressing cells lack chondrogenic potential, while the Prx1CreER-GFP-expressing cells show both chondrogenic and osteogenic potential. Our results indicate that Col1a1CreER-DsRed-expressing cells are committed osteoblasts, while Prx1CreER-GFP-expressing cells are osteochondro progenitor cells. The Prx1CreER-GFP and Col1a1CreER-DsRed transgenes will offer novel approaches for analyzing lineage commitment and early stages of osteoblast differentiation under physiologic and pathologic conditions.
Pathological examination of dementia with Lewy bodies patients identified the presence of abnormal ␣-synuclein (␣Syn) aggregates in the presynaptic terminals. ␣Syn is involved in the regulation of soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) complex. Importantly, ␣Syn-transgenic mouse and postmortem examination of patients with Parkinson's disease have demonstrated the abnormal distribution of SNARE protein in presynaptic terminals. In this study, we investigated the effects of SNARE dysfunction on endogenous ␣Syn using Snap25 S187A/S187A mutant mice. These mice have homozygous knock-in gene encoding unphosphorylatable S187A-substituted synaptosomal-associated protein of 25 kDa (SNAP-25). The mice displayed a significant age-dependent change in the distribution of ␣Syn and its Ser 129 -phosphorylated form in abnormally hypertrophied glutamatergic nerve terminals in the striatum. Electron-microscopic analysis revealed the abnormally condensed synaptic vesicles with concomitant mislocalization of ␣Syn protein to the periactive zone in the glutamatergic nerve terminals. However, the Snap25 S187A/S187A mutant mouse harbored no abnormalities in the nigrostriatal dopaminergic neurons. Our present results suggest that SNARE dysfunction is the initial trigger of mislocalization and accumulation of ␣Syn, and probably is an important pathomechanism of ␣-synucleinopathies.
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