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Query: EC:2.7.10.1 (
ERK
)
95,504
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We have previously shown, by in situ hybridization, that fibroblast growth factor receptor 2 (FGFR2) is present in the basal layer of wound epithelium during limb regeneration in newts (Notophthalmus viridescens). In contrast,
FGFR1
expression is observed throughout the blastema mesenchyme but is distinctly absent from the wound epithelium (Poulin et al. [1993] Development 119:353-361). Sequence analysis revealed that we have isolated both the
KGFR
and bek variants of FGFR2. These two variants differ only in the second half of the last of their three (or two) Ig-like domains. In this report, we show the expression patterns of FGFR2 variants during limb regeneration by in situ hybridization. During the pre-blastema stages of regeneration, FGFR2 expression was observed in the basal layer of the wound epithelium and in the cells of the
periosteum
. The wound epithelial hybridization was observed when the
KGFR
-specific probe was used while the bek-specific probe hybridized to mRNA in the cells of the
periosteum
. As regeneration progresses to the blastema stages,
KGFR
expression continued to be observed in the basal layer of the wound epithelium with additional hybridization seen in the blastema mesenchyme closely associated with the bisected bones. The bek-specific hybridization pattern observed at this stage corresponds specifically to the mesenchymal hybridization. In the differentiation stages of regeneration, the mesenchymal expression of FGFR2 becomes restricted to the cells of the condensing cartilage and later to the perichondrium. Interestingly, there appears to be a dorsoventral gradient of the expression of both
KGFR
and bek variants of FGFR2, which are opposite each other at the later stages of regeneration. Thus, re-programming of expression of the two FGFR2 variants is required during the initial wound closure of limb regeneration. Remarkably, the expression patterns of
KGFR
and bek mimic those observed in the mouse limb bud during early embryonic development (Orr-Urtreger et al. [1993] Dev. Biol. 18:475-486). Moreover, our results suggest that the two FGFR2 variants have distinct roles in limb regeneration. Further investigation regarding the potential sources of the FGF ligands will help establish the roles that FGFs and FGFRs play in limb regeneration.
...
PMID:Re-programming of expression of the KGFR and bek variants of fibroblast growth factor receptor 2 during limb regeneration in newts (Notophthalmus viridescens). 762 94
ECK
is a member of
EPH
receptor protein-tyrosine kinase
subfamily and human B61 has been identified as the ligand for
ECK
recently. In order to better understand the roles of B61-
ECK
signalling pathway in mammalian development, we have cloned rat and mouse B61 cDNA and examined the expression pattern during rat development. Sequence analysis has revealed that there is a considerable degree of identity among rat, mouse and human B61 (98.0% between rat and mouse, 86.3% between rat and human in amino acid level). Examination of B61 mRNA expression by in situ hybridization analysis revealed tight association of B61 with endothelial cells at an early stage and epithelial cells in various tissues including lung, kidney, intestine, skin at later stage of organogenesis. In the developing skeletal system, B61 is expressed in
periosteum
, perichondrium and hypertrophic chondrocytes and osteoblasts. In the developing nervous system, expression of B61 is restricted in the neurons of dorsal root ganglia. These expression profiles of B61 in epithelial cells of various organs, developing skeletal system and dorsal root ganglia match those of
ECK
. Our data suggest that B61 plays pivotal roles in organogenesis, especially vasculogenesis/angiogenesis and epithelial cell proliferation/differentiation.
...
PMID:Molecular cloning and expression of rat and mouse B61 gene: implications on organogenesis. 767 46
Two closely related fibroblast growth factor receptors,
FGFR1
and
FGFR2
, have been cloned from a newt (Notophthalmus viridescens) limb blastema cDNA library. Sequence analysis revealed that we have isolated both the bek and
KGFR
variants of
FGFR2
. These two variants differ only in the second half of the last of their three Ig-like domains. The expression patterns of
FGFR1
and
FGFR2
during limb regeneration have been determined by in situ hybridization. During the preblastema stages of regeneration,
FGFR2
expression is observed in the basal layer of the wound epithelium and in the cells of the
periosteum
. As regeneration progresses to the blastema stages,
FGFR2
expression continues to be observed in the basal layer of the wound epithelium with additional hybridization seen in the blastema mesenchyme closely associated with the bisected bones. From the early bud to the mid-bud blastema stage,
FGFR1
expression is observed throughout the blastema mesenchyme but, unlike
FGFR2
, is distinctly absent from the wound epithelium. In the differentiation stages of regeneration, the mesenchymal expression of
FGFR2
becomes restricted to the cells of the condensing cartilage and later to the perichondrium. During these later stages of regeneration, the wound epithelium hybridization to the
FGFR2
probe is no longer observed. The expression patterns of these receptors suggest that
FGFR1
and
FGFR2
have distinct roles in limb regeneration, despite their sharing a number of the FGF ligands. Further investigation regarding the potential sources of the FGF ligands will help establish the role that FGFs and FGFRs play in limb regeneration.
...
PMID:Heterogeneity in the expression of fibroblast growth factor receptors during limb regeneration in newts (Notophthalmus viridescens). 828 92
The Apert hand is characterized by metaphyseal fusions of the metacarpals and distal phalanges, symphalangism, and soft-tissue syndactyly. More subtle skeletal anomalies of the limb characterize Pfeiffer and Crouzon syndromes. Different mutations in the fibroblast growth factor receptor 2 (FGFR2) gene cause these syndromes, and offer the opportunity to relate genotype to phenotype. The expression of
FGFR1
and of the
Bek
and
KGFR
isoforms of FGFR2 has, therefore, been studied in human hand development at 12 weeks by in situ hybridization. FGFRs are differentially expressed in the mesenchyme and skeletal elements during endochondral ossification of the developing human hand.
KGFR
expression characterizes the metaphyseal
periosteum
and interphalangeal joints.
FGFR1
is preferentially expressed in the diaphyses, whereas FGFR2-
Bek
expression characterizes metaphyseal and diaphyseal elements, and the interdigital mesenchyme. Apert metaphyseal synostosis and symphalangism reflect
KGFR
expression, which has independently been quantitatively related ex vivo to the severity of clinical digital presentations in these syndromes. Studies in avian development implicate FGF signaling in preventing interdigital apoptosis and maintaining the interdigital mesenchyme. Herein is proposed that in human FGFR syndromes the balance of signaling by means of
KGFR
and
Bek
in digital development determines the clinical severity of soft-tissue and bony syndactyly.
...
PMID:Differential expression of fibroblast growth factor receptors in human digital development suggests common pathogenesis in complex acrosyndactyly and craniosynostosis. 1133 97
Endochondral ossification is multistep process that is regulated by a complex network of signalling systems. Endochondral ossification is initiated with the condensation of chondrocytes into cartilage elements in which the chondrocytes subsequently progress through stages of proliferation and hypertrophic differentiation. Finally, terminally differentiated chondrocytes undergo apoptosis and are replaced by bone. As hypertrophic differentiation links chondrocyte proliferation with the ossification of the skeletal elements it seems to be one of the critical steps in this process (Fig. 5). Ihh and PTHrP are two signalling molecules that interact in a negative feedback loop regulating the pace of hypertrophic differentiation. In addition Ihh has recently been shown to independently regulate chondrocyte proliferation and the ossification process, thus coordinating three different steps of endochondral bone formation. Two other groups of signalling molecules have been found to interact with Ihh during endochondral ossification. BMP signalling seems to act downstream of Ihh. BMPs might serve as secondary signals downstream of Ihh mediating the Ihh signals to the periarticular perichondrium to induce PTHrP. Alternatively BMP signalling, induced by Ihh, might reciprocally act back on the prehypertrophic chondrocytes, thereby coordinating hypertrophic differentiation with the differentiation of the
periosteum
. The idea of an interaction of the two signalling systems is supported by the fact that not only BMPs but also their receptors and at least two of the BMP antagonist are expressed in regions that are thought to be targets of Ihh signalling. A third signalling pathway critical for proper bone development is signalling through the
FGFR3
, which seem to act upstream of both Ihh and BMP signalling. In summary, it becomes more and more obvious that the single steps of endochondral ossification are tightly coordinated. For example signals from the joint region of the cartilage elements play an important role in regulating both chondrocyte proliferation and differentiation and at least some of these signals seem to interact with signals from the hypertrophic region, linking hypertrophic differentiation and proliferation. In addition, signals from the perichondrium/
periosteum
are thought to interact with signals from the differentiating chondrocytes to coordinate the differentiation of the
periosteum
with hypertrophic differentiation. Although significant progress has been made during the last years in analysing the signals regulating endochondral ossification in the developing embryo, complete understanding of the control system will require further extensive studies.
...
PMID:Interaction of growth factors regulating chondrocyte differentiation in the developing embryo. 1168 Jun 74
In adult animals, bone marrow is the major site of blood cell production, which is controlled by interactions between the local stroma and blood cell progenitors. The endosteal/subendosteal environment comprises bone-lining and adjacent reticular cells and sustains haemopoietic stem cell (HSC) self-renewal, proliferation and differentiation. We have questioned the specific role of each of these stroma cells in controlling HSC fate. We have isolated two distinct stroma-cell populations containing subendosteal reticulocytes (F-RET) and osteoblasts (F-OST) from
periosteum
-free fragments of murine femurs by a two-step collagenase-digestion procedure. Both populations produce similar extracellular matrix (collagen I, laminin, fibronectin, decorin), except for collagen IV, which is low in F-OST. They also express osteogenic markers: osteopontin, osteonectin, bone sialoprotein and alkaline phosphatase (ALP). The quantity and activity of ALP are however higher in F-OST. When co-cultured with bone marrow mononuclear cells or lineage-negative haemopoietic progenitors, F-OST stroma induces low proliferation and high maintenance of early haemopoietic progenitors, whereas F-
RET
stroma induces high short-term proliferation and differentiation. Analysis by reverse transcription/polymerase chain reaction has revealed higher levels of Jagged-1 expression by F-OST cells than by the F-
RET
population. Thus, two adjacent stroma cells (subendosteal and endosteal) play distinct roles in controlling the stem-cell capacity and fate of HSC and probably contribute distinctly to HSC niche formation.
...
PMID:Bone marrow subendosteal microenvironment harbours functionally distinct haemosupportive stromal cell populations. 1557 25
Apert syndrome (AS), a severe form of craniosynostosis, is caused by dominant gain-of-function mutations in
FGFR2
. Because the
periosteum
contribution to AS cranial pathophysiology is unknown, we tested the osteogenic potential of AS periosteal cells (p.Ser252Trp mutation) and observed that these cells are more committed toward the osteoblast lineage. To delineate the gene expression profile involved in this abnormal behavior, we performed a global gene expression analysis of coronal suture periosteal cells from seven AS patients (p.Ser252Trp), and matched controls. We identified 263 genes with significantly altered expression in AS samples (118 upregulated, 145 downregulated; SNR >or= |0.4|, P <or= 0.05). Several upregulated genes are involved in positive regulation of cell proliferation and nucleotide metabolism, whereas several downregulated genes are involved in inhibition of cell proliferation, gene expression regulation, cell adhesion, and extracellular matrix organization, and in PIK3-MAPK cascades. AS expression profile was confirmed through real-time PCR of a selected set of genes using RNAs from AS and control cells as well as from control cells treated with high FGF2 concentration, and through the analysis of genes involved in FGF-FGFR signaling. Our results allowed us to: (a) suggest that AS periosteal cells present enhanced osteogenic potential, (b) unravel a specific gene expression signature characteristic of AS periosteal cells which may be associated with their osteogenic commitment, (c) identify a set of novel genes involved in the pathophysiology of AS or other craniosynostotic conditions, and (d) suggest for the first time that the
periosteum
might be involved in the pathophysiology of AS.
...
PMID:Apert p.Ser252Trp mutation in FGFR2 alters osteogenic potential and gene expression of cranial periosteal cells. 1762 1
To address the functions of
FGFR2
and
FGFR3
signaling during mandibular skeletogenesis, we over-expressed in the developing chick mandible, replication-competent retroviruses carrying truncated FGFR2c or FGFR3c that function as dominant negative receptors (RCAS-dnFGFR2 and RCAS-dnFGFR3). Injection of RCAS-dnFGFR3 between HH15 and 20 led to reduced proliferation, increased apoptosis, and decreased differentiation of chondroblasts in Meckel's cartilage. These changes resulted in the formation of a hypoplastic mandibular process and truncated Meckel's cartilage. This treatment also affected the proliferation and survival of osteoprogenitor cells in osteogenic condensations, leading to the absence of five mandibular bones on the injected side. Injection of RCAS-dnFGFR2 between HH15 and 20 or RCAS-dnFGFR3 at HH26 did not affect the morphogenesis of Meckel's cartilage but resulted in truncations of the mandibular bones. RCAS-dnFGFR3 affected the proliferation and survival of the cells within the
periosteum
and osteoblasts. Together these results demonstrate that
FGFR3
signaling is required for the elongation of Meckel's cartilage and
FGFR2
and
FGFR3
have roles during intramembranous ossification of mandibular bones.
...
PMID:Roles of FGFR3 during morphogenesis of Meckel's cartilage and mandibular bones. 1833 67
The
periosteum
is now widely recognized as a homeostatic and therapeutic target for actions of sex steroids and intermittent PTH administration. The mechanisms by which estrogens suppress but PTH promotes periosteal expansion are not known. In this report, we show that intermittent PTH(1-34) promotes differentiation of periosteal osteoblast precursors as evidenced by the stimulation of the expression or activity of alkaline phosphatase as well as of targets of the bone morphogenetic protein 2 (BMP-2) and Wnt pathways. In contrast, 17beta-estradiol (E2) had no effect by itself. However, it attenuated PTH- or BMP-2-induced differentiation of primary periosteal osteoblast progenitors. Administration of intermittent PTH to ovariectomized mice induced rapid phosphorylation of the BMP-2 target Smad1/5/8 in the
periosteum
. A replacement dose of E2 had no effect by itself but suppressed PTH-induced phosphorylation of Smad1/5/8. In contrast to its effects to stimulate periosteal osteoblast differentiation, PTH promoted and subsequently suppressed proliferation of periosteal osteoblast progenitors in vitro and in vivo. E2 promoted proliferation and attenuated the antiproliferative effect of PTH. Both hormones protected periosteal osteoblasts from apoptosis induced by various proapoptotic agents. These observations suggest that the different effects of PTH and estrogens on the
periosteum
result from opposing actions on the recruitment of early periosteal osteoblast progenitors. Intermittent PTH promotes osteoblast differentiation from
periosteum
-derived mesenchymal progenitors through
ERK
-, BMP-, and Wnt-dependent signaling pathways. Estrogens promote proliferation of early osteoblast progenitors but inhibit their differentiation by osteogenic agents such as PTH or BMP-2.
...
PMID:Differentiation and proliferation of periosteal osteoblast progenitors are differentially regulated by estrogens and intermittent parathyroid hormone administration. 1861 6
Chick and mouse embryos with heritable deficiencies of aggrecan exhibit severe dwarfism and premature death, demonstrating the essential involvement of aggrecan in development. The aggrecan-deficient nanomelic (nm) chick mutant E12 fully formed growth plate (GP) is devoid of matrix and exhibits markedly altered cytoarchitecture, proliferative capacity, and degree of cell death. While differentiation of chondroblasts to pre-hypertrophic chondrocytes (IHH expression) is normal up to E6, the extended
periosteum
expression pattern of PTCH (a downstream effector of IHH) indicates altered propagation of IHH signaling, as well as accelerated down-regulation of
FGFR3
expression, decreased BrdU incorporation and higher levels of
ERK
phosphorylation, all indicating early effects on FGF signaling. By E7 reduced IHH expression and premature expression of COL10A1 foreshadow the acceleration of hypertrophy observed at E12. By E8, exacerbated co-expression of IHH and COL10A1 lead to delayed separation and establishment of the two GPs in each element. By E9, increased numbers of cells express P-SMAD1/5/8, indicating altered BMP signaling. These results indicate that the IHH, FGF and BMP signaling pathways are altered from the very beginning of GP formation in the absence of aggrecan, thereby inducing premature hypertrophic chondrocyte maturation, leading to the nanomelic long bone growth disorder.
...
PMID:Aggrecan modulation of growth plate morphogenesis. 1926 44
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