A pathway to bone: signaling molecules and transcription factors involved in chondrocyte development and maturation

Kozhemyakina, Elena; Lassar, Andrew B.; Zelzer, Elazar

doi:10.1242/dev.105536

Cited by 454 publications

(482 citation statements)

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“…Similarly, another previous study indicated that overexpression of Sma7 in mesenchymal progenitors (Prx1Cre) led to disturbed mesenchymal condensation associated with decreased Sox9 expression and poor cartilage formation by down-regulating the BMP-activated p38 pathway (Iwai et al 2008). TGF-b signals through Smad2/3 to interact with Sox9 and induces Sox9 transactivity; alternatively, TGF-b recruits the transcriptional coactivators CBP/p300 to increase Sox9 transactivity (Furumatsu et al 2005;Kozhemyakina et al 2015). Regardless of the little known facts about the post-translational regulation of Sox9, phosphorylation of Sox9 by protein kinase A (PKA) at Ser181 is associated with increase in transactivity (Huang et al 2001;Malki et al 2005).…”

Section: Discussionmentioning

confidence: 93%

Signaling Cascades Governing Cdc42-Mediated Chondrogenic Differentiation and Mensenchymal Condensation

Wang

et al. 2016

Genetics

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Endochondral ossification consists of successive steps of chondrocyte differentiation, including mesenchymal condensation, differentiation of chondrocytes, and hypertrophy followed by mineralization and ossification. Loss-of-function studies have revealed that abnormal growth plate cartilage of the Cdc42 mutant contributes to the defects in endochondral bone formation. Here, we have investigated the roles of Cdc42 in osteogenesis and signaling cascades governing Cdc42-mediated chondrogenic differentiation. Though deletion of Cdc42 in limb mesenchymal progenitors led to severe defects in endochondral ossification, either ablation of Cdc42 in limb preosteoblasts or knockdown of Cdc42 in vitro had no obvious effects on bone formation and osteoblast differentiation. However, in Cdc42 mutant limb buds, loss of Cdc42 in mesenchymal progenitors led to marked inactivation of p38 and Smad1/5, and in micromass cultures, Cdc42 lay on the upstream of p38 to activate Smad1/5 in bone morphogenetic protein-2-induced mesenchymal condensation. Finally, Cdc42 also lay on the upstream of protein kinase B to transactivate Sox9 and subsequently induced the expression of chondrocyte differential marker in transforming growth factor-b1-induced chondrogenesis. Taken together, by using biochemical and genetic approaches, we have demonstrated that Cdc42 is involved not in osteogenesis but in chondrogenesis in which the BMP2/Cdc42/Pak/p38/Smad signaling module promotes mesenchymal condensation and the TGF-b/Cdc42/Pak/Akt/Sox9 signaling module facilitates chondrogenic differentiation. KEYWORDS Cdc42; condensation; osteoblast; chondrocyte S EVERAL successive steps, including mesenchymal condensation of undifferentiated cells, chondrocyte differentiation, proliferation of chondrocytes, and differentiation into hypertrophic chondrocytes followed by mineralization and ossification, exist in the process of endochondral ossification (Long and Ornitz 2013). Mesenchymal condensation is a prerequisite for chondrogenesis and is facilitated by cell adhesion molecules. Upregulation of cell adhesion proteins such as N-cadherin is a hallmark of condensing cells, whereas loss of cell adhesion molecules is able to abolish condensation (Delise and Tuan 2002;Bobick et al. 2009). The molecular mechanisms governing condensation are not fully understood, though several genes have been implicated in this process such as bone morphogenic proteins (BMPs) and SRY (sex determining region Y)-box 9 (Sox9) (Fromental-Ramain et al. 1996;Wada et al. 1998;Lu et al. 2008). Conditional inactivationof Sox9 in limb mesenchymal progenitors leads to the absence of condensations, while simultaneous deletion of Bmp2 and Bmp4 in limb mesenchymes leads to the loss of zeugopod elements and to defective joint articulations (Reversade et al. 2005). During endochondral ossification, condensed cells undergo the differentiation into chondrocytes that secrete an abundance of cartilage matrices including types II, IX, and XI collagen. Sox9 is also the earliest known transcription...

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Section: Discussionmentioning

confidence: 93%

Signaling Cascades Governing Cdc42-Mediated Chondrogenic Differentiation and Mensenchymal Condensation

Wang

et al. 2016

Genetics

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“…Runx2 (Cbfa1) and Runx3 (Cbfa3) are required for chondrocyte maturation and indirectly function to enhance chondrocyte proliferation through promoting Ihh expression (Yoshida et al 2004). The balance between chondrocyte proliferation and hypertrophy is regulated by interactions between several signaling pathways, including IHH, PTH-related peptide (PTHLH), BMP, Wnt, and fibroblast growth factor (FGF) (Long and Ornitz 2013;Kozhemyakina et al 2015). The activity of Wnt and PTHLH signals regulates the level of calcium/ calmodulin-dependent protein kinase II (CAMK2), which induces chondrocyte hypertrophy in part through increasing RUNX2 and β-catenin activity Long and Ornitz 2013).…”

Section: Chondrogenesismentioning

confidence: 99%

Fibroblast growth factor signaling in skeletal development and disease

2015

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Fibroblast growth factor (FGF) signaling pathways are essential regulators of vertebrate skeletal development. FGF signaling regulates development of the limb bud and formation of the mesenchymal condensation and has key roles in regulating chondrogenesis, osteogenesis, and bone and mineral homeostasis. This review updates our review on FGFs in skeletal development published in Genes & Development in 2002, examines progress made on understanding the functions of the FGF signaling pathway during critical stages of skeletogenesis, and explores the mechanisms by which mutations in FGF signaling molecules cause skeletal malformations in humans. Links between FGF signaling pathways and other interacting pathways that are critical for skeletal development and could be exploited to treat genetic diseases and repair bone are also explored.

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“…8 Thus, in combination with the data from PTH1-34 treatments, our results demonstrate preservation in al ginate culture of the crucial functions that comprise the PTHrP IHH signaling feedback loop, a key node in the regulatory net work of growth plate cartilage. 2,5 Although treatment with IHH, PMA, or thyroxine resulted in similar effects on chondrocyte hypertrophy, we observed one crucial difference-both IHH and thryoxine treatments pro duced regional differences in chondrocyte hypertrophy in al ginate beads. Specifically, treatment with IHH or thyroxine was sufficient to stratify alginate bead cultures into an inner core consisting of nonhypertrophic (resting/proliferative) chondro cytes and an outer ring of ColXexpressing hypertrophic chon drocytes, which mimics the layered organization of growth plate cartilage in vivo.…”

Section: Ihh Signaling Establishes a Hypertrophic Zone In Alginate Cumentioning

confidence: 62%

“…1 Toward the distal (epiphyseal) end resides the resting (or reserve) zone that is composed of the least mature chondrocytes. 2 These resting zone chondrocytes are progres sively recruited into the proliferative zone, where cell cycle ac tivation and changes in cell morphology and cell organization result in expansion of isogenic columns of chondrocytes along the axis of growth. 3 As columns lengthen, chondrocytes at the proximal (meta physeal) end of the column withdraw from the cell cycle and increase in volume (hypertrophy) in two steps that are char acteristic of the prehypertrophic and the hypertrophic chon drocytes.…”

mentioning

confidence: 99%

“…8,10,[18][19][20] Therefore, crosstalk between PTHrP and IHH paracrine signaling forms the core of a feedback circuit that maintains longterm growth by balancing chondrocyte production with chondrocyte loss through endo chondral ossification. 2,5 Despite a deep understanding of the regulatory pathways that regulate growth, few options exist for clinical intervention in growth disorders. [21][22][23][24] In vitro models of growth plate car tilage that reveal the network structure of regulatory interac tions would advance both drug discovery efforts and tissue en gineering solutions for growth disorders.…”

mentioning

confidence: 99%

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A Tunable, Three-DimensionalIn VitroCulture Model of Growth Plate Cartilage Using Alginate Hydrogel Scaffolds

Erickson

Laughlin

Romereim

et al. 2018

Tissue Engineering Part A

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During embryonic and postnatal skeletal development, the shape and length of bones is determined by the activities of the growth plate cartilage. Growth plate cartilage promotes elongation of long bones via regulation of chondrocyte matura tion that is reflected in morphologically and functionally unique cellular domains. 1 Toward the distal (epiphyseal) end resides the resting (or reserve) zone that is composed of the least mature chondrocytes. 2 These resting zone chondrocytes are progres sively recruited into the proliferative zone, where cell cycle ac tivation and changes in cell morphology and cell organization result in expansion of isogenic columns of chondrocytes along the axis of growth. 3 As columns lengthen, chondrocytes at the proximal (meta physeal) end of the column withdraw from the cell cycle and increase in volume (hypertrophy) in two steps that are char acteristic of the prehypertrophic and the hypertrophic chon drocytes. 4,5 Growth is generated from chondrocyte hypertrophy through increased cell mass and deposition of specialized ma trix. 6 Hypertrophic chondrocytes are subsequently replaced by bone through the process of endochondral ossification. 7 Thus, continuous growth over the twodecade span of human devel opment requires tight coordination between cell production in the resting and proliferative zones, and cartilage loss in the hy pertrophic zone. Chondrocyte maturation in growth plate cartilage is coordi nated by a complex paracrine signaling network that is rooted AbstractDefining the final size and geometry of engineered tissues through precise control of the scalar and vector components of tissue growth is a necessary benchmark for regenerative medicine, but it has proved to be a significant challenge for tissue engineers. The growth plate cartilage that promotes elongation of the long bones is a good model system for studying morphogenetic mechanisms because cartilage is composed of a single cell type, the chondrocyte; chondrocytes are readily maintained in culture; and growth trajectory is predominately in a single vector. In this cartilage, growth is generated via a differentiation program that is spatially and temporally regulated by an interconnected network composed of long and shortrange signaling mechanisms that together result in the formation of functionally distinct cellular zones. To facilitate investigation of the mechanisms underlying anisotropic growth, we developed an in vitro model of the growth plate cartilage by using neonatal mouse growth plate chondrocytes encapsulated in alginate hydrogel beads. In bead cultures, encapsulated chondrocytes showed high viability, cartilage matrix deposition, low levels of chondrocyte hypertrophy, and a progressive increase in cell proliferation over 7 days in culture. Exogenous factors were used to test functionality of the parathyroidrelated protein-Indian hedgehog (PTHrPIHH) signaling interaction, which is a crucial feedback loop for regulation of growth. Consistent with in vivo observations, exogenous PTHrP stimulated cell pr...

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A pathway to bone: signaling molecules and transcription factors involved in chondrocyte development and maturation

Cited by 454 publications

References 206 publications

Signaling Cascades Governing Cdc42-Mediated Chondrogenic Differentiation and Mensenchymal Condensation

Signaling Cascades Governing Cdc42-Mediated Chondrogenic Differentiation and Mensenchymal Condensation

Fibroblast growth factor signaling in skeletal development and disease

A Tunable, Three-DimensionalIn VitroCulture Model of Growth Plate Cartilage Using Alginate Hydrogel Scaffolds

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