Non‐resorbing osteoclasts induce migration and osteogenic differentiation of mesenchymal stem cells

Kreja, Ludwika; Brenner, Rolf E.; Tautzenberger, Andrea; Liedert, Astrid; Friemert, Benedikt; Ehrnthaller, Christian; Huber‐Lang, Markus; Ignatius, Anita

doi:10.1002/jcb.22406

Cited by 52 publications

(48 citation statements)

References 45 publications

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“…A distinct feedback of the osteoclasts on osteoblasts is shown for the gene expression of BSP II, which is clearly most intensive for modifications III and IV -the only modifications which facilitated the formation of large C Heinemann et al Osteoblast/osteoclast co-culture for biomaterials testing multinuclear osteoclasts. Similar results have been recently published by Kreja et al whereby BSP II mRNA expression was up-regulated after stimulation of hBMSC with conditioned media collected from human osteoclasts (Kreja et al, 2010). Taking into account both the differentiation of hBMSC and hMc, modification III seems to be best-suited for cocultivation of human osteoblasts and osteoclasts in the present case.…”

Section: Heinemann Et Al Osteoblast/osteoclast Co-culture For Biomsupporting

confidence: 91%

Development of an osteoblast/osteoclast co-culture derived by human bone marrow stromal cells and human monocytes for biomaterials testing

Heinemann

Heinemann²,

Worch³

et al. 2011

eCM

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The communication of bone-forming osteoblasts and boneresorbing osteoclasts is a fundamental requirement for balanced bone remodelling. For biomaterial research, development of in vitro models is necessary to investigate this communication. In the present study human bone marrow stromal cells and human monocytes were cultivated in order to differentiate into osteoblasts and osteoclasts, respectively. Finally, a cultivation regime was identified which firstly induces the differentiation of the human bone marrow stromal cells followed by the induction of osteoclastogenesis through the osteoblasts formed -without the external addition of the factors RANKL and M-CSF. As a feedback on osteoblasts enhanced gene expression of BSP II was detected for modifications which facilitated the formation of large multinuclear osteoclasts. Phenotype characterization was performed by biochemical methods (DNA, LDH, ALP, TRAP 5b), gene expression analysis (ALP, BSP II, RANKL, IL-6, VTNR, CTSK, TRAP, OSCAR, CALCR) as well as light microscopy, confocal laser scanning microscopy, and scanning electron microscopy. After establishing this model on polystyrene, similar positive results were obtained for cultivation on a relevant bone substitution material -a composite xerogel of silica, collagen, and calcium phosphate.

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Section: Heinemann Et Al Osteoblast/osteoclast Co-culture For Biomsupporting

confidence: 91%

Development of an osteoblast/osteoclast co-culture derived by human bone marrow stromal cells and human monocytes for biomaterials testing

Heinemann

Heinemann²,

Worch³

et al. 2011

eCM

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“…Concerning the interspecies potency of the osteogenic factors demonstrated here, Pederson et al (2008) first reported that RAW264.7 osteoclast-like cells secrete soluble sphingosine 1 phosphate (S1P) and BMP6 which can differentiate hMSC into mineralising osteoblasts. Various other osteoclast-expressed osteogenic factors such as PDGF-BB (Kreja et al, 2010), Wnt10b (Pederson et al, 2008), other BMPs (McCullough et al, 2007, and the recently identified coupling factor CTHRC1 (Takeshita et al, 2013) may have also played a role.…”

Section: Nl Davison Et Al Surface Architecture Of Tricalcium Phosphatementioning

confidence: 99%

“…Additionally, surface architecture may also impact other biological processes important for bone formation such as vasculogenesis and stem cell recruitment. Interestingly, many of the same osteogenic factors that are expressed by osteoclasts and their monocyte/macrophage precursors have also been shown to chemotactically home pre-osteoblasts (OSM, PDGF, CTHRC1) and stimulate blood vessel formation (TNF-α) (Kreja et al, 2010;Glass et al, 2011;Takeshita et al, 2013). For instance, invading macrophages signalled by the foreign body response may preferentially secrete cytokines important for both blood vessel formation and stem cell recruitment (e.g., pericytes) (Bergers and Song, 2005), followed by osteoblast/osteoclast differentiation (Fellah et al, 2010) -all in response to surface architecture.…”

Section: Nl Davison Et Al Surface Architecture Of Tricalcium Phosphatementioning

confidence: 99%

“…Given no clear evidence of osteoclast resorption and depleted Ca 2+ /P i levels in the conditioned medium, we speculate that the osteogenic effects were most likely due to osteoclast-secreted trophic factors in response to the submicrostructured surface topography. In a broader biological context, it is pertinent to note that non-resorbing osteoclasts have been identified as a source of osteogenic factors in vivo (Karsdal et al, 2007;Karsdal et al, 2008;Kreja et al, 2010), emphasising that resorption is not necessary for osteogenic signalling (Fuller et al, 2010), potentially an interesting link for non-resorbable, osteoinductive materials such as microstructured titanium. Concerning the interspecies potency of the osteogenic factors demonstrated here, Pederson et al (2008) first reported that RAW264.7 osteoclast-like cells secrete soluble sphingosine 1 phosphate (S1P) and BMP6 which can differentiate hMSC into mineralising osteoblasts.…”

Section: Nl Davison Et Al Surface Architecture Of Tricalcium Phosphatementioning

confidence: 99%

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Submicron-scale surface architecture of tricalcium phosphate directs osteogenesis in vitro and in vivo

Davison

Luo²,

Schoenmaker³

et al. 2014

eCM

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A current challenge of synthetic bone graft substitute design is to induce bone formation at a similar rate to its biological resorption, matching bone's intrinsic osteoinductivity and capacity for remodelling. We hypothesise that both osteoinduction and resorption can be achieved by altering surface microstructure of beta-tricalcium phosphate (TCP). To test this, two TCP ceramics are engineered with equivalent chemistry and macrostructure but with either submicron-or micron-scale surface architecture. In vitro, submicron-scale surface architecture differentiates larger, more active osteoclasts -a cell type shown to be important for both TCP resorption and osteogenesis -and enhances their secretion of osteogenic factors to induce osteoblast differentiation of human mesenchymal stem cells. In an intramuscular model, submicrostructured TCP forms 20 % bone in the free space, is resorbed by 24 %, and is densely populated by multinucleated osteoclast-like cells after 12 weeks; however, TCP with micron-scale surface architecture forms no bone, is essentially not resorbed, and contains scarce osteoclast-like cells. Thus, a novel submicron-structured TCP induces substantial bone formation and is resorbed at an equivalent rate, potentially through the control of osteoclast-like cells.

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“…PDGF-BB is believed to mobilize cells of mesenchymal origin, stabilize newly formed vessels and orchestrate cellular components for osteoblast differentiation 33 . It has been reported that osteoclasts secret PDGF-BB to induce migration of MSCs or osteoblasts 34–36 .…”

Section: Introductionmentioning

confidence: 99%

PDGF-BB secreted by preosteoclasts induces angiogenesis during coupling with osteogenesis

Xie

Cui

Wang

et al. 2014

Nat Med

666

701

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Osteogenesis during bone modeling and remodeling is coupled with angiogenesis. A recent study shows that the specific vessel subtype, strongly positive for CD31 and Endomucin (CD31hiEmcnhi), couples angiogenesis and osteogenesis. We found that preosteoclasts secrete platelet derived growth factor-BB (PDGF-BB), inducing CD31hiEmcnhi vessels during bone modeling and remodeling. Mice with depletion of PDGF-BB in tartrate-resistant acid phosphatase positive (TRAP+) cell lineage (Pdgfb–/–) show significantly lower trabecular and cortical bone mass, serum and bone marrow PDGF-BB concentrations, and CD31hiEmcnhi vessels compared to wild-type mice. In the ovariectomized (OVX) osteoporotic mouse model, concentrations of serum and bone marrow PDGF-BB and CD31hiEmcnhi vessels are significantly decreased. Inhibition of cathepsin K (CTSK) increases preosteoclast numbers, resulting in higher levels of PDGF-BB to stimulate CD31hiEmcnhi vessels and bone formation in OVX mice. Thus, pharmacotherapies that increase PDGF-BB secretion from preosteoclasts offer a novel therapeutic target for osteoporosis to promote angiogenesis for bone formation.

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Non‐resorbing osteoclasts induce migration and osteogenic differentiation of mesenchymal stem cells

Cited by 52 publications

References 45 publications

Development of an osteoblast/osteoclast co-culture derived by human bone marrow stromal cells and human monocytes for biomaterials testing

Development of an osteoblast/osteoclast co-culture derived by human bone marrow stromal cells and human monocytes for biomaterials testing

Submicron-scale surface architecture of tricalcium phosphate directs osteogenesis in vitro and in vivo

PDGF-BB secreted by preosteoclasts induces angiogenesis during coupling with osteogenesis

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