Wnt inhibitory factor 1 is epigenetically silenced in human osteosarcoma, and targeted disruption accelerates osteosarcomagenesis in mice
Maya Kansara, … , Igor B. Dawid, David M. Thomas
Maya Kansara, … , Igor B. Dawid, David M. Thomas
Published March 23, 2009
Citation Information: J Clin Invest. 2009;119(4):837-851. https://doi.org/10.1172/JCI37175.
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Research Article

Wnt inhibitory factor 1 is epigenetically silenced in human osteosarcoma, and targeted disruption accelerates osteosarcomagenesis in mice

Abstract

Wnt signaling increases bone mass by stimulating osteoblast lineage commitment and expansion and forms the basis for novel anabolic therapeutic strategies being developed for osteoporosis. These strategies include derepression of Wnt signaling by targeting secreted Wnt pathway antagonists, such as sclerostin. However, such therapies are associated with safety concerns regarding an increased risk of osteosarcoma, the most common primary malignancy of bone. Here, we analyzed 5 human osteosarcoma cell lines in a high-throughput screen for epigenetically silenced tumor suppressor genes and identified Wnt inhibitory factor 1 (WIF1), which encodes an endogenous secreted Wnt pathway antagonist, as a candidate tumor suppressor gene. In vitro, WIF1 suppressed β-catenin levels in human osteosarcoma cell lines, induced differentiation of human and mouse primary osteoblasts, and suppressed the growth of mouse and human osteosarcoma cell lines. Wif1 was highly expressed in the developing and mature mouse skeleton, and, although it was dispensable for normal development, targeted deletion of mouse Wif1 accelerated development of radiation-induced osteosarcomas in vivo. In primary human osteosarcomas, silencing of WIF1 by promoter hypermethylation was associated with loss of differentiation, increased β-catenin levels, and increased proliferation. These data lead us to suggest that derepression of Wnt signaling by targeting secreted Wnt antagonists in osteoblasts may increase susceptibility to osteosarcoma.

Authors

Maya Kansara, Michael Tsang, Laurent Kodjabachian, Natalie A. Sims, Melanie K. Trivett, Mathias Ehrich, Alexander Dobrovic, John Slavin, Peter F.M. Choong, Paul J. Simmons, Igor B. Dawid, David M. Thomas

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Figure 7

Expression patterns and epigenetic silencing of WIF1 in human osteosarcoma.

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Expression patterns and epigenetic silencing of WIF1 in human osteosarco...
(A) RT-PCR showing expression of WIF1 transcript in primary human osteoblasts, and lost in primary human osteosarcoma samples. hGAPDH, human GAPDH. (B) Immunohistochemical staining for WIF1 and β-catenin in normal bone and osteosarcomas. A tissue microarray was probed with antibodies to WIF1. Arrow indicates normal osteoblast. Original magnification, ×20. (C) Heatmap clustering of 30 primary osteosarcomas using differentiation and proliferation gene cassettes. Cluster A is a gene cassette of intermediate osteoblastic lineage, cluster B contains proliferation markers, and cluster C is a gene cassette of an osteoblastic phenotype. (D) Heatmap demonstrating unsupervised hierarchical clustering of CpG methylation in primary human osteoblast cultures (green), osteosarcoma cell lines (red), and primary osteosarcoma samples (blue). Individual CpGs are identified by numbers above, and the approximate relationship between CpG location and the WIF1 coding region is identified below. Cluster A represents the tumor-associated methylation group, and cluster B represents the normal osteoblast methylation group. The region underlined below the heatmap, from 63,801,793 to 63,802,086, appeared to be differentially methylated. Green denotes no methylation; red denotes 100% methylation. Asterisks indicate individual CpGs whose degree of methylation significantly correlated with expression of WIF1 transcript (all P < 0.05, ANOVA). The schematic below shows the position of Wif1 exon 1 and the untranslated region (UTR) in relation to regions of methylation.