The liver regulates ectopic calcification in Abcc6-deficient models of pseudoxanthoma elasticum
Yijie Wang, Baiming Sun, Feiyang Ma, Bo Tao, Yiqian Gu, Zhiqiang Zhou, Jason Kim, Linlin Zhang, Zhihao Liu, Johanna ten Hoeve, Linsey Stiles, Lucia Fernandez del Rio, Calvin Pan, Orian Shirihai, Shili Xu, Thomas G. Graeber, Tamer Sallam, Matteo Pellegrini, Aldons J. Lusis, Arjun Deb
Yijie Wang, Baiming Sun, Feiyang Ma, Bo Tao, Yiqian Gu, Zhiqiang Zhou, Jason Kim, Linlin Zhang, Zhihao Liu, Johanna ten Hoeve, Linsey Stiles, Lucia Fernandez del Rio, Calvin Pan, Orian Shirihai, Shili Xu, Thomas G. Graeber, Tamer Sallam, Matteo Pellegrini, Aldons J. Lusis, Arjun Deb
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Research Article Cardiology Metabolism

The liver regulates ectopic calcification in Abcc6-deficient models of pseudoxanthoma elasticum

Abstract

Pseudoxanthoma Elasticum (PXE) is a rare disease caused by loss of function of the ATP-binding cassette C (ABC) member 6 (Abcc6) gene and characterized by ectopic calcification of multiple tissues, but the physiological reasons underlying ectopic calcification in PXE remain unclear. In a murine model of Abcc6-deficient PXE in which animals developed robust cardiac calcification after heart injury, we show the critical importance of the liver in mediating ectopic cardiac calcification. Tissue-specific deletion of Abcc6 in the liver, but not in the heart, was sufficient to cause post-injury cardiac calcification. Metabolomics and gene expression analysis demonstrated deficiencies in nucleotide metabolism, cellular energetics, and defects in cellular respiration underlying ectopic calcification in PXE. Functional abnormalities in cellular respiration in the injured heart were similar in animals with global or liver-specific Abcc6 deficiency, showing that hepatic Abcc6 expression regulated cellular respiration in the injured heart. We show that ectopic calcification in PXE was primarily dystrophic and that treatment with clodronate or etidronate, which prevent the growth of calcium hydroxyapatite mineralization, was sufficient to rescue the phenotype of ectopic cardiac calcification in Abcc6-deficient states. Taken together, these observations highlight the role of the liver in regulating target tissue metabolic and mitochondrial function in causing ectopic calcification in Abcc6-deficient states.

Authors

Yijie Wang, Baiming Sun, Feiyang Ma, Bo Tao, Yiqian Gu, Zhiqiang Zhou, Jason Kim, Linlin Zhang, Zhihao Liu, Johanna ten Hoeve, Linsey Stiles, Lucia Fernandez del Rio, Calvin Pan, Orian Shirihai, Shili Xu, Thomas G. Graeber, Tamer Sallam, Matteo Pellegrini, Aldons J. Lusis, Arjun Deb

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Figure 7

Clodronate inhibits cardiac calcification in animals deficient in Abcc6.

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Clodronate inhibits cardiac calcification in animals deficient in Abcc6....
(A) Heatmap showing the expression levels of a set of osteogenic genes in WT and Abcc6-KO injured heart tissue on day 3 after surgery demonstrating no significant differential expression (n = 3 in each group, P > 0.05). (B) Immunostaining for hydroxyapatite (green) and myocytes (red) in injured hearts from Abcc6-KO mice (inset shows high magnification). The arrow indicates the calcific area within the myocyte. Scale bars: 100 μm (inset: original magnification, ×60). (C) Experimental design for the administration of clodronate liposomes to Abcc6-KO animals to determine the effects on cardiac calcification. (D) Gross images 3 days after cryo-injury of hearts from Abcc6-KO mice that received PBS liposomes or clodronate liposomes (red dotted lines indicate the area of injury; arrowhead indicates the calcific lesion). Note that the animals that received clodronate liposomes showed no mineralization. (E) CT scan, (F) 3D rendering, and (G) quantitative analysis of calcium content in heart scar tissue (n = 6 in each group; mean ± SD; ***P < 0.001, by 2-tailed, unpaired Student’s t test comparing PBS liposome and clodronate liposome groups). (H and I) Histological staining of cryo-injured myocardium with (H) Von-Kossa staining and (I) corresponding quantitative analysis showing calcium deposits. Scale bars: 100 μm (n = 6 in each group; mean ± SD; ***P < 0.001, by 2-tailed, unpaired Student’s t test). (J) Immunostaining for hydroxyapatite and (K) corresponding quantitative analysis. Scale bars: 50 μm (n = 6 in each group; mean ± SD; **P < 0.01, by 2-tailed, unpaired Student’s t test). (L and M) Biochemical measurements of (L) myocardial calcium and (M) phosphate deposits in the injured region (n = 6 in each group; mean ± SD; **P < 0.01, by 2-tailed, unpaired Student’s t test, comparing PBS liposome and clodronate liposome groups).