Cloning and Targeted Deletion of the Mouse Fetuin Gene

Jahnen‐Dechent, Willi; Schinke, Thorsten; Trindl, Andreas; Müller‐Esterl, Werner; Sablitzky, Fred; Kaiser, Sibylle; Blessing, Manfred

doi:10.1074/jbc.272.50.31496

Cited by 230 publications

(201 citation statements)

References 49 publications

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“…On a structural basis, fetuin-B is clearly homologous to fetuin-A, as shown by a shared arrangement in three domains, including two cystatin-like domains D1 and D2 and a domain D3 that is itself divided into the proline-rich D3a and C-terminal D3b subdomains. All these features suggest that the exon\intron arrangement described previously for the human, rat and mouse FETUA genes, namely three exons each for D1 and D2 and a single large exon for D3 [13,39,40], is likely to be conserved in the FETUB gene. The FETUB gene assignments also argue for this view.…”

Section: Discussionmentioning

confidence: 55%

“…Consistent with the importance of fetuins in development, AHSG is involved in osteogenesis and bone resorption [11,12]. These functions have been ascribed to the capacities of AHSG to control calcium-salt precipitation in blood [13] and to accumulate in bone matrix [14] as well as to counteract a transforming growth factor-β activity required for bone mineralization [12,15]. AHSG modulates some insulin-driven and kinase-mediated signal-transduction pathways, possibly in a tissue-specific fashion [16].…”

Section: Introductionmentioning

confidence: 83%

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Fetuin-B, a second member of the fetuin family in mammals

Olivier

Soury

Ruminy

et al. 2000

Biochemical Journal

112

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A set of orthologous plasma proteins found in human, sheep, pig, cow and rodents, now collectively designated fetuin-A, constitutes the fetuin family. Fetuin-A has been identified as a major protein during fetal life and is also involved in important functions such as inhibition of the insulin receptor tyrosine kinase activity, protease inhibitory activities and development-associated regulation of calcium metabolism and osteogenesis. Furthermore, fetuin-A is a key partner in the recovery phase of an acute inflammatory response. We now describe a second protein of the fetuin family, called fetuin-B, which is found at least in human and rodents. On grounds of domain homology, overall conservation of cysteine residues and chromosomal assignments of the corresponding genes in these species, fetuin-B is unambiguously a paralogue of fetuin-A. Yet, fetuin-A and fetuin-B exhibit significant differences at the amino acid sequence level, notably including variations with respect to the archetypal fetuin-specific signature. Differences and similarities in terms of gene regulation were also observed. Indeed, studies performed during development in rat and mouse showed for the first time high expression of a member of the fetuin family in adulthood, as shown with the fetuin-B mRNA in rat. However, like its fetuin-A counterpart, the fetuin-B mRNA level is down-regulated during the acute phase of experimentally induced inflammation in rat.

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Section: Discussionmentioning

confidence: 55%

Section: Introductionmentioning

confidence: 83%

Fetuin-B, a second member of the fetuin family in mammals

Olivier

Soury

Ruminy

et al. 2000

Biochemical Journal

112

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“…In light of this in vitro evidence, early control or prevention of hyperphosphatemia may be key in reducing coronary calcification and the resulting morbidity and mortality as a result of cardiovascular disease for patients on dialysis. Matrix gla-protein (31) Arterial, valve, and cartilage calcification ␤-glucosidase (klotho) (32) Vascular calcification, rapid aging Desmin (33) Neonatal cardiomyopathy with calcification Carbonic anhydrase II (34) Vascular calcification of small arteries Fetuin (35) Decreased serum hyaluronic acid inhibitory activity Osteoprotegrin (36) Osteoporosis, vascular calcification Osteopontin (37) Increased calcification of subcutaneously implanted bioprosthetic valve tissue…”

Section: Resultsmentioning

confidence: 99%

“…It should be added that definitive data on the presence of local and systemic inhibitors of calcification have been accumulating over the past several years and come largely from studies involving gene knockout mice. These data implicate the involvement of several gene products in ectopic calcification (Table 1) (31)(32)(33)(34)(35)(36)(37) and suggest that the matrix gla-protein gene, osteoprotegrin, and osteopontin may serve as natural inhibitors of cardiovascular calcification that may be either constitutively expressed or induced to prevent ectopic calcification. Indeed, vascular calcification may involve an active and dynamic balance of procalcifying and anticalcifying mechanisms.…”

Section: Phosphate Regulation Of Smc Mineralization: An Overviewmentioning

confidence: 99%

Vascular Calcification

Giachelli

2003

Journal of the American Society of Nephrology

274

204

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Abstract. Uremic patients are prone to widespread ectopic extraskeletal calcification resulting from an imbalance of systemic inorganic phosphate (Pi). There can be serious consequences of this process, particularly when it results in the calcification of the vasculature. A recent study examined the response of cultured human aortic smooth muscle cells to varying levels of extracellular Pi. Cells that were exposed to Pi levels similar to those seen in uremic patients (Ͼ1.4 mmol/L) showed dose-dependent increases in cell culture calcium deposition. The results of this study also defined the role of elevated phosphate in transforming the vascular phenotype of these cells to an osteogenic phenotype, such that a predisposition for calcification was created. Pi-induced changes included increased expression of the osteogenic markers osteocalcin and core-binding factor-1 genes, the latter of which is considered a "master gene" critical for osteoblast differentiation. These changes occur early after exposure to high phosphate levels and seem to be mediated by a sodium-dependent phosphate co-transporter, Pit-1 (Glvr-1

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“…This serum protein carries calcium phosphate and has been shown to have a major function in preventing pathological calcification. [29][30][31] The extent of the protective mechanism by fetuin-A, however, seems to be less than that exerted by MGP, as fetuin-A-deficient mice only develop minor calcified lesions compared with the extensive calcifications in MgpÀ/À mice. 30 However, fetuin-A is closely related to the extracellular transport of MGP.…”

Section: Vk-dependent Proteins In Pxe-like Patientsmentioning

confidence: 99%

Low serum vitamin K in PXE results in defective carboxylation of mineralization inhibitors similar to the GGCX mutations in the PXE-like syndrome

Vanakker

Martin

Schurgers

et al. 2010

Laboratory Investigation

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Soft-tissue mineralization is a tightly regulated process relying on the activity of systemic and tissue-specific inhibitors and promoters of calcium precipitation. Many of these, such as matrix gla protein (MGP) and osteocalcin (OC), need to undergo carboxylation to become active. This post-translational modification is catalyzed by the gammaglutamyl carboxylase GGCX and requires vitamin K (VK) as an essential co-factor. Recently, we described a novel phenotype characterized by aberrant mineralization of the elastic fibers resulting from mutations in GGCX. Because of the resemblance with pseudoxanthoma elasticum (PXE), a prototype disorder of elastic fiber mineralization, it was coined the PXE-like syndrome. As mutations in GGCX negatively affect protein carboxylation, it is likely that inactive inhibitors of calcification contribute to ectopic mineralization in PXE-like syndrome. Because of the remarkable similarities with PXE, we performed a comparative study of various forms of VK-dependent proteins in serum, plasma (using ELISA), and dermal tissues (using immunohistochemistry) of PXE-like and PXE patients using innovative, conformation-specific antibodies. Furthermore, we measured VK serum concentrations (using HPLC) in PXE-like and PXE samples to evaluate the VK status. In PXE-like patients, we noted an accumulation of uncarboxylated Gla proteins, MGP, and OC in plasma, serum, and in the dermis. Serum levels of VK were normal in these patients. In PXE patients, we found similar, although not identical results for the Gla proteins in the circulation and dermal tissue. However, the VK serum concentration in PXE patients was significantly decreased compared with controls. Our findings allow us to conclude that ectopic mineralization in the PXE-like syndrome and in PXE results from a deficient protein carboxylation of VK-dependent inhibitors of calcification. Although in PXE-like patients this is due to mutations in the GGCX gene, a deficiency of the carboxylation co-factor VK is at the basis of the decreased activity of calcification inhibitors in PXE.

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Cloning and Targeted Deletion of the Mouse Fetuin Gene

Cited by 230 publications

References 49 publications

Fetuin-B, a second member of the fetuin family in mammals

Fetuin-B, a second member of the fetuin family in mammals

Vascular Calcification

Low serum vitamin K in PXE results in defective carboxylation of mineralization inhibitors similar to the GGCX mutations in the PXE-like syndrome

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