a b s t r a c tAlthough anti-tumor necrosis factor (TNF)-a treatments efficiently block inflammation in ankylosing spondylitis (AS), they are inefficient to prevent excessive bone formation. In AS, ossification seems more prone to develop in sites where inflammation has resolved following anti-TNF therapy, suggesting that TNF-a indirectly stimulates ossification. In this context, our objectives were to determine and compare the involvement of Wnt proteins, which are potent growth factors of bone formation, in the effects of TNF-a on osteoblast function. In human mesenchymal stem cells (MSCs), TNF-a significantly increased the levels of Wnt10b and Wnt5a. Associated with this effect, TNF-a stimulated tissue-non specific alkaline phosphatase (TNAP) and mineralization. This effect was mimicked by activation of the canonical bcatenin pathway with either anti-Dkk1 antibodies, lithium chloride (LiCl) or SB216763. TNF-a reduced, and activation of b-catenin had little effect on expression of osteocalcin, a late marker of osteoblast differentiation. Surprisingly, TNF-a failed to stabilize b-catenin and Dkk1 did not inhibit TNF-a effects. In fact, Dkk1 expression was also enhanced in response to TNF-a, perhaps explaining why canonical signaling by Wnt10b was not activated by TNF-a. However, we found that Wnt5a also stimulated TNAP in MSCs cultured in osteogenic conditions, and increased the levels of inflammatory markers such as COX-2. Interestingly, treatment with anti-Wnt5a antibodies reduced endogenous TNAP expression and activity. Collectively, these data suggest that increased levels of Dkk1 may blunt the autocrine effects of Wnt10b, but not that of Wnt5a, acting through non-canonical signaling. Thus, Wnt5a may be potentially involved in the effects of inflammation on bone formation.
A three-step detergent-mediated reconstitution has been applied to the incorporation of a glycosylphosphatidylinositol -protein into liposomes. The protein studied was alkaline phosphatase from bovine intestine. Liposomes prepared by dialysis were treated with various amounts of two detergents, either n-octyl j3-D-glucoside or Triton X-100. At different steps of the solubilization process, protein was added and the detergent was removed by hydrophobic resins. The most efficient reconstitutions were obtained with an octyl glucoside concentration corresponding to the onset of liposome solubilization and with a Triton X-100 concentration leading to partial solubilization of the liposomes. The involvement of the glycosyl-phosphatidylinositol anchor in alkaline phosphatase reconstitution was demonstrated by the inability of phosphoinositol-specific phospholipase-C-hydrolysed alkaline phosphatase to incorporate into liposomes. Between 70-85% of the protein associated with liposomes were anchored in the outer leaflet of the bilayer, oriented towards the outside of the liposome. The remainder was trapped within the lumen of the liposomes.
Lipid composition and fatty acid analysis of the major classes of membrane phospholipids were determined during myogenic differentiation of L6 skeletal muscle cells. The cholesterol to glycerophospholipids ratio decreased during differentiation, both in total (TM) and detergent-resistant membranes (DRM). Analyses of the membrane lipids showed that differentiation had a major impact on the molecular composition of glycerophospholipids. A significant decrease in the concentration of saturated fatty acids was detected in glycerophospholipid classes, and to a lesser extent in sphingolipids, while the concentration of 16:1n-7, 18:1n-7 and 18:1n-9 increased. At the same time, the concentration of long polyunsaturated fatty acid chains decreased in TM and DRM glycerophospholipids, resulting in a lower saturated to unsaturated fatty acid ratio in myotubes as compared to myoblasts. Interestingly, the observed n-3/n-6 ratio was lower in differentiated cell membranes. PUFA supplementation of L6 cells led to an increase in myogenic differentiation correlated to an incorporation of added PUFAs in TM and DRM glycerophospholipids. As expected after n-3 PUFA supplementation, the n-3/n-6 ratio was clearly increased in TM and, surprisingly, this was also the case in isolated DRM. n-3 and n-6 PUFAs significantly and time-dependently increased the phosphorylation of kinase p70S6K1 during myogenic differentiation, revealing the activation of the upstream kinase mTORC1, a major regulator of cell cycle and protein translation. In contrast, PUFAs did not affect the phosphorylation of the kinase Akt, another pivotal regulator of cell metabolism. These results suggest that PUFA supplementation modified the membrane lipid composition and affected the differentiation of L6 cells.
Atherosclerotic plaque calcification varies from early, diffuse microcalcifications to a bone-like tissue formed by endochondral ossification. Recently, a paradigm has emerged suggesting that if the bone metaplasia stabilizes the plaques, microcalcifications are harmful. Tissue-nonspecific alkaline phosphatase (TNAP), an ectoenzyme necessary for mineralization by its ability to hydrolyze inorganic pyrophosphate (PP), is stimulated by inflammation in vascular smooth muscle cells (VSMCs). Our objective was to determine the role of TNAP in trans-differentiation of VSMCs and calcification. In rodent MOVAS and A7R5 VSMCs, addition of exogenous alkaline phosphatase (AP) or TNAP overexpression was sufficient to stimulate the expression of several chondrocyte markers and induce mineralization. Addition of exogenous AP to human mesenchymal stem cells cultured in pellets also stimulated chondrogenesis. Moreover, TNAP inhibition with levamisole in mouse primary chondrocytes dropped mineralization as well as the expression of chondrocyte markers. VSMCs trans-differentiated into chondrocyte-like cells, as well as primary chondrocytes, used TNAP to hydrolyze PP, and PP provoked the same effects as TNAP inhibition in primary chondrocytes. Interestingly, apatite crystals, associated or not to collagen, mimicked the effects of TNAP on VSMC trans-differentiation. AP and apatite crystals increased the expression of BMP-2 in VSMCs, and TNAP inhibition reduced BMP-2 levels in chondrocytes. Finally, the BMP-2 inhibitor noggin blocked the rise in aggrecan induced by AP in VSMCs, suggesting that TNAP induction in VSMCs triggers calcification, which stimulates chondrogenesis through BMP-2. Endochondral ossification in atherosclerotic plaques may therefore be induced by crystals, probably to confer stability to plaques with microcalcifications.
Tissue-nonspecific alkaline phosphatase (TNAP) is necessary for skeletal mineralization by its ability to hydrolyze the mineralization inhibitor inorganic pyrophosphate (PP i ), which is mainly generated from extracellular ATP by ectonucleotide pyrophosphatase phosphodiesterase 1 (NPP1). Since children with TNAP deficiency develop bone metaphyseal auto-inflammations in addition to rickets, we hypothesized that TNAP also exerts anti-inflammatory effects relying on the hydrolysis of pro-inflammatory adenosine nucleotides into the anti-inflammatory adenosine. We explored this hypothesis in bone metaphyses of 7-day-old Alpl +/− mice (encoding TNAP), in mineralizing hypertrophic chondrocytes and osteoblasts, and non-mineralizing mesenchymal stem cells (MSCs) and neutrophils, which express TNAP and are present, or can be recruited in the metaphysis. Bone metaphyses of 7-day-old Alpl +/− mice had significantly increased levels of Il-1β and Il-6 and decreased levels of the anti-inflammatory Il-10 cytokine as compared with Alpl +/+ mice. In bone metaphyses, murine hypertrophic chondrocytes and osteoblasts, Alpl mRNA levels were much higher than those of the adenosine nucleotidases Npp1, Cd39 and Cd73. In hypertrophic chondrocytes, inhibition of TNAP with 25 μM of MLS-0038949 decreased the hydrolysis of AMP and ATP. However, TNAP inhibition did not significantly modulate ATP-and adenosineassociated effects in these cells. We observed that part of TNAP proteins in hypertrophic chondrocytes was sent from the cell membrane to matrix vesicles, which may explain why TNAP participated in the hydrolysis of ATP but did not significantly modulate its autocrine proinflammatory effects. In MSCs, TNAP did not participate in ATP hydrolysis nor in secretion of
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