SIRT1/FOXO3a axis plays an important role in the prevention of mandibular bone loss induced by 1,25(OH)₂D deficiency

Abstract: It has been reported that 1,25 dihydroxyvitamin D [1,25(OH) 2 D] deficiency leads to the loss of mandibular bone, however the mechanism is unclear. We investigated whether the Sirt1/FOXO3a signaling pathway is involved in this process. Using a 1,25(OH) 2 D deficiency model induced by genetic deletion in mice of 25-hydroxyvitamin D-1α hydroxylase [1α(OH)ase -/- mice]. We first documented a sharp reduction of expression levels of Sirt1 in the 1… Show more

“…Moreover, our results also showed that SIRT1 inhibition stimulated BM-MSCs’ cellular senescence, in agreement with previous studies evidencing SIRT1′s contribution to the prevention of MSCs’ senescence [ 42 , 65 , 66 , 67 ]. However, our results did not confirm the findings showing that vitamin-D3-mediated inhibition of senescence involves SIRT1 activation as it does in endothelial cells [ 68 , 69 ] and human-mandible-derived BM-MSCs [ 43 ]. Specifically, even in the presence of EX-527, VD3 led to the significant inhibition of BM-MSC senescence, indicating that VD3 exerted its anti-senescence effects in BM-MSCs via activation of other signaling pathways, which should be clarified in future studies.…”

“…During the past decade, many studies have indicated an important role of SIRT1 signaling in MSC self-renewal, demonstrating its protective effects against DNA damage, reactive oxygen species, and various inflammatory and apoptotic stimuli [ 22 ]. Moreover, SIRT1 has been implicated in the promotion of murine and human BM-MSCs’ proliferation, and its role in bone homeostasis is generally well documented [ 37 , 42 , 43 , 44 ]. It has been also shown that vitamin D3 exerts its effects on MSCs by increasing SIRT1 expression via VDR-mediated transcription [ 43 , 45 ].…”

“…Moreover, SIRT1 has been implicated in the promotion of murine and human BM-MSCs’ proliferation, and its role in bone homeostasis is generally well documented [ 37 , 42 , 43 , 44 ]. It has been also shown that vitamin D3 exerts its effects on MSCs by increasing SIRT1 expression via VDR-mediated transcription [ 43 , 45 ]. Accordingly, our results confirmed the ability of VD3 to stimulate the expression of SIRT1, as well as its downstream target FoxO3, in BM-MSCs.…”

Vitamin D3 Stimulates Proliferation Capacity, Expression of Pluripotency Markers, and Osteogenesis of Human Bone Marrow Mesenchymal Stromal/Stem Cells, Partly through SIRT1 Signaling

“…Moreover, our results also showed that SIRT1 inhibition stimulated BM-MSCs’ cellular senescence, in agreement with previous studies evidencing SIRT1′s contribution to the prevention of MSCs’ senescence [ 42 , 65 , 66 , 67 ]. However, our results did not confirm the findings showing that vitamin-D3-mediated inhibition of senescence involves SIRT1 activation as it does in endothelial cells [ 68 , 69 ] and human-mandible-derived BM-MSCs [ 43 ]. Specifically, even in the presence of EX-527, VD3 led to the significant inhibition of BM-MSC senescence, indicating that VD3 exerted its anti-senescence effects in BM-MSCs via activation of other signaling pathways, which should be clarified in future studies.…”

“…During the past decade, many studies have indicated an important role of SIRT1 signaling in MSC self-renewal, demonstrating its protective effects against DNA damage, reactive oxygen species, and various inflammatory and apoptotic stimuli [ 22 ]. Moreover, SIRT1 has been implicated in the promotion of murine and human BM-MSCs’ proliferation, and its role in bone homeostasis is generally well documented [ 37 , 42 , 43 , 44 ]. It has been also shown that vitamin D3 exerts its effects on MSCs by increasing SIRT1 expression via VDR-mediated transcription [ 43 , 45 ].…”

“…Moreover, SIRT1 has been implicated in the promotion of murine and human BM-MSCs’ proliferation, and its role in bone homeostasis is generally well documented [ 37 , 42 , 43 , 44 ]. It has been also shown that vitamin D3 exerts its effects on MSCs by increasing SIRT1 expression via VDR-mediated transcription [ 43 , 45 ]. Accordingly, our results confirmed the ability of VD3 to stimulate the expression of SIRT1, as well as its downstream target FoxO3, in BM-MSCs.…”

Vitamin D3 Stimulates Proliferation Capacity, Expression of Pluripotency Markers, and Osteogenesis of Human Bone Marrow Mesenchymal Stromal/Stem Cells, Partly through SIRT1 Signaling

“…The dental volume, reparative dentin volume, and dentin sialoprotein immunopositive areas were also reduced in 1α(OH)ase −/− mice, ( 37 ) and in the mandibles of 1α(OH)ase −/− mice, the cortical thickness, dental alveolar bone volume, and osteoblast number were also all decreased significantly, with accelerated alveolar bone loss. ( 38 ) The SIRT1/FOXO3a signaling axis appears to play an important role in the prevention of mandibular bone loss by 1,25(OH) 2 D. ( 39 )…”

“…The dental volume, reparative dentin volume, and dentin sialoprotein immunopositive areas were also reduced in 1α(OH)ase −/− mice, (37) and in the mandibles of 1α(OH)ase −/− mice, the cortical thickness, dental alveolar bone volume, and osteoblast number were also all decreased significantly, with accelerated alveolar bone loss. (38) The SIRT1/FOXO3a signaling axis appears to play an important role in the prevention of mandibular bone loss by 1,25(OH) 2 D. (39) Effects on skeletal aging Bone mineral density, bone volume, Cyp27b1 renal protein expression, and circulating 1,25(OH) 2 D all decrease progressively with age in haploinsufficient 1α(OH)ase +/− mice, and Cyp27b1 gene haploinsufficiency accelerated age-related bone loss and an osteoporotic phenotype, accompanied by declining osteoblastic bone formation and increasing osteoclastic bone resorption. (40) The INK4a/ARF locus encodes the INK4 family of cyclindependent kinase inhibitors, including p16 INK4a , and a tumor suppressor p19/p14 ARF .…”

Probing the Scope and Mechanisms of Calcitriol Actions Using Genetically Modified Mouse Models

A novel PDIA3/FTO/USP20 positive feedback regulatory loop induces osteogenic differentiation of preosteoblast in osteoporosis