Osteocyte Neuropeptide Y Aggravates Bone Loss in OVX Mice by Inhibiting Preosteoclast Proliferation and PDGF-BB-Induced Type H Vessel Formation Through PI3K/Akt Signaling Pathway.

Osteoporosis is a disease associated with bone resorption, characterized primarily by the excessive activation of osteoclasts. Ginkgetin is a compound purified from natural ginkgo leaves which has various biological properties, including anti-inflammation, antioxidant, and anti-tumor effects. This study investigated the bone-protective effects of ginkgetin in ovariectomized (OVX) mice and explored their potential signaling pathway in inhibiting osteoclastogenesis in a mouse model of osteoporosis. Biochemical assays were performed to assess the levels of Ca, ALP, and P in the blood. Micro CT scanning was used to evaluate the impact of ginkgetin on bone loss in mice. RT-PCR was employed to detect the expression of osteoclast-related genes (ctsk, c-fos, trap) in their femoral tissue. Hematoxylin and eosin (H&E) staining was utilized to assess the histopathological changes in femoral tissue due to ginkgetin. The TRAP staining was used to evaluate the impact of ginkgetin osteoclast generation in vivo. Western blot analysis was conducted to investigate the effect of ginkgetin on the expression of p-NF-κB p65 and IκBα proteins in mice. Our findings indicate that ginkgetin may increase the serum levels of ALP and P, while decreasing the serum level of Ca in OVX mice. H&E staining and micro CT scanning results suggest that ginkgetin can inhibit bone loss in OVX mice. The TRAP staining results showed ginkgetin suppresses the generation of osteoclasts in OVX mice. RT-PCR results demonstrate that ginkgetin downregulate the expression of osteoclast-related genes (ctsk, c-fos, trap) in the femoral tissue of mice, and this effect is dose-dependent. Western blot analysis results reveal that ginkgetin can inhibit the expression of p-NF-κB p65 and IκBα proteins in mice. Ginkgetin can impact osteoclast formation and activation in OVX mice by inhibiting the NF-κB/IκBα signaling pathway, thereby attenuating bone loss in mice.

This study was to determine the bone protective effects and underlying mechanisms of Osthole (OT) in ovariectomized (OVX) mice. We found that the inhibitory effects of OT on receptor activator of nuclear factor kappa-B ligand (RANKL)-activated osteoclastogenesis are responsible for its bone protective effects in OVX mice. Eight-week-old mice were ovariectomized and OT (10 mg/kg/d) was intraperitoneally administrated to OVX mice 7 days after the surgery and were sacrificed at the end of the 3 months. Osteoclasts were generated from primary bone marrow macrophages (BMMs) to investigate the inhibitory effects of OT. The activity of RANKL-activated signaling was simultaneously analyzed in vitro and in vivo using immunohistochemistry, Western blot, and PCR assays. OT dose dependently inhibited RANKL-mediated osteoclastogenesis in BMM cultures. OT administration attenuated bone loss (mg Ha/cm: 894.68 ± 33.56 vs 748.08 ± 19.51, P < 0.05) in OVX mice. OT inhibits osteoclastogenesis (Oc.N/per view area: 72 ± 4.3 vs 0.8 ± 0.4, P < 0.05) and bone resorption activity (bone resorbed percentages %, 48.56 ± 7.25 vs 3.25 ± 1.37, P < 0.05) from BMMs. Mechanistically, OT inhibited the expressions of nuclear factor of activated T-cells c1 (NFATc1) and c-Fos. Moreover, OT suppressed the expression of RANKL-induced osteoclast marker genes, including matrix metalloproteinase 9 (MMP9), Cathepsin K (Ctsk), tartrate-resistant acid phosphatase (TRAP), and carbonic anhydrase II (Car2). OT inhibits RANKL-mediated osteoclastogenesis and prevents bone loss in OVX mice. Our findings revealed that OT is a potential new drug for treating postmenopausal osteoporosis.

More than a decade has passed since the publication of the first report implicating T cells in the bone loss induced by ovariectomy (ovx).1 Since then there has been extraordinary progress in the understanding of the regulatory network that links the hemopoietic and the mesenchymal compartments of the bone marrow (BM), the interactions between the immune system and bone, and the role of lymphocytes as mediators of the effects of calciotrophic hormones in bone. Collectively this body of knowledge has led to the firm establishment of "osteoimmunology" as a novel discipline and a promising area of investigation. The objective of this perspective is to revisit the exciting hypothesis that T cells play a pivotal role in the mechanism of ovx-induced bone loss. The bone-sparing activity of estrogens is due to a repression of bone remodeling coupled with a balancing effect on bone formation and resorption.2 The dominant acute effect of estrogen is the blockade of new osteoclast formation, cells which arise by cytokine-driven proliferation and differentiation of monocyte precursors that circulate within the hematopoietic cell.3 This process is facilitated by BM stromal cells (SCs), which provide physical support for nascent osteoclasts and produce soluble and membrane-associated factors essential for the proliferation and differentiation of osteoclast precursors. This inhibitory effect on osteoclastogenesis is associated with a repressive effect on osteoblastogenesis.4 Another critical effect of estrogen is that of increasing osteoclast apoptosis5-7 while blocking the apoptosis of osteoblasts and osteocytes.2, 8 It has been proposed that the effects of estrogens on the generation of osteoblasts and the lifespan of osteoblasts and osteoclasts result from extranuclear actions of the endoplasmic reticulum (ER) and activation of cytoplasmic kinases.2, 7 The decline of ovarian function at menopause results in decreased production of estrogen and a parallel increase in pituitary follicle-stimulating hormone (FSH) levels. The combined effects of estrogen deprivation and elevated FSH production cause a marked stimulation of bone resorption9 and a period of rapid bone loss that is central to the pathogenesis of postmenopausal osteoporosis. In mice the acute effects of menopause are modeled by ovx, a procedure that stimulates bone resorption by increasing osteoclast formation3 and lifespan.5-7 This initial phase of bone loss is followed by a slower but more prolonged loss of mainly cortical bone due to incomplete refilling of the resorption cavities due to insufficient osteoblast (OB) activity and lifespan.10 An expansion of the osteoclastic pool is therefore the key mechanism responsible for the bone loss that occurs early after ovx. The net bone loss caused by ovx is limited, in part, by an increase in bone formation resulting from stimulated osteoblastogenesis.11 This compensation is fueled by an expansion of the pool of BM–SCs, increased commitment of such pluripotent precursors toward the osteoblastic lineage,11 and enhanced proliferation of early OB precursors.4 Subsequent escalations in OB apoptosis12, 13 extensions of osteoclast lifespan5, 6 and increased secretion of cytokines that suppress bone formation, such as interleukin 7 (IL-7) and tumor necrosis factor (TNF), are the likely reasons for why bone formation does not increase as much as resorption after ovx. The stimulatory effect of ovx on SCs is equally relevant for osteoclastogenesis as one of the consequences of estrogen deprivation is the formation of osteoblastic cells with an increased osteoclastogenic activity14; ie, the capacity to support osteoclast formation. Evidence now suggests that T cells play a pivotal role in the mechanism of ovx-induced bone loss. Core observations include reports showing that ovx fails to induce trabecular and cortical bone loss in: T-cell–deficient nude mice,1, 15-17, wild-type (WT) mice deleted of T cells by injection of anti–T cell antibodies,18 mice treated with Abatacept19 (an agent that blocks T cell costimulation and induces T cell anergy and apoptosis)20, 21 and mice lacking the T cell costimulatory molecule CD40 ligand (CD40L).18 The fact that nude mice are protected against ovx-induced bone loss has been confirmed independently.22 By contrast, Lee and colleagues23 showed that nude mice are protected against the loss of cortical, but not trabecular bone induced by ovx. In another study, T-cell–deficient and B-cell–deficient mice were found to lose bone after ovx.24 The discrepancy between our reports1, 15-19, 25 and those of others23, 24 is likely explained by differences in the experimental design, the lack of B cells in some models, and compensatory mechanisms such as an increase in natural killer (NK) cells producing the osteoclastogenic factor IL-17.26 Both CD4+ and CD8+ cells have been found to play a role in ovx-induced bone loss. CD4+ cells include the TH1, Th2, and Th17 subsets. Th17 are regarded as the most osteoclastogenic subset of T CD4+ cells because they produce high levels of IL-17, receptor activator of NF-κB ligand (RANKL), and TNF, and low levels of interferon gamma (IFNγ).27, 28 The differentiation of Th17 is inhibited by estrogen via a direct effect mediated by estrogen receptor alpha (ERα).29 The role of Th17 in ovx-induced bone loss remains to be determined because one study reported that IL-17R–null mice are more susceptible to ovx-induced bone loss than controls,30 while another group found these mice to be protected from ovx-induced bone loss.26 More abundant information is available about regulatory T cells (Tregs), a population capable of suppressing the effector function of TH1, Th2, and Th17 T cells. Tregs are defined by the expression of the transcription factor FoxP3. Tregs inhibit monocyte differentiation into osteoclasts in vitro and in vivo, and blunt bone resorption31, 32 through the secretion of IL-4, IL-10, and transforming growth factor beta 1 (TGFβ1).33 Attesting to the relevance of Tregs, studies have shown that estrogen increases the relative number of Tregs.27, 34 Moreover, transgenic mice overexpressing Tregs develop progressive high bone mass due to inhibition of bone resorption, and are protected against ovx-induced bone loss.35 Moreover, adoptive transfer of Tregs into T cell–deficient mice increases bone mass, indicating that Tregs directly affect bone homeostasis without the need to engage other T cell lineages.35 Two mechanisms have been described to explain how T cells contribute to ovx-induced bone loss (Fig. 1). The first involves an increase in T cell activation, leading to enhanced production of TNF by BM T cells. The second is a regulatory crosstalk between T cells and SCs, resulting in enhanced production of osteoclastogenic cytokines by SCs. Schematic representation of the role of T cells in the mechanism by which ovx promotes osteoclastogenesis, osteoblastogenesis, and hemopoiesis. Estrogen deficiency promotes T cell activation by increasing the interaction of antigen (Ag)-loaded MHC molecules with bone marrow macrophages (BMM) and dendritic cells (DC) with the T cell receptor (TCR). The Ags are likely to be non-self peptides derived from the intestinal macrobiota. T cell activation also requires at least two costimulatory signals provided by the binding of BMM and DC-expressed CD40 and CD80 to the T cell surface molecules CD40L and CD28, respectively. A critical upstream event is the increased production of reactive oxygen species (ROS) that activate DCs by increasing their expression of CD80. The expansion of T cells in the BM is partially driven by an ovx-induced increase in the thymic output of naïve T cells. Activated T cells secrete TNF that stimulates osteoclast formation primarily by potentiating the response to RANKL. In addition, T cell–expressed CD40L and DLK1/FA-1 increase the osteoclastogenic activity of SC by blunting their secretion of OPG and augmenting their production of RANKL, M-CSF, and other proinflammatory factors. The survival of naïve T cells and some memory T cells requires the low-affinity engagement of the T cell receptor (TCR) by a diverse repertoire of self-antigens (Ags) bound to major histocompatibility complex (MHC) molecules expressed on Ag-presenting cells.36, 37 By contrast, binding of foreign Ags such as bacterial Ags with MHC molecules is followed by high-affinity interactions with TCRs that drive T cell activation. Both low-affinity interactions with self-Ags and high-affinity foreign Ag/MHC/TCR interactions are referred to as "Ag presentation." Ovx induces T cell expression of activation markers and promotes T cell proliferation, expansion, and acquisition of effector functions. These are all features of T cells exposed to foreign Ags.36 The gastrointestinal tract is colonized for life with 100 trillion indigenous bacteria, creating a diverse ecosystem known as the microbiota, whose contributions to human health are profound.38 The macrobiota is likely to represent the source of foreign Ag that drives the expansion of T cells induced by ovx. Although direct verification of a role for macrobiota in T cell expansion is still lacking, compelling supportive data are available. For example, adoptive transfer of T cells into T cell–deficient mice is followed by rapid engraftment and expansion of donor T cells into the host. This process is driven by foreign Ags.36 Attesting to a role of the macrobiota, the expansion of transferred T cells into T cell–deficient mice is greatly reduced in host mice raised in a germ-free environment.36 Moreover, mice maintained in germ-free conditions display increased bone mass due to the lack of immune cell activation.39 T cells are key inducers of bone-wasting because ovx increases T cell TNF production to a level sufficient to augment RANKL-induced osteoclastogenesis.1 This effect is due to an increased number of TNF-producing T cells15 and enhanced production of TNF per cell.18, 40 Ovx also increases the population of premature senescent CD4 + CD28–T cells,40 a lineage that produces high levels of TNF. The presence of increased levels of T cell–produced TNF in the BM of ovx animals is well documented.15, 19, 40, 41 Studies have also shown that menopause increases T cell activation and T cell production of TNF and RANKL in humans.42, 43 The role of TNF in ovx-induced bone loss has been demonstrated in multiple models. For example, ovx fails to induce bone loss in TNF-null mice and in animals lacking the p55 TNF receptor.15 Likewise, transgenic mice insensitive to TNF due to the overexpression of a soluble TNF receptor,44 and mice treated with the TNF inhibitor TNF binding protein45 are protected from ovx-induced bone loss. The specific relevance of T cell TNF production in vivo was demonstrated by the finding that although reconstitution of nude recipient mice with T cells from WT mice restores the capacity of ovx to induce bone loss, reconstitution with T cells from TNF-deficient mice does not.15 The mechanism by which estrogen deficiency expands the pool of TNF-producing T cells is summarized in Figure 1 and involves reactivation of thymic function and induction of T cell activation in the BM. T cell activation is driven by enhanced Ag presentation by macrophages and dendritic cells (DCs).46, 47 The thymus undergoes progressive structural and functional decline with age, coinciding with increased circulating sex-steroid levels at puberty.48 By middle age most parenchymal tissue is replaced by fat, and in both mice and humans fewer T cells are produced and exported to secondary lymphoid organs. However, the thymus continues to generate new T cells even into old age.49, 50 In fact, active lymphocytic thymic tissue has been documented in adults up to 107 years of age.51 Under severe T cell depletion secondary to human immunodeficiency virus (HIV) infection, chemotherapy, or bone marrow transplant, an increase in thymic output (known as thymic rebound) becomes critical for long-term restoration of T cell homeostasis. For example, middle-aged women treated with autologous bone marrow transplants develop thymic hypertrophy and a resurgence of thymic T cell output, which contributes to the restoration of a wide T cell repertoire,52 although the intensity of thymic rebound declines with age. The mechanism driving thymic rebound is not completely understood, but one factor involved is IL-7.53 Both androgens and estrogen suppress thymic function.54, 55 Accordingly, castration reverses thymic atrophy and increases export of recent thymic emigrants to the periphery,56 whereas sex steroids inhibit thymic regeneration by promoting thymocyte apoptosis and arresting thymocyte/prelymphocyte differentiation.57 Restoration of thymic function after castration occurs in young58 as well as in very old rodents.59, 60 In accordance with the notion that estrogen deficiency induces a rebound in thymic function, ovx increases the thymic export of naïve T cells.61 Indeed, stimulated thymic T cell output accounts for ∼50% of the increase in the number of T cells in the periphery. Moreover, thymectomy decreases the bone loss induced by ovx by ∼50%, thus demonstrating that the thymus plays a previously unrecognized role in the pathogenesis of ovx-induced bone loss in mice.61 The remaining bone loss is a consequence of the peripheral expansion of naïve and memory T cells. This finding suggests the tantalizing hypothesis that estrogen deficiency–induced thymic rebound may be responsible for the exaggerated bone loss in young women undergoing surgical menopause62 or for the rapid bone loss characteristic of women in their first 5 to 7 years after natural menopause.63 Indeed, an age-related decrease in estrogen deficiency–induced thymic rebound could mitigate the stimulatory effects of sex steroid deprivation and explain why the rate of bone loss in postmenopausal women diminishes as aging progresses.63 The most upstream effects of ovx in the BM are to stimulate the production of reactive oxygen species (ROS) and to impair the generation of antioxidants.10, 19, 64, 65 In response to ovx, ROS are produced by most BM cells, including T cells.41 ROS play an important role in postmenopausal bone loss by generating a more oxidized bone microenvironment.66, 67 Multiple enzymatic pathways regulate the intracellular redox state through modulation of ROS levels.68 Ovx blunts the BM levels of glutathione (GSH), a critical ROS scavenger, and reduces expression of APE1/Ref-1 and Prx-1 proteins, which collectively limit the production of intracellular ROS.69 ROS have important direct effects on osteoblasts and osteoclasts; these effects have been addressed elsewhere.7, 70, 71 However, additional pivotal effects of ROS include expanding the pool of mature DCs that express the costimulatory molecule CD80, and increasing DC-mediated Ag presentation.19 Antioxidants potently inhibit DC differentiation and their ability to activate T cells,72, 73 in part by suppressing expression of MHC class II and costimulatory molecules in response to Ag.74 N-acetyl-cysteine (NAC), which acts as an intracellular scavenger of ROS by restoring intracellular concentrations of GSM, can block DC maturation75 and DC-mediated T cell activation.76 In vivo support for a role of ROS is provided by experiments demonstrating that administration of antioxidants prevents ovx-induced bone loss,19, 64, 70 while depletion of glutathione by buthionine sulfoximine (BSO), which inhibits glutathione synthesis, enhances bone loss.64 Bone loss caused by BSO has significant similarities to bone loss induced by estrogen deficiency, as both processes are TNF-dependent.77 A second, direct upstream effect of estrogen deficiency is to blunt BM levels of TGFβ,78 a powerful repressor of T cell activation. TGFβ acts as an immunosuppressant by inhibiting T cell activation and T cell production of inflammatory cytokines, including IFNγ. Demonstrating the relevance of the repressive effects of TGFβ on T cell function, mice with T cell–specific blockade of TGFβ signaling were found to be completely resistant to the bone-sparing effects of estrogen.16 Gain of function experiments confirmed that elevation of the systemic levels of TGFβ prevents ovx-induced bone loss and bone turnover.16 The key downstream mechanism by which ovx increases Ag presentation by macrophages is a stimulatory effect on the expression of the gene encoding Class II Transactivator (CIITA). The product of CIITA is a non-DNA binding factor induced by IFNγ that functions as a transcriptional coactivator at the MHC II promoter.79 Increased CIITA expression in macrophages results from ovx-mediated increases in IFNγ production by CD4+ T cells and the responsiveness of CIITA to IFNγ.46 This cytokine was initially described as an anti-osteoclastogenic cytokine because it is a potent inhibitor of osteoclastogenesis in vitro.80 The notion that IFNγ is an inhibitor of bone resorption was reinforced by the finding that silencing of IFNγR−/− signaling leads to a more rapid onset of collagen-induced arthritis and bone resorption81 as compared to WT controls, and by the report that IFNγ decreases serum calcium and osteoclastic bone resorption in nude mice.82, 83 Several mechanisms have been proposed to explain the anti-osteoclastogenic activity of IFNγ, including inhibition of RANKL signaling through the degradation of TNF receptor–associated factor 6 (TRAF6),80 stimulation of apoptosis mediated by Fas/FasL signals,84 and inhibition of RANK and c-Fms gene expression.85 However, the finding that IFNγ is an effective treatment for osteopetrosis both in humans86 and rodents87 demonstrates that the net effect of IFNγ in vivo is to stimulate osteoclastic bone resorption. In keeping with a net pro-resorptive effect of IFNγ in vivo are reports demonstrating that IFNγ−/− and IFNγR−/− mice are protected against ovx-induced bone loss.17, 46 Mice lacking IFNγ production are also protected against infection-induced alveolar bone loss,88 whereas in erosive tuberculoid leprosy and psoriatic arthritis IFNγ production correlates positively with tissue destruction.89 In addition, randomized controlled trials have shown that IFNγ does not prevent bone loss in patients with rheumatoid arthritis (RA),90 nor the bone-wasting effect of cyclosporine A.91 Finally, disruption of IFNγ signaling in vivo results in a strong and sustained inhibition of markers of osteoclastic activity.92 These opposing in vitro and in vivo effects of IFNγ are explained by the fact that IFNγ influences osteoclast formation via both direct and indirect effects.17 IFNγ directly blocks osteoclast formation through targeting of maturing osteoclast.93 However, IFNγ is also a potent inducer of antigen presentation and thus of T cell activation. Therefore, when IFNγ levels are increased in vivo, activated T cells secrete pro-osteoclastogenic factors and this activity offsets the anti-osteoclastogenic effects of IFNγ.17 It should also be mentioned that it is now recognized that IFNγ affects bone turnover by promoting the commitment of BM–SCs into the osteoblastic lineage and their differentiation into mature osteoblasts.94 Accordingly, treatment with IFNγ reverses ovx-induced bone loss by promoting bone formation.92 Another mechanism by which estrogen regulates T cell TNF production is by repressing the production of IL-7, a potent lymphopoietic cytokine and an inducer of bone destruction in vivo.95 Attesting to the relevance of this factor, IL-7 levels are significantly elevated following ovx,61, 96 and in vivo IL-7 blockade is effective in preventing ovx-induced bone destruction.96 The elevated BM levels of IL-7 contribute to the expansion of the T cell population in peripheral lymphoid organs through several mechanisms. First, IL-7 directly stimulates T cell proliferation.61 Second, IL-7 increases antigen presentation by upregulating the production of IFNγ. Third, IL-7 and TGFβ regulate The in TGFβ signaling characteristic of estrogen deficiency may to stimulate IL-7 thus driving the of osteoclastogenic cytokine production and bone In estrogen deficiency, IL-7 bone loss by suppressing bone formation and thus bone formation from resorption. A that the crosstalk between T cells and SCs is relevant for ovx-induced bone loss was provided by the finding that activated T cells induce SC apoptosis via the ligand a which blunts the compensatory increase in bone formation that bone loss in ovx More abundant information is available about the T crosstalk driven by the also known as is a key surface ligand expressed on T CD40L to and several CD40 is expressed on cells, hemopoietic and cells of the osteoblastic CD40L has been to because T cells, through the production of the anti-osteoclastogenic factor by B mice a reduced bone due to exaggerated bone bone has also been found in by a in which CD40L production is due to a in the CD40L However, mice lacking T cell–expressed CD40L are protected against hormone bone the that CD40L may in while promoting bone resorption conditions of bone Studies with mice and with WT mice treated with the CD40L have that silencing of CD40L completely prevents ovx-induced bone A mechanism was shown to be First, silencing of CD40L blocks the activation of T cells and the resulting production of TNF. Second, CD40L is for ovx to increase the proliferation and the differentiation of SCs and their capacity to support osteoclast formation through enhanced production of factor and RANKL, and secretion of a critical additional mechanism by which T cells bone homeostasis in ovx mice is through a crosstalk between T cells and SCs that results in enhanced osteoclastogenesis to a enhanced In ovx increases the number of activated T cells that the expression of and RANKL by SCs, and ovx the SC production of The net result is a significant increase in the rate of The interaction of CD40L with CD40 on SCs in the of estrogen deficiency to the effects of costimulation on B cell OPG the of osteoclast formation in of bone loss. An additional mechanism of T crosstalk the novel of bone mass antigen has been for a known as This factor can be to generate a soluble known as In conditions DLK1/FA-1 are produced by SCs, B cells, and T cells. These factors stimulate osteoclastogenesis and block by the production of TNF, IL-7, and other inflammatory cytokines by SCs. Ovx increases the production of DLK1/FA-1 by activated CD4+ and CD8+ T cells, resulting in a stimulation of the production of osteoclastogenic cytokines by SCs. Attesting to the relevance of mice are significantly protected against ovx-induced bone The hypothesis that the immune system is pivotal for the bone loss about by menopause remains to be demonstrated in it remains to the of why the immune system in and is involved in the mechanism of ovx-induced bone loss. may by postmenopausal bone loss as an of an event critical for the need to stimulate bone resorption in the This process is essential to the increased for calcium about by The for this event is the acute in estrogen levels A second to the period is in associated with is by proliferation of the and formation of These are by and is now that regulates and to by the production of RANKL and a system that is for bone homeostasis is also a key of The in levels in the period results in reduced tissue levels of RANK and RANKL, with the effect of the for The increase in the and TNF levels in the BM induced by estrogen levels the of calcium from the to the and then to the a state of to the is induced by an increase in the number of A to the of is the loss of such immune and the restoration of a immune This is through a decrease in the resulting from the acute in steroid levels. However, a between immune to the and bone is provided by the that OPG is expressed by human it is to that of ovarian function induces bone loss through an immune response because natural has these key within the immune system to (Fig. Schematic representation of in the period and of the involved cells and The that estrogen and are followed by a stimulation of bone resorption, to and of immune to the Activated T cells drive bone resorption by TNF. A decrease in the number of Tregs induces the of the immune The loss of OPG may contribute to the and the increased bone resorption. A decrease in levels of RANKL and RANK induce the of the for with increased of calcium from the the in the contribute to an event critical for The data the hypothesis that of ovarian function induces bone loss through an immune response because natural has key within the immune system to The data support the hypothesis that the bone loss induced by estrogen deficiency is due to a complex of hormones and cytokines that to the process of bone Ovx T cell TNF production by increasing T cell activity in the and the peripheral lymphoid organs. T cell precursors the BM and to the T cell and expansion in the of from the these new T cells to peripheral lymphoid including the BM Ovx induces T cell activation in the BM in part by directly promoting antigen and in part via stimulation of IL-7 and IFNγ production and of TGFβ The net result of these actions is an increase in the number of TNF-producing T cells. The elevated levels of TNF increase RANKL-induced osteoclast formation. Estrogen deficiency also T cell activation and osteoclastogenesis by leading to an in The combined effect of IFNγ and ROS enhances Ag T cell activation. T cells stimulate RANKL and production by SCs, through CD40L and The that has of

Oleanolic acid exerts bone protective effects in ovariectomized mice by inhibiting osteoclastogenesis

2,3,5,4′-Tetrahydroxystilbene-2-O-β-d-glucoside (TSG), an active polyphenolic component of Polygonum multiflorum, exhibits many pharmacological activities including antioxidant, anti-inflammation, and anti-aging effects. A previous study demonstrated that TSG protected MC3T3-E1 cells from hydrogen peroxide (H2O2) induced cell damage and the inhibition of osteoblastic differentiation. However, no studies have investigated the prevention of ovariectomy-induced bone loss in mice. Therefore, we investigated the effects of TSG on bone loss in ovariectomized mice (OVX). Treatment with TSG (1 and 3 μg/g; i.p.) for six weeks positively affected body weight, uterine weight, organ weight, bone length, and weight change because of estrogen deficiency. The levels of the serum biochemical markers of calcium (Ca), inorganic phosphorus (IP), alkaline phosphatase (ALP), and total cholesterol (TCHO) decreased in the TSG-treated mice when compared with the OVX mice. Additionally, the serum bone alkaline phosphatase (BALP) levels in the TSG-treated OVX mice were significantly increased compared with the OVX mice, while the tartrate-resistant acid phosphatase (TRAP) activity was significantly reduced. Furthermore, the OVX mice treated with TSG showed a significantly reduced bone loss compared to the untreated OVX mice upon micro-computed tomography (CT) analysis. Consequently, bone destruction in osteoporotic mice as a result of ovariectomy was inhibited by the administration of TSG. These findings indicate that TSG effectively prevents bone loss in OVX mice; therefore, it can be considered as a potential therapeutic for the treatment of postmenopausal osteoporosis.

Recently, researchers identified a distinct vessel subtype called type H vessels that couple angiogenesis and osteogenesis. We previously found that type H vessels are reduced in ovariectomy (OVX)-induced osteoporotic mice, and preosteoclasts are able to secrete platelet-derived growth factor-BB (PDGF-BB) to stimulate type H vessel formation and thereby to promote osteogenesis. This study aimed to explore whether harmine, a β-carboline alkaloid, is capable of preventing bone loss in OVX mice by promoting preosteoclast PDGF-BB-induced type H vessel formation.Methods: The impact of harmine on osteoclastogenesis of RANKL-stimulated RAW264.7 cells was verified by gene expression analysis and tartrate-resistant acid phosphatase (TRAP) staining. Enzyme-linked immunosorbent assay (ELISA) was conducted to test PDGF-BB production by preosteoclasts. A series of angiogenesis-related assays in vitro were performed to assess the pro-angiogenic effects of the conditioned media from RANKL-stimulated RAW264.7 cells treated with or without harmine. Meanwhile, the role of PDGF-BB in this process was determined. In vivo, OVX mice were intragastrically administrated with harmine emulsion or an equal volume of vehicle. 2 months later, bone samples were collected for µCT, histological, immunohistochemical and immunofluorescent analyses to evaluate bone mass, osteogenic and osteoclastic activities, as well as the numbers of type H vessels. Bone marrow PDGF-BB concentrations were assessed by ELISA.Results: Exposure of RANKL-stimulated RAW264.7 cells to harmine enhanced the formation of preosteoclasts and the production of PDGF-BB. Harmine augmented the ability of RANKL-stimulated RAW264.7 cells to promote angiogenesis of endothelial cells, whereas the effect was blocked by PDGF-BB inhibition. In vivo, the oral administration of harmine emulsion to OVX mice resulted in enhanced trabecular bone mass and osteogenic responses, increased numbers of preosteoclasts, as well as reduced numbers of osteoclasts and fat cells. Moreover, OVX mice treated with harmine exhibited higher levels of bone marrow PDGF-BB and much more type H vessels in bone.Conclusion: Harmine may exert bone-sparing effects by suppression of osteoclast formation and promotion of preosteoclast PDGF-BB-induced angiogenesis.

(S)-Equol Is More Effective than (R)-Equol in Inhibiting Osteoclast Formation and Enhancing Osteoclast Apoptosis, and Reduces Estrogen Deficiency–Induced Bone Loss in Mice

Knockdown of NPY Expression in the Dorsomedial Hypothalamus Promotes Development of Brown Adipocytes and Prevents Diet-Induced Obesity

Eicosapentaenoic acid supplementation modulates the osteoblast/osteoclast balance in inflammatory environments and protects against estrogen deficiency-induced bone loss in mice

Postmenopausal osteoporosis (PMO) is a progressive bone disease characterized by the over‐production and activation of osteoclasts in elderly women. In our study, we investigated the anti‐osteoclastogenic effect of evodiamine (EVO) in vivo and in vitro, as well as the underlying mechanism. By using an in vitro bone marrow macrophage (BMM)‐derived osteoclast culture system, we found that EVO inhibited osteoclast formation, hydroxyapatite resorption and receptor activator of NF‐κB ligand (RANKL)‐induced osteoclast marker gene and protein expression. Mechanistically, we found that EVO inhibited the degradation and RANKL‐induced transcriptional activity of IκBα. RANKL‐induced Ca2+ oscillations were also abrogated by EVO. In vivo, an ovariectomized (OVX) mouse model was established to mimic PMO, and OVX mice received oral administration of either EVO (10 mg/kg) or saline every other day. We found that EVO can attenuate bone loss in OVX mice by inhibiting osteoclastogenesis. Taken together, our findings suggest that EVO suppresses RANKL‐induced osteoclastogenesis through NF‐κB and calcium signalling pathways and has potential value as a therapeutic agent for PMO.

MicroRNAs play important roles in osteoporosis and show great potential for diagnosis and therapy of osteoporosis. Previous studies have demonstrated that miR-146a affects osteoblast (OB) and osteoclast (OC) formation. However, these findings have yet to be identified in vivo, and it is unclear whether miR-146a is related to postmenopausal osteoporosis. Here, we demonstrated that miR-146a knockout protects bone loss in mouse model of estrogen-deficient osteoporosis, and miR-146a inhibits OB and OC activities in vitro and in vivo. MiR-146a-/- mice displayed the same bone mass as the wild type (WT) but exhibited a stronger bone turnover than the WT did under normal conditions. Nevertheless, miR-146a-/- mice showed an increase in bone mass after undergoing ovariectomy (OVX) compared with those subjected to sham operation. OC activities were impaired in the miR-146a-/- mice exposed to estrogen deficiency, which was diametrically opposite to the enhanced bone resorption ability of WT. Macrophage colony-stimulating factor (M-CSF) and receptor activator of NF-κB ligand (RANKL)/osteoprotegerin (OPG) from a bone microenvironment affect this extraordinary phenomenon. Therefore, our results implicate that miR-146a plays a key role in estrogen deficiency-induced osteoporosis, and the inhibition of this molecule provides skeleton protection. © 2019 American Society for Bone and Mineral Research.

Osteogenesis during bone modeling and remodeling is coupled with angiogenesis. A recent study shows that the specific vessel subtype, strongly positive for CD31 and Endomucin (CD31hiEmcnhi), couples angiogenesis and osteogenesis. We found that preosteoclasts secrete platelet derived growth factor-BB (PDGF-BB), inducing CD31hiEmcnhi vessels during bone modeling and remodeling. Mice with depletion of PDGF-BB in tartrate-resistant acid phosphatase positive (TRAP+) cell lineage (Pdgfb–/–) show significantly lower trabecular and cortical bone mass, serum and bone marrow PDGF-BB concentrations, and CD31hiEmcnhi vessels compared to wild-type mice. In the ovariectomized (OVX) osteoporotic mouse model, concentrations of serum and bone marrow PDGF-BB and CD31hiEmcnhi vessels are significantly decreased. Inhibition of cathepsin K (CTSK) increases preosteoclast numbers, resulting in higher levels of PDGF-BB to stimulate CD31hiEmcnhi vessels and bone formation in OVX mice. Thus, pharmacotherapies that increase PDGF-BB secretion from preosteoclasts offer a novel therapeutic target for osteoporosis to promote angiogenesis for bone formation.

BackgroundInflammatory bowel disease (IBD) is a chronic disease in which macrophages play an important role in its pathogenesis. Platelet-derived growth factor-BB (PDGF-BB) secreted by macrophages is involved in the repair of vascular endothelial injury during inflammatory reactions.MethodsThe expression levels of M1 macrophages and PDGF-BB in serum and colonic mucosa of 30 patients with Crohn’s disease (CD) and 30 patients with ulcerative colitis (UC) were measured using enzyme-linked immunosorbent assays and immunohistochemistry. Logistic regression was used for univariate and multivariate analyses, and receiver operating characteristic curves were used to evaluate diagnostic value. Associations were evaluated using Spearman correlation analysis.ResultsThe expression of serum PDGF-BB and M1 macrophages with positive CXCL9 expression in patients with active-stage IBD [206.55(160.41,262.90)and 337.30(217.73,472.28) pg/ml] was higher than that in patients with remission stage [153.42(107.02,219.68)and 218.37(144.49,347.33)pg/ml] and controls [156.19(91.16,216.08)and 191.20(121.42,311.76)pg/ml](P < 0.05). The expression of PDGF-BB, CD86, and CXCL9 in the colon of patients with active-stage IBD [0.380(0.266,0.542) 0.663(0.480,0.591) and 0.564(0.378,0.765) /µm2] was higher than that in the remission stage [0.308(0.214,0.420), 0.376(0.206,0.591) and 0.413(0.275,0.570) /µm2] and controls [0.265(0.185,0.384), 0.416(0.269,0.534) and 0.497(0.415,0.642) /µm2] (P < 0.05). A positive correlation was observed between CD86 and PDGF-BB, and CXCL9 and PDGF-BB levels in patients with IBD (P < 0.05). CD86 and PDGF-BB in the colonic mucosa were independent risk factors for active IBD, and the area under the curve for their combined diagnosis was 0.754 (95%CI: 0.654–0.852, P < 0.05).ConclusionsPDGF-BB was associated with M1 macrophages and has a potential diagnostic value for active IBD.Trial registrationNot applicable.

Platelet-derived growth factor BB (PDGF-BB) has been shown to be an extremely potent negative regulator of smooth muscle cell (SMC) differentiation. Moreover, previous studies have demonstrated that the Kruppel-like transcription factor (KLF) 4 potently represses the expression of multiple SMC genes. However, the mechanisms whereby KLF4 suppresses SMC gene expression are not known, nor is it clear whether KLF4 contributes to PDGF-BB-induced down-regulation of SMC genes. The goals of the present studies were to determine the molecular mechanisms by which KLF4 represses expression of SMC genes and whether it contributes to PDGF-BB-induced suppression of these genes. Results demonstrated that KLF4 markedly repressed both myocardin-induced activation of SMC genes and expression of myocardin. KLF4 was rapidly up-regulated in PDGF-BB-treated, cultured SMC, and a small interfering RNA to KLF4 partially blocked PDGF-BB-induced SMC gene repression. Both PDGF-BB and KLF4 markedly reduced serum response factor binding to CArG containing regions within intact chromatin. Finally, KLF4, which is normally not expressed in differentiated SMC in vivo, was rapidly up-regulated in vivo in response to vascular injury. Taken together, results indicate that KLF4 represses SMC genes by both down-regulating myocardin expression and preventing serum response factor/myocardin from associating with SMC gene promoters, and suggest that KLF4 may be a key effector of PDGF-BB and injury-induced phenotypic switching of SMC.

A clinical and experimental assessment using human samples of lumbar ligamentum flavum (LF). To identify platelet-derived growth factor-BB (PDGF-BB) expression in hypertrophied LF of patients with lumbar spinal canal stenosis (LSS) and relate it to fibrosis. Recent studies showed that fibrosis in LF hypertrophy was due to accumulation of inflammation-related scar tissue. PDGF-BB participates in scar formation and collagen development in wound healing and fibrosis diseases. However, it is unclear whether PDGF-BB expression is associated with fibrosis of the hypertrophied LF in LSS. In all, 10 patients of LSS was enrolled in this study, while 10 patients of lumbar disc herniation (LDH) as a control group. LF thickness was measured by axial T1-weighted magnetic resonance imaging. Fibrosis was graded and type of collagen was identified. The location and the expression of PDGF-BB were analyzed using immunohistochemical stains, real-time polymerase chain reaction, and Western Blotting. Correlation among LF thickness, fibrosis, and PDGF-BB expression was analyzed. LF thickness was 5.3 ± 1.0 mm (range from 3.9 to 7.5 mm) in the LSS group and 2.8 ± 0.7 mm (range from 1.69 to 3.8 mm) in the LDH group. Obvious fibrosis was observed in all samples of the LSS group, and correlated to LF thickness of the dural, middle, and dorsal layers (P < 0.05), respectively. PDGF-BB was detected in the hypertrophied LF, particularly in the dorsal layer. PDGF-BB expression was higher in the LSS group than that in the LDH group (P < 0.05), and in the dorsal layer than the dural layer in the LSS group (P < 0.05). PDGF-BB mRNA correlated significantly to thickness of LF (r = 0.41) and the severity of fibrosis (r = 0.69) (P < 0.05). A higher PDGF-BB expression existed in the hypertrophied LF of patients with LSS and could be a risk factor of the fibrosis.