Microtubule assembly affects bone mass by regulating both osteoblast and osteoclast functions: Stathmin deficiency produces an osteopenic phenotype in mice

Cytoskeleton microtubules regulate various cell signaling pathways that are involved in bone cell function. We recently reported that inhibition of microtubule assembly by microtubule‐targeting drugs stimulates osteoblast differentiation and bone formation. To further elucidate the role of microtubules in bone homeostasis, we characterized the skeletal phenotype of mice null for stathmin, an endogenous protein that inhibits microtubule assembly. In vivo micro–computed tomography (µCT) and histology revealed that stathmin deficiency results in a significant reduction of bone mass in adult mice concurrent with decreased osteoblast and increased osteoclast numbers in bone tissues. Phenotypic analyses of primary calvarial cells and bone marrow cells showed that stathmin deficiency inhibited osteoblast differentiation and induced osteoclast formation. In vitro overexpression studies showed that increased stathmin levels enhanced osteogenic differentiation of preosteoblast MC3T3‐E1 cells and mouse bone marrow–derived cells and attenuated osteoclast formation from osteoclast precursor Raw264.7 cells and bone marrow cells. Results of immunofluorescent studies indicated that overexpression of stathmin disrupted radial microtubule filaments, whereas deficiency of stathmin stabilized the microtubule network structure in these bone cells. In addition, microtubule‐targeting drugs that inhibit microtubule assembly and induce osteoblast differentiation lost these effects in the absence of stathmin. Collectively, these results suggest that stathmin, which alters microtubule dynamics, plays an essential role in maintenance of postnatal bone mass by regulating both osteoblast and osteoclast functions in bone. © 2011 American Society for Bone and Mineral Research     

DLK1 is a novel regulator of bone mass that mediates estrogen deficiency–induced bone loss in mice

Delta‐like 1/fetal antigen 1 (DLK1/FA‐1) is a transmembrane protein belonging to the Notch/Delta family that acts as a membrane‐associated or a soluble protein to regulate regeneration of a number of adult tissues. Here we examined the role of DLK1/FA‐1 in bone biology using osteoblast‐specific Dlk1‐overexpressing mice (Col1‐Dlk1). Col1‐Dlk1 mice displayed growth retardation and significantly reduced total body weight and bone mineral density (BMD). Micro–computed tomographis (µCT) scanning revealed a reduced trabecular and cortical bone volume fraction. Tissue‐level histomorphometric analysis demonstrated decreased bone‐formation rate and enhanced bone resorption in Col1‐Dlk1 mice compared with wild‐type mice. At a cellular level, Dlk1 markedly reduced the total number of bone marrow (BM)–derived colony‐forming units fibroblasts (CFU‐Fs), as well as their osteogenic capacity. In a number of in vitro culture systems, Dlk1 stimulated osteoclastogenesis indirectly through osteoblast‐dependent increased production of proinflammatory bone‐resorbing cytokines (eg, Il7, Tnfa, and Ccl3). We found that ovariectomy (ovx)–induced bone loss was associated with increased production of Dlk1 in the bone marrow by activated T cells. Interestingly, Dlk1^?/? mice were significantly protected from ovx‐induced bone loss compared with wild‐type mice. Thus we identified Dlk1 as a novel regulator of bone mass that functions to inhibit bone formation and to stimulate bone resorption. Increasing DLK1 production by T cells under estrogen deficiency suggests its possible use as a therapeutic target for preventing postmenopausal bone loss. © 2011 American Society for Bone and Mineral Research.     

Deletion of FGFR3 in Osteoclast Lineage Cells Results in Increased Bone Mass in Mice by Inhibiting Osteoclastic Bone Resorption

Fibroblast growth factor receptor 3 (FGFR3) participates in bone remodeling. Both Fgfr3 global knockout and activated mice showed decreased bone mass with increased osteoclast formation or bone resorption activity. To clarify the direct effect of FGFR3 on osteoclasts, we specifically deleted Fgfr3 in osteoclast lineage cells. Adult mice with Fgfr3 deficiency in osteoclast lineage cells (mutant [MUT]) showed increased bone mass. In a drilled‐hole defect model, the bone remodeling of the holed area in cortical bone was also impaired with delayed resorption of residual woven bone in MUT mice. In vitro assay demonstrated that there was no significant difference between the number of tartrate‐resistant acid phosphatase (TRAP)‐positive osteoclasts derived from wild‐type and Fgfr3‐deficient bone marrow monocytes, suggesting that FGFR3 had no remarkable effect on osteoclast formation. The bone resorption activity of Fgfr3‐deficient osteoclasts was markedly decreased accompanying with downregulated expressions of Trap, Ctsk, and Mmp 9. The upregulated activity of osteoclastic bone resorption by FGF2 in vitro was also impaired in Fgfr3‐deficient osteoclasts, indicating that FGFR3 may participate in the regulation of bone resorption activity of osteoclasts by FGF2. Reduced adhesion but not migration in osteoclasts with Fgfr3 deficiency may be responsible for the impaired bone resorption activity. Our study for the first time genetically shows the direct positive regulation of FGFR3 on osteoclastic bone resorption. © 2016 American Society for Bone and Mineral Research.     

Overexpression of H1 calponin in osteoblast lineage cells leads to a decrease in bone mass by disrupting osteoblast function and promoting osteoclast formation

H1 calponin (CNN1) is known as a smooth muscle‐specific, actin‐binding protein which regulates smooth muscle contractive activity. Although previous studies have shown that CNN1 has effect on bone, the mechanism is not well defined. To investigate the role of CNN1 in maintaining bone homeostasis, we generated transgenic mice overexpressing Cnn1 under the control of the osteoblast‐specific 3.6‐kb Col1a1 promoter. Col1a1‐Cnn1 transgenic mice showed delayed bone formation at embryonic stage and decreased bone mass at adult stage. Morphology analyses showed reduced trabecular number, thickness and defects in bone formation. The proliferation and migration of osteoblasts were decreased in Col1a1‐Cnn1 mice due to alterations in cytoskeleton. The early osteoblast differentiation of Col1a1‐Cnn1 mice was increased, but the late stage differentiation and mineralization of osteoblasts derived from Col1a1‐Cnn1 mice were significantly decreased. In addition to impaired bone formation, the decreased bone mass was also associated with enhanced osteoclastogenesis. Tartrate‐resistant acid phosphatase (TRAP) staining revealed increased osteoclast numbers in tibias of 2‐month‐old Col1a1‐Cnn1 mice, and increased numbers of osteoclasts co‐cultured with Col1a1‐Cnn1 osteoblasts. The ratio of RANKL to OPG was significantly increased in Col1a1‐Cnn1 osteoblasts. These findings reveal a novel function of CNN1 in maintaining bone homeostasis by coupling bone formation to bone resorption. © 2013 American Society for Bone and Mineral Research.     

造血干细胞标志物CD74在大鼠肝干细胞中的表达

目的检测与分析大鼠肝干细胞（HSC）标志物,为分离和鉴定HSC提供可能的新方法。方法采用胶原酶灌流法与密度梯度离心法分离正常SD大鼠HSC,利用倒置相差显微镜、逆转录PCR和免疫组织化学法等技术,观察HSC标志物白蛋白、CK19、Oval-6、CD90和成熟肝细胞标志物酪氨酸氨基转移酶（TAT）及造血干细胞标志物CD45和CD74在HSC中的表达情况。结果正常SD大鼠分离培养的HSC在倒置相差显微镜下呈卵圆形,具有较高的核浆比率。逆转录PCR分析显示,该细胞表达白蛋白、CK19、CD90和CD74基因,不表达TAT和CD45。细胞免疫组织化学法检测结果证实HSC表达Oval-6和CD74。结论 CD74有可能成为分离和鉴定HSC的新标志物之一。     

GPR30 deficiency causes increased bone mass,mineralization, and growth plate proliferative activity in male mice

Estrogen regulation of the male skeleton was first clearly demonstrated in patients with aromatase deficiency or a mutation in the ERα gene. Estrogen action on the skeleton is thought to occur mainly through the action of the nuclear receptors ERα and ERβ. Recently, in vitro studies have shown that the G protein–coupled receptor GPR30 is a functional estrogen receptor (ER). GPR30‐deficient mouse models have been generated to study the in vivo function of this protein; however, its in vivo role in the male skeleton remains underexplored. We have characterized size, body composition, and bone mass in adult male Gpr30 knockout (KO) mice and their wild‐type (WT) littermates. Gpr30 KO mice weighed more and had greater nasal‐anal length (p < .001). Both lean mass and percent body fat were increased in the KO mice. Femur length was greater in Gpr30 KO mice, as was whole‐body, spine, and femoral areal bone mineral density (p < .01). Gpr30 KO mice showed increased trabecular bone volume (p < .01) and cortical thickness (p < .001). Mineralized surface was increased in Gpr30 KO mice (p < .05). Bromodeoxyuridine (BrdU) labeling showed greater proliferation in the growth plate of Gpr30 KO mice (p < .05). Under osteogenic culture conditions, Gpr30 KO femoral bone marrow cells produced fewer alkaline phosphatase–positive colonies in early differentiating osteoblast cultures but showed increased mineralized nodule deposition in mature osteoblast cultures. Serum insulin‐like growth factor 1 (IGF‐1) levels were not different. These data suggest that in male mice, GPR30 action contributes to regulation of bone mass, size, and microarchitecture by a mechanism that does not require changes in circulating IGF‐1. © 2011 American Society for Bone and Mineral Research.     

CD74基因调控CXCR4抑制肾癌786-O细胞的侵袭作用

目的探讨抑制人CD74基因后影响肾癌786-O细胞侵袭能力的作用机制。方法通过慢病毒lentivirus-CD74转染肾癌786-O细胞后,MTT法观察细胞活力变化,Transwell实验观察细胞侵袭能力的变化,应用Westernblot技术检测CD74、CXCR4蛋白的变化情况。结果抑制CD74蛋白表达水平后肾癌786-O细胞活力降低,侵袭能力降低,同时伴有CXCR4蛋白的表达降低。结论通过慢病毒转染抑制CD74的表达可以抑制肾癌细胞的侵袭能力,CD74基因可能是通过调控CXCR4蛋白的变化影响细胞侵袭能力的。     

乳腺浸润性导管癌中CD74的表达及临床意义

目的:研究乳腺浸润性导管癌中CD74的表达及其临床意义.方法:用免疫组化技术检测45例乳腺浸润性导管癌组织中CD74,雌激素受体(ER),孕激素受体(PR)及c-erbB-2的表达,分析CD74表达与ER,PR及c-erbB-2表达及临床病理特征和预后的关系;观察乳腺癌MB-MDA-435细胞(高侵袭性),MCF-7细胞(低侵袭性)和转染CD74表达质粒的MCF-7细胞中CD74蛋白的表达,并用Transwell小室检测3种细胞的侵袭能力.结果:乳腺浸润性导管癌中,CD74的表达量与病理分级有关(P＜0.01),癌细胞分化愈差则CD74表达愈高;CD74在受体阳性组中的表达率明显低于受体阴性组(P＜0.01);三阴乳腺癌中CD74的阳性表达率明显高于非三阴乳腺癌组(P＜0.01);CD74阳性患者淋巴结转移率明显高于阴性表达者(P＜0.01);CD74表达阳性与否与患者的5年生存率未见明显关系性.高侵袭性MB-MDA-435细胞CD74蛋白表达量明显高于低侵袭性MCF-7细胞;MCF-7细胞转染CD74表达质粒后侵袭能力明显增强.结论:CD74可能在乳腺癌的侵袭和淋巴结转移中起着重要作用,并有可能成为一种潜在的高侵袭性乳腺癌特别是三阴乳腺癌的标志物.     

CD74 expression is increased in high‐grade,invasive urothelial carcinoma of the bladder

This study aimed to identify the clinicopathological features of bladder cancer patients with high CD74 expression, as milatuzumab humanized anti‐CD74 antibody is being evaluated in clinical trials for hematological malignancies. Expression of CD74 was examined in 342 urothelial carcinomas of the bladder, and two urothelial carcinoma cell lines by immunohistochemistry and western blotting, respectively. CD74 was overexpressed in 192 (56.1%) of the 342 cancer tissues, although it was not expressed in the cancer cell lines. CD74 staining was intense in tumor cells and inflammatory cells in the tumor stroma, but not in normal urothelium. CD74 expression was significantly associated with older age at diagnosis (≥68 years, P = 0.048), high World Health Organization grade (P = 0.019), advanced stages (P = 0.001) and non‐papillary growth pattern (P = 0.040). CD74 expression was also correlated with the absence of tumor‐infiltrating inflammatory cells (P < 0.001) and the presence of tumor‐associated inflammatory cells (P = 0.017). However, CD74 expression was not related to recurrence‐free and overall survivals in primary and subgroup analyses. In conclusion, urothelial bladder carcinomas with high CD74 expression are characterized by older age, high World Health Organization grade, non‐papillary growth and advanced stages.     

The gut microbiota regulates bone mass in mice

The gut microbiota modulates host metabolism and development of immune status. Here we show that the gut microbiota is also a major regulator of bone mass in mice. Germ-free (GF) mice exhibit increased bone mass associated with reduced number of osteoclasts per bone surface compared with conventionally raised (CONV-R) mice. Colonization of GF mice with a normal gut microbiota normalizes bone mass. Furthermore, GF mice have decreased frequency of CD4(+) T cells and CD11b(+) /GR 1 osteoclast precursor cells in bone marrow, which could be normalized by colonization. GF mice exhibited reduced expression of inflammatory cytokines in bone and bone marrow compared with CONV-R mice. In summary, the gut microbiota regulates bone mass in mice, and we provide evidence for a mechanism involving altered immune status in bone and thereby affected osteoclast-mediated bone resorption. Further studies are required to evaluate the gut microbiota as a novel therapeutic target for osteoporosis.     

Sclerostin antibody treatment improves bone mass,bone strength,and bone defect regeneration in rats with type 2 diabetes mellitus

Type 2 diabetes mellitus results in increased risk of fracture and delayed fracture healing. ZDF fa/fa rats are an established model of type 2 diabetes mellitus with low bone mass and delayed bone healing. We tested whether a sclerostin‐neutralizing antibody (Scl‐AbVI) would reverse the skeletal deficits of diabetic ZDF rats. Femoral defects of 3 mm were created in 11‐week‐old diabetic ZDF fa/fa and nondiabetic ZDF +/+ rats and stabilized by an internal plate. Saline or 25 mg/kg Scl‐AbVI was administered subcutaneously (s.c.) twice weekly for 12 weeks (n = 9–10/group). Bone mass and strength were assessed using pQCT, micro–computed tomography (µCT), and biomechanical testing. Bone histomorphometry was used to assess bone formation, and the filling of the bone defect was analyzed by µCT. Diabetic rats displayed lower spinal and femoral bone mass compared to nondiabetic rats, and Scl‐AbVI treatment significantly enhanced bone mass of the femur and the spine of diabetic rats (p < 0.0001). Scl‐AbVI also reversed the deficit in bone strength in the diabetic rats, with 65% and 89% increases in maximum load at the femoral shaft and neck, respectively (p < 0.0001). The lower bone mass in diabetic rats was associated with a 65% decrease in vertebral bone formation rate, which Scl‐AbVI increased by sixfold, consistent with a pronounced anabolic effect. Nondiabetic rats filled 57% of the femoral defect, whereas diabetic rats filled only 21% (p < 0.05). Scl‐AbVI treatment increased defect regeneration by 47% and 74%, respectively (p < 0.05). Sclerostin antibody treatment reverses the adverse effects of type 2 diabetes mellitus on bone mass and strength, and improves bone defect regeneration in rats. © 2013 American Society for Bone and Mineral Research.     

Daily administration of eldecalcitol (ED-71), an active vitamin D analog, increases bone mineral density by suppressing RANKL expression in mouse trabecular bone

Eldecalcitol (ED‐71) is a new vitamin D₃ derivative recently approved for the treatment of osteoporosis in Japan. Previous studies have shown that the daily administration of ED‐71 increases bone mineral density (BMD) by suppressing bone resorption in various animal models. In this study, we examined how ED‐71 suppresses bone resorption in vivo, by analyzing bone histomorphometry and ex vivo osteoclastogenesis assays. Daily administration of ED‐71 (50 ng/kg body weight) to 8‐week‐old male mice for 2 and 4 weeks increased BMD in the femoral metaphysis without causing hypercalcemia. Bone and serum analyses revealed that ED‐71 inhibited bone resorption and formation, indicating that the increase in BMD is the result of the suppression of bone resorption. This suppression was associated with a decrease in the number of osteoclasts in trabecular bone. We previously identified cell cycle‐arrested receptor activator of NF‐κB (RANK)‐positive bone marrow cells as quiescent osteoclast precursors (QOPs) in vivo. Daily administration of ED‐71 affected neither the number of RANK‐positive cells in vivo nor the number of osteoclasts formed from QOPs in ex vivo cultures. In contrast, ED‐71 suppressed the expression of RANK ligand (RANKL) mRNA in femurs. Immunohistochemical experiments also showed that the perimeter of the RANKL‐positive cell surface around the trabecular bone was significantly reduced in ED‐71‐treated mice than in the control mice. ED‐71 administration also increased BMD in 12‐week‐old ovariectomized mice, through the suppression of RANKL expression in the trabecular bone. These results suggest that the daily administration of ED‐71 increases BMD by suppressing RANKL expression in trabecular bone in vivo. © 2012 American Society for Bone and Mineral Research     

Partial loss of Smad7 function impairs bone remodeling,osteogenesis and enhances osteoclastogenesis in mice

Smad7 is well demonstrated as a negative regulator of TGF-β signaling. Its alteration in expression often results in diseases such as cancer and fibrosis. However, the exact role of Smad7 in regulating bone remodeling during mammalian development has not been properly delineated. In this study we performed experiments to clarify the involvement of Smad7 in regulating osteogenesis and osteoclastogenesis both invivo and invitro. Genetically engineered Smad7^ΔE1 (KO) mice were used, whereby partial functional of Smad7 is lost by deleting exon I of the Smad7 gene and the truncated proteins cause a hypomorphic allele. Analysis with μCT imagery and bone histomorphometry showed that the KO mice had lower TbN, TbTh, higher TbSp in the metaphysic region of the femurs at 6, 12, 24 weeks from birth, as well as decreased MAR and increased osteoclast surface compared with the WT mice. In vitro BM-MSC multi-lineage differentiation evaluation showed that the KO group had reduced osteogenic potential, fewer mineralized nodules, lower ALP activity, and reduced gene expression of Col1A1, Runx2 and OCN. The adipogenic potential was elevated in the KO group with more formation of lipid droplets, and increased gene expression of Adipsin and C/EBPα. The osteoclastogenic potential of KO mice BMMs was elevate, with emergence of more osteoclasts, larger resorptive areas, and increased gene expression of TRAP and CTR. Our results indicate that partial loss of Smad7 function in mice leads to compromised bone formation and enhanced bone resorption. Thus, Smad7 is acknowledged as a novel key regulator between osteogenesis and osteoclastogenesis.     

β‐catenin promotes bone formation and suppresses bone resorption in postnatal growing mice

Genetic studies in the mouse have demonstrated multiple roles for β‐catenin in the skeleton. In the embryo, β‐catenin is critical for the early stages of osteoblast differentiation. Postnatally, β‐catenin in mature osteoblasts and osteocytes indirectly suppresses osteoclast differentiation. However, a direct role for β‐catenin in regulating osteoblast number and/or function specifically in the postnatal life has not been demonstrated. Addressing this knowledge gap is important because low‐density lipoprotein receptor‐related protein 5 (LRP5), a coreceptor for WNT signaling proposed to function through β‐catenin, controls osteoblast number and function in postnatal mice or humans. To overcome the neonatal lethality caused by embryonic deletion of β‐catenin in early‐stage osteoblast‐lineage cells, we use the Osx‐CreER^T2 mouse strain to remove β‐catenin in Osterix (Osx)‐expressing cells by administering tamoxifen (TM) temporarily to postnatal mice. Lineage‐tracing experiments in the long bones demonstrate that Osx‐CreER^T2 targets predominantly osteoblast‐lineage cells on the bone surface, but also transient progenitors that contribute to bone marrow stromal cells and adipocytes. Deletion of β‐catenin by this strategy greatly reduces the bone formation activity of the targeted osteoblasts. However, the targeted osteoblasts rapidly turn over and are replaced by an excessive number of non‐targeted osteoblasts, causing an unexpected increase in bone formation, but an even greater increase in osteoclast number and activity produces a net effect of severe osteopenia. With time, the mutant mice also exhibit a marked increase in bone marrow adiposity. Thus, β‐catenin in postnatal Osx‐lineage cells critically regulates bone homeostasis by promoting osteoblast activity and suppressing osteoblast turnover, while restraining osteoclast and marrow fat formation. © 2013 American Society for Bone and Mineral Research.     

The R740S mutation in the V‐ATPase a3 subunit increases lysosomal pH,impairs NFATc1 translocation,and decreases in vitro osteoclastogenesis

Vacuolar H⁺‐ATPase (V‐ATPase), a multisubunit enzyme located at the ruffled border and in lysosomes of osteoclasts, is necessary for bone resorption. We previously showed that heterozygous mice with an R740S mutation in the a3 subunit of V‐ATPase (+/R740S) have mild osteopetrosis resulting from an ～90% reduction in proton translocation across osteoclast membranes. Here we show that lysosomal pH is also higher in +/R740S compared with wild‐type (+/+) osteoclasts. Both osteoclast number and size were decreased in cultures of +/R740S compared with +/+ bone marrow cells, with concomitant decreased expression of key osteoclast markers (TRAP, cathepsin K, OSCAR, DC‐STAMP, and NFATc1), suggesting that low lysosomal pH plays an important role in osteoclastogenesis. To elucidate the molecular mechanism of this inhibition, NFATc1 activation was assessed. NFATc1 nuclear translocation was significantly reduced in +/R740S compared with +/+ cells; however, this was not because of impaired enzymatic activity of calcineurin, the phosphatase responsible for NFATc1 dephosphorylation. Protein and RNA expression levels of regulator of calcineurin 1 (RCAN1), an endogenous inhibitor of NFATc1 activation and a protein degraded in lysosomes, were not significantly different between +/R740S and +/+ osteoclasts, but the RCAN1/NFATc1 ratio was significantly higher in +/R740S versus +/+ cells. The lysosomal inhibitor chloroquine significantly increased RCAN1 accumulation in +/+ cells, consistent with the hypothesis that higher lysosomal pH impairs RCAN1 degradation, leading to a higher RCAN1/NFATc1 ratio and consequently NFATc1 inhibition. Our data indicate that increased lysosomal pH in osteoclasts leads to decreased NFATc1 signaling and nuclear translocation, resulting in a cell autonomous impairment of osteoclastogenesis in vitro. © 2013 American Society for Bone and Mineral Research     

Disruption of the dynein‐dynactin complex unveils motor‐specific functions in osteoclast formation and bone resorption

Osteoclastic bone resorption requires strict interplay between acidified carrier vesicles, motor proteins, and the underlying cytoskeleton in order to sustain the specialized structural and functional polarization of the ruffled border. Cytoplasmic dynein, a large processive mechanochemical motor comprising heavy, intermediate, and light chains coupled to the dynactin cofactor complex, powers unilateral motility of diverse cargos to microtubule minus‐ends. We have recently shown that regulators of the dynein motor complex constitute critical components of the osteoclastic bone resorptive machinery. Here, by selectively modulating endogenous dynein activity, we show that the integrity of the dynein‐dynactin motor complex is an essential requirement for both osteoclast formation and function. Systematic dissection of the osteoclast dynein‐dynactin complex revealed that it is differentially localized throughout RANKL‐induced osteoclast formation and activation, undergoing microtubule‐coupled reorganization upon the establishment of cellular polarization. In osteoclasts actively resorbing bone, dynein‐dynactin intimately co‐localizes with the CAP‐Gly domain‐containing microtubule plus‐end protein CLIP‐170 at the resorptive front, thus orientating the ruffled border as a microtubule plus‐end domain. Unexpectedly, disruption of the dynein‐dynactin complex by exogenous p50/dynamitin expression retards osteoclast formation in vitro, owing largely to prolonged mitotic stasis of osteoclast progenitor cells. More importantly, loss of osteoclastic dynein activity results in a drastic redistribution of key intracellular organelles, including the Golgi and lysosomes, an effect that coincides with impaired cathepsin K secretion and diminished bone resorptive function. Collectively, these data unveil a previously unrecognized role for the dynein‐dynactin motor complex in osteoclast formation and function, serving not only to regulate their timely maturation but also the delivery of osteolytic cargo that is essential to the bone resorptive process. © 2013 American Society for Bone and Mineral Research     

Coupling of Bone Resorption and Formation in Real Time: New Knowledge Gained From Human Haversian BMUs

It is well known that bone remodeling starts with a resorption event and ends with bone formation. However, what happens in between and how resorption and formation are coupled remains mostly unknown. Remodeling is achieved by so‐called basic multicellular units (BMUs), which are local teams of osteoclasts, osteoblasts, and reversal cells recently proven identical with osteoprogenitors. Their organization within a BMU cannot be appropriately analyzed in common histology. The originality of the present study is to capture the events ranging from initiation of resorption to onset of formation as a functional continuum. It was based on the position of specific cell markers in longitudinal sections of Haversian BMUs generating new canals through human long bones. It showed that initial resorption at the tip of the canal is followed by a period where newly recruited reversal/osteoprogenitor cells and osteoclasts alternate, thus revealing the existence of a mixed “reversal‐resorption” phase. Three‐dimensional reconstructions obtained from serial sections indicated that initial resorption is mainly involved in elongating the canal and the additional resorption events in widening it. Canal diameter measurements show that the latter contribute the most to overall resorption. Of note, the density of osteoprogenitors continuously grew along the “reversal/resorption” surface, reaching at least 39 cells/mm on initiation of bone formation. This value was independent of the length of the reversal/resorption surface. These observations strongly suggest that bone formation is initiated only above a threshold cell density, that the length of the reversal/resorption period depends on how fast osteoprogenitor recruitment reaches this threshold, and thus that the slower the rate of osteoprogenitor recruitment, the more bone is degraded. They lead to a model where the newly recognized reversal/resorption phase plays a central role in the mechanism linking osteoprogenitor recruitment and the resorption‐formation switch. © 2017 American Society for Bone and Mineral Research.     

Role of macrophage migration inhibitory factor in head and neck cancer and novel therapeutic targets: A systematic review

Macrophage migration inhibitory factor (MIF) is a proinflammatory cytokine involved in systemic, autoimmune, and inflammatory diseases, such as obesity, rheumatoid arthritis, and systemic lupus erythematosus. For the 2 past decades, MIF has been reported to participate in carcinogenesis, disease prognosis, tumor cell proliferation, invasion, and tumor‐induced angiogenesis in many cancers. The purpose of this article is to review published experimental and clinical data for MIF and its involvement in upper aerodigestive tract cancers. Based on the current literature, we propose a biomolecular model describing the mechanisms underlying the involvement of MIF in the initiation, progression, apoptosis, and proliferation of head and neck tumor cells. In reference to this model, potential therapeutic approaches based on the use of MIF antagonists and neutralizing antibodies are described. It is concluded that MIF is a promising target for future therapeutic strategies, both with and without chemoradiation strategies.     

Interleukin‐33 is expressed in differentiated osteoblasts and blocks osteoclast formation from bone marrow precursor cells

Since the hematopoetic system is located within the bone marrow, it is not surprising that recent evidence has demonstrated the existence of molecular interactions between bone and immune cells. While interleukin 1 (IL‐1) and IL‐18, two cytokines of the IL‐1 family, have been shown to regulate differentiation and activity of bone cells, the role of IL‐33, another IL‐1 family member, has not been addressed yet. Since we observed that the expression of IL‐33 increases during osteoblast differentiation, we analyzed its possible influence on bone formation and observed that IL‐33 did not affect matrix mineralization but enhanced the expression of Tnfsf11, the gene encoding RANKL. This finding led us to analyze the skeletal phenotype of Il1rl1‐deficient mice, which lack the IL‐33 receptor ST2. Unexpectedly, these mice displayed normal bone formation but increased bone resorption, thereby resulting in low trabecular bone mass. Since this finding suggested a negative influence of IL‐33 on osteoclastogenesis, we next analyzed osteoclast differentiation from bone marrow precursor cells and observed that IL‐33 completely abolished the generation of TRACP⁺ multinucleated osteoclasts, even in the presence of RANKL and macrophage colony‐stimulating factor (M‐CSF). Although our molecular studies revealed that IL‐33 treatment of bone marrow cells caused a shift toward other hematopoetic lineages, we further observed a direct negative influence of IL‐33 on the osteoclastogenic differentiation of RAW264.7 macrophages, where IL‐33 repressed the expression of Nfatc1, which encodes one of the key transciption factors of osteoclast differentiation. Taken together, these findings have uncovered a previously unknown function of IL‐33 as an inhibitor of bone resorption. © 2011 American Society for Bone and Mineral Research.