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Despite a clear association between type 2 diabetes (T2D) and fracture risk, the pathogenesis of bone fragility in T2D has not been clearly elucidated. Insulin resistance is the primary defect in T2D. Insulin signalling regulates both bone formation and bone resorption, but whether insulin resistance can affect bone has not been established. On the other hand, evidence exists that bone might play a role in the regulation of glucose metabolism. This article reviews the available experimental and clinical evidence on the interplay between bone and insulin resistance. Interestingly, a bilateral relationship between bone and insulin resistance seems to exist that unites them in a biological partnership.

Significance For over three decades, bisphosphonates have been used for the therapy of osteoporosis and skeletal metastasis. Here we show that this class of drugs reduces the viability of tumor cells that are driven by the human epidermal growth factor receptor (HER) family of receptor tyrosine kinases. We also show that bisphosphonates directly bind to and inhibit HER kinases. Because bisphosphonates are inexpensive and readily available worldwide, our findings may have important healthcare implications by offering an affordable and multiuse alternative or adjunct to current therapies for HER-driven malignancy. Bisphosphonates are the most commonly prescribed medicines for osteoporosis and skeletal metastases. The drugs have also been shown to reduce cancer progression, but only in certain patient subgroups, suggesting that there is a molecular entity that mediates bisphosphonate action on tumor cells. Using connectivity mapping, we identified human epidermal growth factor receptors (human EGFR or HER) as a potential new molecular entity for bisphosphonate action. Protein thermal shift and cell-free kinase assays, together with computational modeling, demonstrated that N-containing bisphosphonates directly bind to the kinase domain of HER1/2 to cause a global reduction in downstream signaling. By doing so, the drugs kill lung, breast, and colon cancer cells that are driven by activating mutations or overexpression of HER1. Knocking down HER isoforms thus abrogates cell killing by bisphosphonates, establishing complete HER dependence and ruling out a significant role for other receptor tyrosine kinases or the enzyme farnesyl pyrophosphate synthase. Consistent with this finding, colon cancer cells expressing low levels of HER do not respond to bisphosphonates. The results suggest that bisphosphonates can potentially be repurposed for the prevention and therapy of HER family-driven cancers.

Significance Small molecules to target oncogenic signaling cascades in cancer have achieved success in molecularly defined patient subsets. The path to approval is often protracted and plagued with failures. Repositioning Food and Drug Administration-approved drugs with known side effects has become a major focus. Bisphosphonates are a commonly prescribed therapy for osteoporosis and skeletal metastases. The drugs have also been associated with reduced tumor burden in some patients, but the mechanism is unknown. Here we provide evidence that bisphosphonates inhibit the human EGFR (HER) receptor tyrosine kinase, including the commonly mutated forms that drive nonsmall cell lung cancer, as well as a resistance mutation. This new mechanism lays the basis for the future use of bisphosphonates for the prevention and therapy of HER family-driven cancers. A variety of human cancers, including nonsmall cell lung (NSCLC), breast, and colon cancers, are driven by the human epidermal growth factor receptor (HER) family of receptor tyrosine kinases. Having shown that bisphosphonates, a class of drugs used widely for the therapy of osteoporosis and metastatic bone disease, reduce cancer cell viability by targeting HER1, we explored their potential utility in the prevention and therapy of HER-driven cancers. We show that bisphosphonates inhibit colony formation by HER1 Δᴱ⁷⁴⁶⁻ᴬ⁷⁵⁰-driven HCC827 NSCLCs and HER1 ʷᵗ-expressing MB231 triple negative breast cancers, but not by HER ˡᵒʷ-SW620 colon cancers. In parallel, oral gavage with bisphosphonates of mice xenografted with HCC827 or MB231 cells led to a significant reduction in tumor volume in both treatment and prevention protocols. This result was not seen with mice harboring HER ˡᵒʷ SW620 xenografts. We next explored whether bisphosphonates can serve as adjunctive therapies to tyrosine kinase inhibitors (TKIs), namely gefitinib and erlotinib, and whether the drugs can target TKI-resistant NSCLCs. In silico docking, together with molecular dynamics and anisotropic network modeling, showed that bisphosphonates bind to TKIs within the HER1 kinase domain. As predicted from this combinatorial binding, bisphosphonates enhanced the effects of TKIs in reducing cell viability and driving tumor regression in mice. Impressively, the drugs also overcame erlotinib resistance acquired through the gatekeeper mutation T790M, thus offering an option for TKI-resistant NSCLCs. We suggest that bisphosphonates can potentially be repurposed for the prevention and adjunctive therapy of HER1-driven cancers.

Two of the most commonly used immunosuppressants, cyclosporine A and tacrolimus (FK506), inhibit the activity of a ubiquitously expressed$Ca^{2+}/calmodulin-sensitive$phosphatase, calcineurin. Because both drugs also cause profound bone loss in humans and in animal models, we explored whether calcineurin played a role in regulating skeletal remodeling. We found that osteoblasts contained mRNA and protein for all isoforms of calcineurin A and B. TAT-assisted transduction of fusion protein TAT-calcineurin Aα into osteoblasts resulted in the enhanced expression of the osteoblast differentiation markers Runx-2, alkaline phosphatase, bone sialoprotein, and osteocalcin. This expression was associated with a dramatic enhancement of bone formation in intact calvarial cultures. Calcineurin$A\\alpha^{-/-}$mice displayed severe osteoporosis, markedly reduced mineral apposition rates, and attenuated colony formation in 10-day ex vivo stromal cell cultures. The latter was associated with significant reductions in Runx2, bone sialoprotein, and osteocalcin expression, paralleled by similar decreases in response to FK506. Together, the gain- and loss-of-function experiments indicate that calcineurin regulates bone formation through an effect on osteoblast differentiation.

Osteoporosis is a common chronic condition in elderly women and is associated with decreased bone strength and an increased risk for fractures. As the incidence of osteoporotic fractures continues to rise, it is important to identify the most effective therapies for reducing patients' risk of fracture. This article reviews the medication classes commonly used for treating osteoporosis and the efficacy, tolerability, and drug-interaction potential of specific medications. The evidence for the use of combination therapies is summarized, as are the agents under investigation. Relevant articles were identified through a search of MEDLINE (August 1985–August 2005) using the terms osteoporosis, postmenopausal, fracture, and efficacy combined with drug theapy, calcium, vitamin D, estrogen, progesterone, selective estrogen modulators, calcitonin, strontium ranelate, bisphosphonates, alendronate, risedronate, ibandronate, pamidronate, parathyroid hormone, combination therapy, and zoledronic acid. The identified articles were reviewed for suitability, with priority given to meta-analyses. Among the therapeutic options for the treatment of osteoporosis, the bisphosphonates appear to provide the greatest antiresorptive efficacy, with some bisphosphonates providing 7% to 8% increases in bone mineral density and 60% to 70% decreases in markers of bone resorption. Bisphosphonates also may reduce the incidence of new vertebral fractures by 50% to 52%. Bisphosphonates are currently the first choice for the treatment of osteoporosis. Use of intermittent regimens of the newer bisphosphonates appears to be a promising alternative to administration of daily or weekly treatment.

Menopause is associated with bone loss and enhanced visceral adiposity. A polyclonal antibody that targets the β-subunit of the pituitary hormone follicle-stimulating hormone (Fsh) increases bone mass in mice. Here, we report that this antibody sharply reduces adipose tissue in wild-type mice, phenocopying genetic haploinsufficiency for the Fsh receptor gene Fshr . The antibody also causes profound beiging, increases cellular mitochondrial density, activates brown adipose tissue and enhances thermogenesis. These actions result from the specific binding of the antibody to the β-subunit of Fsh to block its action. Our studies uncover opportunities for simultaneously treating obesity and osteoporosis. An antibody against the pituitary hormone Fsh reduces adiposity and increases thermogenesis in ovariectomized mice or mice fed a high-fat diet. Fat-reducing antibody Menopause is associated with bone loss and enhanced build-up of abdominal fat. Previously, Mone Zaidi and colleagues showed that an antibody against the pituitary hormone Fsh increases bone mass in mice. In this paper, they show that this antibody also reduces fatty tissue in mice that have had their ovaries removed or mice on a high fat diet. The anti-obesity effect is accompanied by increases in UCP1 expression and thermogenesis in brown and beige fat, increased whole-body oxygen consumption rate and physical activity. The authors suggest that these findings could open up opportunities for combined treatment of obesity and osteoporosis.

Background: The MOTION (Monthly Oral Therapy with Ibandronate for Osteoporosis Intervention) study reported that once-monthly ibandronate was noninferior to once-weekly alendronate in terms of increasing bone mineral density (BMD) at the lumbar spine and total hip over 12 months. On analysis of secondary and exploratory end points in MOTION, which included trochanter and femoral neck BMD, monthly ibandronate was found to be noninferior to weekly alendronate. The coprimary, secondary, and exploratory BMD end points from MOTION have been previously reported. Objective: This report presents additional results from the MOTION study, including response rates in terms of lumbar spine and total hip BMD gains above baseline; findings from a comparison of serum concentrations of bone turnover markers; and tolerability analysis, including adverse events that led to withdrawal and gastrointestinal (GI) adverse events. Methods: MOTION was a 12-month (with 15-day follow-up), randomized, multinational, multicenter, double-blind, double-dummy, parallel-group, nonin-feriority study in postmenopausal women aged 55 to <85 years with osteoporosis. Patients were randomly assigned to receive 150-mg-monthly oral ibandronate and weekly alendronate-matched placebo, or 70-mg-weekly oral alendronate and monthly ibandronate-matched placebo, for 12 months. At baseline, day 7 of treatment, 3 and 6 months, 6 months + 7 days, and 12 months, serum concentrations of markers of bone resorption (C-telopeptide of the a chain of type 1 collagen [sCTX]) and bone formation (serum N-terminal propeptides of type 1 collagen) were measured in a subset of the total trial population. At baseline and month 12, BMD was measured using dual-energy x-ray absorptiometry. Exploratory analyses of patients whose spine, total hip, and trochanter BMD at 12 months were above baseline (responders) were also performed. Results: A total of 1760 women were enrolled (ibandronate, 887 patients; alendronate, 873). The median changes in the trough concentrations of sCTX were −75.5% with monthly ibandronate and −81.2% with weekly alendronate. The percentage of patients with mean lumbar spine and total hip BMD gains above baseline (responders) were 90% and 87%, respectively, for ibandronate and 92% and 90%, respectively, for alendronate. GI adverse events were reported in ≤30% of patients per group during this 1-year study. Conclusion: The data from these postmenopausal women with osteoporosis suggest that once-monthly 150-mg ibandronate therapy provided clinically comparable efficacy in terms of BMD response, reductions in bone turnover, and GI tolerability similar to that of weekly 70-mg alendronate.

Osteoporosis is a skeletal disorder characterized by compromised bone strength and increased risk of fracture. Properties related to bone strength include rate of bone turnover, bone mineral density, geometry, microarchitecture, and mean degree of mineralization. These properties (with or without bone density) are sometimes collectively referred to as bone quality. Antiresorptive agents may reduce fracture risk by several separate but interrelated effects on these individual properties. For example, antiresorptive agents have been reported to reduce bone turnover, stabilize or increase bone density, preserve or improve microarchitecture, reduce the number or size of resorption sites, and improve mineralization. Although changes in bone architecture and mineralization are not currently measurable in clinical practice, bone turnover is assessed easily in vivo and affects the other bone properties. Moreover, antiresorptive therapies that produce larger decreases in bone turnover markers together with larger increases in bone mineral density are associated with greater reductions in fracture risk, especially at sites primarily composed of cortical bone such as the hip. Reductions in fracture risk are the most convincing evidence of good bone quality. Data from well-designed randomized clinical trials with up to 10 years of continuous antiresorptive therapy have shown that certain antiresorptive agents effectively reduce fracture risk and (together with extensive preclinical data) suggest no deleterious effects on bone quality.

Nucleoplasmic calcium ions (Ca 2+ ) influence nuclear functions as critical as gene transcription, apoptosis, DNA repair, topoisomerase activation and polymerase unfolding. Although both inositol trisphosphate receptors and ryanodine receptors, types of Ca 2+ channel, are present in the nuclear membrane, their role in the homeostasis of nuclear Ca 2+ remains unclear. Here we report the existence in the inner nuclear membrane of a functionally active CD38/ADP-ribosyl cyclase that has its catalytic site within the nucleoplasm. We propose that the enzyme catalyses the intranuclear cyclization of nicotinamide adenine dinucleotide to cyclic adenosine diphosphate ribose. The latter activates ryanodine receptors of the inner nuclear membrane to trigger nucleoplasmic Ca 2+ release.