Abstract
Insulin-like growth factor-1 (IGF-1) and its binding proteins are critical mediators of skeletal growth. Insulin-like growth factor-binding protein 4 (IGFBP-4) is highly expressed in osteoblasts and inhibits IGF-1 actions in vitro. Yet, in vivo studies suggest that it could potentiate IGF-1 and IGF-2 actions. In this study, we hypothesized that IGFBP-4 might potentiate the actions of IGF-1 on the skeleton. To test this, we comprehensively studied 8- and 16-week-old Igfbp4−/− mice. Both male and female adult Igfbp4−/− mice had marked growth retardation with reductions in body weight, body and femur lengths, fat proportion and lean mass at 8 and 16 weeks. Marked reductions in aBMD and aBMC were observed in 16-week-old Igfbp4−/− females, but not in males. Femoral trabecular BV/TV and thickness, cortical fraction and thickness in 16-week-old Igfbp4−/− females were significantly reduced. However, surprisingly, males had significantly more trabeculae with higher connectivity density than controls. Concordantly, histomorphometry revealed higher bone resorption and lower bone formation in Igfbp4−/− females. In contrast, Igfbp4−/− males had lower mineralized surface/bone surface. Femoral expression of Sost and circulating levels of sclerostin were reduced but only in Igfbp4−/− males. Bone marrow stromal cultures from mutants showed increased osteogenesis, whereas osteoclastogenesis was markedly increased in cells from Igfbp4−/− females but decreased in males. In sum, our results indicate that loss of Igfbp4 affects mesenchymal stromal cell differentiation, regulates osteoclastogenesis and influences both skeletal development and adult bone maintenance. Thus, IGFBP-4 modulates the skeleton in a gender-specific manner, acting as both a cell autonomous and cell non-autonomous factor.
Introduction
IGF signaling is a crucial pathway controlling muscle, fat and bone growth and is regulated by 6 binding proteins, IGFBP1–6. The IGF-binding proteins can enhance or inhibit IGF action locally (Gustafsson et al. 1999, Tahimic et al. 2013). IGFBP-4, which is highly expressed in adipocytes and osteoblasts, is the smallest IGF-binding protein and contains a cleavage site for pregnancy-associated plasma protein A (PAPPA). It also circulates in relatively substantial amounts in both mice and humans. IGFBP-4 can bind IGF-1 and IGF-2 with higher affinity than the IGF receptor but when cleaved by PAPPA, it can no longer sequester IGF (Mohan et al. 1995, Zhou et al. 2003, Mazerbourg et al. 2004).
IGFBP-4 has been reported to be an inhibitor of IGF signaling in vitro in several cell culture models (Culouscou & Shoyab 1991, Schiltz et al. 1993, Gustafsson et al. 1999, Byun et al. 2001). However, in vivo studies of IGFBP-4 have shown conflicting results. Indeed, systemic injections of IGFBP-4 in mice induced bone formation, whereas local injections inhibited IGF actions on the bone (Miyakoshi et al. 2001). Furthermore, overexpression of IGFBP-4 in bone resulted in a decrease in bone formation (Zhang et al. 2003). Yet, when Igfbp4 was knocked out, mice were born with a decreased body weight persisting up to 14 weeks after birth. It was therefore suggested that IGFBP-4 could regulate prenatal growth by stabilizing IGF-2 before being cleaved by PAPPA leading to increased IGF-2 availability (Ning et al. 2008). However, the impact of IGFBP-4 depletion on adults remains unclear. Additionally, past studies have not clarified whether deletion of Igfbp4 affected females and males as well as specific tissues differentially. Because IGF-1 and IGF-2 play different roles during embryonic life and adulthood, IGFBP4 mechanisms may differ in fetal vs adult animals.
To shed light on the role of IGFBP-4 during postnatal development and in adult mice, we investigated the phenotypes of Igfbp4-null (Igfbp4−/−) females and male mice at 8 and 16 weeks of age; when peak bone mass acquisition is known to occur (Klein et al. 1998). Our results suggest that the growth retardation caused by loss of Igfbp4 persists in adult female and male mice. However, the skeletal phenotype of Igfbp4-null mice was gender specific and point to a potential role for this binding protein in skeletal growth and maintenance that is both cell autonomous and cell non-autonomous.
Material and methods
Animals
Igfpb4−/− mice were a gift from Dr Peter Brooks at Maine Medical Center Research Institute and were generated from the KOMP allele project at University of California Davis. They were produced on the C57BL/6J background by deleting exon 2 of Igfbp4, which results in the global loss of IGFBP-4. Genotyping strategy consisted in PCR reactions using primer sets for the wild-type allele (forward: GGTAAACTGGCTCGGATTAGGG; reverse: TTGACTGTAGCGGCTGATGTTG) or the null allele (forward: TTGACTGTAGCGGCTGATGTTG; reverse: TGCCACAGTACCTCCCTTCTC) to distinguish between Igfbp4−/−-null mice, Igfbp4+/+ control littermates or Igfbp4+/− heterozygous mice. The mice were bred and maintained in a colony under 14:10 h light:darkness cycles at Maine Medical Center Research Institute in polycarbonate cages with sterilized paper bedding. Mice had ad libitum access to sterilized water and Teklad Global 18% Protein Rodent Diet (Harlan Laboratories, Indianapolis, IN, USA). Phenotyping of the mice was performed at 8 and 16 weeks of age (n = 10). For the ovariectomy study, 8-week-old mice were subjected to ovariectomy or sham operation (n = 5–8/surgery/genotype). They were then placed on a standard AIN93M diet (Research Diets, Inc, New Brunswick, NJ, USA), which does not contain phytoestrogens. At 16 weeks of age, mice were killed for harvest. All experimental procedures were approved by the Institutional Animal Care and Use Committee at the Maine Medical Center Research Institute.
Dual-energy X-ray absorptiometry (DXA)
Dual-energy X-ray absorptiometry (DXA) was performed on 8- and 16-week-old animals to assess the body composition by measuring whole-body areal bone mineral density (aBMD), areal bone mineral content (aBMC), lean mass and fat proportion. Measurements were taken with exclusion of the head using the PIXImus densitometer (GE-Lunar, Fairfield, CT, USA). A phantom standard provided by the manufacturer was used for instrument calibration before each measurement.
Micro-computed tomography
Microarchitecture of distal trabecular bone and midshaft cortical bone was analyzed in femora from 16-week-old mice by high-resolution micro-computed tomography (μCT) (VivaCT-40, 10-μm resolution; Scanco Medical AG, Bassersdorf, Switzerland). The machine was calibrated weekly using a phantom provided by the manufacturer. Femurs were scanned at an energy level of 55 kVp and intensity of 145 μA, as described previously (Motyl et al. 2013). All scans were analyzed using manufacturer software (Scanco, version 4.05) in accordance with published guidelines. Scans for the cortical region were measured at the mid-point of each femur, with an isotropic pixel size of 21 µm and slice thickness of 21 μm and used to calculate the average total cross-sectional area (mm2), bone area (mm2) and marrow area (mm2). For midshaft analysis, the cortical shell was contoured by user-defined threshold and iterated across the 50 slices. Trabecular bone volume fraction and microarchitecture were evaluated in the secondary spongiosa, starting proximately at 0.6 mm proximal to the growth plate and extending proximally 1.5 mm. Approximately 230 consecutive slices were made at 10.5 μm interval at the distal end of the growth plate and extending in a proximal direction, and 180 contiguous slices were selected for analysis.
Serum proteins
Blood was collected from 16-week-old animals and spun at 1000 g for 10 min at room temperature. The serum phase was collected and stored at −80°C before being used in assays. IGFBP circulating levels were measured in sera using MILLIPLEX MAP Mouse IGF-Binding Protein Magnetic Bead Panel (EMD Millipore) according to the manufacturer guidelines. Samples were diluted 25-fold before being processed using magnetic beads labeled with antibodies against IGFBP-1, IGFBP-2, IGFBP-3, IGFBP-5 and IGFBP-6. Samples were read using the Luminex 200 System (EMD Millipore) previously calibrated with xPONENT 3.1 compatible Calibration Kit, and performance was verified with the Performance Verification Kit provided by the manufacturer. Total IGF-1 (free and bound), sclerostin and RANKL levels were measured using ELISA kits (IGF-1: Immunodiagnostic Systems, Gaithersburg, MD, USA; Sclerostin: Alpco, Salem, NH, USA, RANKL: R&D Systems) according to the manufacturers’ instructions. Assay sensitivity was 2.8 ng/mL, 7.4 pg/mL and 5 pg/mL for the IGF1, sclerostin and RANKL ELISAs, respectively. The intra-assay variation coefficients were 5.8, 6.4 and 4.3% for the IGF-1, sclerostin and RANKL ELISAs, respectively. The inter-assay variation coefficients were 7.8, 10.25 and 6.8% for the IGF-1, sclerostin and RANKL ELISAs, respectively. All measurements for ELISA were performed in duplicates.
Histomorphometry
Calcein and demeclocycline were injected intraperitoneally at 20mg/kg of body weight at respectively 9 days and 2 days prior to killing the mice at 16 weeks of age. Tibiae were fixed for 48 h in 10% buffered formalin and stored in 70% ethanol. The fixed tibiae were dehydrated with graded ethanol and acetone before being embedded in methyl methacrylate. 4 μm consecutive sections were stained with von Kossa, 2% toluidine blue, pH 3.7 or left unstained to, respectively, observe mineralization, count osteoblasts, osteoid, osteoclasts and adipocytes or fluorescence labeling. Analysis was performed 200 μm away from the growth plate using the OsteoMeasure analyzing software (Osteometrics Inc, Decatur, GA, USA). Standard nomenclature was used for the report.
Quantitative PCR
Total RNA was isolated from cell cultures or flash frozen femurs of 16-week-old mice using TRIzol (Life Technologies) method for tissues. Bone marrow contents were not flushed out from femurs prior to RNA isolation. RNA concentrations were estimated using NanoDrop2000 (Thermo Fisher Scientific), and 500 ng RNA was used as template for the reverse transcription reaction into cDNA using High-Capacity cDNA Reverse Transcription Kit (Thermo Fisher Scientific). The cDNA was diluted 1:20 in nanopure water before being used for quantitative PCR. The iQ SYBR Green Supermix and iQ5 thermal cycler detection system (BioRad) were used to quantify RNA expression. GeNorm kit was used to find the most stable housekeeping gene for bone, which was determined as Hprt. Primers for the housekeeping gene and the genes of interest were purchased from PrimerDesign (Southampton, UK) and designed to be 95–100% efficient. Sequences for primers were as follows: Bglap: sense: ACCTCACAGATGCCAAGCC, antisense: ATCTGGGCTGGGGACTGAG; Hprt: sense: TCCTCCTCAGACCGCTTTT, antisense: AGGTATACAAAACAAATCTAGGTCAT; Igf1r: sense: TAATGACAACACTTAATAGCAACAG, antisense: GTAAAGCAGAAAAGAGAGAAAGGA; Igfbp4: sense: TACCCACGAAGACCTCTTCATC, antisense: GTCTTCCGATCCACACACCA; Runx2: sense: ACCTAACAGTCTTCACAAATCCT, antisense: GAGGCGATCAGAGAACAAACTA; Sost: sense: TGAGAACAACCAGACCATGAAC, antisense: TCAGGAAGCGGGTGTAGTG; Sp7: sense: ATGGCGTCCTCTCTGCTTG, antisense: TTCCCCAGGGTTGTTGAGTC, Tnfrsf11b: sense: AAATTGGCTGAGTGTTTTGGTG, antisense: CTGTGTCTCCGTTTTATCCTCTC; Tnfsf11: sense: TTTGCACACCTCACCATCAAT, antisense: CCCTTAGTTTTCCGTTGCTTAAC.
Primary cell cultures
Bone marrow stromal cells (BMSCs) and hematopoietic stem cells (HSCs) were isolated from femurs and tibias from 8-week-old mice. After the bones were harvested and cut at their distal end, bone marrow contents were spun out by centrifuging at 13,000 g for 1 min. Cell pellets were resuspended in culture media composed of MEMα with 10% FBS and 1% penicillin/streptomycin.
For BMSCs differentiation into osteoblasts, cells were plated in 6-well plates at 1,000,000 cells/cm2. Culture media was replenished every other day. Once cultures were confluent, cells were switched to an osteoblast differentiation media consisting of culture media supplemented with 8 mM β-glycerol phosphate (Sigma-Aldrich) and 0.2 mM ascorbic acid (Sigma-Aldrich). After 7 days of differentiation, cells were fixed with 4% PFA in PBS for 12 min at room temperature. Alkaline phosphatase staining was performed using the Leukocyte Alkaline Phosphatase kit (Sigma-Aldrich) according the manufacturer’s guidelines. For von Kossa staining, 5% silver nitrate solution in water was added to the fixed cells for 1 h with a direct light exposure. Cells were washed with water before being placed in a 5% sodium thiosulfate solution in water for 3 min. Cells were washed and mineral deposits were stained brown.
For HSCs differentiation into osteoclasts, cells were plated at 250,000 cells/cm2 in 96-well plates (Corning) in culture media supplemented with RANKL and mCSF. Culture media was changed every 72 h. TRAP staining was performed to stain osteoclasts. Briefly, cells were fixed with 2.5% glutaraldehyde solution in PBS for 30 min and washed twice with PBS. The acid phosphatase, leukocytes (TRAP) kit (Sigma-Aldrich) was used for TRAP staining according to the manufacturer’s guidelines. Cells were counted as osteoclasts when positive for TRAP (purple) and with 3 or more nuclei. To assess osteoclastic resorption, cells were plated on the Osteo Assay Surface (Corning) made with an inorganic crystalline calcium phosphate matrix. Surfaces were colored by von Kossa staining, and pictures of wells were taken to observe how much matrix had been resorbed. In vitro assays of osteoblastogenesis and osteoclastogenesis were repeated 3 times.
Statistical analysis
All data are expressed as the mean ± standard error of the mean (s.e.m.). Results were analyzed for statistically significant differences using a Student t-test or a two-way ANOVA followed by Bonferroni’s multiple comparison post hoc test. All statistics were performed with Prism 6 statistical software (GraphPad Software). Statistical significance was set at P < 0.05.
Results
IGF-1 and IGFBP levels of Igfbp4−/−l mice
The deletion of the exon 2 of Igfbp4 resulted in a loss of Igfbp4 expression in adipose tissues, liver and femur (Supplementary Fig. 1, see section on supplementary data given at the end of this article). There were no alterations in the serum levels of IGFBP-1, 2, 3 and 5 with loss of Igfbp4 (Fig. 1A, B, C and D); however, an increase of IGFBP-6 was detected in the serum of Igfbp4−/− females when compared to that in controls (Fig. 1E). At 16 weeks of age, total circulating IGF-1 levels were increased in Igfbp4−/− females (324.6 ± 9.8 ng/mL vs 251.4 ± 28.3 ng/mL P = 0.03, Fig. 1F) but decreased in males (299.1 ± 8.8 ng/mL vs 205.8 ± 33.0 ng/mL vs 299.1 ± 8.8 ng/mL P = 0.01, Fig. 1F).
Growth retardation of Igfbp4−/− mice
Igfbp4−/− mice had a significant reduction in body weight at 8 (females: 20.02 ± 0.43 g vs 18.64 ± 0.25 g, P = 0.008, males: 26.83 ± 0.41 g vs 24.64 ± 0.58 g, P = 0.008, Fig. 2A) and 16 weeks of age (females: 25.72 ± 0.74 g vs 22.51 ± 0.44 g P = 0.0009, males: 34.71 ± 0.58 g vs 30.17 ± 0.96 g, P = 0.001, Fig. 2A). Igfbp4−/− mice were smaller with shorter body length (females: 162.0 ± 2.54 mm vs 156.6 ± 0.74 mm P = 0.02, males: 168.8 ± 1.35 mm vs 163.9 ± 0.68 mm, P = 0.003) and femur length (females: 15.9 ± 0.08 mm vs 15.6 ± 0.07 mm P = 0.04, males: 16.3 ± 0.14 mm vs 15.8 ± 0.16 mm, P = 0.03) at 16 weeks of age (Fig. 2B and C). To investigate whether the decreased growth of Igfbp4−/− mice was affecting body compartments differentially, we used DXA to assess body composition. At 8 and 16 weeks of age, significant reductions of fat proportion and lean mass were observed in Igfbp4−/− mice (Fig. 3A and B). There were no significant differences in aBMD or aBMC in 8-week-old animals. However, at 16 weeks of age, Igfbp4−/− females had significant reductions in aBMD (0.049 ± 0.0005 g/cm2 vs 0.047 ± 0.0003 g/cm2, P = 0.006, Fig. 3C) and aBMC (0.41 ± 0.006 g vs 0.39 ± 0.008 g, P = 0.03, Fig. 3D) compared to littermate controls. Igfbp4−/− males had no significant differences in these parameters at both ages (Fig. 3C and D). Taken together, our results are concordant with a previous report by Ning and coworkers in which mice with deletion of Igfbp4 presented with postnatal growth retardation (Ning et al. 2008). However, in 16-week-old mice, our data suggest that females and males are affected differently at the skeletal level and this difference appears after the postnatal growth period.
Gender-specific bone phenotype Igfbp4−/− mice
To investigate the microarchitecture of bone, μCT analysis was performed on femurs of 16-week-old mice. Trabecular BV/TV (5.435 ± 0.225% vs 4.170 ± 0.394%, P = 0.02) in the distal compartment of the femur was significantly decreased in Igfbp4−/− females when compared to littermate controls (Fig. 4A). Trabecular thickness was also decreased in Igfbp4−/− females (Fig. 4B), whereas trabecular separation was increased (Fig. 4D). Significant reductions were also observed in cortical area fraction (Ct.A/TA: 49.80 ± 0.26% vs 48.52 ± 0.48%, P = 0.03, Fig. 4G) and cortical thickness (0.2203 ± 0.001 μm vs 0.2139 ± 0.002 μm, P = 0.009, Fig. 4H) at the femur midshaft. Despite showing no change in trabecular BV/TV and thickness, Igfbp4−/− males had significantly higher trabecular number (4.68 ± 0.08/mm vs 5.13 ± 0.06/mm, P = 0.0003, Fig. 4B) and connectivity density (138.0 ± 9.09 mm3 vs 168.1 ± 7.12 mm3, P = 0.02, Fig. 4E) than littermate controls. Unlike Igfbp4−/− females, males did not show alterations of cortical bone with deletion of Igfbp4 (Fig. 4G and H). Thus, our results indicate that there is a clear gender-specific bone phenotype observed in adult mice with loss of Igfbp4.
Histomorphometry of Igfbp4−/− mice
We performed histomorphometry on the proximal tibia to examine whether deletion of Igfbp4 resulted in different alterations in the multicellular components of bone remodeling in males and females. Histomorphometry analysis of Igfbp4−/− females and littermate controls were partially concordant with the μCT results (Table 1). Indeed, bone formation parameters (MS/BS, MAR, BFR and OS/BS) tended to be lower in Igfbp4−/− females; yet, only differences in mineral apposition rate reached statistical significance. Interestingly, the number and surface of osteoblasts were modestly increased with the deletion of Igfbp4 in females (Table 1). However, the numbers and surface of osteoclasts were also markedly higher leading to a significant increase in eroded surface in Igfbp4−/− females (Table 1). Thus, those increases in osteoclast numbers and surfaces accompanied by the decrease of mineralization might explain the significant reduction of cortical and trabecular bone observed in Igfbp4−/− females.
Histomorphometry of Igfbp4−/− mice.
Females | Males | |||||
---|---|---|---|---|---|---|
Igfbp4+/+ | Igfbp4−/− | t-Test | Igfbp4+/+ | Igfbp4−/− | t-Test | |
MS/BS (%) | 38.7 ± 1.77 | 36.21 ± 1.31 | 0.076 | 41.16 ± 2.74 | 28.46 ± 3.59 | 0.049 |
MAR (µm/day) | 1.82 ± 0.02 | 1.63 ± 0.07 | 0.037 | 1.04 ± 0.06 | 0.93 ± 0.04 | 0.215 |
BFR (µm3/µm2/day) | 0.68 ± 0.06 | 0.59 ± 0.04 | 0.216 | 0.41 ± 0.04 | 0.30 ± 0.03 | 0.062 |
Ob.S/B.Pm | 12.77 ± 1.21 | 16.10 ± 2.10 | 0.207 | 2.96 ± 0.81 | 1.68 ± 0.35 | 0.139 |
N.Ob/B.Pm | 8.72 ± 0.83 | 10.92 ± 1.31 | 0.173 | 2.24 ± 0.64 | 1.66 ± 0.31 | 0.405 |
OS/BS µ | 9.21 ± 1.38 | 7.81 ± 1.42 | 0.485 | 11.03 ± 1.31 | 4.28 ± 1.09 | 0.003 |
O.Th | 2.58 ± 0.12 | 2.59 ± 0.12 | 0.158 | 2.36 ± 0.19 | 2.11 ± 0.13 | 0.308 |
Oc.S/BS | 12.3 ± 0.79 | 14.97 ± 0.60 | 0.022 | 6.99 ± 0.46 | 6.69 ± 0.92 | 0.782 |
N.Oc/B.Pm | 4.24 ± 0.18 | 5.05 ± 0.21 | 0.016 | 2.95 ± 0.17 | 2.77 ± 0.31 | 0.624 |
ES/BS | 3.96 ± 0.35 | 6.38 ± 0.99 | 0.048 | 1.23 ± 0.37 | 1.90 ± 0.45 | 0.282 |
N.Ad/T.Ar | 42.73 ± 8.16 | 50.12 ± 4.19 | 0.482 | 5.13 ± 2.29 | 5.79 ± 2.94 | 0864 |
Static and dynamic histomorphometry analysis of proximal tibia labeled with calcein and demeclocycline from Igfbp4−/− mice compared to littermate controls at 16 weeks of age. Bold values represent measurements for which the difference from littermate gender-matched controls reach statistical significance.
BFR/BS, bone formation rate/bone surface; ES/BS, erosion surface/bone surface; MAR, mineral aposition rate; MS/BS, mineralized surface/bone surface; N.Ad/T.Ar, number of adipocyte/total area; N.Ob/B.Pm, number of osteoblast/bone perimeter; N.Oc/B.Pm, number of osteoclast/bone perimeter; Ob.S/B.Pm, osteoblast surface/bone perimeter; Oc.S/BS, osteoclast surface/bone surface; OS/BS, osteoid surface/bone surface; O.Th, osteoid thickness. (n = 5–6/genotype/gender, t-test P values were considered statistically different when P value <0.05.)
There was a decrease in osteoid surface per bone surface and mineralization surface in 16-week-old Igfbp4−/− males (Table 1). However, there were no significant differences in the number of osteoblasts and osteoclasts compared to those in littermate controls (Table 1). Taken together, our data show that loss of Igfbp4 affects bones of female and male mice differentially with distinct alterations in cells of the bone-forming unit.
Ovariectomy-induced bone loss is blunted in Igfbp4−/− mice
Previous studies have reported that estrogen could regulate Igfbp4 transcription (Kassem et al. 1996, Qin et al. 1999, Wang et al. 2004, Mita et al. 2007). Moreover, estrogen is known to regulate bone resorption and osteoclastogenesis (Kameda et al. 1997, Riggs 2000, Kondoh et al. 2014). Thus, we postulated that estrogen could regulate Igfbp4 expression within the bone, which could explain that gender-specific phenotype. To test our hypothesis, we ovariectomized 8-week-old Igfbp4−/− females and littermate controls to examine bone loss observed during estrogen depletion. Igfbp4 mRNA level was significantly decreased in femurs of Igfbp4+/+ mice after 8 weeks of ovariectomy (Fig. 5A). Igfbp4+/+ ovariectomized females had a significant loss of aBMD and aBMC compared to those in sham-operated animals (aBMD: 0.049 ± 0.0004 g/cm2 vs 0.045 ± 0.002 g/cm2, P = 0.006, aBMC: 0.41 ± 0.002 g vs 0.36 ± 0.005 g, P = 0.01, Fig. 5B and C). However, total aBMD and aBMC were not significantly different between Igfbp4−/− ovariectomized females and sham-operated controls (Fig. 5B and C).
μCT analysis revealed markedly decreased trabecular bone volume in Igfbp4+/+ ovariectomized mice (Fig. 6A, B, C, D, E and F). Albeit for trabecular separation, which was increased in both Igfbp4−/− and Igfbp4+/+ mice upon ovariectomy (Fig. 6D), no changes were observed between sham-operated and ovariectomized Igfbp4−/− mice. Similarly, cortical area fraction (Fig. 6G) and cortical thickness (Fig. 6H) were reduced upon ovariectomy in Igfbp4+/+ mice but not in Igfbp4−/− mice. These data indicate that Igfbp4−/− females are partially protected against trabecular bone loss caused by estrogen deficiency.
Primary marrow cell cultures
To resolve whether the gender-specific alterations of the bone-forming unit caused by loss of Igfbp4 could be recapitulated in vitro, we isolated BMSCs and HSCs from Igfbp4−/− and Igfbp4+/+ mice for evaluation of osteoblastogenesis and osteoclastogenesis in vitro. Consistent with the increase in osteoblast and osteoclast numbers noted by histomorphometry, there was an increase in osteoblastogenesis (Fig. 7A and B) and osteoclastogenesis (Fig. 8A) in cells isolated from Igfbp4−/− females compared to those from Igfbp4+/+. Also, female Igfbp4−/− osteoclasts appeared to have a higher resorbing activity than controls (Fig. 8B). Although male Igfbp4−/− BMSCs showed greater osteoblastogenesis (Fig. 7C and D), there was a reduction of osteoclastogenesis and osteoclastic resorption compared to that in controls (Fig. 8C and D). Taken together, the in vitro data support the hypothesis that loss of Igfbp4 affects the differentiation of progenitor cells and the functions of osteoblasts and osteoclasts.
Femoral gene expression and circulating protein levels in Igfbp4−/− mice
Because loss of Igfbp4 affected males and females differently, we hypothesized that molecular mechanisms regulating bone were also altered in a gender-specific fashion. To address this question, we first examined the expression of bone-related genes: Runx2, Sp7, Bglap, Sost, Tnfsf11, Tnfrsf11b and Igf1r in the femurs of 16-week-old Igfbp4−/− and Igfbp4+/+ mice. Although no significant changes were detected in Igfbp4−/− females (Fig. 9A), Igfbp4−/− males showed decreased expressions of Sp7 and Sost and Tnfs11 when compared to Igfbp4+/+ males (Fig. 9B). The downregulation of Sp7, coding for Osterix, could be consistent with the lower mineralization revealed by histomorphometry (Table 1).
Next, we tested whether the reductions of Tnfs11 and Sost, coding for RANKL and Sclerostin, respectively, were reflected at the circulating level. Measurement of RANKL in the serum of male mice showed no differences between Igfbp4−/− mice and controls (Fig. 10A). However, we observed a mild but significant decrease of circulating Sclerostin at 16 weeks of age in Igfbp4−/− males (51.24 ± 1.06 pg/mL vs 46.74 ± 1.17 pg/mL, P = 0.01, Fig. 10B). Taken together, our results indicate that IGFBP-4 is important for normal growth in adult mice. IGFBP-4 appears to be important for the development and maintenance of bone by locally affecting osteoblast and osteoclast function in a gender-specific manner.
Discussion
In this study, we hypothesized that IGFBP-4 might play an important role in sequestering IGF-I in the adult skeleton and therefore act distinctly in vivo vs in vitro. Instead, we found evidence that IGFBP-4 can act in both a cell autonomous and cell non-autonomous manner and sex specifically to influence the adult skeleton. This is in sharp contrast to the earliest characterization of the IGF-binding proteins, particularly, IGFBP-4 that has been considered within the framework of an inhibitory protein that blocked IGF-1 and IGF-2 actions in various cell systems (Culouscou & Shoyab 1991, Schiltz et al. 1993, Gustafsson et al. 1999). Previous attempts at studying the in vivo actions of IGFBP-4 were limited to characterizing murine embryonic and postnatal mechanisms of IGFBP-4 without specifically looking at sexual dimorphism (Ning et al. 2006, 2008). In contrast, we examined pubertal and adult skeletal maintenance in C57BL/6J mice by phenotyping mice with a germline deletion of the Igfbp4 gene. In this study, we show that IGFBP-4 is required for the sustained growth of adult female and male mice. We found that loss of Igfbp4 resulted in growth retardation marked by decreased fat proportion, lean mass, body length and body weight. An elegant study performed by Ning and coworkers previously reported the growth retardation caused by deletion of Igfbp4 starts during embryonic life and persists up to 14 weeks of age (Ning et al. 2008). Interestingly, although no alterations of the bone mass were detected by DXA at 8 weeks of age, we noted that 16-week-old Igfbp4−/− females had significant decreases in aBMD and aBMC when compared to those in littermate controls (Fig. 3C and D). This suggests that IGFBP-4 plays a role in regulating bone acquisition during the post-pubertal growth period (i.e. between 8 and 16 weeks of age) in mice.
Interestingly, the growth phenotype of both males and females was not concordant with the circulating total IGF-1 levels (Fig. 1F). Indeed, although both genders suffered from growth retardation, only Igfbp4−/− males had a significant reduction in serum IGF-1 levels, whereas Igfbp4−/− females showed increased circulating levels of IGF-1. Thus, the growth retardation phenotype may not be caused by a systemic alteration of IGF-1 in female mice. However, serum levels of IGFBP-6 were also markedly increased in Igfbp4−/− females (Fig. 1E). IGFBP-6 has a higher affinity for IGF-2 than IGF-1 (Gustafsson et al. 1999, Konermann et al. 2013, Raykha et al. 2013). IGF-2 is principally involved in the regulation of placental and fetal growth in mice and its expression is highest in the brain of adult mice (Nielsen 1992, Constancia et al. 2002, Ferron et al. 2015). Thus, we suspect that the increase observed in circulating levels of IGFBP-6 might not have a significant impact on adult growth of Igfbp4−/− females. Furthermore, it has been shown that IGFBP-6 could inhibit osteoblast differentiation (Strohbach et al. 2008). Yet, Igfbp4−/− females showed increased osteoblastogenesis by histomorphometry (Table 1) suggesting that the increased circulating IGFBP-6 levels cannot explain the skeletal phenotype of Igfbp4−/− females. Instead, we propose that tissue-specific regulation of IGF-1 might be causing the skeletal phenotype.
To our knowledge, this is the first study to systematically examine the bones of adult Igfbp4−/− mice. Here, we show that the deletion of Igfbp4 resulted in a sex-specific modification of bone microarchitecture with reduced cortical and cancellous bone in females but a mild increase in trabeculae in males (Fig. 4). Histomorphometry of the tibia revealed that Igfbp4−/− females had more osteoclasts resulting in increased eroded surface/bone surface but decreased bone formation suggesting a significant uncoupling in the bone remodeling unit (Table 1). In contrast, Igfbp4−/− males had more trabeculae but the struts were thinner and there were no alterations in bone volume fraction (Fig. 4).
Based on our observations about the sex differences, we hypothesized that the bone loss observed in female Igfbp4−/− mice might be related to an alteration in estrogen regulation of IGFBP-4. In fact, it has been shown that estrogen induces Igfbp4 gene transcription in osteoblastic and breast cancer cells (Kassem et al. 1996, Qin et al. 1999). Therefore, deletion of Igfbp4 in females could recapitulate an estrogen deficiency state. This is supported by the increase in bone turnover observed in Igfbp4−/− females (Table 1). Similarly, ovariectomized Igfbp4−/− mice did not lose trabecular bone as their littermate controls did (Figs 5 and 6). This could be due to the fact that Igfbp4−/− females have low bone mass independent of estrogen withdrawal and thus, the effects on the skeleton from ovariectomy are minimal compared to ovariectomy in Igfbp4+/+ females. On the other hand, this may imply that loss of IGFBP4 indirectly reflects loss of estrogen signaling to bone cells. Notwithstanding, estrogen does not appear to be the only regulator of Igfbp4 within bone or the circulation as ovariectomy does not completely obliterate Igfbp4 expression (Fig. 5A). Taken together, our findings are consistent with other studies of the IGFBPs suggesting that estrogen can target IGF-binding proteins as one means of regulating IGF signaling in bone cells.
The cell autonomous actions of IGFBP-4 are potentially very important. Histomorphometric studies pointed to significant skeletal effects from global loss of Igfbp4. Thus, we examined the process of osteoclastogenesis and osteoblastogenesis in vitro using primary cells from controls and mutants. Our in vitro cultures of HSCs recapitulated the phenotype we detected by histomorphometry of greater osteoclastogenesis and a larger eroded surface in Igfbp4−/− females (Fig. 8A and B). On the other hand, bone marrow stromal cell cultures revealed an enhanced osteogenic capacity compared to wild-type controls (Fig. 7). Bone marrow stromal cells isolated from Igfbp4−/− male mice also showed increased osteoblastogenesis and mineralization but decreased osteoclastogenesis. The decrease in osteoclasts might explain why Igfbp4−/− males have increased trabecular number. However, it is likely that with higher rates of osteogenesis, Igfbp4−/− males could maintain cortical and trabecular bone volumes similar to littermate controls.
Despite the increase in mineralization seen in vitro in cells from Igfbp4−/− males (Fig. 7C and D), histomorphometry and gene expression analysis revealed decreased mineralization and expression of Sp7 in femurs of Igfbp4−/− males (Fig. 9B and Table 1). It is likely that certain aspects of the regulatory mechanism cannot be recapitulated in vitro in a cell autonomous fashion. In support of this hypothesis, Sost femoral expression (Fig. 9B) and circulating levels of Sclerostin were both decreased in 16-week-old Igfbp4−/− males (Fig. 10B) suggesting a more systemic alteration of bone regulation in Igfbp4−/− mice. Indeed, Sclerostin is an inhibitor of Wnt signaling and Sost-knockout mice have higher bone mass (Li et al. 2008). Although this decrease in Sclerostin might contribute to the increase in trabecular number revealed by μCT and histomorphometry, it does not explain why bone volume is not affected in 16-week-old Igfbp4−/− males.
In summary, our study shows that Igfbp4 is required for normal adult growth of bone and lean mass in mice. Our data also revealed that Igfbp4 was particularly important during the period of peak bone mass acquisition, occurring between 8 and 16 weeks of age in mice. However, there is a clear sex specificity with global deletion of IGFBP-4. Igfbp4−/− females do not gain bone during peak bone mass acquisition, but Igfbp4−/− males are able to acquire sufficient bone mass. Loss of Igfbp4 was sufficient to create a cell autonomous phenotype observed in vitro with increased osteoblastogenesis in Igfbp4−/− cells. A gender dimorphism was also observed in vitro with osteoclastic activity being increased in cells from Igfbp4−/− female mice but decreased in Igfbp4−/− males. Thus, we propose that IGFBP-4 has systemic as well as tissue- and sex-specific actions on the regulation of osteoblastogenesis and osteoclastogenesis. Those actions of IGFBP-4 are most likely conserved in humans. Indeed, IGFBP-4 circulating levels were elevated in older women with hip and spine fractures (Rosen et al. 1992). IGFBP-4 serum levels were also correlated with bone mineral density in growth hormone-deficient adults (Thoren et al. 1998). Furthermore, a locus 500 bp upstream of human Igfbp4 was found to be regulatory of height in a GWAS (Berndt et al. 2013). Thus, IGFBP-4 in humans as in mice appears to be important for growth but our study shows clear sexual dimorphism in mice.
Previous reports showed that overexpression of IGFBP-4 in osteoblasts decreased bone formation and femoral length (Zhang et al. 2003), whereas systemic injections of IGFBP-4 resulted in increased bone formation (Miyakoshi et al. 2001). Those studies concluded that IGFBP-4 is necessary to sequester IGF-I in the bone environment and increased its bioavailability. Our results are concordant with this proposed mechanism where IGFBP-4 is required for adult bone growth with sex specificity. One possible mechanism for the sex differences relate to the role estrogen might play in regulating IGFBP-4 expression in bone. Our study reinforces the importance of studying both sexes as well as different ages when studying skeletal phenotypes from global or conditional deletion of genes in the IGF regulatory system. Our findings also support the long-standing tenet that the IGFBPs work in a cell- and context-specific manner such that assignment of their functional significance is complex.
Supplementary data
This is linked to the online version of the paper at http://dx.doi.org/10.1530/JOE-16-0673.
Declaration of interest
The authors declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported.
Funding
This work was supported by the National Institutes of Health (R01 AR061164-01A1).
Acknowledgements
We wish to thank Peter Brooks, PhD for donating the Igfbp4−/− mice and Casey R Doucette, PhD for her expertise of the Milliplex assay. This project was supported by the Physiology Core of grant number P20GM103465, COBRE and the Molecular Phenotyping Core of grant number P30GM106391, COBRE in Stem Cell Biology and Regenerative Medicine (D Wojchowski, PI) and by the Mouse Transgenic and In Vivo Imaging Core facility of grant number P30GM103392, Phase III COBRE in Vascular Biology (L Liaw, PI). All grants are supported by the National Institute of General Medical Sciences.
References
Berndt SI, Gustafsson S, Mägi R, Ganna A, Wheeler E, Feitosa MF, Justice AE, Monda KL, Croteau-Chonka DC & Day FR et al. 2013 Genome-wide meta-analysis identifies 11 new loci for anthropometric traits and provides insights into genetic architecture. Nature Genetics 45 501–512. (doi:10.1038/ng.2606)
Byun D, Mohan S, Yoo M, Sexton C, Baylink DJ & Qin X 2001 Pregnancy-associated plasma protein-A accounts for the insulin-like growth factor (IGF)-binding protein-4 (IGFBP-4) proteolytic activity in human pregnancy serum and enhances the mitogenic activity of IGF by degrading IGFBP-4 in vitro. Journal of Clinical Endocrinology and Metabolism 86 847–854. (doi:10.1210/jc.86.2.847)
Constancia M, Hemberger M, Hughes J, Dean W, Ferguson-Smith A, Fundele R, Stewart F, Kelsey G, Fowden A & Sibley C et al. 2002 Placental-specific IGF-II is a major modulator of placental and fetal growth. Nature 417 945–948. (doi:10.1038/nature00819)
Culouscou JM & Shoyab M 1991 Purification of a colon cancer cell growth inhibitor and its identification as an insulin-like growth factor binding protein. Cancer Research 51 2813–2819.
Ferron SR, Radford EJ, Domingo-Muelas A, Kleine I, Ramme A, Gray D, Sandovici I, Constancia M, Ward A & Menheniott TR et al. 2015 Differential genomic imprinting regulates paracrine and autocrine roles of IGF2 in mouse adult neurogenesis. Nature Communications 6 8265. (doi:10.1038/ncomms9265)
Gustafsson T, Andersson P & Arnqvist HJ 1999 Different inhibitory actions of IGFBP-1, -2 and -4 on IGF-I effects in vascular smooth muscle cells. Journal of Endocrinology 161 245–253. (doi:10.1677/joe.0.1610245)
Kameda T, Mano H, Yuasa T, Mori Y, Miyazawa K, Shiokawa M, Nakamaru Y, Hiroi E, Hiura K & Kameda A et al. 1997 Estrogen inhibits bone resorption by directly inducing apoptosis of the bone-resorbing osteoclasts. Journal of Experimental Medicine 186 489–495. (doi:10.1084/jem.186.4.489)
Kassem M, Okazaki R, De León D, Harris SA, Robinson JA, Spelsberg TC, Conover CA & Riggs BL 1996 Potential mechanism of estrogen-mediated decrease in bone formation: estrogen increases production of inhibitory insulin-like growth factor-binding protein-4. Proceedings of the Association of American Physicians 108 155–164.
Klein RF, Mitchell SR, Phillips TJ, Belknap JK & Orwoll ES 1998 Quantitative trait loci affecting peak bone mineral density in mice. Journal of Bone and Mineral Research 13 1648–1656. (doi:10.1359/jbmr.1998.13.11.1648)
Kondoh S, Inoue K, Igarashi K, Sugizaki H, Shirode-Fukuda Y, Inoue E, Yu T, Takeuchi JK, Kanno J & Bonewald LF et al. 2014 Estrogen receptor alpha in osteocytes regulates trabecular bone formation in female mice. Bone 60 68–77. (doi:10.1016/j.bone.2013.12.005)
Konermann A, Lossdorfer S, Jäger A, Chen Y & Götz W 2013 Autoregulation of insulin-like growth factor 2 and insulin-like growth factor-binding protein 6 in periodontal ligament cells in vitro. Annals of Anatomy 195 527–532. (doi:10.1016/j.aanat.2013.10.001)
Li X, Ominsky MS, Niu QT, Sun N, Daugherty B, D’Agostin D, Kurahara C, Gao Y, Cao J & Gong J et al. 2008 Targeted deletion of the sclerostin gene in mice results in increased bone formation and bone strength. Journal of Bone and Mineral Research 23 860–869. (doi:10.1359/jbmr.080216)
Mazerbourg S, Callebaut I, Zapf J, Mohan S, Overgaard M & Monget P 2004 Up date on IGFBP-4: regulation of IGFBP-4 levels and functions, in vitro and in vivo. Growth Hormone and IGF Research 14 71–84. (doi:10.1016/j.ghir.2003.10.002)
Mita K, Zhang Z, Ando Y, Toyama T, Hamaguchi M, Kobayashi S, Hayashi S, Fujii Y, Iwase H & Yamashita H 2007 Prognostic significance of insulin-like growth factor binding protein (IGFBP)-4 and IGFBP-5 expression in breast cancer. Japanese Journal of Clinical Oncology 37 575–582. (doi:10.1093/jjco/hym066)
Miyakoshi N, Qin X, Ando Y, Toyama T, Hamaguchi M, Kobayashi S, Hayashi S, Fujii Y, Iwase H & Yamashita H 2001 Systemic administration of insulin-like growth factor (IGF)-binding protein-4 (IGFBP-4) increases bone formation parameters in mice by increasing IGF bioavailability via an IGFBP-4 protease-dependent mechanism. Endocrinology 142 2641–2648. (doi:10.1210/en.142.6.2641)
Mohan S, Nakao Y, Honda Y, Landale E, Leser U, Dony C, Lang K & Baylink DJ 1995 Studies on the mechanisms by which insulin-like growth factor (IGF) binding protein-4 (IGFBP-4) and IGFBP-5 modulate IGF actions in bone cells. Journal of Biological Chemistry 270 20424–20431. (doi:10.1074/jbc.270.35.20424)
Motyl KJ, Bishop KA, DeMambro VE, Bornstein SA, Le P, Kawai M, Lotinun S, Horowitz MC, Baron R & Bouxsein ML et al. 2013 Altered thermogenesis and impaired bone remodeling in Misty mice. Journal of Bone and Mineral Research 28 1885–1897. (doi:10.1002/jbmr.1943)
Nielsen FC 1992 The molecular and cellular biology of insulin-like growth factor II. Progress in Growth Factor Research 4 257–290. (doi:10.1016/0955-2235(92)90023-B)
Ning Y, Schuller AG, Bradshaw S, Rotwein P, Ludwig T, Frystyk J & Pintar JE 2006 Diminished growth and enhanced glucose metabolism in triple knockout mice containing mutations of insulin-like growth factor binding protein-3, -4, and -5. Molecular Endocrinology 20 2173–2186. (doi:10.1210/me.2005-0196)
Ning Y, Schuller AG, Conover CA & Pintar JE 2008 Insulin-like growth factor (IGF) binding protein-4 is both a positive and negative regulator of IGF activity in vivo. Molecular Endocrinology 22 1213–1225. (doi:10.1210/me.2007-0536)
Qin C, Singh P & Safe S 1999 Transcriptional activation of insulin-like growth factor-binding protein-4 by 17beta-estradiol in MCF-7 cells: role of estrogen receptor-Sp1 complexes. Endocrinology 140 2501–2508. (doi:10.1210/en.140.6.2501)
Raykha C, Crawford J, Gan BS, Fu P, Bach LA & O’Gorman DB 2013 IGF-II and IGFBP-6 regulate cellular contractility and proliferation in Dupuytren’s disease. Biochimica et Biophysica Acta 1832 1511–1519. (doi:10.1016/j.bbadis.2013.04.018)
Riggs BL 2000 The mechanisms of estrogen regulation of bone resorption. Journal of Clinical Investigation 106 1203–1204. (doi:10.1172/JCI11468)
Rosen C, Donahue LR, Hunter S, Holick M, Kavookjian H, Kirschenbaum A, Mohan S & Baylink DJ 1992 The 24/25-kDa serum insulin-like growth factor-binding protein is increased in elderly women with hip and spine fractures. Journal of Clinical Endocrinology and Metabolism 74 24–27. (doi:10.1210/jc.74.1.24)
Schiltz PM, Mohan S & Baylink DJ 1993 Insulin-like growth factor binding protein-4 inhibits both basal and IGF-mediated chick pelvic cartilage growth in vitro. Journal of Bone and Mineral Research 8 391–396. (doi:10.1002/jbmr.5650080402)
Strohbach C, Kleinman S, Linkhart T, Amaar Y, Chen ST, Mohan S & Strong D 2008 Potential involvement of the interaction between insulin-like growth factor binding protein (IGFBP)-6 and LIM mineralization protein (LMP)-1 in regulating osteoblast differentiation. Journal of Cellular Biochemistry 104 1890–1905. (doi:10.1002/jcb.21761)
Tahimic CG, Wang Y & Bikle DD 2013 Anabolic effects of IGF-1 signaling on the skeleton. Frontiers in Endocrinology 4 6. (doi:10.3389/fendo.2013.00006)
Thoren M, Hilding A, Brismar T, Magnusson P, Degerblad M, Larsson L, Sääf M, Baylink DJ & Mohan S 1998 Serum levels of insulin-like growth factor binding proteins (IGFBP)-4 and -5 correlate with bone mineral density in growth hormone (GH)-deficient adults and increase with GH replacement therapy. Journal of Bone and Mineral Research 13 891–899. (doi:10.1359/jbmr.1998.13.5.891)
Wang DY, Fulthorpe R, Liss SN & Edwards EA 2004 Identification of estrogen-responsive genes by complementary deoxyribonucleic acid microarray and characterization of a novel early estrogen-induced gene: EEIG1. Molecular Endocrinology 18 402–411. (doi:10.1210/me.2003-0202)
Zhang M, Faugere MC, Malluche H, Rosen CJ, Chernausek SD & Clemens TL 2003 Paracrine overexpression of IGFBP-4 in osteoblasts of transgenic mice decreases bone turnover and causes global growth retardation. Journal of Bone and Mineral Research 18 836–843. (doi:10.1359/jbmr.2003.18.5.836)
Zhou R, Diehl D, Hoeflich A, Lahm H & Wolf E 2003 IGF-binding protein-4: biochemical characteristics and functional consequences. Journal of Endocrinology 178 177–193. (doi:10.1677/joe.0.1780177)