Background
Bone and connective tissue disorders are often considered a local problem centered on the specific target area where bone degradation is seen
. With the aging of the world’s population the incidence of osteoporosis and related skeletal diseases increases constantly. Recent developments in the treatment of bone atrophy and the prevention of osteoporotic fractures have provided modern agents that inhibit bone resorption and lead to increased bone density i.e. specific antibodies or strontium ranelate [
1,
2]. In search for the appropriate treatment of these diseases also bioactive natural products are increasingly used with favorable effect on bone metabolism [
3]. Nevertheless numerous alternative preparations (e.g. Norzoanthamine [
4], Phorbaketal A [
5], Fucoxanthin [
6]) are commercially available but lack scientific evidence of in vivo effectiveness.
Here, we present the use of OSC in a single-center open-label human study as a possible natural therapeutic for skeletal disorders. Several aspects of OSC’s possible action can be assumed when the ingredients are separately looked at. For example, strontium ranelate is a new class of osteoporosis medication, capable of accelerating bone formation and, to a certain extent, inhibiting bone resorption [
2,
7,
8]. Calcium and vitamin D are important dietary supplements to prevent osteoporosis, and several other minerals amongst them iron, copper, and selenium, are known to play a role in the prevention of osteoporosis [
9]. Eggshell membrane is a natural source of glycosaminoglycans such as chondroitin, glucosamine, and sulfated glycoproteins [
10,
11]. Glucosamine and chondroitin sulfate are able to protect subchondral bone [
12,
13] shown in an animal model of osteoporosis [
14]. Chondroitin was also shown to act on subchondral bone osteoblasts by modulating the osteoprotegerin/receptor activator of NF-kB ligand ratio in favor of reduced bone resorption [
15].
In addition to the open-label study, we also analyze the effect of OSC on cellular and molecular level. As a primary target we established osteoblast cultures from femoral head specimens. Human osteoblasts are commonly used to analyze bone metabolism, osteogenesis and focal bone erosion in patients with joint diseases. The most widely used differentiation marker for these cells is alkaline phosphatase production. In contrast, cells devoid of osteoinductive ability show lower alkaline phosphatase activity [
16]. The molecular analyses performed here should provide information on the expression of genes coding for integrin binding sialoprotein (IBSP), bone γ-carboxylglutamic acid-containing protein, (BGLAP), secreted phosphoprotein-1, (SPP1), and dentin matrix acidic phosphoprotein (DMP1) all belonging to the most abundant non-collagenous bone matrix proteins expressed in osteoblasts [
17,
18]. Although their precise mechanism of action is not always understood, these non-collagenous bone matrix proteins play an important role in bone mineralization in part by their ability to react with the mineral components of the bone [
19]. To show whether osteoblast response to OSC is associated with signal transduction events, we also analyze the ERK1/2, and AKT signal transduction pathways as essential mediators in diverse biological responses such as cell differentiation, mineralization, and proliferation of various cell types including osteoblasts [
20,
21].
The data presented here show the results obtained from the open-label human study, and describes the responses of human osteoblasts to OSC.
Methods
Patients and osteoblast cultures
We studied 15 patients (12 female, three male) with osteoporosis of the low back (group 1;
n = 2) of the low back and hip (group 2;
n = 4), and both osteoporosis and osteoarthritis of the hip (group 3;
n = 9). All diagnoses were confirmed by iDXA and X-ray. Mean age of the patients was 69 years (range: 57 to 83 years). All patients were informed about the OSC treatment and gave written informed consent to the participation in this open-label study. A precondition for participating in the study was that, prior to the OSC-treatment, the patients had not taken medications which could have a significant influence on the course of the study. In addition the patients had to have pain and discomfort in the diseased areas at rest and during physical activity. Overweight patients (weighing more than 100 kg) were excluded from the study. The patients received three times daily 0.6 g OSC orally in vegetarian capsules, over a period of 20 days. The dosage was based on in vitro to in vivo extrapolation [
22] of the amount of OSC used in our cell mineralization experiments. Pain level was assessed by a 0–10 Numeric Pain Rating Scale (NPRS) where patients rated their pain on a score where 0 = no pain; 5 = moderate pain; 10 = worst possible pain. Pain intensity was evaluated 5, 10, and 20 days after starting the OSC-treatment.
Eight primary human osteoblast cultures were established from trabecular bone tissue from osteoporotic patients (aged between 62 and 93 years). Six cultures were established from the femoral head, and two from the tibia. The bone specimens were briefly rinsed in PBS, cut into small pieces (1–2 mm in diameter), and then thoroughly rinsed in PBS. The small bone fragments were gently shaken with 2 mL crude collagenase (Biochrom, Berlin, Germany) at 37 °C for 2 h and then rinsed in PBS. The isolated cells were incubated in minimum essential medium (MEM) with 10% (v/v) fetal calf serum, 100 U/mL penicillin/streptomycin (Biochrom) at 37 °C in 5% CO2 humidified atmosphere and were left for 4 days before the first medium change. When primary cultures were confluent cells were detached with trypsin/EDTA (Biochrom) and pelleted. The cells were reconstituted in MEM and counted in a hemocytometer to ensure that an equal number of cells were seeded in the various experimental cultures. Dermal fibroblasts grown in MEM under identical conditions served as control cells.
Scanning electron microscopy (SEM)
Osteoblasts were cultured on small glass discs and at required time-points fixed in 1.5% glutaraldehyde for 30 min at 4 °C, post-fixed in 1% osmium tetroxide for 1 h at 4 °C, and dehydrated through a series of increasing concentrations of ethanol and dried using hexamethyldisilazane (HMDS). Samples were sputter coated with gold using an ion coater (Balzers Union) and analyzed using a scanning electron microscope (Philips, Holland) at 10 kV.
Alkaline phosphatase activity
Activity of alkaline phosphatase in osteoblasts was detected as previously described [
23] using 5-bromo-4-chloro-3-indolyl-phosphate/nitro blue tetrazolium (BCIP/NBT) (0.35 mM BCIP, 0.37 mM NBT, 5 mM MgCl
2, 100 mM Tris buffer, pH 9.5, 45 min) as a precipitating substrate according to the manufacturer’s protocol (Sigma-Aldrich). In brief, prefixed cells were rinsed with 0.1 M Tris-HCl buffer (pH 7.6) and incubated with substrate to obtain optimal staining intensity. After washing with Tris-HCl buffer, coverslips were embedded in antifading solution (glycerol gelatin; Sigma-Aldrich).
Immunocytochemistry
After washing the cells with PBS they were fixed in alcohol and incubated each with primary mouse monoclonal anti-human collagen type-1 and osteocalcin antibody (Thermo-Scientific, Darmstadt, Germany) for 30 min at room temperature. Then they were incubated with biotinylated secondary goat anti-mouse antibody (Dako, Hamburg) for 30 min at room temperature in the dark and subsequently treated with avidin-biotin complex (Biozol, Eching, Germany) for 30 min. Negative controls were obtained by omission of the primary antibody. Cells were counterstained with hemalaun and immunocytochemical staining was assessed using a Zeiss microscopy (Axioplan, Jena, Germany).
RT-PCR analysis
Total RNA of normal and test cells was extracted using the RNeasy Kit (Qiagen, Hilden, Germany) and cDNA synthesis was performed using MMLV reverse transcriptase following the manufacturer’s instruction (Life Technologies, Inc.). For RT-PCR analysis, the cDNA was amplified for 30 cycles using the sense 5′-CCAGCCGAGCCACATCGC-3′ and anti-sense 5′-ATGAGCCCCAGCCTTCTCCAT-3′ oligonucleotides specific for the GAPDH gene (annealing temperature 55 °C), the sense 5′-GATGACGATGAAGATGACAG-3′ and anti-sense 5′-CTCTTCACTCTCACTCTCTTG-3′ specific for the DMP1 gene (annealing temperature 58 °C), the sense 5′-GCAGCGAGGTAGTGAAGAG-3’ and anti-sense 5′-CGATGTGGTCAGCCAACTC-3′ specific for the BGLAP gene (annealing temperature 60 °C), the sense 5′-GCCATGACCACATGGATGAT-3’ and anti-sense 5′-GTCTACTGTGGGGACAACTG-3’ specific for the SPP1 gene (annealing temperature 63 °C), and the sense 5′-GAGATGACAGTTCAGAAGAG-3’and anti-sense 5′-TCATCCACTTCTGCTTCGC-3’ specific for the IBSP gene (annealing temperature 57 °C). The reverse transcription PCR products were analyzed by 1.2% agarose gel electrophoresis. Alpha Imager Gel Doc gel documentation software (Biozym, Germany) was used for quantitation of mRNA expression normalized by GAPDH mRNA expression.
Osteoblast mineralization experiment
The test cells were cultivated under the same temperature and CO
2 conditions as the control cells but the minimum essential medium (MEM) was supplemented with OSC (20 μg/ml), consisting of mineral components similar to those of the bone (8 μg/ml = 0.2 mM calcium, 0.016 μg/ml = 0.5 μM phosphorus, 0.08 μg/ml = 3 μM magnesium, 3 ng/ml = 30 nM strontium, 0.2 ng/ml = 3 nM iron, 0.1 ng/ml = 1 nM copper, and 0.2 pg/ml = 0.002 nM selenium, as well as 0.6 ng/ml = 0.02 IU Vitamin D and 2 μg/ml eggshell membrane hydrolysate containing glycosaminoglycans such as chondroitin, glucosamine, and sulfated glycoproteins [
10]. The in vitro mineralization experiments were monitored over a period of 5, 10, 15, and 20 days respectively. The OSC doses and incubation times were determined in preliminary experiments (unpublished). Culture medium of both the test and the control cells supplemented with and without OSC was changed every second day. Calcium deposits in mineralized cultures were detected by staining with 10% Alizarin Red solution (Sigma-Aldrich) as described elsewhere [
24]
.
Quantification of total calcium content
Control and test cells (2 × 106 each) were grown over a period of 5, 10, 15, and 20 days in dish culture, rinsed twice with PBS and scraped off from the dishes using a cell scraper (Sarstedt, Nümbrecht, Germany). After centrifugation the cells were re-suspended and dissolved in 1 N HCl. Calcium content was measured using the Abcam Calcium Detection Assay Kit ab102505 (Abcam, Berlin). This colorimetric endpoint assay measures the amount of calcium–cresolphthalein complexone formed when cresolphthalein complexone binds to free calcium in alkaline solution within the physiological range of 0.1 mM–3.0 mM. Absorbance was measured at a wavelength of 575 nm with background subtraction of 490 nm using a microplate reader (Dynatech MR5000, Denkendorf, Germany).
Cell cytotoxicity assay
Cell viability was measured using the non-radioactive LDH Detection Kit (Roche Diagnostics, Germany). Cells (2 × 106 each) grown to monolayers were incubated for 15 days in MEM supplemented with OSC (for more information see induction of mineralization in Material Methods section). After centrifugation at 250 g for 10 min. The cell-free culture supernatants were collected and incubated according to the manufacturer’s instruction. To calculate cell viability day 15 control cells (2 × 106) growing in MEM in absence of OSC were treated with Triton-×100 (1% v/v) for one hour and served as second control. Absorbance was measured at 492 and 620 nm using a 96-well plate ELISA reader (Dynatech MR5000, Denkendorf, Germany).
ERK and AKT signaling pathways
Primary osteoblasts (2 × 106 each) growing in MEM were either treated with 100 ng/ml IGF-1 (Life Technology, Darmstadt Germany) for 1 h, or cultivated in MEM supplemented with OSC (20 μg/ml) over a period of 1, 5, 10, and 15 days. The cells were harvested by centrifugation (800 g for 5 min) washed with PBS, and lysed in a solution containing 20 mM Tris/HCl (pH 7.4), 150 mM NaCl, 2 mM EDTA, 1% Igepal 0,5% SDS, 1 mM PMSF, 5% 2-mercaptoethanol, 10% glycerol in presence of protease inhibitor (Roche Diagnistics, Mannheim, Germany). Total protein extracts (10 μg) were analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and Western blot. The primary mouse monoclonal antibodies against AKTPSer473 and ERK1/2PTyr204 were purchased from Life Technology (Darmstadt, Germany) and the horse radish peroxidase-conjugated second antibody from Dako (Hamburg, Germany). Immune complexes were detected utilizing the Amersham ECL Chemi-Lumi detection system and Amersham Hyperfilm MP (GE Healthcare, Buckinghamshire, UK). The Alpha Imager Gel Doc gel documentation software (Biozym, Germany) was used for quantitation of protein expression.
Statistical analysis
Data concerning the pain score evaluation were analyzed by means of repeat measure One-Way ANOVA, followed by Bonferroni post-testing (SPSS vs 20). Data were considered statistically significant if p < 0.05. All data are presented as mean values ± standard deviation (SD). All in vitro experiments were carried out in triplicate and analysis of variance was performed by means of One-Way ANOVA, followed by Bonferroni post-testing (SPSS vs 20).
Discussion
We have carried out a single-center open-label human study to prove the efficacy of OSC for the indications skeletal pain and flexibility. The findings provided a statistical significant positive effect on pain alleviation of 68% after a 20-day-treatment. This study can be considered as a necessary first step in exploring a novel application of intervention, and can be used to evaluate the feasibility and/or modification needed in the design of a large clinical study.
The data presented here also describes the effect of OSC on primary osteoblasts in vitro that exhibit bone tissue specific metabolic responses and produce structural components of bone. The expression of alkaline phosphatase and collagen type-1 in the cytoplasm showed that these cells are of osteoblastic lineage. Although alkaline phosphatase is associated with the osteoblast phenotype, in heavily mineralized cultures cellular levels of this enzyme decline [
26]. We studied the expression of bone-specific genes and observed the formation of mineralized nodules when cells were cultured in OSC-supplemented media.
The regulation of bone-specific gene expression reflects the 3 principle periods of osteoblast development: proliferation, extracellular matrix maturation, and mineralization [
26]. Here we considered mineralization as functional in vitro endpoint reflecting advanced cell differentiation. Studying the mineralization process we focused on the beginning of cell differentiation. At this period there was no mineral nodule formation as shown by negative Alizarin red staining. Microscopic observation of the mineralization process in osteoblasts showed calcium deposits as an indicator of successful in vitro bone formation over cultivation periods of 5 days. The mineralization process dramatically increased as a function of time indicated by formation of increased numbers of mineralized nodules. In this context, we examined the temporal signaling action of OSC on osteoblast mineralization analyzing ERK and AKT, because it is known that these signal transduction pathways play an important role in osteoblast differentiation [
21,
27,
28]. We have shown here that OSC treatment of the osteoblasts does not stimulate ERK activation but induces AKT activation which is associated with enhanced expression of osteoblast-specific genes involved in mineralization. The lack of ERK activity was somewhat unexpected. ERK activity may induce factors required early in the differentiation program as was shown in primary calvarial osteoblasts [
21].
The most abundant non-collagenous protein in bone is BGLAP synthesized exclusively by osteoblasts, and is considered to be an indicator of osteoblast differentiation [
29]. BGLAP binds to hydroxilapatit and calcium and its expression is modulated by parathyroid hormone [
30]
. The expression of BGLAP suggests that it is involved in the preparation of the extracellular matrix and that the co-expression of alkaline phosphatase may support the onset and progression of extracellular matrix mineralization [
26]. In addition to demonstrating the expression and immunocytochemical localization of BGLAP we studied the expression of IBSP, SPP1, and DMP1 genes preferentially expressed in osteoblasts playing important roles in biomineralization. The proteins encoded by these genes belong to the small integrin-binding ligand,
N-linked glycoprotein (SIBLING) family of proteins and they are believed to play a key role in the process of bone development by facilitating cellular adhesion, mineral nucleation, and mineral maturation [
31]. High up-regulation of the SSP1 and DMP1 genes was observed in osteoblasts after an incubation period of 15 days. While the SPP1 gene-encoded protein plays a role in osteoclasts attachment [
32] DMP1 and IBSP enhance osteoblast differentiation and are critical components for proper bone mineralization [
33,
34]. In this study the appearance of BGLAP, SPP1, DMP1, and IBSP was detected at the same time and their expression coincided with the mineralized nodule formation in osteoblasts. Moreover, nodule formation strongly correlated with elevated calcium emphasizing the importance of calcium in osteoblast mineralization in vitro. Indeed, with the onset of mineralization BGLAP, SPP1, DMP1, and IBSP are induced and their expression is increased in accordance with the accumulation of mineral [
26,
34‐
36]
.
The biocompatibility of OSC was examined utilizing the LDH cytotoxicity test to study cell growth, reproduction and morphology. Serial and comparative tests, demonstrated that OSC containing culture media had no toxic effect on osteoblasts as seen by cell attachment, growth, with no LDH release into the culture medium or cell destruction.
Acknowledgments
The authors would like to express their thanks to Gudrun Scherer for her skillful assistance, to Biog for technical support, as well as to all the participants for their commitment to facilitate the research.
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