Introduction
Human diseases with an acquired loss of bone account for increased mortality especially among elderly men and women [
1]. A number of loci associated with bone mineral density and fracture risk have been identified by genome-wide association studies [
2]. Nevertheless, uncovering novel genes and pathways regulating bone metabolism is a key in providing the basis for new therapeutic options to prevent bone loss and subsequent fractures.
On the cellular level, monocyte/macrophage derived osteoclasts are considered to mediate the exceeding loss of bone. Their differentiation depends on the availability of intracellular calcium ions, since calcium binding stimulates phosphatases including calcineurin [
3], which subsequently facilitates the translocation of factors such as nuclear factor of activated T-cells NFATc1 into the nucleus and induces the transcription of osteoclastogenesis-promoting genes [
4].
Many different membrane channels, including the transient receptor potential (TRP) ion channel family, control the entry of calcium ions into the cells [
5]. This family consists of six subgroups including the canonical (TRPC) and the vanilloid (TRPV) subtype, with TRPV channels previously demonstrated as modulators of calcium signaling in osteoclasts [
6,
7]. TRPC channels belong to a group of seven cation channels divided into subgroups according to their amino acid sequence similarities and they can assemble as homo- and heterotetramers [
8].
The subgroup of TRPC3/6/7 channels share between 70 and 80% sequence homology; however, they demonstrate distinctly different affinities for calcium cations. TRPC3 and TRPC7 functionally regulate basal calcium influx, whereas TRPC6 has been described as a receptor operated calcium channel [
9,
10].
TRPC3 and TRPC6 channels have already been targeted in pre-clinical models of renal- and cardiac fibrosis, as well as in the treatment of hypoxic vasoconstriction [
11,
12]. A role of TRPC6 in the pathogenesis of certain kidney diseases has been described, where gain-of-function mutations lead to increased podocyte apoptosis due to altered NFAT signaling [
13,
14]. It is believed that TRPC7 also plays a role in calcium signaling through its characteristic features, but its physiological importance in the native environment is not yet clear [
15].
Although TRPC3 and TRPC6 have been investigated in murine and human osteoblast-like cells [
16], the functional role of these TRPC channels in osteoclasts has not been previously clarified. Therefore, in this study, we aimed to examine whether TRPC3 and TRPC6 channels are involved in bone loss and regulation of osteoclast formation and function via Ca
2+ and NFAT signaling and whether modulation of TRPCs 3 and 6 may effect bone homeostasis.
Materials and Methods
Transcriptome Analysis
The publicly available data sets GSE7158 and GSE56815 (
https://www.ncbi.nlm.nih.gov/geo/), basing on micro array analyses of circulating monocytes, were evaluated for TRPC channel expression, using R (the R-project,
https://cran.r-project.org). Data sets GSE7158 and GSE56815 both compare human individuals with high and low bone mineral density (BMD), respectively [
17]. Gene names of array IDs were assigned corresponding to ‘
https://www.ensembl.org/biomart/martview/’. The following free-available R-packages were used: ‘affy’, ‘affyQCReport’, ‘lattice’, ‘limma’, ‘tkWidgets’, ‘widgetTools’, ‘tcltk’, ‘DynDoc’, ‘oligo’, ‘gplot’ (
https://www.bioconductor.org). The corresponding genes were plotted after z-score transformation for each gene.
Animals
TRPC6
+/− mice [
18] were kindly provided by the group of Alexander Dietrich from Munich, Germany. Animals were housed in a temperature-controlled animal room with water and conventional lab chow ad libitum and with a 12/12 h light/dark cycle. Heterozygous mice were used for breeding and only female littermates of TRPC6
−/− and WT background were used for the experiments. Details of serum and urine analyses are provided in the supplements.
μCT Analysis
Bone-structures of 4 month old mice were analyzed by micro-computed tomography (µCT) on a Bruker Skyscan 1176 in vivo microCT (Kontich, Belgium). The X-ray tube was set to 45 kVp, and the voxel size was 9 mm3. Images were reconstructed and analyzed using manufacturer’s software (NRecon, CTAn, CTVol dataviewer; Bruker microCT). The total bone volume fraction (the percentage of bone volume to total volume, BV/TV), mean trabecular thickness (Tb.Th), trabecular separation (Tb.Sp), and trabecular number (Tb.N) were calculated for trabecular bone, whereas the average cortical thickness (Ct.Th) was quantified from cortical bone.
Cell Culture
Details of cell isolation, culture, differentiation, staining and expression analyses are provided in the supplementary materials and methods.
Generation Of TRPC6 Deficient RAW 264.7 Cells By CRISPR/Cas9 Technology
For cellular knock out of TRPC6 in RAW 264.7 cells sgRNAs were designed, targeting exon 2 and comprising all transcript variants of TRPC6 in mice. For subcloning into lentiCRISPRv2 [
19] (Addgene #52,961) the sequence was modified by attachment of BsmBI restriction sites. One Shot Stbl3
Escherichia coli (Invitrogen, Thermo Fisher Scientific) were transformed and the correct insertion of the sgRNA was verified by sequencing. For production of lentivirus HEK293T cells were transfected with lentiCRISPRv2_sgRNA29, psPAX2 (Addgene #12,260) and pMD2.G (Addgene #12,259) at the ratio of 4:3:1 by Lipofectamine 2000 according to the manufacturer’s protocol (Invitrogen, Thermo Fisher Scientific). Medium was replaced after 12 h; supernatants were harvested after 24 h and 48 h, and filtered through a 0.22 µm membrane. RAW 264.7 cells were seeded in 24 well plates at a density of 10
4 cells/well and incubated with lentiviruses in the presence of 8 μg/mL polybrene (Sigma-Aldrich). Transduced RAW 264.7 cells were positively selected with puromycin (Gibco, Thermo Fisher Scientific), followed by clonal expansion using a serial dilution assay. DNA was isolated from clonally derived cells, amplified with 5′ and 3′ flanking primers located in intron 1 (Pr_003-for) and exon 2 (Pr_587-rev), followed by sequence analysis using a sequencing service (Eurofins Genomics, Ebersberg, Germany). Successful knock out was validated by alignment of DNA sequences with wild type sequences.
Intracellular Ca2+ Measurements
Five × 10
3 RAW 264.7 cells/well were seeded in 96 well plates. One day before incubation with 3 μM Fura-2AM (ThermoFisher Scientific) for 1 h at 37 °C, cells were co-stimulated with 100 ng/mL RANKL and 10 µM Pyr3, or solvent control, respectively [
20]. After three washes with Ringer’s solution at RT, measurements were performed at 24 °C for 150 s on a Spark 10 M microplate reader (TECAN). The change in intracellular calcium (Ca
2+) concentration was indicated as the ratio of fura-2 fluorescence intensities for 340 nm (Ca
2+ bound to fura-2) and 380 nm (free fura-2) excitation (F ratio), at an emission wavelength of 510 nm.
Statistical Analysis
Statistical analyses were performed using R, the R-project as well as GraphPad Prism v6 and v8 (GraphPad Software, Inc, La Jolla, CA USA). Due to the small sample sizes, we used the Mann–Whitney U test for differences. All data are reported as mean standard deviation (SD). A value of p < 0.05 was considered as statistically significant.
Discussion
We show—for the first time—that modulation of the transient receptor potential cation channels TRPC3 and TRPC6 has consequences for the quality of bone. Our transcriptome analysis revealed that women with low bone mineral density show an increased expression of TRPC3 in human osteoclast precursor cells. In mice we measured increased TRPC3 expression after ablation of TRPC6, resulting in an altered bone structure, leading to a phenotype found in osteoporosis. An increased activation of osteoclasts both in vivo and in vitro could be confirmed. In detail, mice lacking TRPC6 revealed decreased bone volume per tissue volume in the lumbar vertebrae, as well as decreased trabecular thickness and trabecular number. Accordingly, number and size of osteoclasts on the surface of trabecular bone and the level of the biomarker CTX in the serum of these mice were significantly increased.
Ong et al. [
22] reported an involvement of TRPC1 in osteoclast formation and function, but so far, there is no direct evidence to suggest a particular role of TRPC3 or TRPC6 channels in bone metabolism. We detected low basal expression for both channels on osteoclast precursor cells, which increased during osteoclastogenesis. Comparison of primary BMMCs isolated from TRPC6 knock out mice and WT mice showed an increased osteoclastic differentiation capacity along with elevated bone resorption activity of TRPC6 deficient cells. This effect is not a phenomenon limited to ablation of TRPC6 in the germline; it could also be confirmed in RAW 264.7 cells after disruption of TRPC6 by CRISPR/Cas9.
The expression of TRPC3 was increased in TRPC6 deficient osteoclasts, compared to differentiated cells from wild type littermates. This is in accordance with previous findings in vascular smooth muscle cells of TRPC6 deficient mice [
18]. Osteoclast function might rely on an equilibrium between TRPC3 and TRPC6, leading to bone loss in mice lacking TRPC6. Recent studies showed discrepancies regarding expression and functional contribution of these channels [
23,
24], which may be related to the fact that the contribution of TRPC3 and TRPC6 channels depends on their association as homo- or heterotetrameric complexes and differences in their association pattern may change their function [
25].
It is known from previous studies, that calcium signaling in osteoclasts plays a vital role in their differentiation process, but there is only limited data available on the regulation of calcium signaling in these cells [
4,
26]. Given that TRPC3 and TRPC6 channels have different affinities to cations [
27], we demonstrated that basal intracellular calcium is elevated in TRPC6 deficient osteoclast precursor cells. Dietrich et al. [
18] have initially described this phenomenon; they showed increased expression levels of TRPC3 in smooth muscle cells of blood vessels after ablation of TRPC6. The up-regulation of TRPC3 after loss of TRPC6 has been reported as being rather cell-type specific [
28]. While the molecular mechanism of these findings remains to be understood, one may consider a possible feed-forward loop of TRPC3 expression that is coupled to increased influx of calcium.
TRPC6 is a cation channel that depends on receptor activation, and absence of TRPC6 gives rise to TRPC3-only composites that show basal channel activity. Because inhibition of TRPC3 using Pyr3 can diminish increased intracellular calcium levels, elevated differentiation, and increased bone resorption of TRPC6 deficient osteoclasts, we propose that elevated TRPC3 presence is driving the increased activity of osteoclasts when TRPC6 is missing. Indeed, TRPC3 expression has been linked to bone biology on several occasions. Our data analyses demonstrate that human individuals with low BMD have a significantly increased expression of TRPC3 in circulating monocytes, the precursors of osteoclasts, when compared to individuals with high BMD. A further indication that elevated TRPC3 expression might be related to increased bone resorption can be concluded from the Williams–Beuren Syndrome, a neurodevelopmental disorder where osteopenia is a common feature of the disease. Increased levels of TRPC3 channels have been described on somatic cells of an individual [
29,
30]. Moreover, recent evidence suggests a TNF-α dependent induction of TRPC3, outlining this channel as constitutively active, and participating in NF-kB signaling [
31]. This supports a role of TRPC3 in regulating pathways that are well known to drive differentiation and resorption activity of osteoclasts [
31,
32]. Furthermore Becker et al
. [
33] characterized the moonwalker (mwk) mouse, which has a dominant T635A TRPC3 gain-of-function mutation. These mice have an abnormal Purkinje cell development and cerebellar ataxia. Interestingly, DEXA scans of heterozygous mwk mice showed significant lower bone mineral densities compared to wild type mice (
www.mousephenotype.org/data/genes/MGI:109526), which supports the hypothesis, that an increased activity of TRPC3 is disadvantageous for a healthy bone.
These findings recommend TRPC3 as an interesting target to modulate bone metabolism. Osteoporosis in elderly men and women, together with secondary bone loss in diseases including cancer, pose a major risk factor for fractures, immobilization and hospitalization [
34,
35]. Targeting osteoclastic bone resorption lowers the risk of fractures and improves the outcome of patients suffering from bone loss [
36,
37].
A variety of medications that suppress bone resorption by affecting the activity of osteoclasts have been developed so far [
38,
39]. Despite their good efficiency in increasing bone mass, these drugs are associated with a number of side effects that limit their therapeutic application in a subgroup of patients that would benefit from an intervention [
40,
41]. TRPC3 is already in the focus of interest as a target for pharmacological interventions due to the observation that gain of function is associated with pathologies of the cardiovascular system and the brain [
42]. A suitability for an application of the pyrazole 3 (Pyr3) developed by Kiyonaka et al. to inhibit TRPC3 in vivo has already been shown [
43].
We could demonstrate that the increased intracellular calcium levels after ablation of TRPC6 are abolished by inhibition of TRPC3 using Pyr3. Hence, we conclude that TRPC3 is regulating influx of calcium from extracellular compartments in osteoclasts. These findings underscore a regulatory function of TRPC on osteoclasts.
In summary, we report that (i) loss of the cation channel TRPC6 in vivo leads to an osteoporosis-like phenotype due to increased size and activity of osteoclasts; (ii) ablation of TRPC6 in osteoclasts leads to increased expression of TRPC3, resulting in elevated intracellular calcium, differentiation, and resorption activity; (iii) inhibition of TRPC3 lowers bone resorption and decreases differentiation of osteoclasts.
Based on these data, we propose that TRPC3 represents a potent driver of osteoclastogenesis, which is regulated by the presence of TRPC6.
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.