Background
Rheumatoid arthritis (RA) is an immune-mediated type of inflammatory arthritis that causes massive bone destruction by increasing osteoclast development (osteoclastogenesis) and activity. Receptor activator of nuclear factor κB ligand (RANKL), its cellular receptor, receptor activator of nuclear factor κB (RANK), and the decoy soluble RANKL receptor osteoprotegerin (OPG) are key regulators of osteoclastogenesis in RA [
1‐
3]. RANKL is produced by osteoblastic lineage cells, activated T cells, synovial fibroblasts, and other stromal cells, and it binds to RANK on osteoclast precursors to stimulate their differentiation, activity, and survival [
4‐
8]. The effects of RANKL are neutralized by OPG which, by binding to RANKL, prevents it from activating RANK. RANKL and OPG are pivotal downstream signals upon which many cytokines, growth factors, and steroid and peptide hormones converge to regulate bone homeostasis [
7,
8]. Shifting the RANKL-to-OPG ratio in favor of bone protection is a promising therapeutic strategy against joint destruction in RA. Prolactin (PRL), the hormone essential for mammary gland development and milk production, may have this protective effect.
The female preponderance and the influence of reproductive states in RA, together with PRL immune-enhancing actions, have long linked this disease to a detrimental effect of PRL [
9‐
11]. However, accumulating evidence has challenged this view by showing that PRL is also immunosuppressive [
12‐
14], and that hyperprolactinemia occurring during pregnancy and lactation [
15,
16] or induced pharmacologically by the dopamine D2 receptor antagonist haloperidol [
17], is associated with a reduction in the severity and risk of RA. Moreover, increasing prolactinemia by PRL infusion or treatment with haloperidol ameliorates inflammation and joint destruction in AIA as revealed by reduced joint swelling, lower local expression of proinflammatory cytokines TNFα, IL-1β, IFNγ, and IL-6, and inhibition of chondrocyte apoptosis, pannus formation, and bone erosion [
18].
PRL protection against bone loss in inflammatory arthritis is not unexpected. PRL-receptor-null mice are osteopenic [
19] and PRL treatment increases bone formation during growth by decreasing the RANKL/OPG ratio in osteoblasts [
20]. Moreover, PRL stimulates the proliferation of pancreatic β cells by promoting OPG-mediated inhibition of RANKL [
21], and RANKL is under the control of PRL to promote mammary gland lobulo-alveolar development during pregnancy [
22].
Here, we investigated whether PRL, either by its exogenous administration or by the genetic deletion of the its receptor, reduces trabecular bone loss and osteoclastogenesis by modifying proinflammatory cytokine-induced upregulation of the RANKL/RANK/OPG system in rodent polyarticular AIA and monoarticular AIA (MAIA), and whether these actions involve a direct effect of PRL on synovial fibroblasts and osteoclast progenitor cells.
Methods
Animals
Male Sprague-Dawley rats (200–250 g) and female C57BL6 mice, wild type (Prlr+/+) or null for the PRL receptor (Prlr-/-) (8 weeks old, 20–25 g), were housed under standard laboratory conditions (22 °C; 12-hour/12-hour light/dark cycle; free access to food and water).
Induction of AIA
AIA was induced in rats as described [
18], by a single intradermal injection at the base of the tail of 0.2 ml complete Freund’s adjuvant (CFA, Difco Laboratories, Detroit, MI, USA; 10 mg heat-killed
Mycobacterium tuberculosis per 1 ml of Freund’s adjuvant). Three days before CFA injection some rats were rendered hyperprolactinemic by the subcutaneous implantation of a 28-day osmotic minipump (Alza, Palo Alto, CA, USA) containing 1.6 mg of ovine PRL (Sigma Aldrich, St. Louis, MO, USA). Ankle swelling, monitored as described [
18], indicated that the onset of arthritis appeared on day 12 after CFA injection and was maximal by day 21, when the animals were euthanized, serum samples collected for PRL and cytokine determinations, and ankle joints processed for histological examination, quantitative (q)PCR, and western blot.
Induction of MAIA
Monoarticular AIA was induced and assessed in mice as described [
23]. Briefly, mice were injected into the articular space of the right knee joint with CFA (5 μg in 10 μl) once every 7 days for 18 days. The diameter across the knee joint (left and right) was measured twice a week with a micro-caliper. Mice were euthanized 18 days after the initial CFA injection, and knee joints were removed and processed as above.
Intra-articular injection of TNFα, IL-1β, and IFNγ (Cyt)
Mice were injected in the articular space of the knee joints with Cyt in a final volume of 20 μl (62.5 ng TNFα, 25 ng IL-1β, and 25 ng IFNγ; R&D Systems, Minneapolis, MN,USA) or with endotoxin-free water as vehicle. Forty-eight hours after Cyt or vehicle injection, mice were euthanized and synovial membranes were extracted and processed for quantitative real-time (qRT)-PCR evaluation.
Serum measurements
Infused ovine PRL was measured in serum by the Nb2 cell bioassay, a standard procedure based on the proliferative response of the Nb2 lymphoma cells to PRL, carried out as described [
18]. The serum levels of C-reactive protein and TNFα were quantified using ELISA kits from BD Biosciences (San Jose, CA, USA) and R&D systems (Minneapolis, MN, USA), respectively.
Histological examination and image analysis
Ankle and knee joints were fixed, decalcified, and dehydrated for paraffin embedding. Four 7-μm-thick sections spaced 380 μm or 126 μm apart, per each rat tibia/tarsal joint or mouse femur/tibia joint, respectively, were stained with Harris’s hematoxylin-eosin solution for measurement of trabecular bone area and with tartrate-resistant acid phosphatase (TRAP) for evaluation of osteoclast number. For the latter, deparaffinized sections were washed, and incubated for 3 hours at 37 °C in TRAP activity staining mix (Fast Red Violet LB Salt (80 mg; Sigma Aldrich), Naphtol AS-MX (40 mg; Sigma Aldrich), formamide (4 ml; Invitrogen, Carlsbad, CA, USA), 0.04 M sodium acetate (0.656 g), 0.2 M disodium tartrate dihydrate (9.2 g), and distilled water (200 ml)). The pH was adjusted to 5.0 and pre-incubated to 37 °C before use. After incubation, sections were rinsed with distilled water, counterstained with Mayer’s hematoxilin (Sigma Aldrich), and coverslipped with mounting medium (Entellan, Merck Millipore Corporation, Billerica, MA, USA). Hematoxylin-eosin-stained and TRAP-stained tissue sections were visualized by light microscopy (Olympus BX60F5, Olympus Tokyo, Japan). Trabecular bone surface and number of TRAP-stained purple spots (osteoclasts) were quantified (Image-Pro Plus analysis software; Media Cybernetics, Silver Spring, MD, USA) and divided by total bone area to obtain trabecular bone area and osteoclast density. Two independent observers, blind to the experiments, performed the measurements.
qRT-PCR
Frozen whole ankle and knee joints were pulverized in liquid nitrogen using a mortar and pestle. Total RNA was isolated using TRIzol reagent (Invitrogen, Carlsbad, CA, USA) and reverse transcribed using the High-Capacity cDNA Reverse Transcription Kit (Applied Biosystems, Foster City, CA, USA). PCR products were detected and quantified using Maxima SYBR Green qPCR Master Mix (Thermo Fisher Scientific, Waltham, MA, USA) in a final reaction of 10 μl containing template and 0.5 μM of each of the primer pairs for different genes (see Additional file
1: Table S1). Amplification performed in the CFX96 real-time PCR detection system (Bio-Rad, Richmond, CA, USA) included a 10-minute denaturation step at 95 ° C, followed by 35 cycles of amplification (10 sec at 95 °C, 30 sec at the primer pair-specific annealing temperature, and 30 sec at 72 °C). The PCR data were analyzed by the 2-
ΔΔCT method, and cycle thresholds (CT) normalized to the housekeeping gene hypoxanthine-guanine phosphoribosyltransferase (
Hprt) were used to calculate the mRNA levels of interest.
Isolation and culture of synovial fibroblasts
Synovial fibroblasts were isolated from the hind limbs of wild-type mice separated at the femur/fibula/tibia junctions, as previously described [
24]. Briefly, limbs were washed in Hanks’ balanced salt solution (HBSS), and dissected while immersed in high glucose DMEM (Invitrogen, Carlsbad, CA, USA) supplemented with 20% heat-inactivated fetal bovine serum (FBS; Gibco, Grand Island, NY, USA) and antibiotics (50 U/ml of penicillin and 50 μg/ml of streptomycin; Invitrogen) to remove all soft tissues from bones. The joint space was opened with a scalpel to expose the synovial tissues and incubated in culture medium containing 1 mg/ml collagenase type IV (Difco Laboratories) and 0.1 mg/ml of deoxyribonuclease I (Sigma Aldrich) in a shaking bath for 3 hours at 37 °C. Tissues were then vortexed vigorously to release cells. The supernatant was passed through an 80-μm filter and centrifuged; cells were re-suspended in fresh culture media and grown to confluency. Cells were used for experiments after 2–4 passages, when the cultures showed >98% synovial fibroblast phenotype (CD90.2+, VCAM1+, and ICAM-1+) as described [
24].
Synovial fibroblasts were seeded at 106 cells/well in 6-well plates and incubated in 2 ml of culture medium for 16 hours with or without PRL (100 nM, recombinant human PRL provided by Michael E. Hodsdon, Yale University, New Haven, CT, USA). Cyt (0.25 ng/ml TNFα, 0.05 ng/ml IL-1β, and 0.05 ng/ml IFNγ) were then added or not to the culture for an additional period of 24 hours. Other cell cultures were pre-incubated for 2 hours with or without the STAT inhibitor, S31-201 at 50 nM (Santa Cruz Biotechnology, Santa Cruz, CA, USA), and then incubated or not with 100 nM PRL for 16 hours, followed by the treatment with or without Cyt for 24 hours. To evaluate PRL effects on phosphorylation/activation of STAT3, synovial fibroblasts were seeded in complete medium for 24 hours, cultured in serum-free medium for another 24 hours, and then pre-treated for 6 hours with the Cyt followed by a 30-minute incubation in the presence or absence of Cyt with or without 100 nM PRL.
Co-culture of synovial fibroblasts and osteoclast progenitors
Synovial fibroblasts (passage 4) were seeded at 5 × 105 cells in 48-well plates and after 12 hours the cells were treated or not with PRL for 16 hours. Cyt were then added or not to the culture, and after 24 hours, bone marrow cells (2 × 106) containing osteoclast progenitors, harvested from the tibias and femurs of 8-week-old C57BL/6 mice, wild type (Prlr+/+) or null for the PRL receptor (Prlr-/-), were delivered in culture medium with 1, 25 dihydroxy-vitamin D3 (10-8 M, Sigma-Aldrich). Co-cultures were incubated for 10 days changing for new medium (containing 1, 25 dihydroxy-vitamin D3, +/- Cyt, +/- PRL) every 2 days. Co-cultures were fixed with 3.7% formaldehyde for 10 minutes at room temperature, washed twice with PBS, air-dried, and incubated for 20 minutes at 37 oC with TRAP activity staining mix. Osteoclastogenesis was assessed by counting the number of enlarged TRAP-positive (TRAP+) cells.
Isolation of chondrocytes, osteoblasts, and osteoclast-like cells
To identify other joint cells expressing the PRL receptor, chondrocytes, osteoblasts, and osteoclast-like cells were obtained from
Prlr+/
+ and
Prlr-/- mice. Synovial fibroblasts obtained from both mouse groups served as positive controls. Articular chondrocytes were isolated from femoral epiphyseal cartilage as described previously [
25]. Murine bone marrow stromal cells were obtained by flushing the bone marrow from femur and tibia with PBS. Cells were maintained in DMEM with 20% FBS and antibiotics until 70% confluence, when they were differentiated into osteoblasts by treatment with 100 μM ascorbate phosphate and 5 mM β-glycerol phosphate for 10 days and medium replacement every 2 days [
26]. Other bone marrow cells were differentiated into osteoclasts by their culture in α-MEM (Sigma-Aldrich) supplemented with 10% FBS and antibiotics, 25 ng/ml recombinant macrophage colony stimulating factor and 50 ng/ml RANKL (PreproTech, Rocky Hill, NJ, USA) for 10 days and medium replacement every 2 days [
27]. All cells were processed for PCR.
The purity of the different cell types has been documented [
27‐
29] and was confirmed by the mRNA expression of specific markers: collagen type II (chondrocytes), runt related transcription factor 2, alkaline phosphatase, and osteocalcin (osteoblasts), and RANK, calcitonin receptor, and TRAP (osteoclast-like cells). Total RNA was isolated, reverse transcribed, and used for the PCR amplification of a 139-bp fragment from exon 5 of the PRL receptor gene (exon 5 is deleted in
Prlr-/- mice) in a final reaction mixture (10 μl) containing template, 0.02 U/μl of Phusion DNA Polymerase (Thermo Fisher, Waltham, MA, USA), 2 μl of 5X Phusion Buffer HF (Thermo Fisher), 0.4 mM of deoxyribonucleotide triphosphates (dNTPs) and 0.5 μM of each of the primer pairs for
PRLr (forward 5′-CAC ATA AAG TGG ATC CGA GGT A-3′; reverse 5′-TGA ATG TCC AGA CTA CAA AAC CA -3′), using
Hprt as loading control (Additional file
1: Table S1). The amplification in the Eppendorf Mastercycler ep Gradient S equipment (Eppendorf, Hamburg, Germany) included denaturation for 2 minutes at 95 °C, followed by 36 cycles of 15 sec at 95 °C, 15 sec at 56 °C, and 30 sec at 72 °C, followed by one cycle of 5 minutes at 72 °C. PCR products were resolved on a 1.2% agarose gel. The specificity of the reaction was confirmed by the lack of amplification products in samples from
Prlr-/- mice.
Western blot
Pulverized ankle joints or synovial fibroblasts were resuspended in lysis buffer (0.1 M Tris-HCl, 0.2 M EGTA, 0.2 M EDTA, 100 mM sodium orthovanadate, 50 mM sodium fluoride, 100 mM sodium acid pyrophosphate, 250 mM sucrose, pH 7.5) and total protein (60 μg), subjected to SDS/PAGE, blotted, and probed overnight with 1:1000 anti-PRL receptor (sc-300; Santa Cruz Biotechnology, Santa Cruz, CA, USA), 1:250 anti-phospho-STAT3 (Tyrosine 705) (9131; Cell Signaling, Beverly, MA, USA), 1:250 anti STAT3 (sc-483; Santa Cruz Biotechnology), or 1:1000 anti-β tubulin (ab6046; Abcam, Cambridge, MA, USA) primary antibodies. Blots were washed in Tris-buffered saline/Tween-20 and detection was performed using goat anti-rabbit conjugated to alkaline phosphatase (1:5000) or to horseradish peroxidase (1:10,000) as secondary antibodies (both from Jackson ImmunoResearch Laboratories Inc., West Grove, PA, USA). Protein densities were quantified with Quantity One software (Bio-Rad, Richmond, CA, USA).
Statistical analysis
The Sigma Stat 7.0 software (Systat Software, San Jose, CA, USA) was used. Data distribution and equality of variances were determined by the D’Agostino-Pearson test. When the distribution was normal and variances were equal, the t test was used to evaluate differences between two groups and one-way analysis of variance (ANOVA) followed by Tukey’s post-hoc test was used to compare differences between more than three groups. In the case of data with a non-parametric distribution, statistical differences between two groups and more than three groups were determined by the Mann-Whitney U test and Kruskal-Wallis test followed by Dunn’s post-hoc correction, respectively. The threshold for significance was set at P < 0.05.
Discussion
Articular bone loss and increased fracture risk in arthritis are indicative of an imbalance between bone resorption and formation. Bone resorption depends on the development of bone resorbing osteoclasts (osteoclastogenesis) in response to systemic and local signals that converge to regulate the RANKL/RANK/OPG system [
2,
3,
7,
8]. Here, we showed that PRL reduces the systemic levels and the joint production of cytokines with osteoclastogenic activity, lowers the joint expression of the genes encoding for RANKL and RANK, decreases osteoclast density, and reduces trabecular bone area in two murine models of inflammatory arthritis. Moreover, synovial fibroblasts are an important source for RANKL-induced bone loss in arthritis [
6], and we showed that PRL downregulates cytokine-induced expression of the RANKL gene in cultured synovial fibroblasts via a STAT3-dependent pathway, and that this hormone reduces osteoclastogenesis in co-cultures of synovial fibroblasts and osteoclast progenitor cells.
Chronic inflammation determines local and systemic bone loss in RA [
2,
3] and may be attenuated by PRL. PRL treatment reduces joint swelling, proinflammatory cytokine expression (TNFα, IL-1β, IL-6, and IFNγ), pannus formation, and the destruction of bone trabeculae in rats with AIA [
18], a model of inflammatory arthritis. Here, we have extended these findings by showing that increasing serum PRL to levels similar to those (40 ng/ml) found in the circulation of some patients with RA [
35] reduced systemic levels of CRP and TNFα, two osteoclastogenic cytokines [
2,
3,
31]. The serum levels of CRP and TNFα in RA patients correlate with their levels in the synovial fluid and reflect systemic and joint inflammatory responses [
31,
36]. Moreover, PRL treatment reduced the expression of transcription factors and cytokines associated with Th17 and T regulatory cells in arthritic joints. Th17 cells promote inflammation, osteoclastogenesis, and bone erosion in arthritis [
32,
37], whereas T regulatory cells suppress immune responses [
38], and the imbalance of the two T lymphocyte subpopulations has been identified as a key event in the pathogenesis of rheumatoid arthritis [
30]. It remains to be determined how PRL actions, particularly the downregulation of T regulatory cells, would contribute to PRL protection against inflammation and osteoclastogenesis in arthritis. The matter is complex as the differentiation and function of Th17 and T regulatory cells are closely related and vary in the presence of strong inflammatory conditions [
39,
40]. Both T cell populations require transforming growth factor (TGF)β for differentiation [
41], and in vivo studies have identified a subset of T cells that dually express elements of both the T regulatory and Th17 phenotypes [
40,
42] with potent inflammatory and osteoclastogenic effects in autoimmune arthritis [
43].
In support of PRL acting locally on inflamed joint tissues, we show that the long PRL receptor isoform is upregulated in the joints of rats with AIA and in the synovial membranes and synovial fibroblasts of mice treated with the proinflammatory cytokines, TNFα, IL-1β, and IFNγ, which contribute to AIA inflammatory lesions [
44]. PRL receptors exist in various molecular forms that differ primarily in the sequence and length of their cytoplasmic domain and are classified as long, intermediate, and short [
45]. The long PRL receptor is considered the major isoform signaling all PRL actions, the intermediate isoform transmits cell proliferation and survival signals, and the short PRL receptor exerts dominant-negative effects on signals by the long form [
46]. The long form of the PRL receptor appears to predominate in osteoblasts [
19] and chondrocytes [
25], where PRL promotes bone development and cartilage survival. Also, fibroblasts and T cells in the synovium of patients with RA express PRL receptors [
47], and proinflammatory cytokines induce the expression of the long form of the PRL receptor in lung fibroblasts to mediate anti-inflammatory effects of PRL in the airways [
48]. Therefore, these findings could imply that the long form of the PRL receptor mediates the protective effects of PRL in arthritis.
Supporting the anti-inflammatory role of PRL in arthritis, PRL-receptor-null mice exhibited increased joint swelling and higher joint expression of the genes encoding for TNFα, IL-1β, IL-6, IFNγ, IL-17A, IL-21, IL-22, IL-23, and IL-10 when subjected to monoarticular AIA (MAIA). These findings are consistent with PRL treatment inhibiting the expression of the same cytokines in the joints of rats with AIA [
18] and with previous reports showing that targeted disruption of PRL [
13] and of PRL receptors [
49] enhances immune responses and mortality under stress-related conditions. Besides their crucial effects on joint inflammation, TNFα, IL-1β, IL-6, and IL-17A also drive bone loss. They promote osteoclastic bone resorption largely by stimulating the expression and function of RANKL and RANK [
2,
32]. Accordingly, we next investigated whether PRL downregulates osteoclast development and bone loss in AIA and MAIA.
Increasing systemic PRL levels in rats with AIA and blocking PRL receptor signaling in
Prlr-/- mice with MAIA reduced and increased, respectively, the loss of trabecular bone area, osteoclast density, the accumulation of phenotypic markers identifying osteoclasts (the gene for RANKL cognate receptor RANK and the genes encoding for acid (TRAP and cathepsin K) and neutral (MMP-9) proteases used by osteoclasts to degrade the organic matrix of bone [
3]). Moreover, PRL and lack of PRL signaling reduced and increased, respectively, the expression of RANKL gene (
Tnfrsf11) in the arthritic joint, which resulted in a lower and higher
Tnfrsf11/Tnfrsf11b mRNA ratio for each condition, respectively.
Tnfrsf11b encodes for OPG, a soluble decoy receptor that neutralizes RANKL and prevents bone erosion in AIA [
4]. A high RANKL/OPG ratio occurs in patients with RA and is associated with increased bone resorption [
50].
Our findings indicate that inhibition of RANKL-induced osteoclast development is a component of PRL protection against bone loss in inflammatory arthritis. It is unclear whether PRL signals directly on osteoclasts or indirectly through other cell types responsible for bone loss. Arguing against osteoclasts being direct targets of PRL is the finding that bone marrow cells differentiated into osteoclasts are devoid of the PRL receptor [
19]. On the other hand, chondrocytes, osteoblasts, and synovial fibroblasts express PRL receptors and are major sources of osteoclastogenic cytokines including RANKL [
2,
5,
6,
51]. Here, we support direct effects of PRL on chondrocytes, synovial fibroblasts, and osteoblasts, but also in osteoclasts by showing the PCR-mediated amplification of a PRL receptor transcript in the various cell types obtained from
Prlr+/+ mice but not in those obtained from
Prlr-/- mice. While differences in osteoclast differentiation protocols may contribute to our contrasting finding [
19], the presence of the PRL receptor in osteoclasts reinforces the role of PRL on bone remodeling.
Consistent with synovial fibroblasts being cellular targets of PRL-induced anti-osteoclastogenesis, the incubation of primary cultures of synovial fibroblasts with TNFα, IL-1β, and IFNγ (Cyt) elevated the expression of the PRL receptor, and treatment of these cells with PRL inhibited Cyt-induced expression of
Il1b,
Il6, and
Tnfrsf11. PRL receptors signal through Janus kinase-2 (JAK-2)-STATs 1, 5, and 3 as their canonical pathway [
52]. STATs, and in particular STAT3, are emerging as important regulators of bone homeostasis [
33]. STAT3 mutations correlate with increased osteoclast number and bone resorption in the clinic [
53,
54] and mice with an osteoblast-specific deletion of
Stat3 have an osteopenic phenotype [
33]. Here, we demonstrate that PRL stimulates the expression of
Stat3 and enhances Cyt-induced phosphorylation/activation of STAT3 in synovial fibroblasts. The Cyt-induced STAT3 activation may be due to the production of IL-6 in response to the Cyt, as IL-6 activates STAT3 in synovial fibroblasts [
55]. However, IL-6-mediated STAT3 activation may lead to either bone resorption [
56] or bone formation [
57]. In support of STAT3 being anti-osteoclastogenic when activated by PRL, pharmacological blockage of STAT3 prevented PRL inhibition of Cyt-induced
Tnfrsf11 expression. These findings suggest that PRL may signal through STAT3 in synovial fibroblasts to inhibit RANKL-induced osteoclastogenesis. Consistent with this notion, we found that PRL acts on co-cultures of synovial fibroblasts and osteoclast precursor cells to downregulate Cyt-induced osteoclast differentiation. The fact that such PRL inhibition was reduced when osteoclast precursors were derived from
Prlr-/- mice implies that PRL receptors in osteoclast progenitor cells contribute to PRL protection against osteoclastogenesis. This is in agreement with the presence of PRL receptors in osteoclast-like cells and with the PRL downregulation of RANK in arthritic joints. Reduction of RANK levels may contribute to PRL inhibitory effects on osteoclastogenesis and bone loss at the level of osteoclast progenitors and mature osteoclasts.
PRL regulation of the RANKL/RANK/OPG system for physiological bone remodeling during growth and reproduction is well-substantiated [
58]. PRL decreases the RANKL/OPG ratio by downregulating RANKL and upregulating OPG in osteoblasts to promote bone formation early in life [
20], whereas in pregnancy and lactation, PRL accelerates bone turnover by raising the RANKL/OPG ratio in osteoblasts [
59,
60] in order to supply calcium for fetal growth and milk production. The opposing effects of PRL on bone remodeling indicate that the outcome of its action depends on complex age-related and hormone-related interactions.
In experimental inflammatory arthritis, PRL appears to be beneficial; however, the role of PRL in RA is controversial (as reviewed [
58]). PRL increases in the circulation of some patients with RA, but it is not clear whether systemic PRL levels correlate with disease severity. Confounding factors include the contribution of PRL synthesized locally by joint tissues like chondrocytes [
61], endothelial cells [
62], synoviocytes and immune cells [
47]; and the ability of PRL to exert immunostimulatory or immunosuppressive effects, depending on its level and that of other cytokines and hormones [
58]. Hyperprolactinemia in the context of reproduction [
59] and non-inflammatory pathology (prolactinoma) [
63] promotes bone loss, whereas high circulating PRL levels can be anti-inflammatory and reduce bone loss under inflammatory conditions [
18,
64] (and present findings). The mechanisms governing the effects of PRL on bone remodeling are challenging but a better understanding of them could lead to the use of hyperprolactinemia-inducing drugs as therapeutic agents in the clinic.