CD34⁺THY1⁺ synovial fibroblast subset in arthritic joints has high osteoblastic and chondrogenic potentials in vitro

We obtained synovial tissues from surgeries of joint replacement for patients with OA and RA. We consecutively collected all the available OA and RA samples for this study. Written informed consent for this study and the ethics approval from the medical research ethics committee of Tokyo Medical and Dental University (approval number: M2000-979) were obtained. The synovial tissues were collected from 70 patients (RA: 18, OA: 52). All the patients with RA have been received treatment with disease-modified anti-rheumatic drugs (DMARDs) including biologics. Ten patients were administered steroids (average dose, 2.9 mg/day). Other characteristics are described in Table 1. In this study, we statistically analyzed combined data from RA and OA samples because of their limited sample numbers. Our previous study demonstrated that the altered proportions of SF subsets but not subsets themselves differed between RA and OA [13].

Tissue samples were collected consecutively from joint replacement surgeries to eliminate any bias as previously reported [13]. Briefly, joint tissues were obtained immediately after the surgeries, followed by removal of bone and adipose tissues with scissors. Synovial tissues were minced into small pieces and then subjected to enzymatic digestion. For cell culture, we digested tissues with 2 mg/mL collagenase type 4 (Worthington, NJ, USA), 0.8 mg/mL Dispase II, and 0.1 mg/mL DNase I (Roche, Basel, Switzerland) in Dulbecco’s modified Eagle Roche’s medium (DMEM) at 37 °C. After 15 min, we collected the supernatant and replaced it with a fresh enzyme mix. These procedures were repeated every 15 min for a total of 1 h. After lysing red blood cells with ACK-lysing buffer, obtained cells were treated with antibodies as described below then sorted by FACS Aria II and III (BD Biosciences, CA, USA) with 100-μm nozzle.

The following antibodies and reagents were used for the analysis of synovial cells with flow cytometry and cell sorting: anti-CD45-APC-H7 (2D1, BD Biosciences, CA, USA), anti-CD235a-APC-Alexa Fluor750 (11E4B-7-6, Beckman Coulter, FL, USA), anti-CD31-PE-Cyanine7 (WM-59, eBioscience, CA, USA), anti-CD146-APC (P1H12, eBioscience), anti-CD34-PE (4H11, eBioscience), anti-PDPN-PerCP-eFluor710 (NZ-1.3, eBioscience), anti-THY1-FITC (5E10, BD Bioscience), anti-CD73-PE-CF594 (AD2, BD Bioscience), anti-CD271-APC (ME20.4, eBioscience), anti-CD54-PE-CF594 (HA58 BioLegend, CA, USA), anti-CD44-APC (G44-26 BD Bioscience), anti-CD29-APC (TS2/16 BioLegend), human TruStain FcX (BioLegend), and Live/Dead fixable aqua dead cell stain kits (Molecular Probes, Thermo Fisher Scientific, MA, USA).

The gating strategy of SF subsets was as shown (Supplementary Figure 1). While the mean ratios of CD34⁻THY1⁻, CD34⁻THY1⁺, and CD34⁺THY1⁺ subsets in RA were 35.5%, 24.1%, and 24.8%, respectively, the mean ratios of these subsets in OA were 56.6%, 10.2%, and 17.2%. These results were compatible as previously reported [13]. The mean purity of each subset after sorting was 95.9%, 94.3%, and 98.0%, respectively.

We evaluated the expression of MSC surface markers (THY1, CD34, CD73, CD271, CD54, CD29, and CD44) in the SF subsets. Considering the expression of MSC markers in the freshly isolated synovial cells, we evaluated the mean fluorescence intensity (MFI) as expression levels of these markers in the individual subsets by flow cytometry in the 12 consecutive samples (RA: 3, OA: 9) (Supplementary Figure 2).

We sorted CD34⁻THY1⁻ fibroblasts, CD34⁻THY1⁺ fibroblasts, and CD34⁺THY1⁺ fibroblasts and cultured them in DMEM supplemented with 10% FBS (Gemini Bio, CA, USA), 2 mM l-glutamine, antibiotics (penicillin and streptomycin), and essential and nonessential amino acids (Life Technologies, CA, USA). The cells were expanded for 20–30 days for assays.

Osteoblastic induction was performed as previously reported [6]. 3.0 × 10³ cells/cm² were plated in a 12-well plate in an osteogenic differentiation medium containing l-ascorbic acid-2-phosphate (0.2 mM; Wako Pure Chemical Industries, Osaka, Japan), beta-glycerophosphate (5 mM; Wako Pure Chemical Industries), and dexamethasone (1 nM; Wako Pure Chemical Industries) and incubated at 37 °C in 5% CO₂. All media were changed twice per week. Each SF subset was cultured for 3–4 weeks. Histological staining was performed with alizarin red (Merk Millipore, MA, USA) and alkaline phosphatase (ALP) staining for osteoblast differentiation.

For chondrogenic differentiation, 1.25–2.5 × 10⁵ cells were placed in a 15-mL polypropylene tube (AGC Techno Glass Co., Ltd, Shizuoka, Japan) and centrifuged at 1500 × g for 5 min. The cells were cultured in a chondrogenic induction medium containing 1000 ng/mL of BMP-2 (PeproTech, NJ, USA) and 10 ng/mL of transforming growth factor-β3 (PeproTech), incubated at 37 °C in 5% CO₂ for 3 weeks. All media were changed twice per week. Histological staining was performed with safranin O staining for chondrogenesis.

For adipogenesis, 7.0 × 10³ cells/cm² are plated and cultured in StemPro™ Adipogenesis Differentiation Kit (Gibco, Thermo Fisher Scientific, MA, USA) for 3 weeks. All media were changed twice per week. Oil-red staining was used to evaluate adipogenesis.

For chondrogenesis and adipocyte differentiation, we referred to the previous reports with some modifications [20, 21]. Briefly, we performed some pellet culture at a density of 1.25 × 10⁵ cells due to an imbalance in the number of each subset.

cDNA was synthesized with QuantiTect Reverse Transcription kit (Qiagen, Hilden, German). Quantitative polymerase chain reaction (qPCR) was performed with Brilliant III Ultra-Fast SYBR Green qPCR master mix (Agilent Technologies, CA, USA) on a LightCycler96® (Roche). The following primers are used as shown in Table 2.

Bulk SFs were seeded at 1.2 × 10⁴ into 12-well cell culture plates and subsequently transiently transfected with 20 pM of THY1 or control small interfering (si) RNA (Thermo Fisher Scientific) using Lipofectamine RNAiMax (Thermo Fisher Scientific) according to the manufacturer’s protocol. Cells were incubated with siRNA for 3 days and subjected to osteogenic differentiation as described above.

Cell survival/proliferation was evaluated with a water-soluble tetrazolium salt (WST-8) colorimetric assay using Cell Counting Kit-8 (Dojindo) according to the manufacturer’s protocol. Briefly, SFs transfected with siRNAs were incubated with 1% WST-8 for 6 h and absorbance of supernatants at 450 nm was measured by a plate reader.

Considering the expression of surface markers in the freshly isolated synovial cells, both CD34⁺THY1⁺ and CD34⁻THY1⁺ subsets expressed THY1 with higher levels than the CD34⁻THY1⁻ subset, as we have shown previously [13]. Interestingly, the expression level of THY1 in CD34⁺THY1⁺ was the highest among the SF subsets regardless of the underlying diseases (Fig. 1A).

The expressions of CD73 and CD271 were the highest in the CD34⁺THY1⁺ subset among three subsets (Fig. 1B), whereas the expression levels of CD54 and CD29, a surface marker with low osteogenic potentials derived from other cell types [22, 23], were lower in the CD34⁺THY1⁺ subset than the CD34⁻THY1⁻ subset (Fig. 1B). The expression level of CD44 was not significantly different among the three subsets (Fig. 1B). We also analyzed data from RA and OA separately (Supplementary Figure 6). Although statistical significance was observed in only RA + OA and OA data, RA and OA showed the same tendency.

Regarding the transcriptions of MSC surface markers in microarray data, these were not significantly different among the three subsets (Supplementary Figure 3), indicating that these molecules are not regulated differently at the transcriptional levels. We also evaluated the expression level of surface THY1, CD34, and CD73 by flow cytometry after 4-week expansion for the subsequent differentiation experiments (Supplementary Figure 4). The expression of CD34 in the CD34⁺THY1⁻ subset was lost after expansion, while that of THY1 and CD73 was comparable among the three subsets.

The average ratio of calcified area stained with alizarin red as red spots was 4 and 1.5 times higher in CD34⁺THY1⁺ subsets than CD34⁻THY1⁻ and CD34⁻THY1⁺ subsets (Fig. 2A, B). We also stained three SF subsets with ALP staining to verify whether observed calcification is due to the differentiation of CD34⁺THY1⁺ SFs into osteoblasts. The activity of ALP, which was expressed as blue-stained area, was observed at twice higher levels in the CD34⁺ THY1⁺ subset (Fig. 2A, B) than the CD34⁻THY1⁻ subset.

To confirm the osteoblast differentiation by quantifying differentiation-associated genes, the expressions of mRNA levels were measured. The expression levels of RUNX2, the master regulator for osteoblast differentiation [24], were 2.8 times higher in the CD34⁺THY1⁺ subset than the CD34⁻THY1⁻ subset (Fig. 2C). As for expression levels of ALPL, which is a marker in the early stage of osteoblast differentiation, it was expressed 1.8 times higher in the CD34⁺THY1⁺ subset than the other two subsets after the differentiation for 3 weeks (Fig. 2C). The expression levels of OCN, a differentiation marker in the mature osteoblast, were 1.7 times higher in the CD34⁺THY1⁺ subset than the CD34⁻THY1⁻ subset after the differentiation for 4 weeks (Fig. 2C). These findings indicate that THY1⁺ subsets, especially the CD34⁺THY1⁺ subset, are the subset with the most superior osteogenic potentials in vitro. We also analyzed data from RA and OA separately (Supplementary Figure 7). Although statistical significance was observed in only RA + OA and OA data, RA and OA showed the same tendency.

After the culture in chondrogenic differentiation medium for 3 weeks, the largest chondrocyte pellets were formed from the CD34⁺THY1⁺ subset (Fig. 3A). The ratio of cartilage matrix stained as red by safranin O staining in CD34⁻THY1⁻, CD34⁻THY1⁺, and CD34⁺THY1⁺ subsets were 39%, 41%, and 46%, respectively (Fig. 3B). The CD34⁺THY1⁺ subset presented a significantly higher ratio of cartilage matrix than CD34⁻THY1⁻ subsets.

Confirming the quantitative verification of chondrogenesis, expression levels of ACAN, which codes aggrecan, were evaluated. In both CD34⁻THY1⁺ and CD34⁺THY1⁺ subsets, ACAN expression levels were 2.8 and 8 times higher than in the CD34⁻THY1⁻ subset, respectively (Fig. 3B). These findings indicated that THY1⁺ subsets, especially the CD34⁺THY1⁺ subset, have the highest chondrogenic potential in vitro. We also analyzed data from RA and OA separately (Supplementary Figure 8). Although statistical significance was observed in only RA + OA and OA data, RA and OA showed the same tendency.

After culture in the adipocyte differentiation medium for 3 weeks, all SF subsets comparably presented lipid droplets (Fig. 4A). The expressions of adipocyte-associated genes, including LPL and PPARγ, which codes lipoprotein lipase and peroxisome proliferator-activated receptor γ, were evaluated. The expression levels of LPL and PPARγ transcripts were not significantly different (Fig. 4B). We also analyzed data from RA and OA separately (Supplementary Figure 9). Although statistical significance was not observed, RA and OA showed the same tendency.

These findings indicated that osteogenic and chondrogenic potentials were relatively high in the CD34⁺THY1⁺ subset, whereas adipogenic potential was comparable among the three subsets.

Since THY1 is one of the MSC surface markers and associated with lineage potentials in osteogenesis and chondrogenesis, we hypothesized that baseline expression of THY1 in SF subsets determined differentiation potentials. Therefore, we investigated the endogenous function of THY1 in the osteoblast differentiation by the depletion using RNA interference in bulk SFs.

THY1 knockdown had minor effects on the survival and proliferation of SFs as assessed by WST-8 assay (Supplementary Figure 5A). We also examined the effects of THY1 knockdown on the expression of other MSC markers (Supplementary Figure 5B). The expression of CD29 was significantly suppressed by THY1 knockdown. CD73 was also suppressed in most samples. We could not detect any changes in CD271 and CD54 expressions.

Compared with those treated with siRNA control, THY1-deficient SF demonstrated impaired calcification as well as attenuated ALP activity after 4-week culture in an osteogenic differentiation medium (Fig. 5A, B). Expressions of THY1, RUNX2, and ALPL were also significantly suppressed (Fig. 5C). These findings supported the hypothesis that the expression of endogenous THY1 is inevitable for the MSC functions in the CD34⁺THY1⁺ subset.