Front. Pharmacol. Frontiers in Pharmacology Front. Pharmacol. 1663-9812 Frontiers Media S.A. 772678 10.3389/fphar.2021.772678 Pharmacology Review Recent Advances in Pharmacological Intervention of Osteoarthritis: A Biological Aspect Deng et al. Pharmacological Treatment of Musculoskeletal Diseases Deng Jinxia 1 Zong Zhixian 1 Su Zhanpeng 1 Chen Haicong 1 Huang Jianping 2 3 Niu Yanru 1 Zhong Huan 1 * Wei Bo 1 * Affiliated Hospital of Guangdong Medical University, Guangdong Medical University, Zhanjiang, China College of Dentistry, Yonsei University, Seoul, South Korea Department of Stomatology, Guangdong Medical University, Zhanjiang, China

Edited by: Liangliang Xu, Guangzhou University of Chinese Medicine, China

Reviewed by: Wenxiang Cheng, Shenzhen Institutes of Advanced Technology, China

Liming Zhao, Stanford University, United States

 *Correspondence: Huan Zhong, zhh7218@qq.com; Bo Wei, webjxmc@163.com

This article was submitted to Integrative and Regenerative Pharmacology, a section of the journal Frontiers in Pharmacology

 23 11 2021 2021 12 772678 08 09 2021 04 10 2021 Copyright © 2021 Deng, Zong, Su, Chen, Huang, Niu, Zhong and Wei. 2021 Deng, Zong, Su, Chen, Huang, Niu, Zhong and Wei

This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

Osteoarthritis (OA) is a degenerative joint disease in the musculoskeletal system with a relatively high incidence and disability rate in the elderly. It is characterized by the degradation of articular cartilage, inflammation of the synovial membrane, and abnormal structure in the periarticular and subchondral bones. Although progress has been made in uncovering the molecular mechanism, the etiology of OA is still complicated and unclear. Nevertheless, there is no treatment method that can effectively prevent or reverse the deterioration of cartilage and bone structure. In recent years, in the field of pharmacology, research focus has shifted to disease prevention and early treatment rather than disease modification in OA. Biologic agents become more and more attractive as their direct or indirect intervention effects on the initiation or development of OA. In this review, we will discuss a wide spectrum of biologic agents ranging from DNA, noncoding RNA, exosome, platelet-rich plasma (PRP), to protein. We searched for key words such as OA, DNA, gene, RNA, exosome, PRP, protein, and so on. From the pharmacological aspect, stem cell therapy is a very special technique, which is not included in this review. The literatures ranging from January 2016 to August 2021 were included and summarized. In this review, we aim to help readers have a complete and precise understanding of the current pharmacological research progress in the intervention of OA from the biological aspect and provide an indication for the future translational studies.

 osteoarthritis DNA RNA exosomes platelet-rich plasma protein gene 2020A1515010003 2019A1515110724 NSFC, 81874000 Natural Science Foundation of Guangdong Province10.13039/501100003453 National Natural Science Foundation of China10.13039/501100001809 Introduction

Osteoarthritis (OA) is a degenerative chronic joint disease mainly affects the elderly, causing pain and loss of movement function. The trends of an aging population worldwide and increasing obesity are likely to make OA a leading cause of disability in the elderly (Hunter et al., 2020). Although many risk factors such as abnormal joint biomechanics, bone-mass index, joint injury, and genetic variations have been identified in the causation of OA, the etiology of OA is still poorly understood. In a traditional point of view, cartilage degradation was purely caused by mechanical imbalance (Francisco et al., 2018). Currently, increasing evidence shows that OA is a complex condition, in which the whole joints, including cartilage, subchondral bone, and synovium probably, are all involved in the pathogenesis (Goldring and Goldring, 2016), among which degradation of cartilage caused by matrix proteases plays a pivotal role (Pérez-García et al., 2019). In general, OA is a disease resulting from an imbalance between catabolic and anabolic events. In recent years, biologic agents become more and more attractive as they either target specific catabolic events, such as inflammation or matrix degradation, or promote anabolic events, such as anti-inflammation or chondrogenesis. In this review, we provide an update of the current treatment strategies and recent research progress in the pharmacological intervention of OA from the biology aspect (Figure 1).

The anabolic or catabolic effect of DNA, RNA, protein, or exosome in the initiation or development of osteoarthritis.

 Methods

We searched PubMed for combination of the following indexed subject headings [MeSH]: osteoarthritis, DNA, noncoding RNAs, exosomes, platelet-rich plasma, and proteins.

Current Treatment Strategies

Clinical management for OA patients depends on their development stages of the disease. As the pathogenesis of OA is complicated, there is still no specific intervention for the treatment of OA. The primary goal for OA management is to alleviate pain and stiffness and maintain the joint function (Hermann et al., 2018). The treatment strategies for OA can be divided into three categories: nonpharmacological interventions, pharmacological interventions, and surgical interventions. Current consensus guidelines recommend the use of combination of nonpharmacological interventions, pharmacological interventions, and surgical intervention where necessary. The majority of individuals with OA can be managed successfully with a combination of nonpharmacological interventions and pharmacological interventions. However, surgical approaches should be considered at the late stages to repair the cartilage lesions or even replace the joint to regain the function.

Lifestyle modification and physical therapy are the two main nonpharmacological interventions. Body weight control in obese patients improves the symptoms and reduces the risk of symptomatic OA will develop. Exercise strengthens the muscle around the joints and maintain the stability. Physical therapy, such as pulsed electromagnetic fields (Yang et al., 2018a), extracorporeal shock wave therapy (ESWT) (Yu et al., 2017), acupuncture (Tu et al., 2021), and so on, improves the mobility and relieves the symptoms. Chondroitin sulfate and glucosamine have been used as dietary supplements.

Nonpharmacological interventions could be insufficient for many patients who develop symptomatic OA. Pharmaceutical agents, especially acetaminophen and nonsteroidal anti-inflammatory drugs, play a key role in symptom control. Other agents such as duloxetine (Weng et al., 2020), opioids, intra-articular steroid (Wijn et al., 2020), and viscosupplement injections are also approved for OA management. These drugs may effectively relieve the pain. However, many safety concerns have been raised regarding their side effects.

Surgical interventions are inevitable for many patients. Joint reservation surgeries, such as high tibial osteotomy and joint distraction, have shown symptomatic improvement (van der Woude et al., 2017). However, evidence for the long-term effectiveness is still to be confirmed. Unicompartmental knee arthroplasty (Murray and Parkinson, 2018), total knee arthroplasty (TKA) (Gademan et al., 2016), and total hip arthroplasty are widely accepted by the patients with end-stage OA.

 Recent Progress in Biological Interventions DNA- or Gene-Based Therapy

DNA (Minchin and Lodge, 2019) is a double-stranded and long-chain polymer composed of four deoxynucleotides. DNA fragments with genetic information are called genes. At present, many genes are reported to be related to the occurrence and development of OA by increasing susceptibility, enhancing cartilaginous matrix degradation, preventing cartilage from repair, increasing the expression of inflammatory factors, or promoting fibroblast transformation. First, the susceptibility genes of OA mainly include ASPN (Wang et al., 2018), ADIPOQ (Shang et al., 2019), AKNA (Zhao et al., 2020a), DPEP1 (Zhang et al., 2021a), rs1065080 (Lu et al., 2019a), TLR7 (Wang et al., 2020a), RTP4 (Wang et al., 2020a), CRIP1 (Wang et al., 2020a), ZNF688 (Wang et al., 2020a), TOP1 (Wang et al., 2020a), EIF1AY (Wang et al., 2020a), RAB2A (Wang et al., 2020a), ZNF281 (Wang et al., 2020a), UIMC1 (Wang et al., 2020a), and PRKACB (Zhao, 2021). Second, the genes that promote the degradation of cartilage mainly include ADAMTS5 (Jiang et al., 2021), ADAM12 (Lv et al., 2017), JUN (Rhee et al., 2017), PTGS2 (Zhou et al., 2019a), MMP1 (Zhou et al., 2019a), MMP3 (Zhou et al., 2019a), MMP13 (Zhou et al., 2019a), AGT (Wang et al., 2020b), and rs2830585 (Zhou et al., 2019b). Third, several genes such as BMP3 (He et al., 2018), rs1799750 (Geng et al., 2018), and CHI3L1 (Song et al., 2021) show an inhibitory effect on cartilage repair. Fourth, the genes that regulate the expression of inflammatory cytokines in chondrocytes mainly include renin (Wu et al., 2019a), ACE (Wu et al., 2019a), Ang II (Wu et al., 2019a), AT1R (Wu et al., 2019a), AT2R (Wu et al., 2019a), ATF3 (Iezaki et al., 2016), PTGS2 (Lin et al., 2018; Wang et al., 2020a), CCL20 (Lin et al., 2018), CHI3L1 (Lin et al., 2018), LIF (Lin et al., 2018), CXCL8 (Lin et al., 2018), and CXCL12 (Lin et al., 2018). Last but not least, COL6A3/ACTG1 (Li et al., 2020a) and fibronectin1 (FN1) (Wu et al., 2020a) were found involved in fibroblast transformation. Although many catabolic genes have been found, there are very limited key anabolic genes that can promote the proliferation or differentiation of chondrocytes or encode key anchoring collagen molecules and the corresponding genes including GDF5 (Sun et al., 2021), Gas7 (Zhong et al., 2020), PRELP (Li et al., 2019a), TGF-β (Tao et al., 2016), SOX9 (Tao et al., 2016), and COL9A1 (Durand et al., 2020).

Genetic modification of joints has been achieved in preclinical models by ex vivo and in vivo strategies using a variety of vectors (Evans et al., 2018). Delivering genes from the body to the joints through direct intra-articular injection is a feasible way to speed up treatment. However, many vectors are inflammatory, immunogenic, or unsafe or provide only short-term transgene expression after successfully transferring cells into joint tissues. In order to solve this problem, an ideal delivery vector in vivo has been discovered; it is the adeno-associated virus (AAV), which is safer, more effective, and less immunogenic than other vectors (Evans et al., 2018). In addition, AAV also prolongs the expression time of transgenes in joints. When injected into the joint, the recombinant AAV will transduce synovial lining cells and chondrocytes at the thickness of the articular cartilage (Watson Levings et al., 2018). Besides the genetic regulation, epigenetic regulations, such as DNA methylation, may be also involved in OA pathology. Hypermethylation leads to a decrease in the expression of COL9A1, destroys the integrity of cartilage, and promotes the development of OA (Miranda-Duarte, 2018). SOX9 is a key transcription factor for cartilage formation in chondrocytes. The DNA methylation of SOX9 gene promoter in chondrocytes of patients with OA increases. This increase in methylation reduces the binding affinity of transcription factors, thereby reducing the expression of SOX9 in OA chondrocytes (He et al., 2020a). The DNA methyltransferases could be the potential targets to the treatment of OA in the future.

 Noncoding RNA-Based Therapy

As mentioned, many studies in OA have focused on the epigenetic regulation of its pathogenesis and potential targets for therapy, specifically noncoding RNA (ncRNA). Human genome is estimated to contain ∼2% protein-coding RNA, whereas a vast majority of the genome comprises ncRNA. These ncRNAs, such as microRNA (miRNA), long noncoding RNA (lncRNA), and circular RNA (circRNA), are involved in the pathological development of OA, which can be used as diagnostic and therapeutic markers for OA progression and prognosis. Recent preclinical evidence shows that many ncRNAs can directly affect the expression of key genes involved in OA, which have great translational potential in OA treatment (Duan et al., 2020). Future research on elucidating the role of ncRNAs will also help in better understanding the etiology of OA. In particular, research and development of therapeutic targets for OA provide important clues (Cong et al., 2017). However, studies also report that many ncRNAs are considered the critical elements in cancer development (He et al., 2021a). Sufficient preclinical safety inspections should be performed before clinical use (Xie et al., 2020a).

MiRNA

Among those ncRNAs, miRNAs are most popular in recent years, with approximately 22 nucleotides, functioning in RNA silencing and posttranscriptional regulation of gene expression. Many studies have reported that several miRNAs could play an important role in regulating bone and cartilage homeostasis (Shen et al., 2019) (Table 1), through regulating the signaling pathways involved in extracellular matrix (ECM) degradation, apoptosis or hypotrophy of chondrocytes, or synovial inflammation.

miRNA and the targets in osteoarthritis.

Functions Effects MiRNAs Targets References
Negative regulation Inhibit chondrocyte proliferation miR-21 GDF-5 Sekar (2021)
Promote osteoclast formation miR-21 Unknown Sekar (2021)
Promote chondrocyte apoptosis miR-146a SMAD4 Malemud (2018)
miR-1236 PIK3R3 Wang et al. (2020c)
miR-34a Visfatin (NF-ΚB)/ADAMTS-4 Cheleschi et al. (2019)
miR-181a GPD1L Zhai et al. (2017)
MiR-155 GPD1L Zhai et al. (2017)
miR-384-5p SOX9 Zhang et al. (2018a)
miR-9 Sirtuin-1 D'Adamo et al. (2017)
miR-335-5P HBP1 Lu et al. (2021)
miR-107 TRAF3 Zhao et al. (2019)
Promote inflammation miR-149-5p AGT Wang et al. (2020b)
Increase matrix degradation miR-33a TGF-β1/Akt/SREBP-2 Ghafouri-Fard et al. (2021)
miR-483-5p HDAC4, Matn3/Timp2 Wang et al. (2019a)
miR-101 SOX9 Chu et al. (2019)
Promote cartilage degradation miR-141/200c SIRT1 Ji et al. (2020a)
miRNA 218-5p PIK3C2A Lu et al. (2017)
miR-146b Alpha-2-macroglobulin (A2M)/SOX5 Liu et al. (2019b)
miR-21-5p FGF18 Wang et al. (2019b)
miR-98 Bcl-2 Wang et al. (2017b)
Inhibit chondrocyte differentiation miR-582-5p Runx2 Wang et al. (2019c)
miR-324-5p GLI1 and SMO Woods et al. (2019)
Positive regulation Promote chondrocyte proliferation miR-132 PTEN/PI3K/AKT Zhang et al. (2021c)
miR29a MMP-13/ADAMTS-5 Komori (2016)
miR-138 NEK2 Xu et al. (2019)
miR-4784 Col2a1/MMP-3 Liu et al. (2018)
miR-210 HIF-3α Zhao et al. (2020c)
miR-101 Sox9/Runx2 Gao et al. (2019)
miR-210-3p SOX9/COLII Yang et al. (2021b)
Promote cartilage regeneration miR-149-5p FUT-1 Çelik et al. (2019)
Inhibit chondrocyte apoptosis miR-766-3P AIFM1 Li et al. (2020b)
miR-132 PTEN/PI3K/AKT Zhang et al. (2021c)
miR-582-3p YAP1 He et al. (2020b)
miR-455-3p PI3K/AKT Wen et al. (2020)
miR-138 NEK2 Xu et al. (2019)
miR-93-5p TCF4 Xue et al. (2019)
Repression of chondrocyte autophagy miR-130a HOTAIR lncRNA Hu et al. (2019)
Inhibit osteoclast formation miR-125b Unknown Yoshiko and Minamizaki (2020)
Inhibit the degradation of cartilage miR-221 SDF1/CXCR4 Zheng et al. (2017)
Decrease metabolic enzyme activity miR-1 FZD7 Xie et al. (2020a)
Suppress inflammation miR-582-3p YAP1 He et al. (2020b)
miR-335-5p 3-MA Zhong et al. (2019)
miR-106a5p GLIS3 Ji et al. (2018)
Inhibit ECM degradation miR-582-3p YAP1 He et al. (2020b)
miRNA-140 MMP-13/ADAMTS-5 Si et al. (2017)
miR-145 MKK4 Hu et al. (2017)
Enhance cartilage repair mi-107 HMGB-1 Lin et al. (2019)
Inhibit the destruction of articular cartilage miR-204 Runx2 Huang et al. (2019a)
LncRNA

lncRNAs are another type of ncRNAs that are longer than 200 nucleotides (Zhang et al., 2021b). LncRNA–RNA interaction controls mRNA translation and degradation, or as silent miRNA sponges. They are also regarded as important regulators of cartilage development (Table 2). The anti-OA mechanism of lncRNA may be achieved by competitively binding miRNA, reducing the binding of miRNA and downstream genes, and increasing the transcription and expression of downstream genes (Wu et al., 2019b).

lncRNAs and the targets in osteoarthritis.

Functions RNAs Target References
Negative regulation MIAI miR-132 Li et al. (2019b)
DANCR miR-216a-5p/JAK2 Zhang et al. (2018b)
TM1P3 miR-22 Li et al. (2019c)
CTD-2574D22.4 Unknown Li et al. (2019d)
CAIF miR-1246 Qi et al. (2019)
TNDSF10 miR-376-3p/FGFR1 Huang et al. (2019b)
LOC101928134 IFNA1 Yang et al. (2019a)
CASA2 Unknown Huang et al. (2019c)
CHRF microRNA-146a Yu et al. (2019)
Nespas miR-291a-3p Park et al. (2019)
H19 miR-130a Hu et al. (2019)
THRIL microRNA-125b Liu et al. (2019c)
TUG miR-195 Tang et al. (2018)
P21 miR-130b Han and Liu (2018)
CIR miR-27 Li et al. (2017a)
PVT1 miR-488-3p Li et al. (2017b)
XIST miR-211 Li et al. (2018a)
MBNL1-AS1 KCNMA1 Li et al. (2018b)
HOTAIR miR-17-5p Hu et al. (2018)
miR-130a-3p He and Jiang (2020)
FAS-AS1 MMP1/MMP13/COL2A1 Zhu et al. (2018)
TMSB4 miRNA-152 Liu et al. (2016)
HOTTIP Unknown He et al. (2021b)
LINC02288 miR-374a-3p Fu et al. (2021)
LINC01534 miR140-5p Wei et al. (2019)
MSR miR-152 Liu et al. (2016)
PART1 miR-373-3p/SOX4 Zhu and Jiang (2019)
GAS5 miR-34a/Bcl-2 Ji et al. (2020b)
NEAT1 miR-193a-3p/SOX5 Liu et al. (2020)
Positive regulation FOXD2-AS1 miR-27a-3p Wang et al. (2019d)
miR-206 Cao et al. (2018)
ANCR TGF-β1 Li et al. (2019e)
ANRIL miR-122-5p/DUSP4 Li et al. (2019f)
DILC IL-6 Huang et al. (2019d)
DNM3OS miR-126/IGF1 Ai and Yu (2019)
MIR4435-2HG Unknown Xiao et al. (2019a)
SNHG1 MAPK/NF-κB Lei et al. (2019)
HULC miR-101 Chu et al. (2019)
HOTAIRM1-1 miR-125b/BMPR2 Xiao et al. (2019b)
PACER Unknown Jiang et al. (2019)
PART1 miR-590-3p/TGFBR2/SMAD3 Lu et al. (2019b)
MEG3 miR-93 Chen et al. (2019)
miR-16 Xu and Xu (2017)
LINC00341 miR-141 Yang et al. (2019b)
ATB miR-223 Ying et al. (2019)
PMS2L2 miR-203 Li et al. (2019g)
MALAT1 miR-150-5p Zhang et al. (2019)
ROR HIF1α/p53 Yang et al. (2018b)
ZFAS1 Wnt3a Ye et al. (2018)
GACAT3 IL-6/STAT3 Li et al. (2018c)
UFC1 miR-34a Zhang et al. (2016)
NKILA miR-145/SP1/NFκB Xue et al. (2020)
CircRNA

CircRNA is a covalently closed circRNA molecule that contains exon sequences and is spliced at the canonical splicing site (Tam et al., 2019), functioning as miRNA sponges or competing endogenous RNAs that naturally sequester and competitively inhibit miRNA activity. CircRNAs also emerge as a new player in the development of OA through mechanisms such as interfering chondrocyte proliferation and apoptosis, regulating ECM degradation, and inflammation (Yang et al., 2020) (Table 3).

CircRNAs and the targets in osteoarthritis.

Functions RNAs Target References
Negative regulation CircRNA-UBE2G1 miR-373/HIF-1a Chen et al. (2020a)
Circ_0136474 miR-127-5p/MMP-13 Li et al. (2019h)
CircPSM3 miRNA-296-5p Ni et al. (2020b)
has_Circ_0005105 miR-26a/NAMPT Wu et al. (2017b)
hsa_Circ_0032131 unknown Wang et al. (2019e)
hsa_Circ_0104873 Unknown Yu et al. (2018)
hsa_Circ_0104595
hsa_Circ_0101251
CircRNA-CDR1as miR-641/FGF-2 Zhang et al. (2020)
CircRNA_Atp9b miR-138-5p Zhou et al. (2018)
CircRNA.33186 miR-127-5p/MMP-13 Zhou et al. (2019c)
CircGCN1L1 miR-330-3p/TNF-α Zhu et al. (2020)
Circ-SERPINE2 miR-1271/ERG Tam et al. (2019)
CiRS-7 miR-7 Zhou et al. (2019d)
CircHYBID miR-29b-3p/TGF-β1 Liao et al. (2021)
Circ-SPG11 miR-337-3p/ADAMTS5 Liu et al. (2021)
Circ-CSNK1G1 miR-4428/FUT2 Xiao et al. (2021)
Positive regulation CircVCAN NF-κB Ma et al. (2020)
Circ9119 miR-26a/PTEN, Chen et al. (2020b)
hsa_Circ_0045714 miR-193b/IGF-1R Li et al. (2017c)
hsa_Circ_0020014 Unknown Wang et al. (2020d)
CircPDE4D miR-103a-3p/FGF18 Wu et al. (2021)
Protein-Based Therapy

The protein currently used in clinical practice is mainly platelet-rich plasma (PRP) (Szwedowski et al., 2021). PRP is an autologous plasma preparation rich in platelets whose plasma concentration is higher than the normal concentration in whole blood. The basic principle of therapeutic potential of high-concentration platelets is based on their ability to provide superphysiological amounts of essential growth factors to provide regenerative stimulation that can promote tissue repair. PRP preparations need to be activated before use (Gentile et al., 2020). Intra-articular injections of PRP may be an effective alternative treatment to pain killers for knee OA (Rajan et al., 2020). It significantly promoted the proliferation of chondrocytes, decreased apoptosis, and increased autophagy by regulating the markers including FOXO1, FOXO3, and HIF-1 in osteoarthritic chondrocytes (Moussa et al., 2017). The concentration of white blood cells during the leukocyte-rich PRP (LR-PRP) preparation will affect its efficacy (Yaşar Şirin et al., 2017). It is reported that compared with the LR-PRP, the leukocyte-poor PRP (LP-PRP) has an effect on improving the proliferation of chondrocytes. The lubricating property of hyaluronic acid (HA) facilitates the movement of joints. And a combination of HA and PRP (HA–PRP) (Zhao et al., 2020b) could exert a beneficial synergistic effect for OA treatment. However, up until now, the preparation method and the components of PRP have still not been standardized, making the efficacy of PRP therapy to be inconclusive.

In addition to PRP, the proteins currently studied include nerve growth factor antibody (Grässel and Muschter, 2020) or its antagonists (Denk et al., 2017), fibroblast growth factor (FGF) (Xie et al., 2020b), insulin-like growth factor–binding proteins (IGFBP) (Tanaka et al., 2021), growth and differentiation factor 5 (Kania et al., 2020), Wnt16 (Tong et al., 2019), low-density lipoprotein receptor–related protein 5 (Wu et al., 2017a), neuropeptide Y (NPY) (Kang et al., 2020), and so on. Among the proteins, fasinumab (Dakin et al., 2020), tanezumab (Berenbaum et al., 2020), sprifermin (Eckstein et al., 2020), teriparatide (Apostu et al., 2019), and so on, have shown various effects on the management of OA in clinical trials. Nerve factor antibodies and their antagonists, fasinumab and tanezumab, can improve pain, and the antagonists have the most significant effect. Tanezumab can easily lead to rapidly progressive OA. FGF, GDF5, Wnt16, NPY, sprifermin, and teriparatide are related to cartilage repair. IGFBP is related to cartilage matrix synthesis. The binding of low-density lipoprotein receptor–related protein and sclerostin can inhibit the degradation of normal chondrocytes, but it does not seem to have such an effect in OA. The specific reason is not clear.

Recently, histone modifications have been recognized as another important epigenetic regulation in OA-related genes. LSD1 KDM4B, KDM6A, KDM6B, EZH2, and DOT1L were reported to be the major epigenetic regulators in OA onset and progression through their methyltransferases and demethylase activities by binding to the OA-related gene (e.g., Runx2, Nfat1, and Sox9) promoters or by interplaying with OA-associated signaling transduction pathways (Sacks et al., 2018). Modified histone domains have thus become epigenetic signatures, which will either mark for gene activation or gene repression. The role of methyltransferases and demethylase in epigenetic regulations also indicate they could be potential targets for the management of OA.

 Exosomes

Exosomes are small, single-membrane, secreted organelles with a diameter of approximately 30–200 nm. They have the same topological structure as cells and are rich in selected proteins, lipids, nucleic acids, and glycoconjugates (Pegtel and Gould, 2019). Exosomes mainly mediate cell–cell communication through direct membrane fusion or protein–protein interaction (Wu et al., 2020b). The source of exosomes comes in many forms (Ni et al., 2020a), including peripheral blood (Chang et al., 2018), synovial fluid (Gao et al., 2020), mesenchymal stem cells (Tofiño-Vian et al., 2018), embryonic stem cells (Wang et al., 2017a), vascular endothelial cells (Yang et al., 2021a), dental pulp stem cells (Lin et al., 2021), monocytes (Bai et al., 2020), amniotic fluid stem cells (Beretti et al., 2018), chondrogenic progenitor cells (Toh et al., 2017), chondrocytes (Zheng et al., 2019), PRP (Liu et al., 2019a), osteocytes (Lyu et al., 2020) (Table 4), and so on. Exosomes with different origins may have different functions. Exosomes in the joint microenvironment are involved in the development of OA. Most therapeutic exosomes may have an anabolic effect by promoting expression of chondrogenic markers or cartilage ECM or exert an effect by inhibiting inflammation, hypertrophy, or apoptosis of chondrocytes (Zhou et al., 2020) showing great potential for OA therapy.

Exosomes in the treatment of OA.

Functions Origins Mechanisms
Catabolic effect Synovial fluid (Gao et al., 2020), vascular endothelial cells (Yang et al., 2021a) Recruit inflammatory cells (Gao et al., 2020), inhibit cartilage proliferation (Gao et al., 2020), promote joint degeneration (Gao et al., 2020), or induce chondrocyte apoptosis (Yang et al., 2021a)
Anabolic effect Mesenchymal stem cells (Tofiño-Vian et al., 2018), embryonic stem cells (Wang et al., 2017a), dental pulp stem cells (Lin et al., 2021), monocyte (Bai et al., 2020), amniotic fluid stem cells (Beretti et al., 2018), chondrogenic progenitor cells (Toh et al., 2017), chondrocytes (Zheng et al., 2019), platelet-rich plasma (Liu et al., 2019a), osteocytes (Lyu et al., 2020) Reduce production of catabolic enzymes (Tofiño-Vian et al., 2018), promote chondrocytes to express cartilage ECM (Wang et al., 2017a; Kim et al., 2020; Guillén et al., 2021), promote chondrocyte differentiation (Bai et al., 2020), promote proliferation of chondrocytes (Liu et al., 2019a; Lyu et al., 2020), inhibit chondrocyte apoptosis (Liu et al., 2019a; Lyu et al., 2020; Lin et al., 2021), regulate immune response (Zheng et al., 2019), or inhibit expression of inflammatory cytokines (Toh et al., 2017; Beretti et al., 2018; Tofiño-Vian et al., 2018; Kim et al., 2020; Qiu et al., 2021)

Sustained-release drug delivery systems have been developed by a combination of exosomes and tissue engineering strategies, showing great promising results in recent research by delivering targeted drug or nucleic acids for regenerative medicine (Akbari et al., 2020). However, because of complexity in the components and rare understanding of their functions, exosomes remain challenges for clinical applications (Zhou et al., 2020).

 Literature Analysis

In order to analyze the research trends in the field of OA treatment using the biologic agent in recent years, we have reviewed relevant literature on DNA, RNA, protein, and exosome in the past 5 years on PubMed and also subdivided RNA into circRNA, lncRNA, and miRNA. We present a graphic (Figure 2) and the corresponding table (Supplementary Table S1) to show the literature trend in the past 5 years from January 2016 to August 2021. From the results, we can see that the number of articles of each type of biological agent has increased throughout the past 5 years. Among the four types of biologic agents, the most abundant research on proteins was found, followed by RNA, then DNA, and finally exosomes. Within RNA, miRNA has been studied most intensively, followed by lncRNA, and finally circRNA. This result shows that the research on proteins and RNA is relatively mature, but DNA and exosomes are new highlights in recent years. Within RNA, there are relatively many studies on miRNA and relatively fewer studies on lncRNA and circRNA. Therefore, DNA, exosomes, lncRNA, and circRNA may all become new research hotspots.

Publication trends in biologics from January 2015 to August 2021.

 Discussion

DNA, RNA, and protein described in this article have shown various regulatory effects on the pathological process of OA. Some of those are expected to become targets in terms of diagnosis and treatment of OA. In general, the effects of biologic agents are divided into two aspects: catabolic or anabolic effect by deteriorating or preventing OA occurrence or development. The catabolic effect is mainly to recruit inflammatory cells, inhibit chondrocyte proliferation, accelerate matrix degradation, or induce cell apoptosis. In opposite, the anabolic effect is mainly to reduce the production of catabolic enzymes, promote the proliferation of chondrocytes, inhibit chondrocyte apoptosis, promote the expression of ECM, or inhibit the expression of inflammatory factors. The main pathways involved in OA treatment are NF-κB, Notch, Wnt/β-catenin, TGF-β, Erk, p38 MAPK, JAK2/STAT3, and so on. At present, most researches on biologic agents are in vitro experiments or animal model experiments. There are still many obstacles to overcome for the biologics agents: (1) safety concern is the first to be considered when applying viral vectors to deliver plasmids, ncRNAs, which may bind to multiple targets; and exosomes and proteins, which may result in immunoresponse and disease transmission; (2) efficacy of most of the biologic agents in OA therapy is various and still yet to be verified; (3) heterogeneity of disease may also affect the therapeutic outcomes. With the advancement of molecular biotechnology in future research, translation research should be considered to address the limitations before clinical trials.

 Conclusion

We have reviewed a wide spectrum of biologic agents in OA therapy, including DNA, RNA, protein, and exosomes, which provide an insight in finding potential therapeutic targets. Although significant progress has been made in this field, translational research is needed to further address the safety concerns, various efficacies, and heterogenetic of OA.

 Author Contributions

JD, ZZ, ZS, and HC did literature retrieval and prepared the draft, JD, JH, and YN made the first revision of the manuscript, HZ and BW finalized the manuscript.

 Funding

This project was funded by Natural Science Foundation of Guangdong Province Science and Technology Department (2020A1515010003 and 2019A1515110724), Natural Science Foundation of China (NSFC, 81874000), Medical Research Fund of Guangdong Province (A2020151), “Peaking Plan” for the construction of high-level hospital at Affiliated Hospital of Guangdong Medical University (20501DFY20190168), Discipline construction project of Guangdong Medical University (4SG21002G), and also supported by the Science and Technology Project of Zhanjiang city (2020A01025 and 2019A01029).

 Conflict of Interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

 Publisher’s Note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

 Supplementary Material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fphar.2021.772678/full#supplementary-material

Abbreviations

CircRNA, circular RNA; FGF, fibroblast growth factor; HA–PRP, hyaluronic acid–platelet-rich plasma; IGFBP, insulin-like growth factor–binding proteins; lncRNA, long noncoding RNA; LP-PRP, leukocyte-poor–platelet-rich plasma; LR-PRP, leukocyte-rich–platelet-rich plasma; miRNA, microRNA; OA, osteoarthritis; PRP, platelet-rich plasma; TGF-β, transforming growth factor β.

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