Adhesive capsulitis, or frozen shoulder, is a debilitating condition in which patients present limited active and passive glenohumeral motion. Adhesive capsulitis occurs in 3%-5% of the general population 1 and the main cause of the painful restriction of movement is inflammatory contracture of the joint capsule. The initial inflammation seems to lead to capsular fibrosis, stiffness and pain 2. Therefore, it has been hypothesized that similarities exist between adhesive capsulitis and the fibrous contractures that occur in Dupuytren disease 3,4. However, the molecular mechanism responsible for the underlying glenohumeral capsule inflammation and fibrosis is poorly understood.

Rodeo et al. suggested that cytokines, such as transforming growth factor beta (TGFβ), may be involved in the inflammatory and fibrotic processes that occur in adhesive capsulitis. These cytokines may cause abnormal regulation of collagen expression and augment fibroblast proliferation 5. Therefore, TGFβ acts as a persistent stimulus that leads to capsular fibrosis.

TGFβ induces fibroblasts to synthesize, remodel and contract extracellular matrix (ECM), making this cytokine a key mediator of the fibrotic response 6. TGFβ is activated by proteolytic cleavage 7 mediated by the signaling receptors TGFβ receptor I (TGFβR1) and TGFβ receptor 2 (TGFβR2) 8. TGFBR1 is the principal propagator of TGFβ signaling 9.

TGFβ1, a key member of the TGFβ superfamily, regulates the collagen-modifying enzymes lysyl oxidase (LOX) 10 and lysyl hydroxylases 1 and 2 (encoded by the PLOD1 and PLOD2 genes, respectively) 11-13. LOX plays a role in connective tissue matrix biogenesis through the oxidation of lysine residues in collagen and elastin, contributing to the formation of covalent cross-links and thereby stabilizing fibrous ECM proteins 14,15. In several fibrotic injuries, TGFβ1 controls the expression and enzymatic activity of LOX 10.

Lysyl hydroxylases such as PLOD1 and PLOD2 promote cross-linking in ECM molecules, which contribute to ECM structural stability and maturation 16,17. Increased PLOD2 expression has been reported in fibroblasts isolated from hypertrophic scars, keloids and palmar fascia from patients with Dupuytren disease 18. To the best of our knowledge, no previous studies have evaluated the roles of lysyl oxidase and hydroxylase in adhesive capsulitis.

TGFβ regulates and is regulated by several ECM proteins. Cartilage oligomeric matrix protein (COMP), a glycoprotein found in the ECM of joints, plays a catalytic role in fibrillogenesis 19. Recent studies have shown that COMP also directly binds members of the TGFβ superfamily of proteins, including TGFβ1 20. Haudenschild et al. showed that TGFβ1 displays enhanced bioactivity when bound to COMP 20. In addition, TGFβ1 appears to have the capacity to induce COMP expression 21.

Fibronectin (FN), a glycoprotein encoded by the FN1 gene, is involved in several biological processes, including cell adhesion, tissue development and wound healing 22. FN also has a role in TGFβ regulation 23. Moreover, FN expression increases under stimuli induced by TGFβ 24.

Moreover, the tenascins (TN), including TNR, TNC and TNX, are a highly conserved family of ECM glycoproteins. TNR is expressed only in the brain, whereas TNC and TNX are expressed in several organs and tissues, including in the joints 25. TNC has an important role in modulating the actions of TGFβ 26 and is also regulated by TGFβ 27. TNXB seems to regulate collagen synthesis or deposition 28. A recent study showed that TNX also regulates TGFβ bioavailability and modulates cell plasticity 29.

In the present study, we quantified the mRNA expression of the TGFβ1, TGFβR1, LOX, PLOD1, PLOD2, COMP, FN1, TNC and TNXB genes in glenohumeral synovium/capsule samples collected from patients with adhesive capsulitis and from controls. We also evaluated how these mRNA levels are associated with clinical features.

Although adhesive capsulitis is considered a self-limited disease, some patients show little to no improvement, maintain a limited range of motion and continue to experience shoulder pain. Non-operative treatment is the initial approach used for adhesive capsulitis. However, operative treatment (such as arthroscopic capsular release) may be considered when patients remain in pain and do not regain satisfactory range of motion after prolonged nonoperative treatment 34,35.

In this study, we found higher levels of TNC and FN1 expression in glenohumeral synovium/capsule samples collected from patients with adhesive capsulitis compared to those collected from controls. TNC immunoreactivity was previously reported in other shoulder diseases, including in rotator cuff tendon tears and in the subacromial bursa of patients with impingement syndrome 36,37. In addition, we have previously found that both TNC and FN1 mRNA levels were upregulated in the glenohumeral capsules of patients with traumatic anterior shoulder instability (unpublished data). TNC is a large hexameric ECM glycoprotein that has roles in cell adhesion, fibroblast migration and other processes related to tissue remodeling and wound healing 38,39. TNC is specifically expressed following tissue damage, being upregulated within 24 h of injury 38. It is activated after local injury and down-regulated after tissue repair or scarring is completed 40. Persistent expression of TNC is associated with several fibrotic diseases and with chronic non-healing wounds 38.

Therefore, we hypothesize that increased TNC expression may be a marker of capsule injury and the genes involved may participate in inflammatory and fibrotic processes in the glenohumeral capsule.

FN is essential for collagen fibril assembly 41. During the early phase of wound healing, FN is deposited at sites of injury and can induce inflammation; increase ECM deposition, including of FN and collagen; and activate fibroblasts. These pathways can create a vicious cycle that eventually induces keloid formation or fibrosis 42. Additionally, FN has been previously associated with Dupuytren's contracture 24. In this disease, FN can be found in its oncofetal form 43,44. Additionally, upregulation of FN1 has been associated with fibrosis in inflammatory orbital diseases 45, hepatic fibrosis 46, idiopathic pulmonary fibrosis 47,48 and liver fibrosis 49. These relationships indicate that this molecule may also be involved in the pathogenesis of other fibrosing diseases. Interestingly, Altrock et al. showed that blocking FN deposition using an FN assembly inhibitor (pUR4) resulted in decreased collagen accumulation and improved liver function during liver fibrogenesis 50. Although only a slight increase in FN1 expression was detected in the glenohumeral capsules of the patients with adhesive capsulitis in the current study, our results suggest that FN1 may play a role in the fibrotic process. Further investigation is still necessary to understand the dynamic transcriptional regulation of FN1 that occurs within the shoulder capsule.

We also observed that the expression of TGFβR1 mRNA in the capsule was directly correlated with symptom duration in the patients with adhesive capsulitis. To the best of our knowledge, only one previous study has evaluated the role of the TGFβ receptor in adhesive capsulitis 5. Rodeo et al. analyzed both TGFβ and its receptor in capsule and synovium samples collected from patients with adhesive capsulitis and in those collected from controls 5. They performed a semi-quantitative analysis by comparing the frequency of positive staining between the groups. The authors described that the synovial and capsular cells of patients with adhesive capsulitis and synovitis showed clear TGFβ and TGFβR staining, whereas no or minimal staining was observed in the normal tissue specimens. The blood vessels of the affected tissues also presented staining for both proteins. Moreover, there was a higher frequency of positive TGFβ and TGFβR staining in the synovial cells of the patients with adhesive capsulitis. In addition, there was a greater frequency of positive TGFβ staining in the ECMs of patients with adhesive capsulitis compared to the controls, particularly in the capsule tissue.

In the present study, we found no differences in the expression of TGFβ1 and TGFβR1 mRNA between the cases and the controls. Because the synovium is adhered to the capsule and cannot be separated from the capsule using arthroscopic instruments, our investigation did not discriminate between gene expression in synovial and capsular tissues. However, molecular alterations in both tissues are important in adhesive capsulitis 51. In addition, our study is the first to use a quantitative approach to evaluate the role of TGFβR1 in adhesive capsulitis. Our results suggest that TGFβR1 may have a role in adhesive capsulitis, especially in the long-term disease.

To the best of our knowledge, this study is the first to quantify TGFβ1, TGFβR1, LOX, PLOD1, PLOD2, COMP, FN1, TNC and TNXB mRNA expression in the shoulder capsules of patients with adhesive capsulitis. However, this study has some limitations. First, few patients with adhesive capsulitis are surgically treated; as such, there is a limited number of tissue samples available for studies of gene expression 5,35,52-59. Therefore, some of our statistical analyses had reduced power to detect significant differences between the studied groups and false-negative results may have occurred. Second, we included patients who failed in conservative treatment in different phases of frozen shoulder, some in freezing and others in frozen stages. This heterogeneity may have also contributed to false negatives. Third, molecular alterations may occur in other capsule regions and may have a different etiological role in capsular injury 30-32. We evaluated the AI region because this portion of the capsule presented macroscopic injuries (i.e., a high level of inflammation) during arthroscopic examination of the studied patients. Although we did not detect a correlation between age and gene expression in the tissue samples collected from the patients with adhesive capsulitis, it is important to highlight that the age distribution between the patients and the controls was different. Thus, we cannot exclude that age might have influenced our findings. Finally, additional analysis of the protein products of the studied genes may be interesting because protein function is also affected by post-transcriptional and post-translational regulation.

Elevated expression of TNC and FN1 mRNA may be a marker of capsule injury and may be involved in capsule inflammation and fibrosis. Upregulation of TGFβR1 seems to be related to symptom duration in adhesive capsulitis; therefore, TGFβ signaling may play a role in this condition.

Cohen C, Leal MF, Smith MC, Ejnisman B and Faloppa F conceived and designed the experiments. Cohen C, Belangero PS, Figueiredo EA, Andreoli CV, Pochini AC and Ejnisman B were involved in data collection. Cohen C, Belangero PS, Figueiredo EA, Figueiredo EA, Pochini AC and Ejnisman B were responsible for sample collection. Leal MF was involved in the genetic analysis. Cohen C, Leal MF, Belangero PS and Figueiredo EA performed the literature search. Leal MF and Smith MC were involved in data and statistical analyses. Cohen C and Leal MF wrote the first draft of the manuscript. All authors listed have contributed to all subsequent drafts and all have approved the final manuscript.