Discussion
Glaucoma is considered a leading cause of irreversible blindness worldwide, with approximately half of all glaucoma patients residing in Asia. The prevalence of PACG is higher in Asia than in Europe and Africa.3 15 PACG can be further classified into three categories: PACS, PAC and PACG. During the continuous circular capsulorhexis step in cataract surgery, we observed that the anterior lens capsule was more relaxed in patients with coexisting PACG and PAC compared with those with ARC alone, characterised by reduced elasticity, increased deformability and the presence of folds. Within the PACG group, the anterior lens capsule was more relaxed in patients with PAC than in those with PACG.
Healthy eyes exhibit strong lens zonules connecting the ciliary body and lens capsule. Instability of these structures may cause capsular bag relaxation during capsulorhexis, suggesting potential weaknesses. This is mirrored in patients with pseudoexfoliation syndrome, where pseudoexfoliative material from the ciliary and lens epithelium accumulates, becomes altered and eventually detaches lens zonules.16 17 These changes can cause intraoperative symptoms, including capsular bag instability characterised by anterior capsule wrinkling, whole-bag movement, posterior capsule laxity, ciliary sulcus collapse and vitreous prolapse around the capsular bag.18 These findings suggest that there may be issues with the lens capsule, ciliary body or zonules in patients with PACG. To further explore these issues, we conducted SEM of the anterior lens capsule in three groups of patients. The PAC+ARC group exhibited disrupted and sparse intercellular connections, whereas the PACG+ARC group showed intercellular connections that were relatively loose. In contrast, the ARC group displayed dense and orderly arranged intercellular connections (figure 1). These microstructural changes suggest that alterations in the structure of the anterior lens capsule in angle-closure glaucoma may be related to decreased elasticity of the lens capsule. Decreased elasticity and relaxation of the lens capsule could potentially cause anterior displacement and convexity of the lens, further resulting in shallowing of the anterior chamber and induction of angle closure. The specific mechanisms require further research.
LTBP-2, encoded by 36 exons, is a matrix protein and a member of the superfamily comprising fibrillin and LTBP.19 TGF-β, a multifunctional pleiotropic growth factor, primarily inhibits cell proliferation and regulates ECM production. Secreted as a latent complex composed of mature dimeric growth factors, latent-associated peptides and LTBP, these complexes are stored in the fibrillin-rich ECM, where they await activation by appropriate signals.20 21 LTBP-2 is expressed in elastic tissues and interacts with fibrillin-1 and fibrillin-5 via their carboxyl and amino terminals, respectively, but not with fibrillin-2. LTBP-2 promotes fibrillin-5 fibrous deposition on fibrillin-1 microfibrils, serving as a structural and regulatory protein, and impacting microfibril function in elastic fibre assembly.11 22 These results suggest that the function of LTBP-2 is related to that of microfibrils and elastic fibres. Defects in microfibrils may cause glaucoma by altering tissue biomechanical properties and/or influencing TGF-β signalling.23 Homozygous LTBP-2 mutations reportedly cause human glaucoma, and mutations also affect other ocular diseases, such as megalocornea, spherophakia and Weill-Marchesani syndrome.24–27 Symptoms in many LTBP-2 mutation patients include laxity or dislocation of the lens zonules, and LTBP-2 deficiency weakens the strength and durability of zonular fibres.28 Currently, there is no consensus regarding how LTBP-2 causes glaucoma. Possible explanations include anterior displacement of the lens that pushes the iris forward and causes angle closure,29 30 or trabecular meshwork ECM changes that cause increased IOP.31 32
Elevated IOP is a significant risk factor for glaucoma, primarily due to damage to the trabecular meshwork and Schlemm’s canal aqueous humour drainage pathways.33 The trabecular meshwork consists of irregular networks of connective tissue bundles, through which the aqueous humour enters Schlemm’s canal and eventually flows into the venous system. While only LTBP-2 among the various LTBP proteins does not covalently interact with TGF-β, non-covalent interactions between LTBP-2 and TGF-β cannot be ruled out.34 The ECM of the trabecular meshwork is a critical component of IOP regulation.31 Some studies have suggested that the impact of oxidative stress and LTBP-2 gene expression downregulation on the ECM in glaucoma may be mediated by activation of the TGF-β and BMP signalling pathways.35 Oxidative stress can disrupt ECM morphology and cell-to-cell interactions. In cultured human scleral cells, oxidative stress induces the production of TGF-β1, thereby increasing the expression of ECM protein-encoding genes.36 Oxidative stress promotes the secretion of TGF-β2 in reactive astrocytes in the human optic nerve head. Hydrogen peroxide and TGF-β2 both increase Hsp27 expression by activating p38MAP kinase and reduce oxidative stress, and TGF-β2 may help reduce the characteristic changes in reactive astrocytes in the optic nerve head in glaucoma patients.37 Various subtypes of TGF-β and BMP are cytokines that belong to the TGF-β protein superfamily. Members of this family affect various cells and physiological functions throughout the body and influence developmental processes, and TGF-β2 and BMP can promote and reduce the expression of ECM proteins in lenses and TM cells.38 Increased TGF-β2 expression in the aqueous humour and trabecular meshwork in primary open-angle glaucoma leads to trabecular ECM deposition, causing elevated IOP, during which BMP may regulate the production of ECM induced by TGF-β2.39
In our study, we examined the expression of LTBP-2, which is known to be most highly expressed in the lens capsule among the various ocular tissues. LTBP-2 is expressed in the transition region between the trabecular meshwork, non-pigmented ciliary epithelium, corneal stroma and sclera, but is minimally expressed in the cornea, iris and sclera.40 Thus, we selected the anterior lens capsules of the enrolled patients as the study targets. Through RT-qPCR, immunoblotting and immunofluorescence staining analysis, we found that the expression of LTBP-2 mRNA and protein was lower in both the PAC+ARC and PACG+ARC groups than in the ARC group, with the PACG+ARC group showing lower LTBP-2 expression than the PAC+ARC group. We hypothesise that changes in the expression and distribution of LTBP-2 in the anterior lens capsule of angle-closure glaucoma lead to alterations in zonular microfibrils and the ECM. This results in decreased elasticity of the lens capsule and may be an important component in the pathogenesis of PACG.
This study had several limitations. First, the inherent constraints of SEM may have led to artefacts during sample preparation. Second, the surgical instruments may have damaged the lens capsule during the procedure. Finally, while our study noted a decline in the nucleic acid and protein expression of LTBP-2 in the anterior capsule in the PAC+ARC and PACG+ARC groups compared with the control group, our understanding of LTBP-2’s role in PACG is speculative and based on previous research. Further animal experiments are needed to clarify the role of LTBP-2 and develop new therapeutic strategies for PACG.