Dysregulation of septin cytoskeletal organization in the trabecular meshwork contributes to ocular hypertension
Rupalatha Maddala, … , Hélène Choquet, Ponugoti V. Rao
Rupalatha Maddala, … , Hélène Choquet, Ponugoti V. Rao
Published December 6, 2024
Citation Information: JCI Insight. 2024;9(23):e179468. https://doi.org/10.1172/jci.insight.179468.
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Research Article Cell biology Ophthalmology

Dysregulation of septin cytoskeletal organization in the trabecular meshwork contributes to ocular hypertension

Abstract

Ocular hypertension, believed to result partly from increased contractile activity, cell adhesive interactions, and stiffness within the trabecular meshwork (TM), is a major risk factor for glaucoma, a leading cause of blindness. However, the identity of molecular mechanisms governing organization of actomyosin and cell adhesive interactions in the TM remains limited. Based on our previous findings, in which proteomics analyses revealed elevated levels of septins, including septin-9 in human TM cells treated with the ocular hypertensive agent dexamethasone, here, we evaluated the effects of septin-9 overexpression, deficiency, and pharmacological targeting in TM cells. These studies demonstrated a profound impact on actomyosin organization, cell adhesion, contraction, and phagocytosis. Overexpression raised intraocular pressure (IOP) in mice, while inhibition increased cell permeability. In addition, we replicated a significant association between a common variant (rs9038) in SEPT9 with IOP in the Genetic Epidemiology Research on Adult Healthy and Aging (GERA) cohort. Collectively, these data reveal a link between dysregulated septin cytoskeletal organization in the TM and increased IOP, likely due to enhanced cell contraction, adhesive interactions, and fibrotic activity. This suggests that targeting the septin cytoskeleton could offer a novel approach for lowering IOP in patients with glaucoma.

Authors

Rupalatha Maddala, Pallavi Gorijavolu, Levi K. Lankford, Nikolai P. Skiba, Pratap Challa, Rakesh K. Singh, K. Saidas Nair, Hélène Choquet, Ponugoti V. Rao

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Figure 2

Septin colocalization with actin stress fibers and the impact of cytoskeletal reorganization agents on the septin cytoskeletal architecture in TM cells.

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Septin colocalization with actin stress fibers and the impact of cytoske...
(A and B) These panels show the colocalization of specified septins with F-actin in TM cells. The right-hand images present a higher magnification of the boxed areas in the third panel, illustrating the colocalization of septins with actin stress fibers (arrows). Cell nuclei are stained with Hoechst (blue, arrowheads). (C) This panel demonstrates the effects of various cytoskeletal reorganization agents on the septin cytoskeleton (SEPT9 immunostaining) in TM cells. Treatments included the F-actin–depolymerizing agent latrunculin A (2 μM for 5 minutes) that reduces septin filaments, resulting in a ring-like organization of septins (see inset for a magnified view of the boxed area); Rho kinase inhibitor Y2632 (10 μM for 2 hours), an actin stress fiber–suppressing agent that also decreases septin filaments; nocodazole (5 μM for 1 hour), a microtubule-depolymerizing agent that increases actin stress fibers (refer to Supplemental Figure 5) and enhances septin filament formation; and constitutively active RhoA expression, which, similar to nocodazole, increases the formation of septin filaments. Images are representative of a minimum of 3 different TM cell strains. Scale bars: 20 μm (A and C) and 5 μm (B).