Department of Biochemistry, Ophthalmology and Visual Sciences, West Virginia University, Morgantown, West Virginia 26506
J Neurosci. 2020 May 13;40(20):4059-4072. doi: 10.1523/JNEUROSCI.2994-19.2020. Epub 2020 Apr 7.
Photoreceptor neurons are surrounded by an extracellular matrix, called the interphotoreceptor matrix (IPM). Activities crucial to vision occur within the IPM, including trafficking of nutrients and metabolites, retinal attachment, and interactions needed for normal outer segment phagocytosis. The IPM includes the following two unique proteoglycans: IPM proteoglycan 1 (IMPG1) and IMPG2. Patients with mutations in IMPG1/IMPG2 develop visual deficits with subretinal material accumulation, highlighting the critical role of the IPM in vision. To determine the role of these proteoglycans in retinal physiology and the pathologic mechanisms that lead to vision loss, we generated mouse models lacking IMPG1/IMPG2. In normal retina, IMPG1 and IMPG2 occupy distinct IPM compartments, represent the main source of chondroitin sulfate and are fundamental for the constitution of the cone-specific glycocalyx stained by the PNA (peanut agglutinin) lectin marker. No evident morphologic or functional deficits were found in mice lacking IMPG1. In the absence of IMPG2, IMPG1 abnormally accumulated at the subretinal space need, likely leading to the formation of subretinal lesions and reduced visual function. Interestingly, mice lacking both IMPG1 and IMPG2, regardless of sex, showed normal retinal structure and function, demonstrating that the aberrant IMPG1 distribution is the main cause of the visual alterations observed in the absence of IMPG2. In conclusion, our results show the dependence of secreted proteoglycans such as IMPG1 on the extracellular environment to properly integrate into the matrix, demonstrate the role of IMPG2 in shaping the IPM, and shed light on the potential mechanisms leading to the development of subretinal lesions and vision loss. The photoreceptors are specialized neurons that drive phototransduction in the mammalian retina. These cells are organized and surrounded by an extracellular matrix, the interphotoreceptor matrix (IPM). Mutations in IPM proteoglycans are associated with blindness in humans. Our studies show that two specific proteoglycans of the IPM, IPM proteoglycan 1 (IMPG1) and IMPG2, form a dynamic structure with distinct localization and dependency. When IMPG2 is absent, IMPG1 cannot integrate into the IPM, leading to abnormal proteoglycan accumulation and visual deficits. This work adds a new layer of understanding to IPM physiology and describes the pathologic events following deficits in proteoglycans, providing novel possibilities for visual restoration in patients with IMPG-related pathologies.
光感受器神经元被一种称为光感受器间基质(IPM)的细胞外基质所包围。许多对视觉至关重要的活动都发生在 IPM 内,包括营养物质和代谢物的运输、视网膜附着以及正常外节吞噬作用所需的相互作用。IPM 包括以下两种独特的蛋白聚糖:IPM 蛋白聚糖 1(IMPG1)和 IMPG2。患有 IMPG1/IMPG2 突变的患者会出现视觉缺陷和视网膜下物质积累,这突出表明 IPM 在视觉中的关键作用。为了确定这些蛋白聚糖在视网膜生理学中的作用以及导致视力丧失的病理机制,我们生成了缺乏 IMPG1/IMPG2 的小鼠模型。在正常视网膜中,IMPG1 和 IMPG2 占据 IPM 的不同隔室,代表软骨素硫酸盐的主要来源,并且对于用 PNA(花生凝集素)标记物染色的锥体特异性糖萼的构成至关重要。在缺乏 IMPG1 的小鼠中未发现明显的形态或功能缺陷。在缺乏 IMPG2 的情况下,IMPG1 异常积聚在视网膜下间隙,可能导致视网膜下病变和视觉功能下降。有趣的是,无论性别如何,缺乏 IMPG1 和 IMPG2 的小鼠均表现出正常的视网膜结构和功能,这表明异常的 IMPG1 分布是观察到的缺乏 IMPG2 时视觉改变的主要原因。总之,我们的研究结果表明,分泌型蛋白聚糖(如 IMPG1)对细胞外环境的依赖性,以正确整合到基质中,证明了 IMPG2 在塑造 IPM 中的作用,并阐明了导致视网膜下病变和视力丧失的潜在机制。光感受器是哺乳动物视网膜中驱动光转导的特化神经元。这些细胞被细胞外基质(光感受器间基质,IPM)组织和包围。IPM 蛋白聚糖的突变与人类失明有关。我们的研究表明,IPM 的两种特定蛋白聚糖,IPM 蛋白聚糖 1(IMPG1)和 IMPG2,具有独特的定位和依赖性的动态结构。当 IMPG2 缺失时,IMPG1 无法整合到 IPM 中,导致异常蛋白聚糖积累和视觉缺陷。这项工作为 IPM 生理学增加了一个新的理解层次,并描述了蛋白聚糖缺陷后的病理事件,为 IMPG 相关病变患者的视觉恢复提供了新的可能性。
