Abstract
Stromal corneal dystrophies are a group of hereditary disorders caused by mutations in the TGFBI gene. The mutant TGFBIp is prone to protein aggregation and the mutant protein gets deposited in the cornea, leading to severe visual impairment. The mutations lead to a corneal specific protein aggregation suggesting the involvement of tissue-specific factors. The exact molecular mechanism of the process of tissue-specific protein aggregation remains to be elucidated. Differential proteolysis of mutant TGFBIp is a critical component of the disease pathology. The differential proteolysis gives rise to shorter peptides that are highly aggregation-prone and initiate the aggregation cascade. Analyzing the proteolytic processing of the different TGFBIp mutant may provide insight to aid in understanding the amyloid aggregation mechanism. We developed a MALDI-MSI methodology to identify expression and spatial localization of TGFBIp peptides in the cornea. Corneal tissue samples were collected from both control and dystrophic patients (with 2 different mutations), embedded in OCT and sectioned. The sections were trypsin digested and subjected to mass spectrometry imaging using a targeted approach to detect TGFBIp. MALDI-MSI identified peptides from TGFBIp that co-localized with the amyloid corneal deposits. In addition to the relative abundance data, the specific location of the peptides across the corneal sections as molecular signatures was also identified. Spatial distribution and intensity of the TGFBIp peptides showed differences between diseased and control models but also between the two LCD phenotypes. The TGFBIp peptide with m/z of 787.474 and m/z of 1179.579 showed increased expression in both LCD mutants compared to the controls. The peptide with m/z of 929.5 showed increased expression in the LCD phenotype with H626R mutation while the peptide with m/z of 1315.802 was abundant in the sample with R124C mutation. This initial report of 2D spatial protein signature and localization of TGFBIp may be expanded to other mutations to understand the proteolytic patterns of TGFBIp in different mutations.
Highlights
The cornea is the clear avascular layer that forms the anterior part of the human eye [1]
We report the Matrix-assisted laser desorption/ionization (MALDI)-Mass Spectrometry Imaging (MSI) method development to identify TGFBIp in mouse and human corneal samples that are related to stromal Corneal dystrophies (CD) and their localization in healthy controls and diseased cornea
The images indicate that the cornea remained clear in both control human and wild type (WT) mice
Summary
The cornea is the clear avascular layer that forms the anterior part of the human eye [1]. The cornea is responsible for focusing light from objects onto the optical center of the human retina. The cornea functions to prevent oxidative damage of internal tissues caused by UV rays from the sun [2]. The adult human cornea is made up of five different layers namely: epithelium, Bowman’s membrane, stroma, Descemet’s membrane and the endothelium. Corneal transparency should be always maintained to have a normal clear vision. The stromal layer of the cornea is an extracellular matrix (ECM) rich in collagen and is the thickest layer of the cornea. The arrangement of collagen fibrils in the cornea plays an important role in maintaining the optical and biomechanical properties of the cornea [3]
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