Abstract
In contrast to the dynamic intracellular environment, structural extracellular matrix (ECM) proteins with half-lives measured in decades, are susceptible to accumulating damage. Whilst conventional approaches such as histology, immunohistochemistry and mass spectrometry are able to identify age- and disease-related changes in protein abundance or distribution, these techniques are poorly suited to characterising molecular damage. We have previously shown that mass spectrometry can detect tissue-specific differences in the proteolytic susceptibility of protein regions within fibrillin-1 and collagen VI alpha-3. Here, we present a novel proteomic approach to detect damage-induced “peptide fingerprints” within complex multi-component ECM assemblies (fibrillin and collagen VI microfibrils) following their exposure to ultraviolet radiation (UVR) by broadband UVB or solar simulated radiation (SSR). These assemblies were chosen because, in chronically photoaged skin, fibrillin and collagen VI microfibril architectures are differentially susceptible to UVR. In this study, atomic force microscopy revealed that fibrillin microfibril ultrastructure was significantly altered by UVR exposure whereas the ultrastructure of collagen VI microfibrils was resistant. UVR-induced molecular damage was further characterised by proteolytic peptide generation with elastase followed by liquid chromatography tandem mass spectrometry (LC-MS/MS). Peptide mapping revealed that UVR exposure increased regional proteolytic susceptibility within the protein structures of fibrillin-1 and collagen VI alpha-3. This allowed the identification of UVR-induced molecular changes within these two key ECM assemblies. Additionally, similar changes were observed within protein regions of co-purifying, microfibril-associated receptors integrins αv and β1. This study demonstrates that LC-MS/MS mapping of peptides enables the characterisation of molecular post-translational damage (via direct irradiation and radiation-induced oxidative mechanisms) within a complex in vitro model system. This peptide fingerprinting approach reliably allows both the identification of UVR-induced molecular damage in and between proteins and the identification of specific protein domains with increased proteolytic susceptibility as a result of photo-denaturation. This has the potential to serve as a sensitive method of identifying accumulated molecular damage in vivo using conventional mass spectrometry data-sets.
Highlights
In contrast to the rapid turnover which characterises intracellular proteomes [1], structural extracellular matrix (ECM) proteins are commonly longlived, some with half-lives measured in decades [2,3,4]
Using LC-MS/MS peptide fingerprinting, we successfully identified broadband UVB- and SSRdamage within the fibrillin-1 monomer and collagen VI alpha chain (COL6A3) chain of human fibrillin and collagen VI microfibrils
The quantity of damage to fibrillin-1 structure and to fibrillin microfibril ultrastructure correlates with the type of ultraviolet radiation (UVR) exposure, many of the foci of proteolytic susceptibility within the protein structure are conserved between UVR sources
Summary
In contrast to the rapid turnover which characterises intracellular proteomes [1], structural extracellular matrix (ECM) proteins are commonly longlived, some with half-lives measured in decades [2,3,4]. As a consequence, these proteins may accumulate damage due to ageing and chronic disease [5,6,7,8] which can manifest as changes in their abundance and architecture [9,10,11]. The presence of cumulative molecular damage within elastic fibre components, which may impair structural and biochemical functionality [29,30], has yet to be demonstrated
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