Alzheimer’s Disease Protein Linked to Common Sight Loss | Nutrition Fit

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Summary: Exposing retinal pigment epithelium cells in mouse models to amyloid-beta resulted in retinal pathologies similar to those seen in human age-related macular degeneration.

Source: University of Southampton

Newly published research has revealed a close link between proteins associated with Alzheimer’s disease and age-related sight loss.

The findings could open the way to new treatments for patients with deteriorating vision and through this study, the scientists believe they could reduce the need for using animals in future research into blinding conditions.

Amyloid beta (AB) proteins are the primary driver of Alzheimer’s disease but also begin to collect in the retina as people get older. Donor eyes from patients who suffered from age-related macular degeneration (AMD), the most common cause of blindness amongst adults in the UK, have been shown to contain high levels of AB in their retinas.

This new study, published in the journal Cells, builds on previous research which shows that AB collects around a cell layer called the retinal pigment epithelium (RPE), to establish what damage these toxic proteins cause RPE cells.

The research team exposed RPE cells of normal mouse eyes and in culture to AB. The mouse model enabled the team to look at the effect the protein has in living eye tissue, using non-invasive imaging techniques that are used in ophthalmology clinics. Their findings showed that the mouse eyes developed retinal pathology that was strikingly similar to AMD in humans.

Dr Arjuna Ratnayaka, a Lecturer in Vision Sciences at the University of Southampton, who led the study said, “This was an important study which also showed that mouse numbers used for experiments of this kind can be significantly reduced in the future. We were able to develop a robust model to study AMD-like retinal pathology driven by AB without using transgenic animals, which are often used by researchers the field. Transgenic or genetically engineered mice can take up to a year and typically longer, before AB causes pathology in the retina, which we can achieve within two weeks. This reduces the need to develop more transgenic models and improves animal welfare.”

The investigators also used the cell models, which further reduced the use of mice in these experiments, to show that the toxic AB proteins entered RPE cells and rapidly collected in lysosomes, the waste disposal system for the cells.

Whilst the cells performed their usual function of increasing enzymes within lysosomes to breakdown this unwanted cargo, the study found that around 85% of AB still remained within lysosomes, meaning that over time the toxic molecules would continue to accumulate inside RPE cells.

Furthermore, the researchers discovered that once lysosomes had been invaded by AB, around 20 percent fewer lysosomes were available to breakdown photoreceptor outer segments, a role they routinely perform as part of the daily visual cycle.

This shows a pair of glasses
Amyloid beta (AB) proteins are the primary driver of Alzheimer’s disease but also begin to collect in the retina as people get older. Image is in the public domain

Dr Ratnayaka added, “This is a further indication of how cells in the eye can deteriorate over time because of these toxic molecules collecting inside RPE cells. This could be a new pathway that no-one has explored before. Our discoveries have also strengthened the link between diseases of the eye and the brain. The eye is part of the brain and we have shown how AB which is known to drive major neurological conditions such as Alzheimer’s disease can also causes significant damage to cells in retina.”

The researchers hope that one of the next steps could be for anti-amyloid beta drugs, previously trialled in Alzheimer’s patients, to be re-purposed and trialled as a possible treatment for age-related macular degeneration. As the regulators in the USA and the European Union have already given approval for many of these drugs, this is an area that could be explored relatively quickly.

The study may also help wider efforts to largely by-pass the use of animal experimentation where possible, so some aspects of testing new clinical treatments can transition directly from cell models to patients.

This research was funded by the National Centre for the Replacement Refinement & Reduction of animals in research (NC3Rs). Dr Katie Bates, Head of Research Funding at the NC3Rs said:

“This is an impactful study that demonstrates the scientific, practical and 3Rs benefits to studying AMD-like retinal pathology in vitro.”

Note: Animal studies were overseen by the institutions’ Ethical Research Committee and carried out in accordance with the UK Animal (Scientific Procedures) Act of 1986. Experiments also conformed to the ARVO statement for the Use of Animals in Ophthalmic and Vision Research. The experimental protocol was approved by the University of Southampton Research Ethics Committee and work carried out under the UK Home Office project licence #P395C9E5F (licence approval date: 4 July 2016).

About this visual neuroscience research news

Source: University of Southampton
Contact: Steve Bates – University of Southampton
Image: The image is in the public domain

Original Research: Open access.
“Oligomeric Aβ1-42 Induces an AMD-Like Phenotype and Accumulates in Lysosomes to Impair RPE Function” by Arjuna Ratnayaka et al. Cells


Abstract

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This shows a brain made up of SARM1

Oligomeric Aβ1-42 Induces an AMD-Like Phenotype and Accumulates in Lysosomes to Impair RPE Function

Alzheimer’s disease-associated amyloid beta (Aβ) proteins accumulate in the outer retina with increasing age and in eyes of age-related macular degeneration (AMD) patients.

To study Aβ-induced retinopathy, wild-type mice were injected with nanomolar human oligomeric Aβ1-42, which recapitulate the Aβ burden reported in human donor eyes. In vitro studies investigated the cellular effects of Aβ in endothelial and retinal pigment epithelial (RPE) cells.

Results show subretinal Aβ-induced focal AMD-like pathology within 2 weeks. Aβ exposure caused endothelial cell migration, and morphological and barrier alterations to the RPE. Aβ co-localized to late-endocytic compartments of RPE cells, which persisted despite attempts to clear it through upregulation of lysosomal cathepsin B, revealing a novel mechanism of lysosomal impairment in retinal degeneration.

The rapid upregulation of cathepsin B was out of step with the prolonged accumulation of Aβ within lysosomes, and contrasted with enzymatic responses to internalized photoreceptor outer segments (POS). Furthermore, RPE cells exposed to Aβ were identified as deficient in cargo-carrying lysosomes at time points that are critical to POS degradation.

These findings imply that Aβ accumulation within late-endocytic compartments, as well as lysosomal deficiency, impairs RPE function over time, contributing to visual defects seen in aging and AMD eyes.

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