Your search keyword '"Reynolds, NP"' showing total 3 results

1. Cell invasive amyloid assemblies from SARS-CoV-2 peptides can form multiple polymorphs with varying neurotoxicity.

Author

Sanislav O, Tetaj R, Metali, Ratcliffe J, Phillips W, Klein AR, Sethi A, Zhou J, Mezzenga R, Saxer SS, Charnley M, Annesley SJ, and Reynolds NP

Subjects

Humans, Peptides chemistry, Animals, Viral Proteins chemistry, Viral Proteins metabolism, Peptide Fragments chemistry, Peptide Fragments metabolism, SARS-CoV-2 metabolism, SARS-CoV-2 chemistry, Amyloid chemistry, Amyloid metabolism, Neurons metabolism, Neurons pathology, COVID-19

Abstract

The neurological symptoms of COVID-19, often referred to as neuro-COVID include neurological pain, memory loss, cognitive and sensory disruption. These neurological symptoms can persist for months and are known as Post-Acute Sequalae of COVID-19 (PASC). The molecular origins of neuro-COVID, and how it contributes to PASC are unknown, however a growing body of research highlights that the self-assembly of protein fragments from SARS-CoV-2 into amyloid nanofibrils may play a causative role. Previously, we identified two fragments from the SARS-CoV-2 proteins, Open Reading Frame (ORF) 6 and ORF10, that self-assemble into neurotoxic amyloid assemblies. Here we further our understanding of the self-assembly mechanisms and nano-architectures formed by these fragments and their biological responses. By solubilising the peptides in a fluorinated solvent, we eliminate insoluble aggregates in the starting materials (seeds) that change the polymorphic landscape of the assemblies. The resultant assemblies are dominated by structures with higher free energies ( e.g. ribbons and amorphous aggregates) that are less toxic to cultured neurons but do affect their mitochondrial respiration. We also show the first direct evidence of cellular uptake of viral amyloids. This work highlights the importance of understanding the polymorphic behaviour of amyloids and the correlation to neurotoxicity, particularly in the context of neuro-COVID and PASC.

Published

2024

2. SARS-CoV-2 infection as a cause of neurodegeneration.

Author

Bonhenry D, Charnley M, Gonçalves J, Hammarström P, Heneka MT, Itzhaki R, Lambert JC, Mannan M, Baig AM, Middeldorp J, Nyström S, Reynolds NP, Stefanatou M, and Berryman JT

Subjects

Humans, SARS-CoV-2 pathogenicity, COVID-19 complications, Neurodegenerative Diseases etiology

Published

2024

3. Composite Bioprinted Hydrogels Containing Porous Polymer Microparticles Provide Tailorable Mechanical Properties for 3D Cell Culture.

Author

Mclean B, Ratcliffe J, Parker BJ, Field EH, Hughes SJ, Cutter SW, Iseppi KJ, Cameron NR, Binger KJ, and Reynolds NP

Subjects

Porosity, Tissue Engineering methods, Hydrogels, Printing, Three-Dimensional, Biocompatible Materials, Polymers, Gelatin, Cellulose, Cell Culture Techniques, Three Dimensional, Tissue Scaffolds, Bioprinting methods

Abstract

The mechanical and architectural properties of the three-dimensional (3D) tissue microenvironment can have large impacts on cellular behavior and phenotype, providing cells with specialized functions dependent on their location. This is especially apparent in macrophage biology where the function of tissue resident macrophages is highly specialized to their location. 3D bioprinting provides a convenient method of fabricating biomaterials that mimic specific tissue architectures. If these printable materials also possess tunable mechanical properties, they would be highly attractive for the study of macrophage behavior in different tissues. Currently, it is difficult to achieve mechanical tunability without sacrificing printability, scaffold porosity, and a loss in cell viability. Here, we have designed composite printable biomaterials composed of traditional hydrogels [nanofibrillar cellulose (cellulose) or methacrylated gelatin (gelMA)] mixed with porous polymeric high internal phase emulsion (polyHIPE) microparticles. By varying the ratio of polyHIPEs to hydrogel, we fabricate composite hydrogels that mimic the mechanical properties of the neural tissue (0.1-0.5 kPa), liver (1 kPa), lungs (5 kPa), and skin (10 kPa) while maintaining good levels of biocompatibility to a macrophage cell line.

Published

2024