Intracellular tracing of amyloid vaccines through direct fluorescent labelling.
Matthew J MoldManpreet KumarAmbreen MirzaEmma ShardlowChristopher ExleyPublished in: Scientific reports (2018)
Alzheimer's disease is a debilitating neurodegenerative condition that progressively causes synaptic loss and major neuronal damage. Immunotherapy utilising Aβ as an active immunogen or via passive treatment utilising antibodies raised to amyloid have shown therapeutic promise. The migratory properties of peripheral blood-borne monocytes and their ability to enter the central nervous system, suggests a beneficial role in mediating tissue damage and neuroinflammation. However, the intrinsic phagocytic properties of such cells have pre-disposed them to internalise misfolded amyloidogenic peptides that could act as seeds capable of nucleating amyloid formation in the brain. Mechanisms governing the cellular fate of amyloid therefore, may prove to be key in the development of future vaccination regimes. Herein, we have developed unequivocal and direct conformation-sensitive fluorescent molecular probes that reveal the intracytoplasmic and intranuclear persistence of amyloid in a monocytic T helper 1 (THP-1) cell line. Use of the pathogenic Aβ42 species as a model antigen in simulated vaccine formulations suggested differing mechanisms of cellular internalisation, in which fibrillar amyloid evaded lysosomal capture, even when co-deposited on particulate adjuvant materials. Taken collectively, direct fluorescent labelling of antigen-adjuvant complexes may serve as critical tools in understanding subsequent immunopotentiation in vaccines directed against amyloidosis and wider dementia.
Keyphrases
- peripheral blood
- living cells
- quantum dots
- oxidative stress
- early stage
- induced apoptosis
- cerebral ischemia
- traumatic brain injury
- cognitive impairment
- genome wide
- dna methylation
- gene expression
- regulatory t cells
- functional connectivity
- big data
- cell proliferation
- reactive oxygen species
- white matter
- immune response
- multiple sclerosis
- fluorescent probe
- resting state
- deep learning
- current status
- molecular dynamics simulations