In almost a century of scientific work on the mechanism of amyloid diseases much of the attention has been focused on the amyloid fibrils, which still represent the diagnostic hallmark of the disease and are easily identified in affected organs for their peculiar tinctorial properties and the fibrillar shape. However, it has been lately discovered that the seeds of the pathogenesis are deeply hidden in the structure and folding dynamics of proteins at the monomeric state which almost indistinguishable from the normal counterpart through classical biochemical approaches. In the recent years soluble oligomeric/prefibrillar species, putatively cytotoxic, were discovered and even more recently polymorphisms of shape and structure of fibrils was emerging as a property that could dictate the bioactivity of amyloid as well as the specificity of its tissue localization. Nanotechnology through the biophysical analysis of the single molecules (monomers or oligomers or fibrils) is the propulsive disciplines in the transformation of our knowledge on the molecular mechanism of this disease. It will provide, in the forthcoming years, precious analytical devices mimicking the biological microenvironment where the molecular events causing the amyloid formation will be monitored and possibly modulated in a real time frame.

Nanotechnology drives a paradigm shift on protein misfolding diseases and amyloidosis

BELLOTTI, VITTORIO;STOPPINI, MONICA
2012-01-01

Abstract

In almost a century of scientific work on the mechanism of amyloid diseases much of the attention has been focused on the amyloid fibrils, which still represent the diagnostic hallmark of the disease and are easily identified in affected organs for their peculiar tinctorial properties and the fibrillar shape. However, it has been lately discovered that the seeds of the pathogenesis are deeply hidden in the structure and folding dynamics of proteins at the monomeric state which almost indistinguishable from the normal counterpart through classical biochemical approaches. In the recent years soluble oligomeric/prefibrillar species, putatively cytotoxic, were discovered and even more recently polymorphisms of shape and structure of fibrils was emerging as a property that could dictate the bioactivity of amyloid as well as the specificity of its tissue localization. Nanotechnology through the biophysical analysis of the single molecules (monomers or oligomers or fibrils) is the propulsive disciplines in the transformation of our knowledge on the molecular mechanism of this disease. It will provide, in the forthcoming years, precious analytical devices mimicking the biological microenvironment where the molecular events causing the amyloid formation will be monitored and possibly modulated in a real time frame.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11571/573899
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