The structural basis of protein folding and its links with human disease

The structural basis of protein folding and its links with human disease

The ability of proteins to fold to their functional states following synthesis in the intracellular environment is one of the most remarkable features of biology. Substantial progress has recently been made towards understanding the fundamental nature of the mechanism of the folding process. This un...

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Published in:Philosophical transactions of the Royal Society of London. Series B. Biological sciences Vol. 356; no. 1406; pp. 133 - 145
Main Authors: Dobson, C. M., Ellis, R. J., Fersht, A. R., Dobson, Christopher M.
Format: Journal Article
Language:English
Published: England The Royal Society 28-02-2001
Subjects:
Ageing
Aggregation
Aging - physiology
Alzheimer Disease - physiopathology
Alzheimers disease
Amyloid - chemistry
Amyloid Fibrils
Amyloidosis - physiopathology
Amyloids
Energy Landscapes
Folding Diseases
Folding Mechanisms
Humans
Huntington disease
Molecules
Nervous system diseases
Parkinson Disease - physiopathology
Prion diseases
Protein Folding
Proteins - chemistry
Proteins - genetics
Proteostasis deficiencies
Solar fibrils
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Summary:The ability of proteins to fold to their functional states following synthesis in the intracellular environment is one of the most remarkable features of biology. Substantial progress has recently been made towards understanding the fundamental nature of the mechanism of the folding process. This understanding has been achieved through the development and concerted application of a variety of novel experimental and theoretical approaches to this complex problem. The emerging view of folding is that it is a stochastic process, but one biased by the fact that native-like interactions between residues are on average more stable than non-native ones. The sequences of natural proteins have emerged through evolutionary processes such that their unique native states can be found very efficiently even in the complex environment inside a living cell. But under some conditions proteins fail to fold correctly, or to remain correctly folded, in living systems, and this failure can result in a wide range of diseases. One group of diseases, known as amyloidoses, which includes Alzheimer's and the transmissible spongiform encephalopathies, involves deposition of aggregated proteins in a variety of tissues. These diseases are particularly intriguing because evidence is accumulating that the formation of the highly organized amyloid aggregates is a generic property of polypeptides, and not simply a feature of the few proteins associated with recognized pathological conditions. That such aggregates are not normally found in properly functional biological systems is again a testament to evolution, in this case of a variety of mechanisms inhibiting their formation. Understanding the nature of such protective mechanisms is a crucial step in the development of strategies to prevent and treat these debilitating diseases.
Bibliography:ark:/67375/V84-S3Z9SKZW-J
istex:38F2C6C6D2339BD0034918392CB3CFB982AF91DC
Discussion Meeting Issue 'Protein misfolding and disease' organized by C. M. Dobson, R. J. Ellis and A. R. Fersht
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SourceType-Scholarly Journals-1
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ISSN:0962-8436
1471-2970
DOI:10.1098/rstb.2000.0758