Sandbox Reserved 1232
From Proteopedia
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The image shown is the average structure produced by NMR constraints. | The image shown is the average structure produced by NMR constraints. | ||
| - | The protein can exist in multiple isoforms, the normal PrPC, and as Protease resistance PrPRes like the disease-causing PrPSc(scrapie) and an isoform located in mitochondria. | + | The protein can exist in multiple isoforms, the normal PrPC (cellular), and as Protease resistance PrPRes like the disease-causing PrPSc (scrapie) and an isoform located in mitochondria. |
PrP is highly conserved through mammals. Comparison between primates is especially similar, ranging from 92.9-99.6% similarity in amino acid sequences. | PrP is highly conserved through mammals. Comparison between primates is especially similar, ranging from 92.9-99.6% similarity in amino acid sequences. | ||
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Mammals contain cellular prion related proteins (PrPC) in their bodies and when functioning correctly are believed to assist in copper binding and signal transduction in neurons. Expression of the protein is most predominant in the nervous system but occurs in many other tissues throughout the body. | Mammals contain cellular prion related proteins (PrPC) in their bodies and when functioning correctly are believed to assist in copper binding and signal transduction in neurons. Expression of the protein is most predominant in the nervous system but occurs in many other tissues throughout the body. | ||
== Disease == | == Disease == | ||
| - | In PrPC's mutated state, the prion protein contributes to the development of amyloid disease (misfolded proteins that stick together forming fibrils). Mutated Prion proteins are associated with a variety of neurodegenerative diseases such as | + | In PrPC's mutated state, the prion protein contributes to the development of amyloid disease (misfolded proteins that stick together forming fibrils). Instead of other infectious agents such as viruses, bacteria, parasites, or fungi, PrP does not contain any genetic material such as DNA or RNA. Prion diseases can originate spontaneously, genetically or by infection and are comprised entirely of misfolded proteins. When a misfolded prion (PrPSc) enters a host it induces existing, properly folded PrPC’s to fold into the infectious form. |
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| + | Mutated Prion proteins are associated with a variety of neurodegenerative diseases such as | ||
The common prion disease in humans is known as Creutzfeldt-Jakob disease. | The common prion disease in humans is known as Creutzfeldt-Jakob disease. | ||
Revision as of 20:09, 24 April 2017
Contents |
Human Prion Protein
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Function
Mammals contain cellular prion related proteins (PrPC) in their bodies and when functioning correctly are believed to assist in copper binding and signal transduction in neurons. Expression of the protein is most predominant in the nervous system but occurs in many other tissues throughout the body.
Disease
In PrPC's mutated state, the prion protein contributes to the development of amyloid disease (misfolded proteins that stick together forming fibrils). Instead of other infectious agents such as viruses, bacteria, parasites, or fungi, PrP does not contain any genetic material such as DNA or RNA. Prion diseases can originate spontaneously, genetically or by infection and are comprised entirely of misfolded proteins. When a misfolded prion (PrPSc) enters a host it induces existing, properly folded PrPC’s to fold into the infectious form.
Mutated Prion proteins are associated with a variety of neurodegenerative diseases such as
The common prion disease in humans is known as Creutzfeldt-Jakob disease.
Relevance
Structural Highlights
This is a sample scene created with SAT to by Group, and another to make of the protein. You can make your own scenes on SAT starting from scratch or loading and editing one of these sample scenes.
References
An, Lu, David Fitzpatrick, and Paul M Harrison. "Emergence And Evolution Of Yeast Prion And Prion-Like Proteins." BMC Evolutionary Biology 16.(2016): 24.MEDLINE Complete. Web. 12 Feb. 2017.
Kovacs, Gabor G., and Herbert Budka. “Prion Diseases: From Protein to Cell Pathology.” The American Journal of Pathology 172.3 (2008): 555–565. PMC. Web. 13 Feb. 2017.
