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Prion biology problem space: Mad cows, itchy sheep and protein structure.

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Presentation on theme: "Prion biology problem space: Mad cows, itchy sheep and protein structure."— Presentation transcript:

1 Prion biology problem space: Mad cows, itchy sheep and protein structure

2 Touring the problem space I. History and introduction to prion biology II. Idea of conformational change III. Exploring sequences of prion proteins IV. Exploring physical properties and structures of prion proteins V. Linking evolution, structure and function of prion proteins

3 Touring the problem space I. History and introduction to prion biology II. Idea of conformational change III. Exploring sequences of prion proteins IV. Exploring physical properties and structures of prion proteins V. Linking evolution, structure and function of prion proteins

4 Prion History 17 th ct. “Sheep are strangely dizzy” – scrapie described in Europe 17 th ct. “Sheep are strangely dizzy” – scrapie described in Europe 1950’s: Carleton Gajdusek studied cannibalistic ceremonies of Fore tribe in New Guinea and discovered the Kuru disease 1950’s: Carleton Gajdusek studied cannibalistic ceremonies of Fore tribe in New Guinea and discovered the Kuru disease Kuru attacks dura matter of brain and creates vacuoles, causing infected person to deteriorate and die within 3 months Kuru attacks dura matter of brain and creates vacuoles, causing infected person to deteriorate and die within 3 months

5 Prion History 1960: Alper - DNA destroying UV radiation doesn’t prevent scrapie infections. 1966: Gajdusek - Chimps get Kuru from ingesting infected brain tissue. 1967: Griffith - Speculated that TSE’s due to protein conformational changes. 1981: Mertz - Fibrils detected in scrapie infected mouse brains. (CONTINUED…) http://www.css.edu/USERS/pstein/CHM3430/11 1700s: Scrapie behavior described

6 1997: Stanley Prusiner proposed a link between kuru, CJD, scrapie and BSE. 1997: Stanley Prusiner proposed a link between kuru, CJD, scrapie and BSE. -Proposed that “prion” was responsible for spongiform manifestations in BSE-infected patients DEFINITION: PRION = Proteinaceous Infectious Particles Prion protein exists in two forms: Prion protein exists in two forms: PrPc vs. PrPsc PrPc vs. PrPsc http://www.mentorcorp.com/gynecology/prion_history.htm http://www.css.edu/USERS/pstein/CHM3430/Prions.ppt

7 Protein folding as we know it http://images.google.com/imgres?imgurl=press2.nci.nih.gov/sciencebehind/snps_cancer/snps_cancer/images/21.jpg&imgrefurl=http://press2.nci.nih.gov/sciencebehind/snps_cancer/snps_cancer/snps_cancer21.htm&h=461&w=402&sz=22&tbnid=32gDooND7ssJ:&tbnh=124&tbnw=109&start=1&prev=/images%3Fq%3Dprotein%2Bfolding%26hl%3De n%26lr%3D%26ie%3DUTF-8%26sa%3DG

8 Touring the problem space I. History and introduction to prion biology II. Idea of conformational change III. Exploring sequences of prion proteins IV. Exploring physical properties and structures of prion proteins V. Linking evolution, structure and function of prion proteins

9 Prion protein folding PrPc PrPsc k folding-c k folding-sc k unfolding-sc k unfolding-c Intermediates?

10 Prion folding model as link between chemistry and biology What do folding rates and equilibrium constants mean? If a protein has stability of 7 kcal mol -1, how many molecules are unfolded at 37 o C? Would you expect PrP to be more or less stable than other proteins? Folded Unfolded Keq

11 One protein: Two structures http://www.uccs.edu/~rmelamed/MicroFall2002/Chapter%2010/Prion%20Structure.html http://www.uccs.edu/~rmelamed/MicroFall2002/Chapter%2010/Prion%20Structure.html http://www.uccs.edu/~rmelamed/MicroFall2002/Chapter%2010/Prion%20Structure.html PrPc “NORMAL” conformation PrPsc “BAD” conformation

12 Not all pretty pictures can be trusted! Based on NMR results Proposed based on low- resolution structural studies

13 PrPc PrPsc PrPc

14 PrP C PrP SC PrP C

15 PrP sc fibrils

16 Plaque

17 Disease transmission modes Infections (Kuru, scrapie, bovine spongiform encephalophathies, etc) Infections (Kuru, scrapie, bovine spongiform encephalophathies, etc) Inherited (Creutzfeld-Jacob disease, Gerstmann-Straussler-Scheinker disease, Fatal familial insomnia) Inherited (Creutzfeld-Jacob disease, Gerstmann-Straussler-Scheinker disease, Fatal familial insomnia) Sporadic (BSE, CJD ?) Sporadic (BSE, CJD ?) Link to The Case of the Cherry Hill Cluster Link to The Case of the Cherry Hill Cluster By D.T. MAX NY Times magazinePublished: March 28, 2004 By D.T. MAX NY Times magazinePublished: March 28, 2004

18 Prion diseases and Koch’s postulates I. The agent must be present in every case of the disease II. The agent must be isolated from the host and grown in a lab dish III. The disease must be reproduced when a pure culture of the agent is inoculated into a healthy susceptible host IV. The same agent must be recovered again from the experimentally infected host. Can this be applied to understanding prion diseases?

19 Touring the problem space I. History and introduction to prion biology II. Idea of conformational change III. Exploring sequences of prion proteins IV. Exploring physical properties and structures of prion proteins V. Linking evolution, structure and function of prion proteins

20 Global view of the amino acid sequence of PrP

21 Multiple ways to visualize and analyze protein sequence Use GeneDoc from Pittsburgh Supercomputing Center to analyze multiple prion sequences Use GeneDoc from Pittsburgh Supercomputing Center to analyze multiple prion sequences By using different coloring schemes, can visualize and quantify conservation of different properties By using different coloring schemes, can visualize and quantify conservation of different properties

22 Comparison of human, cow, sheep and mouse prion protein sequence

23 Conservarion of polar vs. non-polar pattern PROPERTIES Level 1 DEHKRNQTPOLAR LIVMFYWAGCPNON-POLAR Level 2 DEHKR NQST LIVMFYW AG

24 Analyzing charge distribution Level 2 DEHKRCHARGED NQSTPOLAR UNCHARGED LIVMFYWHYDROPHOBIC AGSMALL hydrophobic

25 Expanded amino acid properties

26 Examples of questions that can be examined through sequence analyses Determining evolutionary relationships among the various organisms examined. Determining evolutionary relationships among the various organisms examined. Investigating how amino acid sequence may be linked to the overall structure of the protein Investigating how amino acid sequence may be linked to the overall structure of the protein Examining the role of repetitive elements in prion homologies. Examining the role of repetitive elements in prion homologies.

27 Touring the problem space I. History and introduction to prion biology II. Idea of conformational change III. Exploring sequences of prion proteins IV. Exploring physical properties and structures of prion proteins V. Linking evolution, structure and function of prion proteins

28 Exploring physical characteristics How big is the prion protein? How does that compare to other proteins? Where is it localized in the cell? Is its size or shape unusual? Is the distribution of amino acids unusual?

29 PROTPARAM: a tool for analysis of physical properties http://ca.expasy.org/cgi-bin/protparam http://ca.expasy.org/cgi-bin/protparam http://ca.expasy.org/cgi-bin/protparam Number of amino acids: 253 Molecular weight: 27629.1 Theoretical pI: 9.23 Amino acid composition: Ala (A) 10 4.0% Arg (R) 11 4.3% Asn (N) 12 4.7% Asp (D) 6 2.4% Cys (C) 4 1.6% Gln (Q) 14 5.5% Glu (E) 9 3.6% Gly (G) 45 17.8% His (H) 10 4.0% Ile (I) 9 3.6% Leu (L) 12 4.7% Lys (K) 11 4.3% Met (M) 11 4.3% Phe (F) 7 2.8% Pro (P) 17 6.7% Ser (S) 15 5.9% Thr (T) 13 5.1% Trp (W) 9 3.6% Tyr (Y) 13 5.1% Val (V) 15 5.9%

30

31 Visualizing protein structure with Cn3D

32 Secondary structural elements can be analyzed in isolation

33 Helices can be dissected by mapping onto helical wheel http://bioinf.man.ac.uk/%7Egibson/HelixDraw/helixdraw.html

34 Examples of questions that can be explored through structural analyses Some mutations have been associated with prion diseases. By mapping these onto structures, propose a hypothesis to explain this. Most of the variation seems to be in the N- terminal region. Is there homology to this region in other proteins?

35 Touring the problem space I. History and introduction to prion biology II. Idea of conformational change III. Exploring sequences of prion proteins IV. Exploring physical properties and structures of prion proteins V. Linking evolution, structure and function of prion proteins

36 What does PrP do? GPI- anchored cell surface protein Knockout mice mostly normal Might be involved in some signaling cascades Interaction with hypothetical “protein x” might be needed for structural conversion

37 What makes prion a prion? Why don’t other proteins adopt two drastically different stably folded conformations? Why don’t other proteins adopt two drastically different stably folded conformations? A helix is a helix…but why are helices in prion protein likely to undergo a big structural change? A helix is a helix…but why are helices in prion protein likely to undergo a big structural change? How would you test/further explore these questions?

38 “Big picture” questions as a platform for development of testable hypotheses Why would nature evolve prions? How would you tell a prion if you saw one? Yeast prions do not cause a disease. Are there other non-harmful prion-like proteins? Can prions be beneficial?


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