Chapter 8 Proteomics

1. Chapter 8 Proteomics 暨南大學資訊工程學系 黃光璿 2004/06/07

2. proteome • the sum total of an organism’s proteins • genome • the sum total of an organism’s genetic material

3. 8.1 From Genomes to Proteomes We want to know • what proteins are present in cells; • what those proteins do and how they function. However, it’s not easy.

4. Why? • The longevity (壽命) of an mRNA and the protein it codes for are very different. • Many proteins are extensively modified after translation. • Many proteins are not functionally relevant until they are assembled into larger complexes or delivered to an appropriate location.

5. Proteins require more careful handling than DNA. • Function may change. • Protein identification requires • mass spectrometric analysis • specific antibodies. • Obtaining large numbers of protein molecules requires chemical isolation for living cells.

6. 8.2 Protein Classification Based on • protein function • six categories • evolutionary history & structural similarity • 1000 homologous families

7. 8.2.1 Enzyme Nomenclature • Started at 1950s International Union of Biochemistry and Molecular Biology

8. 8.2.2 Family and Superfamily • Modern-day proteins may be derived from ~ 1000 original proteins. • folds  superfamilies  families • databases • SCOP, CATH, DALI

9. fold • the same major secondary structure & topological connections • superfamily • probable evolutionary relationships • family • clear evolutionary relationships

12. 8.3 Experimental Techniques • 2D Electrophoresis • Mass Spectrometry

13. 2D Electrophoresis liver kidney http://tw.expasy.org/cgi-bin/map1

16. Problems • tens of thousand v.s. thousands • under presentation of membrane-bound proteins • difficult to determine exactly which protein is represented

17. 8.3.2 Mass Spectrometry 2D  mass spectrometry, for identification

18. 8.3.3 Protein Microarrays • Use antibodies as probes. Problems • Single proteins will interact with multiple probes. • The binding kinetics of each probe are different. • Proteins are sensitive to their environment.

19. 8.4 Inhibitors and Drug Design • development & testing of a new drug • ~ 15 years, US$ 700 million • discovery • target identification • lead discovery & optimization • toxicology (毒理學) • pharmacokinetics • testing

20. HIV protease • has an active site; • cuts a single, large polypeptide chain into many proteins.

21. 8.5 Ligand Screening

22. 8.5.1 Ligand Docking Determine how two molecules of known structure will interact. Three issues: • Identify the energy of a particular molecular conformations. • Search for the conformation that minimizes the free energy.

23. How to deal with flexibility in both the protein and the putative ligand. • Lock and key approaches • rigid protein structure, flexible ligand structure • induced fit docking • flexible in both protein and ligand

24. Softwares • AutoDock • FTDock • DOCK • Hammerhead • Gold • FlexX

25. 8.5.2 Database Screening • Primary consideration • complete and accurate search • with a reasonable computational complexity • SLIDE • Fig. 8.4

27. 8.6 X-Ray Crystal Structures • W. C. Roentgen (1895) discovered X-rays. • M. von Laue (1912) discovered crystals diffract X-rays. • D. Hodgkin, etc. (1950s), crystallized complex organic molecules and determined their structures.

28. grow a crystal of the protein

31. File formats • PDB formatted text • mmCIF (MacroMolecular Crystallographic Information File)

32. databases & resources • PDB • PIR • ExPASy

33. Visualizing Tools • Fig. 8.8 • RasMol • Swiss PDB viewer • VMD (Visual Molecular Dynamics) • Spock • Protein explorer • DINO

34. 8.7 NMR Structures • ~ 200 amino acids • the structures determined are not unique

35. 8.8 Empirical Methods and Prediction Techniques • Example: • Fig. 8.9 • extracting features • learning, training • testing

37. 8.9 Post-Translational Modification Prediction • Remove segments of a protein. • Covalently attach sugars, phosphates, or sulfate groups into surface residues. • Cross-link residues within a protein (disulfide bond).

38. 8.9.1 Protein Sorting

39. associated with membranes • not associated with membranes Table 8.3 (Case 2)

40. PSORT: nearest neighbor classifier • Prediction of protein subcellular localization • SignalP: artificial neural networks • Prediction of signal peptide cleavage sites

41. 8.9.2 Proteolytic Cleavage • chymotrypsin • cleaves polypeptides on the C-terminal side of bulky and aromatic residues • trypsin • cleaves on the carboxyl side • elastase • cleaves on the C-terminal side of small residues

42. Prediction • proteasomes, > 98%, by neural network

43. 8.9.3 Glycosylation • The process of covalently linking an oligosaccharide to the side chain of a protein surface residue (科學人) • N-linked, 75% • O-linked, 85% by neural network

44. 8.9.4 Phosphorylation • kinases : add • phosphatases : remove • signal • NetPhos, > 70%, neural network

45. 參考資料及圖片出處 • Fundamental Concepts of BioinformaticsDan E. Krane and Michael L. Raymer, Benjamin/Cummings, 2003. • Merrian-Webster Dictionary