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Ionic properties of amino acids impart ionic properties to proteins

Ionic properties of amino acids impart ionic properties to proteins. in general these are SURFACE properties (i.e. charged sidechains are on solvent-exposed outside of folded structure) affect protein-ligand binding (e.g. DNA-binding proteins) or catalysis

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Ionic properties of amino acids impart ionic properties to proteins

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  1. Ionic properties of amino acids impart ionic properties to proteins • in general these are SURFACE properties (i.e. charged sidechains are on solvent-exposed outside of folded structure) • affect protein-ligand binding (e.g. DNA-binding proteins) or catalysis • average charge on protein is an important consideration in the design of a purification process

  2. pKa3 pKa2 pKa1

  3. pI= isoelectric point--the pH at which the net charge is 0. For amino acids with no ionizable functional group, pI = (pK1 + pK2)/2 For amino acids with an ionizable functional group, the average of the 2 pKs surrounding the isoelectric form of the amino acid determines the pI.

  4. pKa3 The isoelectric form of asp occurs between pK1 and pK2. pKa2 pI = 2.0 + 3.9 2 = 2.95 pKa1

  5. Other Properties of Amino Acids • Stereochemistry (all biosynthetic proteins made up of L-isomer) • Hydropathy (partitioning between polar and nonpolar solvents as indicator of polarity) (see Table 6-2 in VVP p 150; Take Note p58) these two properties are major determinants of peptide conformation

  6. See VVP Fig 4-3

  7. VVP Fig 6-3 p 126

  8. Example of a protein sequence MANSKINKQL DKLPENLRLN GRTPSGKLRS FVCEVCTRAF ARQEHLKRHY RSHTNEKPYP CGLCNRCFTR RDLLIRHAQK IDSGNLGETI SHTKKVSRTI TKARKNSASS VKFQTPTYGT PDNGGSGGTV LSEGEWQLVL HVWAKVEADV AGHGQDILIR LFKSHPETLE KFDRFKHLKT EAEMKASEDL KKHGVTVLTA LGAILKKKGH HEAELKPLAQ SHATKHKIPI KYLEFISEAI IHVLHSRHPG DFGADAQGAM NKALELFRKD IAAKYKELGY G N-terminus C-terminus

  9. VVP page 150 “nonpolar” “polar”

  10. VVP Fig 6-1 p 125

  11. VVP Fig 5-1 p 94 C-termini N-termini

  12. (Rasmol)

  13. VVP Fig. 5-1 Bovine Insulin

  14. VVP Fig. 5-3 ELISA

  15. VVP Fig. 5-4 Salting Out

  16. VVP Fig. 5-5 Ion Exchange Chromatography

  17. VVP Fig. 5-6 Gel Filtration (SEC)

  18. VVP Fig. 5-7 Affinity Chromatography

  19. VVP Fug, 5-8 Purification of Stapylococcal Nuclease

  20. Stryer Fig. 4.7 PAGE

  21. Animation http://www.whfreeman.com/lodish/con_index.htm?03 choose animations and then SDS gel electrophoresis

  22. Stryer Fig. 4.9 Coomassie blue stained SDS gel.

  23. VVP Fig. 5-9 PAGE

  24. Stryer Fig. 4.8

  25. VVP Fig. 5-10 SDS-PAGE of Salmonella proteins

  26. VVP Fig. 5-10 MW vs. Mobility in SDS-PAGE

  27. Stryer Fig. 4.36 Western blot.

  28. VVP Fig. 5-11 Density Gradient Ultracentrifugation

  29. Stryer Fig. 4.14

  30. Stryer Fig. 4.6 MALDI-TOF Matrix-assisted laser desroption-ionization- Time of Flight

  31. Stryer Fig. 4.17

  32. Determining Primary Structure 1. Determine aa composition

  33. Stryer Fig. 4.18 Ion-exchange chromatography

  34. Stryer p. 92 Agents for N-terminal analysis

  35. Stryer Fig. 4.20

  36. Stryer Fig. 4.21

  37. Animation: Edman Degradation http://www.wiley.com/college/fob/quiz/quiz05/f5-15.html

  38. Stryer Fig. 4.22 Separation of PTH-aa by HPLC.

  39. 2. Partially digest intact protein with specific agents.

  40. Stryer Fig. 4.23

  41. Stryer Fig. 4.24

  42. 3. Sequence the fragments and align overlapping sequences.

  43. Stryer Fig. 4.25

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