1. Dek Woolfson, Biological Sciences, Sussex Biomolecular Machines Dek Woolfson University of Sussex

2. Dek Woolfson, Biological Sciences, Sussex

4. Transcription: getting from DNA to RNA

5. Dek Woolfson, Biological Sciences, Sussex Switching Genes On: Transcription Factors ≈2,300 atoms

6. Dek Woolfson, Biological Sciences, Sussex Mad Max

7. Dek Woolfson, Biological Sciences, Sussex Translation: getting from RNA to protein

8. Dek Woolfson, Biological Sciences, Sussex Making Proteins: Translation on the Ribosome

9. Dek Woolfson, Biological Sciences, Sussex Protein Folding: getting proteins into shape

10. Dek Woolfson, Biological Sciences, Sussex Folding Proteins: The GroE Chaperone

11. Dek Woolfson, Biological Sciences, Sussex doing everything...

12. Dek Woolfson, Biological Sciences, Sussex Sticky Molecules: EPO ≈3,500 atoms

13. Dek Woolfson, Biological Sciences, Sussex Dynamic Molecules: Haemoglobin ≈4,400 atoms

14. Dek Woolfson, Biological Sciences, Sussex Protein Misfolding: proteins behaving badly

15. Dek Woolfson, Biological Sciences, Sussex Prions & Amyloid

16. Dek Woolfson, Biological Sciences, Sussex Garbage Disposal: getting rid of unwanted proteins

17. Dek Woolfson, Biological Sciences, Sussex Recycling Proteins: The Proteasome ≈56,400 atoms

18. Dek Woolfson, Biological Sciences, Sussex

19. The Proteasome as a molecular ruler

20. Dek Woolfson, Biological Sciences, Sussex The Grim Reaper: ubiquitin

21. Dek Woolfson, Biological Sciences, Sussex ≈600 atoms

22. Dek Woolfson, Biological Sciences, Sussex

25. Finding the Energy: How ATP is made.

26. Dek Woolfson, Biological Sciences, Sussex The F1F0 Complex

27. Dek Woolfson, Biological Sciences, Sussex The F1 ATPase ≈23,000 atoms

28. Dek Woolfson, Biological Sciences, Sussex The  -subunit acts as a crankshaft

29. Dek Woolfson, Biological Sciences, Sussex Rotary Catalysis

30. Dek Woolfson, Biological Sciences, Sussex The F0 component is in the membrane and acts as a molecular turbine

31. Dek Woolfson, Biological Sciences, Sussex There’s plenty to do: human karyotype

32. Dek Woolfson, Biological Sciences, Sussex