html5-img
1 / 53

Peter Virnau, Mehran Kardar, Yacov Kantor

Capturing knots in (bio-) polymers …. Peter Virnau, Mehran Kardar, Yacov Kantor. History of knot science. Lord Kelvin (1867): “Vortex atoms”. P.G. Tait: Knot tables. Classification of knots. J.W. Alexander (1923): First algorithm which can distinguish between knots (… somewhat).

tegan
Télécharger la présentation

Peter Virnau, Mehran Kardar, Yacov Kantor

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Capturing knots in (bio-) polymers … Peter Virnau, Mehran Kardar, Yacov Kantor

  2. History of knot science Lord Kelvin (1867): “Vortex atoms” P.G. Tait: Knot tables

  3. Classification of knots J.W. Alexander (1923): First algorithm which can distinguish between knots (… somewhat) 2005: still no complete invariant

  4. Motivation: Polymers Knots are topological invariants (self-avoiding) ring polymers A sufficiently long polymer will have knots (Frisch & Wassermann (1961), Delbrück (1962)) Knots are not included in the standard theories Knots modify dynamics of polymers; e.g. relaxation or electrophoresis

  5. Motivation: Polymers Knots are topological invariants (self-avoiding) ring polymers A sufficiently long polymer will have knots (Frisch & Wassermann (1961), Delbrück (1962)) Knots are not included in the standard theories Knots modify dynamics of polymers; e.g. relaxation or electrophoresis

  6. Motivation: Polymers Knots are topological invariants (self-avoiding) ring polymers A sufficiently long polymer will have knots: (Frisch & Wassermann (1961), Delbrück (1962)) Knots are not includedin thestandard theories Knots modify dynamics of polymers; e.g. relaxation or electrophoresis

  7. Motivation: Polymers Knots are topological invariants (self-avoiding) ring polymers A sufficiently long polymer will have knots (Frisch & Wassermann (1961), Delbrück (1962)) Knots are not included in the standard theories Knots modify dynamics of polymers; e.g. relaxation or electrophoresis

  8. Motivation: Biology Knots: Why? Structure <-> Function Role of entanglements?

  9. Motivation: Biology Knots: How? Reference system: Single homopolymer in stretched and compact state

  10. Motivation: Biology Knots: How? Reference system: Single homopolymer in stretched and compact state 1. At which chain length do knots occur? 2. Are knots localized or spread?

  11. Model Polymer: Coarse-grained model for polyethylene Bead-spring chain(LJ+FENE): 1 bead @ 3 CH2

  12. Model Polymer: Coarse-grained model for polyethylene Bead-spring chain(LJ+FENE): 1 bead @ 3 CH2 Equilibrium configurations are generated with standard Monte Carlo techniques (pivot, reptation, local moves)

  13. Simplification

  14. Coil / Globule Polymer: Coarse-grained model for polyethylene Bead-spring chain(LJ+FENE): 1 bead @ 3 CH2

  15. Coil / Globule Polymer: Coarse-grained model for polyethylene Bead-spring chain(LJ+FENE): 1 bead @ 3 CH2 Reduce chain, connect ends, calculate Alexander polynomial

  16. At which chain length do knots occur? unknot 31 41

  17. At which chain length do knots occur? unknot 31 41

  18. At which chain length do knots occur? unknot 31 41 Knots are rare in the swollen phase (1% for3000 CH2)

  19. At which chain length do knots occur? unknot 31 41 Knots are common in a dense phase (80% for3000 CH2)

  20. Are knots localized or spread?

  21. Are knots localized or spread? Knots are localized in the swollen phase

  22. Are knots localized or spread? Knots are delocalized in a dense phase

  23. Summary I frequency of knots localized ? dilute rare (1% for 3000 CH2) yes dense frequent (80%) no

  24. Summary I frequency of knots localized ? dilute rare (1% for 3000 CH2) yes dense frequent (80%) no • Probabilities:Open polymers <-> Loops ?

  25. Summary I frequency of knots localized ? dilute rare (1% for 3000 CH2) yes dense frequent (80%) no • Probabilities: Open polymers <-> Loops? • Excluded volume ?

  26. Summary I frequency of knots localized ? dilute rare (1% for 3000 CH2) yes dense frequent (80%) no • Probabilities: Open polymers <-> Loops? • Excluded volume ? • Distribution of sizes and location ?

  27. Summary I frequency of knots localized ? dilute rare (1% for 3000 CH2) yes dense frequent (80%) no • Probabilities: Open polymers <-> Loops? • Excluded volume ? • Distribution of sizes and location ? • -> simpler (faster) model: Random walk

  28. Polymers vs. Random Walks

  29. Loops vs. Chains unknot 31 41 Knots are frequent

  30. Loops vs. Chains unknot 31 41 Loops and chains have similar knotting probabilities

  31. Distribution of knot sizes

  32. Distribution of knot sizes Knots are localized in random walks

  33. Distribution of knot sizes Most likely knot size: only 6 segments

  34. Distribution of knot sizes

  35. Distribution of knot sizes Power-law tail in knot size distribution

  36. Where are knots located?

  37. Where are knots located? Knots are equally distributed over the entire polymer, but…

  38. Where are knots located? … larger in the middle

  39. Where are knots located?

  40. Summary II frequency of knots localized ? dilute rare (1% for 3000 CH2) yes dense frequent (80%) no RW very frequent extremely DNA ??? ??? Proteins ??? ???

  41. Knots in DNA? Human DNA is wrapped around histone proteins

  42. Knots in DNA? Human DNA is wrapped around histone proteins DNA coiled in phage capsid, but some indication of knotting inside Arsuaga et al., PNAS 99, 5373 (2002)

  43. Knots in DNA? Human DNA is wrapped around histone proteins DNA coiled in phage capsid, but some indication of knotting inside Arsuaga et al., PNAS 99, 5373 (2002) DNA in good solvent: 0.5%-4% for 10000 base pairs Rybenkov et al., PNAS 90, 5307 (1991)

  44. The Protein Data Bank www.pdb.org 02/2005 (24937)

  45. The Protein Data Bank www.pdb.org Problems: 1. Missing atoms 2. Multiple Chains 3. Microheterogeneity 4. Same Proteins

  46. Knots in proteins Knots are very rare: 230 / 24937 (1%) Source: mostly bacteria and viruses, but also mouse, cow, human and spinach Depth >5 >10 >15 >20 >25 # structures 35 33 28 28 25 (0.1%) # proteins 26 (9) 24 20 20 17 Size: 43% of protein, but variations from 17% to 82% Complexity: 23 trefoils, 2 figure-eights, 52 Functions: mostly enzymes (13 transferases)

  47. Final Summary frequency of knots localized ? dilute rare (1% for 3000 CH2) yes dense frequent (80%) no RW very frequent extremely DNA in vivo: probably few in vivo: - Proteins very few not enough statistics virnau@mit.edu

More Related