1 / 44

Proteins: “ dopable Solid-State Electronic Transport Materials

e -. Proteins: “ dopable Solid-State Electronic Transport Materials. “Traditional” methods to measure electron transfer in proteins. Electrochemistry (ML on electrode). Spectroscopy (in solution). Pulse- radiolysis . Flash- quench . Cyclic Voltammetry. Chrono - amperometry.

loe
Télécharger la présentation

Proteins: “ dopable Solid-State Electronic Transport Materials

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. e- Proteins:“dopableSolid-State Electronic Transport Materials

  2. “Traditional” methods to measure electron transfer in proteins Electrochemistry (ML on electrode) Spectroscopy (in solution) Pulse- radiolysis Flash- quench Cyclic Voltammetry Chrono- amperometry All these measure the Electron transfer rate (s-1)

  3. From electron transfer to “solid-state” electron transport • Goal: • Understand how electron transport (ETp)via proteins in a 'dry' configuration occurs and what influences it. • Common approaches to measure solid state ETp: CP-AFM STM

  4. Protein layer 150 nm 400 nm

  5. Protein layer Cytochrome C CH-stretches IR UV-Vis CD

  6. Proteins as Electronic Transport Medium? Proteins survive partial Dehydration Suitable… Proteins are rather efficient solid-state transport medium Co-factor is central  proteins can be doped Amide backbone maybe involved in elastic transport Functional and dopable ★★★ Ultimate scientific goal: Control & predict electron transport across proteins

  7. Proteins on Today’s Menu Natural electron transfer proteins Not an electron transfer protein Azurin Cytochrome C Serum Albumin

  8. Our main experimental approach • Substrate – Smooth! • Protein layer – Dense, usually linked by a short linker • Top electrode – Suitable to contact soft matter Idealized Cartoon! Electrical top contact Conductive substrate

  9. Substrate • Highly doped Si, Al(ox), Au • Controllable growth of thin oxide layer on Si • Linker layer (“glue”) Propyl-silane linker 6-8Å SiO2 9-10Å <100> p++-Si (< 0.001 Ω.cm)

  10. Top Electrode Au Hanging Hg drop Lift off float on (LOFO) - Au 0.2 mm2 ~107-109proteins/contact

  11. Conductive probe AFM • Less defects • Force variation

  12. 2μm A 10 nm Metallic substrate What does a nanoscale experiment look like? Idealized Cartoons!

  13. Electrophoretic nanowire assembly of poly-peptide & protein junctions - suspended nanowire method protein junction Azurin Device figure from G. Noy and Y. Selzer, Angew. Chem. Int. Ed. (2010)

  14. Current-voltage Characteristics of the different proteins • Same configuration • Same temperature SAM propyl-silane SiO2 Si p++

  15. Net decay What is the ETp mechanism? Gray and Winkler, 2003 proteins Tunneling Log conductance hopping Isied, JACS 2004 Joachim & Ratner, PNAS, 2005 8 1 2 3 4 5 6 7 Length (nm)

  16. What is the ETp mechanism? Thermally activated Temperature-independent Lower βvalues than for ET in solution Hopping ……………… Super-exchange …….. 2-step tunneling ???

  17. What is the ETp mechanism? • 1. Vary temperature • 2. Modify protein: • Remove the intramolecular cofactor • Replace cofactor • Add cofactor • Change binding (to electrode) • Change orientation of protein Not feasible with ET methodologies

  18. Temperature dependence I-V - Azurin Azurin covalently bound to the surface Sepunaru et al., JACS 2011

  19. Cu ion removal 300 meV Sepunaru et al., JACS 2011

  20. Cu ion replacement Cu-Az Ni-Az Co-Az Zn-Az Unpublished Results

  21. Connect to what was done before: Conductive probe AFM studies on Az A Our setup Our results (6-15 nN) All metal (platinum) Literature results (6 nN) Au Au Tip Bias (V) J. Davis (Oxford) setup Li et al., ACS Nano 2012

  22. Temperature-dependent conductive probe AFM Apo-Az Holo-Az 358K 268K Li et al., ACS Nano 2012

  23. Force-dependent measurements Apo-Az Holo-Az Increased force Increased force Different ETp mechanism Increased currents Same ETp mechanism Li et al., ACS Nano 2012

  24. Temperature dependent I-V with Cyt c Cyt C bound electrostatically (physisorbed) to surface 100 meV Iron-free CytC Holo-CytC Fe Apo-CytC What is the ETp mediator? Amdursky et al., JACS 2013

  25. Can we Control ETp ?‘Doping’ Serum Albumin Azurin CytC Apo-Az HSA

  26. ‘doping’ serum albumin with hemin

  27. ‘doping’ serum albumin with hemin HSA-hemin HSA Amdursky et al., PCCP 2013

  28. ‘doping’ serum albumin with hemin 95 meV HSA-hemin HSA 220 meV kET=4.8 s-1 kET=18.3 s-1 HSA-hemin CytC Amdursky et al., PCCP 2013

  29. ‘doping’ serum albumin with hemin What is the ETp mediator? The conjugated porphyrin ring, rather than the Fe ion is the main ETp mediator, while Fe2+/3+ redox controls the transfer in ET. Amdursky et al., PCCP 2013

  30. ‘doping’ serum albumin with retinoate-Can we increase ETp efficiency? Ligand/protein Ka=4*105 Amdursky et al., JACS 2012

  31. ‘doping’ serum albumin with retinoate Amdursky et al., JACS 2012

  32. The power of protein ‘doping’

  33. The importance of the contact to the electrodes and the orientation • Electrostatic (physisorbed) vs. Covalent (chemisorbed) binding CytC Amdursky et al., Submitted

  34. The importance of the contact to the electrodes and the orientation • The importance of the protein’s orientation Amdursky et al., Submitted

  35. Importance of the Protein’s Orientation Previous studies • Cyt b562 ACS Nano 2012, 355

  36. Importance of the Protein’s Orientation Amdursky et al., Submitted

  37. Can we use existing models to describe solid-state type of ETp?

  38. Importance of the Protein’s Orientation NO distance-current correlation!!! Amdursky et al., Submitted

  39. Importance of the Protein’s Orientation D • Clues from computational modeling Probably, there is no specific pathway in the ETp process from one side of the protein to the other A TP – tunneling pathway Vs. APD – atomic packing density Amdursky et al., TBP

  40. Conclusions • Electron transport through proteins can be measured by solid state configuration, both on the macro and the nano scales • The electron transport mechanism can be investigated by • Changing the temperature • Modifying the protein • Proteins can be viewed as electronic conducting material with the possibility of doping • The contacts to the electrodes and the orientation of the protein are of prime importance

  41. Thanks to students, PDs & other colleagues AcknowledgmentsMinerva Foundation, Munich Dr. Ann Erickson AbdElrazek Haj Yahia Dr. RotemHarLavan Dr. Omer Yaffe Dr. AyeletVilan NirK. Kedem Arava Zohar Mudi Sheves Israel Pecht 43

  42. Porphyrin- and apo-CytC

  43. ET vs. ETp Waldeckc.s. – PNA length dependence ACS Nano (2013) 5391

More Related