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- Introduction to Protein Folding and Misfolding
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1. Protein folding and misfolding: from theory to therapy
- Prof. Christopher Dobson
- Stability and Kinetics of Protein Folding
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2. Mechanisms of protein folding reactions
- Prof. Thomas Kiefhaber
- Protein Folding Theory
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3. Mapping disordered proteins with single-molecule FRET
- Dr. Hagen Hofmann
- Protein Folding Simulations
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4. Protein folding
- Prof. Eugene Shakhnovich
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5. Simulating protein folding with full atomistic detail
- Prof. Vijay Pande
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6. Molecular dynamics simulations of protein dynamics, unfolding and misfolding
- Prof. Valerie Daggett
- Protein Folding Inside the Cell: Chaperones
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7. Protein folding Inside the cell: macromolecular crowding and protein aggregation
- Prof. Emeritus R. John Ellis
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8. Chaperone mechanisms in cellular protein folding
- Prof. Dr. F. Ulrich Hartl
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9. Quality control of proteins mislocalized to the cytosol
- Dr. Ramanujan Hegde
- Protein Misfolding and Disease
- Protein Design
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11. Designing proteins with life sustaining activities 1
- Prof. Michael Hecht
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12. Designing proteins with life sustaining activities 2
- Prof. Michael Hecht
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13. Folding and design of helical repeat proteins
- Prof. Lynne Regan
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14. Design and engineering of zinc-finger domains
- Prof. Jacqui Matthews
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15. Prediction and design of protein structures and interactions
- Prof. David Baker
- Amyloid Fibrils: Structure, Formation and Nanotechnology
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16. Amyloid fibrils as functional nanomaterials
- Prof. Juliet Gerrard
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17. Functional amyloid fibrils from fungi and viruses
- Prof. Margaret Sunde
- Intrinsically disordered Proteins
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18. Fuzzy protein theory for disordered proteins
- Prof. Monika Fuxreiter
- Intersection of RNA, translation and protein aggregation.
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19. Expanding roles of RNA-binding proteins in neurodegenerative diseases
- Prof. Aaron D. Gitler
- Proteostasis
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20. Adapting proteostasis to ameliorate aggregation-associated amyloid diseases
- Dr. Jeffery W. Kelly
- Archived Lectures *These may not cover the latest advances in the field
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21. Amyloidosis: disease caused by amyloid
- Prof. Mark Pepys
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22. Protein folding and dynamics from single molecule spectroscopy
- Prof. Dr. Benjamin Schuler
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23. Prion diseases
- Prof. Fred Cohen
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25. Titin I27: a protein with a complex folding landscape
- Dr. Jane Clarke
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26. Novel proteins from designed combinatorial libraries
- Prof. Michael Hecht
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28. The sequence determinants of amyloid fibril formation
- Prof. Fabrizio Chiti
Printable Handouts
Navigable Slide Index
- Introduction
- Outline
- Protein folding
- Folding in solution versus folding on the ribosome
- Early experiments on protein folding
- The Anfinsen experiment
- Early models for protein folding
- Folding of Tendamistat
- Slow steps coupled to protein folding
- Slow protein folding - cis - trans isomerization
- Catalysis of cis-trans isomerization - tendamistat
- Catalysis of cis-trans isomerization - RNAseT1
- Prolyl isomerization during refolding
- Prediction of cis-trans proline equilibria
- Non-prolyl peptide bond isomerization
- Folding of proline-free tendamistat
- Double-jump experiments
- Double-jump experiments in tendamistat
- Temperature dependence of refolding
- LiCl increases the fraction of cis peptide bonds
- Association reactions of oligomeric proteins
- Foldon domain from T4 fibritin
- Effect of the foldon domain on fibritin folding
- NMR structure of the foldon domain - trimer
- NMR structure of the foldon domain - monomer
- Stability of the foldon domain
- Is association of folding rate - limiting?
- Determination of the reaction order
- Folding mechanism of the foldon domain
- Folding kinetics of the foldon domain
- Comparison to other small proteins
- Folding in the absence of slow reactions
- Folding of tendamistat - fast reactions
- Folding of lysozyme
- Complex folding kinetics of lysozyme
- Placing an intermediate on a folding pathway
- Refolding time course of kinetic species
- Time course of formation of intermediate and native
- Discrimination between folding pathways (1)
- Discrimination between folding pathways (2)
- Discrimination between folding pathways (3)
- Mechanism of lysozyme folding
- Folding of SFV protease
- SFV
- The structural polyprotein of SFV
- Co-translational folding of SFVP
- Comparison to other two-domain proteins
- Folding studies: the structural polyprotein of SFV
- Structure of SFVP
- Stability of SFVP
- Stopped-flow refolding of SFVP
- Formation of native SFVP
- Folding mechanism of SFVP
- Folding mechanism of SFVP - models
- Folding of SFVP
- Summary
- References
- Additional literature
Topics Covered
- History of protein folding
- Origin of complexity in protein folding kinetics
- Slow reactions coupled to folding
- Prolyl isomerization
- Non-prolyl isomerization
- Association reactions
- Detection of folding intermediates
- Discrimination between different kinetic mechanisms
- Folding of multi-domain proteins
Talk Citation
Kiefhaber, T. (2015, October 27). Mechanisms of protein folding reactions [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved November 22, 2024, from https://doi.org/10.69645/ELYH5869.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. Thomas Kiefhaber has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
A selection of talks on Biochemistry
Transcript
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0:00
This talk deals with the mechanisms of protein folding reactions.
0:06
The outline of my talk,
I will first give a brief introduction into the history of protein folding,
I will then talk about intrinsically slow reactions coupled to protein folding.
These are prolyl peptide bond isomerization,
non-prolyl peptide bond isomerization,
association reactions of oligomeric proteins.
In the second part of my talk,
I will address kinetic mechanisms of protein folding,
and I will specifically discuss how we can
place an intermediate on a kinetic folding pathway.
This will be shown in two case studies.
The first one is folding of Iysozyme,
and the second one is folding of Semliki Forest virus protease.
0:44
If you regard protein folding as a chemical reaction,
we start from the ensemble of different conformations representing
the unfolding state and end up in the biologically active native state,
which represents a single conformation with defined side chain and backbone interactions.
This is a simplification, of course,
because we know that there is conformation of fluctuations in the native state.
But the basic problem in protein folding is how the ensemble of
different states from the unfolded ensemble reach the native state.
And the questions we are addressing is,
are there intermediates located between the unfolded and the native state and what are
the rate limiting steps between the unfolded and the native state?
1:26
My talk deals with protein folding studies in vitro,
with purified proteins under well-defined conditions.
However, in vivo, protein folding occurs on the ribosome and it has been argued that
results from in vitro protein folding studies
may not be relevant for the situation in the cell.
Based on concept dating back to Van't Hoff's work in 1884,
I will try to show you that folding on the ribosome rather
represents a special case for protein folding reaction in the cell.
If you assume an equilibrium between
the ensemble of unfolded states and the native state,
with typical values for rate constants and stability,
we assume that delta G zero value of minus 17 kilojoules per mole for
the native state corresponding to an equilibrium constant of 10 to the three.
That means, we have a thousand times more native molecules
than unfolded molecules in equilibrium.
And we assume rate constants for folding of 10 per
second and the unfolding of point zero one per second.
These are also typical values formed for
small proteins or for domains of larger proteins.
We further assume a protein concentration of 10 micro molar.
We can then calculate that we have about 10 micro molar of molecules in the native state
and 10 to the minus two micro molar of molecules in the unfolded state in equilibrium.
Since the flux in the forward and
backward reaction are identical under equilibrium conditions,
we can calculate that, per second,
point one micro molar of molecules fold and unfold.
Now, let us apply these numbers to experimental systems.
If you perform experiments in vitro,
we typically have volumes of one milliliter in a cuvette.
That is, in this cuvette,
we have 10 to the 16 molecules in the native state,
and 10 to the 13 molecules in the unfolded state.
And every second, 10 to the 14 molecules fold and unfold.
If you do the same calculations for an E.
Coli cell with a volume of 10 to the minus 12 milliliter,
we see that we have 10 to the four molecules in the native state,
and 10 molecules in the unfolded state.
And every second, 100 molecules fold and unfold.
This means that without correct folding,
there would be less than one percent of native molecules after 500 seconds.
That means folding has to be able to occur in the absence of
the ribosome for protein to survive in a cell for longer times.
Let's take a short look at the history of protein folding experiments.