protein folding
DESCRIPTION
Protein Folding. Atlas F. Cook IV & Karen Tran. Overview. What is Protein Folding? Motivation Experimental Difficulties Simulation Models: Configuration Spaces Triangular Lattice models Pull Moves Probabilistic Roadmaps Map-Based Master Equation (MME) Map-Based Monte Carlo (MMC) - PowerPoint PPT PresentationTRANSCRIPT
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Protein Folding
Atlas F. Cook IV & Karen Tran
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Overview What is Protein Folding? Motivation Experimental Difficulties Simulation Models:
Configuration Spaces Triangular Lattice models
Pull Moves Probabilistic Roadmaps
Map-Based Master Equation (MME) Map-Based Monte Carlo (MMC)
Conclusion
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Motivation What is protein folding?
Folding/Morphing process 1D Amino Acid Chain 3D Folded protein
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Motivation
Why study protein folding? Proteins regulate almost all cellular functions 1D chain dictates 3D shape (NP-Hard) 3D Shape determines protein’s function
1D amino acid chain 3D folded protein
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Motivation
Holy grail of Protein Folding Build amino acid chain that:
folds into a desired shape and has a nice function (e.g., kill cancer cells)
How would we do this?
KillCancerCells
Desired FunctionRequired ShapeRequired Amino Acid Chain
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Motivation Another reason to study protein folding:
Unfolded protein = vulnerable protein
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Motivation
Misfolded proteins cause diseases:
Alzheimer’s Mad Cow Parkinson’s
Understand protein folding cure diseases!
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Terminology
Primary Structure 1D Amino Acid Chain (string) MGDVEKGKKIFIMKCSQCH
Secondary Structure Local patterns in a global folding Helices and Strands
Tertiary Structure Global 3D folded shape
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Experimental Difficulties Levinthal Paradox
Exponentially many ways to fold, yet folding occurs rapidly (milliseconds to seconds)
Why is folding so fast? Unfolded protein = vulnerable protein
Experimental observation Too slow to capture all significant motions
Our Goal: Simulate protein folding on computer!
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Simulation Models
HP Lattice Model: [Böckenhauer08] HP = Hydrophobic-Polar Models forces between Hydrophobic amino acids
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Simulation Models HP Lattice Model: [Böckenhauer08]
Amino acid vertex in a grid Protein self-avoiding chain in a grid
Amino Acid Chain
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Simulation Models HP Lattice Model: [Böckenhauer08]
Spring-like forces are modeled between neighboring amino acids.
Sum of forces for a state Energy.
1 2
3
4 5+2
+0 +1
+3 +10
Energy = 16
1
3
4
+1+2
+1
+2
Energy = 8
+2 5
2
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Simulation Models HP Lattice Model: [Böckenhauer08]
Global min energy “native state” = final folded state
Native state is stable. Global minimum is MUCH smaller than local minima.
1
3
4
+1+2
+1
+2Global min Energy = 8
+2 5
2
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Simulation Models
HP Lattice Model: [Böckenhauer08] A state is defined by the position of every amino
acid in the chain
A State Another State
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Simulation Models
HP Lattice Model: [Böckenhauer08] Configuration space = set of all possible states
Exponential to protein length
Protein folding simulation: “Move” from start state goal state.
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Simulation Models
HP Lattice Model: [Böckenhauer08] Move Properties:
Complete – moves can reach all feasible states Reversible – every move has an inverse
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Simulation Models
HP Lattice Model: [Böckenhauer08] Forward Pull Move
Pull vertex 5 to a new position
Before move After move
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Simulation Models
HP Lattice Model: [Böckenhauer08] Tabu Search
Greedy, heuristic search Simulates protein folding Pull moves transform start state local minimum Records recent moves in a Tabu list
Fast backtracking to different paths
Summary of HP Lattice Model: Input: Amino acid sequence Output: Heuristically folded protein
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Probabilistic Roadmap
Model
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Simulation Models
Probabilistic Roadmap [Song04] 2D Graph (Configuration space):
Each point represents an entire state (all amino acids). Obstacles are infeasible states
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Simulation Models
Probabilistic Roadmap [Song04] Goal:
Given start & goal states Find “best path” from start goal
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Simulation Models
Probabilistic Roadmap [Song04]
3 Steps:1. Node generation:
Generate points randomly (dense near the goal state)
2. Roadmap Construction Connect nearest neighbors graph
3. Query roadmap Dijkstra’s algorithm shortest path Shortest path = set of states Describes the dynamic folding process
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Simulation Models
Probabilistic Roadmap [Song04]1. Node generation:
Generate random points “Obstacles” are infeasible (self-overlapping) states
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Simulation Models
Probabilistic Roadmap [Song04]2. Roadmap Construction
Connect nearest neighbors graph
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Simulation Models
Probabilistic Roadmap [Song04]3. Query roadmap
Dijkstra’s algorithm shortest path Path = set of states that describes the folding process
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Molecular Dynamics
Model
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Simulation Models Molecular Dynamics Models [Tapia07]
Model forces based on Newton’s laws of motion Very accurate Very slow!
Simulating one microsecond of folding for a 36 residue protein = Months of supercomputer time!
Cannot handle full length proteins
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Simulation Models
Map-based Master Equation (MME) [Tapia07] Fast enough to study full length proteins More accurate than simplistic lattice models MME is an extension of a Probabilistic Roadmap
Probabilistic roadmap ≈ Viterbi algorithm returns one optimal path
MME ≈ Baum-Welch algorithm Maintains transition probabilities for every state Learning is executed until probabilities stabilize. Can return the probability of any state at time t.
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Simulation Models Map-based Monte-Carlo (MMC) [Tapia07]
MMC = Probabilistic Roadmap + Monte-Carlo
Monte-Carlo [Wiki08_MC] random sampling + algorithms = result Example: Battleship
Make random shots Apply prior knowledge
Battleship = 4 vertical/horizontal dots Apply algorithms to quickly sink the ship
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Simulation Models
Map-based Monte-Carlo (MMC) [Tapia07] Fast & reasonably accurate
Models the protein as an articulated figure Each joint = set of angles Movement-based (kinetic) statistics
Results suggest that: Local helix structures form first Folding occurs around hydrophobic core
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Conclusion Protein Folding:
1D Amino acid chain folds into 3D structure Misfolding Alzheimer’s, Parkinson’s, Mad Cow diseases Folding is too fast to observe experimentally
Four Simulation Models:1. Triangular Lattice model (2D Graph)
Vertex = one amino acid “Moves” transition between states
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Conclusion Four Simulation Models (cont.)
2. Probabilistic Roadmaps Vertex represents state of entire protein Random sampling + Dijkstra’s alg Best folding route ≈ Viterbi (returns one path)
3. Map-Based Master Equation (MME) Learn probabilities ≈ Baum-Welch (confidence level for each state)
4. Map-Based Monte Carlo (MMC) Articulated figures with joints model proteins
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References: [Böckenhauer08]
Hans-Joachim Böckenhauer, Abu Zafer M. Dayem Ullah, Leonidas Kapsokalivas, and Kathleen Steinhöfel. A local move set for protein folding in triangular lattice models. In Keith A. Crandall and Jens Lagergren, editors, WABI, volume 5251 of Lecture Notes in Computer Science, pages 369–381. Springer, 2008.
[Dobson99] C. Dobson and M. Karplus. The fundamentals of
protein folding: bringing together theory and experiment. Current Opinion in Structural Biology, 9:928–101, 1999.
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References: [Song04]
G. Song and N. M. Amato. A motion planning approach to folding: From paper craft to protein folding. Proc. IEEE Transactions on Robotics and Automatics, 20:60–71, 2004.
[Tapia07] Lydia Tapia, Xinyu Tang, Shawna Thomas, and
Nancy M. Amato. Kinetics analysis methods for approximate folding landscapes. Bioinformatics, 23(13):i539–i548, 2007.
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References: [˘Sali94]
A., E. Shakhnovich, and M. Karplus. How does a protein fold? Nature, 369:248–251, 1994.
[Wiki08] Wikipedia. Protein folding — Wikipedia, the free
encyclopedia, 2008. http://en.wikipedia.org/wiki/Protein_folding.
[Wiki08_MC] Wikipedia. Monte-Carlo method — Wikipedia, the
free encyclopedia, 2008. http://en.wikipedia.org/wiki/Monte_Carlo_method
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Thank you for your
attention.Questions
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Extra Slides
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Simulation Models
Map-based Master Equation (MME) [Tapia07] MME = Probabilistic roadmap + Master Equation
Master Equation – set of equations defining the probability of a system to be in a discrete set of states at a given time.