USTC iGEM 2007 Extensible Logic Circuit in Bacteria Aims How to implement elementary computations? How to form a more complex one?
Mar 31, 2015
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USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Aims
• How to implement elementary computations?
• How to form a more complex one?
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Concrete Example
• Gates: NAND, NOR, NOT gates, 2 levels• Wires: 3 wires, which can cross and branch off • I/O: 2 inputs and 2 outputs
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Concrete Example
• Gates: NAND, NOR, NOT gates, 2 levels• Wires: 3 wires, which can cross and branch off • I/O: 2 inputs and 2 outputs
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Objectives
• Transcriptional Regulation can be utilized to implement NAND, NOR, NOT gates in E.coli.
• Transcriptional Factors can transmit message from one component to another.
USTC iGEM 2007 Extensible Logic Circuit in BacteriaUSTC iGEM 2007 Extensible Logic Circuit in Bacteria
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Repression Model
Bintu, L. et al. Transcriptional regulation by the numbers: models. CurrOpin Genet Dev (2005)
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Repression Model
Bintu, L. et al. Transcriptional regulation by the numbers: models. CurrOpin Genet Dev (2005)
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Simulation and Score Function
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Simulation and Score Function
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Simulation and Score Function
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Cis-acting Logic Promoters
NOT Gate
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Cis-acting Logic Promoters
NOR Gate
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Cis-acting Logic Promoters
NAND Gate
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Constructions and Measurements
Solo-Repression Assay
Co-Repression Assay
PCR Construction
77 Promoter Synthesized~ 400 Quantitative Assays
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Effect of Operator Position
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Effect of Operator Composition
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
DNA-Looping
[1] Müller, J., et al. Repression of lac promoter as a function of distance,phase and quality of an auxiliary lac operator. J. Mol. Bio. (1996)[2] Saiz, L. and Vilar, J. M. G. DNA looping: the consequences and itscontrol., Curr Opin Struct Biol (2006)
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Hybrid Operator
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Dual-Repressed Operator
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Suggested Patterns
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Suggested Patterns
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Suggested Patterns
USTC iGEM 2007 Extensible Logic Circuit in BacteriaUSTC iGEM 2007 Extensible Logic Circuit in Bacteria
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Repressor-Operator Recognition
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Repressor-Operator Pairs
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Directed Evolution
• Select Target Sites• Mutagenesis by PCR• Screen on Plates• Quality Control• Quantitative
Measurements• Result Analysis
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Directed Evolution
• Select Target Sites• Mutagenesis by PCR• Screen on Plates• Quality Control• Quantitative
Measurements• Result Analysis
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Directed Evolution
• Select Target Sites• Mutagenesis by PCR• Screen on Plates• Quality Control• Quantitative
Measurements• Result Analysis 5000 colonies screened
3 artificial operators400 candidates per operator11 novel artificial repressors
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Directed Evolution
• Select Target Sites• Mutagenesis by PCR• Screen on Plates• Quality Control• Quantitative
Measurements• Result Analysis
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Directed Evolution
• Select Target Sites• Mutagenesis by PCR• Screen on Plates• Quality Control• Quantitative
Measurements• Result Analysis
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Directed Evolution
• Select Target Sites• Mutagenesis by PCR• Screen on Plates• Quality Control• Quantitative
Measurements• Result Analysis
Repression Matrix
Diagonal Repression Matrix
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Repressor Evolution in Silico
Selection of target ligand
and variable positions
Side chain conformation optimization
Sequence evaluation
Test the results in vivo
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Repressor Evolution in Silico
Selection of target ligand
and variable positions
Side chain conformation optimization
Test the results in vivo
Sequence evaluation
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Diagonal Repression Matrix
6 repressors bind to only 1 operator3 repressors bind to 2 operators3x3 array for the demo system
9 Repressors vs. 4 Operators
USTC iGEM 2007 Extensible Logic Circuit in BacteriaUSTC iGEM 2007 Extensible Logic Circuit in Bacteria
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
A Demo: Diagram
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
A Demo: Signaling Pathway
USTC iGEM 2007 Extensible Logic Circuit in BacteriaUSTC iGEM 2007 Extensible Logic Circuit in Bacteria
What we have done:
Patterns for NAND, NOR, NOT gates
Highly-specific artificial repressors
A demonstration system
123 Parts Submitted247 Part Sequences 77 Synthesized Promoters 11 Novel Artificial Repressors ~ 350 New Strains ~ 130 DNA Strands Sequenced > 5000 Colonies Screened ~ 400 Quantitative Assays
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Cis-acting Logic Gates
• Work in vivo• Can be systematically
constructed• Small in scale
– About 2.0nm in width– 20 - 70nm in length
• Can be cascaded to implement complex combinational logic computation
Promoters with Cis-acting Elements
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Wires without Interference
• The number can grow• Do not interrupt natural sig
naling network• Do not interrupt each other• Provide supports for cis-ac
ting logic gates– DNA Recognition– Dimerization– Tetramerization
Highly-Specific Artificial Repressor
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
What We Plan To Do
• Further Optimization– Size of the Wires
– Response Time
– More Input Signals
– Better NOR pattern
• Conductance Adjusting– Using different RBS
– Using different operators
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Further More
The First Transistor1947
The First Integrated Circuit1958
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Further More
?
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
USTC iGEM 2007
• Graduates– Zhan Jian– Ding Bo– Ma Rui– Ma Xiaoyu
• Undergrads– Liu Ziqing– Su Xiaofeng– Zhao Yun
• Advisors– Prof. HY Liu– Prof. JR Wu– Prof. ZH Hou
USTC iGEM 2007 Extensible Logic Circuit in Bacteria
Acknowledgments
We are sponsored by:
Univ. of Sci. and Tech. of China
HHTech Co. Ltd.
NNSFC
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