BE 150/Bi 250b Winter 2013: Difference between revisions

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<font color='blue' size='+2'>Systems Biology</font>__NOTOC__
<font color='blue' size='+2'>Systems Biology</font>__NOTOC__
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'''Instructors'''
'''Instructors'''
* Michael Elowitz (Bi/BE/APh)
* Michael Elowitz (Bi/BE/APh)
* Richard Murray (CDS/BE)
* Richard Murray (CDS/BE)
* Lectures: MW 10-11, location TBD
* Lectures: MWF 10-11, 200 BRD
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'''Teaching Assistants'''
'''Teaching Assistants'''
* Emzo de los Santos
* Emzo de los Santos
* TBD
* Victoria Hsiao
* Recitation: Fr 10-11, location TBD
* Recitation: Fr 10-11, location TBD
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__TOC__
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This is the course homepage for BE 150/Bi 250b for Winter 2013.  This page contains all of the information about the material that will be covered in the class, as well as links to the homeworks and information about the course projects and grading.
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=== Lecture Schedule ===
=== Lecture Schedule ===
There will be two 1-hour lectures each week, as well as a 1-hour recitation section.
There will be 2-3 one-hour lectures each week, as well as occasional one-hour tutorials, recitations or journal club.
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| '''Week'''
| '''Week'''
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===== 1 =====
'''1'''
| 7 Jan <br> 9 Jan <br> MBE/RMM
| 7 Jan <br> 9 Jan+ <br> MBE/RMM
| Course overview, gene circuit dynamics
| Course overview, gene circuit dynamics
* Principles in systems biology
* Principles in systems biology
* Core processes in cells
* Core processes in cells
* Modeling transcription, translation and regulation using ODEs
* Modeling transcription, translation and regulation using ODEs
* Negative auto-regulation
Recitation section:
Recitation section:
* MATLAB tutorial (optional)
* [[Media:MatlabTutorial.pdf|MATLAB]] and [[Media:SimbiologyTutorial.pdf|SimBiology]] Tutorial
[https://www.cds.caltech.edu/~murray/wiki/images/6/64/MatlabTutorial.pdf  Matlab Tutorial]
* Useful MATLAB commands: {{be150-wi13 matlab|useful_matlab.m}}
* SimBiology example: {{be150-wi13 matlab|rec1_pos_regdemo.sbproj}}
* MATLAB/ode45 example: {{be150-wi13 matlab|pos_reg_main.m}}, {{be150-wi13 matlab|pos_reg.m}}
 
|  
|  
Bi 250b:
Bi 250b:
* Alon, Ch 1: Introduction
* Alon, Ch 1: Introduction
* Alon, Ch 2: Transcription networks : basic concepts
* Alon, Ch 2: Transcription networks : basic concepts
* Alon, Ch 3: Autoregulation : a network motif


BE 150:
BE 150:
* {{be150 pdf|wi12|caltech/bfs-class-intro_01Jan12.pdf|BFS, Ch 1}}: Introductory Concepts
* {{be150 pdf|wi13|caltech/bfs-class-intro_05Jan13.pdf|BFS Ch 1}}: Introductory Concepts (skim)
* {{be150 pdf|wi12|caltech/bfs-class-coreproc_18Jan12.pdf|BFS, Ch 2}}: Modeling of Core Processes
* {{be150 pdf|wi13|caltech/bfs-class-coreproc_05Jan13.pdf|BFS Ch 2}}: Modeling of Core Processes
** Section 2.1: Modeling Techniques
** Section 2.1: Modeling Techniques (skim)
** Sections 2.2-2.3: transcription and translation, transcriptional regulation
** Sections 2.2-2.3: transcription and translation, transcriptional regulation
<!--
<!--
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* [http://www.nature.com/nature/journal/v426/n6965/abs/nature02089.html A positive-feedback-based bistable 'memory module' that governs a cell fate decision], Xiong and Ferrell. ''Nature'', <b>426</b>:460-465, 2003.
* [http://www.nature.com/nature/journal/v426/n6965/abs/nature02089.html A positive-feedback-based bistable 'memory module' that governs a cell fate decision], Xiong and Ferrell. ''Nature'', <b>426</b>:460-465, 2003.
-->
-->
| HW1
| [http://www.cds.caltech.edu/~murray/courses/be150/wi13/hw1.pdf HW1]
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===== 2 =====
 
'''2'''
| 13 Jan <br> 15 Jan <br> MBE
| 13 Jan <br> 15 Jan <br> MBE
| Circuit motifs
| Circuit motifs
* Negative auto-regulation
* Feedforward loops (FFLs)
* Feedforward loops (FFLs)
* Phosphorylation cascades
* Phosphorylation cascades
* Two-component signaling systems
* Two-component signaling systems
* Sequestration for ultrasensitivty
* Sequestration for ultrasensitivty
|  
Recitation (17 Jan): sample problems
Bi 250b:
* MATLAB/curve fitting tool example: {{be150-wi13 matlab|cftools_example.m}}
* Alon, Ch 3: Autoregulation : a network motif
 
|Bi 250b:
* Alon, Ch 4: The feed-forward loop network motif
* Alon, Ch 4: The feed-forward loop network motif
* Alon, Ch 6: Network motifs in developmental, signal transduction, and neuronal networks  
* Alon, Ch 6: Network motifs in developmental, signal transduction, and neuronal networks  


BE 150:
BE 150:
* {{be250c pdf|wi12|caltech/bfs-class-coreproc_18Jan21.pdf|BFS, Ch 2}}: Modeling of Core Processes
* {{be150 pdf|wi13|caltech/bfs-class-coreproc_05Jan13.pdf|BFS Ch 2}}: Modeling of Core Processes
** Section 2.4: post-transcriptoinal regulation
** Section 2.4: post-transcriptional regulation
** Section 2.5: cellular subsystems
** Section 2.5: cellular subsystems
<!--
<!--
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* [http://www.nature.com/msb/journal/v5/n1/full/msb200930.html Protein sequestration generates a flexible ultrasensitive response in a genetic network], N. E. Buchler and F. R. Cross.  ''Molecular Systems Biology'', 5:272, 2009.
* [http://www.nature.com/msb/journal/v5/n1/full/msb200930.html Protein sequestration generates a flexible ultrasensitive response in a genetic network], N. E. Buchler and F. R. Cross.  ''Molecular Systems Biology'', 5:272, 2009.
-->
-->
| HW 2
| [http://www.cds.caltech.edu/~murray/courses/be150/wi13/hw2.pdf HW2]
 
* {{be150-wi13 matlab|I1FFL.sbproj}}
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===== 3 =====
'''3'''
| <s>21 Jan</s> <br> 23&nbsp;Jan <br> 25 Jan <br> RMM
| <s>21 Jan</s> <br> 23&nbsp;Jan* <br> 25 Jan <br> RMM
| Biological clocks: how to produce oscillations in cells
| Biological clocks: how to produce oscillations in cells
* Plant clocks/circadian rhythm
* Plant clocks/circadian rhythm
* Synthetic oscillators (repressilator, dual-feedback oscillator)
* Synthetic oscillators (repressilator, dual-feedback oscillator)
* Circadian clocks in cyanobacteria
* Circadian clocks in cyanobacteria
No recitation
|  
|  
* [http://stke.sciencemag.org/cgi/content/full/sci;321/5885/126 Robust, Tunable Biological Oscillations from Interlinked Positive and Negative Feedback Loops], Tsai, Choi, Ma, Pomerening, Tang and Ferrell. ''Science Signaling'', 321(5885): 126, 2008
* [http://www.nature.com/nature/journal/v403/n6767/full/403335a0.html A synthetic oscillatory network of transcriptional regulators], Elowitz and Leibler. ''Nature'', 403:335-338, 2000.
* [http://www.nature.com/nature/journal/v403/n6767/full/403335a0.html A synthetic oscillatory network of transcriptional regulators], Elowitz and Leibler. ''Nature'', 403:335-338, 2000.
* [http://www.nature.com/nature/journal/v456/n7221/full/nature07389.html A fast, robust and tunable synthetic gene oscillator], Stricker, ''et al.''.  ''Nature'',  456:516-519, 2008.
* [http://www.nature.com/nature/journal/v456/n7221/full/nature07389.html A fast, robust and tunable synthetic gene oscillator], Stricker, ''et al.''.  ''Nature'',  456:516-519, 2008.
* [http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1855407/ Cyanobacterial clock, a stable phase oscillator with negligible intercellular coupling], M. Amdaoud, M. Vallade, C. Weiss-Schaber, and I. Mihalcescu.  ''Proc Natl Acad Sci'', 104(17):7051–7056, 2007.
BE 150:
BE 150:
* {{be150 pdf|wi12|caltech/bfs-class-dynamics_18Jan12.pdf|BFS, Ch 3}}: Analysis of Dynamic Behavior
* {{be150 pdf|wi13|caltech/bfs-class-dynamics_05Jan13.pdf|BFS Ch 3}}: Analysis of Dynamic Behavior
** Sections 3.5: Oscillatory Behavior
** Sections 3.5: Oscillatory Behavior
| HW 3
| [http://www.cds.caltech.edu/~murray/courses/be150/wi13/hw3.pdf HW3]
* {{be150-wi13 matlab|dde.m}}


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===== 4 =====
 
| 28 Jan <br> 30 Feb <br> RMM
'''4'''
| 28 Jan <br> 30 Jan <br> RMM
| Robustness
| Robustness
* Chemotaxis and perfect adaptation
* Chemotaxis and perfect adaptation
* Fold change detection
* Fold change detection
* Controls analysis of robustness
* Controls analysis of robustness
Recitation (1 Feb): sensitivity analysis
*Demo of sensitivity analysis and how to add events in simbio: {{be150-wi13 matlab|I1FFL_sens_event_demo.sbproj}}
*Demo of how to use compartments within one model: {{be150-wi13 matlab|multiple_compartments.sbproj}}
|
|
* Alon, Ch 7: Robustness of protein circuits : the example of bacterial chemotaxis
* Alon, Ch 7: Robustness of protein circuits : the example of bacterial chemotaxis
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* (optional) C. V. Rao, J. R. Kirby, and A. P. Arkin, [http://www.ncbi.nlm.nih.gov/pubmed/14966542 Design and diversity in bacterial chemotaxis: a comparative study in Escherichia coli and Bacillus subtilis], PLoS Biol, vol. 2, no. 2, p. E49, Feb. 2004.
* (optional) C. V. Rao, J. R. Kirby, and A. P. Arkin, [http://www.ncbi.nlm.nih.gov/pubmed/14966542 Design and diversity in bacterial chemotaxis: a comparative study in Escherichia coli and Bacillus subtilis], PLoS Biol, vol. 2, no. 2, p. E49, Feb. 2004.
BE 150:
BE 150:
* {{be150 pdf|wi12|caltech/bfs-class-dynamics_29Jan12.pdf|BFS, Ch 3}}: Sec 3.3 (Robustness) and Sec 3.6 (Bifurcations)
* {{be150 pdf|wi13|caltech/bfs-class-dynamics_05Jan13.pdf|BFS, Ch 3}}: Sec 3.3 (Robustness) and Sec 3.6 (Bifurcations)
* {{be150 pdf|wi12|caltech/bfs-class-chemotaxis_29Jan12.pdf|BFS, Sec 5.2}}: Bacterial chemotaxis
* {{be150 pdf|wi13|caltech/bfs-class-chemotaxis_05Jan13.pdf|BFS, Sec 5.2}}: Bacterial chemotaxis
* (optional) O. Shoval, L. Goentoro, Y. Hart, A. Mayo, E. Sontag, and U. Alon, [http://www.pnas.org/content/107/36/15995.long Fold-change detection and scalar symmetry of sensory input fields], Proceedings of the National Academy of Sciences, vol. 107, no. 36, pp. 15995–16000, Sep. 2010.
* (optional) O. Shoval, L. Goentoro, Y. Hart, A. Mayo, E. Sontag, and U. Alon, [http://www.pnas.org/content/107/36/15995.long Fold-change detection and scalar symmetry of sensory input fields], Proceedings of the National Academy of Sciences, vol. 107, no. 36, pp. 15995–16000, Sep. 2010.
| HW 4
| [http://www.cds.caltech.edu/~murray/courses/be150/wi13/hw4.pdf HW4]
 
|-
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| 1 Feb
| colspan=3 | [[BE 150/Bi 250b project ideas, Winter 2013|'''Course projects''']] posted.  Instructions:
{{BE 150 project instructions, Winter 2013}}


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===== 5 =====
 
| 4 Feb* <br> 8 Feb <br> MBE
'''5'''
| 4 Feb <br> 6 Feb <br> MBE
| Noise
| Noise
* Random processes
* Random processes
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* Stochastic modeling: master equation, SSA
* Stochastic modeling: master equation, SSA
|  
|  
* BFS, Ch 4 and App C
* [http://www.sciencemag.org/content/297/5584/1183 Stochastic Gene Expression in a Single Cell], Michael B. Elowitz, Arnold J. Levine, Eric D. Siggia and Peter S. Swain.  ''Science'', 297(5584):1183-1186, 2002.
* [http://www.sciencemag.org/content/297/5584/1183 Stochastic Gene Expression in a Single Cell], Michael B. Elowitz, Arnold J. Levine, Eric D. Siggia and Peter S. Swain.  ''Science'', 297(5584):1183-1186, 2002.
* [http://www.nature.com/nature/journal/v440/n7082/full/nature04599.html Stochastic protein expression in individual cells at the single molecule level], Long Cai, Nir Friedman and X. Sunney Xie.  ''Nature'', 440:358-362, 2006.
* [http://www.nature.com/nature/journal/v440/n7082/full/nature04599.html Stochastic protein expression in individual cells at the single molecule level], Long Cai, Nir Friedman and X. Sunney Xie.  ''Nature'', 440:358-362, 2006.
BE 150:
BE 150:
* {{be150 pdf|wi12|caltech/bfs-class-stochastic_29Jan12.pdf|BFS, Ch 4}}: Stochastic behavior
* {{be150 pdf|wi13|caltech/bfs-class-stochastic_05Jan13.pdf|BFS, Ch 4}}: Stochastic behavior
* {{be150 pdf|wi12|caltech/bfs-class-random_29Jan12.pdf|BFS, App C}}: Probability and random processes (optional)
* {{be150 pdf|wi13|caltech/bfs-class-random_05Jan13.pdf|BFS, App B}}: Probability and random processes (optional)
| HW 5
| rowspan=2 |  [http://www.cds.caltech.edu/~murray/courses/be150/wi13/hw5.pdf HW5]


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===== 6 =====
'''6'''
| 11 Feb+ <br> 13 Feb <br> MBE
| 11 Feb <br> 13 Feb+ <br> MBE
| Burstiness in gene expression and signalling
| Burstiness in gene expression and signalling
* Birth-death processes
* Birth-death processes
Line 145: Line 169:
* [http://www.nature.com/nature/journal/v455/n7212/full/nature07292.html Frequency-modulated nuclear localization bursts coordinate gene regulation], Long Cai, Chiraj K. Dalal and Michael B. Elowitz.  Nature 455:485-490, 2008.
* [http://www.nature.com/nature/journal/v455/n7212/full/nature07292.html Frequency-modulated nuclear localization bursts coordinate gene regulation], Long Cai, Chiraj K. Dalal and Michael B. Elowitz.  Nature 455:485-490, 2008.
* [http://www.nature.com/nature/journal/v466/n7303/full/nature09145.html Single-cell NF-kB dynamics reveal digital activation and analogue information processing], S. Tay ''et al''.  ''Nature'', 466(7303):267-271, 2010
* [http://www.nature.com/nature/journal/v466/n7303/full/nature09145.html Single-cell NF-kB dynamics reveal digital activation and analogue information processing], S. Tay ''et al''.  ''Nature'', 466(7303):267-271, 2010
| HW 6
 
|-
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| 15&nbsp;Feb+*<br>
| colspan=3 | Course project discussion with TAs


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===== 7 =====
'''7'''
| <s>18 Feb</s> <br> 20&nbsp;Feb <br> 22&nbsp;Feb <br> RMM
| <s>18 Feb</s><br><s>20 Feb</s><br>22&nbsp;Feb* <br> 25 Feb <br> RMM
| Patterning
| Patterning
* Morphogenesis
* Morphogenesis
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* [http://linkinghub.elsevier.com/retrieve/pii/S0959437X04000887 Elucidating mechanisms underlying robustness of morphogen gradients], Avigdor Eldar, Ben-Zion Shilo and Naama Barkai. ''Curr Opin Genet Dev.'', 14(4):435-439, 2004.
* [http://linkinghub.elsevier.com/retrieve/pii/S0959437X04000887 Elucidating mechanisms underlying robustness of morphogen gradients], Avigdor Eldar, Ben-Zion Shilo and Naama Barkai. ''Curr Opin Genet Dev.'', 14(4):435-439, 2004.
* [http://www.pnas.org/content/107/15/6924.short Scaling of morphogen gradients by an expansion-repression integral feedback control], Danny Ben-Zvia and Naama Barkai.  ''PNAS'',  107(15):6924-6929, 2010.
* [http://www.pnas.org/content/107/15/6924.short Scaling of morphogen gradients by an expansion-repression integral feedback control], Danny Ben-Zvia and Naama Barkai.  ''PNAS'',  107(15):6924-6929, 2010.
| HW 7
| rowspan=2 |  [http://www.cds.caltech.edu/~murray/courses/be150/wi13/hw6.pdf HW6]
 
[http://www.cds.caltech.edu/~murray/courses/be150/wi13/matlab/NotchDeltaGui.m NotchDeltaGui.m]
[http://www.cds.caltech.edu/~murray/courses/be150/wi13/matlab/NotchDeltaGui2.m NotchDeltaGui2.m]
|- valign=top
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===== 8 =====
'''8'''
| 25 Feb <br> 27 Feb <br> RMM
| 27 Feb <br> 1 Mar <br> RMM
| Fine grain patterns
| Fine grain patterns
* Lateral inhibition
* Lateral inhibition
Line 173: Line 202:
* [http://www.ncbi.nlm.nih.gov/pubmed/9015458 Pattern formation by lateral inhibition with feedback: a mathematical model of delta-notch intercellular signalling], Collier et al. Journal of theoretical biology (1996) vol. 183 (4) pp. 429-46.
* [http://www.ncbi.nlm.nih.gov/pubmed/9015458 Pattern formation by lateral inhibition with feedback: a mathematical model of delta-notch intercellular signalling], Collier et al. Journal of theoretical biology (1996) vol. 183 (4) pp. 429-46.
* [http://www.ncbi.nlm.nih.gov/pubmed/20418862 Cis-interactions between Notch and Delta generate mutually exclusive signalling states], Sprinzak et al. Nature (2010) vol. 465 (7294) pp. 86-90
* [http://www.ncbi.nlm.nih.gov/pubmed/20418862 Cis-interactions between Notch and Delta generate mutually exclusive signalling states], Sprinzak et al. Nature (2010) vol. 465 (7294) pp. 86-90
| HW 8


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===== 9 =====
 
| 4 Mar <br> 6 Mar <br> MBE
'''9'''
| Special topics
| 4 Mar <br> 6 Mar <br> 8 Mar <br>
|
| colspan=3 | Project presentations
|


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===== 9 =====
 
| 11 Mar <br> 13 Mar <br> RMM
'''10'''
| Special topics
| 11 Mar <br> 13 Mar
|
| colspan=3 | Project presentations
|
|}
|}


Line 213: Line 239:
|- valign=top
|- valign=top
| align=right | &nbsp;[BFS]&nbsp;
| align=right | &nbsp;[BFS]&nbsp;
| D. Del Vecchio and R. M. Murray, ''Biomolecular Feedback Systems''.  Available online at http://www.cds.caltech.edu/~murray/amwiki/BFS.
| D. Del Vecchio and R. M. Murray, ''[[http:www.cds.caltech.edu/~murray/amwiki/BFS|Biomolecular Feedback Systems]]'' (available online)
* Note: these notes are being written and will be updated during the course
* Note: these notes are being written and will be updated during the course
* Class version (Caltech access only, 29 Jan 2012): {{be150 pdf|wi12|caltech/bfs-class-frontmatter_01Jan12.pdf|TOC}}, {{be150 pdf|wi12|caltech/bfs-class-intro_01Jan12.pdf|Ch 1}}, {{be150 pdf|wi12|caltech/bfs-class-coreproc_18Jan12.pdf|Ch 2}},  {{be150 pdf|wi12|caltech/bfs-class-dynamics_29Jan12.pdf|Ch 3}},  {{be150 pdf|wi12|caltech/bfs-class-stochastic_29Jan12.pdf|Ch 4}}, {{be150 pdf|wi12|caltech/bfs-class-chemotaxis_29Jan12.pdf|Sec 5.2}}, {{be150 pdf|wi12|caltech/bfs-class-random_29Jan12.pdf|App C}}, {{be150 pdf|wi12|caltech/bfs-class-backmatter_01Jan12.pdf|Refs}}
* The public version is missing some copyrighted figures.  These are available in the class version.
* Class version (Caltech access only, 5 Jan 2013): {{be150 pdf|wi13|caltech/bfs-class-frontmatter_05Jan13.pdf|TOC}}, {{be150 pdf|wi13|caltech/bfs-class-intro_05Jan13.pdf|Ch 1}}, {{be150 pdf|wi13|caltech/bfs-class-coreproc_05Jan13.pdf|Ch 2}},  {{be150 pdf|wi13|caltech/bfs-class-dynamics_05Jan13.pdf|Ch 3}},  {{be150 pdf|wi13|caltech/bfs-class-stochastic_05Jan13.pdf|Ch 4}}, {{be150 pdf|wi13|caltech/bfs-class-chemotaxis_05Jan13.pdf|Sec 5.2}}, {{be150 pdf|wi13|caltech/bfs-class-random_05Jan13.pdf|App B}}, {{be150 pdf|wi13|caltech/bfs-class-backmatter_05Jan13.pdf|Refs}}
|}
|}


Line 221: Line 248:
{|
{|
|- valign=top
|- valign=top
| align=right | &nbsp;[FBS]&nbsp;
| K. J. Astrom and R. M. Murray, ''Feedback Systems''.  Available online at http://www.cds.caltech.edu/~murray/amwiki.
|- valign=top
|- valign=top
| align=right | &nbsp;[Klipp]&nbsp;
| align=right | &nbsp;[Klipp]&nbsp;
Line 230: Line 255:
| Steven Strogatz, ''Nonlinear Dynamics And Chaos: With Applications To Physics, Biology, Chemistry, And Engineering''.  Westview Press, 2001.
| Steven Strogatz, ''Nonlinear Dynamics And Chaos: With Applications To Physics, Biology, Chemistry, And Engineering''.  Westview Press, 2001.
|}
|}
=== Course project ===
All students enrolled in the course will be expected to participate in a course project, which will be assigned after the fourth week of class.  Course projects will generally consist of reviewing one or more papers on a topic that makes use principles and tools discussed in the course.  Each project will be undertaking by two students (nominally one from BE 150, one from Bi 250).  Topic suggestions are posted [[BE 150/Bi 250b project ideas, Winter 2013|here]].  Students can also propose their own topic of student by preparing a 1-2 page proposal and submitting this to the instructors no later than 4 Feb for consideration.
Course project timeline:
* 1 Feb (Fri): [[BE 150/Bi 250b project ideas, Winter 2013|course projects]] posted on home page and announced in class
* 4 Feb (Mon): course project preferences due
* 6 Feb (Wed): project assignments available
* 20 Feb (Wed): discussion of course projects with TAs and others
* 4-13 Mar: course project presentations.  15-20 minutes per project + 5-10 minutes questions.
Course preference instructions
{{BE 150 project instructions, Winter 2013}}


=== Grading ===
=== Grading ===
The final grade will be based on biweekly homework sets.  The homework will be due in class one week after they are assigned. Late homework will not be accepted without prior permission from the instructor.  The lowest homework score you receive will be dropped in computing your homework average.
The final grade will be based on biweekly homework sets (75%) and a course project (25%).  The homework will be due in class approximately one week after they are assigned. Late homework will not be accepted without prior permission from the instructor.  The lowest homework score you receive will be dropped in computing your homework average.  The class project will be assigned and the end of the 5th week of instruction and project presentations will be scheduled for the last two weeks of class.


=== Collaboration Policy ===
=== Collaboration Policy ===
Collaboration on homework assignments is encouraged. You may  consult outside reference materials, other students, the TA, or the instructor.  Use of solutions from previous years in the course is not allowed.  All solutions that are handed in should reflect your understanding of the subject matter at the time of writing.
Collaboration on homework assignments and the course project is encouraged. You may  consult outside reference materials, other students, the TA, or the instructor.  Use of solutions from previous years in the course is not allowed.  All solutions that are handed in should reflect your understanding of the subject matter at the time of writing.  Your course project presentation to properly acknowledge all source materials.


[[Category:Courses]]
[[Category:Courses]]

Latest revision as of 18:49, 6 March 2013

Systems Biology

Instructors

  • Michael Elowitz (Bi/BE/APh)
  • Richard Murray (CDS/BE)
  • Lectures: MWF 10-11, 200 BRD

Teaching Assistants

  • Emzo de los Santos
  • Victoria Hsiao
  • Recitation: Fr 10-11, location TBD

This is the course homepage for BE 150/Bi 250b for Winter 2013. This page contains all of the information about the material that will be covered in the class, as well as links to the homeworks and information about the course projects and grading.

Lecture Schedule

There will be 2-3 one-hour lectures each week, as well as occasional one-hour tutorials, recitations or journal club.

Week Date Topic Reading Homework

1

7 Jan
9 Jan+
MBE/RMM 		Course overview, gene circuit dynamics
  • Principles in systems biology
  • Core processes in cells
  • Modeling transcription, translation and regulation using ODEs
  • Negative auto-regulation

Recitation section:

Bi 250b:

  • Alon, Ch 1: Introduction
  • Alon, Ch 2: Transcription networks : basic concepts
  • Alon, Ch 3: Autoregulation : a network motif

BE 150:

  • BFS Ch 1: Introductory Concepts (skim)
  • BFS Ch 2: Modeling of Core Processes
    • Section 2.1: Modeling Techniques (skim)
    • Sections 2.2-2.3: transcription and translation, transcriptional regulation
 HW1

2

13 Jan
15 Jan
MBE 		Circuit motifs
  • Feedforward loops (FFLs)
  • Phosphorylation cascades
  • Two-component signaling systems
  • Sequestration for ultrasensitivty

Recitation (17 Jan): sample problems

Bi 250b:
  • Alon, Ch 4: The feed-forward loop network motif
  • Alon, Ch 6: Network motifs in developmental, signal transduction, and neuronal networks

BE 150:

  • BFS Ch 2: Modeling of Core Processes
    • Section 2.4: post-transcriptional regulation
    • Section 2.5: cellular subsystems
 HW2

3

21 Jan
23 Jan*
25 Jan
RMM 		Biological clocks: how to produce oscillations in cells
  • Plant clocks/circadian rhythm
  • Synthetic oscillators (repressilator, dual-feedback oscillator)
  • Circadian clocks in cyanobacteria

No recitation

BE 150:

  • BFS Ch 3: Analysis of Dynamic Behavior
    • Sections 3.5: Oscillatory Behavior
 HW3

4

28 Jan
30 Jan
RMM 		Robustness
  • Chemotaxis and perfect adaptation
  • Fold change detection
  • Controls analysis of robustness

Recitation (1 Feb): sensitivity analysis

BE 150:

HW4
1 Feb Course projects posted. Instructions:
  • Each student should send e-mail no later than 4 Feb (Mon) with the following information
    • Course: (BE 150/Bi 250b/Audit)
    • Up to three project preferences (use titles from project listings)
    • Optional preferred partner (both students should e-mail identical preferences)
  • Students will work in pairs, with most teams consisting of a BE 150 student and a Bi 250b student
  • To propose your own project, please e-mail a 1-2 page proposal in addition to at least two project preferences selected from the list of course projects

5

4 Feb
6 Feb
MBE 		Noise
  • Random processes
  • Intrinsic and extrinsic noise
  • Stochastic modeling: master equation, SSA

BE 150:

HW5

6

11 Feb
13 Feb+
MBE 		Burstiness in gene expression and signalling
  • Birth-death processes
15 Feb+*
 Course project discussion with TAs

7

18 Feb
20 Feb
22 Feb*
25 Feb
RMM 		Patterning
  • Morphogenesis
  • Robust morphagen gradient
  • Proportionality and scaling
 HW6

NotchDeltaGui.m NotchDeltaGui2.m

8

27 Feb
1 Mar
RMM 		Fine grain patterns
  • Lateral inhibition
  • Notch-delta

9

4 Mar
6 Mar
8 Mar
Project presentations

10

11 Mar
13 Mar 		Project presentations


Course Description

BE 150/Bi 250b is a jointly taught class that shares lectures but has different reading material and homework assignments. Students in BE 150 are expected to have a more quantitative background and the course material includes a combination of analytical and conceptual tools. Students in Bi 250b are expected to have more knowledge of basic biological processes and the course material focuses on the principles and tools for understanding biological processes and systems.

BE 150: Quantitative studies of cellular and developmental systems in biology, including the architecture of specific genetic circuits controlling microbial behaviors and multicellular development in model organisms. Specific topics include chemotaxis, multistability and differentiation, biological oscillations, stochastic effects in circuit operation, as well as higher-level circuit properties such as robustness. Organization of transcriptional and protein-protein interaction networks at the genomic scale. Topics are approached from experimental, theoretical and computational perspectives.

Bi 250b: The class will focus on quantitative studies of cellular and developmental systems in biology. It will examine the architecture of specific genetic circuits controlling microbial behaviors and multicellular development in model organisms. The course will approach most topics from both experimental and theoretical/computational perspectives. Specific topics include chemotaxis, multistability and differentiation, biological oscillations, stochastic effects in circuit operation, as well as higher-level circuit properties such as robustness. The course will also consider the organization of transcriptional and protein-protein interaction networks at the genomic scale.

Textbook

The primary text for the BE 150 and Bi 250b is

 [Alon]  U. Alon, An Introduction to Systems Biology: Design Principles of Biological Circuits, CRC Press, 2006.

Students in BE 150 should also obtain the following notes (freely downloadable from the web):

 [BFS]  D. Del Vecchio and R. M. Murray, Biomolecular Feedback Systems (available online)
  • Note: these notes are being written and will be updated during the course
  • The public version is missing some copyrighted figures. These are available in the class version.
  • Class version (Caltech access only, 5 Jan 2013): TOC, Ch 1, Ch 2, Ch 3, Ch 4, Sec 5.2, App B, Refs

The following additional texts and notes may be useful for some students:

 [Klipp]  Edda Klipp, Wolfram Liebermeister, Christoph Wierling, Axel Kowald, Hans Lehrach, Ralf Herwig, Systems biology: A textbook. Wiley, 2009.
 [Strogatz]  Steven Strogatz, Nonlinear Dynamics And Chaos: With Applications To Physics, Biology, Chemistry, And Engineering. Westview Press, 2001.

Course project

All students enrolled in the course will be expected to participate in a course project, which will be assigned after the fourth week of class. Course projects will generally consist of reviewing one or more papers on a topic that makes use principles and tools discussed in the course. Each project will be undertaking by two students (nominally one from BE 150, one from Bi 250). Topic suggestions are posted here. Students can also propose their own topic of student by preparing a 1-2 page proposal and submitting this to the instructors no later than 4 Feb for consideration.

Course project timeline:

  • 1 Feb (Fri): course projects posted on home page and announced in class
  • 4 Feb (Mon): course project preferences due
  • 6 Feb (Wed): project assignments available
  • 20 Feb (Wed): discussion of course projects with TAs and others
  • 4-13 Mar: course project presentations. 15-20 minutes per project + 5-10 minutes questions.

Course preference instructions

  • Each student should send e-mail no later than 4 Feb (Mon) with the following information
    • Course: (BE 150/Bi 250b/Audit)
    • Up to three project preferences (use titles from project listings)
    • Optional preferred partner (both students should e-mail identical preferences)
  • Students will work in pairs, with most teams consisting of a BE 150 student and a Bi 250b student
  • To propose your own project, please e-mail a 1-2 page proposal in addition to at least two project preferences selected from the list of course projects

Grading

The final grade will be based on biweekly homework sets (75%) and a course project (25%). The homework will be due in class approximately one week after they are assigned. Late homework will not be accepted without prior permission from the instructor. The lowest homework score you receive will be dropped in computing your homework average. The class project will be assigned and the end of the 5th week of instruction and project presentations will be scheduled for the last two weeks of class.

Collaboration Policy

Collaboration on homework assignments and the course project is encouraged. You may consult outside reference materials, other students, the TA, or the instructor. Use of solutions from previous years in the course is not allowed. All solutions that are handed in should reflect your understanding of the subject matter at the time of writing. Your course project presentation to properly acknowledge all source materials.

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