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==Synthetic Biology==
===Engineering Living Matter===
'''The lab's goal is to make biology ''easy'' to engineer.''' Our research is largely student-initiated and driven.  Students and others have joined the lab from a wide-range of backgrounds including biology, chemistry, english, mathematics, physics, and all fields of engineering.  Reading our dissertations and research papers (below) is a great way to learn about the sort of work that the lab has been able to support, and provides good background and introductory materials as well as glimpses of future ideas and directions. You'll find that the lab has a strong interest in foundational technology development, that we pursue both experimental and theoretical work, and that we are interested in the applications of biological technologies tooIf you are searching for a passionate place to work on a new (or old) research idea that's relevant to synthetic biology then we would very much like to hear from you.
We are passionate about making living matter fully engineerable.  We don't consider this goal to be abstract or arbitrary, rather something that should be accomplished over the next few decades and that is absolutely central to enable all of humanity to flourish in partnership with Earth (10 billion happy people AND a healthy planet)See the following for additional high-level framing:


==Postdocs==
===Fine, But What Can I Do?===
*'''Jerome Bonnet''' (Stanford, October 2008 start)
People often struggle to parse our broad goal in ways that lead to specific opportunities, either as a potential student or postdoc here at Stanford or as a collaborator.  We share the same struggle; it's a big puzzle with many opportunities!  Practically, we have a few guiding principles that help us understand what projects and questions will be exciting to work on.  We tend to look for and support projects that require progress along two or more of these principles:
**''Genetically Encoded Memory,'' in progress


==PhD Students==
**'''The Humpty Dumpty Problem''' -- How can we get orders of magnitude better at composing integrated synthetic biological systems comprised of functional biomolecules?
*'''Francois St-Pierre''' (MIT class of 200?)
**'''The Swiss Watchmaker Problem''' -- Living systems are dominated by atomic-scale thermal noise yet, when so-selected, can realized incredibly precise dynamic behavior.  How can we best engineer precision dynamics within synthetic living systems?
**''Deterministic cell-fate selection during phage lambda infection'', or equivalent (in prep., Research Paper)
**'''Joy's Law''' -- Briefly, "most people work for other people."  So what do you do about this fact?  Only ~1 in 100,000 work for Larry Page, yet Larry benefits whenever someone links one web page to another, regardless of whether he pays them. How should Joy's Law practically ramify in biology and biotechnology?
*'''Barry Canton''' (MIT class of 2008, TBA)
**'''Biologization of Industry''' -- Many people default to a mindset of industrialization.  But, why naively inherit a metaphor that dominated 19th century Britain?  Biology is the ultimate distributed manufacturing platform. We are keen to explore and make true future biotechnologies that enable people to more directly and freely make whatever they need where-ever they are.
**''Engineering the interface between cellular chassis and synthetic biological systems'' ([URL pending, Dissertation])
**'''Real-Time Bug Debug''' -- Shouldn't it be possible to program and debug synthetic biological systems on the same physical time scale by which the biology operates?  Why do we have to grow up and sacrifice billions of cells every time we want to see if a simple recombinant plasmid works?
**''BBa_F2620, an engineered cell-cell communication receiver device'' (in press, Research Paper)
**'''Keep Synthetic Biology Weird''' -- Most of biotechnology hasn't yet been imagined let alone made true. Why settle?
**''A virtual machine for synthetic biology'', or equivalent (in prep., Research Paper)
*'''Jason Kelly''' (MIT class of 2008, TBA)
**''Tools and reference standards for evolving engineered biological systems'' ([URL pending, Dissertation])
**''Measurement kits and reference standards for characterizing BioBrick promoters and ribosome binding sites'', (submitted, Research Paper)
**''Programmed selection and preferential promotion of disadvantaged bacteria'', or equivalent (in prep., Research Paper)
*'''Reshma Shetty''' (MIT 2008 PhD, w/ Tom Knight as lead advisor, TBA)
**''Applying engineering principles to the design and construction of transcriptional devices'' ([http://dspace.mit.edu/handle/1721.1/41843 Dissertation])
**''Engineering BioBrick vectors from BioBrick parts'' ([http://www.jbioleng.org/content/2/1/5 Research Paper])
**''A synthetic biology approach to reprogramming bacterial odor'' (submitted, Research Paper)
**''Signal levels, load, and error rates in engineered transcriptional devices'', or equivalent (in prep., Research Paper)
*'''Samantha Sutton''' (MIT class of 2008 PhD, TBA)
**''Engineering phosphorylation-dependent post-translational protein devices'' ([URL pending, Dissertation])
**''Engineering phosphorylation-dependent post-translational protein devices'' (submitted, Research Paper)
**''Signals and specifications for a family of phosphorylation-dependent devices'', or equivalent (in prep., Research Paper)
*'''Ty Thomson''' (MIT class of 2008 PhD, moving to Epitome Biosystems)
**''Models and analysis of yeast mating response: Tools for model building, from documentation to time-dependent stimulation'' ([URL pending, Dissertation])
**''Tools for making systems biology models more scientific'' (in prep., Research Paper)
**''Mechanics, controls, and models of yeast mating response'' (in prep., Research Paper)
**''Measurement and analysis of protein abundances suggests tradeoff between signaling system output and dynamic range'' (in prep., Research Paper)
*'''Sri Kosuri''' (MIT class of 2007 PhD, now at a very low-profile biotechnology startup)
**''Simulation, models, and refactoring of bacteriophage T7 gene expression'' ([http://dspace.mit.edu/handle/1721.1/39912 Dissertation])
**''Refactoring bacteriophage T7'' ([http://www.nature.com/msb/journal/v1/n1/full/msb4100025.html Research Paper])
**''TABASCO: A single molecule, base-pair resolved gene expression simulator'' ([http://www.biomedcentral.com/1471-2105/8/480 Research Paper])
**''Measures and models of bacteriophage T7 gene expression'' (in prep., Research Paper)


==MS Students==
===Any Specific Examples===
*'''Alex Mallet''' (MIT class of 2007, now at Microsoft, Inc.)
Here are some examples of recent or ongoing projects that recombine various aspects of the above:
**''Analysis of Targeted and Combinatorial Approaches to Phage T7 Genome Generation'' ([http://dspace.mit.edu/handle/1721.1/35880 Thesis])
**Rewritable genetic logic and data storage (many parts, precision dynamics)
*'''Jeff Gritton''' (MIT class of 2006, now at Harvard Law School)
**Engineering lineage-agnostic cells (even more parts, many people, precision dynamics)
**''Architecture and evolutionary stability of yeast signaling pathways'' ([http://dspace.mit.edu/handle/1721.1/37258 Thesis])
**Enabling wood-fungus to grow many things (distributed manufacturing, keeping it weird)
**Growing arbitrary patterns (many parts, precision dynamics)
**What are all the atoms inside a cell? (many parts, new tools)
**Robobench (aka "[https://youtu.be/s4WgCs-tH3o Alexa, do this experiment for me!]") (new tools, many people)


==Undergraduate Students==
===Research Background & Context, Additional Materials===
*'''iGEM 2008''' [http://openwetware.org/wiki/IGEM:MIT/2008 Project TBD] (MIT team's wiki)
The many and diverse dissertations from past students in the lab, their peer-reviewed published articles, and our written perspectives and other published projects are all [[Endy:Reprints | freely available online]]. We hope that students who are interested in exploring and taking forward their own research projects in the lab will be informed and inspired by the curiosity and independence of past student's work. We hope that others who are interested in understanding, contributing to, or constructively criticizing the lab's work make full use of our published record.
*'''iGEM 2007''' [http://openwetware.org/wiki/IGEM:MIT/2007 Bioremediation] (MIT team's wiki)
*'''iGEM 2006''' [http://openwetware.org/wiki/IGEM:MIT/2006 Eau d'E. coli] (MIT team's wiki)
*'''iGEM 2005''' [http://openwetware.org/wiki/IGEM:MIT/2005 Biosensing] (MIT team's wiki)
*'''2004 Synthetic Biology Competition''', [http://images.google.com/images?hl=en&q=2004%20synthetic%20biology%20competition&um=1&ie=UTF-8&sa=N&tab=wi see Google] (web search)
*'''IAP 2004''' [http://parts.mit.edu/wiki/index.php/IAP2004:Polkadorks Polkadorks] (an "typical" project)
*'''IAP 2003''' [http://web.mit.edu/newsoffice/2003/blinkers-0226.html MIT News Report]

Latest revision as of 15:17, 4 August 2017

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Engineering Living Matter

We are passionate about making living matter fully engineerable. We don't consider this goal to be abstract or arbitrary, rather something that should be accomplished over the next few decades and that is absolutely central to enable all of humanity to flourish in partnership with Earth (10 billion happy people AND a healthy planet). See the following for additional high-level framing:

Fine, But What Can I Do?

People often struggle to parse our broad goal in ways that lead to specific opportunities, either as a potential student or postdoc here at Stanford or as a collaborator. We share the same struggle; it's a big puzzle with many opportunities! Practically, we have a few guiding principles that help us understand what projects and questions will be exciting to work on. We tend to look for and support projects that require progress along two or more of these principles:

    • The Humpty Dumpty Problem -- How can we get orders of magnitude better at composing integrated synthetic biological systems comprised of functional biomolecules?
    • The Swiss Watchmaker Problem -- Living systems are dominated by atomic-scale thermal noise yet, when so-selected, can realized incredibly precise dynamic behavior. How can we best engineer precision dynamics within synthetic living systems?
    • Joy's Law -- Briefly, "most people work for other people." So what do you do about this fact? Only ~1 in 100,000 work for Larry Page, yet Larry benefits whenever someone links one web page to another, regardless of whether he pays them. How should Joy's Law practically ramify in biology and biotechnology?
    • Biologization of Industry -- Many people default to a mindset of industrialization. But, why naively inherit a metaphor that dominated 19th century Britain? Biology is the ultimate distributed manufacturing platform. We are keen to explore and make true future biotechnologies that enable people to more directly and freely make whatever they need where-ever they are.
    • Real-Time Bug Debug -- Shouldn't it be possible to program and debug synthetic biological systems on the same physical time scale by which the biology operates? Why do we have to grow up and sacrifice billions of cells every time we want to see if a simple recombinant plasmid works?
    • Keep Synthetic Biology Weird -- Most of biotechnology hasn't yet been imagined let alone made true. Why settle?

Any Specific Examples

Here are some examples of recent or ongoing projects that recombine various aspects of the above:

    • Rewritable genetic logic and data storage (many parts, precision dynamics)
    • Engineering lineage-agnostic cells (even more parts, many people, precision dynamics)
    • Enabling wood-fungus to grow many things (distributed manufacturing, keeping it weird)
    • Growing arbitrary patterns (many parts, precision dynamics)
    • What are all the atoms inside a cell? (many parts, new tools)
    • Robobench (aka "Alexa, do this experiment for me!") (new tools, many people)

Research Background & Context, Additional Materials

The many and diverse dissertations from past students in the lab, their peer-reviewed published articles, and our written perspectives and other published projects are all freely available online. We hope that students who are interested in exploring and taking forward their own research projects in the lab will be informed and inspired by the curiosity and independence of past student's work. We hope that others who are interested in understanding, contributing to, or constructively criticizing the lab's work make full use of our published record.

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