Kristala L. J. Prather (MIT) Part 1: Introduction to Synthetic Biology and Metabolic Engineering

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My name is Kristala Prather, or Kris. I'm an associate professor

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in the Department of Chemical Engineering at MIT

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and today I'm going to talk to you about metabolic engineering and synthetic biology,

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two fields in which I work and which have a very, very strong influence from biology.

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If you think about biology in the world around you,

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if you look around at nature, you'll see a lot of beauty and a lot of diversity.

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You might see feathers on a peacock.

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You can look at a nautilus shell

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and see the structures, the symmetry, all of the details that are there.

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You might look at the wing of a butterfly, for example,

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and you see colors, and patterns, and lots of richness,

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or even as you look at the leaf of a tree, you'll see lots of wonderful details and structures.

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And all of that we see on a very large scale,

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thinking about how nature gives us a lot of beauty, a lot of diversity,

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a lot of function. If we actually look deeper, though, at that same leaf that came from the tree,

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you'll notice that as you go closer and closer in scope,

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or in scale, you'll see details that you couldn't see before.

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You'll see that that leaf is actually composed of a series of individual cells,

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and even within those cells, you see even smaller structures, structures we call organelles

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that are all giving you this macroscopic property, or phenotype you see,

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that you recognize as a leaf. And when we look at structures like this,

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what we really realize is that it's really all about the DNA.

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Everything that gives us what we see from nature,

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that gives us the color, the structure, and the function,

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the things that we think are beautiful, and the things that we think are useful,

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really come back down to the DNA.

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And it's really this focus on the DNA which is a hallmark of synthetic biology.

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Synthetic biology has been defined in many different ways,

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and it's actually interesting to think about some of the older definitions.

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One of my favorite actually comes from 2000,

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in a publication called Chemical and Engineering News.

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And in that publication, synthetic biology was defined in the way that you can see on the screen now.

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In particular, there's a focus on the use of non-natural, synthetic molecules.

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That is, things that aren't really of biological origin,

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and being able to use those molecules in order to give you function.

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Ok, so the keys here are things being non-natural,

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and the function that you would get in biological systems.

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In the 10 to 15 years since this definition came out,

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really synthetic biology has changed and the work that's going on in synthetic biology has become much broader.

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And the definitions that are used more commonly than this first one that's given

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are the following. One is that synthetic biology is the design and construction

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of new biological parts, devices and systems.

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And those parts, devices and systems are words that actually come from engineering.

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So, one of the ways that we also think about synthetic biology, then,

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is to re-design existing, natural biological systems for useful purposes,

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which is really what engineering is all about.

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Engineering is about design, it's about re-design, for useful purposes,

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and that is, for specific applications.

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So, you can see in just looking at how the definitions have changed,

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from one in 2000, to the working definitions that are used more today,

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we don't have to focus on unnatural pieces giving us natural or biological functions,

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but rather, there's more of a focus on taking what nature has given us,

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repurposing or re-using that for intentions that we as engineers

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actually design.

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So, for us, within what's called the Synthetic Biology Engineering Research Center,

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this also a center in which I work,

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we have what I describe as a practical definition of synthetic biology.

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And that is synthetic biology is the effort to make biology easier to engineer.

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And it's this fusion of engineering principles with biology

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that really gives synthetic biology its heart and its purpose.

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And here are some of the engineering principles that we think about as engineers.

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Things like design; by design, what we mean in that case is saying,

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I want to build a certain machine that has this specific function,

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and I know how to draw out or sketch out a way in which I get there.

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If I think about modeling in an engineering sense, modeling is really about mathematics.

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That means I can write an equation that actually will support my design,

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and it represents as well the understanding I have of the underlying principles

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that allow me to have that design.

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And then we have these principles of characterization and abstraction,

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and that really means the practice of going through your design,

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what you have actually designed, to the point where you build that and then you test it,

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and in the process of testing it, you characterize the system as a whole,

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as well as the individual parts.

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And finally, abstraction means actually being able to take, now,

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a larger view and if go back to my definitions of parts and devices,

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it means not always having to look at the very specific level of detail,

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but knowing that if I want some bigger function,

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I could encode that in a simpler way.

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So, the key technology in synthetic biology for all of this

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is DNA synthesis.

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And DNA synthesis is really about having biology or biological function

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but taking a step where you really remove biology from that process.

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Here's actually an example of how that works;

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so if we think about biology and think about DNA,

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I've already told you that all of biology is really about the underlying DNA,

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there's a sequence of A's and G's and C's and T's

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in the natural system that is the DNA and how those strings of nucleotides, as they're called,

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are strung together, actually gives us the function that we're interested in.

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So, I may study the biological system,

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and then figure out, what is that sequence that gives me the function that I actually want,

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or the function that I'm looking to be able to now design,

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into a new system,

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I can then go now to a computer, store that information digitally

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and go through the design process that I talked about

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where I can specify now my own sequence of those A's and G's and C's and T's,

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to give me the function that I want and then rather than having to go back into the biological host,

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I can take advantage of DNA synthesis to make the DNA that I want,

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without actually having to go back into a biological host to do this,

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but by rather recognizing that those sequences of A's and G's and C's and T's

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are just chemicals and those chemicals can be synthesized without biology,

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and they can be strung together without biology.

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I can though, once I've made those, put those, put them back into a biological host,

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and that gives me then the function, as far as biology is concerned, that I'm interested in.

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So, this is a nice representation of this type of process,

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from Seed magazine, this was drawn by Drew Endy,

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who's now at Stanford University,

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and it's just a cartoon representation of exactly what I described,

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where you start at the beginning, with actually defining what that sequence is,

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of the A's, the G's, the T's and the C's, from now a natural host,

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you can then reconstruct those now as synthetic DNA,

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and then this abstraction is actually the line that I'm crossing here,

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where we think about now that I have that DNA, if you will,

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encoding a function that I'm interested in,

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and that may result in taking a certain input, converting it to a different output,

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or stringing together different devices here now,

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one that may have one function, one that has another function,

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and having now a composite device,

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as we would call it, that would give us this feature that we're interested in.

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And I might be able to string these together in many different ways,

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in order to get different kinds of functions now,

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putting two devices together, or maybe multiple devices together that may give me a certain structure,

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or feature, that has the function that I'm interested in.

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So, if we now think about some examples of how we could make this work,

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that is designing different pieces of DNA such that we put them together and get different functions,

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you can see a movie that's playing on the screen now

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where there are individual cells that are growing, they're dividing,

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and you can see that they're actually blinking.

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They're sometimes having light turned on and sometimes having light turned off.

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This is actually an example of something that's called an oscillator,

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that process of turning on and off means that the expression, in this case of this protein,

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is oscillating. And that feature of being able to have a system now that blinks, if you will,

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is something that can be encoded in the DNA,

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by taking advantage of different parts,

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for example, what's shown here is a Tet repressor,

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a Lac repressor and a lambda repressor,

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that all work together in a way that you have now a system that gives you sometimes the gene expression being on,

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that is the light is on,

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and sometimes the light being off.

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So, this is an example of how a specific function, that is, oscillation, or blinking,

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could be designed, there were models that were built in this system,

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that is mathematical equations to describe how that had to happen,

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and then you could actually build in those pieces with DNA,

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these circles here are plasmid DNA, and the output, finally, is GFP.

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And that's actually the protein that gives you the lightness or the darkness,

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that is the blinking pattern.

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Here's a different example of being able to string those pieces of DNA together

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in order to get a particular type of function that we want,

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and in this case, the goal was to have effectively a bacterial photography system.

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And in this case, there was DNA taken from many different pieces,

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there was something called phytochromes, or light sensors, from an organism called Synechocystis.

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There was something called an osmoregulation system,

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and this is really just a way to make proteins from E. coli

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and then a protein called LacZ, which has really been around for quite a long time,

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in biological standards, since the late 1970's,

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which allows you to either have color or not have color.

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And you can see now in the pictorial diagram here the way this is supposed to work

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is that when light is present, you're going to have now activation of this osmoregulation system,

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that gives you an output which in this case is going to be black.

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If there's no light that's present, then you'll have an output that's going to be light.

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So, we can have a table that's written here, that would be our design table that says,

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the first condition that we want is a light condition,

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and in that case the LacZ is going to be low,

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and the result is a light color.

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The second condition now would be a condition that's dark.

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In that case, the LacZ output is going to be high, and that's actually going to give us a dark color.

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How does this actually work?

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Well, what you can do now is to create a mask where if you look on the left-hand side here,

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what's shown is 'Hello World,' where everything now that's white would be white,

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and you would actually be able to shine light through the words hello and world

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and you can see next to that then the result of what happens.

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When the light output was low,

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you have no color, when it's high, you have a dark color,

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and that actually gives you now, in bacteria, bacteria that are dark that say hello,

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bacteria that are dark that say world, and will actually recapitulate, or give you that image,

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much like a camera would.

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Here's an example of this same system now, taking it a little bit further,

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with images that are even more complex.

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And you see in this case, now, from a paper published in Nature from the same group,

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that you can actually end up with a picture of a bacteriophage

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based on this same principle of having a mask and exposing light,

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and in the places where the light is there, you have a dark color,

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when it's not, you have a lighter color.

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And you can even go even further and make a picture of Andy Ellington,

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who is the professor in whose lab this was developed.

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These are examples, now, of being able to put biology, or biological pieces together

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for functions, but as engineers, we often want to think about how do we actually solve problems,

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whether they be problems in healthcare, in energy or the environment.

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And so I'd like give you a few examples of applications

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that are emerging from synthetic biology

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where researchers are actively working to build these biological systems

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to address some of these global problems.

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And the first example I'm going to give you is from the lab of professor Ron Weiss

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who's in biological engineering at MIT,

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and he's been looking at the issue of diabetes.

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There are two types of diabetes: type I and type II.

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In type I diabetes, what actually happens is that your body destroys

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the cells that make the insulin that you need

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to control your glucose levels in the blood.

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And so, you may have seen an image like this before,

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where patients who have diabetes have to check their blood glucose levels,

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they actually have to prick themselves to extract blood,

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expose that to a glucose meter, and then based on their glucose levels,

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decide to dose themselves with insulin or not.

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Well, if we say the problem is in the pancreas,

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the question is, can you actually engineer an artificial pancreas

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or engineer cells that will perform the function of the pancreas

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so that you now no longer need to have this process of measuring blood glucose levels,

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and then actually dosing yourself with insulin.

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So, what Professor Weiss is doing is looking at engineering stem cells

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to be able to stay in an undifferentiated state

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to then sense when the presence of these insulin producing cells has gone very low,

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and then to differentiate and produce new cells, only up to a point,

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and then to stay quiet again, or quiescent,

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such that you maintain this population of cells

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that can spontaneously produce new insulin producing cells whenever your body needs them.

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That's an application in health.

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There are other applications, for example, in the environment,

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and this is actually a significant problem in agriculture,

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which is that you have to provide a lot of nitrogen

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to plants in order to get them to grow.

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Proteins, for example, have a lot of nitrogen in them, and so it's necessary to provide that

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because it can be difficult to actually extract it in a way that's usable.

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But it turns out that there are certain organisms that will actually live on the roots of plants

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that have the ability to fix nitrogen, that means they can take nitrogen from the atmosphere,

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and convert it into the kind of nitrogen which is useful for plants.

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And so Professor Chris Voigt, who's in biological engineering at MIT

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has been looking at whether or not you could take that ability to fix nitrogen, as we call it,

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that is to take nitrogen out of the atmosphere and put it into a usable form for plants,

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can you actually take that capacity from these microorganisms and put it directly into the plants

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so that you actually have a need for much less fertilizer in the environment.

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Here's a third example of a way that now a group of students

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were looking at using synthetic biology to be able to really address a critical problem in both health and the environment.

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And this is actually part of the iGEM program, you can see the URL for that at the bottom of the screen,

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where iGEM stands for international genetically engineered machines

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and the iGEM competition is an opportunity for students from all over the world to come together

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and decide for themselves, here's a problem that we want biology to try to solve

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and then to go through this process of designing, modeling, characterizing and building these systems

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to see if they can address those problems.

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The University of Edinburgh iGEM team in 2006

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decided to try to tackle the problem of groundwater contaminated by arsenic in Bangladesh.

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They studied the problem, found that it really is significant,

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in terms of a lot of the groundwater being contaminated

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and there not being really any easy systems for villagers to know whether or not a source of water

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was safe to drink or not.

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So, they decided to take pieces from biology that naturally responded to arsenic

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and to build a sensor that would tell them whether or not there was arsenic in the water or not.

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And it was actually designed after something you may have seen,

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which is just a sensor that tells you, for example, the chlorine level and the pH level in a pool.

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The idea being that you could take a sample of water, you could add now this sample of bacteria,

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E. coli in this case, that could detect the arsenic.

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If the arsenic was present at a certain level, the colors would become very bright,

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and you would know that that water was not safe to drink.

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Now, I want to actually switch gears a little bit and talk about metabolic engineering,

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which is an area that's been around for awhile,

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but we're increasingly seeing a merger between principles of metabolic engineering and those of synthetic biology.

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And metabolic engineering is really about the fact

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that biology is very good at doing chemistry;

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that is, from biological systems, you can get a wide range of chemical molecules

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that have useful functions. And I've shown two of them here.

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The first one is called caspofungin, and then there's another one that's shown here that's called lovastatin.

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Caspofungin is actually an antifungal organism, that is, it's used to treat fungal infections,

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and lovastatin is one of the first cholesterol lowering drugs.

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So, you've heard about statins, perhaps, and there are lots of them now,

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but lovastatin was one of the first that was discovered.

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Both of these are naturally produced by biological systems

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and they've been very useful as natural products, we would call them in this case,

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to have therapeutic functions. And traditionally, when we think about biology being used for chemistry,

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it's usually for molecules like this.

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If you look at caspofungin, for example, you can see that it has complexity

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both in terms of just the number of atoms that it has, it's a pretty big molecule,

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and then you'll also see a lot of these hydroxyl groups, you'll also see chiral centers,

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which are shown now by the bold, or the arrows that go back and forth.

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And so traditionally, if you think about how synthetic chemistry works

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it's not that chemistry can't make a molecule like that,

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but the yields would be very low, it would take a large number of steps

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to get to that compound, whereas you have a biological organism

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that can make these molecules very easily.

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And so it's molecules like this that traditionally have been made by biology.

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Now, I want to introduce as well a couple of other molecules, one being an amino acid, glutamic acid,

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and the other being an organic acid, malic acid.

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And these are also molecules that biology can make efficiently

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using biological means as opposed to chemistry.

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And what I mean by that is they can be produced commercially through fermentation.

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So, you have an organism that's capable of making these compounds,

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you can grow them up in very large quantities,

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and now you have a product that you can bring to market.

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What's true about all of these molecules is that they are produced by organisms

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that naturally make them and the goal when metabolic engineering first arose

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was to figure out how do you actually get these organisms

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to do what they do better.

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And better, in an engineering extent means to make more of the molecule, to make it faster,

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and to make it more efficiently and the efficiency part, it's typically considered as yield.

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That is, how much of the starting material that goes into the system

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ends up in the product that you're interested in.

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So, I have a graduate student who once came up with this analogy, or this cartoon,

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to describe how metabolic engineering actually works in terms of improving these natural producers.

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And what you see here is a maze, where you have this poor mouse, Wemberly,

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that's lost its pet rabbit Petal, and Wemberly has to figure out how to get to Petal.

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And you can see, as with any maze, there are a number of different starting points

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that the mouse could use in order to get to the end point.

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However, we know not all of those are going to be productive.

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So, with metabolic engineering, what you want to do is to remove those routes

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that are going to be non-productive.

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That means to actually knock out, or delete, competing pathways.

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Pathways that would actually take your substrate, your intermediate or your carbon

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a place that you don't want it to go.

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The other thing that you might want to have in order to have this faster objective met

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is a little bit of a stimulation or motivation

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for the enzymes to be overexpressed.

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And overexpressing those enzymes, you can increase the amount of a limiting enzyme

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in order to get more of that through the system.

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And now again, in our cartoon fashion, what that means is encouraging the mouse to run a little bit faster

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and to get through the maze quicker than it otherwise would.

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So, I finally want to introduce just as background two other molecules that are interesting

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both from a metabolic engineering and a synthetic biology standpoint.

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And these are 1,3-propanediol and artemisinic acid

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and you can see on the slide the uses for them.

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1,3-propanediol, or PDO, as it's called, is an industrial chemical that's also used for materials production,

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and artemesinic acid is a precursor to an anti-malarial drug.

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Now, these are also compounds that are produced by biology,

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meaning that we can make them through fermentation,

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that is growing up a large number of microorganims to produce the compound that we're interested in.

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They're also natural products, meaning that they're naturally produced by organisms.

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But the difference between these two molecules and the first four examples that I gave

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is that those molecules are produced naturally by one particular host,

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but it's actually a different host that's been able to be used to have them produced economically.

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And this allows us now to think about that DNA that we talked about, in terms of moving that around,

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to be able to move it to reconstitute natural pathways in heterologous hosts,

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or in hosts that don't normally contain that pathway.

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Here's actually an example of doing just this thing.

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So, the artemisinic acid that I told you about is a precursor to the drug that's shown here,

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which is called artemesinin. It's naturally produced in a plant that's called Artemisia annua

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and the goal is to be able to have, rather than that plant, a yeast cell

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make this same compound. The reason for that is that you can put yeast cells into a factory

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that looks much like factories that you may have seen before,

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or, if you think about yeast and fermentation, this might actually be a brewery,

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or a beer manufacturing unit.

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And you can't take plants and actually scale them up in that same way.

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Instead, you have to plant plants in the ground,

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and wait for the proper amount of sunlight and nutrition in order for them to grow.

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So, if my goal is to actually have a compound that's produced in Artemisia annua,

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to have that be produced in a yeast, so that I can put it into a factory,

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what that really means is identifying the DNA that encodes for those enzymes

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that gives me the chemical that I'm interested in. I now can go through this process that I talked about before,

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of sequencing that DNA and then synthesizing the DNA to get just those pieces that I need,

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and then I can move that DNA now into my unnatural, or my heterologous host,

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and that host, once it's properly engineered, is able to make the compound that I'm interested in,

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and I can actually grow it up now in a large factory.

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And this is work that's been done by Professor Jay Keasling, in chemical engineering at UC-Berkeley.

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So, the work that's done in my lab is really focused on expanding this capacity of biology

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to do chemistry. And we're motivated by the diagram that's shown here,

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where if we think about the materials that we get in our world today,

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where they come from and what they're used for, most of it comes from crude oil as the input,

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and the outputs are things that you're familiar with, which include fuels,

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which I think is mostly what we think about in terms of oil being used for,

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but also quite a large bit of petrol chemicals.

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And these are actually the molecules, olefins and aromatics are highlighted here as examples,

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that are used for polymers, for resins, for adhesives, et cetera.

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That is, those are molecules where the chemicals that are being produced

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are being used for their mass properties, or their properties as chemicals

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and not for their energetic properties, which is what we use them for for fuels.

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And we've talked a lot in this country and across the world

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about replacing crude oil as the input for this process,

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and instead we can think about creating what we might describe as a bio refinery,

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where the input in that case, rather than being oil, is glucose or other sugars,

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that might come from biomass, in the same way that we now want to be able to make biofuels,

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we want to be able to make more chemicals,

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that is, the same chemicals that give us the function that we're used to from petrochemicals,

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we want to be able to access those from biomass as well.

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In the second part of my talk, I'm actually going to give you examples from my lab,

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where we focus on exactly this, that is, building new kinds of chemical molecules

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from biology in different ways that really take advantage of the key principles of synthetic biology,

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but also are very firmly rooted within metabolic engineering as well.

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So, this is actually our vision of how that happens, this is a cartoon representation from an artist at MIT,

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where really what we're looking at doing in expanding the capacity of biology to do chemistry,

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is to think about these microbes as they were, this is an E. coli representation,

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as little chemical factories, where we can now, inside the cell, engineer different pathways

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to make different products and that same image that I showed you before

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of a large factory, we can think about that on a greatly, greatly magnified scale

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or a greatly miniaturized scale, I should say, in terms of having now small microbes give us this same capacity.

24:44

So, let me give you my final thoughts about the field of synthetic biology

24:48

and a little bit about metabolic engineering. Synthetic biology is a very diverse field

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and it's actually composed of very diverse individuals as well,

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and so people like myself, who work in metabolic engineering are in that field,

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those who are trained as electrical engineers, as computer scientists, as biological engineers,

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as physicists, they are a lot of different people in this area who are looking at how do you actually use DNA

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in order to get important functions of interest to solve the problems that we have to solve in the world.

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The problems that are being worked on are very diverse problems;

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I gave you examples that come from health, from the environment, from energy,

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and again, this diverse set of people are working on this diverse set of problems

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and are also taking diversity of approaches towards solving those problems.

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And I would say that the goal for all of us as we go through this

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is to actually make biology easier to engineer,

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so that we really can bring solutions to some of our most pressing global problems.

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In the second half of my talk, I'll talk much more about examples from my lab,

25:44

but this is my overview for metabolic engineering and for synthetic biology.