[ Music ] >> Jenny Montooth: If only there was a good way to use genomics to find a good use for all these strawberries. >> Eric Green: Are you thinking what I'm thinking? >> [DNA Extraction!!!] >> Eric: Luckily you only need household items to do that. Otherwise, it would take us forever to set up but let's get going. [ Background Sounds ] >> Jenny: Okay, well it's super convenient. You had a craving for strawberries. They're really easily to extract DNA from. We'll be experts in strawberry and DNA. >> Eric: Do you know how many copies of the genome that each strawberry cell has? >> Jenny: No, how many? >> Eric: Eight. >> Jenny: Eight? >> Eric: Eight, 4 times more per cell than humans, so purifying DNA from a strawberry is really easy because it has so much DNA in it. >> Jenny: Oh, that's a lot. >> Eric: Yeah. >> Jenny: Awesome. >> Eric: It's sure awesome, no time to waste, let's use some science. >> Jenny: So let's just make sure we have all the materials we need. >> Eric: Yeah, you know, it's always good to get organized. >> Jenny: Agreed. So first, 1 resealable plastic bag. >> Eric: So I tend to use the small ones, you can use the big ones, but small ones work really well. >> Jenny: You're the experts so I will listen to that. >> Eric: Okay. >> Jenny: Two strawberries. >> Eric: Two strawberries. >> Jenny: Very important. >> Eric: Two. And if I remember right, it's actually very good to take off the green stems and get rid of those. >> Jenny: Correct. >> Eric: Okay. >> Jenny: And you can use fresh or frozen. Two teaspoons of dish detergent. >> Eric: So we have the dish detergent, put that aside. >> Jenny: Okay. >> Eric: And we have a teaspoon for measuring it. >> Jenny: Perfect. Alright, 1 teaspoon of salt. >> Eric: So here's a teaspoon for measuring and here is the salt. >> Jenny: Great. Okay, a half cup of water. >> Eric: So here we have a measuring cup, [inaudible] half a cup of water. I'll just sit that here. >> Jenny: Perfect. Okay, 2 plastic cups. >> Eric: Got those. >> Jenny: Got those right here. >> Eric: Okay. >> Jenny: One coffee filter. >> Eric: [inaudible] we actually have an extra but yes I have a coffee filter. >> Jenny: You never know. >> Eric: Yeah. >> Jenny: Might need 2. Half cup of rubbing alcohol, we've got that right here. >> Eric: Yep. >> Jenny: Got to be careful with that. One coffee stirrer. >> Eric: And I got 2 just in case we need an extra. >> Jenny: Wonderful. >> Eric: There you go. >> Jenny: And probably most importantly, 1 scientist or in our case, 2 scientists. >> Eric: Alright. >> Jenny: Yes. >> Eric: Okay, so you take the strawberries and what you have to do is to basically break up the strawberries first because then in the next step we're going to break open the cells that are in the strawberries to release the DNA. But to sort of help that process along, you really got to unfortunately be a little mean to your strawberries, so you put them in the plastic bag and you seal up the plastic bag and then you're going to gently just want to start smashing those strawberries and as best you can. Now there's lots of techniques that can be used for this. You don't want to get too violent because if you do, you could spray strawberries all over your kitchen table or all over yourself. But at the same time, you have to really work it good as much to get sort of strawberry puree. We just keep getting this to the point that all the big pieces are broken up and in doing so, you will then have it to a point where you can then go to the next step where you're going to break open then individual cells in strawberries and let the DNA come floating into solution. Here's the thing, in this bag are smashed up strawberries with a bunch of individual cells in them. And maybe one way to think about is like a water balloon and that's the cell and what we need to do is to break open that water balloon so that the DNA will come floating out. Now like a water balloon like you might use a nail to pop it but for this, what you do if you're dealing with a cell, is you use a detergent like detergent you use for cleaning your dishes >> Jenny: Like this one here. >> Eric: So we're going to make a solution that's going to both have detergent in it but it's also going to have other things like salt and water that make the DNA happy and comfortable floating around inside of a cell. >> Jenny: Cool. >> Eric: So that's why we'll make this what we call an extraction liquid, okay? >> Jenny: Little concoction sounds great. >> Eric: So I think you start at 2 teaspoons of the detergent. >> Jenny: Okay, sounds great. You want some? >> Eric: No, no I already had breakfast. >> Jenny: Okay, just want to check, looks good though. Okay, 2 of those, 1 teaspoon of salt. >> Eric: Yeah, maybe you can use a different teaspoon. >> Jenny: Yes, good thing I have 2. >> Eric: Yep. >> Jenny: Alright. Perfect. >> Eric: And then remember we have that half a cup of water-- >> Jenny: Yes. >> Eric: that was poured to the very top. >> Jenny: I'm going to meet you halfway. >> Eric: Alright, thank you very much and then I'll just pour it in using my skills as a scientist and there you go. And now just shake it up a little. >> Jenny: [inaudible] a little shake. >> Eric: Yeah, yeah and all you're really wanting to make sure to do is to make sure the salt gets into solution and that detergent sort of gets evenly dispersed throughout. >> Jenny: Okay. >> Eric: Okay, so that's our extraction liquid. >> Jenny: Cool. >> Eric: So now we're basically going to use that detergent like a little pin to pop the water balloons. Use the detergent to break open those strawberry cells. I'll open this up. >> Jenny: Let's do it. >> Eric: You can just pour it in. >> Jenny: Okay. >> Eric: And there we have it. And so now you seal it. Now here you can't smash, you don't even want to smash because, of course, if you really start smashing then you really spew out the liquid and that would [inaudible] and actually the other thing is you don't want to be too tough with this because otherwise you'll get a lot of bubbles. But you just want to sort of work this around just like you're making a smoothie by hand. And so but here's the thing is that while all the DNA is now collecting in the liquid, if you look in there, you have a lot of other stuff that's in the way. Now scientifically, we might refer to that as cellular debris but you know it's just you know strawberry schmutz and you got to get rid of that strawberry schmutz and so that's why we use a coffee filter. It's now time to get rid of this schmutz and get the liquid that'll contain the strawberry DNA, so [inaudible] you can fold that for me. >> [inaudible]. >> Eric: I'm going to use this as a filter. Now you can use a coffee filter, sometimes you could use gauze if you happen to have some gauze in your house. You just do whatever it takes to filter out all that schmutzy stuff that was in the strawberries and just let things slowly leak through, seep through like you're making drip coffee. So when most of the liquid has filtered through, what's good is to just remove that filter that contains all that strawberry schmutz and we can just put it on the side, we don't need that anymore. >> Jenny: Alright. >> Eric: So this is basically the extraction liquid, which has the insides of all the cells of those strawberries including the DNA. And in order to get the DNA to come out of solution, we do a scientific step which is called precipitation-- >> [inaudible]. >> Eric: which is basically a way of getting a compound or molecule to sort of come out from being in the liquid state to being in a solid state. To do that, we use this rubbing alcohol-- >> Jenny: Alright. >> Eric: which you often want to have it be a little bit cold and I know this was in the refrigerator and that's good. You just want to add a equal amount, so what I always do is I just sort of estimate where my finger is as sort of the equal amount and you can just pour the alcohol up until about that amount-- >> Jenny: Okay. >> Eric: and a little more [inaudible] that's good. >> Jenny: Okay. >> Eric: [inaudible] like that. And then what you want to do is not be overly harsh with this but you can sort of see there's almost like a layer, the alcohol's a bit on top-- >> [inaudible]. >> Eric: the extraction liquid's on the bottom, [inaudible] just sort of roughly sort of gently swirl it around and what you start to see forming sort of between those 2 layers is like a flocculent-like material sort of almost looks like cotton. >> Jenny: Yeah. >> Eric: And as you swirl more and more and it gets more and more mixed you'll see more of it forming and that flocculent material is the DNA. >> Jenny: That's awesome. >> Eric: But you know it's very whitish and it's sort of very viscous and what does it really look like in real life? >> Jenny: It kind of looks like snot. >> Eric: It does look like snot and so-- And when you start to see big things of snot then you know it's really working well and you can even see here as we've done this, you can really start to see some of this precipitated DNA forming. >> Jenny: Wow, look at that. >> Eric: And we can get more in a bit but what you can do is when you start to see it, that's where the coffee stirrer comes in and you can just sort of fish that out. Look at that, look at that. >> Jenny: That's awesome. >> Eric: That is strawberry DNA, which, again, to our eyes looks like a bunch of snot. >> [inaudible]. >> Eric: But in fact if we could look at it at a molecular level, it would just consist of that classical double helix, that sort of the iconic view of DNA but this is strawberry-- Purified strawberry DNA [inaudible] you could get and you could if you wanted to keep swirling but you can see you've got a tremendous amount there-- >> [inaudible]. >> Eric: which is great. And just imagine, you did all of this using materials that you have in your kitchen, so you can do science in your kitchen and do something that is as wonderful as isolate DNA from a strawberry. >> Jenny: That is really cool. >> Jenny and Eric: DNA extraction. [ Music ] >> Jenny: Science is delicious. >> Eric: Especially the DNA. [ Music ]