This is quite possibly the smallest gel I have ever run:
To put this in perspective, usual gel-running machines are big clunky plastic things about 40cm square (or a little more rectangular) with all sorts of wires and things sticking out of both ends and gels floating around in TAE buffer solution.
The swish little thing shown above was 10x20 cms. All compact, only one wire, and the agarose gels come pre-packed and all ready to run. The stain is gel-green as well, which shows up under blue light, so the gel rests on top of a blue-light box. When the gel is finished you put the orange filter on, switch on the light, and observe the bands.
And, well, look at it. It's the most stylish piece of equipment I've ever worked with. It's going to be so hard saying good bye when I move into my new lab in November.
We didn't even have to pay for it. It was a freebee kindly donated by Invitrogen for our synthetic biology project.
(In case anyone was wondering the bands are just standard DNA ladders. We dug all the old ladders out of the freezer to see if they were working still. They are...but they're kind of in the wrong range, they are for little pieces of DNA and all our genes so far are looking like they're going to be quite big.)
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Biological Engineering. Now in Colour!
As I covered in this post, one of the main aims of synthetic biology is to produce modular building blocks for biology, to design and build up systems using registered and characterised parts. One thing this allows is the use of logic gates; by turning genes into abstract 'blocks' with certain properties engineers can use them to design biological circuits.
Here's an example from my work at the moment. One of the pigments I'm looking at is violacein - a purple pigment found in marine bacteria. Four genes are used to make this pigment, the first two take a molecule of tryptophan and modify it, the third joins the two modified molecules together, and the fourth further modifies this structure. This can be shown diagrammatically:VioA, vioB, vioC and vioD are the names of the genes. This diagram also shows that there is an intermediate colour within the pathway. If vioC is knocked out (so the gene can no longer function) the cells produce cyan pigment rather than violet.
This gives two separate 'states' for the cell to be in. The engineers start getting excited about this, because vioC needn't be completely destroyed in order for cyan to be produced, it can be put under the control of a certain input system, e.g an arsenic sensor. This means that the cells will normally be cyan, but in the presence of arsenic vioC is expressed and they turn violet. Instant biosensor. Easy to use, and easy to interpret.
As well as being explained biologically this can also be represented diagrammatically:
I like this diagram, because it shows just how useful a set of four genes making two colours can be. The vioA and vioD genes act as an AND gate. Putting them both under different input systems means that you can engineer bacteria that only turn cyan when two conditions are met; e.g correct temperature and correct levels of (say) iron. The vioC is then a further AND gate. Or...if the vioC is controlled by a repressor instead of an activator, a NOT gate. The possibilities are endless...
The really great thing about this is that it provides a level of abstraction for designers and engineers to work with biological systems. They don't need to know about the gene sequence, or the biological basis of gene activators and repressors. All they have to do is work with the blocks.
(Thanks to a fellow Lab Rat for the images!)
Here's an example from my work at the moment. One of the pigments I'm looking at is violacein - a purple pigment found in marine bacteria. Four genes are used to make this pigment, the first two take a molecule of tryptophan and modify it, the third joins the two modified molecules together, and the fourth further modifies this structure. This can be shown diagrammatically:VioA, vioB, vioC and vioD are the names of the genes. This diagram also shows that there is an intermediate colour within the pathway. If vioC is knocked out (so the gene can no longer function) the cells produce cyan pigment rather than violet.
This gives two separate 'states' for the cell to be in. The engineers start getting excited about this, because vioC needn't be completely destroyed in order for cyan to be produced, it can be put under the control of a certain input system, e.g an arsenic sensor. This means that the cells will normally be cyan, but in the presence of arsenic vioC is expressed and they turn violet. Instant biosensor. Easy to use, and easy to interpret.
As well as being explained biologically this can also be represented diagrammatically:
I like this diagram, because it shows just how useful a set of four genes making two colours can be. The vioA and vioD genes act as an AND gate. Putting them both under different input systems means that you can engineer bacteria that only turn cyan when two conditions are met; e.g correct temperature and correct levels of (say) iron. The vioC is then a further AND gate. Or...if the vioC is controlled by a repressor instead of an activator, a NOT gate. The possibilities are endless...
The really great thing about this is that it provides a level of abstraction for designers and engineers to work with biological systems. They don't need to know about the gene sequence, or the biological basis of gene activators and repressors. All they have to do is work with the blocks.
(Thanks to a fellow Lab Rat for the images!)
Creating Biobricks
One of the main features of synthetic biology is that it should work very much like Lego. Genes are acquired from a standard registry, and can be introduced into bacteria in the form of plasmids (small autonomously replicating sections of DNA). The genes are in a standard format, connected to standard 'prefix' and 'suffix' sections (which contain restriction sites - cut and paste DNA sections that connect everything together, most specifically connect the gene to the plasmid).
The BioBrick part (shown bracketed in blue) contains the actual gene. In my case, the gene for the brown pigment melanin. The little circles on either side are restriction sites, enzymes can cut the DNA at these places, allowing the BioBricks to be moved around and, if necessary, stuck together. The red brackets show the plasmid. The purple square labelled 'origin' is the origin of replication, allowing the plasmid to be copied within the bacterial cell. The green 'antibiotic resistance' box is a marker, to check whether the plasmid has entered the cell. The plasmids are put into the bacteria in a process called transformation, after which the bacteria are plated out onto antibiotic plates. Only those which contain the plasmid are able to survive.
It works well on paper. And it seems to work quite well in real life. There is even a registry of standard BioBrick parts, you can order them and mix them together to form biological engineering systems. They tend to work as well, with varying degrees of success, and if all goes well hopefully my little brown pigment plasmid will be in there as well one day. All I have to do is cut the gene out of the plasmid it's currently in, remove unwanted restriction sites, and stick it into the red-bracketed plasmid shown above.
This can all be done by PCR =D
(If I get totally stuck with it, the other option is just to get the gene synthesised and stick it straight into the plasmid. Easier...but more expensive)
The BioBrick part (shown bracketed in blue) contains the actual gene. In my case, the gene for the brown pigment melanin. The little circles on either side are restriction sites, enzymes can cut the DNA at these places, allowing the BioBricks to be moved around and, if necessary, stuck together. The red brackets show the plasmid. The purple square labelled 'origin' is the origin of replication, allowing the plasmid to be copied within the bacterial cell. The green 'antibiotic resistance' box is a marker, to check whether the plasmid has entered the cell. The plasmids are put into the bacteria in a process called transformation, after which the bacteria are plated out onto antibiotic plates. Only those which contain the plasmid are able to survive.
It works well on paper. And it seems to work quite well in real life. There is even a registry of standard BioBrick parts, you can order them and mix them together to form biological engineering systems. They tend to work as well, with varying degrees of success, and if all goes well hopefully my little brown pigment plasmid will be in there as well one day. All I have to do is cut the gene out of the plasmid it's currently in, remove unwanted restriction sites, and stick it into the red-bracketed plasmid shown above.
This can all be done by PCR =D
(If I get totally stuck with it, the other option is just to get the gene synthesised and stick it straight into the plasmid. Easier...but more expensive)
This time it's personal...
Well...today was going to be the day the we started the 'wet-work' of the project, the actual laboratory procedure rather than the planning of the last few weeks. Our project involves the bacterial species E. coli (a nice safe laboratory strain) and we were planning on opening the membranes up, sticking in new DNA and seeing if they expressed it.
Except of course today I was ill.
Bacterial infection.
E. coli...
The massive irony of this is not lost on me. However I am feeling a lot better this afternoon than I did this morning, and when I hit the lab tomorrow, there will be Vengeance.
(For the sake of scientific accuracy I should probably say that I don't know for sure that it's E. coli, but I've had this infection before, and it was E. coli the last few times, so it's a relatively high probability).
Except of course today I was ill.
Bacterial infection.
E. coli...
The massive irony of this is not lost on me. However I am feeling a lot better this afternoon than I did this morning, and when I hit the lab tomorrow, there will be Vengeance.
(For the sake of scientific accuracy I should probably say that I don't know for sure that it's E. coli, but I've had this infection before, and it was E. coli the last few times, so it's a relatively high probability).
Bacterial Photography
One of the things I'll be doing in my project over the next few weeks is designing a synthetic microbiological system; inserting different bits of DNA into bacteria to make them do ... well ... whatever I want really. There are a huge range of things you can get bacteria to do, and over the next ten weeks (while I'm doing my project) I'm going to try and cover one a week, just to give an idea of the scope and applications of synthetic biology, especially within bacteria.
So...for this week, bacterial photography: The picture above (image courtesy of UT/UCSF) is a coliroid, a picture taken by shining light onto a bacterial plate. This is done by putting genes that produce a black pigment under the control of a light-sensing bacteria. Bacteria in the light do not produce pigment, those in the dark do, creating a photographic image when light is shone on to a lawn of bacteria.
A more in-depth explanation of what is happening is shown in the diagram on the right (taken from this paper). The green blobs are photoreceptors; they sense light and in response they activate an intracellular protein portrayed as an orange blob (the double dotted lines are the bacterial cell membrane). This activated protein can then diffuse over to the DNA, and activate the promoter for a black pigment, which is then secreted out of the cell.
When light is present it blocks this activation process by stopping the action of the photoreceptors. Bacteria in the light will therefore not produce pigment, while those in the dark do produce pigment, leading to a darker colour on the agar plate.
The main challenge involved in this process was creating the photoreceptor. E. coli (the bacterial species used for this procedure) do not have any proteins for sensing light. Instead, a light sensing protein from a cyanobacterium was used, and held in place by fusing it to a trans-membrane protein (in the diagram above the cyanobacterium receptor is the green blob while the E. coli trans-membrane protein is the dark black line). This creates a chimeric protein, which can be put on a small circle of DNA (known as a plasmid) and inserted into the bacteria, along with the genes for the pigment. The bacteria can then be grown on a large plate, ready to be used for photography.
So...for this week, bacterial photography: The picture above (image courtesy of UT/UCSF) is a coliroid, a picture taken by shining light onto a bacterial plate. This is done by putting genes that produce a black pigment under the control of a light-sensing bacteria. Bacteria in the light do not produce pigment, those in the dark do, creating a photographic image when light is shone on to a lawn of bacteria.
A more in-depth explanation of what is happening is shown in the diagram on the right (taken from this paper). The green blobs are photoreceptors; they sense light and in response they activate an intracellular protein portrayed as an orange blob (the double dotted lines are the bacterial cell membrane). This activated protein can then diffuse over to the DNA, and activate the promoter for a black pigment, which is then secreted out of the cell.
When light is present it blocks this activation process by stopping the action of the photoreceptors. Bacteria in the light will therefore not produce pigment, while those in the dark do produce pigment, leading to a darker colour on the agar plate.
The main challenge involved in this process was creating the photoreceptor. E. coli (the bacterial species used for this procedure) do not have any proteins for sensing light. Instead, a light sensing protein from a cyanobacterium was used, and held in place by fusing it to a trans-membrane protein (in the diagram above the cyanobacterium receptor is the green blob while the E. coli trans-membrane protein is the dark black line). This creates a chimeric protein, which can be put on a small circle of DNA (known as a plasmid) and inserted into the bacteria, along with the genes for the pigment. The bacteria can then be grown on a large plate, ready to be used for photography.
Genetic engineering - video
As I mentioned in the last post, I'm currently doing a two-week course in synthetic biology. Along with scientists and engineered there are also a group of design students here from London. It's been really amazing so far, seeing things from different peoples points of view, it really gives a new perspective on things. And of course it is very useful to find out just how much other disciplines are aware of what happens in moleular biology.
One of the design students (you can find her website here) made an amazing video, just exploring and explaining genetic engineering and it's uses. I particularly like the bit about classification, although the little animated bacteria is fun too. It's definately worth a watch:
One of the design students (you can find her website here) made an amazing video, just exploring and explaining genetic engineering and it's uses. I particularly like the bit about classification, although the little animated bacteria is fun too. It's definately worth a watch:
The Synthetic Kingdom from Daisy Ginsberg on Vimeo.
Playing with wires
As I write, I am busy on another computer programing an Arduino board to make little lights flash on and off. Thee guy next to me has made his play Billy Jean...at double speed, which is kind of annoying and fun at the same time.
Arduino is interesting. You have the little circuit board which you wire up, and then you connect it too the computer using a USB, write a program (heh), get it to run, and, if you're lucky, a little light flashes. Or Billy Jean plays at double speed.
It's so much fun!
To put this in a little bit of context, I'm in the middle of a two week synthetic-biology course. People keep trying to get me to do programing, which is slightly disturbing. I am enjoying playing with Arduino though. Almost as much as I enjoyed constructing the bed-side tables last night :D
Arduino is interesting. You have the little circuit board which you wire up, and then you connect it too the computer using a USB, write a program (heh), get it to run, and, if you're lucky, a little light flashes. Or Billy Jean plays at double speed.
It's so much fun!
To put this in a little bit of context, I'm in the middle of a two week synthetic-biology course. People keep trying to get me to do programing, which is slightly disturbing. I am enjoying playing with Arduino though. Almost as much as I enjoyed constructing the bed-side tables last night :D