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  • Hello, I'm Roger Tsien.

  • And I'm here today to tell you about fluorescent proteins.

  • which have made a major impact on microscopy

  • because they are genetically codable and

  • provide a relatively direct link from molecular and cell biology

  • into colors that we can directly see

  • particularly in the light microscope

  • but also, as you will see later on,

  • more macroscopic levels as well as eventually now

  • beginning to help us with super-resolution.

  • So, here this picture is, of course,

  • of the jellyfish, and

  • this jellyfish is where it all began.

  • And in a way, this is the creature that we most have to thank.

  • This is the jellyfish Aequorea victoria.

  • which was studied in Puget Sound

  • by Professor Shimomura, and in a moment,

  • we'll learn a little bit more about him soon.

  • This is the source of two of the most actually valuable proteins

  • in cell biology

  • First, there is the protein that actually enables this jellyfish to glow

  • And that's called aequorin, and

  • when the jellyfish is alarmed in the water,

  • and the water is disturbed, it emits a glow.

  • And then the partner of aequorin is the

  • green fluorescent protein, which changes the color from blue to green

  • to this day, we really don't have a well-accepted explanation

  • as to why the jellyfish wants to glow

  • why should it show this remarkable phenomenon

  • when the water's disturbed

  • nor do we know why when the jellyfish glows

  • why was it so important that it glows green instead of blue

  • why not just leave aequorin, or

  • if it really was important to glow green

  • why not just change aequorin in the first place to make it glow green directly

  • rather than invent an additional protein

  • but we are very grateful to the jellyfish

  • for having invented GFP.

  • So, the example - this is perhaps one of the only videos that we know of where we can show you the

  • glow of the jellyfish.

  • And this is a jellyfish upside-down

  • in a beaker in an aquarium at Alaska

  • where the jellyfish can still be found.

  • And we are illuminating with ultraviolet light right now.

  • And you may be able to see that there's a circle here.

  • There are little dots around the edge; that is the jellyfish glowing.

  • And this is the green fluorescent protein naturally made by the jellyfish

  • that we are exciting with the UV lamp.

  • I'm sorry the beaker is a bit fluorescent.

  • We should have got a better beaker that didn't have any,

  • but it's some yellow background.

  • But nevertheless, you can see the jellyfish there.

  • And it's upside-down and confined to this little beaker.

  • And what we're gonna do in a moment

  • is poke it to stimulate the flash.

  • So we're gonna start here, and you may be able to see

  • that the jellyfish is slightly moving around.

  • In this video, we are playing with the illumination

  • trying to get it nicely aimed at the jellyfish,

  • and in a moment, we're going to bring in this rod, with which we are going to poke it.

  • Then we turn out the lights, and we stir.

  • And during that stirring, that was the light emitted by the jellyfish

  • - not the light that previously had been applied from a UV lamp.

  • So that's it. That's the flash.

  • And maybe, you might have been able to see

  • it was sort of greenish - maybe.

  • Anway, the man who discovered that phenomenon is shown here.

  • This is Osamu Shimomura, and in 1962,

  • he published his first paper on aequorin.

  • And that was really the protein he was most interested in.

  • It had the really exciting job of turning chemical energy into light.

  • And he also mentioned that he found this contaminant

  • that got in the way a little bit of the purification

  • and that it was a greenish protein that fluoresced green

  • and that later he mentioned that it changed color of the jellyfish from the blue of aequorin to the green of GFP.

  • Later in 1979, he actually proposed the structure of the chromophore, GFP

  • based on surprisingly little evidence

  • but he got it almost absolutely, completely correct.

  • There were only very very small modifications from later work that came in.

  • This is a picture of him much later in 2008

  • in the rehearsal for the Nobel Ceremony.

  • And he is actually holding a UV lamp.

  • That's the violet that's on your left, and then next to it is the tube of GFP.

  • And this is the last tube in existence that is actually made from real jellyfish that he had kept in his freezer all this time.

  • Since then, everything has been made by molecular biology

  • and that's due to this man, here, Douglas Prasher at the center

  • of the photograph who in 1992 published the cloning of the gene for GFP.

  • And that was a long struggle. He didn't know what to look for.

  • And he could not predict that it would become green fluorescent.

  • In fact, that was a major worry

  • that there was no precedent for a protein that made by a biological organism would absorb blue light

  • and fluoresce green.

  • We didn't know whether it needed any cofactors.

  • Normally, in many cases, when biology does this sort of remarkable thing,

  • with light, it uses small molecule cofactors.

  • you're seeing me, for example, not because the proteins in your eye directly

  • absorb the light through the protein, but rather,

  • because the proteins bind retinal, the pigment that we have

  • to get from other sources, and that binds into the protein to make the functional protein.

  • And for all we knew, the fear was that maybe this protein used another cofactor

  • Or the chromophore structure that Shimamura had proposed might take many enzymes to generate out of the protein.

  • But, Marty Chalfie, who's shown here on the right side of the picture

  • then got the clone, the gene, from Prasher, as I did as well,

  • but Marty was first that proved that just that gene alone was

  • self-sufficient; in other words, if you took that gene

  • and expressed it in other organisms,

  • and he did it in E. coli and

  • in worms, then you would generate fluorescence.

  • And that proved that GFP was self-sufficient.

  • It knew how to make its own chromophore out of its own guts.

  • Fred Tsuji, not shown here, also did very very soon after Chalfie independently.

  • So, we now know that the chromophore structure

  • is something like this structure here

  • at the right, but it had to come from the

  • protein structure shown here

  • where just at this stage still amino acids.

  • There's a serine, a tyrosine, and a glycine

  • that somehow have to be modified,

  • and we have to introduce through a various number of steps,

  • which people are still now somewhat debating exactly how it happens.

  • We generated extra double bond; we generate a ring, and so on.

  • And all of this does require oxygen.

  • If you do not have oxygen in the atmosphere

  • when this protein is growing, it cannot become fluorescent or doesn't even absorb light - let alone become fluorescent.

  • So the oxygen is essential

  • and the only creatures which are biologically capable of using GFP

  • assuming we can get the DNA, the gene for GFP, in would be organisms that

  • cannot tolerate oxygen at any stage of their life cycle.

  • In other words, obligate anaerobes.

  • But they are a limitation. You do need oxygen.

  • So then, this may seem to be a completely unprecedented reaction,

  • but it turns out that the crucial first step is the attack of a backbone NH from Gly67

  • onto the amide bond of Ser65.

  • And this is a very strange reaction, you might think.

  • Since when does one amide attack another.

  • But in fact, it turns out to be fairly similar to a known

  • reaction in biochemistry

  • where the side chain amide of glycine attacks the side chain amide of Asparagine.

  • And that is promoted by bringing them closely

  • and it requires the special properties of glycine that it can curl up

  • and also that it's relatively unencumbered in its NH group.

  • And it's interesting that of all the fluorescent proteins that have ever been discovered,

  • the most conserved residue is not the one that contributes the most atoms to the chromophore

  • nor this other one that gets attacked,

  • but rather Gly67 - every known fluorescent protein has Gly67 in it.

  • And maybe it's because that's necessary for that first step.

  • Later on, the Asn-Gly goes into a different path.

  • It also forms a ring, but it spits out ammonia and so on.

  • And they diverge. Now there's one important other feature about this chemistry that I have to mention.

  • Oxygen comes in and at some stage pulls off the hydrogens

  • that were on the tyrosine

  • connecting the beta-hydrogens of the tyrosine that connect it to the rest of the chromophore.

  • So O2 pulls off H2, and the product is hydrogen peroxide.

  • H2 + O2 does not give you water in this case.

  • You have to balance the number of hydrogens and oxygens.

  • H2 + O2 gives you H2O2, which is hyrdogen peroxide.

  • So there is one molecule of a slightly toxic substance

  • that's generated for every molecule of GFP.

  • And that's sort of required by the conservation of mass.

  • It has been now directly verified, and it is a potential problem

  • that GFP is not totally totally safe for the organism,

  • and making a heck of a lot of GFP could generate one mole of hydrogen peroxide per every mole of GFP you make.

  • And you have to keep that in mind.

  • Now, fortunately, most organisms that have grown up in air has some defense

  • against a slow bit of hydrogen peroxide that's trickling out.

  • And we seem to be ok, but it's something that you have to keep in mind.

  • I should also say that in this original scheme

  • we propose that dehydration went before oxidation, and actually,

  • that's not quite so clear at exactly which stage the oxygen comes in and makes hydrogen peroxide

  • maybe a little bit earlier than I drew here.

  • So the original jellyfish protein actually was not very strongly fluorescent.

  • This dotted line here is the spectrum of the wild-type GFP.

  • And it has a big peak at around 400 nm - just below 400 nm.

  • In other words, the jellyfish actually GFP glows best in the UV.

  • And it only has a minor peak out here in the sort of green that gave it its name

  • and that's the one everyone wants to use.

  • Why the jellyfish deliberately crippled this protein

  • so that actually 5/6th of the time roughly, it is generating the UV,

  • and only 1/6th of the time, the visible, we really don't know.

  • Nevertheless, mutagenesis soon showed that particular mutations at Ser65

  • which you might think wasn't that close to the chromophore

  • though it contributed some of the atoms turns out to clean up the spectrum enormously

  • and get rid of this UV peak

  • and accentuate the visible peak

  • and also make the protein more stable,

  • and so these are the ones, the descendants of these improved proteins are the ones that

  • everyone uses nowadays including the very popular

  • so-called eGFP - e standing for enhanced,

  • which was this mutation S65T + a folding mutation to make it fold a little bit better.

  • Another feature I should say is that the jellyfish originally

  • grew and lives in Puget Sound or very cold water.

  • It never had any reason to worry about the ability to fold

  • at warm temperatures, but so many of us

  • want to work on mammalian tissue

  • at 37 degrees, this original protein just sorta collapsed

  • and basically wouldn't fold officially.

  • And a lot of mutagenesis of which this was just the beginning

  • then gradually made the protein able to tolerate warmer temperatures and fold more efficiently.

  • So later on, the crystal structure appeared almost simultaneously

  • from two groups in 1996

  • one of them was of this mutant S65T

  • and it showed a beautiful 1-stranded beta-barrel.

  • So the GFP is almost a perfect cylinder

  • made out of these strands that cross in this sort of helical lattice

  • around the outside, and then up the middle is

  • an alpha-helix that carries the chromophore.

  • And the chromophore in this model here is the bit in the middle that has the red and blue atoms that show up at atomic level

  • whereas everything else is just beta-strands or alpha-helix.

  • And this revealed why, in a way, no other enzymes were necessary.

  • They couldn't have been necessary because the chromophore's completely deeply buried inside this cylinder

  • so nothing else could have ever gotten that.

  • So it was essential in a way that the protein learned to do surgery on its own guts

  • and thereby generate the chromophore

  • in that chemistry I was just discussing where the hydrogen oxygen somehow has to get in,

  • hydrogen peroxide gets out.

  • Simultaneously, the other structure which was more of the original wild-type GFP

  • happened to be in a different crystal form

  • and showed that the GFP was also dimeric.

  • And that's another form of GFP, and actually,

  • there's an equillibrium between the two.

  • And it turns out that the GFP has a hydrophobic patch

  • where these amino acids mentioned here - three of them from each of the subunits get together

  • and this greasy patch enables dimerization.

  • And this is something to keep in mind again.

  • And one of the slight problems with wild-type GFP is that it likes a little bit to dimerize

  • And dimerization is generally bad when we want to tag a particular protein

  • because that forces the protein that we're really interested in, the partner, to also become dimeric

  • when it wouldn't otherwise have been.

  • We have forced it to be dimeric by fusing it to GFP.

  • And that often changes the cell biology and messes things up.

  • It doesn't matter so much if you're just trying to light up a cell

  • and you're using isolated protein because

  • then the fact that it wants to be a dimer, if it's not stuck to anything,

  • nobody else cares, so to speak.

  • Nevertheless, there's been a lot of interest in the dimerization, and we now know exactly how to get rid of it.

  • For example, if you take the A206, which is one of the ones mentioned

  • and change it to a lysine, A206K

  • completely destroys the dimerization because

  • then a lysine and a lysine replacing the alanine and alanine are now

  • in each other's face, and the electrostatic repulsion

  • between the two plus charges blows apart this dimer interface

  • and we supress the dimerization.

  • So in anytime that you are in any concern about it, there are mutations that can be used

  • to fix the dimerization problem, and they don't seem to have any bad effects on any of the other properties of GFP.

  • So can we get other colors?

  • And there was a lot of interest in getting other colors for various reasons.

  • The very simplest is that sometimes we want to follow several different proteins simultaneously

  • or follow different cells, which are marked with different and by making them different colors,

  • we can distinguish all of these.

  • So the original color is pretty close to this - the green output

  • if you forget the UV that the wild-type produces, you wouldn't have seen it with your eyes anyway

  • the residual green is very similar to this green from S65T

  • except S65T puts all of its energy into this green instead of only 1/6th of it.

  • It turns out to be possible to make a blue, a cyan, and evena somewhat yellowish version.

  • It's not awfully yellow; it's a yellowish-green still. But we call it YFP.

  • And these were found by various substitutions of the chromophore or around the chromophore.

  • So for example, if you change the original tyrosine in the chromophore, which is here,

  • and change it to a histidine, then we get the blue.

  • If we change it to a tryptophan, we get the cyan.

  • Ánd by the way, the UV peak was when this tyrosine was neutral.

  • And the green peak was when the tyrosine is negatively charged.

  • And this turns out to be crucial for my next lecture where we often, people now play with this equilibrium

  • and make it subject to environmental influences.

  • And by changing the ratio basically of the UV to the visible peak, we can make a GFP that switches on due to environmental influences.

  • And finally, the yellowish version is by taking an amino acid that's remote in the primary sequence that's

  • threonine 203 changing it to things like tyrosine or phenylalanine

  • and thereby it's close in 3-dimensional space.

  • It stacks above the real chromophore, and

  • the pi-pi stacking is what we believe is responsible for the yellow shift

  • that makes it a somewhat yellowish-green.

  • If we now look at the range of fluorescent proteins up to now,

  • everything was based on GFP from the jellyfish with mutational engineering

  • but it turns out that fluorescent proteins are fairly widely distributed in nature.

  • In fact, there are homologs in vertebrates

  • though they happen not to be fluorescent

  • if they were, we'd all be walking around like sort of the green giant.

  • But in fact, the ones that are all fluorescent all come from

  • the phyllum Cnidaria

  • which is the glorified Latin name for basically the family of coelenterates that includes

  • jellyfish, and corals, and some other related organisms.

  • And it's not just the jellyfish that can make fluorescence, but it turns out that corals

  • and that was the brilliant discovery of a Russian group, first author Matz et al.

  • And they have subsequently have done a lot of the phylogenetic tree by doing this classic molecular evolutional and genome analyses.

  • So a lot of you know, of course, tropical corals have beautiful colors.

  • Every scuba diver knows that or even snorkeler

  • but what we didn't realize is that so many of those colors are actually due to

  • homologs of GFP,

  • and particularly, one that attracted a lot of interest and was the subject of that first paper by Matz et al.

  • was Discosoma, which has a beautiful red fluorescence.

  • And that paper was about the cloning of the gene

  • for a red fluorescent protein that they called Ds for Discosoma - DsRed.

  • And it proved to be this beautiful red color.

  • At that time, it was not clear right away how did the corals manage to coerce the chromophore into absorbing green light

  • now instead of blue

  • and fluorescing red instead of green.

  • But chemical analysis of the chromophore eventually showed

  • that was the corals had figured out was add an extra double bond, which is between the carbon in this place and the nitrogen here

  • and this forms a very unusual structure called an acylamine

  • that is basically completely unstable

  • in ordinary solution and is only held together

  • by virtue of being inside the protein

  • but that extra double bond here in addition to all the double bonds that were up here

  • now extends the chromophore and it recruits this ketone or carbonyl group that used to be part of amide

  • and this extended chromophore then turns out to beautifully explain the red color as even shown by quantum mechanical calculations.

  • And when this structure was determined, some people in my lab were really

  • pleased with themselves, and they used the actual bacteria expressing the protein and used this ink, and with little toothpicks, they drew the structure on a petri dish.

  • So you can both see the beautiful red color and the structure that gives rise to to it all in one picture.

  • Now DsRed made by the corals as typical was made by the coral for its own reasons

  • and to this day, as usual, we really don't have a definitive explanation that everyone accepts

  • for why the coral should want to have these colors.

  • But whatever it is, the protein was not ideal for cell biological use.

  • The biggest problem was that it turned out to be a very tight obligate tetramer.

  • GFP was a weak dimer, and even the weak dimerization gave problems.

  • But DsRed being a tight tetramer often prevents proper trafficking, or fusions.

  • It's even worse because it's really strong and tight,

  • and four copies of your protein that you're trying to label red

  • now get fused together

  • And an example here was connexin-43, which is a constituent of gap junctions

  • and its detailed structure is shown here.

  • If you fuse it to GFP, you can get a fluorescent gap junction

  • and it trafficks reasonably well and makes this fluorescent plaque in a micrograph, of course,

  • showing that there's a boundary between one cell and another

  • which is slightly fluorescent, but when you do the same with DsRed,

  • the plaque is of course trying to make this connexin-43 wants to make a hexamer on its own.

  • Two of them eventually get together to 12-mer or decamer; meanwhile, the connexin-43 is trying to make a tetramer.

  • The two clash with each other, and you get a mess.

  • And the protein can never make a gap junction.

  • There are additional problems like the DsRed took a really long time to turn red,

  • and it didn't finish the job.

  • It left some green behind.

  • But the fact that it went through green stage is an interesting clue.

  • Eventually, these were all fixed by mutagenesis.

  • It was much more difficult than with GFP because that tetramer was really hard to break,

  • But eventually now, we now have a whole gamut of different colors.

  • of fluorescent proteins derived from DsRed through monomeric forms,

  • and it turned out to be not too hard to change their color.

  • So over here are the four that came from the jellyfish -

  • blue, cyan, green, and yellow

  • and these are all, by the way, these are all little tubes of protein made in E. coli and purified and simply a photographed by their own fluorescent light

  • and then we eventually got these additional colors in my lab

  • and in order to separate them and keep them easy to remember, we gave them the names of fruits

  • which each color references. Like this one is honeydew.

  • because honeydews are sort of yellowish green.

  • And then there's tangerine and strawberry and cherry and so on

  • - all these different beautiful red colors.

  • The one exception that really isn't monomeric is so-called tandem dimer Tomato.

  • And that is actually two copies of the original 11-stranded beta-barrel that are permanently genetically fused to each other.

  • And in that way, they satisfy each other.

  • This protein is not a tetramer; it's a dimer. But it's internally satisfied.

  • It's got two copies, and when you fuse it, you fuse both together as one unit.

  • And that's why we call it a tandem dimer.

  • So I wanted to mention then, derived from these new coral proteins, there have been

  • actually there's some varieties that were made from original jellyfish as well.

  • It now turns out that there are proteins that can be deliberately changed with light.

  • Of course, some proteins bleach, and that can be very useful in techniques

  • like fluorescence recovery after photobleaching.

  • But an even more spectacular case is this protein called dendra

  • which starts out green like DsRed.

  • But whereas DsRed spontaneously changes from green to red,

  • this one sits green indefinitely until you shine blue light on it

  • and that is what switches it from green to red.

  • So we can use this as an optical highlighter

  • to, for example, in this case track the migration of

  • a protein called fibrillarin

  • these authors fused Dendra to fibrillarin and locally

  • turned, shined blue light on, turned some of it from green to red and then watched

  • the subsequent fate of just those proteins that had been labeled.

  • So those proteins that were in the spot first lost their green color - not quite completely.

  • It might have been better if it had been complete, but they lost it considerably.

  • And then there's some recovery as proteins move around into this illuminated zone.

  • And meanwhile, the red protein made in the spot then over time spreads out.

  • And we can watch. And these are 1, 2, 3, 4 are different regions of interest in the original that were being tracked.

  • And even more spectacular form of photochemistry is shown by Dronpa

  • which is reversible, and it starts out green fluorescent,

  • and as you continue to excite its green fluorescence using blue-green light,

  • it fades away and reaches essentially down to nothing.

  • And you might think that this protein is dead, and most fluorescent proteins had you done it, you'd be right.

  • But this one, when you shine violet light on it, springs back to life

  • and comes back fully completely, just about, rejuvenated.

  • And we can do this cycle after cycle after cycle, and we show here,

  • these are compressed time course of probably 50 cycles,

  • and there's a slight bit of rundown as you go through many many many cycles.

  • But you can do this over and over again.

  • And the applications for repetitively following movements inside cells or as you will later hear from other people for doing super-resolution microscopy.

  • There are major implications that have been exploited, but I don't have the time to go into them here.

  • But the authors were so pleased with themselves that they

  • simply laid down a film of protein, a wet film of protein

  • and then they shined its own name successively using this trick of

  • starting fluorescent, bleaching it completely, shining the letter D,

  • a silhouette of the letter D,

  • onto this film of protein, and then they

  • lit up the letter D, and then they erased it again.

  • and then they wrote it again, this time the letter R, et cetera and wrote out its name.

  • Ok, so I don't have time talk more about these very interesting photochemically active proteins.

  • I'm now gonna turn briefly to the question of how do we look inside a more intact animal.

  • especially animals that are not quite as transparent as the ideals.

  • Now, the ideals may be zebrafish and a lot of microscopists like zebrafish or C. elegans because

  • they are transparent, but many of the other important ones like mice or flies are somewhat more opaque.

  • And in general, most organisms, especially mammals are nearly completely opaque

  • down in short wavelengths

  • below 600 nm, and that's because of the peaks of hemaglobin.

  • After all, that's what makes us pink.

  • why flesh is red, and as long as it's there,

  • you can't easily excite through much thickness of this tissue.

  • A standard demonstration is that if I try to shine a green laser through even the thinnest of my fingers,

  • nothing will get through, but if I shine a red laser,

  • laser pointer, a lot will get through,

  • and that's because a red laser is about 630 nm

  • beyond the shoulder, so it would be really nice

  • if we had fluorescent proteins that could be both excited and would emit longer than 600 nm.

  • And the record for current proteins derived from the jellyfish, coral, cnidarian family is just barely over 600 nm

  • and sort of marginal.

  • But we'd like to get out say to the 700 or so.

  • And it turns out that this is possible, but you have to be willing to go to a whole new protein family.

  • And this protein family is now back to cofactors.

  • These are small organic molecules.

  • This is what we were afraid the jellyfish and corals were using.

  • Now, we actually use them, and these pigments are derived

  • from the heme biosynthesis pathway.

  • Particularly, this is heme with a porphyrin, which is four pyrroles in a big circle

  • and with an iron in the middle

  • and when we break down heme or any organism that uses heme, that's essentially the entire kingdom of life - almost

  • when we break it down with an enzyme called heme oxygenase, the first breakdown product is called biliverdin.

  • Biliverdin is something that every adult human being makes about a quarter gram of every day

  • Normally, it's sort of kept sequestered, but if any of you have had a big bruise,

  • and you turned a sort of black and blue, a lot of that color is broken down heme that makes biliverdin.

  • And later bilirubin here, which is part of what gets excreted.

  • So it turns out that weak biliverdin is phylogenetically ubiquitous

  • Some organisms elaborate it into known fluorescent pigments that have these more elaborate cofactors.

  • But it turns out that bacteria use bilverdin in proteins that sense light.

  • And by mutagenesis, it was possible to prevent them from sensing light and instead use the energy to fluoresce.

  • These now make infrared fluorescent proteins that absorb at 680-some nanometers and emit just over 700 nm, hence, their name as infrared fluorescent proteins.

  • And they are genetically encodable; you have to make sure that the organism either provides biliverdin,

  • or the cell provides biliverdin. And as I said, most of our cells make it.

  • If necessary, you could can supply the extra by injection if you don't think they make enough of their own.

  • And so up to now, this has been the only way to decisively get beyond 600 nm.

  • And an example of its use here is when this is transfected into the liver;

  • now we can see the liver through the skin of an intact mouse

  • Far far better than even a relatively red-shifted protein that was derived from corals

  • And in turn, that is better than GFP,

  • which is essentially hopeless.

  • You cannot see the liver

  • of a corresponding GFP-transfected mouse that's got that.

  • Instead, all you see is the autofluorescence or the fur around the outside.

  • Whereas this stuff is shining through the abdomenal cavity.

  • And there's many things more that need to be done to improve this relatively recent work.

  • There's actually thousands of phytochromes; this is extremely widely diversified gene family.

  • There may be possible to get longer than what I just described.

  • And it should be helpful for lots of interesting in vivo macroscopic fluorescence imaging

  • somewhat similar to microscopy but at a more a less-space resolution but greater depth inside intact animals.

  • It provides colors that are orthogonal even to the wide range we've already got.

  • It could be an acceptor for fluorescence resonance energy transfer if it's quantum yield was improved a bit more.

  • It may be also good for the photoacoustic type of imaging

  • and many other tricks, and finally if heme oxygenase activity is itself biologically important in a lot of metabolic activities,

  • it's responsible for making carbon monoxide and helps makes cyclic-GMP,

  • and this is a possible way we could detect that activity in a cell that doesn't have much of its own and doesn't have any other source of biliverdin.

  • So in conclusion, these are some of the people in my lab who contributed or that we collaborated with

  • who contributed most to it,

  • and once again, I'm showing you the fun that you could have with these multi-colored living inks made out of fluorescent proteins in which some people in my lab with more artistic talent than I did

  • actually tried to draw a sunset with a green flash as you might see it from the beach not far from our lab.

  • Thank you very much.

Hello, I'm Roger Tsien.

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B1 中級

顕微鏡で見る蛍光タンパク質 (ロジャー・ティエン) (Microscopy: Fluorescent Proteins (Roger Tsien))

  • 114 5
    Pei-jyun Guan に公開 2021 年 01 月 14 日
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