How do Cohesin and CTCF Fold DNA in Mammalian Genomes?

Part 1: Cohesin: Roles Beyond Sister Chromatid Cohesion?

00:00:07.26 Hello, my name is Jan-Michael Peters.
00:00:10.03 I am a Senior Scientist and also Scientific Director at the IMP,
00:00:13.12 the Research Institute of Molecular Pathology in Vienna, Austria.
00:00:18.06 And I would like to tell you about how a protein complex called cohesin
00:00:21.16 and a DNA binding protein called CTCF
00:00:24.21 together fold DNA in mammalian genomes.
00:00:28.25 Now, in the first part of this lecture, which has two parts,
00:00:31.25 I would like to introduce the hypothesis between this work...
00:00:34.17 behind this work.
00:00:36.08 I would like to explain how cohesin was discovered.
00:00:40.03 I would like to tell you that it was discovered
00:00:42.13 for having an essential role in sister chromatid cohesion.
00:00:44.24 But then would like to explain why we think that this function in cohesion
00:00:48.13 cannot be the only role that cohesin complexes have.
00:00:52.08 And that instead, and that will then follow in Part II,
00:00:54.18 they also, together with CTCF,
00:00:57.05 have a very important function in structuring genomes.
00:01:00.28 Now, I assume that most of you who are watching this video
00:01:04.05 do not need to be reminded about the fundamental role
00:01:07.03 that genomes have for all forms of life on our planet,
00:01:10.27 but I would like to remind you of the fact that genomes
00:01:13.27 can be very large.
00:01:15.07 They can contain a lot of DNA, as is beautifully illustrated
00:01:18.04 in this old electron micrograph from Johnson and Mullinger,
00:01:20.27 which shows just a tiny, tiny proportion of a genome,
00:01:24.12 of the DNA contained in a genome.
00:01:27.07 Now, if we look at our own genome,
00:01:29.25 if you add up all the DNA that is contained in our chromosomes
00:01:32.16 and stretch them out,
00:01:35.01 this will end up giving a length of about 2 meters of DNA,
00:01:38.19 corresponding to 6.5 feet,
00:01:40.26 which have to fit into a microscopically tiny cell nucleus.
00:01:45.04 Now, to put this into perspective,
00:01:47.01 if for a moment you imagine that the diameter of the cell nucleus
00:01:50.26 was not a few microns, which it is,
00:01:53.12 but had the size or had the diameter of a soccer ball,
00:01:57.00 then this would mean that about 80 kilometers or 50 miles of DNA
00:02:02.00 would have to fit into the sphere of this soccer ball.
00:02:07.07 Now, this tells us that DNA has to be very thin
00:02:10.08 -- that's the only reason why so much DNA can fit into a cell nucleus --
00:02:15.03 but it also implies that DNA has to be highly organized
00:02:17.28 for genomes to be able to undergo all the processes
00:02:20.17 that they have to undergo, like gene expression, DNA replication,
00:02:25.23 DNA damage repair, recombination,
00:02:28.22 but then also condensation into mitotic or meiotic chromosomes,
00:02:31.23 and segregation of these chromosomes in mitosis or meiosis.
00:02:35.11 For most of these processes,
00:02:37.22 it is important that the genomic DNA is properly organized
00:02:41.10 for these processes to be able to be carried out
00:02:45.13 with high speed and very high fidelity.
00:02:48.13 Now, one organizational principle
00:02:51.09 that is being used to fold DNA in chromatin and chromosomes
00:02:54.03 is the folding into loops, schematically shown here.
00:02:57.18 When two distant sequences are brought into proximity,
00:03:00.13 they form the anchor or the base of such a loop,
00:03:02.16 which then is formed by such a process.
00:03:07.08 Now, these loops are thought to exist in interphase somatic cells
00:03:10.12 but also in mitotic in meiotic chromosomes.
00:03:13.01 In interphase, some of these loops
00:03:15.23 have been implicated in gene regulatory processes,
00:03:18.01 such as bringing a distant enhancer into the proximity of a gene promoter,
00:03:21.10 which is important during development, for example,
00:03:24.07 or cell differentiation.
00:03:26.27 Such a looping mechanism is also thought to be important
00:03:30.29 for recombination events, for example in the B and T cells of our immune system
00:03:34.28 to allow recombination of immunoglobulin genes
00:03:39.26 to create, then, the diversity of antibodies and T cell receptors
00:03:45.06 that is needed for immune responses.
00:03:47.20 But it turns out that there's many such long-range interactions, many loops,
00:03:51.17 which presumably do not have regulatory functions in gene expression or recombination
00:03:56.10 but quote unquote "simply" are there for structural purposes,
00:04:00.03 to make sure that genomic DNA is properly organized
00:04:04.03 so that the genome can undergo all the processes
00:04:07.04 that I have already mentioned
00:04:09.28 with high speed and precision.
00:04:12.05 Now, how do we know that loops exist?
00:04:14.13 They are very hard to see in interphase chromatin.
00:04:16.19 It's possible to do this by microscopy but not easy.
00:04:19.14 But they can be quite easily seen in special meiotic chromosomes
00:04:22.20 called lampbrush chromosomes,
00:04:24.25 where they were discovered already at the end of the 19th century
00:04:28.13 by Walther Flemming, who also discovered chromosome segregation in mitosis.
00:04:33.06 These are meiotic chromosomes, as I mentioned,
00:04:35.12 where maternal and paternal chromosomes have been paired, recombined,
00:04:39.06 but then -- this is a very unusual situation --
00:04:42.14 are active in transcription.
00:04:44.23 And this transcription occurs in large loops
00:04:48.15 that are emanating from the chromosomal axis,
00:04:50.18 as you can see in these beautiful light micrographs,
00:04:54.24 which come from Ulrich Scheer's lab.
00:04:57.22 These are very special cases, and they...
00:04:59.26 it's not clear how related they are to the loops
00:05:02.12 that are existing in interphase somatic cells.
00:05:04.23 But this case does illustrate very clearly
00:05:07.02 that the principle of looping is clearly being used
00:05:09.22 to organize DNA in chromosomes.
00:05:12.16 Now, about 100 year later, after Flemming,
00:05:15.14 Ulrich Laemmli postulated that similar loops also exist in mitotic chromosomes,
00:05:19.29 mammalian mitotic chromosomes, which are much smaller.
00:05:22.26 Smaller because they are more compact,
00:05:24.26 but also because mammalian genomes are smaller
00:05:28.10 than the genomes of salamanders,
00:05:30.28 from which I just showed you lampbrush chromosomes.
00:05:33.13 Laemmli's lab prepared such mitotic chromosomes
00:05:36.25 by extracting the proteins by salt
00:05:40.05 and then visualizing what was left by electron microscopy.
00:05:44.05 By doing that, they saw what they called
00:05:46.28 a chromosomal scaffold,
00:05:49.01 which at the time was thought to be a static skeletal element,
00:05:51.22 but now today is known to be highly dynamic.
00:05:54.21 But importantly, they also saw DNA emanating from the scaffold
00:05:58.06 in loop-like structures,
00:06:01.25 again providing evidence that DNA is organized by this principle.
00:06:05.22 Now, that's not to say, of course,
00:06:07.19 that DNA looping is the only way how DNA
00:06:11.01 is organized in chromatin and chromosomes.
00:06:13.16 Most of our DNA is of course
00:06:16.18 wrapped around histone octamers into nucleosomal structures,
00:06:19.27 giving rise to 10-nanometer chromatin fibers,
00:06:22.20 as shown here by electron microscopy.
00:06:26.22 And then, over very long distances,
00:06:29.01 these chromatin fibers can not only fold into loops
00:06:32.15 but also into what is known as euchromatic or heterochromatic regions,
00:06:36.29 which electron microscopically are recognized as
00:06:40.15 electron-light and electron-dense regions,
00:06:43.14 and which by modern sequencing techniques,
00:06:45.06 which I'll come to in the second part,
00:06:47.07 can also be observed as so-called A compartments and B compartments.
00:06:52.16 So, looping is only one of several mechanisms
00:06:54.27 that is used to organize DNA in chromatin.
00:06:58.27 Now, in interphase somatic cells
00:07:01.11 -- not in mitotic chromosomes, but in interphase somatic cells --
00:07:05.04 many loops are formed by cohesin complexes.
00:07:09.06 More specifically, we think that these complexes
00:07:12.08 bring together distant sequences
00:07:15.03 to form the base or anchors of loops
00:07:17.11 but that the identity of these sequences,
00:07:19.18 which form the loop anchors,
00:07:22.06 are specified by the DNA binding protein
00:07:25.17 that I mentioned, CTCF.
00:07:27.22 Now, we postulated this hypothesis about 10 or 11 years ago,
00:07:31.14 and one reason for doing this at the time was that we knew very well
00:07:36.16 that cohesin has another function in sister chromatid cohesion.
00:07:40.18 Now, what is cohesion?
00:07:42.18 This is the phenomenon that newly replicated DNA molecules
00:07:44.27 -- the sister chromatids,
00:07:46.25 which are generated during S phase by DNA replication --
00:07:50.02 are physically connected.
00:07:52.26 And this connection depends on cohesin complexes.
00:07:56.16 So, it was clear that cohesin had the ability
00:08:00.02 to connect different DNA sequences
00:08:03.01 in the case of cohesion in trans.
00:08:04.25 But we wondered at the time whether, if they had that property,
00:08:08.10 they could not also bring together sequences in cis
00:08:11.22 -- distant sequences on the same DNA molecule --
00:08:14.00 to form the loops I've been talking about.
00:08:17.20 Now, let me introduce how cohesin was discovered,
00:08:20.18 because that's important to understand
00:08:23.15 more about its function.
00:08:25.24 And it was discovered, as I mentioned,
00:08:28.20 as a protein that's essential for sister chromatid cohesion.
00:08:32.19 This physical connection between the sisters
00:08:35.17 is created during DNA replication
00:08:38.02 but is then needed later in the cell cycle,
00:08:40.17 before chromosomes are segregated,
00:08:43.07 because cohesion is what allows biorientation of chromosomes
00:08:46.19 on the mitotic or meiotic spindle,
00:08:48.27 where each single chromosome needs to be attached
00:08:51.21 to the two poles of the bipolar spindle.
00:08:54.20 And this so-called biorientation process
00:08:56.19 is only possible because the sister chromatids
00:09:00.01 are being connected by cohesin.
00:09:02.21 If you imagine for a moment such a cohesion mechanism did not exist,
00:09:07.08 and the sisters were able to diffuse apart
00:09:10.09 once they had been synthesized during S phase,
00:09:13.02 you can realize that it would be very difficult
00:09:16.07 for the bipolar spindle to attach to a chromosome symmetrically,
00:09:20.06 and then to separate them during anaphase
00:09:23.24 to opposite poles in a way that each forming daughter cell
00:09:27.16 would obtain the identical or identical sets of chromosomes,
00:09:32.01 which is what they need to do of course.
00:09:34.29 So, for this reason, it's very important that
00:09:37.17 cohesion is formed during DNA replication
00:09:40.05 and then maintained until the subsequent chromosome segregation event.
00:09:44.29 Now, with this in mind, two laboratories
00:09:46.26 -- the one of Doug Koshland and the one of Kim Nasmyth --
00:09:50.08 used genetic screens in budding yeast
00:09:53.22 to identify genes that are essential for cohesion,
00:09:56.03 for the physical connection between sister chromatids.
00:09:59.07 And in total found seven such genes,
00:10:01.06 which are listed here.
00:10:03.11 It turns out that four of these encode subunits of the cohesin complex,
00:10:08.08 as I'll explain in a minute.
00:10:10.12 Two other ones, called Scc2 and Scc4 in yeast,
00:10:13.06 but they have different names in mammalian cells, NIPBL and MAU2,
00:10:18.04 are subunits of a different complex,
00:10:21.09 which is needed to load cohesin onto DNA in cells.
00:10:25.07 And then a seventh gene turned out to be an enzyme,
00:10:27.28 an acetyltransferase,
00:10:30.00 that is modifying one cohesin subunit during DNA replication
00:10:33.29 and makes sure that these modified complexes
00:10:36.18 can maintain cohesion from replication
00:10:40.07 until chromosome segregation.
00:10:42.11 And why that is I'll briefly explain later.
00:10:45.12 Now, what do we know about the four proteins
00:10:47.20 that are encoded by cohesin genes?
00:10:50.00 Two of these are very large ATPases.
00:10:54.27 They're called Smc1 and Smc3.
00:10:57.12 They can form heterodimers by using a heterodimerization or hinge domain,
00:11:03.23 schematically shown here.
00:11:05.27 You can see these in these electron micrographs at the top.
00:11:09.28 They also have very long coiled-coil regions,
00:11:13.09 which you can see again here
00:11:16.00 in the schematic drawing and in the EM images.
00:11:19.01 About 50 nanometers long.
00:11:21.08 And at the other end of these long coiled-coils, down here,
00:11:24.26 they form nucleotide binding domains,
00:11:27.29 domains that can bind ATP and hydrolyze it,
00:11:31.02 provided that the nucleotide binding domains of Smc1 and Smc3
00:11:37.09 are brought to... into the proximity
00:11:40.09 that's needed for the ATP binding and hydrolysis event.
00:11:44.15 Now, these two nucleotide binding domains
00:11:46.19 are also connected by another subunit, the so-called kleisin.
00:11:52.19 In the case of cohesin, this subunit is called Scc1,
00:11:56.13 or is also known by the names Mcd1 or RAD21.
00:12:00.16 And this third subunit, then,
00:12:03.17 by connecting the ATPase domains,
00:12:06.27 forms a ring-like structure, together with Smc1 and Smc3.
00:12:11.01 And it is connected by... with a fourth subunit called Scc3 in yeast.
00:12:15.00 It's represented by different orthologues in mammalian cells,
00:12:19.10 two of which in somatic cells are called STAG1 and STAG2.
00:12:25.11 Now, what is interesting is that these complexes
00:12:28.27 belong to a family of complexes,
00:12:31.12 the so-called structural maintenance of chromosome family,
00:12:34.07 first discovered by Doug Koshland.
00:12:37.25 This family also has members
00:12:41.00 which are functioning in mitotic chromosomes,
00:12:42.21 namely condensin complexes.
00:12:44.15 Mitotic chromosomes, as I mentioned,
00:12:46.29 have DNA loops,
00:12:49.03 but these loops are not formed by cohesin
00:12:51.26 but are thought to be formed by condensins.
00:12:54.05 And then also, really interestingly,
00:12:56.09 it turns out that this Smc family
00:12:58.24 also has members in bacteria,
00:13:01.20 where they also are important for structuring and organizing the genomes of bacteria,
00:13:09.15 which implies that DNA organization by Smc complexes,
00:13:11.26 in evolutionary terms,
00:13:14.08 must be a very ancient process, an ancient principle,
00:13:17.08 and might in fact have predated the wrapping around...
00:13:21.00 of DNA around histone octamers,
00:13:24.07 which as I explained, of course, is also used to organize DNA.
00:13:32.19 Now, cohesin complexes are large
00:13:35.26 relative to the DNA they're interacting with.
00:13:37.21 They have a diameter of about 50 nanometers.
00:13:40.03 That's 25 times larger than the diameter of naked DNA,
00:13:43.10 which is only 2 nanometers,
00:13:46.03 as is beautifully shown in this electron micrograph from Pim Huis in’t Veld.
00:13:51.10 And based on this notion and the fact that three of the subunits of cohesin
00:13:56.12 form a ring-like structure,
00:13:59.05 it has been postulated by the Nasmyth lab
00:14:02.22 that cohesin might be interacting with DNA in a topological manner,
00:14:06.04 according to which it would entrap DNA...
00:14:08.18 DNA inside its ring structure.
00:14:10.26 And that so-called ring hypothesis
00:14:13.04 is supported by a number of observations,
00:14:15.16 for example the finding that one can
00:14:19.21 cleave any of the ring-forming subunits of cohesin,
00:14:22.24 and that cleavage will result in
00:14:25.11 dissociation of cohesin from chromosomes
00:14:27.11 and will abrogate sister chromatid cohesion.
00:14:29.20 And in fact, such a cleavage process of the Scc1 subunit
00:14:33.00 is being used shortly before chromosome segregation by cells
00:14:37.11 to destroy sister chromatid cohesion.
00:14:40.29 Again, as I said, we'll discuss in a minute.
00:14:44.10 And furthermore, chemical cross-linking experiments
00:14:47.16 that have been performed in yeast
00:14:50.26 have shown that if one cross-links the subunits
00:14:54.12 between the ring-forming subunits Scc1, Smc1, and Smc3,
00:14:58.16 then these covalently linked rings
00:15:02.06 are found to topologically be interacting with circular yeast mini-chromosomes in yeast.
00:15:08.02 And these findings have led the Nasmyth lab
00:15:11.22 to hypothesize that sister chromatid cohesion is formed by two...
00:15:15.29 those two sister DNA molecules
00:15:19.20 being entrapped inside the cohesin ring structure.
00:15:23.02 Now, once this ring structure has been formed,
00:15:25.15 which as I mentioned happens during DNA replication, around the two sisters,
00:15:28.24 it has to be maintained under chromosome segregation.
00:15:32.25 But then, once chromosomes have become attached to the bipolar spindle,
00:15:38.01 these cohesin molecules of course have to be removed again from chromosomes,
00:15:42.09 because otherwise the sister DNAs
00:15:44.11 could not be separated in anaphase by the spindle apparatus,
00:15:46.28 which is the whole purpose of mitosis or meiosis.
00:15:51.17 Now, somewhat unexpectedly, this removal of cohesin in mi...
00:15:55.19 at least in mitosis in higher eukaryotes, occurs in two steps.
00:15:59.27 At the beginning of mitosis, in prophase and prometaphase,
00:16:03.08 about 90% of all cohesin
00:16:05.14 is removed from chromosome arms
00:16:08.14 by a mechanism that depends on a protein which is called WAPL.
00:16:11.26 Now, WAPL, we think,
00:16:14.16 is a protein that's able to open the cohesin ring
00:16:17.00 by dissociating the Scc1 subunit from the Smc3 subunit.
00:16:22.08 And that of course, according to the ring hypothesis,
00:16:24.26 would result in release of cohesin from DNA.
00:16:29.00 Now, this process is started in prophase
00:16:32.17 and continues throughout prometaphase.
00:16:34.14 For that reason, it is also called the prophase pathway.
00:16:37.06 It depends on activation of mitotic kinases,
00:16:40.13 which drive many other processes in mitosis.
00:16:45.03 But because it's initiated early in mitosis
00:16:48.01 -- so, at a time where the spindle has not been fully assembled
00:16:51.10 and has not attached to all chromosomes in a bipolar fashion yet --
00:16:57.20 this process would destroy coho... cohesion too early,
00:17:02.01 namely before chromosomes are all bioriented.
00:17:06.20 And for this reason,
00:17:09.04 a small population of cohesin is protected from this prophase pathway,
00:17:11.26 specifically at centromeres,
00:17:15.08 so, the point on chromosomes where kinetochores assemble,
00:17:18.15 to which then microtubules of the spindle attach,
00:17:21.24 and where the highest pulling force is created by the spindle apparatus
00:17:25.10 in pro... in metaphase and anaphase.
00:17:29.02 And at this point, at the centromere,
00:17:31.15 cohesin is protected from the prophase pathway by a phosphatase,
00:17:35.18 PP2A,
00:17:38.01 which is targeted to this chromosomal location
00:17:40.12 by a dedicated targeting factor called Shugoshin or Sg1,
00:17:44.04 and which protects cohesin from the prophase pathway,
00:17:46.25 presumably by reverting phosphorylation events
00:17:50.11 that are catalyzed by mitotic kinases,
00:17:54.09 which would activate the prophase pathway.
00:17:57.11 Now, these cohesin complexes,
00:17:59.11 which are protected at centromeres,
00:18:01.12 are maintaining cohesion until spindle assembly
00:18:05.24 has been completed, until every chromosome of the cell
00:18:08.02 has become attached to both spindle poles.
00:18:10.23 And then and only then, a different mechanism is activated,
00:18:13.16 which depends on a protease called separase,
00:18:16.10 which now is cleaving the Scc1 subunit,
00:18:20.06 the kleisin subunit of cohesin,
00:18:22.22 and thereby, like WAPL,
00:18:25.12 is opening the cohesin ring.
00:18:27.13 And that releases the remaining
00:18:30.15 until-then protected cohesin complexes from centromeres,
00:18:32.16 thereby liberating the sister chromatids
00:18:35.01 so that now the pulling force that's created by the mitotic spindle
00:18:37.23 can separate the sister chromatids
00:18:40.08 towards opposite poles in anaphase.
00:18:43.20 This second pathway, as I mentioned,
00:18:45.29 is only activated once the spindle has been fully assembled.
00:18:50.09 And that's the case
00:18:52.29 because there's a surveillance mechanism called the spindle assembly checkpoint
00:18:55.19 which is monitoring whether there are chromosomes in the cell
00:18:58.26 that have not...
00:19:01.04 have not fully been attached to spindle microtubules in the right way,
00:19:04.15 and as long as that is the case
00:19:07.15 will prevent activation of separase,
00:19:10.05 which depends on a ubiquitin ligase complex
00:19:12.22 known as the anaphase promoting complex,
00:19:14.20 which is under control of this surveillance mechanism,
00:19:18.13 the spindle assembly checkpoint.
00:19:20.27 So, that summarizes the function, briefly,
00:19:24.22 that cohesin complexes have in the cell cycle in proliferating cells,
00:19:29.15 namely to mediate sister chromatid cohesion,
00:19:32.09 which is essential for biorientation of chromosomes
00:19:36.13 on the mitotic spindle.
00:19:38.16 I told you briefly that the ATPase activity of cohesin complexes,
00:19:41.06 and the loading complex,
00:19:43.18 are needed to bring these complexes onto DNA in the first place.
00:19:48.13 They then establish cohesion during replication,
00:19:53.13 when the sister chromatids are being synthesized,
00:19:56.01 presumably in close proximity to the replication fork
00:19:58.24 by a process that's very poorly understood.
00:20:02.00 They then maintain cohesion until chromosome segregation.
00:20:05.13 That, as mentioned, allows biorientation of chromosomes on the spindle.
00:20:09.01 And then they are removed from chromosomes, again,
00:20:12.00 by two steps, first by the prophase pathway,
00:20:14.16 depending on WAPL,
00:20:16.13 and then, once spindle assembly has been completed,
00:20:19.03 by separase, which is a protease that cleaves cohesin
00:20:22.06 and can only become active once spindle assembly has been completed.
00:20:26.13 So, that's all very well and nice,
00:20:28.12 and it explains how cohesin complexes function in proliferating cells
00:20:32.01 and what their essential role in chromosome segregation is.
00:20:36.20 But what is interesting is that
00:20:39.07 while this process was being studied,
00:20:41.02 we and others made a number of observations
00:20:43.05 which could not be easy explained
00:20:45.14 if one assumed that the only...
00:20:48.00 the one and only function that cohesin complexes have
00:20:50.18 would be this cohesion function,
00:20:52.25 which of course initially was thought to be the case.
00:20:55.04 And so, I will now briefly summarize what these observations were,
00:20:59.07 which will then bring us to the hypothesis
00:21:02.01 that cohesin has a different function in DNA looping.
00:21:05.18 Now, one of these observations is the finding
00:21:08.25 that both the Hirano lab and we made
00:21:10.24 that in vertebrate cells cohesin complexes
00:21:13.01 are loaded onto DNA actually long before they're needed
00:21:16.06 for their cohesion function.
00:21:17.26 Namely, they're loaded onto DNA during mitotic exit,
00:21:20.24 starting in telophase and continuing, then,
00:21:23.15 throughout G1 phase,
00:21:25.17 so many hours before DNA is being replicated in the cell cycle
00:21:28.22 and cohesion can possibly be established.
00:21:32.00 That was a bit surprising.
00:21:34.11 Likewise, it was a bit surprising
00:21:36.23 that it was found in a number of species
00:21:39.10 that cohesin on chromosome arms
00:21:42.05 is enriched in very discrete locations,
00:21:44.18 as one can see by chromatin immunoprecipitation experiments.
00:21:48.03 One example is shown here,
00:21:50.10 where you see that cohesin is enriched at very discrete sites,
00:21:52.25 visible as peaks, here.
00:21:55.21 Now, if the one and only function of cohesin
00:21:58.10 was to hold the sisters together,
00:22:00.12 one would not necessarily have expected that they would be
00:22:03.11 always located in particular places,
00:22:05.11 because that function they could perform anywhere on the DNA.
00:22:09.25 Likewise, it was a bit surprising to realize that...
00:22:12.27 and I told you that already, in a sense...
00:22:15.01 that there is much more cohesin loaded onto DNA initially
00:22:19.15 than is needed to resist the pulling force of the mitotic spindle,
00:22:23.02 which we think is its key function in the cell cycle
00:22:26.15 when it builds cohesion
00:22:29.17 to enable the biorientation of chromosomes.
00:22:31.28 Because most of the cohesin is removed from chromosome arms,
00:22:34.20 again, before chromosomes are being segregated, as I explained,
00:22:40.20 and only very small amounts are left, then,
00:22:43.20 behind at centromeres,
00:22:45.08 where they are resisting the pulling force of the mitotic spindle.
00:22:47.19 But these amounts, or these complexes,
00:22:50.09 do not represent more than at best
00:22:52.18 10% of the cohesin that is initially loaded onto DNA.
00:22:57.18 And why it would be there in the first place
00:23:00.02 if it's not needed for cohesion
00:23:02.06 was of course not immediately obvious.
00:23:04.02 Now, one hypothesis or one possibility I need to say is that
00:23:08.12 maybe these complexes on chromosome arms
00:23:11.11 that are removed early in mitosis
00:23:13.28 have a function in DNA damage repair,
00:23:17.10 because it turns out that from S phase onwards
00:23:20.09 DNA damage repair can be performed by homologous recombination,
00:23:24.28 where a DNA double-strand break in one sister molecule
00:23:28.11 can be repaired by using the undamaged sister molecule as a template.
00:23:33.28 And for that to work, they have to be in close proximity.
00:23:36.09 And that proximity is thought to be provided by cohesion,
00:23:39.10 mediated by cohesin.
00:23:42.22 But it would... that would not explain why cohesin is rich in particular sites,
00:23:46.01 as I mentioned on the previous slide,
00:23:48.14 because DNA damage could occur anywhere on these chromosome arms, of course.
00:23:54.06 Now, another surprising finding was that
00:23:57.13 initially cohesin is loaded onto DNA during telophase and G1 phase
00:24:01.23 in a fashion that is actually unsuitable for maintaining cohesion later,
00:24:06.15 in that cohesin initially binds to DNA
00:24:08.12 in a highly dynamic manner,
00:24:10.06 as was first shown by Daniel Gerlich and Jan Ellenberg
00:24:13.23 using photobleaching experiments.
00:24:17.22 And this dynamic binding, it turns out,
00:24:20.00 depends on the same WAPL protein
00:24:22.09 that is also being activated in early mitosis,
00:24:24.29 because WAPL is present also in interphase
00:24:28.27 and, to a lesser extent than in mitosis, is also active there.
00:24:33.27 In other words, it can also release cohesin complexes,
00:24:36.18 presumably by ring opening, during interphase,
00:24:39.15 leading to a dynamic binding mode
00:24:42.09 where cohesin would constantly be loaded onto chromatin
00:24:45.09 by the loading complex
00:24:46.26 but could be removed again by WAPL,
00:24:49.06 also during this phase of the cell cycle.
00:24:52.03 Now, that means that cohesin complexes
00:24:55.13 that bind to DNA can only sit there with
00:25:00.01 a certain residence time of a few minutes,
00:25:02.06 which would not be sufficient for them
00:25:04.21 to maintain cohesion from replication
00:25:07.04 until chromosome segregation, which is their key function in cohesion,
00:25:10.00 as I explained.
00:25:11.24 And as a result of that,
00:25:14.02 cells have evolved a complicated pathway
00:25:16.18 that allows cohesin to be stabilized on chromatin
00:25:20.06 so that now it can maintain cohesion
00:25:22.27 once that has been established.
00:25:24.14 And in this pathway, initially,
00:25:26.18 one subunit of cohesion, namely Smc3,
00:25:29.09 is being acetylated by the Eco1 acetyltransferase,
00:25:33.01 or related enzymes that I mentioned earlier,
00:25:36.14 which were discovered in the initial yeast genetic screens.
00:25:40.07 And in vertebrates, then,
00:25:42.09 this modification of Smc3
00:25:45.19 allows cohesin to interact with a different protein called Sororin
00:25:49.05 -- discovered by Marc Kirschner and Susannah Rankin --
00:25:52.01 which it turns out is also essential for cohesion,
00:25:56.07 in fact to the same extent as cohesin itself is.
00:25:59.20 And we think it is essential for that
00:26:02.03 because it is essential for stabilizing cohesin on chromatin.
00:26:07.09 And we think it does that by somehow
00:26:10.02 inhibiting or antagonizing WAPL,
00:26:12.06 which otherwise would release cohesin from chromatin.
00:26:15.01 Now, one reason for thinking that
00:26:17.14 is shown in an experiment on this slide,
00:26:19.24 where we have looked at the state of cohesion
00:26:23.22 in mitotic chromosomes spread onto glass surfaces,
00:26:26.26 because one can easily recognize from the structure of these chromosomes
00:26:30.22 whether they have cohesion or not.
00:26:33.03 If you look at such a chromosome spread from a control cell,
00:26:38.16 which has WAPL and Sororin
00:26:40.21 -- these are human cultured cells --
00:26:42.25 you will see a classical X shape,
00:26:45.09 which is created by the fact that at this stage of mitosis
00:26:48.06 the prophase pathway has removed cohesin from the arms
00:26:51.17 -- dependent on WAPL --
00:26:54.03 but cohesin is still present at the centromeres,
00:26:57.15 leading to this tight connection there and the X shape.
00:27:01.24 The morphology is very different, however,
00:27:03.23 if Sororin is depleted.
00:27:05.13 That's shown in this chromosome spread,
00:27:07.12 where now you can see that all chromosomes have lost cohesion.
00:27:10.26 They have fallen apart into single sister chromatids.
00:27:15.20 Yet a different phenotype is seen if WAPL is depleted...
00:27:18.03 sorry, that's shown here...
00:27:20.07 where now not only centromeres but also chromosome arms
00:27:23.16 remain cohered, remain tightly connected.
00:27:26.12 That's because normally WAPL would remove cohesin from chromosome arms,
00:27:30.14 as I told you.
00:27:32.09 If it's not there, it cannot do that.
00:27:34.05 And now cohesion persists a way into mitosis,
00:27:36.26 into prometaphase and metaphase,
00:27:39.25 with cohesion between chromosome arms.
00:27:42.29 But the really interesting point is to ask
00:27:45.19 what is happening if both WAPL and Sororin are depleted,
00:27:49.09 which is shown here.
00:27:50.29 And I hope you can see that under these conditions,
00:27:53.08 chromosomes again have cohesion between centromeres and arms,
00:27:56.25 so they have the same phenotype
00:28:00.01 that is seen after WAPL depletion alone,
00:28:02.15 despite the fact that these cells
00:28:05.10 did not contain Sororin any longer,
00:28:07.18 which is essential for cohesion if WAPL is there.
00:28:11.08 So, the result is that Sororin is completely essential for cohesion
00:28:14.19 but only in the presence of WAPL.
00:28:17.15 And that's consistent with the idea
00:28:19.20 that somehow it must be inhibiting WAPL
00:28:21.26 and must thereby allow cohesin
00:28:25.27 to maintain cohesion from replication on until chromosome segregation.
00:28:30.18 Now, to come back to the original point,
00:28:33.00 it is a bit surprising that cells evolved
00:28:36.29 such a complicated mechanism,
00:28:38.21 where cohesin is first loaded onto chromatin in a dynamic fashion
00:28:41.14 to then only stabilize it by a multistep process during replication,
00:28:46.17 so that now it can maintain cohesion.
00:28:48.26 Why did cells not evolve a simple mechanism
00:28:52.04 where cohesin would be loaded immediately during S phase
00:28:55.15 in a stably bound form
00:28:58.01 that was sufficient to maintain cohesion?
00:29:00.27 Now, we think the answer to that question
00:29:03.29 is because cohesin has a very important function,
00:29:06.21 also, other than cohesion.
00:29:09.11 And that became very clear
00:29:11.18 when we started to look at non-proliferating cells,
00:29:14.05 at post-mitotic differentiated cells.
00:29:16.20 And at the time, to our surprise,
00:29:19.03 found that they also contain cohesin complexes.
00:29:21.00 And these also bind to chromatin.
00:29:23.00 And this is illustrated here, for example,
00:29:25.16 for mouse neurons,
00:29:27.20 which are not thought to ever divide again,
00:29:31.24 and therefore would never need sister chromatid cohesion again.
00:29:34.13 So, why would they contain cohesin complexes?
00:29:36.17 And the answer had to be
00:29:39.16 because they must have some other function on chromatin,
00:29:41.20 different from cohesion.
00:29:44.17 So, in summary, what I've told you is that,
00:29:47.03 yes, cohesin is essential for cohesion,
00:29:50.01 but despite that is loaded onto DNA
00:29:52.26 before it's actually needed for having that function.
00:29:54.28 It's... it's enriched at particular sites
00:29:59.01 for which it's not immediately clear
00:30:01.09 why they would be necessary for the cohesin function.
00:30:03.19 It's loaded in a large excess,
00:30:05.25 in higher amounts than what is needed to resist
00:30:09.06 the pulling force of the mitotic spindle.
00:30:11.17 It's surprisingly loaded in a form that is dynamic
00:30:14.03 and thus unsuitable for maintaining cohesion.
00:30:17.10 And it's present in cells that will never need cohesion again.
00:30:20.13 So, clearly, these complexes must have another function.
00:30:24.07 Now, an important hint to what this function could be
00:30:28.23 came from the observation made by a number of labs
00:30:31.06 that cohesin in mammalian genomes
00:30:33.20 is colocalizing with CTCF,
00:30:35.27 the DNA binding protein that I mentioned at the beginning,
00:30:38.07 which had been discovered multiple times,
00:30:41.03 initially by Gary Felsenfeld,
00:30:43.20 as a protein that is required for insulation
00:30:47.00 of certain gene promoters from enhancers that are not meant,
00:30:50.18 or not supposed,
00:30:52.11 to activate these particular promoters.
00:30:54.16 And it had been shown, very interestingly,
00:30:57.26 that this insulator function is used at some loci
00:31:00.24 for a very special gene expression pattern,
00:31:03.03 namely so-called imprinted gene expression,
00:31:05.19 where a particular gene is being active
00:31:08.07 on one of the two alleles but not the other.
00:31:10.06 This could be the maternal or the paternal one.
00:31:13.10 And for one such locus, the H19/Igf2 locus,
00:31:16.24 it had been shown, or evidence had been provided,
00:31:21.00 that CTCF mediates this allele-specific gene expression
00:31:24.19 by forming allele-specific chromatin loops.
00:31:27.23 So, a loop on one but not the other allele.
00:31:30.26 And that was really interesting
00:31:33.10 because if there was one thing that we knew about cohesin complexes
00:31:36.05 it was that they can bring DNA sequences together
00:31:40.24 to build cohesion.
00:31:42.15 And so, we wondered whether they could be actually responsible,
00:31:46.01 because they colocalize with CTCF,
00:31:48.02 for the loop formation that had been assigned to CTCF.
00:31:51.06 And consistent with this possibility, Kerstin Wendt,
00:31:54.03 who was in my lab at the time,
00:31:55.25 indeed found that the imprinted gene expression which depends on CTCF
00:31:58.26 also depends on cohesin.
00:32:01.20 And so that led to the idea
00:32:05.11 that it might be CTCF that specifies,
00:32:07.18 as a DNA binding protein that can recognize particular sequences in the genome,
00:32:10.19 which it can,
00:32:12.20 which anchors should form a loop.
00:32:14.27 But it might actually be cohesin that then
00:32:18.00 physically mediates the connection between these sequences
00:32:20.13 to form a chromatin loop.
00:32:22.25 Now, whether that's true,
00:32:25.01 and what we know about this process,
00:32:27.04 I will explain to you in the second part of my lecture.
00:32:29.19 And for now, I would like to thank all the colleagues in the field
00:32:33.23 that have contributed to this work on the role of cohesin,
00:32:36.22 both in sister chromatid cohesion and in loop formation.
00:32:40.11 And I would like to especially thank
00:32:42.20 all past and present members of my lab
00:32:45.27 for their great work in this field,
00:32:49.01 which has led to the knowledge that I have summarized in this lecture.
00:32:52.14 And of course, I would like to thank
00:32:54.29 our shareholders and funding agencies,
00:32:57.05 which have made this work possible.
00:32:59.02 Thank you very much for your attention.

Part 2: How do Cohesin and CTCF Fold DNA in Mammalian Genomes?

00:00:07.28 Hello, my name is Jan-Michael Peters.
00:00:09.24 I'm a Senior Scientist and Scientific Director at the IMP,
00:00:12.24 the Research Institute of Molecular Pathology
00:00:15.16 in Vienna, Austria.
00:00:18.10 And I would like to talk to you about
00:00:20.20 the role that the cohesin complex and the DNA binding protein CTCF have
00:00:25.00 in folding DNA in mammalian genomes.
00:00:29.04 Now, in this second part of this lecture,
00:00:31.20 which has two parts,
00:00:33.23 I would like to discuss with you what the evidence is that we have in the field
00:00:37.23 that cohesin has such a DNA folding function.
00:00:40.21 Then, I would like to discuss with you how we think
00:00:43.19 the CTCF protein contributes to this process.
00:00:46.02 And I would like to discuss with you
00:00:49.03 the loop extrusion hypothesis, which provides a very interesting, novel view on
00:00:54.24 how DNA loops might be formed.
00:00:57.22 Now, in case you have seen Part I of this lecture series,
00:00:59.27 you might remember that one can see loops
00:01:03.25 relatively easily by light microscopy in very specialized meiotic chromosomes,
00:01:07.29 the so-called lampbrush chromosomes.
00:01:10.02 But it turns out it's much harder to visualize loops
00:01:12.22 in somatic interphase nuclei.
00:01:15.28 At best, one can do this for one or two, or a few at the time,
00:01:19.11 by using hybridization or fluorescent labeling techniques.
00:01:22.17 But it turns out that one can identify such loops, long-range interactions,
00:01:28.10 by a different technique, called Hi-C,
00:01:30.23 which was developed around 2009 by Erez Lieberman-Aiden,
00:01:34.20 which uses formaldehyde cross-linking in cell nuclei
00:01:40.11 to physically connect sequences that at the point of cross-linking
00:01:44.13 had been in close proximity.
00:01:47.05 And by processing this cross-linked DNA through multiple steps,
00:01:51.01 one can then use next-generation sequencing
00:01:54.29 to identify which sequences had been cross-linked,
00:01:58.25 i.e., had been in close proximity.
00:02:01.00 And these long-range interactions
00:02:04.20 one can then visualize in heat maps -- as one is shown here --
00:02:09.20 where typically one shows DNA sequence on the x axis,
00:02:15.17 and the same sequence on the y axis,
00:02:18.14 so that one can visualize, by intensity of color,
00:02:22.14 which regions in this particular locus
00:02:26.20 interacted with other regions in the same locus
00:02:29.10 . And one can do this for the whole genome in one Hi-C map,
00:02:33.01 or for a single chromosome,
00:02:35.07 or one can zoom into a particular locus, as we did here.
00:02:39.09 Now, if one looks at very long-range interactions,
00:02:42.07 which are not shown here,
00:02:43.25 one can visualize the compartments that are briefly mentioned
00:02:46.04 in Part I of my lecture.
00:02:48.07 But these are not thought to depend on cohesin,
00:02:50.03 so I will not talk about them today.
00:02:52.27 But if one zooms in further, as we did here,
00:02:55.09 one can see two different types of patterns.
00:02:58.19 One of these appear as pyramid-like structures,
00:03:02.02 so-called topologically associating domains,
00:03:04.25 within which many sequences seem to be able to interact with other sequences
00:03:09.19 in this particular domain,
00:03:11.28 first described in 2012 by Bing Ren and Edith Heard.
00:03:15.18 And a few years later, by increasing the resolution of this technique further,
00:03:19.00 Erez Lieberman-Aiden could show that, in addition,
00:03:22.19 one can see also discrete dots in these Hi-C maps,
00:03:25.16 which we refer to as loops.
00:03:28.00 It's important to note that these loops might in mechanistic terms
00:03:31.16 not be very different from the interactions that constitute TADs.
00:03:38.14 But these are the two types of patterns
00:03:40.12 that one can identify,
00:03:42.20 which do represent folded DNA within interphase chromatin.
00:03:46.29 Now, the question was, do these interactions depend on cohesin,
00:03:49.27 as we had hypothesized and I explained in Part I of this lecture series?
00:03:54.11 And to be able to test that,
00:03:56.06 it was important to inactivate cohesin very efficiently.
00:03:59.09 Otherwise, one wouldn't see whether these structures
00:04:02.07 really depend on these proteins or not.
00:04:05.01 And we and others did this by using
00:04:07.13 a technique called auxin-mediated degradation,
00:04:10.23 where one is fusing a sequence domain to a protein of interest
00:04:15.12 -- in our case, a subunit of cohesin --
00:04:18.08 that can be recognized by an adapter protein that,
00:04:21.09 under the right conditions,
00:04:23.09 can then target the protein of interest to a ubiquitin ligase,
00:04:26.10 which can then multiubiquitinate this protein
00:04:29.05 and thereby target it for destruction by the 26S proteasome.
00:04:34.04 And this particular tagging system can be controlled
00:04:40.26 by the absence or presence of the plant hormone auxin,
00:04:44.12 which is needed for activation of this particular ubiquitin ligase system
00:04:48.06 which is being used here.
00:04:50.06 Now, we did this for the cohesin subunit Scc1,
00:04:52.29 which we tagged with such an auxin-inducible degron tag,
00:04:56.15 AID.
00:04:58.19 But in addition, also with GFP,
00:05:00.11 so we could visualize it by fluorescence microscopy
00:05:02.29 in cell culture.
00:05:04.25 And when we added, now, auxin to such cells
00:05:07.25 which contained only Scc1 fused to GFP and AID...
00:05:12.25 achieved by Crispr genome editing,
00:05:16.01 but no other untagged alleles of Scc1...
00:05:18.09 then we saw that the GFP signal disappeared very rapidly,
00:05:22.07 quantified here.
00:05:24.29 And this disappearance of GFP was indeed caused by degradation,
00:05:28.24 as could be seen by western blotting,
00:05:32.08 where the Scc1 protein disappeared both from the chromatin pellet
00:05:35.10 but also from the supernatant fraction,
00:05:39.20 whereas other subunits of cohesin remained stable,
00:05:43.26 for example, Smc1,
00:05:46.24 but interestingly, disappeared...
00:05:49.20 were released from chromatin, as you can see here,
00:05:51.27 at the same time as Scc1 was degraded.
00:05:55.07 Exactly as one would have predicted,
00:05:57.02 since we know that these are subunits of the same cohesin complex.
00:06:01.15 So, this turned out to be a very efficient
00:06:03.19 -- and also rapid, by the way --
00:06:05.12 way of inactivating cohesin.
00:06:07.23 And so, then, the question then was,
00:06:10.05 what would now happen to chromatin structure?
00:06:13.07 What will we see in Hi-C experiments
00:06:15.19 with respect to the presence of TADs and loops?
00:06:18.19 And the phenotype is really dramatic.
00:06:21.02 As is shown in this slide, on the righthand side,
00:06:24.07 you can see the same chromosomal locus that's shown on the left,
00:06:27.25 but now three hours after addition of auxin to the cells
00:06:31.13 that only have cohesin which is degradable.
00:06:35.20 And you can appreciate that the majority of interactions
00:06:38.24 that constitute TADs and loops have gone.
00:06:41.22 They... they disappeared,
00:06:44.10 implying that cohesin is indeed needed
00:06:46.24 for these long-range interactions.
00:06:48.24 And we've also looked at earlier time points by Hi-C
00:06:51.20 and can see,
00:06:54.08 consistent with the disappearance of Scc1,
00:06:56.23 that these structures begin to diminish already
00:07:00.06 after 15 to 20 minutes.
00:07:02.06 So, clearly, they depend on cohesin.
00:07:04.15 That's one reason for believing that cohesin
00:07:06.25 is important for folding DNA in mammalian genomes.
00:07:10.23 The other reason for believing that
00:07:13.23 comes from a very different type of experiment,
00:07:15.27 which initially we did for a different reason.
00:07:18.14 Well, we wanted to know
00:07:22.07 why cells have an elaborate system
00:07:24.29 by which they can remove cohesin from chromatin again
00:07:27.25 using the release factor WAPL,
00:07:29.25 which I introduced in the first part of this lecture,
00:07:31.27 which we think is a protein that binds to cohesin
00:07:34.00 and opens the ring structure,
00:07:36.10 thereby enabling it to dissociate from DNA again,
00:07:40.00 which clearly happens to complexes
00:07:43.02 that have not established cohesion, in G1 phase, for example.
00:07:47.17 Now, because co... WAPL is a release factor,
00:07:50.04 we had expected that its removal
00:07:53.06 would now stabilize cohesin on chromatin
00:07:55.10 -- it would have a longer residence time.
00:07:57.24 And we also expected that, as a result of that,
00:08:00.08 there would over time be more cohesin accumulating on chromatin,
00:08:03.11 because there's always an equilibrium
00:08:05.18 between soluble and DNA-bound cohesin.
00:08:08.09 And if we removed WAPL,
00:08:10.17 then of course the prediction was it would continue to be loaded onto DNA,
00:08:15.07 but cohesin would no longer be released,
00:08:17.19 so it would have a longer residence time,
00:08:19.27 and it would be there in higher amounts.
00:08:21.26 And that is indeed exactly what we found.
00:08:24.27 But what we had not expected was that this...
00:08:28.04 these changes would have dramatic effects on chromatin structure
00:08:35.02 and also on the localization, or the distribution,
00:08:38.25 of cohesin within the nucleus.
00:08:40.07 And that's shown on this slide,
00:08:42.08 where on the top you can see
00:08:45.19 a mammalian cell nucleus stained with DAPI,
00:08:47.18 so the DNA is stained.
00:08:49.21 You can see a relatively amorphous staining pattern,
00:08:52.22 which is typical for a cell in G1 phase, which this is.
00:08:56.28 But after inactivation of WAPL,
00:08:59.02 now we can see that the DNA
00:09:02.26 had begun to become condensed,
00:09:04.10 as if it had entered prophase, early mitosis,
00:09:06.17 which this cell clearly hadn't
00:09:09.09 by all sorts of criteria that we looked at.
00:09:11.14 Even more surprisingly,
00:09:13.12 we found that the distribution of cohesin was dramatically changed.
00:09:17.05 Normally, as seen by fluorescence microscopy,
00:09:19.13 cohesin would be distributed on chromatin relatively evenly,
00:09:21.25 as you see here in this control cell.
00:09:24.29 But after WAPL depletion,
00:09:27.03 now it had changed localization
00:09:30.09 and accumulated in axial domains of chromatin territories,
00:09:36.02 which from hybridization experiments
00:09:38.29 we believe are running from one telomere...
00:09:41.16 so, one... from one end of the chromosome, if you wish,
00:09:44.05 to the other.
00:09:45.23 And we called these axial staining patterns vermicelli,
00:09:51.20 which is Italian for little worms,
00:09:53.14 because the student in my lab who discovered them
00:09:56.03 was Italian, Antonio Tedeschi.
00:09:58.08 So, that's what we call these structures.
00:10:02.22 Now, that was really interesting.
00:10:06.14 It reminded us of how complexes that are related to cohesin
00:10:12.13 are distributed in mitotic and meiotic chromosomes.
00:10:16.02 In mitotic chromosomes,
00:10:18.14 the condensin complexes are also adopting an axial distribution.
00:10:23.10 And in meiotic chromosomes,
00:10:26.04 there are different types of cohesin complexes
00:10:28.10 -- specialized meiotic forms of cohesin --
00:10:31.04 that also form similar axial structures.
00:10:33.17 And in both cases,
00:10:36.01 it is believed that these axial structures
00:10:38.17 form the base of chromatin loops.
00:10:40.23 So, based on that, and based on our hypothesis
00:10:43.29 that cohesin might be folding DNA into loops,
00:10:46.03 as I explained in Part I of the lecture,
00:10:48.18 we hypothesized that these vermicelli,
00:10:52.04 these axial domains,
00:10:54.05 might also represent the base of chromatin loops
00:10:58.09 in WAPL-depleted cells.
00:11:01.09 Now, that was very exciting.
00:11:02.24 But the real question of course was,
00:11:04.07 how would the depletion of a release factor,
00:11:08.18 which leads to the stabilization of cohesin on chromatin,
00:11:10.13 lead to this dramatic relocalization of cohesin into vermicelli?
00:11:17.00 And how would it, then,
00:11:18.22 somehow lead to compaction of DNA?
00:11:20.19 That was really unclear.
00:11:22.28 And it was Leonid Mirny, a polymer physicist at MIT,
00:11:27.00 who realized that both these phenotypes could be explained
00:11:31.04 by a very interesting hypothesis called the loop extrusion hypothesis.
00:11:35.27 This hypothesis has been postulated multiple times
00:11:40.17 over a number of decades, independently,
00:11:43.25 starting with Arthur Riggs
00:11:46.24 and others working on enhancer-promoter interactions,
00:11:50.04 who were faced with the question,
00:11:52.09 how could a distant enhancer element in DNA
00:11:54.27 find its target gene promoter?
00:11:57.21 And they speculated, they hypothesized,
00:11:59.23 that maybe it would find it by what today we would call
00:12:04.22 an extrusion mechanism.
00:12:05.08 I'll explain in a second what that is.
00:12:07.22 Then Kim Nasmyth postulated that condensin
00:12:10.04 could form loops by such a mechanism
00:12:12.10 in mitotic chromosomes,
00:12:13.26 and by extension,
00:12:16.00 maybe also cohesin would do something similar.
00:12:18.15 And then, after that,
00:12:21.04 Leonid Mirny and several others...
00:12:23.19 Erez Lieberman-Aiden and John Marko...
00:12:26.18 also came up with this idea.
00:12:28.21 Now, the Mirny lab realized that this hypothesis
00:12:31.18 could explain our WAPL depletion phenotype,
00:12:35.16 because the loop extrusion hypothesis posits
00:12:39.21 that maybe two different sequences would specifically be brought into proximity,
00:12:43.00 not by diffusion -- that's hard to imagine --
00:12:46.01 but by a mechanism where a hypothetical extrusion factor
00:12:49.09 would land somewhere on the genome,
00:12:52.20 and then, by an unknown mechanism,
00:12:54.25 would pump DNA into a loop-like structure
00:12:57.04 until it would reach, eventually,
00:12:59.23 the anchor sequences that would be defined
00:13:04.19 or would be the sequences that should form the base of such a loop.
00:13:09.12 And if one imagines cohesin could be such a loop extrusion factor,
00:13:13.14 it could explain why WAPL depletion
00:13:16.06 would give these really unusual phenotypes,
00:13:18.10 unexpected phenotypes,
00:13:20.09 in the sense that if WAPL was present we would know that
00:13:24.06 it would limit the residence time of cohesin on chromatin.
00:13:27.02 And so, if cohesin was forming a loop by extrusion,
00:13:30.02 the lifetime of such a loop,
00:13:32.02 and therefore also its length, will be limited,
00:13:34.23 because every couple of minutes or so
00:13:37.24 WAPL would release the cohesin complex again,
00:13:39.22 and the loop would fall apart.
00:13:42.08 But, if WAPL was now depleted,
00:13:44.20 cohesin could no longer be released,
00:13:46.22 it would have a long residence time,
00:13:49.28 and it could now form very long loops,
00:13:53.09 longer than usually.
00:13:55.25 And in theory, they could be so long that
00:13:59.06 eventually the cohesin complexes could bump into each other.
00:14:02.05 And that could explain why we saw them now
00:14:05.23 all of a sudden accumulating in axial domains
00:14:08.13 within interphase chromatin territories.
00:14:11.25 And at the same time, formation of long loops
00:14:14.21 could explain why chromatin became compacted,
00:14:18.28 because it is thought that formation of long loops
00:14:21.12 -- that's been supported by in silico simulations and polymer modelling --
00:14:27.02 is causally responsible for chromatin compaction.
00:14:32.18 Now, this hypothesis has made the very interesting prediction
00:14:36.28 that when we deplet WAPL
00:14:39.22 we should now be able to detect more long loops,
00:14:43.11 more long-range interactions, by Hi-C.
00:14:46.08 And both my lab, and also the one of Ben Rowland,
00:14:50.01 have tested this and indeed found that that's the case,
00:14:52.08 as shown in this slide, where on the left you see,
00:14:55.21 again, a Hi-C matrix from a control cell,
00:14:58.00 but then on the right-hand side you see a Hi-C matrix
00:15:00.21 from a cell from which WAPL was depleted.
00:15:03.02 And I hope you can see that now
00:15:06.17 there are additional long-range interactions in the WAPL-depleted cells
00:15:10.07 that cannot be detected, at least to the same extent,
00:15:12.28 in the control cells,
00:15:15.03 implying that now more long-range interactions had been formed.
00:15:19.10 We showed that these, again, depend on cohesin,
00:15:22.05 of course.
00:15:24.25 Now, in the first part of this lecture series,
00:15:27.11 I explained that initially we had speculated
00:15:30.20 that cohesin would be the molecule that mediates
00:15:33.03 long-range interactions to form chromatin loops,
00:15:35.14 but it would be CTCF or its ability to recognize a particular consensus sequence in the genome
00:15:40.23 that would specify the identity of these loop anchors.
00:15:45.00 Now, if cohesin was mediating loop formation by extrusion,
00:15:47.28 the question is, what could be the role of CTCF in this process?
00:15:52.22 Now, obviously, CTCF could function in this process
00:15:56.16 as a physical boundary.
00:15:58.27 Everything that we know about these loops
00:16:01.16 could be explained if one assumes that
00:16:03.29 extruding cohesin complexes were stopped in the extrusion process
00:16:07.28 once they encountered CTCF when it's bound to DNA.
00:16:10.09 And that would in fact very nicely explain
00:16:13.20 the observation that cohesin accumulates,
00:16:15.27 as one can see by chromatin immunoprecipitation,
00:16:18.23 at CTCF sites, and therefore seems to co-localize,
00:16:22.10 at least if one analyzes large populations of cells.
00:16:26.16 So, the loop extrusion hypothesis would predict that
00:16:29.25 CTCF must be a physical boundary for extruding cohesin complexes.
00:16:33.13 Now, what is very interesting in this context
00:16:35.24 is that the binding site for the...
00:16:38.02 or the consensus site for CTCF
00:16:40.11 is not a symmetrical sequence but asymmetric.
00:16:42.14 It's not a palindrome.
00:16:44.10 And for that reason, can exist in two different orientations in the genome,
00:16:47.14 implying that CTCF can bind in two different orientations.
00:16:52.03 Now, that in itself is not unusual for DNA binding proteins.
00:16:55.07 But what is very unusual
00:16:57.12 is that a number of labs have observed
00:17:00.21 that those CTCF sites that form the anchors of cohesin-mediated...
00:17:04.06 cohesin-mediated loops are always pointing towards each other
00:17:08.12 in their orientation.
00:17:10.16 And that implies that CTCF
00:17:13.03 may not only function as a simple physical barrier
00:17:16.01 but may function as a boundary in an asymmetric fashion,
00:17:20.01 implying that if cohesin was arriving from one side
00:17:23.13 at such a DNA-bound CTCF molecule,
00:17:26.15 it might block extrusion,
00:17:29.03 but if it's arriving from the other, it might not.
00:17:31.17 And in fact, Maciej Zaczek in my laboratory
00:17:34.09 has recently been able to reconstitute part of this boundary function
00:17:37.20 using recombinant CTCF and cohesin,
00:17:40.14 and has seen that indeed, under in-vitro conditions,
00:17:44.06 CTCF is sufficient to block translocating cohesin complexes
00:17:48.28 that arrive at a CTCF site from one side
00:17:52.01 but cannot block cohesin
00:17:55.00 if it's translocating along DNA from the other side.
00:17:57.28 And how that works mechanistically,
00:18:00.08 what the structure of CTCF looks like
00:18:02.22 to be able to achieve this unusual symm... asymmetry
00:18:05.18 will be a very interesting question to study in the future.
00:18:09.06 Now, that in itself then represents another complication,
00:18:14.14 because if these CTCF sites function as boundaries
00:18:19.01 for loop-extruding cohesin complexes,
00:18:22.02 why would, then, the loops become longer
00:18:24.21 if WAPL is depleted?
00:18:26.19 And we don't know the answer to that.
00:18:28.24 But one has to postulate that they do become longer
00:18:31.24 because these boundary elements,
00:18:33.18 these CTCF sites, are only transient boundaries,
00:18:37.00 either because CTCF dissociates and rebinds,
00:18:39.23 and while it does that cohesin can go past and form a longer loop, or be...
00:18:45.15 perhaps because cohesin can somehow, at some point,
00:18:47.21 jump over such a CTCF boundary
00:18:49.28 and thereby form a longer loop.
00:18:51.28 So, we think of them a bit like red streetlights in a traffic system,
00:18:55.20 where cars would accumulate in front of the red streetlight,
00:19:00.25 but of course, at some point, the streetlight would switch to green,
00:19:03.14 and then the cars would move on.
00:19:04.27 And maybe that's how cohesin somehow
00:19:07.14 analogously behaves with respect to CTCF
00:19:10.24 as a boundary element.
00:19:12.21 But what is interesting is that the longer loops that we see WAPL depletion
00:19:17.05 -- that's shown here --
00:19:19.09 indeed occur as discrete dots on these Hi-C matrices.
00:19:24.10 So, it's not a range of long-range interactions;
00:19:26.09 it's very discrete longer loops that can be seen.
00:19:30.15 And if one looks at the sequences underlying the anchors of these loops,
00:19:34.02 it turns out that each of them represents
00:19:38.04 a CTCF binding site,
00:19:39.25 as if cohesin, now having a long residence time,
00:19:42.09 would be able to sit long enough on DNA to go beyond one CTCF boundary,
00:19:47.05 but then would stop at the next one,
00:19:49.18 until it could go over that,
00:19:51.11 and then it then would stop at the next one.
00:19:53.26 Again, in analogy to the red streetlight model.
00:19:59.24 Now, if this was all correct,
00:20:03.02 then this loop extrusion hypothesis would make a number of predictions,
00:20:07.12 namely that the binding of cohesin that we had initially identified
00:20:11.24 by chromatin immunoprecipitation
00:20:14.15 as being found in very discrete peaks
00:20:17.18 -- I showed an example in Part I --
00:20:19.18 would in fact not represent how cohesin
00:20:23.26 really behaves on genomic DNA
00:20:26.07 but would basically be an image
00:20:30.21 that emerges from superimposing
00:20:33.25 the behavior of many cohesin complexes in large populations of cells.
00:20:37.05 And that in reality,
00:20:39.17 cohesin would be highly mobile in the genome.
00:20:41.14 It would be extruding loops all the time.
00:20:43.21 And only the complexes that would be stopped by CTCF
00:20:46.20 would then be present in these peaks
00:20:49.29 that one sees by chromatin IP.
00:20:53.05 So, the hypothesis was that
00:20:56.06 cohesin would be highly mobile
00:20:58.12 but would be constrained once it hits a CTCF site.
00:21:01.08 And another important prediction
00:21:04.07 would be that CTCF itself would not be important
00:21:09.05 for the long-range interaction
00:21:11.19 but would define where they are being formed.
00:21:14.05 It would be able to recognize a particular sequence
00:21:17.06 and thereby specifies what the loop anchor should be.
00:21:21.10 And so, both of these predictions have been tested by us and others, of course.
00:21:24.03 First, to the question, is cohesin mobile in the genome?
00:21:27.04 And is it constrained by CTCF?
00:21:29.14 To test this, we have depleted CTCF, initially by RNAi...
00:21:33.12 in this experiment, by using a mouse model provided by Niels Galjart
00:21:36.17 where, inducibly, the CTCF gene could be deleted.
00:21:41.10 And when we did that, we indeed found that
00:21:45.03 cohesin no longer... would now accumulate to the same extent at CTCF sites.
00:21:49.03 That's shown here,
00:21:51.26 where you're looking at chromatin immunoprecipitation results,
00:21:54.07 and you're looking at one of thousands of CTCF sites
00:21:57.00 that are present in mammalian genomes.
00:21:59.12 And you see that at the same site cohesin can be detected
00:22:03.23 -- also by ChIP, chromatin IP --
00:22:07.14 provided CTCF is there.
00:22:09.02 But if CTCF is depleted,
00:22:11.02 because the gene has been deleted,
00:22:13.00 now much less cohesin accumulates there.
00:22:15.20 That's true not just for this site but for thousands of sites.
00:22:19.18 Now, interestingly, what we hadn't expected is that
00:22:22.18 under these conditions cohesin accumulates at different sites.
00:22:25.13 As you can see here,
00:22:27.10 it often accumulates at the promoter of genes,
00:22:30.03 at transcription start sites,
00:22:32.28 for reasons that are not well understood.
00:22:35.07 But implying that, indeed,
00:22:38.07 cohesin is highly mobile in the genome
00:22:40.06 and not statically sitting at one site.
00:22:45.10 Now, that can be even seen more impressively or more clearly
00:22:49.29 in cells where not only CTCF has been depleted
00:22:52.20 but also the release factor WAPL.
00:22:55.01 And an example for that is shown here,
00:22:57.13 where again you're looking at chromatin immunoprecipitation results,
00:23:00.29 where you're seeing one of many thousand CTCF sites
00:23:06.13 which normally colocalizes with cohesin,
00:23:09.06 provided that CTCF is there.
00:23:11.20 As I just showed in the previous slide, if CTCF is depleted
00:23:15.20 then cohesin is no longer accumulating there to the same extent,
00:23:17.26 but now instead accumulates at transcription start sites.
00:23:21.20 One is here.
00:23:24.04 Another one is shown here, there.
00:23:27.18 But what is really interesting is what happens if, now,
00:23:31.00 in addition to CTCF... this condition... also WAPL is depleted.
00:23:34.22 So that now cohesin has neither its normal boundary
00:23:38.12 nor its short residence time,
00:23:42.01 but instead a long residence time on chromatin.
00:23:44.00 And now you can see a very dramatic effect,
00:23:45.29 namely that cohesin accumulates in very large regions
00:23:48.18 -- not looking like a regular peak --
00:23:51.03 and these so-called cohesin islands, as we call them,
00:23:55.18 are typically found at the 3' end of active genes,
00:23:59.05 in particular at the 3' end at loci
00:24:03.09 where two genes converge on each other.
00:24:06.02 One is being transcribed from left to right
00:24:08.05 and the other from the other strand from right to left.
00:24:10.24 And at these convergent locations,
00:24:14.01 cohesin now is accumulating,
00:24:16.24 provided there was no CTCF as a boundary and WAPL was depleted,
00:24:20.27 so it has a long residence time,
00:24:23.12 implying that, yes,
00:24:25.22 it must be highly mobile in the genome
00:24:27.12 -- it's probably moving around all the time --
00:24:29.26 but normally is seen accumulating in cell populations at CTCF sites,
00:24:34.15 but then can go to very different places
00:24:38.20 if these boundaries are gone.
00:24:41.10 So, that's clearly consistent with the loop extrusion hypothesis.
00:24:45.12 Now, what do we know about the role of CTCF in this process?
00:24:47.29 The loop extrusion hypothesis
00:24:49.26 posits that it would not be needed
00:24:52.16 for forming long-range interactions
00:24:54.15 but instead would specify which sequences form these interactions.
00:24:57.27 And indeed, the data that we and others have
00:25:00.16 are consistent with this idea.
00:25:02.03 Again, if we look by Hi-C,
00:25:04.10 in the presence of CTCF or in cells depleted of CTCF...
00:25:09.17 this experiment was not done genetically, but again
00:25:14.17 by using auxin-induced degradation of CTCF, in this case.
00:25:17.13 First of all, we can see that superficially
00:25:19.27 the two Hi-C patterns look very similar.
00:25:22.05 You see there's still a lot of interactions present.
00:25:26.02 And one can analyze this, also, genome-wide
00:25:28.22 by plotting all the interactions,
00:25:31.14 as shown in this graph down here,
00:25:33.25 on the y axis as a function of their genomic distance on the x axis.
00:25:39.03 And this graph must look to you like
00:25:43.24 just one line,
00:25:46.22 but in reality, it is two lines superimposed,
00:25:48.17 one representing the distribution of interactions in the control cells that have CTCF,
00:25:53.00 and the other representing the interactions in cells
00:25:56.10 depleted for CTCF.
00:25:58.13 So, the result is there is no change.
00:26:00.12 The interactions are still all being formed,
00:26:02.24 and their number is roughly similar,
00:26:05.10 and their length distribution in the genome is also roughly similar.
00:26:09.09 So, that clearly tells us that
00:26:12.25 CTCF can't be essential for the formation of these interactions.
00:26:16.03 That's because we think cohesin is mediating them.
00:26:20.19 Now... but if you look more carefully, you can...
00:26:23.01 you can appreciate two differences,
00:26:24.21 and they're interesting.
00:26:26.19 First of all, one can see, if one looks very carefully,
00:26:31.11 as explained at the beginning,
00:26:33.20 that at the... at the corner of these TADs there are often these dots,
00:26:40.05 which we think are loops that have been formed.
00:26:44.20 And they can no longer be clearly detected
00:26:48.02 after depletion of CTCF, as you can see here.
00:26:51.08 The arrows are pointing at this.
00:26:53.15 And genome-wide, one can quantify this using special algorithms
00:26:56.28 -- that's shown in the histogram on the bottom --
00:27:00.28 where you can see that the number of loops one can algorithmically detect
00:27:05.02 after CTCF depletion is much reduced.
00:27:09.07 And a similar phenomenon is seen
00:27:11.21 if one looks at the boundaries between TADs,
00:27:13.28 which, in the presence of CTCF,
00:27:16.19 appear as relatively distinct and sharp boundaries,
00:27:21.06 but, after depletion of CTCF,
00:27:24.19 now are much more fuzzy.
00:27:28.02 And that can, again, be genome-wide analyzed algorithmically
00:27:32.01 as a so-called TAD insulation score.
00:27:34.25 And one can see that this is much reduced after...
00:27:38.20 not abolished but reduced... after CTCF degradation.
00:27:42.29 So, what these results imply is that
00:27:45.26 CTCF is indeed needed for the insulation of TADs,
00:27:51.08 presumably because it's normally sitting there
00:27:54.22 and functions as a boundary for extruding cohesin complexes.
00:27:59.16 And the fact that one can no longer detect so many loops in the absence of CTCF
00:28:03.16 is presumably not because these loops are not being formed
00:28:06.03 -- we think they are all there --
00:28:08.10 but no longer they are confined exactly
00:28:11.21 to the CTCF binding site as a sequence anchor.
00:28:14.09 Because without CTCF,
00:28:16.16 cohesin can now go a little further than normally,
00:28:19.11 and would form loops that are less specified, less defined,
00:28:24.02 in these large cell populations that are being analyzed here.
00:28:28.04 So, these data are consistent
00:28:30.17 with the idea that cohesin is essential
00:28:33.09 for TADs and loops.
00:28:34.22 I showed you that at the beginning.
00:28:37.01 It forms clearly longer loops
00:28:39.21 if WAPL is depleted and cohesin now has a longer residence time.
00:28:43.11 And clearly, cohesin must be highly mobile in the genome,
00:28:46.16 and what we typically see in chromatin IP experiments
00:28:49.27 is just the average of where most cohesin has accumulated,
00:28:54.01 but not really showing us where, in individual cells,
00:28:56.22 cohesin would be present while extruding loops.
00:29:01.01 And for CTCF, the data are consistent with the idea
00:29:04.17 that it's not essential for the extra-long-range interactions,
00:29:07.14 because these are mediated by cohesin,
00:29:10.03 but is needed to specify them by telling cohesin
00:29:12.06 where to stop the local extrusion process.
00:29:16.09 And that would then form these
00:29:19.20 less sharp TAD boundaries
00:29:22.15 and would result in the reduction of loops
00:29:26.15 that can be detected.
00:29:28.08 Now, these phenotypes...
00:29:30.13 in the case of CTCF depletion, are clearly not null phenotypes.
00:29:32.28 You can see there are still some TAD boundaries.
00:29:35.27 And so, an important question for the future will be,
00:29:37.26 is that because CTCF wasn't fully degraded?
00:29:39.20 We think it is not by this AID system,
00:29:41.24 so that could be one reason.
00:29:43.15 But of course, it could also be that there's other boundaries,
00:29:46.10 or other molecules that contribute to a boundary function,
00:29:49.03 and that's why CTCF depletion has a partial loss of TAD insulation
00:29:52.28 and not a full phenotype.
00:29:55.13 That remains to be explored.
00:29:57.29 Now, towards the end, let me briefly discuss with you
00:30:02.07 what we know, or don't,
00:30:04.06 about the really important question, then,
00:30:06.07 of how cohesin, in mechanistic terms,
00:30:08.11 might be forming chromatin loops,
00:30:10.14 and in particular whether it does so by loop extrusion.
00:30:13.25 Now, the short answer is we don't know.
00:30:16.00 But before I summarize for you what we know but cohesin,
00:30:19.10 let's... let me turn to cohesin's cousin,
00:30:22.16 the condensin complex,
00:30:24.11 which as I mentioned is thought to be responsible
00:30:27.23 for forming long chromatin loops on mitotic chromosomes,
00:30:31.09 and thereby condensing these chromosomes.
00:30:35.19 And very recent work from Christian Haering and Cees Dekker
00:30:38.27 has shown that if one prepares or isolates these complexes
00:30:41.20 -- the condensin complexes --
00:30:44.03 from budding yeast and uses them in similar assays to... the microscopy assays...
00:30:48.22 to the ones I've just shown,
00:30:52.11 one can indeed see that these yeast condensin preparations
00:30:55.02 have an activity which is able to extrude a loop.
00:30:58.00 That's extremely exciting.
00:30:59.24 It was published last year.
00:31:02.02 That's just to remind you that cohesin and condensin are complex...
00:31:05.09 the complexes are related,
00:31:07.14 and they both accumulate in axial elements
00:31:10.19 under the right conditions.
00:31:12.14 Now, if we watch this movie,
00:31:15.18 you can see here a DNA molecule
00:31:17.28 that's tethered at both ends to a glass surface
00:31:22.25 under buffer flow.
00:31:23.23 And you will see in a minute that
00:31:26.06 one arm of this synthetic DNA loop, if you wish,
00:31:29.11 is shortened at the expense of a new loop
00:31:32.24 that's being formed here,
00:31:35.18 coming out of this doubly tethered DNA molecule.
00:31:38.29 The idea being that condensin must be sitting here,
00:31:42.02 in the center of this doubly tethered DNA molecule,
00:31:45.06 and must be pumping DNA from one side
00:31:48.23 into a loop structure.
00:31:53.20 And that's schematically shown in this illustration
00:31:57.28 from the paper from Cees Dekker and Christian Haering,
00:32:01.06 according to which condensin
00:32:04.26 must be sitting on this doubly tethered DNA molecule
00:32:07.19 and must be pumping DNA from it
00:32:10.27 into such a loop-like structure, as you can see here.
00:32:15.14 Now, such an activity has not been seen for cohesin yet,
00:32:18.26 but this type...
00:32:21.19 this result clearly illustrates
00:32:24.05 that members of the Smc family must have activities
00:32:26.15 that are able to form DNA loops.
00:32:31.27 Now, that raises the really interesting question
00:32:34.21 of whether cohesin can not only function
00:32:37.16 as a topological linker,
00:32:39.11 as which it is thought to function when it mediates cohesion
00:32:42.04 by embracing the two sister DNA molecules inside its ring structure,
00:32:46.10 but whether it can actively form chromatin loops,
00:32:49.22 and perhaps therefore is a molecular motor,
00:32:52.27 more related to other motor proteins like kinesins or myosins or dynein,
00:32:58.09 and whether it could use its ATP binding and hydrolysis activity,
00:33:01.06 which it clearly has,
00:33:03.12 for that purpose.
00:33:05.06 And very recent experiments performed in my laboratory
00:33:08.07 by Maxim Molodtsov and Benedikt Bauer
00:33:12.24 have indeed provided evidence that cohesin has such a motor function.
00:33:18.01 This evidence comes from experiments in which
00:33:21.23 we have tethered cohesin to a glass surface
00:33:24.11 with one of its subunits
00:33:26.22 and then connected one of the other Smc subunits to a long handle,
00:33:31.12 a coiled-coil, which again is connected with a bead,
00:33:36.23 the position of which can be controlled by a laser beam.
00:33:40.13 And this so-called optical tweezer type of experiment
00:33:44.01 allows, at the piconewton scale,
00:33:47.06 a measurement of forces that are generated by proteins
00:33:50.24 such as motor proteins.
00:33:53.00 And it turns out from these types of experiments that
00:33:57.04 indeed, under the right conditions,
00:33:59.05 cohesin is able to perform a power stroke,
00:34:01.28 to perform mechanical work,
00:34:04.08 which we think it uses to bend DNA.
00:34:08.13 And from these experiments,
00:34:11.09 which are not published yet,
00:34:14.06 we have reasons to believe, therefore,
00:34:17.19 that cohesin can not only form under...
00:34:19.23 sorry, can not only function as a passive linking molecule,
00:34:23.21 which it... is what it seems to do during cohesion,
00:34:28.02 but instead is an active motor,
00:34:30.23 and uses that activity to bend DNA.
00:34:32.25 And we've also found that the ATPase activity and the NIPBL protein,
00:34:36.24 which has previously been shown to load cohesin onto DNA,
00:34:39.17 are needed for this motor function.
00:34:42.03 And so, that quite radically changes our view
00:34:44.28 of how cohesin is functioning at the...
00:34:48.03 at the mechanistic level.
00:34:50.14 But at the same time, it raises many new questions,
00:34:52.14 in particular the ones that I have listed here,
00:34:54.23 namely how cohesin could bend DNA.
00:34:57.01 For that, it would have to be able to bind to it directly.
00:34:59.06 And so, we are trying to understand how it can do that.
00:35:03.25 The topological interaction that has been described before
00:35:06.29 would obviously not be sufficient for such a bending activity.
00:35:09.24 We would very much like to understand
00:35:12.10 whether this ability to bend DNA
00:35:15.26 and function as a motor
00:35:18.08 is important for structuring chromatin into loops and cells.
00:35:21.20 Again, that needs to be tested.
00:35:24.22 And obviously, it would be very important to know
00:35:27.18 whether this motor activity that we can measure by optical tweezer experiments
00:35:30.09 is required for loop extrusion
00:35:35.03 for the type of DNA loop formation that Cees Dekker and Christian Haering
00:35:37.19 have observed for yeast condensin,
00:35:39.14 but no one has observed for cohesin yet.
00:35:41.27 And so, these are very exciting questions for the future
00:35:45.05 that I'm sure the field will answer in the coming years.
00:35:49.09 Now, I would like to thank you again for your attention,
00:35:52.21 but also my former and past members of the lab,
00:35:56.24 who have done fantastic work
00:36:00.13 which has contributed to the knowledge that I have summarized here,
00:36:02.25 as well as to all other colleagues in the field
00:36:06.18 that have contributed to what I told you about today.
00:36:10.00 And last, but not least,
00:36:12.04 to our shareholders and funding agencies,
00:36:14.00 which have made our work possible.
00:36:15.20 Thank you very much.

Videos in this Talk

Part 1: Cohesin: Roles Beyond Sister Chromatid Cohesion?
Audience:
- Student
- Researcher
- Educators of H. School / Intro Undergrad
- Educators of Adv. Undergrad / Grad
Part 2: How do Cohesin and CTCF Fold DNA in Mammalian Genomes?
Audience:
- Researcher
- Educators of Adv. Undergrad / Grad

Speaker: Jan-Michael Peters

Total Duration: 1:09:47

Recorded: May 2019

All Talks in Cell Biology

Talk Overview

It has been known for many years that the protein cohesin is necessary to join sister chromatids together before they are segregated during mitosis. Electron micrographs have shown that cohesin subunits form a ring complex which is thought to encircle the DNA keeping the chromatids together. When they need to separate during anaphase, the cohesin complex is removed by another set of proteins. In his first talk, Dr. Peters explains how observations that he and others made suggested that cohesin may have additional roles in the cell. For instance, cohesin is initially loaded onto chromosome arms at discrete sites and in much larger amounts than is needed for chromatid cohesion. Cohesin also was shown to co-localize on chromosomes with a DNA binding protein called CTCF. CTCF is known to regulate transcription by forming DNA loops. Peters explains that, taken together, these observations hinted at a role for cohesin and CTCF in folding DNA into loops to allow efficient packing of very large eukaryotic genomes into small cell nuclei, and regulating functions such as gene expression.

In his second talk, Peters presents evidence that cohesin is indeed necessary for genomic DNA to fold into loops. Long range DNA interactions such as loops can be detected using a technique called Hi-C. Using Hi-C, Peters shows that depleting cohesin removes DNA loops, while depleting the proteins that remove cohesin from DNA, results in bigger DNA loops. In addition, CTCF appears to recognize specific sequences that define the base of the loops. Incorporating all of this data, Peters describes a model in which DNA is extruded by cohesin to form a loop and the boundaries of the loop are determined by CTCF. Peters explains that many questions about the mechanism of DNA loop extrusion and its importance in cells remain to be answered.

Speaker Bio

Jan-Michael Peters

Dr. Jan-Michael Peters earned his Diploma in biology and his PhD in cell biology from the University of Heidelberg. He did a short post-doc with Werner Franke at the German Cancer Research Center (DKFZ), before moving to the Harvard School of Medicine to continue his training with Marc Kirschner. Peters returned to Europe in 1996… Continue Reading

Comments

mehdi says

August 24, 2019 at 4:08 am

Hi Amazing work

I really enjoyed the lecture as I just started working on CTCF and did not know too much about its relation with cohesin complex. Now I have a really better picture in my mind.

Thank you iBiology group for providing us such an amazing lectures.

Regards,
Mehdi

Reply
Sihong Yu says

August 17, 2021 at 3:04 am

These two videos are so amazing and logical! Thank you for doing this!

Reply

Part 1: Cohesin: Roles Beyond Sister Chromatid Cohesion?

Part 2: How do Cohesin and CTCF Fold DNA in Mammalian Genomes?

Talk Overview

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Jan-Michael Peters

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