El Dr. Jer és un investigador postdoctoral al New York Genome Center.

Quin era l'objectiu de la xerrada del Dr. Jer?

Discutir la importància de l'alternativa del splicing en cèl·lules individuals i el seu impacte en salut i malalties.

En quin camp es centra la recerca del Dr. Jer?

En el desenvolupament d'algoritmes per explorar l'estructura tridimensional del genoma i estudiar les isoformes d'ARNm.

Què és l'alternativa del splicing?

És un procés intermediari que ocorre entre la transcripció d'ADN a ARN i la traducció d'ARN a proteïna, que pot influir significativament en funcions cel·lulars i salut.

Per què és important estudiar les isoformes d'ARNm segons el Dr. Jer?

Perquè les diferents isoformes poden tenir impactes significatius en salut i malalties, alterant la funció i estructura de les proteïnes.

Quina tècnica ha desenvolupat el laboratori del Dr. Jer per estudiar les isoformes?

Han desenvolupat una tècnica anomenada 'scissor-seq' per obtenir lligams d'ARN complet en cèl·lules individuals.

Quin és un exemple d'un gen estudiat pel Dr. Jer?

Un dels gens estudiats és binan, implicat en malalties com l'Alzheimer.

El Dr. Jer considera que les isoformes són un punt focal en el desenvolupament de drogues?

Sí, argumenta que comprendre quina isoforma està expressada és crucial en el desenvolupament de medicaments.

Dr. Anoushka Joglekar, NY Genome Center, presents seminar at UGA Bioinformatics

00:46:33

https://www.youtube.com/watch?v=eR3SbNc8agw

Ringkasan

TLDREl Dr. Jer ha presentat la seva recerca sobre les isoformes d'ARNm i l'alternativa del splicing en cèl·lules individuals. En la seva xerrada, ha destacat com aquestes isoformes poden influir en la salut i la malaltia, evidenciant exemples com el gen cd33 en relació amb l'Alzheimer. A més, ha parlat de la metodologia desenvolupada pel seu laboratori per estudiar aquestes isoformes a través d'una tècnica anomenada 'scissor-seq'. També va mostrar dades sobre com aquestes isoformes poden variar entre tipus de cèl·lules i durant el desenvolupament del cervell. Jer ha subratllat la importància d'estudiar l'expressió específica d'isoformes tant en la investigació bàsica com en el desenvolupament de fàrmacs, destacant que fins a un 75% de gens poden expressar diferents isoformes depenent del tipus de cèl·lula.

Takeaways

👨‍🔬 Dr. Jer és un expert en genoma 3D i isoformes d'ARN.
🧬 L'alternativa del splicing afecta la salut i malalties com l'Alzheimer.
🔬 Desenvolupament de la tècnica 'scissor-seq' per estudiar isoformes.
🧠 Les isoformes varien entre tipus cel·lulars i durant el desenvolupament del cervell.
📊 75% dels gens poden expressar diferents isoformes en funció del tipus de cèl·lula.
🔍 Comprendre quin isoforma està expressada és crític per al desenvolupament de medicaments.
🧪 L'estudi se centra en teixit cerebral, explorant etapes del desenvolupament.
⚠️ Cal investigar més sobre el comportament de les isoformes al llarg del temps.
🌍 Importància de traduir recerques de models de ratolí a humans.
📚 Conferència valuosa per a professionals en biologia computacional i genòmica.

Garis waktu

00:00:00 - 00:05:00
Introducció de la Dr. Jer, investigadora en el Centre del Genoma de Nova York, que desenvolupa algoritmes per explorar l'estructura 3D del genoma. Presentació del seu treball en esplicació alternativa amb resolució de cèl·lula única.
00:05:00 - 00:10:00
La Dr. Jer parla sobre les isoformes d'ARN i la seva importància en la salut i la malaltia. Explica el procés d'esplicació alternativa i la seva influència en la complexitat del proteoma.
00:10:00 - 00:15:00
Discussió sobre l'esplicació alternativa com a específica de teixit, fins i tot dins d'un sol teixit. Descripció de la metodologia per estudiar les isoformes en cèl·lules individuals.
00:15:00 - 00:20:00
Explicació del mètode Scissor-seq per superar les limitacions del seqüenciament basat en gotes, permetent l'identificació d'isoformes transcriptòmiques completes en cèl·lules individuals.
00:20:00 - 00:25:00
Presentació dels estudis sobre teixit cerebral per examinar la variabilitat de les isoformes entre regions cerebrals i tipus de cèl·lules. Exemples de gens específics estudiats.
00:25:00 - 00:30:00
Troballes sobre la variabilitat de les isoformes entre cèl·lules i regions cerebrals, especialment en exons micro. Discussió d'exemples de diferències observades.
00:30:00 - 00:35:00
Investigació de la persistència de les observacions d'isoformes en diverses regions cerebrals al llarg del temps. Mètodes per categoritzar la variabilitat de les isoformes.
00:35:00 - 00:40:00
Estudi detallat de gens amb gran variabilitat d'isoformes en diversos tipus cel·lulars i etapes del desenvolupament. Exploració de patrons específics de canvis en les isoformes.
00:40:00 - 00:46:33
Conclusions sobre l'estudi de les exons extremadament variables i com les diferències en isoformes estan relacionades amb tipus cel·lulars específics i etapes de desenvolupament.

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Peta Pikiran

Pertanyaan yang Sering Diajukan

Qui és el Dr. Jer?
El Dr. Jer és un investigador postdoctoral al New York Genome Center.
Quin era l'objectiu de la xerrada del Dr. Jer?
Discutir la importància de l'alternativa del splicing en cèl·lules individuals i el seu impacte en salut i malalties.
En quin camp es centra la recerca del Dr. Jer?
En el desenvolupament d'algoritmes per explorar l'estructura tridimensional del genoma i estudiar les isoformes d'ARNm.
Què és l'alternativa del splicing?
És un procés intermediari que ocorre entre la transcripció d'ADN a ARN i la traducció d'ARN a proteïna, que pot influir significativament en funcions cel·lulars i salut.
Per què és important estudiar les isoformes d'ARNm segons el Dr. Jer?
Perquè les diferents isoformes poden tenir impactes significatius en salut i malalties, alterant la funció i estructura de les proteïnes.
Quina tècnica ha desenvolupat el laboratori del Dr. Jer per estudiar les isoformes?
Han desenvolupat una tècnica anomenada 'scissor-seq' per obtenir lligams d'ARN complet en cèl·lules individuals.
Quin és un exemple d'un gen estudiat pel Dr. Jer?
Un dels gens estudiats és binan, implicat en malalties com l'Alzheimer.
El Dr. Jer considera que les isoformes són un punt focal en el desenvolupament de drogues?
Sí, argumenta que comprendre quina isoforma està expressada és crucial en el desenvolupament de medicaments.

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Teks

Gulir Otomatis:

00:00:09
very awesome good morning everyone it's
00:00:12
my pleasure to introduce Dr Jer as
00:00:14
today's seminar speaker um Dr J lier is
00:00:18
currently a postdoc researcher at New
00:00:21
York genome Center where she's
00:00:23
developing algorithms to explore the 3D
00:00:26
structure of genome across different
00:00:28
cell types she got her PhD in
00:00:31
computation biology and medicine from
00:00:33
whale Coral medicine at Corell
00:00:36
University working in Tingler lab her
00:00:39
doctoral research focused on creating
00:00:41
algorithms and Technologies for studying
00:00:43
alternative splicing in the brain at
00:00:46
single cell and single nucleus
00:00:48
resolution I've had the opportunity to
00:00:51
work with a few of the tools that she
00:00:53
has developed and they are really great
00:00:56
um I especially I'm especially grateful
00:00:58
to her for agreeing without visitation
00:01:00
when I invited her to present at today's
00:01:03
seminar so please join me in welcoming
00:01:06
Dr
00:01:09
juger um very nice to meet you in person
00:01:14
for the first time n yeah and uh thank
00:01:17
you for inviting me I'm very excited to
00:01:19
give this talk and um before I begin I
00:01:22
just want to say that everyone is
00:01:24
welcome to interrupt me at any point uh
00:01:28
I'd like to keep this as informal as
00:01:30
possible uh but of course we can save um
00:01:34
questions for the end as well so I'm
00:01:36
going to aim for this to be 40 to 45
00:01:38
minutes but if I run over just stop me
00:01:40
because sometimes that happens okay so I
00:01:44
actually have to figure out how to do
00:01:46
this um given that I've never shared a
00:01:51
keynote presentation before let's see
00:01:55
okay you see this right yeah we do see
00:01:58
see your screen okay and do you see like
00:02:01
um the full screen mode of the uh
00:02:05
presentation okay awesome
00:02:07
thanks okay so before we jump into the
00:02:12
actual science I wanted to First
00:02:15
discuss what um isoforms are why we
00:02:19
should even study them in single cells
00:02:22
what's the point of it all
00:02:25
so excuse me okay so we all know the
00:02:30
Dogma where we go from a DNA to an RNA
00:02:33
molecule um and the functional unit most
00:02:36
people will say is protein but for us
00:02:39
transcriptomics people it's the Gene and
00:02:42
uh this process of going from DNA to RNA
00:02:45
is called transcription and then from
00:02:47
RNA you get protein um in a process
00:02:50
called
00:02:51
translation and often times what is
00:02:54
ignored is there's an intermediate step
00:02:58
between um transcript description and
00:03:00
translation and that step is called
00:03:02
alternative splicing so the way that
00:03:06
works is that you have a very complex
00:03:10
um like a complex col spical complex and
00:03:15
it's a collection of proteins it's got
00:03:16
about a 100 or so proteins and what it
00:03:19
does is that it spices out um introns uh
00:03:23
or junk DNA from your or junk RNA from
00:03:27
your RNA molecule and along with the
00:03:29
anons it also spices out certain exons
00:03:32
so you get like this combinatorial
00:03:35
expansion of um isoforms these are
00:03:39
called RNA isoforms which then get
00:03:42
translated into protein isoforms so as I
00:03:45
said it like combinatorially expands the
00:03:49
proteome and uh one of my favorite like
00:03:52
illustrations of this is that the worm
00:03:56
mice and humans we all approximately
00:03:58
have the same gene which is why we use
00:04:00
worm and mice as model organisms right
00:04:04
and I would argue that as we go down
00:04:07
this trajectory we get increasingly
00:04:10
complex and one source of this
00:04:12
complexity is the fact that each um Gene
00:04:16
and a worm is only represented as one
00:04:19
isopor versus in humans there can be up
00:04:22
to 10 sometimes hundreds of isoforms per
00:04:25
Gene and if this hasn't convinced you um
00:04:28
isoforms aren't just like tweaking the
00:04:31
proteins a little bit they actually do
00:04:33
make uh quite big impact in health and
00:04:36
disease
00:04:38
so here is a uh Gene called cd33 and
00:04:43
it's a microgo so like an immune Gene
00:04:46
and the M like capital M isopor has two
00:04:51
um alternative exons which are included
00:04:54
and the small m is um not the canonical
00:04:58
version and that this Exon and that
00:05:02
actually um is neuroprotective in terms
00:05:05
of Alzheimer's disease and the first one
00:05:07
is neurotoxic so depending on what
00:05:09
isopor you have it literally makes a
00:05:12
difference between health and disease in
00:05:13
some cases life and death um there's
00:05:16
different types of alternative splicing
00:05:18
and the one that I just showed and what
00:05:20
is the most commonly seen in mammals is
00:05:23
Exxon skipping so you either have or
00:05:25
don't have excuse me this red isopor and
00:05:28
then you can have a bunch of other types
00:05:31
uh depending on whether you're skipping
00:05:33
two at a time or you have a shorter Gene
00:05:36
because of the first or the last
00:05:38
isoforms being included or
00:05:41
excluded so splicing can be tissue
00:05:44
specific uh meaning that you can have
00:05:46
the same gene have two different
00:05:47
isoforms and say the brain versus the
00:05:49
gut and as you know genes don't occur in
00:05:53
like a isolated form they have Gene Gene
00:05:56
interactions protein protein
00:05:57
interactions so it can have a lot of
00:05:59
Downstream effects based off of where
00:06:01
your isopor is expressed and then um
00:06:05
it's not just tissue specific even
00:06:07
within tissues it can have differences
00:06:10
so that's kind of what I was studying
00:06:12
and in my case I was studying the brain
00:06:14
but there's other tissues such as the
00:06:16
liver that make use of isoforms quite
00:06:19
frequently for regulation so there can
00:06:21
be different regions of the brain
00:06:23
expressing different isoforms and to
00:06:25
make matters more complicated you can
00:06:27
have different cell types um when I
00:06:30
started my PhD this was new so this
00:06:32
slide is now not quite out of date but
00:06:34
everyone knows um how single cell is
00:06:37
studied and usually speaking there's
00:06:40
some degree of droplet based
00:06:42
microfluidics um and that's like the way
00:06:45
to get High throughput um single cell
00:06:47
RNA signal but of course there's other
00:06:49
methods and um you would generally
00:06:52
represent that in a tne uh one second
00:06:56
I'm just going to skip a couple slides
00:06:57
because we don't need these
00:07:00
uh one thing I do want to say is that um
00:07:03
droplet based RNA seek while capturing
00:07:06
single cell information doesn't capture
00:07:09
the full information and the reason for
00:07:10
that is that it is three or a five Prime
00:07:14
quantification method for the most part
00:07:16
smart seek or other versions aren't just
00:07:19
three prime Quant but um 10x for example
00:07:23
pars these um have three or five Prime
00:07:27
bias what that means from an isopor
00:07:29
perspective if you look at the full um
00:07:33
formulation what you'll find is that you
00:07:35
know you could maybe be sequencing this
00:07:38
end of your read and you could maybe
00:07:40
tell that this is a protein C versus
00:07:43
protein A or B being expressed but for
00:07:46
the most part you wouldn't really be
00:07:47
able to tell the difference between
00:07:49
proteins A and B if you got you know 10x
00:07:52
3 Prime sequencing for example so to
00:07:55
circumvent this our lab came up the
00:07:58
tilgner lab came up with
00:07:59
um method called scissor seek and it's
00:08:02
very simple it's really not rocket
00:08:05
science the way it works is you follow
00:08:07
your um short rate sequencing Paradigm
00:08:10
the way you normally would and what we
00:08:13
do is we reserve half of our um cdna and
00:08:18
we do this pref fragmentation so what
00:08:21
that means is that we can send half of
00:08:24
that cdna the same like like a different
00:08:26
aload of the same sample for long rate
00:08:29
sequencing
00:08:30
and because the long raid will contain
00:08:32
the entire isopor but also contain the
00:08:35
barcodes um we can figure out which
00:08:38
barcode is coming from which single cell
00:08:41
and then you can basically identify um
00:08:44
and Trace back fulllength transcripts to
00:08:47
their cell cell and then we usually work
00:08:50
on a cell type level because of
00:08:52
throughput um so you can get cell type
00:08:55
specific
00:08:56
isoforms so this happened in like my
00:08:59
first first ISS of my PhD and then once
00:09:02
we had this method up and running we
00:09:04
wanted to use it um on brain tissue
00:09:09
so what we wanted to do was find out um
00:09:13
a couple things firstly we looked at a
00:09:16
very young so postnatal day seven which
00:09:18
is think of it like as a baby mouse um
00:09:22
and we wanted to find out if there are
00:09:25
two different brain regions say the
00:09:26
hippocampus and the prefrontal cortex
00:09:29
which which are both important for
00:09:30
memory cognition all of the high level
00:09:33
processes that we have in mammals um if
00:09:37
you look at these two different brain
00:09:38
regions firstly for the same cell type
00:09:41
let's say asites found between
00:09:43
hippocampus and PFC do we see
00:09:46
differences in isopor I said that there
00:09:48
was Regional variability but to what
00:09:50
extent do you find it and then the
00:09:52
second thing was within a single brain
00:09:54
region what is the extent of isopor
00:09:57
variability between different cell types
00:09:59
is it that you know like 90% of the
00:10:02
genes are expressing the same isopor in
00:10:05
different cell types or is it like um
00:10:08
much much lower and isoforms play a
00:10:11
pretty big regulatory role so I'm not
00:10:14
going to give too much detail about this
00:10:16
but the punch line is that there is a
00:10:19
lot of variability uh both between and
00:10:22
within regions for the between regions
00:10:25
we found about 400 genes that are pretty
00:10:28
highly implicated
00:10:30
um in Regional variability and we found
00:10:32
like changes on the level of what we
00:10:35
call microexons so like 15 to 30 base
00:10:37
pairs that can change the protein
00:10:40
structure um and therefore probably
00:10:42
change the function um I'll just focus
00:10:45
on an example in the hippocampus so we
00:10:48
looked at not just within cell types
00:10:51
like asites versus neurons but we looked
00:10:55
at um within neuronal types so here I'm
00:10:59
going to show you a gene called fgf13
00:11:02
it's a growth Gene it peaks in
00:11:04
expression right around this p7 PA time
00:11:08
point and what I'm showing you here is a
00:11:10
heat map on the like rows we have two
00:11:15
isoforms the S is the short and the VY
00:11:18
is the long isopor and notice that the
00:11:21
only difference between them is where
00:11:23
this one starts versus this one starts
00:11:25
so this is happening on the five Prime
00:11:27
end not something you would be able to
00:11:29
see using just 10x sequencing and it's
00:11:32
colored by the degree to which the
00:11:35
isopor is expressed so we call it Pi Pi
00:11:38
per inclusion of an isopor and what
00:11:41
you'll notice is that the excitatory
00:11:44
neurons which are this middle section
00:11:46
here
00:11:47
exclusively um Express the short isopor
00:11:51
versus the other neurons and
00:11:53
particularly I want to draw your
00:11:54
attention to V uh inhibitory neurons
00:11:57
they modulate the expr expression of
00:11:59
both of them to varying degrees and when
00:12:03
we did some overexpression studies what
00:12:05
we found was that the S isopor not only
00:12:09
is it expressed differently in different
00:12:11
cell types but where it's expressed
00:12:13
where it's localized within the cell in
00:12:15
this case it's the nucleis in this case
00:12:17
it's the entire cytoplasm um that also
00:12:20
makes a difference so you definitely
00:12:23
know that there is some degree of
00:12:25
functional uh variation depending on
00:12:28
which isopor is being expressed and this
00:12:30
is not just for like big cell types but
00:12:33
at a pretty granular granular level of
00:12:36
cell subtypes um this is unsolicited
00:12:40
advice but this was this um whole
00:12:43
example came about because I had a
00:12:45
friend called Susan well she wasn't
00:12:48
really a friend I didn't know her but
00:12:49
she saw me give a talk uh about this in
00:12:52
like an internal forum and she was like
00:12:55
oh would you mind looking at this Gene
00:12:58
because I think they're could be
00:12:59
something here um so I encourage you
00:13:03
during your PhD talk to your friends
00:13:05
give as many talks as you can um that
00:13:08
way something cool can come out of it um
00:13:10
for both you and your uh
00:13:13
collaborator so this is um within the
00:13:17
brain regions and then another thing we
00:13:19
did to sort of validate the between
00:13:22
brain region thing was spatial
00:13:24
sequencing was just coming out so 10x
00:13:26
had this like beta version of their
00:13:30
um what's Zoom platform and we got
00:13:33
access to it so what we wanted to do was
00:13:35
see if um or the signal that we found of
00:13:39
regional variability in isoforms could
00:13:41
we see that using slide seek or whatever
00:13:43
visium Plus long rate sequencing and
00:13:47
indeed we find that to be true so snap
00:13:50
25 is another developmental Gene it
00:13:53
Peaks again in expression actually I
00:13:56
don't think it peaks in expression what
00:13:58
happens is that there's a known switch
00:14:00
uh from isopor A to B that happens at
00:14:04
this p7 p8 um time point in postnatal
00:14:08
development and um we find that this
00:14:11
switch is very very visible just at a
00:14:15
snapshot in time so the a isopor again
00:14:18
I'm showing you a very similar plot to
00:14:20
before except it it's not a heat map
00:14:21
anymore um each dot here represents a
00:14:24
spot on the visium um slide and yellow
00:14:28
means that it's expressed highly black
00:14:31
means that it's expressed lowly and so
00:14:33
the young isopor or the young Exxon is
00:14:37
expressed in the front of the brain and
00:14:39
the old Exxon or like older um isopor is
00:14:43
expressed in the back of the brain and
00:14:45
this is kind of a known thing that the
00:14:47
brain sort of develops in a back to
00:14:51
front manner um with the cerebellum
00:14:54
becoming more active as you can see like
00:14:56
you know kids don't have that much
00:14:58
prefrontal cortex or cognitive
00:15:00
capabilities that's because it's kind of
00:15:02
slower um and so you can really see that
00:15:05
dynamism in action just even at a single
00:15:08
snapshot Okay so we've established at
00:15:11
this time Point um and you can read more
00:15:14
about it in this paper um that isoforms
00:15:18
change on a brain region level isoforms
00:15:21
change on a cell type level and they
00:15:23
change on a cell subtype level but now
00:15:25
there's more questions that remain um so
00:15:29
so first thing do these observations
00:15:31
that we made at the postnatal time point
00:15:33
do they persist a along different brain
00:15:37
regions b along different time points
00:15:40
and the main question and I don't think
00:15:43
I've gotten even close to answering it
00:15:46
but in humans what happens because we
00:15:48
use mice as model organisms a lot but if
00:15:52
you can't use what you've learned from
00:15:55
mice and like extrapolate that to human
00:15:58
what is the point
00:15:59
um or can we can we finesse um the genes
00:16:02
in which we can actually model things
00:16:04
versus we cannot so this last part I
00:16:08
won't talk about too much given time
00:16:10
constraints but if we do get to it um
00:16:13
I'll talk about how we optimize the
00:16:16
scissor seek protocol to be used in
00:16:17
Frozen tissue but if I don't get to it
00:16:20
um you can read about it in this paper
00:16:23
okay
00:16:25
so what we did to ask about this
00:16:28
persistence over regions as well as time
00:16:31
is we uh designed a study wherein we
00:16:34
would kind of sequence everything we
00:16:36
would sequence space which is different
00:16:38
brain regions at an adult time point and
00:16:41
two brain regions the visual cortex and
00:16:44
the
00:16:45
hippocampus um overdevelopment and the
00:16:48
reason we chose this was because we were
00:16:50
part of the a Consortium and they really
00:16:53
wanted to focus on particular brain
00:16:55
regions excuse me but I think this was a
00:16:58
very good pan
00:16:59
because uh these two brain regions
00:17:02
capture a lot of like cognitive and
00:17:04
memory and all this development versus
00:17:07
these are more
00:17:09
um like they they take care of a lot of
00:17:12
involuntary processes and Regulation and
00:17:15
things like that okay so we got these 11
00:17:20
time points and we sequence single cell
00:17:22
samples from there um and there were two
00:17:25
replicates for each so we ended up with
00:17:26
about 200,000 cells which again now
00:17:29
doesn't seem like a lot but when we
00:17:31
started definitely did and um this is
00:17:34
just a you map showing what um the cell
00:17:38
types were and um what I want to point
00:17:41
out is that this is like the entire data
00:17:44
set right but there's so much to explore
00:17:47
how do we go about exploring it so one
00:17:50
thing we did was we first broke it down
00:17:52
by uh time point and brain region so you
00:17:55
have this brain regions um showing
00:17:58
different um colocalization and whatever
00:18:01
you map things which you don't want to
00:18:03
read too much into but you can see the
00:18:05
different brain region specific say
00:18:08
neurons for example and you can do the
00:18:10
same for age so if we want to study how
00:18:14
not like how the gene expression changes
00:18:16
but how isoform expression changes um
00:18:19
there's different axes of variability of
00:18:22
this so you can have the region like I
00:18:25
said the age or you can have cell
00:18:27
subtype and so so we wanted to go about
00:18:29
this in first like a very broad Strokes
00:18:33
kind of way to see what are the broad
00:18:36
changes brought about by development and
00:18:39
brain region um uh changes so how we
00:18:44
measured this was I'm going to go
00:18:46
through an illustrative example and then
00:18:48
go into actual examples so let's
00:18:52
consider Gene called XYZ or whatever and
00:18:56
there's five isoforms for the Gene and
00:19:00
this is a given cell type so it's it's
00:19:02
not
00:19:03
overall um what we can do is we can
00:19:06
measure that pi value that I said the
00:19:08
percent isopor and we can measure that
00:19:11
along all three axes so the first one is
00:19:13
region and then you can do the same for
00:19:15
cell um subtype and time and what we do
00:19:20
is we to measure the variability we just
00:19:23
look at the max of the Delta Pi in most
00:19:26
cases you're going to have a pretty un
00:19:28
uniform expression or that's what we
00:19:30
assumed um but in some cases you might
00:19:33
have one or two outliers that are very
00:19:36
different in how they express a certain
00:19:38
isopor and this was informed by our
00:19:40
previous study so you can find this Max
00:19:43
Delta Pi for the region and the other
00:19:45
two axes and um then you can represent
00:19:50
that as a vector so um 30 20 35 in this
00:19:54
case is the change in the Delta pi and
00:19:58
you can do the same for not just this
00:20:00
isopor but all isoforms and so you can
00:20:02
have a matrix instead of a vector and
00:20:05
what we did was we not R normalized it
00:20:08
and it has a couple benefits and a
00:20:10
couple um disadvantages so what you can
00:20:14
do is you can represent this in a Turner
00:20:17
plot or a Simplex whatever you want to
00:20:19
call it so it's kind of like a scatter
00:20:21
plot except it has three axes instead of
00:20:23
Two And depending on which triangle it
00:20:28
ends up in you know that that particular
00:20:31
isopor is either subtype or region or
00:20:35
age specific um the center triangle is
00:20:38
this like kind of complic it's not
00:20:39
complicated but it's like this weird
00:20:41
place where it can either be all low or
00:20:44
all high because we have normalized it
00:20:47
and there's no real way of telling them
00:20:48
apart just visually but what we were
00:20:51
interested in which axis is like the
00:20:54
most um important for a given cell type
00:20:59
so what we find is that excitatory
00:21:01
neurons here each uh dot is an isopor
00:21:05
and this is true for like I don't know
00:21:07
12 or 15,000 genes um they all sort of
00:21:12
like colocalize to the bottom triangle
00:21:15
so this is a subtype triangle and um and
00:21:19
it's not just the subtype right so what
00:21:21
we look at is is a gene uh if a gene has
00:21:25
multiple isoforms are there are they all
00:21:29
in the subtype triangle and so that's
00:21:30
like a gene expression change or are
00:21:33
they in multiple triangles meaning that
00:21:35
this is true isopor regulation and so
00:21:38
that's something I've represented in
00:21:39
this like Network diagram and what we
00:21:42
find is that for most genes the subtype
00:21:46
variability is usually accompanied by
00:21:50
something else um one of the other axes
00:21:53
but subtype variability is the most
00:21:56
predominant and so we find this very
00:21:58
exory neurons and when you switch when
00:22:00
you go into other cell types you find
00:22:03
that uh the pattern looks different so
00:22:05
in this case it's mostly on the bottom
00:22:07
right here it's like the bottom and here
00:22:09
it's the top and left so really
00:22:12
different cell types have different ways
00:22:15
in which their isoforms change and this
00:22:18
would be what I would call the broad
00:22:19
strokes and then what you can do is you
00:22:22
can sort of zoom in on individual um
00:22:26
genes to see like you know are there
00:22:29
genes that Express variability across
00:22:31
different cell types and across
00:22:33
different axes so I isolated a few I
00:22:36
forget how many I'm sorry but here is a
00:22:39
gene called ruy 3 and I call this a
00:22:42
hypervariable gene and the reason for
00:22:44
that will become apparent in a minute so
00:22:48
here are six seven seven isoforms for
00:22:52
this Gene and what I'm going to show you
00:22:55
is um for a given cell type this
00:22:57
triangle plot that I showed you
00:23:00
previously um and below that triangle
00:23:02
plot I'm going to also show you what the
00:23:04
isopor percentage so Pi uh that I showed
00:23:08
you
00:23:09
before is for different ages and here
00:23:12
you'll see that for the most part um
00:23:15
it's kind of distributed but for this
00:23:17
purple um isopor the p28 time point is
00:23:21
kind of like
00:23:23
special uh so this is true for
00:23:25
progenitors and then if you look at some
00:23:27
other cell type you'll see that the heat
00:23:29
map starts looking different so I point
00:23:31
out a couple things for example
00:23:33
excitatory neurons at all ages seem to
00:23:36
prefer this second isopor versus
00:23:39
astrocytes at all ages seem to prefer
00:23:42
this pink isopor and again if you like
00:23:45
start staring more and more at this
00:23:47
you'll notice that oh it's not just the
00:23:49
fact that it's an isopor change it's
00:23:50
like how is that affecting the protein
00:23:52
how are the ends being folded in the
00:23:55
protein structure and you can like
00:23:56
really go down a rabbit hole
00:23:59
depending on what Gene you're looking at
00:24:01
another thing I want to point out is
00:24:02
that in the immune cells you go from one
00:24:06
isopor being used to a different isopor
00:24:09
being used to again some diffus sort of
00:24:11
structure so if there's anything you can
00:24:15
take away from this is that these
00:24:17
isoforms can get really really
00:24:18
complicated really really fast and
00:24:21
that's true for not just age but regions
00:24:24
as well as cell types and um don't
00:24:27
ignore your forms guys is is all I'm
00:24:30
saying um and you can find this
00:24:32
information like you can explore these
00:24:34
genes in more detail on this isopor
00:24:37
atlas.com um but the point is that we
00:24:41
found something like 75% of genes
00:24:44
Express um different isoforms across at
00:24:47
least one axis which is kind of crazy so
00:24:51
not only do different cell types have
00:24:53
different genes being expressed but 75%
00:24:56
of genes have a different isopor
00:24:58
depending on which cell type you're
00:24:59
looking at okay so this is the broad
00:25:02
Strokes version now we want to zoom in
00:25:04
so what we did was we looked at
00:25:06
something called extremely variable
00:25:07
exons and the reason for that is as you
00:25:10
can see these different isoforms have so
00:25:12
many moving Parts how do you know what's
00:25:15
what's changing so we focused on
00:25:17
individual exons and uh the way we did
00:25:20
this was this is just for illustrative
00:25:22
purposes but let's say you have two uh
00:25:26
cell types like one cell types cell type
00:25:28
present across two different brain
00:25:31
regions in adulthood what you can do is
00:25:34
you can measure the change in Exxon
00:25:36
usage across these two brain regions and
00:25:40
um I would call that brain region
00:25:42
specific difference and if that change
00:25:45
is more than 75% I think that was our
00:25:48
arbitrary cut off then we report that as
00:25:51
something being extremely variable for
00:25:54
adult brain region specific differences
00:25:56
you can do the same with the
00:25:59
um like a map for different cell types
00:26:02
as well as within a developmental time
00:26:04
point so we're calling that
00:26:05
developmental cell type uh differences
00:26:08
and finally you can do it over time um
00:26:11
like how is the isopor landscape
00:26:14
changing within an olgod dendrite
00:26:17
population over time so we isolated
00:26:21
these extremely variable exons and that
00:26:23
came out to be about 600 something exons
00:26:27
Manning fewer genes and if you notice
00:26:31
straight off the bat there's this one
00:26:33
giant cluster in the middle and what
00:26:36
that cluster is is it's both adult and
00:26:39
developmental cell type spe specific
00:26:41
differences now this is not a surprising
00:26:44
thing because you do know like we do
00:26:47
know that big cell types like neurons
00:26:50
versus glea are going to have pretty
00:26:53
large differences regardless of which
00:26:55
time point or which brain region you
00:26:57
look at and um that is exactly what we
00:27:01
found uh in this network diagram I'm
00:27:03
showing where the differences came from
00:27:05
so the on the right are neurons and the
00:27:07
left are Gia and as you can see there's
00:27:10
nothing connecting the neurons and
00:27:12
nothing connecting the Gia meaning that
00:27:14
this is Neuron versus Gal changes that
00:27:17
we're seeing the most unsurprising but
00:27:20
the cool thing about it is like we went
00:27:22
and looked at not just particular genes
00:27:25
but the protein domains um that these in
00:27:28
code and it's funny that there's like
00:27:31
these uh fibronectin type domains which
00:27:33
are highly repetitive regions and even
00:27:36
within them you can see that two exons
00:27:39
are being used by neurons and two exons
00:27:40
are being used by Gia um if I understand
00:27:44
that correctly yep and um so like just
00:27:49
it shouldn't make a difference that
00:27:52
these highly repetitive structures have
00:27:54
some method to their Madness but it does
00:27:57
so that is all the more reason for
00:27:59
people to look at not just which protein
00:28:02
like the canonical form but which
00:28:04
isoform is being used especially in like
00:28:07
drug uh development for example okay so
00:28:11
the next cluster we looked at was this
00:28:13
one over here in the middle of these two
00:28:16
and what we see is that there is adult
00:28:19
cell type specific difference as well as
00:28:21
adult brain region specific difference
00:28:24
so what that means is what we're finding
00:28:26
is for a given Gene in this case it's
00:28:29
called
00:28:30
tex9 um we find that a given isopor is
00:28:35
or Exon is different for a brain region
00:28:39
and for a particular cell type so in
00:28:42
this case we're seeing that an ISO um
00:28:44
Exxon is going from 90% inclusion to 10%
00:28:48
11% inclusion depending on which brain
00:28:51
region this is coming from I should also
00:28:53
mention that this is a uh plot kind of
00:28:57
that we developed in house on the bottom
00:29:00
is each line represents um the Gen code
00:29:03
annotation and on the top each line
00:29:05
represents a single read coming from
00:29:08
whatever this uh region is so and I
00:29:12
think n has used that as well and
00:29:14
hopefully without too many issues but um
00:29:17
this is kind of how we show differences
00:29:19
in cell types or brain regions or
00:29:21
whatever our thing of interest is okay
00:29:25
so this is what we find that whenever
00:29:28
have a brain region specific difference
00:29:30
it is usually occurring in single cell
00:29:32
types as opposed to all cell types and
00:29:34
this kind of agrees with what we'd found
00:29:37
um in the postnatal mouse brain as well
00:29:40
the next um thing we look at is these
00:29:42
two um are lit up so they're
00:29:45
developmental um changes but they are
00:29:49
age specific and in a given cell type so
00:29:51
again it's a same as the brain region
00:29:53
but this is happening over development
00:29:56
and here you'll see that for the
00:29:58
hippocampus you're going from like a 70%
00:30:01
to a 40% to 100% inclusion of a given
00:30:05
Exxon but that's not really true for say
00:30:08
a given for the prefrontal cortex or
00:30:10
sorry visual
00:30:11
cortex um another thing that I'm just
00:30:15
going to touch upon and you're going to
00:30:16
be like where do human come from um was
00:30:19
we sequenced human uh tissue kind of on
00:30:23
the side but we basically found out that
00:30:26
whenever we see cell type specific spe
00:30:28
it it is conserved in human but when you
00:30:32
find cell type specificity in human um
00:30:35
it is not always found in Mouse so that
00:30:38
kind of ties back into what I was saying
00:30:40
before like you can model things from
00:30:42
Mouse to human but the reverse Direction
00:30:44
I Would caution against I'm not going to
00:30:47
go over this plot for time purposes um
00:30:49
so let's move on and then the last plot
00:30:52
I want to last cluster I want to talk
00:30:54
about is this one this to me was the
00:30:57
most surpris in what we're seeing is
00:30:59
that there's changes that are occurring
00:31:02
in development that are not cell type
00:31:04
specific and they kind of disappear in
00:31:07
adulthood and I was very intrigued by
00:31:09
what this could be so we found a gene uh
00:31:12
that we've looked at before and which is
00:31:14
what I'm going to focus on now it's
00:31:15
called binan it's a neuronal like um
00:31:19
like brain specific Gene it's been
00:31:21
implicated in Alzheimer's disease a lot
00:31:24
and we've studied it pretty heavily in
00:31:26
the past so we we looked at P1 which is
00:31:30
like really tiny baby mice and um this
00:31:34
is again a scissor Wiz plot um wherein
00:31:37
you have your annotation on the bottom
00:31:40
and different cell types and different
00:31:41
colors the orange represents um
00:31:45
alternative exons so what you'll find is
00:31:49
that um these neuronal types the ones in
00:31:52
blue happen to include the orange a lot
00:31:56
and then the cell um types below which
00:31:59
are the G types do include the orange
00:32:02
but not that much so in our head we were
00:32:06
like this is a gal sorry this is a gal
00:32:09
isopor and this is a neuronal isopor and
00:32:12
that's just how it is for bin one we
00:32:15
look at our like new data and what we
00:32:17
find is this so at um
00:32:20
p14 depending on whether you're looking
00:32:22
at um hippocampus or visual cortex you
00:32:27
will see that um this neuronal isopor is
00:32:31
present where you have some of the green
00:32:33
which is orange here um even both cell
00:32:36
types and then at p56 but this is true
00:32:40
for all time points in all good endr
00:32:42
sites which are glea you have the G
00:32:44
isopor cool as the cells or mice mature
00:32:49
you find truly that this is there like
00:32:52
you see the neuronal isopor um but then
00:32:56
when we look at P2 21
00:32:59
hippocampus it starts to kind of
00:33:02
disappear right like the green is not as
00:33:05
as strongly expressed as it was as it is
00:33:08
over here then we go to p28 and the
00:33:11
green almost entirely disappears so what
00:33:15
that is meaning and we're looking at
00:33:16
this across multiple replicates and
00:33:19
multiple genes and things like that um
00:33:22
the green is disappearing so the neurons
00:33:25
have taken on almost like a GLE identity
00:33:28
of their isopor and I don't have a
00:33:31
question like answer for why but I do
00:33:33
know that this is happening and what's
00:33:36
even crazier is that it kind of bounces
00:33:38
back so it's not just monotonically
00:33:42
increasing or decreasing overdevelopment
00:33:45
it is literally going up and down so
00:33:47
then I wanted to look at um what is how
00:33:51
it's going up and down um so I started
00:33:56
like trying to do this in in a bit more
00:33:59
um systematic manner so what I looked at
00:34:04
was instead of isopor variability um
00:34:07
across the different axes I looked at it
00:34:10
just over time and what I'm looking at
00:34:14
is cell type variability so if all cell
00:34:17
types uh have a given variability here
00:34:20
for p14 and a different variability at
00:34:23
p21 then I measure the Delta between
00:34:26
them
00:34:28
um I I can do the same for p21 to
00:34:32
p28 and then I can do the same for p28
00:34:35
to p56 so whenever there's an
00:34:38
outlier um say in this case this red
00:34:41
point asite is showing differences at
00:34:43
p28 that would be captured because that
00:34:47
um variability is pretty high and then
00:34:50
it's kind of Disappearing at a later
00:34:51
time point so for most genes you would
00:34:55
expect that things are going pretty
00:34:57
stable uh but you can have genes like
00:35:01
this where it's kind of not that
00:35:03
different at this um transition from p14
00:35:07
to p21 but from p21 to 28 it's kind of
00:35:11
going up and then it's going down at
00:35:14
p56 so you can see this pattern um as
00:35:18
you can imagine there are 27 possible
00:35:20
patterns because there's three at every
00:35:23
what's it called um
00:35:26
interval and um so we tried to basically
00:35:31
figure out how many genes follow which
00:35:34
pattern so as I mentioned most of the
00:35:37
genes or most of the exons are
00:35:39
invariable they're going to be pretty
00:35:42
stable um across the different cell
00:35:44
types at um each interval but then
00:35:48
there's about a thousand genes uh Exon
00:35:51
that show a very like different types of
00:35:54
patterns so first I'm going to show you
00:35:56
the invariant one because it's easy to
00:35:58
show and then I'll show you the others
00:36:01
so over here I'm just showing line plots
00:36:04
with the green being like the average
00:36:07
and um this number on the y- axis is
00:36:11
showing the variability so as you can
00:36:13
see for the most part it's like not
00:36:15
changing that much and the average is
00:36:17
about the same and you can visualize the
00:36:19
actual um Exon expression value and
00:36:23
again you can see that it's fairly green
00:36:24
or fairly red either all low or all high
00:36:28
but then you can look at some of these
00:36:30
other patterns that are showing up
00:36:32
especially the the Thousand xon are show
00:36:35
so that I showed and what you'll see is
00:36:37
what I showed you with the bin one
00:36:39
example where it's not just going up or
00:36:42
not just coming down it's kind of going
00:36:45
up and down in Crazy different ways and
00:36:48
that's not just like this variability
00:36:50
that I'm showing but you can see that
00:36:52
like in individual exons if you
00:36:55
visualize the uh VAR ility PSI and the
00:37:00
other thing I want to point out is that
00:37:02
if you look at these patterns the uh two
00:37:05
time points that come out the most but
00:37:07
the one time point that comes out the
00:37:09
most is p28 so it's always the
00:37:12
transition between p21 to 28 that is
00:37:14
either going like um up or down or being
00:37:19
crazy um so and the reason for that and
00:37:22
this is my hypothesis it's speculation
00:37:24
that's not been tested is that the p21
00:37:28
to 28 time point is when is called the
00:37:31
critical developmental time point in
00:37:33
mice it is after mice have opened their
00:37:36
eyes and they have like started to
00:37:39
actually see the world uh so in human
00:37:42
terms it's days not like also days U but
00:37:46
it's kind of crazy that there's things
00:37:48
happening on a developmental front in
00:37:51
the brain that you're seeing in action
00:37:54
um for individual
00:37:56
exons okay so with that I'll uh conclude
00:38:00
this part actually I'll conclude my talk
00:38:02
because I'm basically out of time um so
00:38:06
as you as I showed you we looked at
00:38:08
extremely variable exons and what we
00:38:11
found was that the cell type specific
00:38:14
differences may it be developmental or
00:38:16
may it be adult um those are the most
00:38:20
prevalent what we find is that the adult
00:38:23
brain region specific differences are
00:38:25
usually accompanied by cell type
00:38:28
specific differences so there is some
00:38:31
like critical modulation happening um of
00:38:36
um critical modulation happening of
00:38:39
function on a cell type specific level
00:38:42
uh even though it's across different
00:38:43
brain regions the next thing we found
00:38:46
was that it was conserved in human and
00:38:49
um lastly we found that uh these
00:38:52
developmental differences that we found
00:38:54
that are critical are transient they
00:38:57
they don't like they don't come and go
00:39:00
in a monotonic fashion they come and
00:39:03
then they disappear especially around
00:39:06
this critical uh time point so this work
00:39:11
was recently published in April uh and
00:39:14
you're welcome to go read it or ask me
00:39:17
questions whatever um I also wanted to
00:39:20
talk to you about developing single
00:39:22
nucleus isopor sequencing but
00:39:24
unfortunately I don't have that much
00:39:26
time so just going to go straight to my
00:39:28
acknowledgement slide um I'd like to
00:39:32
thank the tner lab which is where I did
00:39:34
most of this work um and when and Bay
00:39:38
were the ones who did most of the sample
00:39:40
processing for this project the brain
00:39:42
initiative was the funding body for it
00:39:46
and um of course lots of
00:39:49
collaborators and um I actually switched
00:39:52
from the New York genome Center but I
00:39:54
worked with um the ulinski and the gors
00:39:57
Labs while I was there and so I want to
00:39:59
thank them as well and um I'm happy to
00:40:02
take any questions you guys may
00:40:14
have thank you great talk Dr jar um I
00:40:17
have a few questions but I feel like um
00:40:20
we can open the floor for others to ask
00:40:22
first yeah sure
00:40:33
okay U While others are thinking I'll
00:40:35
I'll I'll get started uh anishka again
00:40:37
fantastic talk I really enjoyed it um so
00:40:40
um I mean it's this is fascinating you
00:40:42
know during the developmental stage and
00:40:44
know how how the different isop forms
00:40:46
are changing I was curious if with with
00:40:49
any of these isop forms do you see sort
00:40:50
of correlated changes in in the other
00:40:53
isop forms because ultimately we won't
00:40:55
understand this at sort of the network
00:40:56
context right so so have have you have
00:40:59
you found any correlated changes with
00:41:02
any of these that's a great question and
00:41:05
I would love to explore that especially
00:41:07
in like you know because like Gene
00:41:09
regulatory networks are going to have
00:41:12
these corresponding isopor regulatory
00:41:14
networks and I haven't saided them uh
00:41:17
personally but that's a that's a um
00:41:20
something on the radar because we wanted
00:41:22
to actually look at and I don't know if
00:41:25
they're doing this still but we wanted
00:41:27
to look at how RNA binding protein
00:41:30
changes affect these so that would be
00:41:33
the best way to study the coordination
00:41:35
we did look because of reviewer comments
00:41:37
so it was a very brief look um at
00:41:42
something like that where like if you
00:41:44
have changes like a knockdown in an RBP
00:41:47
how that affects multiple exons or um
00:41:50
genes at once but we didn't do a not a
00:41:54
satisfactory analysis so they don't have
00:41:57
a good answer okay well thank
00:42:17
you
00:42:20
Jessica hiy yeah thank you um really
00:42:22
nice talk um I've done Isa seek
00:42:25
interestingly in single cellular
00:42:27
organisms where you don't have different
00:42:28
tissues and we are seeing different
00:42:30
isoforms one of the challenges we
00:42:32
encountered and it's just a
00:42:34
methodological uh question here detail
00:42:37
um did you rely on the reverse
00:42:39
transcription to get to the five Prime
00:42:41
end or do you do cap selection you know
00:42:45
yeah no we didn't do cap selection This
00:42:47
was um we just did RT and we definitely
00:42:51
see so like I don't know if you uh I'll
00:42:54
try and pull up a oops that was a
00:42:56
different one um I'll try and pull up a
00:42:59
plot so for example actually just in the
00:43:02
bin one case if you look on the left
00:43:05
this was generated with pack bio and uh
00:43:09
this was generated with on and as you
00:43:13
can see like already there is like um
00:43:17
differences in how full length the
00:43:20
molecule is so this is on a
00:43:22
technological front but also with the RT
00:43:25
we see a similar thing where if you do
00:43:27
human samples sometimes you'll have
00:43:30
random stuff happening and it doesn't go
00:43:32
to the five Prime end of the molecule
00:43:35
and so that's just kind of
00:43:39
um like
00:43:40
a yeah you just kind of have to deal
00:43:43
with it artifactual thing um is what we
00:43:47
ended up on but that being said I don't
00:43:49
know if you followed work from the crg
00:43:53
but they did do some cap trap new method
00:43:57
that does capture the five Prime tail
00:43:59
and apparently that is much better at
00:44:02
getting the entire molecule um yeah yeah
00:44:06
yeah I mean that's kind of the
00:44:07
conclusion that I had come to because I
00:44:09
was just seeing a lot of variability and
00:44:10
I didn't know if they degradation
00:44:12
project you know products or just our te
00:44:14
coming off you know like you just you
00:44:15
don't know what's going on and so you
00:44:17
know having that five Prime cap
00:44:19
selection seems to be important all
00:44:21
right thank you
00:44:30
I have a quick question so when you say
00:44:32
alternative splicing is there a
00:44:34
threshold that you that the software
00:44:36
uses that saying if this percentage of
00:44:40
um the cells cell population has this
00:44:42
Exon that means it's an alternative SP
00:44:45
alterntive yeah uh no that's a good
00:44:47
question and there's two parts to it so
00:44:49
we generally work on a cell type level
00:44:52
and the reason for that is that these
00:44:54
long read methods still don't have the
00:44:57
same level of throughput as say alumina
00:44:59
so you're getting like a tenth or so of
00:45:02
the throughput so we don't work on a
00:45:04
cell level um so we don't do that filter
00:45:09
but once we get to a point where we're
00:45:10
getting millions and millions of reads
00:45:13
that is definitely something to do what
00:45:15
we do do is um we ask for at least a 10%
00:45:21
change between cell types um to classify
00:45:25
it as an alternative spicing
00:45:28
event um and that can change so we've
00:45:31
we've played around with this like we
00:45:33
don't just use the Delta we also use a P
00:45:37
value because like you get more
00:45:38
confidence in your results if you kind
00:45:40
of use two Avenues as opposed to just
00:45:42
one um and so sometimes like if we want
00:45:45
to be hyper confident that's why I use
00:45:47
the 75% cut off in the alternative sorry
00:45:50
extremely variable exons because we
00:45:52
wanted to be sure that this is something
00:45:54
that we like a robust signal that we're
00:45:57
but in most cases it'll be 10 sometimes
00:46:09
20% um if there are no more questions
00:46:12
then thank you Dr Jer it was a great
00:46:15
talk um and thank you everyone for
00:46:18
joining I'll connect with you offline
00:46:20
for more of my questions by that sounds
00:46:23
good yeah okay you awesome thank you bye
00:46:26
bye hi thank you