Opensource drug discovery | Dr Jay Bradner | TEDxBoston

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I moved to Boston
10 years ago from Chicago,
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with an interest in cancer
and in chemistry.
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You might know that chemistry
is the science of making molecules
0:20 - 0:22

or, to my taste,
0:22 - 0:23

new drugs for cancer.
0:24 - 0:27

And you might also know that,
for science and medicine,
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Boston is a bit of a candy store.
0:31 - 0:35

You can't roll a stop sign in Cambridge
without hitting a graduate student.
0:35 - 0:37

The bar is called the Miracle of Science.
0:38 - 0:41

The billboards say "Lab Space Available."
0:41 - 0:43

And it's fair to say
that in these 10 years,
0:43 - 0:47

we've witnessed absolutely the start
of a scientific revolution --
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that of genome medicine.
0:50 - 0:52

We know more about the patients
that enter our clinic now
0:52 - 0:53

than ever before.
0:54 - 0:56

And we're able, finally,
to answer the question
0:56 - 0:58

that's been so pressing for so many years:
0:58 - 1:00

Why do I have cancer?
1:01 - 1:03

This information
is also pretty staggering.
1:04 - 1:07

You might know that, so far,
in just the dawn of this revolution,
1:07 - 1:11

we know that there are perhaps
40,000 unique mutations
1:11 - 1:13

affecting more than 10,000 genes,
1:13 - 1:17

and that there are 500 of these genes
that are bona-fide drivers,
1:17 - 1:19

causes of cancer.
1:20 - 1:21

Yet comparatively,
1:21 - 1:24

we have about a dozen
targeted medications.
1:25 - 1:27

And this inadequacy of cancer medicine
1:27 - 1:31

really hit home when my father
was diagnosed with pancreatic cancer.
1:33 - 1:34

We didn't fly him to Boston.
1:34 - 1:36

We didn't sequence his genome.
1:36 - 1:39

It's been known for decades
what causes this malignancy.
1:41 - 1:45

It's three proteins: ras, myc, p53.
1:46 - 1:49

This is old information
we've known since about the 80s,
1:49 - 1:51

yet there's no medicine I can prescribe
1:51 - 1:55

to a patient with this
or any of the numerous solid tumors
1:55 - 1:56

caused by these three ...
1:57 - 2:00

Horsemen of the Apocalypse that is cancer.
2:00 - 2:02

There's no ras, no myc, no p53 drug.
2:03 - 2:05

And you might fairly ask: Why is that?
2:06 - 2:09

And the very unsatisfying
yet scientific answer is:
2:09 - 2:10

it's too hard.
2:10 - 2:12

That for whatever reason,
2:12 - 2:15

these three proteins have entered
a space, in the language of our field,
2:15 - 2:17

that's called the undruggable genome --
2:17 - 2:20

which is like calling
a computer unsurfable
2:20 - 2:21

or the Moon unwalkable.
2:21 - 2:23

It's a horrible term of trade.
2:23 - 2:24

But what it means
2:24 - 2:27

is that we've failed to identify
a greasy pocket in these proteins,
2:28 - 2:30

into which we, like molecular locksmiths,
2:30 - 2:35

can fashion an active, small,
organic molecule or drug substance.
2:35 - 2:38

Now, as I was training
in clinical medicine
2:38 - 2:41

and hematology and oncology
and stem-cell transplantation,
2:41 - 2:43

what we had instead,
2:44 - 2:49

cascading through the regulatory
network at the FDA,
2:49 - 2:50

were these substances:
2:50 - 2:52

arsenic,
2:52 - 2:53

thalidomide,
2:53 - 2:56

and this chemical derivative
of nitrogen mustard gas.
2:56 - 2:59

And this is the 21st century.
2:59 - 3:00

And so, I guess you'd say,
3:01 - 3:04

dissatisfied with the performance
and quality of these medicines,
3:04 - 3:06

I went back to school, in chemistry,
3:08 - 3:13

with the idea that perhaps by learning
the trade of discovery chemistry
3:13 - 3:16

and approaching it in the context
of this brave new world
3:16 - 3:18

of the open source,
3:18 - 3:19

the crowd source,
3:20 - 3:23

the collaborative network
that we have access to within academia,
3:23 - 3:27

that we might more quickly bring
powerful and targeted therapies
3:27 - 3:29

to our patients.
3:29 - 3:32

And so, please consider
this a work in progress,
3:32 - 3:34

but I'd like to tell you today a story
3:34 - 3:37

about a very rare cancer
called midline carcinoma,
3:38 - 3:42

about the undruggable protein target
that causes this cancer,
3:42 - 3:44

called BRD4,
3:44 - 3:48

and about a molecule developed at my lab
at Dana-Farber Cancer Institute,
3:48 - 3:49

called JQ1,
3:49 - 3:51

which we affectionately named for Jun Qi,
3:51 - 3:53

the chemist that made this molecule.
3:54 - 3:57

Now, BRD4 is an interesting protein.
3:57 - 4:01

You might ask: with all the things
cancer's trying to do to kill our patient,
4:01 - 4:02

how does it remember it's cancer?
4:02 - 4:04

When it winds up its genome,
4:04 - 4:06

divides into two cells and unwinds again,
4:06 - 4:09

why does it not turn
into an eye, into a liver,
4:09 - 4:11

as it has all the genes
necessary to do this?
4:11 - 4:13

It remembers that it's cancer.
4:13 - 4:16

And the reason is that cancer,
like every cell in the body,
4:16 - 4:18

places little molecular bookmarks,
4:18 - 4:20

little Post-it notes,
4:20 - 4:23

that remind the cell, "I'm cancer;
I should keep growing."
4:24 - 4:28

And those Post-it notes involve this
and other proteins of its class --
4:28 - 4:29

so-called bromodomains.
4:29 - 4:32

So we developed an idea, a rationale,
4:32 - 4:34

that perhaps if we made a molecule
4:34 - 4:37

that prevented
the Post-it note from sticking
4:37 - 4:38

by entering into the little pocket
4:38 - 4:40

at the base of this spinning protein,
4:40 - 4:42

then maybe we could convince cancer cells,
4:42 - 4:45

certainly those addicted
to this BRD4 protein,
4:45 - 4:46

that they're not cancer.
4:47 - 4:49

And so we started to work on this problem.
4:49 - 4:52

We developed libraries of compounds
4:52 - 4:54

and eventually arrived
at this and similar substances
4:54 - 4:56

called JQ1.
4:56 - 4:58

Now, not being a drug company,
4:58 - 5:01

we could do certain things,
we had certain flexibilities,
5:01 - 5:04

that I respect that a pharmaceutical
industry doesn't have.
5:04 - 5:06

We just started mailing it to our friends.
5:07 - 5:08

I have a small lab.
5:08 - 5:11

We thought we'd just send it to people
and see how the molecule behaves.
5:11 - 5:13

We sent it to Oxford, England,
5:13 - 5:16

where a group of talented
crystallographers provided this picture,
5:16 - 5:19

which helped us understand exactly
how this molecule is so potent
5:19 - 5:20

for this protein target.
5:20 - 5:23

It's what we call a perfect fit
of shape complementarity,
5:23 - 5:24

or hand in glove.
5:25 - 5:27

Now, this is a very rare cancer,
5:27 - 5:28

this BRD4-addicted cancer.
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And so we worked with samples of material
5:31 - 5:35

that were collected by young pathologists
at Brigham and Women's Hospital.
5:35 - 5:37

And as we treated these cells
with this molecule,
5:37 - 5:39

we observed something really striking.
5:40 - 5:41

The cancer cells --
5:41 - 5:43

small, round and rapidly dividing,
5:43 - 5:45

grew these arms and extensions.
5:45 - 5:47

They were changing shape.
5:47 - 5:48

In effect,
5:48 - 5:52

the cancer cell
was forgetting it was cancer
5:52 - 5:53

and becoming a normal cell.
5:55 - 5:56

This got us very excited.
5:58 - 6:00

The next step would be to put
this molecule into mice.
6:00 - 6:04

The only problem was there's no
mouse model of this rare cancer.
6:04 - 6:06

And so at the time
we were doing this research,
6:06 - 6:10

I was caring for a 29-year-old
firefighter from Connecticut
6:10 - 6:12

who was very much at the end of life
6:12 - 6:14

with this incurable cancer.
6:14 - 6:18

This BRD4-addicted cancer
was growing throughout his left lung.
6:18 - 6:21

And he had a chest tube in
that was draining little bits of debris.
6:21 - 6:24

And every nursing shift,
we would throw this material out.
6:24 - 6:26

And so we approached this patient
6:26 - 6:28

and asked if he would collaborate with us.
6:28 - 6:32

Could we take this precious
and rare cancerous material
6:32 - 6:34

from this chest tube
6:34 - 6:36

and drive it across town
and put it into mice
6:36 - 6:40

and try to do a clinical trial
at a stage that with a prototype drug,
6:40 - 6:42

well, that would be, of course, impossible
6:42 - 6:44

and, rightly, illegal to do in humans.
6:44 - 6:45

And he obliged us.
6:46 - 6:49

At the Lurie Family Center
for Animal Imaging,
6:50 - 6:53

our colleague, Andrew Kung,
grew this cancer successfully in mice
6:53 - 6:55

without ever touching plastic.
6:55 - 6:59

And you can see this PET scan
of a mouse -- what we call a pet PET.
6:59 - 7:00

The cancer is growing
7:00 - 7:03

as this red, huge mass
in the hind limb of this animal.
7:04 - 7:06

And as we treat it with our compound,
7:06 - 7:07

this addiction to sugar,
7:07 - 7:09

this rapid growth, faded.
7:09 - 7:11

And on the animal on the right,
7:11 - 7:13

you see that the cancer was responding.
7:14 - 7:16

We've completed, now, clinical trials
7:16 - 7:18

in four mouse models of this disease.
7:18 - 7:20

And every time, we see the same thing.
7:20 - 7:23

The mice with this cancer
that get the drug live,
7:23 - 7:25

and the ones that don't rapidly perish.
7:27 - 7:29

So we started to wonder,
7:29 - 7:31

what would a drug company
do at this point?
7:31 - 7:33

Well, they probably
would keep this a secret
7:33 - 7:35

until they turn the prototype drug
7:35 - 7:37

into an active pharmaceutical substance.
7:38 - 7:39

So we did just the opposite.
7:39 - 7:42

We published a paper
that described this finding
7:42 - 7:44

at the earliest prototype stage.
7:45 - 7:48

We gave the world the chemical
identity of this molecule,
7:48 - 7:50

typically a secret in our discipline.
7:50 - 7:52

We told people exactly how to make it.
7:53 - 7:54

We gave them our email address,
7:54 - 7:56

suggesting that if they write us,
7:56 - 7:58

we'll send them a free molecule.
7:58 - 7:59

(Laughter)
7:59 - 8:02

We basically tried to create
the most competitive environment
8:02 - 8:03

for our lab as possible.
8:03 - 8:05

And this was, unfortunately, successful.
8:05 - 8:06

(Laughter)
8:06 - 8:08

Because now, we've shared this molecule,
8:08 - 8:10

just since December of last year,
8:10 - 8:13

with 40 laboratories in the United States
8:13 - 8:14

and 30 more in Europe --
8:14 - 8:16

many of them pharmaceutical companies,
8:16 - 8:18

seeking now to enter this space,
8:18 - 8:21

to target this rare cancer
that, thankfully right now,
8:22 - 8:24

is quite desirable
to study in that industry.
8:27 - 8:30

But the science that's coming back
from all of these laboratories
8:30 - 8:32

about the use of this molecule
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has provided us insights
we might not have had on our own.
8:35 - 8:37

Leukemia cells treated with this compound
8:37 - 8:39

turn into normal white blood cells.
8:40 - 8:42

Mice with multiple myeloma,
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an incurable malignancy
of the bone marrow,
8:46 - 8:48

respond dramatically
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to the treatment with this drug.
8:50 - 8:52

You might know that fat has memory.
8:53 - 8:55

I'll nicely demonstrate that for you.
8:55 - 8:56

(Laughter)
8:56 - 8:58

In fact, this molecule
8:58 - 9:01

prevents this adipocyte,
this fat stem cell,
9:01 - 9:04

from remembering how to make fat,
9:04 - 9:07

such that mice on a high-fat diet,
9:07 - 9:09

like the folks
in my hometown of Chicago --
9:09 - 9:10

(Laughter)
9:10 - 9:12

fail to develop fatty liver,
9:12 - 9:14

which is a major medical problem.
9:15 - 9:16

What this research taught us --
9:16 - 9:19

not just my lab, but our institute,
9:19 - 9:21

and Harvard Medical School
more generally --
9:21 - 9:23

is that we have unique
resources in academia
9:23 - 9:24

for drug discovery;
9:24 - 9:28

that our center, which has tested
perhaps more cancer molecules
9:28 - 9:29

in a scientific way
9:29 - 9:30

than any other,
9:30 - 9:31

never made one of its own.
9:32 - 9:35

For all the reasons you see listed here,
9:35 - 9:37

we think there's a great
opportunity for academic centers
9:37 - 9:41

to participate in this earliest,
conceptually tricky
9:41 - 9:43

and creative discipline
9:43 - 9:45

of prototype drug discovery.
9:48 - 9:49

So what next?
9:49 - 9:52

We have this molecule,
but it's not a pill yet.
9:52 - 9:54

It's not orally bioavailable.
9:54 - 9:57

We need to fix it so we can
deliver it to our patients.
9:57 - 9:59

And everyone in the lab,
9:59 - 10:02

especially following the interaction
with these patients,
10:02 - 10:04

feels quite compelled
to deliver a drug substance
10:04 - 10:05

based on this molecule.
10:06 - 10:07

It's here where I'd say
10:07 - 10:10

that we could use your help
and your insights,
10:10 - 10:12

your collaborative participation.
10:12 - 10:16

Unlike a drug company,
we don't have a pipeline
10:16 - 10:18

that we can deposit these molecules into.
10:18 - 10:21

We don't have a team
of salespeople and marketeers
10:21 - 10:23

to tell us how to position
this drug against the other.
10:23 - 10:26

What we do have is the flexibility
of an academic center
10:26 - 10:28

to work with competent, motivated,
10:28 - 10:31

enthusiastic, hopefully well-funded people
10:31 - 10:33

to carry these molecules
forward into the clinic
10:33 - 10:37

while preserving our ability
to share the prototype drug worldwide.
10:38 - 10:41

This molecule will soon leave our benches
10:41 - 10:44

and go into a small start-up company
called Tensha Therapeutics.
10:44 - 10:47

And, really, this is the fourth
of these molecules
10:47 - 10:49

to kind of "graduate"
from our little pipeline
10:49 - 10:50

of drug discovery,
10:51 - 10:55

two of which -- a topical drug
for lymphoma of the skin
10:56 - 10:59

and an oral substance for the treatment
of multiple myeloma --
10:59 - 11:02

will actually come to the bedside
for the first clinical trial
11:02 - 11:06

in July of this year -- for us,
a major and exciting milestone.
11:07 - 11:09

I want to leave you with just two ideas.
11:09 - 11:14

The first is: if anything is unique
about this research,
11:14 - 11:16

it's less the science than the strategy.
11:16 - 11:18

This, for us, was a social experiment --
11:18 - 11:24

an experiment in "What would happen
if we were as open and honest
11:24 - 11:26

at the earliest phase
of discovery chemistry research
11:26 - 11:28

as we could be?"
11:28 - 11:30

This string of letters and numbers
11:30 - 11:32

and symbols and parentheses
11:32 - 11:34

that can be texted, I suppose,
11:34 - 11:35

or Twittered worldwide,
11:36 - 11:39

is the chemical identity
of our pro compound.
11:39 - 11:43

It's the information that we most need
from pharmaceutical companies,
11:43 - 11:48

the information on how these early
prototype drugs might work.
11:48 - 11:50

Yet this information is largely a secret.
11:51 - 11:54

And so we seek, really, to download
11:54 - 11:57

from the amazing successes
of the computer-science industry,
11:57 - 12:01

two principles -- that of open source
and that of crowdsourcing --
12:01 - 12:07

to quickly, responsibly accelerate
the delivery of targeted therapeutics
12:07 - 12:09

to patients with cancer.
12:10 - 12:13

Now, the business model
involves all of you.
12:13 - 12:15

This research is funded by the public.
12:15 - 12:16

It's funded by foundations.
12:16 - 12:18

And one thing I've learned in Boston
12:18 - 12:21

is that you people will do anything
for cancer, and I love that.
12:21 - 12:24

You bike across the state,
you walk up and down the river.
12:24 - 12:26

(Laughter)
12:26 - 12:29

I've never seen, really, anywhere,
12:29 - 12:32

this unique support for cancer research.
12:32 - 12:34

And so I want to thank you
12:34 - 12:37

for your participation, your collaboration
12:37 - 12:38

and most of all,
12:38 - 12:40

for your confidence in our ideas.
12:40 - 12:46

(Applause)

Title:: Opensource drug discovery | Dr Jay Bradner | TEDxBoston
Description:: How does cancer know it's cancer? At Jay Bradner's lab, they found a molecule that might hold the answer, JQ1 - and instead of patenting JQ1, they published their findings and mailed samples to 40 other labs to work on. An inspiring look at the open-source future of medical research.

This talk was given at a TEDx event using the TED conference format but independently organized by a local community. Learn more at http://ted.com/tedx

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Video Language:: English
Team:: closed TED
Project:: TEDxTalks
Duration:: 12:49

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Opensource drug discovery | Dr Jay Bradner | TEDxBoston

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