Stem Cells L23_F2024v2 - PDF

Summary

These notes cover stem cells including embryonic stem cells, induced pluripotent stem cells (iPS cells), and adult stem cells. The topics include challenges, applications, and basic science of stem cells. The document also contains information about final exams and prelims for a course at Cornell University.

Full Transcript

Stem cells
Learning objectives:
Reading: ECB6 739-745, DevBio11 167-1
Understand that stem cells are
capable of self renewal,
creating more stem cells and
differentiated progeny
Understand the differences
between embryonic stem cells
and adult stem cells
Understand the concept of the
stem cell niche
Understand the challenges of
using adult stem cells or
embryonic stem cells in
therapy
Understand how induced
pluripotent stem cells (iPS
cells) can be generated
Recognize the potential utility
of organoids in biomedical
 BIOMG1350 PRELIM 4: December 9th, 2024 (L19-24; S10-11)
check your room/seat assignment by Saturday
practice prelim will be uploaded today
review sessions with TAs 1-4PM this Sat/Sun in G01 Biotech

BIOMG 1350 FINAL EXAM: Saturday 12/14/2024 9:00 AM BTN100CENT,
BTN100EAST
Location Barton Hall. BTN100CENT, BTN100EAST
We are trying to make previous prelims available for practice
Review sessions with TAs 1-3PM
December 12th Thursday – Racker room G01
December 13th - Friday – Room TBD (Warren Hall 101, tentative)
Watch for instructions announcement next week
It is your responsibility to read and know the rules, including academic integrity
issues

BIOMG 1350 MAKE-UP FINAL EXAM REQUEST: DEADLINE Wednesday Dec 4 th
send request to [email protected] with
a reason for wanting a make-up exam
 a list of ALL your final exams with their course number, date, and time
 conflicts will be scheduled between Dec 16 th - 20th, date and location TBD
“We are drawn to the subject of stem
cells as we are to stories of perpetual
motion machines or the fountain of
youth; understanding the inner
workings of stem cells might help to
realize their mythic promise.”
Alan Spradling (2001), Nature 414:98
What makes stem cell biology
so exciting?
Basic science promise: tissue
homeostasis, control embryonic
development, tissue regeneration,
aging!

Clinical applications promise:
Diabetes, cardiovascular diseases,
Parkinsons, Alzheimer, severe burns,
spinal cord injuries, etc
A stem cell is a cell that is
capable of extensive self
renewal, creating more stem
cells AND more differentiated
progeny.

(progenitors)
 Types of
A pyramidal hierarchy of
cell potency Cells
TOTIPOTENT Totipotent Cells
Not Stem Cells
Make all embryo cells + placenta
Pluripotent Stem Cells:
PLURIPOTENT iPSC= Induced Pluripotent Stem C
ESC= Embryonic Stem Cells

Adult/Tissue Stem Cell
MULTIPOTENT HSC= Hematopoietic Stem Ce
EpSC= Epidermal Stem Cel
NSC= Neural Stem Cells
OLIGOPOTENT
Committed Progenito
Not Stem
Cells

Terminally differentiated
 Adult stem
cells

Embryonic
stem cells
Today’s
topics Reprogrammin
g

Applications
 Types of stem cells
1) Adult stem cells:
committed stem cells that
give rise to a limited set
of cells and tissue types
(multipotent).
Examples:
hematopoietic,
epidermal, neural,
hair, melanocyte,
muscle, tooth, gut,
Present throughout
germline stem cells
the life of the
individual; but they
are rare and difficult
to isolate, ~1/1000
 Adult stem cells reside in a special
regulatory environment called niche

Stem cell niche: environment
producing signals that regulate stem
cell proliferation and differentiation
The stem cell niche in the mammalian
intestine
Challenges for using adult stem cells
in therapy
Adult stem cells can be used
in therapy
eg: bone marrow
Difficult to find and
transplantation
isolate because of
scarcity

Need different types of
adult stem cells for
different therapies

Need to identify the
niche conditions to
maintain and
differentiate

They generally grow
poorly in culture and are
difficult to expand
 Adult Stem
cells

Embryonic
stem cells
Today’s
topics Reprogrammin
g

Applications
 Types of stem cells
2) Embryonic stem (ES) cells: derived from cells
transiently present in embryogenesis; when cultured,
can remain undifferentiated, but can give rise to any
cell in the body under appropriate conditions
(pluripotent).

Inner cell mass (ICM) trophoblast

A blastocyst stage
mammalian embryo:
Inner cell mass (ICM): gives
rise to all cells in the
embryo body becomes
Trophoblast: (pluripotent)
the
extra- embryonic tissue (part
of the placenta)
ES cells have tremendous therapeutic
potential

DevBio11 5-21
 Problems associated with the use of
ES cells in therapy

Technical problems:
Histo-incompatibility (ES cells are not
patient-derived and can be rejected by
the patient’s immune system)
The differentiation pathways are not well
known and are difficult to identify

Ethical problems:
Is it ethical/moral to create human
blastocysts just for the purpose of
generating stem cells for therapies?
Is a blastocyst a human individual with
on: createrights?
personalized pluripotent cells from patients’ own adu
 Adult Stem
cells

Embryonic
stem cells
Today’s
topics Reprogrammin
g
NTSCs
iPSCs

Applications
Nuclear Transfer Stem Cells = NTSCs
e.g. “therapeutic
cloning”
Problems associated with therapeutic
cloning

Technical problem: success rate is very
low (Dolly: 1/434 nuclei transplanted), a
lot of eggs need to be donated

Ethical problem: Is it ethical/moral to
create human blastocysts just for the
purpose of generating stem cells? Is a
blastocyst a human individual with
rights?
Induced pluripotent stem cells (iPS
cells)
Nobel Prize in Physiology or
Medicine 2012
for the discovery that mature
cells can be reprogrammed to
become pluripotent Shinya
Yamanaka
OSK transcription regulators are necessary and sufficient for
pluripotency
Inner Cell Mass (ICM)

OSK = Oct4, Sox2, Klf4

Transcription regulators:
Expressed in ICM and in cultured ESCs
Essential for pluripotency (mutant
studies) = necessary
Are they also sufficient for
pluripotency? = sufficient

(screening ~22 of them)

Differentiated
somatic cell
Shinya Yamanaka & Helen M. Blau NATURE|Vol 465|10 June
 The master regulators of pluripotency participate in a self-
sustained positive feedback loop

Klf
4

Figure 22-41 MBC6
Overall, ~1500 genes
are differentially
expressed in response
Problems associated with the use of iPS
cells in therapy
Technical problems:

The pluripotency factors must be turned
off in order to allow iPS cells to
differentiate and to avoid tumorigenesis

iPS cells are not identical to ES cells (eg.
differences in some epigenetic marks)

Somatic cells used to make iPS cells may
carry damaging mutations

Safety of reprogramming is not completely
known

Although straightforward it is still very
 Adult Stem
cells

Embryonic
stem cells
Today’s
topics Reprogrammin
g

Applications
iPS cells can be used to study and treat
genetic disease
Cultured ES (or iPS) cells can give rise to a three-
dimensional organoid.
 Organoids can also be obtained from
tissue SCs

o and Clevers (2013) Science 340: 1190
Adult hematopoietic stem cells are frequently used
in clinics

Find immune- Inject the cells into
Use strong compatible donor and the
chemotherapy or collect stem cells to bloodstream of the
radiation to kill the transplant. (In some patient; stem cells
cancer cells, but this cases, patient can will find their way
treatment also kills donate marrow prior to the marrow and
hemopoietic stem to treatment.) repopulate the
cells. blood.
 Basic Science Applications of ESCs:
The Nobel Prize in Physiology/Medicine 2007 for introducing specific
gene modifications in mice via embryonic stem cells

Gene targeting
to introduce mutations
(e.g. CRISPR/Cas9)

Mutant ES cells

Breeding to transmit mutati
to next generation of mice

Blastocyst develops in
Clump of mutant foster mother into a
ES cells injected in chimeric mouse; the
blastocyst ES cells
contribute to all
igure 22-40 MBC6e tissues
Example of gene knockout experiment:
leptin knockout mice are obese

* KO experiment helped show that leptin is a hormone
which regulates body fat as well as the sensation of
hunger, and its loss results in obesity, susceptibility to
diabetes, and other complications.
 Stem cells and cancer

1) Stem cells are likely to be important targets of
cancer
long-lived ->accumulate mutations
proliferative -> more prone to transformation
evidence of ‘cancer stem cells’ – rare tumor cells can rebuild
a tumor

2) Stem cells regulatory signals are often
perturbed in cancer
Quiescence signals -> inactivated
Activation signals -> super-activated
Differentiation signals -> inactivated or abberrant
Stem cell renewal and pro-cancer
pathways are linked

Reya et al. (2001) Nature 414:10