Pluripotency of Stem Cells PDF

Summary

This document is a lesson about the pluripotency of stem cells, detailing various aspects of this topic. It covers totipotent, pluripotent, multipotent, and unipotent stem cells, and discusses the features and regulation of pluripotency. The lesson includes diagrams and explanations.

Full Transcript

Stem Cells
Stem cells are master cells with two important
characteristics
– Unspecialized cells capable of their own renewal
– Ability to differentiate into different cell types

The stem cells may have various differentiation
potentials
Totipotent
Pluripotent
Multipotent
Unipotent
 Pluripotent Stem Cells

Pluri derived from latin word plures –
means several or many
Most commonly the term is used to

describe stem cells that give rise to
cells derived from all three
embryonic germ
Pluripotent Stem Cells
Types of Pluripotent Stem
Cells
❑ Embryonic stem cells
❑ Embryonic carcinoma cells
❑ Embryonic germ cells
Induced pluripotent stem cells
 Origins of pluripotent cells

Embryonic Carcinoma Cells Abnormal karyotypes,
Teratomas Germline transmission unlikely

Adult
Zygote

Fetus Blastocyst

Primordial germ Cells Inner cell mass (ICM)

Embryonic Germ Cells Embryonic Stem Cells
Undergo spontaneous
Pluripotent cells
differentiation
Unable to support normal Partially
development understood
due to epigenetic modifications Great potential
during PGCs
 Criteria for pluripotency

✓ Immortality

✓ Undifferentiation

✓ Clonality

✓ Broad developmental potential
Demonstration of
pluripotency
 In vitro

a) Differentiation triggered when grown in suspension,
Embryoid Body formation

b) Different cells obtained spontaneously

c) Specific growth factors can be used to direct the
differentiation of ES cells into specific cells
 In vivo
a) Teratoma formation when injected into nude
mouse

b) When injected into host blastocysts, the ES cells
integrate, proliferate and differentiate into all
germ lineages including germ cells
Regulation of pluripotency in ES cells

“Pluripotency is maintained by
promotion of proliferation and
Inhibiting differentiation”
 Epigenetic modifications

ES Cells pluripotency

Transcription Factors

Stage specific Require other Target genes/
functioning processes receptors required
Factors Required

Nanog
Oct 3/4
Sox 2
LIF
c-Myc
Klf4
Zic3
 Core regulatory circuitry in ES cells

Activation of target genes
 Nanog

Transcription factor containing homeobox domain

Downstream effectors of signals of LIF and BMP

Elevated levels excludes inclusion of LIF and feeder layer

Works with other key factors including Oct4 and Sox2
 Oct3/4
❑ POU-domain transcription factor

❑ Maintains pluripotency (ESCs, EGCs, ECCs, GSCs)

❑ Tightly regulated transcription factor, associated with a number of
target genes implicated in pluripotency maintenance

❑ Regulatory elements in target genes are in close vicinity of Sox2-
binding sites

❑ Key factor in the transcriptional framework of self-renewing stem
cells
 Sox2
Member of HMG-domain DNA-BP family

Necessary for embryonal development and to prevent ES cell
differentiation

Many ES cell pluripotency-associated genes are co-regulated
by Sox2 and Oct3/4

A ternary complex formed with Oct4 or Oct1 on enhancer
sequence of Fgf4 is must for functioning

Cooperate with other TFs, e.g. Nanog to activate transcription
of pluripotency markers
 Leukaemia inhibitory factor,
LIF

Interleukin-6 cytokine family

Essential for maintaining pluripotency in vitro in the presence
of serum

Binds to a heterodimeric receptor comprising of LIF-receptor
(LIFR) and gp130 on cell membrane

Binding results in the activation of Jak/ Stat signal
transduction pathway

Activated Stat3 maintains pluripotency
 Combinatorial signaling pathways
(involving LIF and master regulator genes)
in maintaining mouse ESC pluripotency

Boiani and Scholer, 2005
 c-Myc

Helix-loop-helix/leucine zipper transcription factor

Takes part in a variety of cellular functions

Downstream effecter of STAT3 in LIF receptor signaling
pathway

c-Myc is a substrate for GSK3b in Wnt signalling pathway

Compensates anti-proliferative effects of Klf4, e.g. in iPS
cells
 Klf4

Member of the quartet, a Krueppel-type zinc finger
transciption factor

Can act as an oncogene and as a tumor suppressor protein

Over expression inhibits differentiation of ES cells

Klf4 upregulates, in concert with Oct3/4, but the role as co-
factor for Oct3/4 may be limited to only a few targets

Can repress p53, a negative regulator of Nanog
Pluripotent lineages in the mouse embryo

ll
 Pluripotent cells form the ICM of the blastocyst

After giving rise to the primitive endoderm on the surface
of the ICM, pluripotent stem cells form the
epiblast and start to proliferate rapidly after implantation

They then form the primitive ectoderm, a monolayer
epithelium that has restricted pluripotency
which goes on to give rise to the germ cell lineage and to
the somatic lineages of the embryo

Certain key transcription factors (blue) are required for
the differentiation of the various embryonic
lineages
Differentiation of mouse ES cells
 Differentiation of mouse ES cells

ES cells differentiate into three cell types –
❑ primitive endoderm
❑ trophectoderm (TE)
❑ primitive ectoderm
mimicking the differentiation potential of pluripotent stem cells in
preimplantation embryos

In the absence of LIF and in the presence of an excess of Oct3/4,
ES cells differentiate into primitive endoderm-like cells

In the absence of Nanog and in the presence of Gata6, they
differentiate into parietal endoderm-like cells

Removing Oct3/4 and adding Cdx2 to, ES cell culture induces TE-
like differentiation.

MEFc, mouse embryonic fibroblast conditioned medium
Regulation of proliferation of mouse ES
cells
 Regulation of proliferation of mouse ES
cells

❖ Pluripotent transcription factors activate the
expression of certain effectors that drive ES
cell proliferation

❖ Eras and Tcl1 stimulate the phosphoinositide-3-
kinase (PI3K)/Akt signaling pathway to promote
the cell cycle, whereas b-Myb and c-Myc
activate the progression of the cell cycle directly
 Transcriptional regulation of the mouse
Oct3/4 gene
A

B
 Zic3
Oct4 Sox2 Nanog

Zic3

Sox17, PDGFRA
Gata4, Gata6
Foxa2, Sox7

Endoderm

Zic3 contributes to the maintenance of pluripotency by operating
downstream of Oct4, Nanog, and Sox2 to inhibit endoderm
lineage specification as characterized by endodermal markers
Sox17, PDGFRA, Gata4, Gata6, Foxa2, and Sox7

The presence of Zic3 also maintains the expression of the
homeodomain protein Nanog, a key regulator of pluripotency in
embryonic stem cells
Epigenetic regulations of ES
cells pluripotency
Characteristics of the pluripotent
epigenome

The nucleus shrinks and the distribution of
electrondense areas (mainly heterochromatin)
changes dramatically when ES cells are induced
to differentiate into primitive endoderm by the
ectopic expression of Gata6
 Epigenetic features of the pluripotent
cell nucleus

Small regions of perinuclear heterochromatin exist, but most of
the chromatin exists as euchromatin, bearing histone marks
associated with transcriptional activity
The hyperdynamics of chromatin proteins (green) might contribute
to the maintenance of euchromatin
Bivalent domains are also a feature of the pluripotent epigenome,
in which active histone marks (such as H3K4me) are flanked by
transcriptionally repressive histone marks (such as H3K9me)