2024 Stem Cells, Cell Asymmetry, and Cell Death Notes (BIOL 374)

Summary

These notes from Burman University cover stem cells, cell asymmetry, and cell death. The document defines relevant terms and discusses different categories of stem cells, including examples like adult stem cells and embryonic stem cells. It also explores cell lineage and differentiation.

Full Transcript

Burman University, BIOL 374 Cellular Biology, Stem Cells

Stem Cells, Cell Asymmetry, and Cell Death (Topic 9)

Learning Objectives: After completing this module, you will be able to
1. Define the following terms: apoptosis, apoptosome, asymmetric vs symmetric cell
division, Bcl-2 family, caspases, cell fate, cell lineage, embryonic stem cells, iPS cells,
multipotent, pluripotent, progenitor cells, stem cell, stem-cell niche survival signals and
totipotent.
2. Differentiate the different categories of stem cells used in biological research and
therapy.
3. Discuss the key stem cells in the intestinal stem-cell niche.
4. Compare apoptosis to necrosis.

Text: Lodish et al. (2021), Ch. 22

Verse: The sons of Noah who came out of the ark were Shem, Ham and Japheth. (Ham was the
father of Canaan.) These were the three sons of Noah, and from them came the people who
were scattered over the whole earth. Gen 9:18-19 (NIV)

Are you affected by increasing divisiveness, whether it is political leanings, or races, or
nationalities, or gender, or religion (Christian/Muslim), or vaccinated/unvaccinated, that exists in
this world? The Bible reminds us that we are all related – brothers and sisters, family – with the
same lineage. Let us do our part to break down these divisive barriers. Be kind and love one
another!

9.1 Cell lineage
§ Developmental history of a cell from its birth until its final
division and differentiation into a particular cell type is known as
its cell fate.
§ A cell lineage traces the birth order of cells as they progressively
become more restricted in their developmental potential and
differentiate into specialized cell types [F22-1c].
§ e.g., cell lineage in the nematode worm C. elegans is well defined
for all cells of this organism (F22-26).

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§ Cell fate in the embryo can be determined by cell location experiments in a labelled cell
and followed during development [F22-26bc].

9.2 Stem cells

§ Unspecialized cells that can reproduce themselves
(i.e., self-renewing) as well as generate specific
types of more specialized cells are called stem cells
(F22-11).
§ There are four main types of stem cells as
categorized by the researchers working with them:
1. Adult stem cells are stem cells that are derived from a stem cell that is present in
adult tissue.
2. Fetal stem cells are stem cells that are taken from fetuses; these are more powerful
and have more differential potential then adult stem cells.
3. Embryonic stem cells are taken from blastocyst, an early-stage embryo usually at 4-
5 days after fertilization. Embryonic stem cells have the most potential for
differentiation amongst them all.
4. Induced stem cells (or induced pluripotent stem cells; iPS) are adult cells that have
been reprogrammed to give rise to stem cell capabilities.

§ Totipotent cells [F22-2]
- Human embryos pass through an
8-cell stage in which each cell can
still form every tissue, both
embryonic and extraembryonic (e.g., placental tissue).
- These 8 cells are totipotent.
§ ES cells
- At 16-cell stage, some of the cells are committed to particular differentiation paths,
hence are no longer totipotent.
- At the blastocysts stage, a distinctive inner cell mass becomes separated from other
cells. These inner cell mass become embryonic stem cells (ES cells) that can
generate all embryonic tissues, but not extraembryonic tissues (i.e., placental tissues).
- These ES cells are pluripotent. Pluripotent cells can give rise to all the cell types
that make up the body.
- The pluripotency of ES cells is controlled by
multiple factors: [F22-5]
1. State of DNA methylation
2. Chromatin regulators
3. Certain miRNAs
4. Transcription factors like Oct4, Sox2 and Nanog.
- ES cells can be grown indefinitely in culture (in defined media on a bed of
fibroblast cells that nourish the stem cells by providing specific growth factors),

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where they can divide symmetrically, so that each daughter cell
remains pluripotent and can potentially give rise to all the tissues
of an animal [F22-4a].

§ Adult stem cells
- Most cells have lifespans much shorter than that of the organism
and so need to be constantly replaced, e.g., cells lining stomach
and some immune cells live only a few days.
- Adult stem cells are thus important in the replacement of these
cells.
- Unlike ES cells, adult stem cells are multipotent (except germ-
line stem cells that are unipotent).
- Multipotent cells can develop into more than one cell type but are more limited
than pluripotent cells because they cannot generate all cell types.
- The number of stem cells of a particular type
stays constant (F22-12a) or increases (F22-12b)
during an organism’s lifetime.
- Other daughter cells, termed transiently
amplifying cells, divide rapidly, and undergo
limited numbers of self-renewal divisions, but
ultimately produce lineage-restricted progenitor cells F22-11).

§ Hematopoietic stem cells replenish all the necessary blood cells. Progenitors and
precursors proliferate under the control of distinct cytokines [F22-18].

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§ Intestinal stem cells continuously generate all the cells of the intestinal epithelium.
- The most abundant epithelial cells, the absorptive enterocytes, transport nutrients
essential for survival from the intestinal lumen into the body.
- The intestinal epithelium is the most rapidly self-renewing tissue in adult
mammals, turning over every 5 days (in humans 300 million intestinal epithelium
cells are lost daily).
- The most differentiated cells reside at the tips of
the villus, and are regenerated when damaged,
sloughed, or aged. These cells are continually
regenerated from a stem-cell population located
deep in the intestinal wall in pits called crypts
(F22-14).
- Stem cells are formed in niches that provide
signals to maintain a self-renewing population of
undifferentiated stem cells.
- The niche must maintain stem cells without
allowing their excess proliferation and must
block differentiation (via specific controls that
involve signaling pathways, e.g., Wnt pathway in
intestinal niches).
- Intestinal stem cells reside at the base of the crypts
express the Lgr5 receptor. Lgr5+ cells are the
precursors of the transit amplifying cells, the
terminal differentiating cells and several
differentiated epithelial cells in the villus.
- Lgr5+ stem cells begin to differentiate as they are
pushed out of the niche at the bottom of the crypt
when the Wnt signal is reduced.
- If the Notch signal is present, Lgr5+ cells
differentiate towards absorptive enterocytes;
otherwise, they become secretory cells (Notch off).
- These Lgr5+ cells are adjacent to the Paneth cells,
which form part of the niche. Paneth cells secrete
antimicrobial defense proteins. They are produced
from the transit amplifying cells every 3-6 weeks.
- The +4 “reserve” stem cells (which occupies the 4th position from the crypt base)
can restore the Lgr5+ stem cells following injury. They are also generated from the
Lgr5+ cells (F22-14b).
- Telocytes are thin cells with long protrusions that form a 3-dimensional network
underlying the epithelial cells throughout the intestines and are the major source of
growth factors (Wnt, Notch, etc) necessary for stem-cell self-renewal.
- Enteroendocrine cells are specialized cells that produce and release hormones in
response to several stimuli.
- Tuft cells, sometimes referred to as brush cells, are chemosensory cells in the
epithelial lining of the intestines and respiratory tract.

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- The main role of goblet cells is to secrete mucus to protect the mucous membranes.
- M cells are highly specialized immune cells that take up intestinal microbial antigens.
§ iPS
- Induced pluripotent stem (iPS) cells
can be derived from somatic cells by
the expression of combinations of
key transcription factors, including
KLF4, Sox2, Oct4 and Myc.
- Differentiated cells produced in
culture from human iPS cells can be
used to understand the underlying
cause of a disease as well as to screen
drugs that can be used to treat the
disease, e.g., ALS (F22-7).
- b islet cells produced in culture from
human iPS cells secrete insulin
normally in response to an elevation
of glucose in the media and reverse
the high glucose levels in diabetic
mice.

9.3 Cell Polarity and Asymmetric Cell Division
§ Symmetric cell divisions [F22-1a]
- Many yeasts, fungi and other single-celled eukaryotes
undergo symmetric cell division, where division gives rise to
two daughter cells that look and function exactly like the
parent cell.
- Mature hepatocytes also divide symmetrically.

§ Asymmetric cell divisions [F22-1b]
- In complex multicellular plants and animals, distinct
developmental or environment signals result in daughter
cells inheriting different components (e.g., mRNA,
proteins) from the parental cells despite receiving the same
genes.
- Daughter cells may differ in size, shape, or protein composition, or their genes may
be in different states of activity or potential activity.
- Asymmetric cell division requires that the parental cell to become asymmetric, or
polarized before cell division, so that the cell contents are unequally distributed to
daughter cells.
- Cells have an intrinsic program that can generate polarity using feedback loops.

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§ General steps in generating polarized cells:
1. To know in which orientation to polarize, cells must be
exposed to a spatial clue.
2. Receptors (or other mechanisms) to sense the clue.
3. Signal transduction pathway initiated
4. to regulate the cytoskeleton (microtubules and/or
microfilaments) to reorganize in the appropriated polarized
manner.
5. Polarized cytoskeleton provides framework for the transport
of fate/cell polarity determinants.
6. Reinforcement of cell polarity determinants (F22-24a).

§ Cell polarity determinants
- Cell polarity requires specific determinants, including
mRNAs, proteins, and lipids, to be asymmetrically localized
in a cell.
- If the mitotic spindle is positioned so that these
determinants are segregated during cell division,
the two daughter cells will have different cell fate
determinants (F22-24b).
- Otherwise, if mitotic spindle is not orientated
appropriately, the determinants will not be segregates
properly, and the daughter cells could have the same
fate.

9.4 Cell death
§ Vertebrate cells require trophic factors (or survival signals) to
survive. In the absence of these factors, cells commit suicide via a
programmed cell death called apoptosis.
§ Conserved apoptotic pathways include 3 components -
membrane-bound regulatory proteins, cytosolic regulatory
proteins, and apoptotic proteases (called caspases in
vertebrates).
§ Once activated, caspases cleave specific intracellular substrates,
leading to the demise of the cell.
§ Other proteins, like CED-4 and Apaf-1, that bind the cytoplasmic
regulatory proteins and caspases are required for caspase
activation.
§ Apoptotic cells shrink, condense, and then fragment, releasing
small membrane-bound apoptotic bodies, which are engulfed by
neighbouring phagocytic cells (F22-34a). Unlike necrotic cells
that swell and burst, releasing their intracellular content, which
can damage surrounding cells and frequently cause inflammation.

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§ The Bcl-2 family contains pro- and anti-apoptotic
proteins, where most are transmembrane proteins [F22-41].

§ In mammals, apoptosis can be triggered by oligomerization
of Bax or Bak proteins. These pro-apoptotic members of the
Bcl-2 family form channels in the outer mitochondrial
membrane, leading to efflux of cytochrome c and
SMAC/DIABLO proteins to the cytosol.
§ These proteins then promote caspase activation and cell
death (F22-36b, 22-42).
§ Bcl-2 (and Bcl-xL) can restrain the oligomerization of Bax
and Bak by binding to them, thus blocking cell death.
§ Pro-apoptotic BH3-only proteins (e.g., Puma, Bad, Bim)
activated by environmental stress bind directly to Bcl-2,
causing Bax and Bak to dissociate from Bcl-2. This stimulates the oligomerization of Bax
and Bak, allowing cytochrome c to escape into the cytosol. In the cytoplasm cytochrome
c binds to Apaf-1 activating caspases (F22-42).
§ Direct interactions between pro- and anti-apoptotic proteins lead to cell death:
1. Binding of extracellular trophic factors can trigger changes in these interactions,
resulting in cell survival
(F22-42, step 1). A survival
signal generated by trophic
factor binding to their receptors
trigger a phosphorylation relay
that leads to the phosphorylation
of Bad. Bad is sequesterd by
cytosolic 14-3-3 protein upon
phosphorylation and unable to
bind Bcl-2.
2. DNA damage leads to the
induction of Puma gene
synthesis. Puma binds to
Bcl-2.
3. Removal of cells from its
substratum result in a
disruption of integrin signaling
leading to the release of Bim
from the cytoskeleton. Bim
also binds to Bcl-2 to promote
Bak-Bax pore formation.

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§ Fas-mediated apoptosis
- Binding of extracellular death signals, like
tumor necrosis factor and Fas ligand, to their
receptors oligomerizes an associated protein
FADD, which in turn triggers the caspase
cascade, leading to apoptosis [F22-44a].

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