SIO2004 Animal Cell and Tissue Culture Lecture 7 PDF

Summary

This document is a lecture on animal cell and tissue culture from Universiti Malaya. It covers the definition, identification, types, and clinical applications of stem cells. The presentation is likely to be useful for students taking a biotechnology program.

Full Transcript

SIO2004
Animal Cell and Tissue Culture
Lecture 7
Biotechnology Program
Universiti Malaya

Instructor: Dr. Nuradilla Mohamad Fauzi
Definition of stem cells
Stem cells are cells that are capable of:
Self-renewal:
the ability to go through numerous cycles of cell
division while maintaining the undifferentiated
state.
Differentiation
the capacity to differentiate into mature,
specialized cell types.
Identification of stem cells
Morphology and behavior
Cell surface markers (e.g. “CD” proteins)
Flow cytometry
Ability to self-renew
Clonogenic assay
Ability to differentiate
Differentiation assays
Morphology
Cell staining (cytochemical)
Gene expression of markers of differentiation
Types of stem cells commonly cultured
Unipotent stem cells / precursor cells
Fibroblasts
Osteoblasts
Multipotent stem cells
Mesenchymal stem cells (MSCs)
Hematopoeitic stem cells (HSCs)
Neural stem cells (NSCs)
Pluripotent stem cells
Embryonic stem cells (ES cells/ESCs)
Induced pluripotent stem cells (iPS cells/iPSCs)
Primordial germ cells (PGCs, especially in chickens)
http://www.nature.com/nrcardio/journal/v10/n7/fig_tab/nrcardio.2013.81_F1.html
Hematopoietic stem cells (HSCs)
Multipotent stem cells that give rise to all blood cells through the
process of hematopoiesis (Greek: “to make blood”)
In a healthy adult person, approximately 1011–1012 new blood cells are
produced daily in order to maintain steady state levels in the peripheral
circulation
HSC research began in the 1950s with the demonstration that
intravenously injected bone marrow cells can rescue irradiated mice
from lethality by reestablishing blood cell production.
HSC are rare, with estimated frequencies of 1 in 10,000 bone marrow
cells and 1 in every 100,000 blood cells.
Figure 22-35 A tentative scheme of
hemopoiesis

The multipotent stem cell normally divides
infrequently to generate either more multipotent
stem cells, which are self-renewing, or committed
progenitor cells, which are limited in the number
of times that they can divide before differentiating
to form mature blood cells. As they go through
their divisions, the progenitors become
progressively more specialized in the range of cell
types that they can give rise to, as indicated by the
branching of the cell-lineage diagram in the region
enclosed in the gray box. Many of the details of
this part of the lineage diagram are still
controversial, however.

In adult mammals, all of the cells shown develop
mainly in the bone marrow—except for T
lymphocytes, which develop in the thymus, and
macrophages and osteoclasts, which develop from
blood monocytes. Some dendritic cells may also
derive from monocytes. Mast cells (not shown) are
thought to develop from circulating basophils.
By User:Mikael Häggström and A. Rad - File:Hematopoiesis (human)
diagram.png, by A. Rad., CC BY-SA 3.0,
https://commons.wikimedia.org/w/index.php?curid=11107853

Diagram including some of the
important cytokines that determine
which type of blood cell will be created.

SCF= Stem cell factor Tpo= Thrombopoietin IL= Interleukin
GM-CSF= Granulocyte Macrophage-colony stimulating factor
Epo= Erythropoietin M-CSF= Macrophage-colony stimulating
factor G-CSF= Granulocyte-colony stimulating factor SDF-1=
Stromal cell-derived factor-1 FLT-3 ligand= FMS-like tyrosine
kinase 3 ligand TNF-a = Tumour necrosis factor-alpha TGFβ =
Transforming growth factor beta
 Isolation of HSCs
HSCs are found in the bone marrow. They are HSC
also found in umbilical cord blood and, in small
numbers, in peripheral blood.
To harvest HSCs from the circulating peripheral
blood, blood donors are injected with the cytokine
granulocyte-colony stimulating factor (G-CSF), which
induces HSCs to leave the bone marrow and
circulate in the blood vessels.
CD34
The classical marker of human HSCs is CD34.
They do not express cell surface markers that are
found on mature blood cells.
If we tag HSCs with fluorescent antibodies that bind
to CD34, flow cytometry can select for these cells!
 Flow cytometry
Flow cytometers are automated
instruments that quantitate properties of
single cells, one cell at a time.
Flow cytometers take in a suspension of
single (unclumped) cells and run them one
at a time past a laser beam. As each cell
passes through the laser beam, scattered
and fluorescent light are quantitated.
The machine sorts and counts the cells that
have been labelled or tagged using
fluorescent antibodies or dyes.
They can count cells, measure cell size, cell
granularity, amounts of cell components
such as total DNA, mRNA, amounts of
intracellular proteins, or amounts of specific
surface receptors.
Resulting data show the proportion different
sub-populations of cells with different
properties within the sample.
Fluorescence-activated cell sorting (FACS)
A specialized type of flow cytometry that sorts a
heterogeneous mixture of biological cells into two or
more containers, one cell at a time, based upon the
specific light scattering and fluorescent
characteristics of each cell.
Provides fast, objective and quantitative recording of
fluorescent signals from individual cells as well as
physical separation of cells of particular interest.
Can be used to select for the sub-population of cells
(e.g. stem cells) that you are interested in!
In the case of HSCs: cells that are CD34+ !

http://www.unifr.ch/pathology/assets/images/FACS%20Schema.jpg
e.g. antibody against CD34

By SariSabban - Sabban,
Sari (2011) Development of
an in vitro model system
for studying the interaction
of Equus caballus IgE with
its high- affinity FcεRI
receptor (PhD thesis), The
University of Sheffield, CC
BY-SA 3.0,
CD34- cells CD34+ cells https://commons.wikimedi
a.org/w/index.php?curid=1
8139883
https://www.youtube.com/watch?v=CeC2cFIsA0U
Clinical applications of HSC
The application of most classes of adult stem
cells is either currently untested or is in the
earliest phases of clinical testing. The only
exception is HSCs, which have been used
clinically since 1959 and are used increasingly
routinely for transplantations, albeit almost
exclusively in a non-pure form.
To date, close to 1.5 million hematopoietic cell
transplants have been performed in more than
1,500 transplantation centers worldwide

Virtually all HSC transplants are carried out with either non-purified, mixed cell populations
(mobilized peripheral blood, cord blood, or bone marrow) or cell populations that have
been enriched for HSCs (e.g. by selection for CD34+ cells), for treatment of:
hematopoietic cancers (leukemias and lymphomas),
the use of high-dose chemotherapy for non-hematopoietic malignancies (cancers in other organs)
Diseases that involve genetic or acquired bone marrow failure, such as aplastic anemia, thalassemia,
sickle cell anemia, and increasingly, autoimmune diseases.
 HSC

Risk of graft versus
host disease

GVHD: donor immune cells attacks the host
 Banking of UCB samples: if expansion of
fully functional HSCs in tissue culture
becomes a reality, HSC transplants may be
possible by starting with small collections of
HSCs from UCB banks
Collections of HSCs from volunteer
donors or umbilical cords could be
theoretically converted into storable,
expandable stem cell banks useful on
demand for clinical transplantation
and/or for protection against radiation
accidents.
https://www.forbes.com/sites/tylerroush/2024/07/18/hiv-stem-cell-treatment-likely-cures-7th-person-in-history-of-virus-doctors-say/
http://www.nature.com/nrcardio/journal/v10/n7/fig_tab/nrcardio.2013.81_F1.html
Mesenchymal stem cells: history
Also known as such as “mesenchymal stromal cells” or
“multipotent stromal cells”
In 1970, Friedenstein et al. discovered a rare population
of precursor cells from the bone marrow that were able
to form fibroblastic colonies and were capable of bone
formation.
These progenitor cells isolated from marrow tissue
were then dubbed “mesenchymal stem cells” by Arnold
Caplan in 1991, referring to their mesenchymal tissue of
origin and ability to self-renew and differentiate into
either osteoblasts or chondrocytes.
In 1999, Pittenger et al. reported the isolation of these
cells from human bone marrow tissue and showed that
these cells possessed multipotent differentiation
capacities.
 Clonogenic assay
Cells that have the capability to self-
renew are able to proliferate from a
single cell into a colony – MSCs can!
Each colony is a ‘clone’
Can estimate % of stem cells within a
sample (colony-forming units, CFU)

J Anim Sci Biotechnol. 2015 Jan 11;6(1):1. doi: 10.1186/2049-1891-6-1. eCollection 2015.
http://www.nvrb.org/2016/10/31/radiation/
MSCs are multipotent adult/somatic stem cells
Have been shown to differentiate into mesodermal tissue types:
bone (osteocytes)
cartilage (chondrocytes)
fat (adipocytes)
smooth muscle (smooth myocytes)
skeletal muscle (skeletal myocytes)
cardiac muscle (cardiomyocytes)
tendon (tenocytes) and ligament
Front. Immunol., 04 September 2013 | http://dx.doi.org/10.3389/fimmu.2013.00201
*only applicable to human MSCs?
Differentiation
= manipulating culture conditions to stimulate the process of
differentiation
Mimic cell-to-cell contact necessary for differentiation (e.g. confluency)
Adding compounds (growth factors, hormones, cytokines, etc.) to the
media
Induce expression of genes important for differentiation into the
specific tissue type
In vitro differentiation: osteogenic
Standard procedure: treatment of a confluent
monolayer with a cocktail of dexamethasone,
ascorbic acid and β-glycerophosphate.
These substances on intracellular signaling
cascades that lead to osteogenic differentiation
Dexamethasone induces expression of RUNX2
(earliest marker of osteogenesis; a transcription
factor that is essential for osteogenic
differentiation)

Journal of Cell Science 2008 121: 1002-1013; doi: 10.1242/jcs.019315
 Cytochemical staining
Following fixation, cells and tissues could be stained with dyes that target specific compounds.
These stains are used to selectively stain cells and cellular components used to characterize tissues.

Alizarin Red S – stains calcium
(for bone)
Mohamad-Fauzi et al. Journal of Animal Science and Biotechnology 2015, 6:1 / Mohamad-Fauzi personal collection
 Dexamethasone (Dex) induces the osteogenic differentiation of stem cells by increasing the transcription of FHL-2. Binding of FHL-2 to β-catenin potentiates the
transport of β-catenin to the nucleus, where it binds TCF/LEF-1 (T-cell factor/lymphoid enhancer factor) and leads to the transcription of Runx2. Dex also contributes
to osteogenic differentiation by increasing the expression of the Runx2 co-activator TAZ. Additionally, Dex treatment induces the expression of the gene encoding
MKP-1 (a component of the mitogen-activated protein kinase (MAPK) signaling pathway), which dephosphorylates and thereby activates the key transcription factor
Runx2 via extracellular related kinase (ERK) signaling. The addition of ascorbic acid (Asc) facilitates osteogenic differentiation by increasing secretion of collagen type
I (Col1), resulting in increased binding of α2β1 integrins to Col1. This leads to the phosphorylation of ERK1/2 in the MAPK signaling pathway, and a subsequent
translocation of P-ERK1/2 to the nucleus where it activates Runx2 by phosphorylation. Abbreviations: ECM, extracellular matrix; +OH, hydroxylation; MEK,
Stem Cell Res Ther. 2013; 4(5): 117. MAPK/ERK Kinase; FAK, Focal Adhesion Kinase; P, phosphate.
In vitro differentiation: chondrogenic
Similar to osteogenic media: inductive
media contains dexamethasone and
ascorbic acid, but with the addition of
insulin-transferrin-selenium (ITS) and
TGF-β3 or TGF-β1
Done in pellet cultures, or by
differentiating cells in a micromass
culture system
Culturing in these systems mimics the
cellular condensation phase that occurs at
the initiation of mesenchymal
chondrogenesis
Cell-to-cell contact and cell shape appear to
promote chondrogenesis
Stem Cell Res.10(3): 464-76, 2013
 Cytochemical staining
Following fixation, cells and tissues could be stained with dyes that target specific compounds.
These stains are used to selectively stain cells and cellular components used to characterize tissues.

Alcian Blue – stains proteoglycans Alizarin Red S – stains calcium
(for cartilage) (for bone)
Mohamad-Fauzi et al. Journal of Animal Science and Biotechnology 2015, 6:1 / Mohamad-Fauzi personal collection
In vitro differentiation:
adipogenic

Addition of dexamethasone,
isobutyl methylxanthine
(IBMX), indomethacin and
insulin to the media
Cell-to-cell contact is necessary
cells that do not eventually reach
full confluence fail to
differentiate
 Cytochemical staining
Following fixation, cells and tissues could be stained with dyes that target specific compounds.
These stains are used to selectively stain cells and cellular components used to characterize tissues.

Alcian Blue – stains proteoglycans Alizarin Red S – stains calcium Oil Red O – stains triglycerides
(for cartilage) (for bone) (for fat)
Mohamad-Fauzi et al. Journal of Animal Science and Biotechnology 2015, 6:1 / Mohamad-Fauzi personal collection
Tissues of origin
MSCs can be isolated from:
BM-MSCs
Bone marrow UC-MSCs

Adipose tissue
Wharton’s Jelly
Umbilical cord blood
AD-MSCs

Even though MSCs isolated from different tissues appear similar/identical in
morphology, they have been shown to demonstrate phenotypical differences,
such as in expansion rates, cell surface marker profile, and differentiation
capacities.
MSCs have been
isolated from a
multitude of
species to date!
 MSCs are one of the most studied classes of
adult stem cells
Ease of culture and expansion in vitro in medium with no or minimal
additives
Possible isolation from multiple tissue sources
isolation from adult tissue allows for autologous transplantation
Ability to differentiate into bone and cartilage, hence serving as a
potential source of cells for osteochondoral regeneration
such as repairing segmental bone defects and restoring cartilage in the context
of injury or diseases such as osteoarthritis and osteoporosis
in one clinical trial, as patients who received autologous BM-MSC
transplantations for articular cartilage showed no signs of tumors or
abnormalities after 11 years
Wilson SM et al. Journal of Oral and Maxillofacial Surgery [01 Mar 2012,
70(3):e193-203]
 Low immunogenicity due to their immunosuppressive abilities
heterologous (allogeneic) transplantation of MSCs is feasible
treat autoimmune diseases, such as rheumatoid arthritis and systemic lupus
modulate inflammation
MSC

MSC
 Critically ill COVID-19 patients treated with non-
altered stem cells from umbilical cord connective
tissue were >2x as likely to survive as those who
did not have the treatment.
The trial used stem cells obtained through
explants from actual umbilical cord tissue.
https://www.eurekalert.org/news-releases/827321
 Remember that MSCs have …

Low immunogenicity due to their immunosuppressive abilities
heterologous (allogeneic) transplantation of MSCs is feasible
treat autoimmune diseases, such as rheumatoid arthritis and systemic lupus
support allografts by suppressing host immune rejection: infusion of MSCs
also treat existing graft-versus-host disease (GVHD) in patients who received
heterologous HSC transplants
Donor immune cells against host tissues
Reduce risk of graft versus host disease

MSC

MSC
HSC
 Ability to migrate and promote healing
to damaged tissue/sites of injury, direct repair and support tissue regeneration
to sites of inflammation, and reduce inflammation and recruit immune cells
to tumors

Secretes signaling factors to nearby cells (paracrine)
growth factors, cytokines, and other bioactive factors produced by MSCs may be
contained in exosomes and microvesicles that function in a paracrine manner
these exosomes can be administered as cell-free therapy

https://www.nature.com/articles/s41536-019-0083-6
https://doi.org/10.1016/j.ymthe.2018.05.009
 Ability to migrate and promote healing
to damaged tissue/sites of injury, direct repair and support tissue regeneration
to sites of inflammation, and reduce inflammation and recruit immune cells
to tumors

Potential of using modified MSCs as delivery vehicles
deliver therapeutics to tumors
https://doi.org/10.1016/j.jconrel.2020.10.037
 Typical immunotherapies work by harnessing the power of
the immune system. In CAR T-cell therapy, for example,
patients receive a transfusion of their own T cells that
have been modified to recognize a specific protein on the
surface of cancer cells and then destroy the cancer. “But if
you reprogram immune cells to kill cancer by fiddling
around with your endogenous immune system, [there
could be] some side effects,” says coauthor and
bioengineer Martin Fussenegger of ETH Zurich.

In a study published [November 13, 2017] in Nature
Chemical Biology, researchers have generated nonimmune
cells with the ability to kill cancer cells on contact.... the research team built a cancer-detecting sensor in …
human mesenchymal stem cells.... When the receptors
come into contact with a cancer cell presenting the
antigens they recognize... [this interaction] launches a
falling-domino cascade of reactions—some endogenous
and some that Fussenegger and colleagues engineered
into the cell lines—ultimately resulting in the release of a
drug-activating enzyme. The enzyme is then trafficked
into nearby cells and, in the presence of a prodrug,
converts the medicine into its active form, killing the
https://www.the-scientist.com/?articles.view/articleNo/50933/title/Researchers- cells.
Build-a-Cancer-Immunotherapy-Without-Immune-Cells/
https://doi.org/10.1016/j.ymthe.2018.05.009
 Multipotent stem cells are cool,
but their differentiation capacity is limited …

What if we can work with stem cells that can
potentially divide into any tissue type?