Animal Cell and Tissue Culture Lecture 6 PDF

Summary

This document is a lecture on animal cell and tissue culture, focusing on topics such as replicative cell senescence, telomeres, telomerase, and transformation. It's a detailed presentation of the topic, delivered at Universiti Malaya.

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SIO2004
Animal Cell and Tissue Culture
Lecture 6
Biotechnology Program
Universiti Malaya

Instructor: Dr. Nuradilla Mohamad Fauzi
Can normal cells divide forever and ever?
(in culture)

Nope, most normal cells have a finite lifespan!
(most of them will eventually stop dividing)
Replicative cell senescence
Multicellular organisms replace worn-out cells through cell division.
However, in many cells, proliferation slows down until cell division
eventually halts. Cells enter a non-dividing state, known as
senescence.
In humans this occurs, on average, after 52 divisions, known as the
“Hayflick limit”.
e.g. Human fibroblasts permanently cease dividing after 25-40 divisions
(population doublings)
In culture, primary cells have a finite lifespan.
Cells stop dividing because the telomeres, protective bits of DNA on
the end of chromosomes, shorten with each division, eventually
being consumed.
 Telomeres
A telomere is a region of repetitive nucleotide
sequences at each end of a chromosome.
Protects the end of the chromosome from
deterioration or from fusion with neighboring
chromosomes.
Disposable buffers at the ends of
By U.S. Department of Energy Human Genome Program -

chromosomes which are truncated during http://science.nasa.gov/media/medialibrary/2006/03/16/22mar_telomeres_resources/caps.gif, Public Domain,
https://commons.wikimedia.org/w/index.php?curid=5234303

cell division; their presence protects the
genes before them on the chromosome
from being truncated instead.

For vertebrates, the sequence of
nucleotides in telomeres is TTAGGG.
 Telomeres and cellular ageing
Each time a cell divides, some of the telomere is lost
(usually 25-200 base pairs per division)
In humans, average telomere length declines from about
11 kilobases at birth to less than four kilobases in old age
During chromosome replication, the enzymes that
duplicate DNA cannot continue their duplication all the
way to the end of a chromosome, so in each duplication
the end of the chromosome is shortened
When the telomere becomes too short, the
chromosome reaches a "critical length" and can no
longer replicate (the cell has become “old”)
Cells undergo senescence or apoptosis
 Telomerase
Telomerase is a reverse transcriptase enzyme that lengthens telomeres in
DNA strands
Adds telomere repeats
Prevents degradation of the chromosomal ends following multiple rounds of
replication
Telomerase activity is regulated during development.
Most post-natal somatic cells are deficient in telomerase.
 Cells that express telomerase
Which cells express telomerase?
Fetal tissues
Adult germ cells
Stem cells
Cancer and transformed cells

Telomerase expression can allow senescent cells that would otherwise
become post-mitotic and undergo apoptosis to exceed the Hayflick
limit, extend the lifespan of the cells, and become potentially immortal
(transformation!)
Transformation
Transformation of cultured cells: a spontaneous or induced permanent
phenotypic change resulting from a heritable change in DNA and gene
expression, leading to genetic instability.
It involves one or all of these phenotypic changes in a cell line:
(1) immortalization, the acquisition of an infinite life span,
(2) aberrant growth control; the loss of contact inhibition of cell motility, density
limitation of cell proliferation, and anchorage dependence, and
(3) malignancy, as evidenced by the growth of invasive tumors in vivo.
When injected into animals without functional immune system, transformed cell lines cause
tumors
Note: the acquisition of an infinite life span alone is referred to as
immortalization because it can be achieved without grossly aberrant growth
control and malignancy, which are usually linked.
Transformation and cancer
Transformed cell lines are the in vitro equivalent of cancerous cells.
Cancer occurs when a somatic cell which normally cannot divide
undergoes mutations which cause de-regulation of the normal cell
cycle controls leading to uncontrolled proliferation.
Immortalized cell lines have undergone similar mutations allowing a
cell type which would normally not be able to divide to be
proliferated in vitro.
Transformation methods
Natural/spontaneous
Mutations required for immortality can occur naturally, such as in tumor/cancer cells, or
randomly arise spontaneously in culture
Artificial expression of key proteins required for immortality (e.g. oncogenes)
e.g. telomerase!
Artificial inactivation of tumor suppressor genes
e.g. p53, Rb
Chemical mutagens
Treating primary cells or nontransformed cell lines with chemical carcinogens, DNA
methylation inhibitors
Introduction of viral genes
Introduction of a viral gene that partially deregulates the cell cycle, such as SV40 T
antigen, HPV-16 E6/7 gene
TUMOR SUPRESSOR ONCOGENE
In normal cells: ON In normal cells: OFF
In cancer cells: OFF In cancer cells: ON
e.g. p53, Rb e.g. telomerase
Example: how SV40 T antigen works
The SV40 LT gene is often used to induce immortalization.
The product of this gene, T antigen, is known to bind Rb
and p53.
By doing so, it restricts the DNA surveillance activity p53
and Rb, thereby allowing an increase in genomic
instability and an increased chance of generating further
mutations favorable to immortalization (e.g. the
upregulation of telomerase or the downregulation of one
of the telomerase inhibitors).
= allows an extended proliferative life span
Many cell lines cultured around the world are immortalize/cancer cells!

Examples of immortal/cancer cell lines
Most immortalized cell lines are classified by the cell type they originated from or
are most similar to biologically.
HeLa cells – a widely used human cell line isolated from cervical cancer patient,
Henrietta Lacks
3T3 cells – a mouse fibroblast cell line derived from a spontaneous mutation in
cultured mouse embryo tissue
A549 cells – derived from a cancer patient lung tumor
Jurkat cells – a human T lymphocyte cell line isolated from a case of leukemia
Vero cells – a monkey kidney cell line that arose by spontaneous immortalization
F11 cells – a line of neurons from the dorsal root ganglia of rats
HEK 293 cells – derived from human fetal cells

Wiki
Advantages of cancer/immortalized cell lines
Immortal!
Cells can be grown indefinitely in culture
Inexhaustible supply of cells throughout your research project
No need to re-establish fresh primary cultures
Ease of culture
no need complex medium or additives
In vitro model for cancer
Limitations of cancer/immortalized cell lines
Genome instability
Abnormal chromosomes
Cell lines can change genetically over multiple passages, which leads to
accumulation of mutations and variability between stocks
Poor model/not representative of normal tissues
While immortalized cell lines often originate from a well-known tissue type
they have undergone significant mutations to become immortal. This can
alter the biology of the cell and must be taken into consideration in any
analysis.
http://uvmgg.wikia.com/wiki/HeLa_Cells
 What if we want both??

Wouldn’t it be nice if we have cells that have long lifespans
AND
are representative of normal tissues and physiological
processes??

Stem cells!
Stem cells
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.
Alberts et al. (2002) Molecular Biology of the Cell, 4th edition
Importance of stem cells in vivo
Stem cells are the body's raw materials — cells from which all other
cells with specialized functions are generated
Cell renewal
Produce more cells
Replacing dead cells, cells lost through normal wear and tear
Repair damaged, diseased tissue
Essential for the development of the organism!
egg sperm

(zygote) (morula)
 Blastocoel
Trophoblast (cavity)
forms extraembryonic
tissues, e.g. placenta

Inner cell mass (ICM)
forms the embryo
(all embryonic tissues!)

Potency
(potential to
become
Endoderm Mesoderm Ectoderm different cell
types)
Differentiation
Specialization
Lineage
commitment
 egg sperm

(zygote) (morula)

Totipotent
Can differentiate into all embryonic
and extraembryonic tissues
 Blastocoel
Trophoblast (cavity)
forms extraembryonic
tissues, e.g. placenta

Inner cell mass (ICM)
forms the embryo Pluripotent
(all embryonic tissues!) Can differentiate into
all embryonic tissues

HSC
Multipotent MSC
Endoderm Mesoderm Ectoderm Can differentiate into
multiple tissue types

Oligopotent
Can differentiate into
a few tissue types

Tripotent (3)
Bipotent (2)
Unipotent (1)
(precursor cells)
fibroblasts
Terminally
differentiated
cells
Development, germ layers and development
A germ layer is a primary layer of cells that form
during embryogenesis
Germ layers eventually give rise to all of an animal’s
tissues and organs through the process of
organogenesis
In vertebrates, three germ layers:
Ectoderm is the outer most layer and gives rise to the integument including hair, nails and epidermis,
and the epithelial of the nose, mouth and the sense of the eye, the nervous system and inner ear).
Mesoderm is the middle layer and it forms the musculoskeletal, circulatory and most of the excretory
systems. Mesoderm also develops into gonads and the muscular and connective tissue in the digestive
and respiratory system.
Endoderm is the inner layer, which will eventually develop into the epithelia linings of the digestive and
respiratory tracts including the lungs. It also forms the pancreas, thyroid, bladder and distal urinary
tracts. Finally it will also form parts of the liver as well.
Development and cell potency
The developmental potential, or potency, of a cell describes the range of
different cell types it CAN become.
The zygote and its very early descendants are totipotent - these cells have the
potential to develop into a complete organism. Totipotency is common in plants,
but is uncommon in animals after the 2-4 cell stage (still under debate!*).
Throughout development; cells undergo progressive restrictions in their
developmental potentials.
Differentiation occurs when the cell elaborates a cell-specific developmental
program. Differentiation results in the presence of cell types that have clear-cut
identities, such as muscle cells, nerve cells, and skin cells.
As embryonic development proceeds, the potency of cells become progressively
more limited.

*Stem Cells Dev. 2014 Apr 15; 23(8): 796–812.
Q: Are stem cells really immortal?
Tbh, scientists are still figuring it out!
 Importance of stem cells in research
Due to their self-renewal and differentiation abilities, stem cells cultivated
in vitro are incredibly useful and important in research!
Increase understanding of developmental mechanisms, how diseases occur
Stem cell therapy: Regenerative medicine, transplantations
Transplantation to regenerate and repair diseased or damaged tissues in people
Grow new tissue in vitro
Bone marrow transplantations → “old-school” stem cell transplants!
Test new drugs for safety and effectiveness
Generate specific cell types for testing new drugs
Homing and delivery of compounds to target tissues
Stem cells can home to tumors, wounds/damaged tissues
 Cancer stem cells?
CSC Hypothesis—that cancers are perpetuated by a small population
of tumor-initiating cells that exhibit numerous stem cell-like
properties.
Researchers now believe that cancerous stem cells may trigger
reproduction and growth of cells within a cancer. These cancerous
stem cells lurking within the cancer, under the radar of cancer drugs
that target cell proliferation, may underlie the relapse of tumors after
surgery of the primary tumor or other cancer treatments.
Some breast and prostate cancer cases have fueled the cancer stem cell
theory. Often years after the organ or the cancerous lesions are removed and
the patient is declared cancer-free, breast or prostate cancer can return in
other organs, indicating the cancer had metastasized before it was originally
detected. Cancerous stem cells may be the reason for this.
The cancer stem cell model
suggests that the cells in a
tumour are in a strictly organised
system with cancer stem cells at
the top of the tree, giving rise to
all other cancer cells.

The stochastic model of cancer
growth argues that the cells in a
tumour are not in an organised
system – any cell has the same
intrinsic potential to contribute
to tumour growth.

Different types of cancer may
work in different ways, so it is
possible that both of these
models apply to different cancers
or different stages of tumour
development.
http://www.eurostemcell.org/factsheet/cancer-disease-stem-cells
 Evidence for cancer stem cells
There is no definitive proof in favor of either theory of cancer growth.
However, an increasing amount of evidence suggests that the cancer stem
cell theory holds true in some cases.
The first evidence in favor of cancer stem cells came from studies of human
leukemia. Researchers found that only a subset of leukemic cells can cause
leukemia when transplanted into a healthy body, the key characteristic of
cancer stem cells.
Since that discovery, many researchers have found cells with cancer stem cell
characteristics in a great variety of human and mouse cancers, including
breast, brain, skin, prostate and colonic cancers.
In some types of tumor the cancer stem cells are rare, for example in colon cancer.
In other types of cancer, such as melanoma, a very large number of the tumor cells
have cancer stem cell characteristics.
http://www.eurostemcell.org/factsheet/cancer-disease-stem-cells
How Do Cancer Stem Cells
Arise? The molecular pathways
that maintain "stem-ness" in
stem cells are also active in
numerous cancers. This
similarity has led scientists to
propose that cancers may arise
when some event produces a
mutation in a stem cell, robbing
it of the ability to regulate cell
division. This figure illustrates 3
hypotheses of how a cancer
stem cell may arise: (1) A stem
cell undergoes a mutation, (2) A
progenitor cell undergoes two or
more mutations, or (3) A fully
differentiated cell undergoes
several mutations that drive it
back to a stem-like state. In all
3 scenarios, the resultant cancer
stem cell has lost the ability to
regulate its own cell division.
https://stemcells.nih.gov/info/Regenerative_Medicine/2006chapter9.htm