Haematopoietic Stem Cell Sciences PDF

Summary

This document provides an introduction to haematopoietic stem cells, covering topics such as embryogenesis, properties, types, applications, and challenges within the context of medical laboratory sciences. It offers a detailed exploration of these key concepts.

Full Transcript

Chapter 1

Introduction to Haematopoietic Stem Cells

Medical Laboratory Sciences
Haematopoietic Stem Cell Sciences

Dr. Ali Abdelfattah
 Headlines

Embryogenesis
Definition of stem cells
Properties of stem cells
Different types of stem cells
Applications of stem cells
Challenges of stem cell research
 Embryogenesis

Embryology is the study of embryos and their development.

Embryonic period vs Fetal period
▪ Embryonic period is first 8 weeks after fertilization
including the development of the three primary germ
layers that give rise to all body structures.
▪ Fetal period is a period of 30 weeks, where organs
continue to grow and develop.

❑Human body composed of approximately 220
types of cells with about 50-75 trillion cells.
 Embryogenesis

Stages of development
Fertilization: The process of fusion of the sperm with the
mature ovum, producing the fertilized single mono- nucleated
cell called the zygote.
Cleavage: a sequence of rapid mitotic divisions (without cell
growth). Cleavage starts approximately 30 hrs after fertilization.
Gastrulation: A phase in which the single-layered structure
(blastula) converts into a three-layered structure known as the
gastrula.These three germ layers are known as the ectoderm,
mesoderm, and endoderm.
Organogenesis: The production and development of the organs
 Embryogenesis

Cleavage
The morula enters the
(Day 3-4)
uterus approximately 4
days after fertilization.
Fluid accumulates
within the morula and
forms blastocyst
6-7 days after
Fallopian
tube fertilization, the
blastocyst attaches to
the endometrium and
(Day 5-6) implantation begins
Implantation
Three germ layers
forms around 2 weeks
after fertilization).
 Embryogenesis

▪ Trophoblast: layer of outer cells that will form the placenta
▪ Blastocoel: inside the blastocyst that will form body cavity
▪ Inner cell mass (Embryoblast, ESCs): inside the
blastocyst that will form the embryo

Upon implantation of the blastocyst, the trophoblast will
differentiate into the cytotrophoblast and the
syncytiotrophoblast.
▪ The syncytiotrophoblast produces human chorionic
gonadotropin (hCG). Secreted hCG enters the maternal
blood circulation and is approximately sufficient by the end
of the second week post fertilization to yield a positive
pregnancy test.
Embryogenesis

The embryoblast undergoes cellular
differentiation into two layers: the hypoblast,
which forms the yolk sac, and the epiblast,
which forms the amnion. These two layers will
give rise to the three germ cell layers that will
form all the body’s tissues and organs.

Ectoderm generates the outer layer of the embryo
and produces the skin cells and the nervous system
Endoderm becomes the innermost layer of the
embryo and gives rise to the cells that line the
internal organs including gut, liver, lungs, and
pancreas
Mesoderm becomes the middle layer between the
ectoderm and endoderm and generates the blood,
heart, kidney, bones, and connective tissues
 What Are Stem Cells?

Stem cells provide the starting material for every organ
and tissues
Difference between stem cell and other body cells
▪ Ability to divide throughout life
▪ Ability to differentiate into many different cell types

❑ Stem cells are the mother cells
that have the ability to
continuously reproduce
themselves and differentiate
into other kinds of cells/tissues
(specialized cells)
The unique properties of all stem cells
 Unique properties of stem cells

Stem cells are unspecialized cells
They do not yet have any tissue specific structures that allow them to perform
specialized function.
Self-renewal potential
They can undergo unlimited cell division to repopulate themselves for indefinite
periods
Differentiation (Potency)
Stem cells can differentiate under proper physiological conditions to specialized
cells such as heart muscle cells, blood cells or nerve cells required to repair
damaged or depleted cells
Plasticity
Stem cell from one tissue may be able to give rise to cell types of completely
different tissue
e.g. Haematopoietic stem cells becoming nerve cells or heart cells
Stem cell potency
 Stem cell potency

❑ Totipotent stem cells: can become any cell in body, placenta,
and umbilical cord
Each cell can form a complete organism

❑ Pluripotent stem cells: can become any cell in body
Undifferentiated inner cell mass of blastocyst
Form approximately 200 different cell types

❑ Multipotent stem cells: can become any cell within a specific
tissue/organ
Ability to differentiate is more limited
 Stem cell potency

The difference between totipotent and pluripotent cells depends
on the cellular potency

The difference between totipotent and pluripotent cells is only
that totipotent cells can give rise to the placenta, the umbilical
cord, and the embryo, while pluripotent cells can only give rise
to the embryo

Totipotent stem cells form around 220 different cell types
Pluripotent stem cells form around 200 different cell types
Stem cell potency
Stem cell timeline
Stem cells exist in both
embryos and adults
 Types of stem cell

❑Pluripotent stem cells
Embryonic stem cells (ESCs)
Induced pluripotent stem cells (iPSCs)

❑Multipotent stem cells
Cord blood stem cells
Placenta stem cells
Tissue-specific stem cells (Adult stem cells)
Hematopoietic stem cells (HSCs)
Mesenchymal stem cells (MSCs)
Intestinal stem cells
Endothelial stem cells
Neural stem cells
 Pluripotent stem cells

Pluripotency describes the ability of a cell to develop
into the three primary germ cell layers of the early
embryo and therefore into all cells of the adult body
Embryonic stem cells (ESCs)
Induced pluripotent stem cells (iPSCs)
 Embryonic stem cells (ESCs)

Embryonic stem cells (ESCs) are derived from inner cell
mass of the blastocyst, a ball of around 50 cells, which
develops 5-6 days after conception, before the embryo
implants in the uterus

ESCs are pluripotent stem cells
▪ These cells have self-renew potential
▪ These cells can differentiate to become
almost every cell in the body
 Embryonic stem cells (ESCs)

Researchers extract ESCs from a 5-6 days old blastocyst
ESCs can divide in culture to form a new stem cell line.
The research aims to induce these cells to generate healthy
tissue needed by patients.
 Induced pluripotent stem cells (iPSCs)

❑ Scientists have recently discovered how to turn adult stem cells
(multipotent stem cells ) into pluripotent stem cells. These cells
are called induced pluripotent stem cells (iPSCs).

They can differentiate into all types of specialized cells in the body.
This means they can potentially produce new cells for any organ or
tissue.

iPSCs are generated by process known as “de-differentiate”
It is a process by which cells develop in reverse and become less
specialized, from a more differentiated to a less differentiated state.

To create iPSCs, scientists genetically reprogram the adult stem cells
so they behave like embryonic stem cells.
 Induced pluripotent stem cells (iPSCs)

❑ Scientists are hoping that the
cells can be made from
someone’s own skin to treat a
disease. This will help prevent
the immune system from
rejecting an organ transplant.
Research is underway to find
ways to produce iPSCs safely
 Multipotent stem cells

❑ Multipotent stem cells can develop into more than one cell type,
but are more limited than pluripotent cells

❑ Multipotent stem cells have the capacity to self-renew and to
develop into multiple specialised cell types present in a specific
tissue or organ
❑ Types of Multipotent stem cells
Cord blood stem cells
Placenta stem cells
Tissue-specific stem cells (Adult stem cells)
Hematopoietic stem cells (HSCs)
Mesenchymal stem cells (MSCs)
Intestinal stem cells
Endothelial stem cells
Neural stem cells
 Cord blood stem cells

Cord blood stem cells are harvested from the umbilical cord
after childbirth. These cells can be frozen in cell banks for use
in the future
Cord blood stem cell
transplants are less prone to
rejection than either bone
marrow or peripheral blood
stem cells. This is probably
because the cells have not
yet developed the features
that can be recognized and
attacked by the recipient's These cells have been successfully used
immune system to treat and cure chronic blood-related
disorders such as Sickle cell disease,
Thalassemia, and Leukaemia
 Placenta stem cells

Placenta is a good source of multipotent
stem cells

Placental stem cells, like umbilical cord
blood, can be used to cure chronic blood-
related disorders such as sickle cell
disease, Thalassemia, and Leukaemia.

The placenta is comprised of many stem cells that are also
found within cord tissue. However, cord blood stem cells are
a pure source of fetal stem cells, whereas the placenta is a
mix of stem cells, some of which are maternal. Therefore,
stem cells from the placenta can be contaminated with trace
amounts of maternal cells, not easily isolated from fetal cells.
 Adult stem cells
(Tissue specific stem cells)
Adult stem cells have a misleading name, because they are also
found in infants and children. These stem cells come from
developed organs and tissues in the body.

In contrast to the ESCs, which are pluripotent, adult stem cells
have a more restricted differentiation capacity and are usually
lineage specific.

Adult stem cells act as a repair system for the body, replacing
damaged tissue in the same area in which they are found, such
as blood, skin or intestinal tissues.
Embryonic vs Adult Stem Cells

Embryonic stem cells Adult stem cells

Pluripotent stem cells, Multipotent stem cells
Differentiate into any cell types Differentiate into some cell types
Known Source Unknown source

Large numbers can be harvested Limited numbers, more difficult
from embryos to isolate
May cause immune rejection Less likely to cause immune
rejection, since the patient’s own
cells can be used
Ethical issues - when does life No ethical issues
begin?
 Adult stem cells
(Tissue specific stem cells)
Hematopoietic stem cells (HSCs)
Mesenchymal stem cells (MSCs)
Intestinal stem cells
Endothelial stem cells
Neural stem cells
 Haematopoietic stem cells

Haematopoietic stem cells (HSCs) are multipotent stem cells
and have both the self-renewal potential (HSCs replication and
maintenance) to sustain HSCs pool size and the differentiation
potential (formation of functional blood cells) to sustain mature
blood cells homeostasis

HSCs are anatomically localised in
a specialised microenvironment
that provides soluble factors that
are essential for HSC regulation.
This unique microenvironment is
called the HSC niches
 Haematopoietic stem cells

The term haematopoiesis
describes the formation of
all types of blood cells
from a small pool of
HSCs
 Mesenchymal stem cells (MSCs)

MSCs are multipotent stem cells and make the different
specialized cells found in the skeletal tissues.
 Applications of stem cells

Numerous diseases and damaged organs could potentially be
treated with cell therapy.
Stem cells can be used to generate healthy and functioning
specialized cells, which can then replace diseased or
dysfunctional cells. It is similar to the process of organ
transplantation only the treatment consists of transplanting cells
instead of organs
▪ Stem cell transplantation (SCT) is
an example of cell therapy in which
the stem cells in a donor's marrow
are used to replace the blood cells of
the victims of malignant diseases in
order to restore the normal blood
cell production, such as leukaemia,
lymphoma or myeloma
 Applications of stem cells

Cell therapy is also being used in experiments to graft new skin
cells to treat serious burn victims, grow new corneas for the
sight-impaired, and stems cells might be trained to become
pancreatic islets cells needed to secrete insulin to treat patients
with type I diabetes.
Stem cells could allow scientists to test new drugs using
human cell line which could speed up new drug development.
It would allow quicker and safer development of new drugs.

❖ In all of these uses, the goal is for the healthy cells to
become integrated into the body and begin to function like
the patient's own cells.
 Challenges of stem cell research

Is stem cell research ethical?
Embryonic stem cells - Morally objectionable
Harvesting ESCs destroy the blastocyst. This is murder
when does life begin?
o If the embryo is inanimate matter, then the resistance to embryonic stem cell
research is unreasonable.
o If the embryo is alive matter, then embryonic stem cell research is immoral.

✓ ESCs are unstable and mutate in culture. They accumulate significant
numbers of mutations over time and may become tumours
Umbilical cord stem cells - Morally acceptable
The umbilical cord is no longer required once the delivery has been completed.

Adult stem cells - morally acceptable