Hematopoiesis Lecture 2 PDF

Summary

This document provides an overview of Hematopoiesis, focusing on stem cell theories, progenitor cells, and colony-forming units (CFUs). It covers the process of blood cell formation and differentiation, highlighting the roles of various factors.

Full Transcript

MT 61 | BSMLS-3A-3D | A.Y. 2024-2025

HEMATOPOIESIS

STEM CELL THEORIES
❖ Monophyletic Theory
🖝 All blood cells are derived from single Pluripotent Hematopoietic stem cell
🖝 Most widely accepted
❖ Polyphyletic Theory
🖝 Each of the blood cell lineages is derived from its own unique stem cell
Noncommitted or Undifferentiated Hematopoietic Stem Cells
❖ capable of self-renewal
❖ have a high degree of proliferative capability
❖ pluripotent
❖ morphologically unrecognizable cells
❖ give rise to differentiated progenitor cells
Committed or Differentiated Progenitor Cells
❖ descendants of stem cells that can differentiate further into a specific cell lineage
❖ morphologically unrecognizable cells
❖ Two types of Multilineage-specific Progenitor Cells
1. Commo Myeloid Progenitor
2. Common Lymphoid Progenitor
❖ Multilineage progenitors → Unilineage progenitors → give rise to precursor cells
Culture-Derived Colony-Forming Units (CFUs)
Abbreviation Cell Line
CFU-GEMM Granulocyte, erythrocyte, megakaryocyte, monocyte
CFU-E Erythrocyte
CFU-Meg Megakaryocyte
CFU-M Monocyte
CFU-GM Granulocyte, monocyte
CFU-Baso Myeloid to basophil
CFU-Eo Myeloid to eosinophil
CFU-G Myeloid to neutrophil
CFU-pre-T T lymphocyte
CFU-pre-B B lymphocyte

PREPARED BY: KAREN B. ROSETE, RMT 1
 MT 61 | BSMLS-3A-3D | A.Y. 2024-2025

Precursor Cells
❖ committed to forming a particular type of blood cell
❖ morphologically recognizable cells
❖ lineage-specific
MODEL OF HEMATOPOIESIS
❖ Pluripotent HSCs → Common Myeloid Progenitor → Granulocytic, Monocytic, Erythrocytic, Megakaryocytic
Lineage
❖ Pluripotent HSCs → Common Lymphoid Progenitor → T, B, NK-Lymphocytes, Dendritic Lineages
❖ Stem Cell Markers
CD 34: Lymphoid & Myeloid Precursors
CD 33 & CD38: Committed Myeloid Progenitor
CD 10 & CD 38: Committed Lymphoid Progenitors
CD 7: T-lymphoid Progenitor cells
CD 19: B-lymphoid Progenitor Cells

THREE POSSIBLE FATES OF HEMATOPOIETIC STEM CELL
❖ Self-renewal
❖ Differentiation Symmetric Division
❖ Apoptosis 🖝 HSCs divide → 2 identical daughter cells → both daughter cells leave the stem
cell pool → undergo differentiation
Asymmetric Division
🖝 HSCs divide → 2 identical daughter cells → 1 daughter cell remains in the stem
cell pool | 1 daughter cell leaves the stem cell pool → undergo differentiation
Apoptosis
 HSCs divide → 2 identical daughter cells → undergo apoptosis

THEORIES ON THE FATE OF THE STEM CELL
❖ Stochastic Model (Till and McCulloch)
🖝 HSC randomly commits to self-renewal or differentiation
❖ Instructive Model
🖝 Microenvironment in the BM determines whether the HSC will self-renew or differentiate
Note: Currently, a combination of both theories is accepted.

Initial decision: HSC randomly commits to self-renewal or differentiation (Stochastic) → decision to proceed
with lineage differentiation in the presence of various signals from the hematopoietic inductive
microenvironment of the BM (Instructive) → cell differentiation and maturation occur

PREPARED BY: KAREN B. ROSETE, RMT 2
 MT 61 | BSMLS-3A-3D | A.Y. 2024-2025

MORPHOLOGIC CHANGES THAT OCCUR AS CELL DIFFERENTIATES AND MATURES
❖ Overall decrease in cell volume and decrease in the ratio of nucleus and cytoplasm (N:C ratio)
❖ Changes in the nucleus
Loss of nucleoli
↓ diameter of nucleus
Condensation of nuclear chromatin
Shape of nucleus
Loss of nucleus
❖ Changes in the cytoplasm
↓ in basophilia
↑ proportion of cytoplasm
Possible appearance of granules in the cytoplasm
SIGNALS FROM THE HEMATOPOIETIC INDUCTIVE MICROENVIRONMENT
❖ Intrinsic Factors
🖝 Intrinsic regulation involves genes
TAL1 – expressed in the cells in the hemangioblast (bipotential progenitor cell of
mesodermal origin)
GATA2 – expressed in late-appearing HSCs
🖝 TAL1 and GATA2 are essential for primitive and definitive hematopoiesis
❖ Extrinsic Factors
🖝 Extrinsic regulation involves growth factors/cytokines
❖ Regulatory Signaling Factors
🖝 Allow HSCs to respond to hematopoietic inductive microenvironment
Notch-1
Notch-2
HEMATOPOIETIC GROWTH FACTORS OR CYTOKINES
❖ group of specific glycoproteins that regulate the proliferation, differentiation and maturation of
hematopoietic precursor cells
❖ Cytokines include: interleukins (ILs), lymphokines, monokines, interferons, chemokines, and
colony-stimulating factors (CSFs)
❖ have stimulatory or inhibitory effects
🖝 Cytokines that exert positive influence (stimulatory)
KIT ligand
FLT3 ligand
GM-CSF
IL-1
IL-3
IL-6
IL-11
🖝 Cytokines that exert negative influence (inhibitory)
Growth factor-β
Tumor necrosis factor-
Interferons

PREPARED BY: KAREN B. ROSETE, RMT 3
 MT 61 | BSMLS-3A-3D | A.Y. 2024-2025

❖ Roles of Cytokines
1. Inhibit apoptosis
2. Stimulate cells to divide by ↓ the transit time from G0 to G1 of the cell cycle
3. Regulate cell differentiation into the various cell lineages

Apoptosis
 Programmed cell death
 Natural physiologic process
 Eliminates unwanted, abnormal or harmful cells
 When cells do not receive the appropriate cytokines necessary
to prevent cell death, apoptosis is initiated

COLONY-STIMULATING FACTORS
Examples:
GM-CSF (Granulocyte-Macrophage Colony stimulates formation of CFU-GM (colony-forming unit for
Stimulating Factor) granulocyte & monocyte/macrophage also known as
Granulocyte-Monocyte Progenitor)
M-CSF (Macrophage-Stimulating Factor) stimulates formation of CFU-M (colony-forming unit-
monocyte)
G-CSF (Granulocyte-Stimulating Factor) stimulates formation of CFU-G (colony-forming unit-
granulocyte)
EARLY-ACTING MULTILINEAGE GROWTH FACTORS
❖ KIT Ligand (Stem Cell Factor)
🖝 Receptor: KIT
Receptor-type tyrosine-protein kinase expressed on HSCs
Downregulated with differentiation
❖ FLT3 Ligand
🖝 Receptor: FLT3

INTERLEUKINS
❖ Protein molecules that regulate hematopoiesis
❖ They have synergistic interactions with other cytokines to stimulate proliferation and differentiation
of specific cell lines
❖ Effective at very low concentrations

Note: Please refer to Turgeon, M.L. (2012). Clinical Hematology: Theory and Procedures. (5th
Ed.). Philadelphia: Lippincott Williams & Wilkins, pp. 80-82 for the Summary of Interleukins

PREPARED BY: KAREN B. ROSETE, RMT 4
 MT 61 | BSMLS-3A-3D | A.Y. 2024-2025

SELECTED HEMATOPOIETIC GROWTH FACTORS OR CYTOKINES
Cytokine/Growth Primary Cell Source Primary Target Cell Biological Activity
Factor
❖ Kidney (peritubular ❖ Bone marrow ❖ Simulates proliferation of
EPO
interstitial cell) erythroid erythroid progenitors and
progenitors (BFU-E prevents apoptosis of CFU-E
and CFU-E)
❖ Endothelial cells ❖ Neutrophil ❖ Stimulates granulocyte
G-CSF
❖ Placenta precursors colonies
❖ Monocytes ❖ Fibroblasts ❖ Differentiation of progenitors
❖ Macrophages ❖ Leukemic toward neutrophil lineage
myeloblasts ❖ Stimulation of neutrophil
maturation
GM-CSF ❖ T cells ❖ Bone marrow ❖ Promotes antigen presentation
❖ Macrophages progenitor cells ❖ T cell homeostasis
❖ Endothelial cells ❖ Dendritic cells ❖ Hematopoietic cell growth
❖ Fibroblasts ❖ Macrophages factor
❖ Mast cells ❖ NKT cells
IL-2 ❖ CD4+ T cells ❖ T cells ❖ Cell growth/activation of CD4+
❖ NK cells ❖ NK cells and CD8+ T cells
❖ B cells ❖ B cells ❖ Suppress Treg responses
❖ Monocytes ❖ Mediator of immune tolerance
❖ Activated T cells ❖ Hematopoietic stem ❖ Proliferation of hematopoietic
IL-3
❖ NK cells cells and progenitors
progenitors
❖ T cells ❖ T cells ❖ Co-stimulation with other
IL-6
❖ Macrophages ❖ B cells cytokines
❖ Fibroblasts ❖ Liver ❖ Cell growth/activation of T
cells and B cells
❖ Megakaryocyte maturation
❖ Neural differentiation
❖ Acute phase reactant
❖ CD4+, Th2 T cells ❖ T cells ❖ Inhibits cytokine production
IL-10
❖ CD8+ T cells ❖ Macrophages ❖ Inhibits macrophages
❖ Monocytes
❖ Macrophages
IL-12 ❖ Macrophages ❖ T cells ❖ T cell, Th1 differentiation
❖ CD4+ T cells ❖ CD4+/CD8+ T cell
IL-15 ❖ Activated CD4+ T
❖ CD8+ T cells proliferation
cells
❖ NK cells ❖ CD8+/NK cell cytotoxicity
❖ Dendritic cells ❖ Macrophages ❖ Antiviral
IFN-
❖ NK cells ❖ NK cells ❖ Enhances MHC expression
❖ T cells
❖ B cells
❖ Macrophages
❖ Fibroblasts
❖ Endothelial cells

PREPARED BY: KAREN B. ROSETE, RMT 5
 MT 61 | BSMLS-3A-3D | A.Y. 2024-2025

❖ Osteoblasts
BFU-E, Burst-forming unit–erythroid; CFU-E, colony-forming unit–erythroid; EPO, erythropoietin; G-CSF, granulocyte colony-
stimulating factor; GM-CSF, granulocyte-macrophage colony-stimulating factor; IFN, interferon; IL, interleukin; NK, natural
killer; NKT, natural killer T cells; Th1, T helper, type 1; Th2, T helper, type 2; T reg, regulatory T cells

LINEAGE-SPECIFIC HEMATOPOIESIS

ERYTHROPOIESIS
❖ Production of erythrocytes

Pluripotent HSC → Common Myeloid Progenitor/CFU-GEMM → BFU-E → CFU-E → Erythroid Precursor Cells →
Mature erythrocytes

Note:
Burst-Forming Unit – Erythroid (BFU-E): contains few receptors for EPO
Colony-Forming Unit – Erythroid (CFU-E): contains many receptors for EPO

❖ Erythropoietin (EPO)
🖝 Lineage-specific glycoprotein hormone produced specifically by the peritubular interstitial cells of
the kidney
🖝 A small amount of it is produced in the liver
🖝 Stimulus for production and secretion of EPO: oxygen availability in the kidneys
 ↓ oxygen → ↑ EPO production
🖝 Stimulates RBC production by:
1. Recruitment of CFU-E from BFU-E
2. Preventing apoptosis of erythroid progenitors
3. Inducing hemoglobin synthesis
LEUKOPOIESIS
❖ Production of leukocytes
Two Major Categories
❖ Myelopoiesis → production of monocytes and granulocytes (neutrophils, basophil, eosinophil)

CFU-Eo → Precursor Cells → Eosinophil
Pluripotent HSC → CMP/CFU-GEMM CFU-Baso → Immature Basophil → Mature Basophil
CFU-GM/GMP CFU-G → Precursor Cells → Neutrophil
CFU-M → Precursor Cells → Monocyte

PREPARED BY: KAREN B. ROSETE, RMT 6
 MT 61 | BSMLS-3A-3D | A.Y. 2024-2025

Note:
CFU-Eo: Colony-Forming-Unit – Eosinophil/Eosinophil Progenitor
CFU-Baso: Colony-Forming-Unit – Basophil/Basophil Progenitor
CFU-GM: Colony-Forming-Unit – Granulocyte & Monocyte/Macrophage; it is also known as Granulocyte-
Monocyte/Macrophage Progenitor (GMP)

❖ Lymphopoiesis → production of lymphocytes

Natural Killer (NK) cells

Pluripotent HSC → Common Lymphoid Progenitor CFU-pre-B → Precursor Cells → Mature B cells

CFU-pre-T → Precursor Cells → Mature T cells

MEGAKARYOPOIESIS
❖ Production of platelets

Pluripotent HSC → CMP/CFU-GEMM → Megakaryocyte progenitors (Burst-Forming Unit-Meg/BFU-Meg → CFU-
Meg → Light Density-CFU-Meg/LD-CFU-Meg) → Precursor cells → Platelets

MAIN REFERENCES:
❖ Keohane, E.M., Otto, C.N., Walenga, J.M. (2020). Rodak’s Hematology: Clinical Principles and Applications.
(6th Ed.). Singapore: Elsevier
❖ Keohane, E.M., Smith, L.J., Walenga, J.M. (2016). Rodak’s Hematology: Clinical Principles and Applications.
(5th Ed.). Missouri: Elsevier Saunders
❖ Steininger, C.A., Martin, E. S., Koepke, J.A. (1992). Clinical Hematology: Principles, Procedures,
Correlations. Philadelphia: J.B. Lippincott Company
❖ Turgeon, M.L. (2012). Clinical Hematology: Theory and Procedures. (5th Ed.). Philadelphia: Lippincott
Williams & Wilkins

PREPARED BY: KAREN B. ROSETE, RMT 7