Hematopoiesis Lecture Notes PDF

Summary

These lecture notes provide an overview of hematopoiesis, the process of blood cell formation. They discuss stem cells, different types of stem cells, and the stages of blood cell development both prenatally and postnatally. The notes mention key factors and regulatory mechanisms.

Full Transcript

HEMATOPOIESIS
The Formation and
Development of Blood Cells
 Hematopoiesis
 A continuous, regulated process of
blood cell production that includes cell
renewal, proliferation, differentiation,
and maturation in the blood-forming
organs.
Hematopoietic Stem Cells (HSCs)
 They are the foundation of the adult hematopoietic
system. The embryo produces the first adult
repopulating HSCs.
 They are also referred to as hemocytoblasts.
TYPES OF HUMAN STEM CELLS (SC)

 1. Totipotent SC- present the first few hours after
fertilization. The most versatile type of SC because
can develop into any human cell type, including
dev't from embryo into fetus/.
 2. Pluripotential SC- present several days after
fertilization. Can develop into any cell type, except
they cannot develop into fetus.
 3.Multipotent SC- derived from pluripotential SC,
found in adults,but they are limited to specific types
of cells to form tissues. e.g.bone marrow SC
 Human SC
 can produce all types of blood cells, bone,
cartilage, adipose/fat cells so are said to be
MULTIPOTENTIAL
 can differentiate along any cell line( erythrocytic,
granulocytic, monocytic, megakaryocytic,
lymphocytic)
 the main factor that will influence what they will
differentiate into is the NEED OF THE BODY.
Early Dev't of Blood Cells
 Blood cells originate from the mesenchymal tissue
that arises from the embryonic germ layer, the
mesoderm. The mesodermally derived STRUCTURES
ARE:
 1. paraaortic splannchnopleure
 2. aorta-gonad-mesonephros region
 In here production of multipotent progenitor cells
and hematopoietic stem cells (HSCs) happens
before their appearance in the yolk sac.
3 DIVISIONS OF HEMATOPOIETIC
CELLS IN THE BONE MARROW
 1. Primitive multipotential cells- stem cells, the
most immature group capable of self-renewal and
differentiation into all blood cell lines.
 2. Intermediate cell or Progenitor cells- committed
cell and are denoted by the prefix CFU /BFU. They
are unipotential and are already committed to
develop into a specific cell line.
 3.Mature cells or Precursor cells- the developed
group and are already with specific function/s.
 STAGES OF
HEMATOPOIESIS
 Pre-natal Hematopoiesis
 Post-natal Hematopoiesis
 PRE-NATAL HEMATOPOIESIS
I. MESOBLASTIC PERIOD
 Starts on 14th day, peaks on the 1st month and persist
up to 3rd month of gestation, start of ERYTHROPOIESIS.
 Chief site – blood islands of yolk sac
 3rd month fetal life = Primitive Erythroblast
 Primitive Erythroblast
 Formed intravascularly( or within developing
blood cells), megaloblastic( bigger in size) , and
retain their nuclei
 Contains Embryonic Hemoglobin- Gower1, Gower
2, Portland
 PRE-NATAL HEMATOPOIESIS
II. HEPATIC PERIOD
 Starts on the 5th to 7th week of gestation and persist
up to birth( wanes- lowers in production)
 Chief site – Liver, as well as spleen and lymph nodes,
thymus (lesser extent)
 Definitive Erythroblasts
Formed extravascularly and extrude their
nucleus, CONTAINS HbF
Continuation of erythropoiesis, 3rd month- starts
granulopoiesis & megakaryopoiesis
 4th month- lymphopoiesis, 5th month-
monocytopoiesis/ monopoiesis
 PRE-NATAL HEMATOPOIESIS
III. MEDULLARY or MYELOID PERIOD
 Starts on the 5th month of fetal life up to adulthood
 Bone Marrow is the chief site of hematopoiesis by the
end of 24 weeks( 6 months). Measureble levels of
Erythropoietin (EPO), Granulocyte- Colony Stimulating
Factor, (G- CSF)Granulocyte-Monocyte/ Macrophage –
colony stimulating factor( GM- CSF). HbA and HbF are
detected.

 Cells at various stages of maturation can be seen in all
blood cell lineages/ lines.
POST-NATAL HEMATOPOIESIS
I. MEDULLARY/ MYELOID
Bone Marrow – is the only site of erythropoiesis,
myelopoiesis and thrombopoiesis IN POST-NATAL LIFE.
A. Red Bone Marrow – Hematopoietically active
marrow- PRODUCE BLOOD CELLS
B. Yellow Bone Marrow – composed primarily of
adipocytes (fats)

Bone Marrow at Birth 1.5 % of total body weight
Bone Marrow (Adult) 4.5% of total body weight
Red Bone Marrow

Site of Blood Cell
Yellow Bone Marrow Formation

Red Bone Marrow
POST-NATAL HEMATOPOIESIS
II. EXTRAMEDULLARY
 Blood cell production in hematopoietic tissue
other than bone marrow. This is resorted to when
the converted yellow marrow to red marrow is
insufficient to meet the body’s demands
A. Lymph nodes-T & B cells dendritic cells(DC)(
antigen-presenting cells), macrophages, plasma
cells
B. Spleen –T and B cells, plasma cells, macrophages
C. Liver-can be hematopoietic when needed
 2 characteristics of stem cells
1. Uncommitted
2. Mutipotential and can differentiate along any cell
line( depending on the body’s need)
Theories of Blood Cell Production
A. Monophyletic
All blood cells are derived from uncommitted
stem cells which are capable of giving rise to
several types of cells- the accepted theory
B. Polyphyletic
The first recognizable and most primitive blood
cells are already committed to develop into a
specific cell line- not accepted theory
 3 compartments of cells in
Bone Marrow( BM)
1. Hematopoietic Stem Cells (HSCs)
 most immature, can do self-renewal & differ-
entiation into any of the cell lineages
 Divide by mitosis to give rise to multipotent
progenitors
 Have the morphology of medium- sized
lymphocytes
 CD34+ but lacks MHC Class II antigen

 Can give rise to CFU-L and CFU-
GEMM(myeloid)
3 compartments of cells in the
BM
2. Progenitors
 Starts to commit, as they mature, acquire more
cluster of differentiation (CD), remain CD34+ for
identification. CD34 is marker for immaturity
 Cells with prefix- BFU or CFU

 They are unipotential- committed to differentiate
along a single cell line
 Cells in the BM
3. Precursor cells
 Recognized due to additional expression of

antigens (CD38)
CD71+ – erythroid CD10+ – B cells
CD33+ – myeloid CD7+ – T cells
CD5+ - T cells
Cells in the BM
 The formation & dev't of mature blood cells from
the multipotent Stem Cells is controlled by growth
factors & inhibitors, and the microenvironment.
The microenvironment or locale influences
behavior & controls the proliferation of
multipotential stem cells.
 The bone provides the microenvironment most
appropriate for proliferation & maturation of
cells.
 The BM is encased by endosteum
Progenitor Cells
 The hematopoietic progenitor cells (HPCs) can be
mobilized from the BM to the blood by a wide
variety of stimuli, including the hematopoietic
growth factors & chemokines.
 Individual hematopoietic cytokines can be
lineage- specific or can regulate cells in multiple
lineages, and for some cell types, e.g. stem cells,
the simultaneous action of multiple cytokines is
required for proliferative responses.
HSC
 The HSCs in the BM exist in a highly organized
microenvironment composed of stromal cells & an
extracellular matrix rich in fibronectin, collagen, &
various proteoglycans.
 HSCs can be found in umbilical cord blood (UCB) also.
UCB hematopoietic cells is used as therapeutic source of
autologous & allogeneic transplants for more than 20
yrs. Cryopreservation prolongs the storage time of
UCB.
 Aside from UCB, BM and peripheral blood are sources
of stem cells for therapeutic purposes.
Hematopoietic Processes
 1. Erythropoiesis- process of red blood cell (RBC)
formation. Occurs in erythroblastic islands, which
are specialized niches in which erythroid precursors
proliferate, differentiate, & enucleate( extrude their
nucleus). Each island consists of a
macrophage(mother cell surrounded by a cluster of
developing normoblasts. Within erythroid niches,
cell-cell & cell-extracellular matrix adhesion,
positive & negative regulatory feedback. Erythroid
cells account for 5%- 38% of nucleated cells in BM.
Maturation of Blood Cells

 A. Principles of Synchronistic Maturation- when
nucleus & cytoplasm mature at the same time
resulting in normal/ typical cells. While the
following cytoplasmic occur, the nuclear changes
also occur:
 1. Cytoplasmic Changes
 a. Loss of basophilia- Generally, the younger
the cell, the higher is the RNA content of its
cytplasm. The RNA is the cytoplasmic component
which give it basophilia( love for basic dyes)
Synchronistic Maturation
 b. Production of cytoplasmic granules- this is a
special feature of the granulocytes (neutrophil,
eosinophil, basophil). In the promyelocyte, the
non-specific/ primary granules develop. In the
next stage, the early myelocytic stage, secondary
granules appear. On the late myelocytic
stage,tertiary granules appear. Both secondary &
tertiary granules are specific granules At the
myelocytic stage then, the 3 types of granulocytes
are distinguishible from each other because of the
color of their cytoplasmic granules.
Synchronistic Maturation
 c. Elaboration of Hemoglobin (Hb)- a special
feature of the erythrocytic cells. Hb formation starts
in the pronormoblasts(1st stage of devt) and seen
first in the polychromatophilic normoblast stage,
continues in the orthochromic stage, up until the
reticulocytic stage. At the reticulocytic stage, only
35% of Hb are formed and is thne one used by the
erythrocyte for its function of oxygen delivery to the
tissues for its entire life span in the blood of 120
days.
 Synchronistic Maturation
2. Nuclear Changes
 a. Lobulation of nucleus- a special feature of the

granulocytic cells. The granulocytes, increase in in
nuclear lobes on matutaion. At maturation, the
neutrophil has 2-5 nuclear lobes with an average of
3. The eosinophil, has 2-3 lobes, and mostly are bi-
lobed. The basophil does not increase its lobe on
maturation, but retains its stab-shaped nucleus.
 Synchronistic Maturation
b. Changes in the structure and cytochemistry of
chromatin material - At an early stage, the nuclear
chromatin are fine and linear because of the DNA’s
double-helical structure. This is referred to as
euchromatin. In maturing stages, the chromatin
becomes coarse & clumped and are called the
heterochromatin. In stages where, heterochromatin is
observed, there are non-staining areas seen and
are called the parachromatin.
Synchronistic Maturation
 c. Extrusion of nucleus- a special feature of the
erythrocytic cells. In immature stages, from
pronormoblast- orthochromic normoblast, these cells
are nucleated. Enucleation/ Nucleolysis, the process
of removal of the nucleus happens just before the
orthochromic normoblast becomes a reticulocyte, the
5th stage. After 2-3 days as retics in the BM, the
cell migrates to the blood a & remains in the blood
for 1 day until it becomes an erythrocyte.
 Synchronistic Maturation
 3. Reduction in size of cells- As cells mature, they
undergo mitosis, and the daughter cells become smaller,
except the megakaryocytic cells. The megakaryocytic
cells become bigger as they mature. This cell line
undergo endomitosis/ endoreduplication where
these do not occur:
late telophase & cytokinesis, hence, one
megakaryoblast matures into ultimately one mature
megakaryocyte or metamegakaryocyte which is the
mother cell of platelets. This cell line results in
polyploid cells.
 Asynchronistic Maturation
Pathologic hematopoiesis results in abnormal nuclear
maturation, abnormal cytoplasmic differentiation &
abnormal size. Their development is asynchronistic.
1. Abnormal cytoplasmic differentiation- In RBC, this
is characterized by persistent cytoplasmic basophilia
& late hemoglobinization. Abnormal cytoplasmic
inclusion bodies may be found in the cytoplasm of
borh erythrocytes and leukocytes, especially in the
granulocyes.
Asynchronistic Maturation
 2. Abnormal nuclear maturation- in leukemia &
other severe disturbances, 2 nuclei may be present;
one may be diploid & the other polyploid. The
nucleus may be hypersegemnted or
hyposegemented. In megaloblastic anemia, the
megalocytes' nucleus takes longer to mature than its
cytoplasm. This is so because the mitotic &
intermitotic phases in megalocytes are prolonged
when compared to the normal red cells.
Asynchronistic maturation
 3. Abnormal size - abnormally large cells are
frequently seen in benign or malignant
proliferation. In the erythrocytic series, the
megaloblasts are larger than normal mature
erythrocytes. Likewise, abnormally small cells may
be found.
Erythropoiesis
 Maintenance of the circulating red cell mass within the
BM limits seen in health is achieved by a feedback
mechanism, which senses body oxygen demands &
adjusts the rate of erythropoiesis accordingly. This
feedback mechanism is mediated by the glycoprotein
hormone erythropoietin (EPO) - 38kD. The Sequence :
 1. Decrease in circulating RBC mass leads to
decreased delivery of oxygen to the tissues &
hypoxia develops. Hypoxia is the stimulus for
erythropoiesis.
Erythropoiesis
 2.Tissue hypoxia is sensed by an enzyme-linked
mechanism in the kidney and synthesis of EPO by
the peritubular interstitial cells of the kidney is
stimulated.
 3.EPO binds to specific receptors on CFU-E(higher
binding activity), BFU-E(very low level of binding or
almost none), in the BM resulting in a shortening of
cell-cycle time, an increased rate of maturation & an
increased rate of release of red cells from the BM.
 The target cells of EPO: CFU-E and pronormoblasts
Erythropoiesis
 4. The increased RBC count improves oxygen
delivery to the tissues, the hypoxia is corrected &
EPO synthesis is switched off/ decreased.
 Erythropoiesis is influenced ny interleukin 3 which
come from T cells.
 DAILY: 1 % OF ALL RBC IS DESTROYED, AND
REPLACED BY 1% NEW RBCS. THIS IS TO
MAINTAIN THE OXYGEN LEVEL NEEDED BY THE
BODY
Erythropoiesis
 Of the 1% destroyed( equivalent to 20 mL of
blood,
 90 % undergo extravascular lysis- macrophage
mediated -senescent rbc are disposed by the
splenic macrophages.
 10% undergo intravascular lysis- happens in the
blood circulation.
 Increased intravascular lysis results in hemolytic
conditions.
Erythrocytic Cell Stages
 1. Pronormoblast/ Rubriblast/ Proerythroblast-
earliest regognizable stage of the series., 14-20 um
indiameter., 1-2 nucleoli,cytoplasm show a lighter -
staining area around the nucleus(perinuclear halo),
round nucleus, n:C ratio is 8:1. Undergoes 1 mitosis to
produce 2 basophilic normoblast.
 - 12-17 um,, intensely basophilc(more tham2.
Basophilic normoblast/Prorubricyte/ Basophilic
erythroblast-n pronormoblast), N:C ratio is 6:1. Nuclear
chromatin is slightly coarser. Able to have 2 mitoses
giving rise to 8 polychromatophilic normoblast.
 3. Polychromatophilic normoblast/ Rubricye/
Polychromatophilic erythroblast- 10-15 um in
diameter., blue-gray to pink gray cytoplasm due to the
start of Hb production(acidophilic) and the presence of
RNA (basophilic) 4:1 is its N:C ratio. Smaller nucleus
that that of the previous stage. last mitosis to produce
16 orthochromic normoblast.
 4. Orthochromic normoblast/ Metarubricyte?
Orthochromic erythroblast- 7-12 um.. pinker than the
previous stage, bec of increased Hb product, no more
mitosis because nucleus is pyknotic.
 5. Reticulocyte- 7-10 um.. Slightly bigger than mature
RBC and possess 2 or more reticular dots(RNA)
which only stains by supravital stains(staining
blood/ cells immediately upon removal from the
body. New methylene blue or brilliant cresyl blue)
should be used. No more nucleus as it was extruded
already before this stage is reached.
 6. Erythrocyte/ Mature RBC- 6-8 um in diameter,(
round) pink to peach/buff color in a properly Wright-
stained smear, anucleated, round with 1/3 central
pallor, biconcave on lateral/side view.
 Stages in Granulocytic Series:
 1. Myeloblast-15-20 um in diameter, the earliest
recognizable stage in the lineage. Blue cytoplasm,
round or slightly oval nucleus, N:C ratio is 4:1, fine
chromatin(euchromatin). Nucleus is red-purple in color
and with 2-5 nucleoli. The earliest recognizable cell in
the series.
 2. Promyelocyte- 15-21 um in diameter. Cytoplasm is
pale pink to bluish due to primary granules. Oval or
round nucleus. N:C ratio is 3-1 to 2:1. Chromatin is
coarser compared to the 1st stage. A little bit bigger
than pyeloblast.
 3. Myelocyte- 12-18 um in diameter. Cytoplasm is
moderate in amount, few specific granules begin to
appear (early myelocyte-secondary granules, late
myelocyte-tertiary granules. Both are specific
granules)At this stage the 3 granulocytes may be
differentiated:
 a. Neutrophil myelocyte- pinkish specific granules
seen near the nucleus.
 b. Eosinophil myelocyte- specific granules are red to
orange. Granules are bigger than the non-specific
& specific granules of neutrophil.
 c. Basophil myelocyte- the specific granules are few,
large, & stain a dark blue-purple, nucleus is
oval/round. Chromatin is coarse/ more condensed,
Generally, no ncleoli. Nucleus may be centrally
located or may be eccentric. N:C ratio is 1:1.
 4. Metamyelocyte- 10-15 um. Nucleus is indented/
kidney-shaped.. Decreased N:C ratio. Full
complement of specific granules, with a dew non-
specific granules.
 a. Neutrophilic metamyelocyte- granules are more
pink & more numerous.
 b. Eosinophil metamyelocyte- more numerous and
brighter orange-red granules
 c. Basophil metamyelocye- dark purple to black
granules are more numerous.
 5. Stab/ Band/ Staff cell- 9-15 um in diameter.,
Cytoplasm is same as metamyelocyte. Nucleus is
elongated/band-shaped, more deeply-indented tham
metamyelocyte. Chromatin pattern is more coarse
&clumped.
 6. Segmented Neutrophil- 9-15 um in diamter. With pink
to rose-violet specific granules, with few non-specific
granules. Nucleus is not covered by its granules.
 Eosinophil- 9-15 um in diameter.
 contains the full complemet of large, reddish-orange
granules. Nucleus is usually bi-lobed wc is not overlayed
by its granules. Nuclear chromatin is coarse and clumped.
 Basophil- 10-16 um in diameter. Cytoplasm is slightly
pink to colorless. Contains specific dark purple to blue-
black granules which are fewer than in eosinophil.
Granules are water-soluble.
 Nucleus is not coarse as in eosinophil and neutrophil.
Unsegmented nucleus or rarely bilobed and is
covered by its granules.
Granulopoiesis
 Granulocytes account for 23%-85% of the
nucleated cells in the normal BM. Granulopoiesis
can be said as a maturational unit. Early cells are
located in the cords & the bone trabeculae.
Neutrophils in the BM reside in theproliferating pool
& maturation storage pool. Maturing cells spend an
average of 3-6 days in the proliferating pool. If
needed, cells from the storage pool can exit into the
circulation rapidly and will have an average life
span of 6-10 hours. Related to granulopoiesis is
monocytopoiesis/ monopoiesis. CFU-GM is
influenced by GM-CSF & IL3. IL5 influences
Granulopoiesis
 no more mitosis happen and spends the next 6-14
days in the maturation and storage pools, durin wc
it develops into stab cells and segemented
neutrophils or PMNs.
 The stab/band is the most clinically impt to doctors
as an increase (N. V. 2-6%) signifies infection. The
increase in band cells is usually acompanied by
leukocytosis or an increase WBC count (N.V. =
4500-11000/uL).
 Granulopoiesis

 Mature neutrophils are divided as: 50% in the
circulatory pool & 50 % in the marginal pool.
Neutrophils change back and forth the 2 pools in
their 10 hours(average) stay in the blood.
 A small % of band/ stab cells are continually
released to the blood. The average lifspan is 5
days, since they can go out to the tissues
(diapedesis) & perform their function in fighting
infectious agents, after which they leave via
excretions from GIT, GUT,lungs, saliva.
 Pus cell- PMN which had been destroyed after its
it had phagocytosed infectious organisms.
 Abscess- a collection of pus cells.
 Pus cells are eventually disposed of by the cells of
the RES/ MPS (monocytes and macrophages)
Granulopoiesis
 INFECTION is the main stimulus for the
generation of a larg number of granulocytes. The
response to infection entails three mechanisms:
 1. Granulocytes ( and monocytes) are recruited into
& around the infected tissue by a releazse of
chemotactic factors which comes from bacteria, their
products, like toxins, or any other infectious
organisms.
Granulopoiesis
 2. Granulocytes (and monocytres ) stored in the BM are
mobilized & released into the blood.
 3. The response initiates accelerated cellular production
to satisfy the increased demand for these cells.

 There are 3-5 mitosis that happen in the series over a
period of 6-7 days in the BM. The mitosis happens in
the myeloblast, promyelocyte and in the myelocyte, wc
compose the proliferative compartment. On mits 4th
stage, the metamyelocyte,
Eosinophils
 Matures in the same manner as neutrophil. Its
maturation is through the help of Eo-CSF from the T
cells. Primarily a tissue cell. For every 1 eos in the
blood there are 300-500 in the tissues.Lifespan is
several days, much longer than neutrophils.
 Diurnal in vriation, since its number in the blood
increases during nightime.
 Steroids inhibit their release from the BM & enhance
their movement to the tissues.
 They can move to and from the tissues/ blood.
 Metabolically more active than neutrophils.
 Secretory products:
 1. major basic protein- against helminths
 2.histaminase-neutralize effect of histamine,
(secretion of basophils, mast cells)so con-
 sidered an anti-inflammatory cell.
 3.arylsulfatase B
 4. phospholipase B
 5. Heparin
Basophils
Manner of maturation is same with neutrophil,
eosinophil.
Once released from BM to the blood, itremains in
circulation same time as neutrophil, before it moves to
the tissues where they are long-living.2. Mast cells
have roy
Mast cell(tissue basophils) and basophils differ in the
ff morphological aspects:
1.Mast cells are slightly larger than basophils
hils and Mast cells

 2. Mast cells have round, oval nucleus while
basophils possess stab-shaped nucleus.
 3.Mast cells possess granules which are slightly
smaller & less soluble than those of basophils.
 Common to both basophils & mast cells :
 1. secrete histamine, an impt part of
inflammation.
 2.both have membranes which readily bind IgE,
which is followed by degranulation, anaphylaxis.
Monocytopoiesis/ Monopoiesis
 The monocytes arise from the same bipotential
which give rise to the stem cell, the CFU-GM. From
this, arise the CFU-M which is the mother cell of all
monocytes. The proliferation of monocytes in the
BM takes about 55 hours. They mature in BM but
leave without no specific order.
 The marginal pool of the monocytes in peripheral
blood is about 3.5X the size of the circulating pool.
 The mature monocyte spends about 12 hours in
the peripheral blood before going iout to the
tissues.
Monocytic Series
 1. monoblast- earliest recognizable cell in the series. 12-23
um in diameter. Non-granular cytoplasm which is
moderately basophilic to blue-gray, non-granular. Nucleus is
ovoid/round wc is light blue purple in color. Chromatin is
fine, lacey.Nucleus has 1-2 nucleoli, N:C ratio is 4:1 to 3:1.
 2. promonocyte-immature monocyte- 14-18 um in
diameter. Cytoplasm is blue-gray and may contain
azurophilic granules which is dust-like. Ground glass
appearance cytoplasm which is moxderate in amount.
Nucleus is oval, may have a single fold or fissure, with 1-5
nucleoli, fine chromatin pattern. N:C ratio is 3:1 to 2:1.
 3. Monocyte- a14-20 um in diameter. Cytoplasm is
abundant, blue-gray in color. Cytoplasmic outline may
be irregular because of the presence of
pseudopods.The cytoplasm has many, fine azurophilic
granules giving a ground glass appearance. Vacuoles
may be present. The nucleus is round/ kidney-shaped or
may show slight lobulation. It may be folded over on
top of itself, thus showing brainlike convolutions. No
nucleoli are visible. Chromatin is fine & lacey(not
clumped), arranged in skein-like(loosely coiled &
knotted) strands.
Macrophages

 The macrophages are more active than monocytes
and have richer supply of acid hydrolases. They
stay for months or longer in the tissues and later die.
They do not re-enter the blood altkough an
occasional macrophage may enter the blood via the
lymphatic system. They are 20-40 um in diameter.
Macrophages
 Possess eccentric nucleus, egg-shaped, indented or
elongated. The chromatin appears spongy & i-2
nucleoli may be seen. Cytoplasm is abundant, sky-
blue & has coarse, azurophilic granules. Cytoplasm
is usually vacuolated, & may contain phagocytosed
materials. The cytoplasmic outline may be irregular
because of the presence of pseudopods.
Lymphopoiesis
 where antigen-independent lymphopoiesis occur.
Lymphocytes are developed in these organs and
NO ANTIGEN is needed for lympphopoiesis to
happen. In the spleen, lymph nodes, MALT( GALT &
BALT), antigen -dependent lymphopoiesis happen
because ANTIGEN IS REQUIRED for lymphocytes
to undergo lymphopoiesis(incrrease in number as in
lymphadenitis/lymphadenopathy)
 Stages in Lymphocytic Series:
 1. Lymphoblast- 10-18 um in diameter, Cytoplasm is
agranular, smooth, moderate to dark-blue, may stain
deep-blue at the periphery & lighter blue near the
nucleus. More abundant cytoplasm than in the myeloblast.
Chromatin pattern is somewhat coarse.Nucleus is round or
oval in shape, with 1-2 nucleoli. N:C ratio is 4:1.
 2. Prolymphocyte- may be same size as lymphoblast/
smaller. Cytoplasm is moderate to dark blue, non-
granular, more abundant than the lymphoblast.
 Nucleus is round/ oval or slightly indented.
Chromatin pattern is more clumped than in the
lymphoblast with 1-2 nucleoli.
 3. Mature lymphocyte:
 a. small lymphocyte-8-10 um, more or less same
size as mature RBC. Cytoplasm forms a thin rim
around the nucleus moderate to dark-blue color.
Nucleus is round/oval & may be slightly indented,
with dense & clumped chromatin. No nucleolus.
 b. Medkium sized lymphocyte -10-12 um in diameter,
Cytoplasm is more abundant than in the small
lymphocye, pale to moderately blue. Nucleus is
round/oval & may be slightly indented. Chromatin
pattern is clumped but not as dense as in the small
lymphocyte. No nucleolus visible.
 c. Large lymphocyte - 12-16 umin diameter.
Cytoplasm is abundant, clear, very pale blue.Nucleus is
round/oval and may be slightly indented. Chromatin
pattern is cloarse, without nucleolus. Nucleus may be
eccentrically located.
Morphological and Functional Classes
of Lymphocytes
 A. Morphologic:
 1. Small
 2. Medium
 3. Large
 B. Functional:
 1. T cell
 2. B cell
 3. Null cell/ non-T, non-B/ Large granular
lymphocytes (LGL)
Morphological Types
 1. Small lymphocytes- life span is 4-10 yrs.,
accounts for about 80% of the total lymphocytes in
blood,, size is 1.5x of the size of a normal red
blood cell., demostrate the so called “ hand-mirror”
apperance during locomotion.
 2. Medium sized lymphocytes- accounts for 5-10 %
of the total lymphocytes in blood.
 3. Large lymphoctes- short-lived, lasts for 3-4 days,
accounts for about 15 % of total adult lymphocytes
in blood, 2-3X the size of normal RBC.
 The major factor that affects the total number of
lymphocytes in the body is the AMOUNT OF
EXPOSURE TO ANTIGEN( something foreign like
bacteria, viruses)
 Lymphocytes are capable of blast transformation &
mitosis and so can serve as their own stem cell
compartment in terms of replacemet when
needed.
 Morphological transformation of
lymphocytes in disease process
 Lymphocytes which undergo transformation during a
disease process are called the atypical
lymphocytes. They are 2-3X bigger than the small
lymphocyte in size.
 Morphology of atypical or reactive lymphocytes:
 cytoplasm usually seem to flow on one side of RBC,
or follows the contour of RBC
 Changes in atypical lymphocytes
after stimulation by antigen
 1.increase in size and nucleus becomes less dense &
may show one or more nucleoli. Chromatin not
clumped compared with normal lymphocyte.
 2. cytoplasm becomes basophilic and increase in
size as compared to the nucleus.
 3.foamy ( holes) or vacuolated or moth-eaten
cytoplasm
 4.irregularly-shaped nucleus which may be
lobulated, clefted and stained reddish to blue
purple.
 Changes in atypical l. ff antigenic
stimulation
 5. increased number of azurophilic granules in the
cytoplasm.
The Downey Classification
 1. Downey Type 1- nucleus may be irregularly
shaped. Cytoplasm is basophilic & at ytimes foamy.
 2. Downey Type II - increased amount of cytoplasm.
The peripheral part of the cell becomes more
basophilic. Nuclear chromatin becomes more coarse
& clumped.
 3. Downey Type III- increase in size & shows
basophilic cytoplasm. The nucleus has nucleoli.These
cells resemble immature lymphocytes & is seen in
Burkitt lymphoma patients.S
Megakaryopoiesis
 Takes place adjacent to the sinus endothelium.
Megakaryocytes protrude through the vascular
wall as small cytoplasmic processes to deliver
platelets into the sinusoidal blood. Megakaryocytes
develop into platelets in approximately 5 days.
 Megakaryocytes account for about 1% of total
nucleated cells in the BM.
 Undergo ENDOMITOSIS, no telophase,
cytokinesis.
Megakaryopoiesis
 2 factors which help in their maturation/
development:
 1. Megakaryocyte Colony Stimulating Factor (Meg-
CSF)- induce the committed cells to proliferate &
differentiate into megakaryoblasts.
 2. Thrombopoietin (TPO)- induces the differentiation
& maturation of megakaryocytes & also influences
their size,number of platelets which will be formed
from their cytoplasm.
 Stages of devt
 1.Megakaryoblast- 20-50 um in diameter.
Cytoplasm is varying shades of blue, usually darker
than the myeloblast, may have small, blunt
pseudopods. Cytoplasm is moderate in amount, a
narrow band around the nucleus. On maturation,
cytoplsm increases, non granular.. Nucleus is round/
oval/ may be kidney-shape with fine chromatin
pattern. Nucleus has multiple nucleoli that generally
stain blue. N:C ratio is 10:1.
 2. Promegakaryocyte- - 20-60 um in diameter.
Cytoplasm is more abundant than the previous
stage, less basophilic than the blast stage. Granules
begin to form in the golgi apparatus region.
Nucleus has multiple nucleoli, irregular in shape,
may show slight lobulation, chromatin becomes more
coarse. N:C ratio is 4:1 to 7:1 depending on the
ploidy.
 3. Granular megakaryocyte- 30-90 um in diameter.
Cytoplasm kis abundant, pinkish-blue in color, very fine
and diffusely granular, with irregular peripheral border.
The nucleus is small in comparison the the big cell size.
Multiple lobulation of nucleus, coarser chomatin than in the
previous stage, no nucleolus. N:C ratio is 2:1 to 1:1.
 5. Mature megakaryocyte- 40-120 um in diameter.
Cytoplas has coarse clumps of granules aggregating into
little bundles which bud off from the periphery to
become platelets.. Nucleus is multiple or multilobulated.
No nucleolus. N:C ratio is 1:1.
 5. Platelet- thrombocyte - 2-4 um in diameter,
light blue to purple, very granular. The cental part
is called the granulomere, and the peripheral
part, the hyalomere.
 Characteristics of Blasts Cells
1. Size – generally large with high nuclei and
cytoplasmic ratio
2. Cytoplasm – basophilic, small in amount, no
granules
3. Nucleus – large and round to oval in shape
**Chromatin (Euchromatin) – very fine, very
smooth, reddish purple, no clumping of chromatin
materials
**Nucleoli – pale light blue, capable of mitosis
 Synchronistic Maturation
A. Cytoplasmic changes
1. Loss of Basophilia – decrease in RNA as cell
matures
2. Cytoplasmic Granules – special feature of
granulocytic series/lines(N,E,B)
3. Elaboration of hemoglobin – special feature of
erythrocytic series. seen in polychromatophic
pronormoblastic stage,end-retics
 Synchronistic Maturation
B. Nuclear Changes
1. Structure and Cytochemistry – most reliable criterion
2. Number of Nucleoli – decreases nucleoli and amount
of ribosome
3. Shape
Granulocytes – Indentation and Segmentation,
most number of lobes (mature)
Erythrocytes – Pyknotic, and is eventually
extruded at orthochromatic stage
 Synchronistic Maturation
C. Reduction in Cell Size
 Special feature of all cell lineage except

megakaryocytes

General Rule: As the cell matures, the size,
basophilia of cytoplasm and number of nucleoli
decreases while coarseness of chromatin
increases.
 Asynchronistic Maturation
1. Abnormal Cytoplasmic Maturation
 Persistent cytoplasmic basophilia – should
be decrease or lost
 Late hemoglobinization – erythrocytic series
 Inclusion bodies – (erythrocytes,
granulocytes) remnants of cell organelle,
microorganism, parasites, iron deposits
 Asynchronistic Maturation
2. Abnormal Nuclear Maturation
 Polyploidy (megakaryocytic cells) – 2 nuclei
in 1 cell, myeloid precursor
 Hyposegementation or Hypersegmentation
– excess lobes, infectious and toxic
substances
 Delayed Maturation – megalocyte (blast),
smaller, takes longer time to mature than its
cytoplasm
 Asynchronistic Maturation

3. Abnormal Size
 Large atypical lymphocytes
 Megalocytes or Macrocytes
 Micromegakaryocytes
 Regulation of Hematopoiesis
1. Qualitative & Quantitative Cellular Equilibrium
Balance between qualitative and quantitative
parameters
**Qualitative – normal morphology (size and shape)
**Quantitative – normal count
Regulation of Hematopoiesis
 Erythropoietin (EPO) - major regulator of
erythropoiesis, stimulates erythroid CFU cells
and proerythroblasts/pronormoblasts. encoded
on Chromosome 7.HEMA

 Thrombopoietin (TPO) - increases platelet
production, stimulates megakaryocyte CFU cells

 Granulocyte CSF (G-CSF) - increases production
of neutrophils, stimulates granulocyte-
macrophage CFU cells
Regulation of Hematopoiesis
 Granulocyte-macrophage CSF (GM-CSF) - increases
macrophage production, stimulates granulocyte-
macrophage CFU cells
 IL3-stimulates hematopoietic SC,promotes growth by
early lineages.
 The above are the hematopoietic growth factors.
 Interleukins (IL) - stimulate B- and T-cell formation,
function together with G-CSF and GM-CSF, and other
activities. They are the primary messengers & directors
of the immune response (IR). As of 2010,there are 35
known ILs. Pls refer to pp. 80-85 0f CLINICAL
HEMATOLOGY, Theory & Procedures by Mary Louise
Turgeon., 5th edition.
 The genes for GM-CSF, M-CSF & IL3 are clustered
in the long arm of Chromosome 5. Chromosome 17
is the location of G_-CSF