Title: Hematology 425 Leukopoiesis
1Hematology 425 Leukopoiesis
- Russ Morrison
- October 11, 2006
2Leukopoiesis
- Leukopoiesis is the development of WBCs
- WBC development (except lymphycytes) occurs in
the same locations as RBCs (review figure 6-1)
- In WBCs the maturation changes are more
unidirectional since with the exception of
neoplasia or myeloid metaplasia, the spleen and
liver do not participate in WBC formation after
birth
3Leukopoiesis
- Though one term, erythron, is used to define RBC
production, there is no corollary for WBC
production
- WBC production involves complex populations of
cells with different compartments that they
occupy during their life cycle
- Control mechanisms of cellular behavior are more
complex in WBCs than in RBCs
4Leukopoiesis
- WBC control mechanisms include interrelations
with adipose tissue, fibroblasts and endothelial
cells
- Again, as with RBCs, cellular production takes
place in all marrow space at birth and by the end
of adolescence is found only in the marrow of the
proximal ends of the long bones and in flat bones
such as the skull and sternum. (review fig.6-2) - The inactive marrow of adolescence and adulthood
can revert to active marrow in times of stress
5Leukopoiesis
- WBCs can be divided into categories based on
specific function, site of origin or morphology
- All WBCs exist to defend the body against
nonself agents
- This defense is accomplished through intricate
cooperation and communication among cells
6Leukopoiesis
- As a for instance, phagocytes attack and destroy
a wide variety of invading matter on their own.
However, lymphocytes direct and amplify
phagocytic action through the release of
lymphokines (a sort of bioresponse mediator) - WBCs are divided into granulocytes and
lymphocytes based on differentiation at the
primitive stem cell level (fig. 11-1)
7Leukopoiesis
- Lymphocytes are produced in both bone marrow and
lymphoid tissue
- Environmental and hormonal stimuli of lymphocytes
are different than those that control
granulocytes and monocytes
- Granulocytes (PMNs) function as destroyers of
pyogenic bacteria, monocyte/macrophages are less
descriminating in their dietary preferences
8Leukopoiesis
- Granulocytes contain visible granules and develop
in the bone marrow
- Granulocytes are subdivided according to
morphology and according to size/visibility of
granules
- Cells containing large, visible granules are
called granulocytes and are further divided into
PMNs, Eos and Basos based on differential
staining of the granules with Romanowsky-based
stain - Monocytes contain tiny granules that cause their
cytoplasm to appear grainy with light microscopy
9Leukopoiesis
- Microscopic evaluation of WBCs is the basis of
clinical study
- Flow cytometry of receptor sites, antigenic
labeling and even functional studies now
contribute to clinical information gathered in
the diagnosis and management of disease - Cell markers have been given alphanumerical codes
(CD1) in which CD stands for cluster designation,
discussed in chapter on flow cytometry
10Leukopoiesis, Granulocytes
- Found in high concentrations in 4 locations
called granulocyte pools
- Bone marrow
- PB circulation
- Marginating up against the endothelium of blood
vessels
- Tissues
11Leukopoiesis, Granulocytes
- Bone marrow pool is large and has 3 functions
- Proliferation
- Maturation
- Storage
- Cells found in the proliferating component are
myeloblasts, promyelocytes and myelocytes, all
capable of mitotic division
12Leukopoiesis, Granulocytes
- The maturation component of the BM consists of
metamyelocytes and band forms no longer capable
of mitosis but not yet fully functional
- The storage component of the BM consists of bands
and PMNs and holds 25x as many cells as in the
circulating PB
13Leukopoiesis, Granulocytes
- Fully mature granulocytes are stimulated by
chemotactic factors and leave the marrow entering
the PB where they become part of either the
marginating pool of the circulating pool - The marginating pool consists of 50 of total PB
granulocyte levels where the cells have adhered
to blood vessel endothelium or are engaged in
diapedesis (egressing into tissue through vessel
walls)
14Leukopoiesis, Granulocytes
- The circulating pool contains the remaining 50
of PB granulocytes and are the cells seen and
counted in PB hematologic studies
- Granulocytes move freely between marginating and
circulating pools in a bi-directional flow for a
variety of reasons
15Leukopoiesis, Granulocytes
- Maturation of the Granulocytic Series
- Begins with the pluripotential stem cell (PSC)
- PSC commits its progeny to lymphoid or bone
marrow origin, for reasons unknown, through the
action of growth factors that are either tyrosine
kinase receptors or cytokines
16Leukopoiesis, Granulocytes
- For granulopoiesis, the PSC undergoes
stimulation, mitosis and maturation into a stem
cell that is specific for bone marrow-derived or
myeloid cells - This CFU-GEMM matures into another stem cell
called the CFU-GM
- The CFU-GM matures into the earliest cell of the
neutrophilic series, the myeloblast
17Leukopoiesis, Granulocytes
- Cell numbers and function is controlled by
complex interaction of humoral factors such as
interleukins and CSFs
- CSFs are categorized by the type of cell
stimulated
- GM-CSF granulocytes monocytes/ macrophages
- G-CSF granulocytes
- M-CSF - monocytes/macrophages
18Leukopoiesis, Granulocytes
- CSF specificity is mediated by receptor sites on
precursors and on mature cells
- Biologic action of receptors consists of a ligand
specific low-affinity binding chain and a second,
high-affinity chain for binding and signal
transduction. - The second chain interacts with IL-3 and IL-5
(Chapter 6)
19Neutrophil Maturation - Myeloblast
- Cells in the BM proliferation pool take 24-48
hours for a single cell cycle
- Less than 1 of the normal BM compartment is
composed of myeloblasts
- Large, 15-20 um in size
- Delicate nucleus with prominent nucleoli
- Small amount of cytoplasm with rough endoplasmic
reticulum, a developing Golgi apparatus and an
increasing number of azurophilic granules
20Neutrophil Maturation - Myeloblast
- Cytochemical staining shows presence of
myeloperoxidase which is required for
intracellular kills
- Killing function is the first to be operational
in the neutrophil cell line
- Myeloblast is incapable of motility, adhesion and
phagocytosis and is therefore nonfunctional
21Neutrophil Maturation - Promyelocyte
- After a few days in the blast stage, the cell
becomes a promyelocyte
- 1-5 of BM compartment composed of promyelocytes
- Size is variable and may exceed 20 um, so may be
larger than myeloblast
- Nuclear chromatin may be delicate or may show
slight clumping
- Nuceloli begin to fade
22Neutrophil Maturation - Promyelocyte
- Granules are present throughout the cytoplasm and
on top of the nucleus
- Motility may develop by the end of this stage
- Myeloperoxidase is found throughout the cell
which with other enzymes can provide the
peroxidase/superoxide burst capable of
intracellular kill
23Neutrophil Maturation - Myelocyte
- Production and accumulation of neutrophilic
granules is characteristic of the myelocyte
- The myelocyte is the last cell of the BM
compartment capable of mitosis
- Myelocytes demonstrate morphologic variability as
this development stage lasts from 4-5 days and
cause alterations in the staining characteristics
of the cell
24Neutrophil Maturation - Myelocyte
- Smaller in size than the promyelocyte (12-18 um)
- Less than 10 of BM compartment is made up of
myelocytes
- Nucleus is round to oval with a flattened side
near the now well-developed Golgi apparatus
- Nuclear chromatin shows clumping
- Nucleoli no longer visible
25Neutrophil Maturation - Myelocyte
- Secondary granules stain pink causing a dawn of
neutrophilia or pink blush within the cytoplasm
- Compounds such as alkaline phosphatase begin to
concentrate in the cell
- The cell acquires some motility
26Neutrophilic Maturation - Metamyelocyte
- The myelocyte becomes a metamyelocyte with the
cessation of all DNA synthesis
- Delineator of maturation change is that the
nucleus of the metamyelocyte becomes indented
with clumped chromatin
- Complete collection of primary and secondary
granules used to kill and degrade toxic,
infectious or non-self agents
- Cell is not yet capable of responding to
chemotactic factors or of initiating phagocytosis
27Neutrophilic Maturation - Metamyelocyte
- 13-22 of BM compartment
- 10-15 um in size
- Not seen in normal PB
- Not fully functional, part of the maturation
component of the marrow
28Neutrophilic Maturation - Band
- The band is a transitional form that exists in
both the PB and the BM and considered part of
both the maturation and storage pools
- Up to 40 of the WBCs of the BM are bands
- Represents the almost mature neutrophil having
full motility, active adhesion properties, and
some phagocytic ability
29Neutrophilic Maturation - Band
- Band forms begin to produce tertiary granules
- Membrane maturity shows changes in cytoskeleton,
surface charge and presence of receptors for
complement
- Once entered into the PB, account for less than
6 of circulating WBCs
- 10-15 um in size
- Found in marginating and circulating poos of the
PB
30Neutrophilic Maturation - PMN
- This cells nucleus continues to indent until
thin strands of membrane and heterochromatin form
into segments, hence it is also called a seg
- Polymorphonuclear means many-shaped nucleus,
describing the varied nuclear shapes
- Cell is completely functional and spend time in
the storage pool of the BM as well as marginating
and circulating pools of the PB
- 50-70 of circulating WBCs of PB
31Neutrophilic Maturation - PMN
- PMNs spend their life performing phagocytosis and
pinocytosis
- Phagocytosis involves larger material and can be
observed with light microscopy, pinocytosis
involves small material (liquids) and is observed
with EM - Both of these function can be performed in the
circulation of the blood stream or in the tissues
32Eosinophil Maturation
- Close relative of the PMN whose secondary
granules stain orange-red with Romanowsky-based
stains
- Development of PSCs into eosinophils requires
IL-3, IL-5 and GM-CSF and is inhibited by the
presence of interferon
- CFU-GEMM to CFU-Eo to myeloblast
- Myeloblast to promyelocyte which is
indistinguishable from other promyelocytes
33Eosinophil Maturation
- Myelocyte becomes distinguishable from
neutrophilic line due to presence of large, round
granules containing major basic protein, which in
turn is responsible for the staining qualities of
the eosiniphilic granules. - Eosinophils spend less than 1 week in the PB
- Large storage capacity of Eos in BM allow rapid
deployment, on demand
34Eosinophil Maturation
- When stimulated, Eos leave the marrow and pass
quickly into the tissues
- Actively motile, using same migration paths as
neutrophils
- Short transit times in PB cause variability in Eo
numbers in the WBC differential
- Less than 5 of circulating WBCs
- Allergic response may increase numbers of Eos
35Eosinophil Maturation
- Mature Eos may be in band form or bilobed while
nuclei with higher lobe counts are seldom seen
- Slightly larger than PMN at 12-17 um
36Basophil Maturation
- Characterized by presence of large, purple
granules
- Granules are irregularly shaped, unevely
distributed and deep purple to black when stained
with Romanowsky stains
- Maturation from stem cell to mature Baso is not
well defined, but thought to parallel that of the
Eo
37Basophil Maturation
- As with Eos, Basos can be classifed as
myelocytes, metamyelocytes, bands and PMN cells
on the basis of nuclear development
- As with Eos, mature cells with more than 2
nuclear lobes are not usually seen
- The least common cell in the PB, at less than 1
of circulating WBCs
- Have high-affinity receptors for the Fc region of
IgE
38Monocyte/Macrophage Maturation
- Monocyte/Macrophage cells mature from monoblast
to promonocyte to blood monocyte to free and
fixed macrophages, but the mechanism of
commitment is not well understood. - Granular content vary considerably with more than
50 secretory compounds having been dentified.
- PB monocytes demonstrate morphologic variability
- Aggressive motility and adherence may distort the
monocytes during PB smear preparation
39Monocyte/Macrophage Maturation
- Monocyte nucleus is indented or curved with
chromatin that is lacy with small clumps
- Typically the largest cell in the PB
- Cytoplasm is filled with minute granules that
produce a cloudy appearance
- Cytoplasmic membrane may be irregular, pseudopods
and phagocytic vacuoles may be evident
40Monocyte/Macrophage Maturation
- Described as a transitional cell because it
leaves the BM to enter the PB and then leaves to
enter tissues in response to chemotactic factors
- Makes up les than 15 of PB WBC differential
- Highly motile and tend to marginate along vessel
walls with a strong tendency to adhere to
surfaces
- May be stimulated to undergo diapedesis and
become free macrophages with increased phagocytic
activity
41Monocyte/Macrophage Maturation
- Macrophages are large, acively phagocytic cells
with a size of 15-85 um
- Pleomorphic in shape, frequently with pseudopods
- Function is phagocytosis
- Material ingested is highly variable
- Pinocytosis also occurs with items less than 2 um
in size
42Monocyte/Macrophage Maturation
- Multistep process of recognition/ attachment,
ingestion, intracellular kill, digestion/degradati
on, and exocytosis occurs in both phagocytosis
and pinocytosis. - Monocytes kill any recognizable non-self agents
including dead or dying cells, bacteria, fungi
and viruses.
- Play a role in processing antigens for lymphocyte
recognition and stimulation of lymphocyte
transformation.
43Monocyte/Macrophage Maturation
- May function as anti-tumor agents by phagocytic
action of nonself cells via elaboration of tumor
necrosis factor and stimulation of lymphocyte
activity - Macrophages are in 2 categories
- Free found in varying concentrations in all
sites of inflammation and repair, alveolar spaces
and peritoneal and synovial fluids
44Monocyte/Macrophage Maturation
- Fixed found in specific concentrations in
specific sites such as the nervous system
(microglial cells), liver (Kupffer cells),
spleen, bone marrow and lymph nodes - Macrophages are large, 15-80 um, have ample
cytoplasm filled with granules and often have
multiple vacuoles
- Nucleus is round to reniform and may contain 1 or
2 nucleoli
45Lymphocytes
- The only human WBCs whose site of development is
not just BM, but also tisues referred to as
primary and secondary lymphoid organs
- In humans, the primary lymphoid organs are the
thymus and bone marrow, the secondary organs
include the spleen, Peyers patches of the GI
tract, the Waldermyer ring of the tonsils and
adenoids, the lymph nodes and modules scattered
throughout the body
46Lymphocytes
- Lymphocytes circulate throughout the body in both
PB and lymph which act as carrier streams to
bring the lymphocytes to sites of activity
- Lymphocytes migrate from thoracic duct through
vessel endothelium to lymph nodes to blood stream
and back.
- Lymphocytes are categorized in a variety of ways
and may be short-lived or long-lived cells
- Lymphocytes may produce antibodies or lymphokines
and have different surface charges, densities and
antigen receptors.
47Lymphocytes - Development
- The PSC results in a stem cell for the lymphoid
cell (CFU-L) as a result of hormonal stimuli
- The CFU-L matures in several environments
- Thymus and BM give rise to lymphocytes, foster
differentiation and are indepentendent of
antigenic stimulation
48Lymphocytes - Development
- Cells that develop under the influence of the
thymus are called T cells and have specific
receptors and responses.
- B cells develop from the BM and have a different
set of functions and receptors.
- The end cell of the B lymphocyte maturation is
the plasma cell
- Once the environmental effects of the thymus and
BM have been achieved, lymphocytes migrate to
secondary lymphatic tissues such as the spleen
and tonsils, which act as the main repositories
for already differentiated lymphocytes.
49Lymphocytes - Development
- Cellular interactions for the presentation of
antigen to the cells have a critical role in
priming cells for proliferation and impact cell
maturation, especially T cells. Once primed, the
cells are now responsive to specific antigens. - Lymphocytes demonstrate lymphoblast,
prolymphocyte and mature lymphocyte stages when
stained with Romanowsky stains.
50Lymphocytes - Development
- Lymphocyte in the PB varies, depending on age.
- Children under the age of 4 have a higher
proportion of lymphocytes in the PB than do
adults
- Lymphocytes are the second most common WBC of the
PB making up 20-40 of WBCs.
- 20-35 of circulating lymphocytes are B cells
51Lymphocytes - Maturation
- Lymphoblast to prolymphocyte
- Lymphoblast is small, 10-18 um
- Round to oval nucleus
- Loose chromatin with one or more active nucleoli
- Scanty cytoplasm
- Prolymphocyte difficult to distinguish, subtle
changes, more clumped chromatin, lessening
nucleolar priminence, change in thickness of the
nuclear membrane
52Lymphocytes - Maturation
- Prolymphocyte to Lymphocyte
- Lymphocytes vary mostly by size
- Small 9 um in diameter, non-dividing or
resting
- Medium 11-14 um, non-dividing
- Large 15 um, more generous cytoplasm that is
deep blue when stained
- Morphologic variants (table 11-2)
53Lymphocytes Immunologic Differentiation
- Lymphocytes may be classified by immunologic
function
- B Cells
- Possess cytoplasmic IG concentrations of IgD and
IgM
- Some membrane receptors are apparent
- The fully committed B lymphocyte is the plasma
cell
- Demonstrate class I and class II human leukocyte
antigens (HLA-A, HLA-B, HLA-C and HLA-D, HLA-DR)
54Lymphocytes Immunologic Differentiation
- T Cells
- The primitive T cell, CFU-L, travels to the
thymus
- Acquires a transferrin receptor that is specific
to proliferation
- Mature T cells lose all precursor markers and
have an active helper or suppressor function
- T cells are further differentiated through
presence or absence of HLA-D antigens
- T cells possess HLA-A, HLA-B and HLA-C class I
antigens
55Lymphocytes - Activity
- The main function of the lymphocyte is to
regulate immune function
- If foreign material is completely engulfed,
degraded and disposed of by phagocytes, no immune
response occurs
- If digestion is incomplete, antigenic fragments
are transported to lymph nodes
- In the lymph node the antigen is fixed to the
exterior surface and brought into the lysozymes
of the macrophage
56Lymphocytes - Activity
- The antigen is processed and once that occurs,
proliferation occurs
- Development of clones of antigen-specific B
lymphocytes and cytotoxic T cells begins
- Activity that accompanies clonal expansion
required for antigen removal can be seen in the
morphology of cells called reactive lymphocytes