Lecture 6

Question 1

what are Erythrocytes

Answer 1

• Anucleate cells when mature
• Comprised of 95% hemoglobin
• Function
  ‒Primary carry O2 from lungs to tissues
  ‒Secondary – return CO2 from tissues to lungs and buffer pH of blood

Question 2

What does Normal Erythropoiesis look like

Answer 2

• Mature RBCs circulate for 120
  days
• BM always over-produces RBCs:
  ‒Excess precursors ready for quick
  response if needed
  ‒‘Unnecessary’ RBC precursors die by ‘programmed cell death’ or
  apoptosis (natural process) if no stimulus occurs
• 1% RBCs replaced daily

Question 3

what are the

*Progenitors and
precursor cells?

*Controlled by?

*Maturation
sequence?

of Erythropoiesis

Answer 3

-the process of how RBCs are produced in the bone marrow in erythroid island next to the venus sinusoid or around a central macrophage with Iron
start with the common myeloid progenitor - megakaryocyte erythrocyte progenitor - mature in the perpherial blood after release

-controlled by EPO - main hormone to control Bone marrow production of red cells - growth factor cytokine

Question 4

Erythropoietin (EPO) what is it

Answer 4

• Glycoprotein hormone (or growth factor)
• Synthesized mainly in the kidneys (some in liver)
• Released into the bloodstream in response to hypoxia
  ‒E.g., not enough RBC or abnormal RBCs, defective HGB, or poor lung function
• Peritubular cells (fibroblasts) in kidney detect insufficient O2 this triggers EPO production mediated by increased EPO gene transcription by Hypoxia Inducible Factors (HIFs)

HIF proteins build up and promote erythropoiesis

in low PO2 , HIF proteins promote activation of genes that can adapt to hypoxia conditions. HIF binds to kidney and increases EPO and increases O2 in blood by increasing RBC production

Question 5

Erythropoietin (EPO) what does it do

Answer 5

• stimulate and regulate the production of erythrocytes
• Binds to EPO-receptors on RBC progenitors and precursors causing:
  1. Allows early release of immature RBCs (reticulocytes) from BM
  2. Preventing RBC apoptosis (CFU-E progenitors protected)
  3. Reduce BM transit time (shortens time between and reduces the number of mitoses of precursors)
• Recombinant version available for use in treating anemia
  ‒ Especially due to renal disease (no EPO)
  ‒ Used by athletes in ‘doping’ scandals

when epo binds to its receptor EPOR and stimulates JAK2 pathway to promote RBC production at a faster rate

Question 6

Nomenclature for Erythroid
Precursors

Answer 6

Pronormoblast
Basophilic normoblast
Polychromatic (or Polychromatophilic) normoblast
Orthochromic normoblast
All above nucleated precursors found ONLY in the bone marrow

Reticulocyte- no nuc- in BM then PB
Erythrocyte - slowly loses nucleus as it matures

Question 7

How does Erythropoiesis occur

Answer 7

CFU-GEMM acts on the HSC forming the BFU-E: Burst-Forming Unit-Erythroid - produces daughter cells with few EPO receptors with the help of EPO form CFU -E

colonies CFU-E: Colony-Forming Unit Erythroid have many EPO receptors allowing for their differentiation of the below precursors

Pronormoblasts:
* Earliest recognizable erythrocyteprecursor in the BM
* Production stimulated by EPO
* Able to divide
* Each daughter cell matures to the next stage

Basophilic & Polychromatic Normoblasts:
* Able to divide
* Each daughter cell matures to the next stage

Orthochromatic normoblast:
* Does not divide (nucleated)
* Matures to a Reticulocyte in BM then to PB (no nucleus)

Mature Erythrocyte:
* 18-21 days from BFU-E to RBC
* 8-32 RBCs produced from 1 pronormoblast

Question 8

Typical Production of
Erythrocytes

Answer 8

• 1 Pronormoblast produces 8 RBCs
• Last division at Polychromatic
  normoblast stage
• Lose nucleus in BM, released to PB before complete maturation

Question 9

Criteria for differentiating the
stages of RBC development:

Answer 9

A - Cell size decreases, and cytoplasm turns blue to salmon pink
B- Nucleus size decreases and color changes from purplish-red to dark blue – N:C Ratio decreases
C - Nuclear chromatin becomes coarser, clumped & condensed (pyknotic) and nucleoli disappear
D- Composite of changes during developmental process

Question 10

RBC Maturation Chart:

Answer 10

18-24 days= mature RBC from BFU E for 1 week and one week as a CFU E and 1 week to mature from the pronormoblast to mature RBC.

cell diameter and DNA reduces as cell matures

what happens the RBC as the DNA/RNA content reduce and increased acidophilia occurs in a Wrights stain?
RBC cytoplasm from blue to pink increases in hemoglobin content.
Basophilia is high in the prophase - high DNA/RNA/Protein content.

Green arrow increase in Hemoglobin or eosinophile staining. Acidophila corresponds with RBC maturation
hemoglobin makes up most of the protein in the later stages

Question 11

HEMOGLOBIN BIOSYNTHESIS

Answer 11

-made in mitochondria and cytoplasm
-65% of Hemoglobin Synthesis
occurs in nucleated stages-
-35% Hgb synthesis occurs in the
Reticulocytes

Why can’t mature RBCs make hemoglobin? Mature RBCs lack nucleus, mitochondria, and other organelles, and are therefore, incapable of protein synthesis
The immature forms have these cell tools to make hemoglobin

Question 12

Orthochromic Normoblast

How does cell lose its nucleus?

Answer 12

• Nucleus is condensed or ‘pyknotic’ meaning the cell cant divide. Losing the nuc will mean that the RBC will be able to carry more hemoglobin
• Membrane ‘projection’ forms as nucleus squeezes out to edge of cell
• Entire projection pinches off and nucleus is ejected
• Bone marrow macrophages engulf and breakdown expelled nucleus
• This stage is often seen in PB during disease states
  ‒ Rarely are earlier stages seen except in very severe disease
• We call this a ‘Nucleated RBC’ or NRBC if seen in PB

Question 13

Polychromatic Erythrocyte
(Reticulocyte) - after nucleus is lost

Answer 13

• Large, oval or irregularly-shaped (lumpy) cell with no nucleus
• Still producing hemoglobin- through RNA and Ribosomes that are leftover in the cytoplasm
• Cytoplasm contains precipitated RNA (seen supravitally)
• Location
  ‒ In BM for ~ 1 to 2 days
  ‒ In PB for ~ 1 day then mature into Erythrocytes
• Up to 2.5% of PB RBC are ‘Retics’ – this is normal
  ‒ > 2.5% in PB is reported as ‘Increased Polychromasia’ - disease process - Wrights GIemsa with methylene blue azure

the polychromatic erythrocyte is retained in the spleen for polishing by splenic macrophages, which
results in the biconcave discoid mature RBC

Question 14

Mature Erythrocyte

Answer 14

Biconcave disc- shape is good for hemoglobin are close to the RBC membrane
* Central pale area- Central pallor 1/3 of cell diameter~
‒ Corresponds to concavity

• Unable to synthesize HGB
  ‒ No nucleus, ribosomes or mitochondria, no protein synthesis
• Carries oxygen from lungs to tissues and exchanges O2 for CO2
• Recall, mature RBC lives ~ 120 days

Question 15

Three aspects of RBC physiology
are crucial for normal erythrocyte
maturation, survival and function:

Answer 15

1. RBC membrane‒ Deformability depends on
   membrane shape, viscosity, and elasticity
2. Hemoglobin structure and function
3. Cellular energetics

RBCs job is gas exchange using hemoglobin and biconcave shape

Question 16

RBC Membrane contains:

Answer 16

• to maintain shape stable membrane structure
• transport of nutrients, ions, etc.
• Considered a lipid-bilayer tied to an cytoskeleton
  ‒ Phospholipids (fluidity) and cholesterol (tensile strength) in equal parts elasticity and strength

Separating plasma from cytoplasm
* Maintain an osmotic differential
* Permeable to H2O, bicarbonate and chloride (anions)
* Impermeable to Ca2+, K+, and Na+ (cations)
‒ Passive transportation of anions, gases, water and glucose
‒ Active transportation of cations

Question 17

RBC Membrane Deformability

Answer 17

*RBCs must squeeze through capillaries to exchange O2 & CO2
*Depends on RBC SHAPE, VISCOSITY, & MEMBRANE
ELASTICITY
*Biconcave SHAPE better than sphere – more surface area

Question 18

Cytoplasm Viscosity

Answer 18

• Refers to concentration of HGB in RBC cytoplasm
• We measure:
  ‒ Amount of HGB (g/L) in total blood
  ‒ By weight per RBC- MCH (pg)
  ‒ Concentration of HGB per RBC – MCHC (g/L) – Normal 32-36%
• Low viscosity allows the RBC to deform and squeeze through narrow spaces
• RBCs with MCHC >36% are too viscous & less deformable = RBC life span ↓
  ‒ Cells become damaged as they pass through narrow capillaries or small splenic pores - cold agglutination or spherocytes

Question 19

RBC Membrane part Membrane Carbohydrates

Answer 19

• glyco- protein and -lipid chains
• Function in cell-cell recognition and adhesions (such as, ABH blood)
• anchor protective coating called Glycocalyx
  ‒ Adsorbs substances from extracellular matrix
  ‒ Gives net negative charge to RBC membrane
  -RBCs able to repel one another

Question 20

MEMBRANE CHARGE & ZETA
POTENTIAL

Answer 20

• Negative charges of membrane keep RBCs apart – stops them from
  ‘bunching’ up in circulation
• Anything that will reduce the Zeta potential will allow RBCs to come
  closer together

-the negative charge of RBC is produced by high salic acid content on the membrane

-the positive charge form an ionic cloud around the negatively charged cells

-the difference in the neg and positive is the zeta potential

Question 21

RBC Membrane * Transmembrane Proteins –

Answer 21

function as transport and adhesion sites, surface antigens, and signaling receptors ‒ Rh Blood group system, cation pumps (Na/K-ATPase and Ca2+ ATPase), Aquaporin 1, Glut-1, etc.

‒ Possible immunogenicity to
proteins that act as ‘antigens’

• Anchor to underlying cytoskeleton (Ankyrin or Actin junctional complex) which Provide vertical membrane structure and stability helps with integrity and prevent membrane loss

Question 22

RBC Membrane * Cytoskeletal Proteins

Answer 22

*complex lattice and/or anchorage structure found on inner (cytoplasmic) lipid bilayer ‒ Major proteins are α- and β-spectrin, Ankyrin, Protein 4.1, Protein 4.2,Tropomodulin, Tropomyosin, -
-do not penetrate the bilayer

‒ Provides horizontal or lateral support to RBC
membrane and Gives mechanical stability and supports membrane elasticity

Question 23

what are Spectrins

Answer 23

• form a hexagonal cytoskeletal lattice on inner lipid bilayer
  (they are antiparallel heterodimers)
• Ends linked to actin junctional complex
• Bonds break and form to RBC membrane deformability
• Loss or mutations of these proteins can affect the membrane integrity and eventually the shape of the RBC

Question 24

What is
Hemoglobin?

Answer 24

• Globular protein
• Consists of- 4 Globin chains
  and 4 Heme groups

Question 25

What are Globin Chains

Answer 25

• Protein - long chains of amino acids or polypeptides
• 141-146 amino acids per chain
• Different amino acid sequences = different types of globin chains
• Each combination of two types results in a different HGB
  -* Most types of HGB have: ‒ 2 α ‒ 2 others to form molecule
• chain divided into 8 helices and 7 nonhelical segments
• Combine to hold the HEMO

Question 26

What is HEME?

Answer 26

-Protoporphyrin IX (C, H, N ring structure)
+ 1 central atom of Ferrous iron
(Fe2+)

Each HEME component can combine
reversibly with 1 molecule of oxygen

Question 27

Iron Sources & Forms

Answer 27

• Ingested and absorbed in GI tract as Fe2+ or Ferrous iron
• Stored mainly in liver as:
  ‒Ferritin
• Fe3+ or Ferric Iron is stored in Apoferritin (cage-like protein)

‒Hemosiderin
* Partially degraded aggregates of Ferritin

• Iron transported to BM as Transferrin
  ‒Up to two molecules bind to Apotransferrin
  (glycoprotein)
• RBC precursors have receptors to Transferrin
  When bound, receptors and Transferrin are taken into cell & Ferric ions released into cytoplasm

Question 28

HEMOGLOBIN
ASSEMBLY

Answer 28

-synthesis occurs in the BM
-production involves enzymes working in the mitochondria and cytoplasm of the RBC

• globin chains proteins produced from gene transcription in nucleus of RBC and translation to polypeptide chains on ribosomes in the RBC cytoplasm
• Dimers of: 1 α /HEME & 1 non-α /HEME combine to form tetramer (positively charged)

Question 29

Normal Hemoglobins

Answer 29

• Fetus – Hb F - high affinity for O2
• Newborn – mostly Hb F, switching to Hb A
• Adult – mostly Hb A, small amount of Hb A2, very little Hb F

KNOW THE CHART *** WITH STARS

can use Electrophoresis to see what is needed

Question 30

Hemoglobin
Function

Answer 30

• Carries and releases Oxygen
  to tissues
  ‒ Each HGB tetramer can bind
  4 O2 molecules
• Facilitates removal of CO2
• Buffers pH of blood (by binding and releasing hydrogen ions)
• Transports nitric oxide (regulator of vascular patency)

Question 31

RBC Metabolism

Answer 31

• Energy not required to exchange oxygen/carbon dioxide (passive)
• Energy is required for RBCs metabolic processes
• RBCs can’t produce enzymes – lack nucleus,
  ribosomes, and mitochondria

** Rely on glucose from plasma and a series of enzyme pathways for ATP production
‒Anaerobic glycolysis (main) - Embden-Meyerhof Pathway (entry via facilitated diffusion)

‒Glycolysis Diversion Shunts-Oxidative glycolysis –
* Hexose Monophosphate Pathway
* Methemoglobin Reductase Pathway
* Rapoport-Luebering Pathway

Question 32

RBC Senescence

Answer 32

RBC getting old

• To maintain membrane volume, permeability, shape, and flexibility, RBCs rely on glucose from plasma and enzyme pathways for ATP - limited time
• Mature RBCs ⇒ no nucleus, no ribosomes or mitochondria, ↓ ATP over time
  ‒ ∴ as the cellular functions decline the cell is unable to repair cell structure or replenish enzymes involved in metabolic pathways/metabolic function
• ‘Old’ RBCs change over 120-day lifespan: ‒Membrane becomes rigid and fragile – membrane loses deformability
  ‒Selective permeability decreases, cells more permeable to water – spheroid shape results

RBCs are taken out via intra or extravascular hemolysis

Question 33

RBC Destruction

Answer 33

• Spleen- filters large circulating blood volume ‒ Movement through spleen is slow, glucose depletes, and glycolysis slows, less ATP is produced, and pH is low increasing oxidation of iron
• Stressful environment + age-related changes, leaves ‘Old’ RBCs unable to squeeze through splenic sinusoids and are removed by splenic Macrophages
• This is called Extravascular Hemolysis
• Most RBCs lost this way
  ‒ AKA Macrophage-Mediated Hemolysis
  ‒ Occurs outside of vasculature
  ‒ Excessive in some Hemolytic anemias

Question 34

Extravascular Hemolysis

Answer 34

In spleen, senescent RBCs are phagocytosed and lysed by Macrophages
* Enzymes of the macrophage phagolysosome either salvage or metabolize RBC
* HGB is broken down & components are released
‒ Globin into metabolic amino acid pool
‒ Iron stored as Ferritin in macrophage or released as Transferrin in plasma
‒Protoporphyrin degraded eventually into Bilirubin and then Bile or Urobilinogen

Question 35

Intravascular Hemolysis

Answer 35

• RBC destruction inside the blood vessels ‒AKA Fragmentation or Mechanical Hemolysis
  ‒ mechanical or traumatic stress in vessels
  ‒Damage to blood vessels that causes clots to trap the RBCs
• RBCs fragment or lyse
  ‒Free hemoglobin released directly into the peripheral blood
• Minor component of normal RBC destruction
• System in place to salvage RBC components
• Free HGB in plasma attaches to transport proteins Haptoglobin or if oxidizedbinds to Hemopexin
• Breakdown products taken to liver &/or excreted through kidney

Question 36

In times of Increased
Intravascular Hemolysis what happens

Answer 36

‒ Kidney can become overwhelmed & renal failure can occur (hemoglobinemia
and hemoglobinuria can be seen)
‒ E.g., Malarial protozoa bursting out of RBCs

Question 37

Feedback loop

Answer 37

-after 120 days damaged RBC removed via extravascular hemolysis via spleen or liver
-Fe recycled and globin sent to amino pool causing decrease of O2
-This decrease causes production of EPO in kidney
-Which bind to surface receptors of erythrocyte progenitors to stimulate Bone marrow erythropoiesis
-This stimulates the CFU-E and then after 7 days when precursor cells mature to produce a fully goblinized RBC
- The rbc is released in to peripheral circulation to be use for gas exchange