8/4- Red Cell Physiology

Question 1

What are the main functions of RBCs?

Answer 1

Transport of Oxygen/CO2

• Also a scavenger of nitrix oxide (NO)! (for BP)

Hemostasis

• Increasing hemostatic effects of platelets (blood transfusions or EPO will shorten prolonged bleeding time of uremic pts)
  (e. g. anemic pts with fewer RBCs have longer bleeding time b/c platelets are more central in the vessel)

Clearance of immune complexes

Question 2

The total body hematocrit is higher or lower than hematocrit observed in blood drawn from a large vein?

Answer 2

The total body hematocrit is somewhat lower than the hematocrit observed in blood drawn from a large vein

Question 3

Is human blood a Newtonian or Non-Newtonian fluid? How so?

Answer 3

Human blood is a Non-Newtonian fluid; its viscosity depends on shear rate

• In arterial flow, blood is thinner than blood flowing more slowly in a vein
• In areas of slow flow, RBCs tend to aggregate, increasing viscosity

Question 4

What is shown on the left? right?

Which is more mature?

Answer 4

Left: reticulocyte

• Excess surface area with gathers into a hilum
• Left over area contains mitochondria, ribosomes, etc.

Right: discocyte (more mature)

Question 5

Geometry of RBC? Dimensions?

Answer 5

7-8 um diameter

Question 6

What are Howell Jolly bodies?

Answer 6

Left over bits of DNA of RBCs removed by the spleen?

Question 7

What is seen in pts who have had their spleens removed/impaired?

Answer 7

• Increased number of acanthocytes and Howell Jolly bodies are seen
• Also there are intracellular vacuoles in normal red blood cells which have the appearance of pits or pocks when viewed under interferance (Nomarski) optics.

Question 8

Components of the RBC?

Answer 8

• Membrane
• Hemoglobin (globin, Porphyrin–HEME)
• Enzymes
• 2,3 DPG
• Cations (K mostly)
• Water

Question 9

Structure of the RBC membrane?

Answer 9

• Lipid bilayer (asymmetric)

Inner layer:

• Aminophospholipids PS and PE

Outer layer:

• Phosphatidyl choline
• Sphingomyelin
• Unesterified cholesterol (enriched)

Transmembrane:

• Band 3 (anion transporter)
• Glycophorin A, B

Cytoskeleton

• Spectrin (Stabilized by cytoskeleton comprised of spectrin alpha and beta (share homology with myosin))
• Actin

Question 10

How many RBCs in a vein are echinocytic?

What favors this state?

Answer 10

About 1%

• Echinocytic state is favored by aging in a test tube, uremia, and exposure to glass surfaces if there isn’t much protein around. Certain agents can intercalate into the outer membrane leaflet and cause a similar change

Question 11

What is this?

Answer 11

Echinocyte (Burr cell)

Question 12

What is this? When is it seen?

Answer 12

Stromatocyte

• Common artefact
• Real in patients who have a lot of alcohol on board
• Certain drugs or agents which intercalate in the inner membrane leaflet.
• Osmotic swelling will produce the same effect—one side of the biconcave disk pops out and with further swelling both sides are out—a spherocyte.

Question 13

What is this? When is it seen?

Answer 13

Spherocyte

• Osmotic swelling —one side of the biconcave disk pops out and with further swelling both sides are out—a spherocyte.

Question 14

What are these? When are they seen?

Answer 14

Target cells (codocyte)- results from increased surface area to volume ratio of a RBC

• Can occur in liver disease with partitioning of lipids into the membrane—giving macrocytosis and targeting
• The enzyme disorder LCAT—lescithin cholesterol acyl transferase deficiency also does this; cholesterol and lecithin are increased in the membrane
• Hemoglobinopathies—C and E hemoglobins—activate membrane transport to dehydrate the red blood cell, the decrease in volume results in targets.
• Thalassemia and also iron deficiency will show targets—this slide is sickle beta thalassemia.

Hb S trait does not give you anything, but the thalassemia here does that.

Question 15

What are these? When are they seen?

Answer 15

Acanthocytes (claw cells)

• Seen in post splenectomy states and in certain conditions such as a betalipoproteinemia
• Rare McCleod phenotype- an X linked disorder with these sorts of red blood cell and problems with transfusion because they don’t express Kell red blood cell antigens
• When cholesterol is increased in the plasma it can partition with the red cell to give shapes like this (some times only one big claw is present—a spur cell)

Question 16

Characteristics of echinocytes/Burr cells vs. acanthocytes?

Answer 16

Echinocytes/Burr cells: lots of small spicules.

Acanthocytes: smaller number of spicules which are larger

Note the acanthocyte here and the Howell Jolly Body—their presence indicates the absence of splenic function.

Question 17

The RBC cytoskeleton is comprised of what main types of interactions?

What property is each responsible for?

Answer 17

Vertical interactions: preventing lipid bilayer form becoming unstable soap bubble

Horizontal interactions: elastic behavior; integrity

Question 18

Structure of alpha and beta spectrin?

Answer 18

• Alpha and beta chains self-associate to form dimers
• Two dimers can associate to form a tetramer
• At the non-self associated end of the dimer, there is an actin junctional complex

(Spectrin is an analog of myosin)

Question 19

Rh protein is part of what?

Answer 19

Two principle vertical structures

Question 20

Structure of hemoglobin?

Answer 20

• Alpha and beta globins are translated into protein on their respective ribosomes and heme is inserted
• Alpha and beta globins combine to form a very stable dimer
• Dimers attach to form a tetramer
• Alpha chain is negatively charged overall and the beta chain is positively charged
• Involves 8 alpha helices, heme pocket, and heme ring containing and iron molecule

Question 21

What are hemoglobinopathies?

Answer 21

Mutations that affect the structure of beta or alpha chains

Question 22

What are thalassemias?

Answer 22

Mutations that affect the balance of production of alpha and beta chains such that not enough alpha or bet chains exist

Question 23

What are the three periods of development in terms of RBC/hemoglobin production?

What hemoglobin types are seen in them?

Answer 23

• Embryonic yolk sac
• Fetal
• Adult

Question 24

When does gamma predominate?

When does it switch/to what?

Answer 24

Gamma predominates in utero

• Switch to adult beta in the 3rd TM

Question 25

When do beta chain problems arise? Ex?

Answer 25

- Sickle cell disease or beta thalassemia - Manifested 6 mo or later after birth

Question 26

When do alpha chain problems arise?

Answer 26

Alpha chain problems are recognized at birth (or even in utero if more severe)

Question 27

What are the components of the principal adult hemoglobins?

Answer 27

- All adult hemoglobins share a common alpha chain - Can predict the A2 will go up in beta thalassemia (when beta globin is reduced/absent) - Hb F is not uniformly expressed in RBCs; certain cells (a subpopulation) have a lot of F so they are called F cells

Question 28

Oxyhemoglobin is relaxed (R) or taut (T) conformation?

Answer 28

Oxyhemoglobin is **relaxed (R)** conformation

Question 29

Deoxyhemoglobin is relaxed (R) or taut (T) conformation?

Answer 29

Deoxyhemoglobin is **taut** (T) conformation

Question 30

Hemoglobin oxygen saturation relationship?

Answer 30

- S shaped curve - Lower % saturation at low tissue PO2 - DPG stabilizes the taut formation, favoring deoxygenation

Question 31

O2 saturation cruve

Answer 31

Question 32

What are standard conditions for blood?

Answer 32

Temp = 37'C pH = 7.4 PCO2 = 40 mmHg BPG = 5 mmol/L **Arterial:** PO2 (art) = 90-100 mmHg Sat = 98-100% **Venous:** PO2 vein = 35-40 mmHg Sat = 66-73%

Question 33

Effect of temperature on oxygen binding?

Answer 33

Increased temperature causes decreased oxygen affinity (binding is exothermic)

Question 34

What is the acid Bohr effect?

Answer 34

**Stabilization** of the **deoxy** form of Hb in the presence of **H+ ions** - So in the tissues which are slightly acidotic, deoxygenation is favored - Normal resting muscle pH is 7.03 - Exercise pH goes to 6.0 and increases extraction of O2 form 30 to 70%

Question 35

Does a curves shift left or right correspond to lower oxygen affinity?

Answer 35

Right shift = lower oxygen affinity

Question 36

What things affect Hb O2 affinity? How?

Answer 36

- Note that in hypothermia oxygen isn’t released so well from hemoglobin - Anemia results in increased 2,3 BPG and decreased affinity

Question 37

What are some homotropic ligands?

Answer 37

CO and NO

Question 38

Where does CO come from in the body?

Answer 38

Produced by **porphyrin metabolism** - **1-2 % of Hb** is HbCO - Binding of CO to two subunit increases the O2 affinity of the remaining 3 subunits Darling-Roughton effect - **Shifts** oxygen saturation curve to **LEFT** - One/250 CO/O2 results in 50 % CO Hb - CO binds more slowly, but **dissociation is way slow** CO may be higher in people living in an urban environment and is also higher in smokers and a cause of erythrocytosis

Question 39

What is HbA1C?

Answer 39

Hb + glucose - Criteria for DM - Need a normal RB life span for this to be informative - Normal range: **4-5.6%** - At risk for DM: **5.7-6.4** - DM: **6.5**

Question 40

What is Met Hb?

Answer 40

Fe++ -\> Fe+++ (2-\> 3) - Usually about 1% of Hb

Question 41

What is the structure of Hb F?

Answer 41

**a2y2 (alpha2, gamma2)** - Primary **fetal** Hb - In adults produced by a subset of cells or “**F-Cells**”. F hemoglobin is heterogenously distributed. - Doesn’t bind 2,3 BPG—high affinity Hb - Can form mixed tetramers with Hb A (when beta is a S Hb, the gamma in the tetramer inhibits sickling) - It is about **1%** of **normal adult Hb**

Question 42

What is the human heme biosynthetic pathway?

Answer 42

8 enzymatic steps: - 4 in mitochondria - 4 in cytosol Heme is exported from mitochondria for incorporation into cellular hemoproteins and, particularly in liver, exerts feedback regulation

Question 43

Porphyrin metabolism steps/regulation?

Answer 43

Starts with ALAS1 (liver) or ALAS2 (red cell precursors) ALAS1 negative feed back by Heme ALAS2 control by Iron Response Element - Iron deficiency inhibits - Iron presence increases activity

Question 44

Mutations in ALAS2 are associated with what?

Answer 44

X-linked sideroblastic anemia

Question 45

What is Acute Intermittent Porphyria (AIP)?

Answer 45

Mutations in Porphobilinogen deaminase Presentation after puberty - Abdominal pain, tachycardia, HTN - Neuropathy, psychosis - Hyponatremia and seizures - Precipitated by drugs/starvation/ETOH Increased porphyrins in blood and urine - Watson Schwartz Reaction Response to glucose infusions and Hematin (King George)

Question 46

What is Porphyria Cutanea Tarda?

Answer 46

Uroporphyrinogen decarboxylase (UROD) - Hereditary - Association with hemochromatosis - Acquired: Hepatitis C, Iron overload, HIV, Halogenated hydrocarbons Involves **skin** and **liver** Most stiking feature is **bullous dermatosis** on light exposed areas

Question 47

Regulation of Hb Synthesis?

Answer 47

Alpha and Beta chain production are similar Globin production is inhibited when heme is absent - HRI heme regulated eIF2alpha kinase - This increases if Heme is absent - Protein synthesis at the ribosome is halted ALA syntase is regulated by IRE Feline leukemia virus sub group C receptor (FLVCR) - Heme exporter Alpha hemoglobin stabilizing protein, AHSP