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HEMOGLOBIN FORMATION- Lecture # 2 page # 451 Ch: # 33 Superfast Simplified self Learning Guyton Physiology 15th Edition.

  • Hemoglobin synthesis begins in polychromatophil erythroblasts.
  • It continues during the reticulocyte stage of RBC development.
  • After reticulocytes leave the bone marrow and enter the bloodstream, they continue producing small amounts of hemoglobin for about one more day.
  • After this, they become mature erythrocytes.
  • Figure 33.5 shows the basic chemical steps of hemoglobin formation.
  • Step I
    • Succinyl-CoA is formed in the Krebs metabolic cycle.
    • Succinyl-CoA combines with glycine.
    • This forms a pyrrole molecule.
  • Step II
    • Four pyrrole molecules combine.
    • This forms protoporphyrin IX.
  • Step III
    • Protoporphyrin IX combines with Fe²⁺ (iron).
    • This forms the heme molecule.
  • Step IV
    • Each heme molecule combines with a long polypeptide chain (globin).
    • The globin is synthesized by ribosomes.
    • This forms a hemoglobin chain.
    • Figure 33.6
  • Step V
    • Four hemoglobin chains bind loosely together.
    • This forms one complete hemoglobin molecule.
  • Each hemoglobin chain has a molecular weight of about 16,000.
  • Four chains together form one hemoglobin molecule.
  • There are slight differences in hemoglobin chains because of differences in the amino acid sequence of the polypeptide portion.
  • The different hemoglobin chains are:
    • Alpha (α)
    • Beta (β)
    • Gamma (γ)
    • Delta (δ)
  • The most common adult hemoglobin is Hemoglobin A (HbA).
  • Hemoglobin A consists of:
    • Two alpha (α) chains
    • Two beta (β) chains
  • Hemoglobin A has a molecular weight of 64,458.
  • Each hemoglobin chain contains one heme prosthetic group.
  • Each heme group contains one iron atom.
  • Since one hemoglobin molecule has four chains, it contains four iron atoms.
  • Each iron atom can bind one oxygen molecule (O₂).
  • Therefore, one hemoglobin molecule can transport:
    • Four oxygen molecules (O₂)
    • Eight oxygen atoms
  • The type of hemoglobin chains determines the oxygen-binding affinity of hemoglobin.
  • Abnormal hemoglobin chains can change the physical properties of the hemoglobin molecule.
  • In sickle cell anemia:
    • Valine replaces glutamic acid at one position in each of the two beta chains.
  • When this abnormal hemoglobin is exposed to low oxygen:
    • It forms long, elongated crystals inside RBCs.
    • These crystals may reach 15 micrometers in length.
  • These crystals make it very difficult for RBCs to pass through small capillaries.
  • The pointed ends of the crystals can rupture the RBC membrane.
  • This leads to sickle cell anemia.

KEY CONCEPT

  • Hemoglobin synthesis starts in polychromatophil erythroblasts and continues until the reticulocyte becomes a mature erythrocyte.
  • Figure 33.5 shows the five chemical steps of hemoglobin formation.
  • Figure 33.6 shows the hemoglobin chain.
  • Formation pathway:
    • Succinyl-CoA + Glycine → Pyrrole
    • 4 Pyrroles → Protoporphyrin IX
    • Protoporphyrin IX + Fe²⁺ → Heme
    • Heme + Globin → Hemoglobin Chain
    • Four Hemoglobin Chains → Hemoglobin A
  • Hemoglobin A contains 2 α chains + 2 β chains.
  • Each hemoglobin molecule contains 4 iron atoms and carries 4 oxygen molecules (8 oxygen atoms).
  • The hemoglobin chain type determines oxygen-binding affinity.
  • In sickle cell anemia, valine replaces glutamic acid in the β chains, causing crystal formation under low oxygen and leading to sickle-shaped RBCs.

Hemoglobin Combines Reversibly With Oxygen

  • The most important property of hemoglobin is its ability to combine loosely and reversibly with oxygen.
  • The primary function of hemoglobin is:
    • To combine with oxygen in the lungs.
    • To transport oxygen in the blood.
    • To release oxygen in the peripheral tissue capillaries.
  • Oxygen is released in the tissues because the oxygen tension there is much lower than in the lungs.
  • Oxygen does not combine with the two positive bonds of the iron atom in the hemoglobin molecule.
  • Instead, oxygen binds loosely to one of the coordination bonds of the iron atom.
  • This coordination bond is very weak (loose).
  • Because the bond is loose, the binding of oxygen to hemoglobin is easily reversible.
  • Oxygen remains in the form of molecular oxygen (O₂) while attached to hemoglobin.
  • Oxygen does not become ionic oxygen.
  • Hemoglobin carries oxygen to the tissues in the form of molecular oxygen (O₂).
  • Because the bond is loose and reversible, oxygen is easily released into the tissue fluids.
  • Oxygen is released into the tissues still as molecular oxygen (O₂), not as ionic oxygen.

KEY CONCEPT

  • Hemoglobin binds oxygen loosely and reversibly.
  • Hemoglobin picks up oxygen in the lungs.
  • Hemoglobin releases oxygen in the peripheral tissue capillaries, where oxygen tension is lower.
  • Oxygen binds to a coordination bond of the iron atom, not to its two positive bonds.
  • The loose bond allows easy loading and unloading of oxygen.
  • Oxygen is transported and released in the form of molecular oxygen (O₂), not ionic oxygen.

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