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Chapt. 44 Ch. 44 Biochemistry of Erythrocytes Student Learning Outcomes: • Describe the structure/ function of blood cell types: • Erythrocytes, leukocytes, thrombocytes • Explain the metabolism of the red blood cell • Explain basics of hematopoiesis from bone marrow • Describe some errors of hemoglobin function, anemias, hemoglobin switching • Describe the structure/ function of blood group antigens (Ch. 30) Blood cells Table 1 Blood cells (cells/mm3): • Erythrocytes carry oxygen 5.2 x 106 men 4.6 x 106 women • Neutrophils 4300 granules; phagocytic, O2 burst kills • Lymphocytes 2700 immune response, B- and T-cells, NK • Monocytes 500 macrophages for bacteria, damage • Eosinophils 230 granules destroy parasites (worms) • Basophils 40 • granules hypersensitivity, allergic histamine, proteases, Hematopoiesis Hematopoiesis: • Stem cells in bone marrow (1/105) • Proliferate, differentiate, mature by growth factors, hormones signal transduction paths • Myeloid, lymphoid lines • Leukemias: immature cells keep proliferating; defined by cell type Fig. 15 Anemia Anemias: hemoglobin concentration is low: • Normal Hb g/dL: men 13.5-17.5; women 11.5-15.5 Anemias classified by red blood cell morphology: Rbc morphology Microcytic, hypochromic functional deficit impaired Hb synthesis Macrocytic normochromic impaired DNA synthesis Normocytic normochromic red cell loss possible cause thalassemia, lead, iron deficiency vit B12 or folic acid deficient, erythroleukemia acute bleeding, sickle cell defects Erythrocyte metabolism Erythrocyte metabolism: Only glycolysis • ATP for Na+/K+, Ca2+ • HMP shunt makes NADPH G6PD is 1st enzyme Lifetime rbc by G6PD activity • 2,3-BPG modulates O2 binding • Need Fe2+ Hb bind O2; If ROS made Fe3+, NADH can reduce Fig. 1 Heme synthesis Heme synthesis in erythrocyte precursor: • Heme = porphryn ring, coordinated to Fe • Complexed to proteins in hemoglobin, myoglobin and cytochromes; most common porphryn in body • 4 pyrrole rings with –CH- joining • Various side chains • Heme is red color Fig. 2 Heme synthesis Heme synthesis: Glycine, succinyl CoA form d-Aminolevulinic acid (d-ALA) Each heme needs 8 of each Final step is Fe2+ Heme regulates: inhibit 1st enzyme repress synthesis Porphyria diseases from defective enzymes intermediates accumulate photosensitive, toxic products Fig. 3 Heme synthesis Heme synthesis begins with d-ALA: • Decarboxylation by d-ALA synthase • PLP is pyridoxal phosphate • Dehydratase joins 2 d-ALA • 4 pyrroles form porphyrinogen Fig. 4 Sources of iron and heme Iron is essential from diet – 10-15 mg/day recommended Iron is not readily absorbed from many sources Iron in meats is form of heme, readily absorbed Nonheme iron of plants not as easily absorbed becauuse other compounds precipitate iron Iron absorbed in ferrous state (Fe2+), oxidized by ferroxidase to Fe3+ for transport Apotransferrin binds Fe3+ = Transferrin Stored as ferritin in cells Heme stimulates synthesis of globin proteins from ribosomes Iron metabolism Iron metabolism: • Transferrin carries Fe3+ to cells; stored as ferritin • Transferrin taken up by R-mediated endocytosis • Hemosiderin stores excess Fig. 6 RE = reticuloendothelial system Degradation of hemoglobin Heme is degraded to bilirubin: • Bilirubin is congugated to glucuronate (more soluble),excreted • Rbc only live ~120 days • Globin is degraded to amino acids Figs. 7,8 Red blood cells Erythrocyte cell membrane: • Red disc, pale center • Biconcave shape • Maximizes surface area • 140 um2 vs. 98 um2 sphere • Deforms to enter tissues • Spleen destroys damaged red blood cells Fig. 9 Cytoskeleton of erythrocyte Erythrocyte cytoskeleton • provides shape, structure, permits stretch • 2-D lattice of proteins links to membrane proteins: • spectrin (a, b) • actin • ankyrin • band 4.1 • membrane proteins: • glycophorin • band 3 protein •Mature rbc does not synthesize new proteins • Gets lipids from circulating LDL Fig. 10 general side view; inside cell view up Agents affect oxygen binding of hemoglobin Agents affect oxygen binding of hemoglobin: • • • 2, 3-BPG (glycolysis intermediate) binds between 4 subunits of Hb, lowers affinity for O2, releases O2 to tissues Proton (Bohr) effect: ↑H+ lowers affinity of Hb for O2: CO2 can bind to Hb (not only bicarbonate) Fig. 11,12, 14 Effect of H+ on oxygen binding to Hb Effect of H+ on oxygen binding to Hemoglobin: • Tissues: CO2 released → carbonic acid, H+ • H+ bind Hb → release O2 to tissues • Lungs reverse: O2 binds H+Hb → release H+ • H2CO3 forms, releases CO2 to exhale Fig. 13 Hematopoiesis Hematopoiesis: • Stem cells in bone marrow • proliferate • differentiate • mature • myeloid vs. lymphoid • Stromal cells secrete growth factors • Cytokines signal via membrane receptors Fig. 15 Bone marrow Bone marrow stromal cells secrete growth factors Hematopoietc stem cells respond Hematopoiesis involves cytokine signaling Growth factors signal through membrane receptors: • Ligand causes receptors to aggregate • Activates JAK (kinases) by phosphorylation (cytoplasmic RTK) • JAK phophorylates cytokine receptor on Tyr • Other signaling molecules bind, including STAT (signal transducer and activator of transcription) → nucleus transcription • Also RAS/Raf/MAP kinase activated • Overactive signal → cancer • Transient signal: SOCS silences Figs. 16; 11.15 Erythropoiesis Erythropoiesis: Erythropoietin from kidney increases red blood cell proliferation (if low oxygen) • Reticulocytes still have ribosomes, mRNA to make Hb Mature in spleen, lose ribosomes • Make 1012 rbc/day • Anemia if not appropriate diet • Iron, vitamin B12, folate Fig. 17 Hemoglobin genes Hemoglobinopathies, hemoglobin switching: • Order of genes parallels development, controls • >700 mutant Hb (often base subsittution) • HbS sickle cell (Hb b Glu6Val) • HbC (Hb b Glu6Lys) Both ↑ malaria resistance Fig. 18 Thalassemias Thalassemias: unequal production of a, b of Hb: • need a:b 1:1 • a has 2 genes each chromosome; b only 1 • can have amino acid substitutions, promoter mutations, gene deletions, splice • Improper synthesis cause instability, or aggregation b+ has some b; b0 makes none • People offten survive if hereditary persistence of fetal hemoglobin: HPFH (a2g2 = HbF) • Treatments of b-thalassemia or sickle cell: increase Hb g transcription VI. Hemoglobin switching Hemoglobin switching: • embryo blast synthesis yolk • fetus liver synthesis • adult bone marrow Multiple genes for Hb Order of genes parallels development Problems if deletions, other mutations Problems if imbalance Fig. 18 Transcription factors control Hb switching a-globin locus about 100 kb; HS40 control region b-globin locus has LCR control region • Promoter of g gene has many transcription factors that bind; HPFH mutations often map promoter • Mutated repressor (CDP) or site • SSP and SP1 compete for binding near TATA Fig. 19 Blood types reflect erythrocyte glycolipids Blood group substances are glycolipids or glycoproteins on cell surface of erythrocytes: • Glycosyltransferases add sugars, detemine blood type • Two alleles (three choices) iA, iB, i • Produced in Golgi, lipid part of membrane of vesicle, fuses and carbohydrate extends extracellular Fig. 30.16,17 Key concepts Key concepts: • Blood contains distinct cell types • Erythrocytes transport O2 and return CO2 to lung • Limited metabolism • Heme synthesis in rbc precursos • Oxygen binding • Hematopoiesis from bone marrow • Leukocytes include monocytes, polymorphonuclear • Hemoglobin mutant proteins, expression Review question Review question: 1. A compensatory mechanism to allow adequate oxygen delivery to tissues at high altitudes, where oxygen concentrations are low, is which of the following? a. Increase in 2,3-bisphosphoglycerate synthesis by rbc b. Decrease in 2,3-bisphosphoglycerate synthesis by rbc c. Increase in hemoglobin synthesis by rbc d. Decrease in hemoglobin synthesis by rbc e. Decreasing the blood pH