Describe the effects of PO2, PCO2, pH, and temperature on hemoglobin and oxygen transport.
Partial pressure is an important aspect of the binding of oxygen to and disassociation from heme. An oxygen–hemoglobin dissociation curve is a graph that describes the relationship of partial pressure to the binding of oxygen to heme and its subsequent dissociation from heme. Remember that gases travel from an area of higher partial pressure to an area of lower partial pressure. In addition, the affinity of an oxygen molecule for heme increases as more oxygen molecules are bound. Therefore, in the oxygen–hemoglobin saturation curve, as the partial pressure of oxygen increases, a proportionately greater number of oxygen molecules are bound by heme. Not surprisingly, the oxygen–hemoglobin saturation/dissociation curve also shows that the lower the partial pressure of oxygen, the fewer oxygen molecules are bound to heme. As a result, the partial pressure of oxygen plays a major role in determining the degree of binding of oxygen to heme at the site of the respiratory membrane, as well as the degree of dissociation of oxygen from heme at the site of body tissues.
The mechanisms behind the oxygen–hemoglobin saturation/dissociation curve also serve as automatic control mechanisms that regulate how much oxygen is delivered to different tissues throughout the body. This is important because some tissues have a higher metabolic rate than others. Highly active tissues, such as muscle, rapidly use oxygen to produce ATP, lowering the partial pressure of oxygen in the tissue to about 20 mm Hg. The partial pressure of oxygen inside capillaries is about 100 mm Hg, so the difference between the two becomes quite high, about 80 mm Hg. As a result, a greater number of oxygen molecules dissociate from hemoglobin and enter the tissues. The reverse is true of tissues, such as adipose (body fat), which have lower metabolic rates. Because less oxygen is used by these cells, the partial pressure of oxygen within such tissues remains relatively high, resulting in fewer oxygen molecules dissociating from hemoglobin and entering the tissue interstitial fluid. Although venous blood is said to be deoxygenated, some oxygen is still bound to hemoglobin in its red blood cells. This provides an oxygen reserve that can be used when tissues suddenly demand more oxygen.
Describe the effects of PO2, PCO2, pH, and temperature on hemoglobin and oxygen transport.
104 Homework 6 4. (15 points): Hemoglobin (Hb) is the main oxygen transport protein in the blood. Each hemoglobin molecule can transport four oxygen atoms at a time, one at each of its four iron-based binding sites. The binding of O2 to hemoglobin is a pH-dependent equilibrium, simplified as: Use Le Chatelier's Principle to answer the following questions: a) What form of hemoglobin, HbH" or Hb(Ojle, would be favored in the lungs? What form would be favored in the cells...
Which box the indicates the oxygen binding curve of
Hemoglobin?
po, in tissues pO2 in lungs B 12 16 8 pO2 (kPa)
PCO, (partial pressure of carbon dioxide) pO2 (partial pressure of oxygen) Hemoglobin - O, saturation [HCM] 40 mm Hg 90 - 100 mm Hg 94 - 100% 24 meq/liter Case study 1: A 14-year-old girl with cystic fibrosis has complained of an increased cough productive of green sputum over the last week. She also complained of being increasingly short of breath, and has sounds in her lungs on physical examination. Arterial blood was drawn and sampled, revealing the following values:...
The Bohr effect describes the tendency for hemoglobin to more readily unload oxygen under which conditions? a. increased pH and decreased Pco2 b. decreased pH and increased Pco2 c. decreased pH and Pco2 d. increased pH and Pco2
2. What fraction of oxygen bound in the lungs is released in peripheral tissues for each hemoglobin? Which hemoglobin is better at transporting oxygen? Assume that the lung pO2 = 100 torr and that the peripheral tissue pO2 is 20 torr. Based on the shape of the saturation curve shown above, describe the effect of the Asp99Asn substitution on the cooperativity of oxygen binding? Is the cooperatively positively or negatively impacted by this mutation? 3. 4. In normal deoxyhemoglobin (hemoglobin...
Which of the following statement(s) is/are TRUE regarding the binding of oxygen to hemoglobin? A. The pH difference between the lungs and the surrounding tissues that decreases efficiency in oxygen transport is known as the Bohr effect. B. 100% of CO2 is transported by formation of a carbamate bond with the amino terminal residues in the hemoglobin chains. C. 2,3-Bisphosphoglycerate stabilizes the T state. D. All of the statements are true.
Define partial pressure. What is the partial pressure of oxygen (PO2) in the outside air, in the alveoli, in the pulmonary vein, and after the tissue (i.e. muscle)? What is the cause of the drop on PO2 at each of these places? What is the partial pressure of CO2 (PCO2) in the arterial blood after an exhalation and then after the muscles? What causes the PCO2 to go up from the lungs to after the muscles?
Hemoglobin is the oxygen transport protein in the red blood cells of all vertebrates. It's emperical formula is C738H1166N203O208S2Fe. It's molecular mass is 65332.91 amu, what is the molecular formula of hemoglobin? How do I solve this problem?
Draw on a single set of axes the oxygen binding curves (i.e. YO2 vs. pO2) for a Hemoglobin with typical oxygen affinity and for bar-headed goose Hemoglobin. Include a detailed legend that provides enough information .
Why do we need hemoglobin to transport oxygen in the bloodstream, but no protein is required to transport carbon dioxide in the blood from the tissues to the lungs? A. carbon dioxide is hydrophilic, and can interact with water molecules in the blood, but oxygen cannot B. the bonds in carbon dioxide are nonpolar covalent bonds, but the bonds in oxygen are polar bonds C. carbon dioxide is surrounded by a shell of sodium ions in the bloodstream, but oxygen...