“Chloride shift”的意思、由来-开放百科全书

Carbon dioxide (CO₂) is produced in tissues as a byproduct of normal metabolism. It dissolves in the solution of blood plasma and into red blood cells (RBC), where carbonic anhydrase catalyzes its hydration to carbonic acid (H₂CO₃). Carbonic acid then spontaneously dissociates to form bicarbonate Ions (HCO₃⁻) and a hydrogen ion (H⁺). In response to the decrease in intracellular pCO₂, more CO₂ passively diffuses into the cell.

Cell membranes are generally impermeable to charged ions (i.e. H⁺, HCO₃⁻ ) but RBCs are able to exchange bicarbonate for chloride using the anion exchanger protein Band 3. Thus, the rise in intracellular bicarbonate leads to bicarbonate export and chloride intake. The term "chloride shift" refers to this exchange. Consequently, chloride concentration is lower in systemic venous blood than in systemic arterial blood: high venous pCO₂ leads to bicarbonate production in RBCs, which then leaves the RBC in exchange for chloride coming in.^[2]

The opposite process occurs in the pulmonary capillaries of the lungs when the PO₂ rises and PCO₂ falls, and the Haldane effect occurs (release of CO₂ from hemoglobin during oxygenation). This releases hydrogen ions from hemoglobin, increases free H⁺ concentration within RBCs, and shifts the equilibrium towards CO₂ and water formation from bicarbonate. The subsequent decrease in intracellular bicarbonate concentration reverses chloride-bicarbonate exchange: bicarbonate moves into the cell in exchange for chloride moving out. Inward movement of bicarbonate via the Band 3 exchanger allows carbonic anhydrase to convert it to CO₂ for expiration.^[3]

The chloride shift may also regulate the affinity of hemoglobin for oxygen through the chloride ion acting as an allosteric effector.^[4]

Reaction

Bicarbonate in the red blood cell (RBC) exchanging with chloride from plasma in the lungs.

The underlying properties creating the chloride shift are the presence of carbonic anhydrase within the RBCs but not the plasma, and the permeability of the RBC membrane to carbon dioxide and bicarbonate ion but not to hydrogen ion. Continuous process of carbonic acid dissociation and outflow of bicarbonate ions would eventually lead to a change of intracellular electric potential because of lasting H+ ions. Inflow of chloride ions maintains electrical neutrality of a cell. The net direction of bicarbonate-chloride exchange (bicarbonate out of RBCs in the systemic capillaries, bicarbonate into RBCs at pulmonary capillaries) proceeds in the direction that decreases the sum of the electrochemical potentials for the chloride and bicarbonate ions being transported.

References

1. ^{{cite journal |vauthors=Crandall ED, Mathew SJ, Fleischer RS, Winter HI, Bidani A |title=Effects of inhibition of RBC HCO₃⁻/Cl⁻ exchange on CO2 excretion and downstream pH disequilibrium in isolated rat lungs |journal=J. Clin. Invest. |volume=68 |issue=4 |pages=853–62 |year=1981 |pmid=6793631 |doi=10.1172/JCI110340 |pmc=370872}}
2. ^{{cite journal|year=2003|title=A reexamination of the mechanisms underlying the arteriovenous chloride shift|journal=Physiol. Biochem. Zool.|volume=76|issue=5|pages=603–14|doi=10.1086/380208|pmid=14671708|vauthors=Westen EA, Prange HD}}
3. ^{{cite journal |vauthors=Westen EA, Prange HD |title=A reexamination of the mechanisms underlying the arteriovenous chloride shift |journal=Physiol. Biochem. Zool. |volume=76 |issue=5 |pages=603–14 |year=2003 |pmid=14671708 |doi=10.1086/380208}}
4. ^{{cite journal |vauthors=Nigen AM, Manning JM, Alben JO |title=Oxygen-linked binding sites for inorganic anions to hemoglobin |journal=J. Biol. Chem. |volume=255 |issue=12 |pages=5525–9 |date=25 June 1980|pmid=7380825 |url=http://www.jbc.org/cgi/reprint/255/12/5525 }}

Mechanism

Reaction

References