The Electrogenic Sodium Bicarbonate Cotransporter NBCe1 as a Conduit for CO2

Abstract

The established role of NBCe1‐A (SLC4A4) is to cotransport Na+ and HCO3− (or more likely, CO3=). We present evidence that NBCe1‐A also conducts CO2. We record the ionic current carried by NBCe1‐A (INBC)—a direct measure of cotransport activity, while simultaneously assessing the CO3= and CO2 traffic through NBCe1‐A from maximal rates of intracellular pH (pHi) changes, (dpHi/dt)max. We employ a continuous‐flow, rapid‐mixing approach for generating out‐of‐equilibrium (OOE) CO2/HCO3− solutions to control [CO2], [HCO3−], and extracellular pH (pHo) individually in the bath. Exposing Xenopus oocytes expressing NBCe1‐A to a pure‐HCO3− (0% CO2/33 mM HCO3−) OOE solution at pHo 7.5 causes pHi to rise +(dpHi/dt)max, moderately fast due to electrogenic Na+/CO3= uptake. Exposing NBCe1‐A expressing oocytes to a pure‐CO2 (5% CO2/0 mM HCO3−) OOE solution causes pHi to fall, −(dpHi/dt)max, rapidly as CO2 enters. Computer simulations predict that in a pHo 7.5‐equilibrated 5% CO2/33 mM HCO3− solution (EQ), the pHi in NBCe1‐A oocytes should fall at a rate approximately halfway between that of the pure‐HCO3− and pure‐CO2 OOE conditions. However, experiments show that the pHi of EQ‐exposed NBCe1‐A oocytes falls more rapidly than predicted in the simulations. Importantly, the INBC associated with the 5% CO2/33 mM HCO3− condition at pHo 7.5 is virtually identical to the INBC during the pure‐HCO3− condition. To increase [CO3=]o by ~30‐fold and accelerate NBCe1‐A, we raised pHo to 9.0. In pure‐HCO3−/pHo 9.0, pHi rises twice as fast as recorded at pHo 7.5. In pure‐CO2/pHo 9.0, pHi falls, though not as rapidly as it rises in pure‐HCO3−/pHo 9.0. Thus, we expected pHi to rise in a 5% CO2/33 mM HCO3−/pHo 9.0 OOE solution (i.e., follow midpoint between pure‐HCO3− and pure‐CO2). However, our data show that pHi falls with a magnitude almost identical to that for pure‐CO2/pHo 9.0, even though the magnitude of the concurrent INBC in both pure‐HCO3− and 5% CO2/33 mM HCO3−/pHo 9.0 is twice those at pHo 7.5. In contrast, experiments performed on oocytes expressing AE1 show that (dpHi/dt)max values in the EQ solution approximately equal the sum of (dpHi/dt)max rates in pure‐HCO3− and pure‐CO2 OOE conditions. A trivial explanation for our data would be carbonic anhydrase (CA) activity caused by expression of NBCe1‐A. However, a stopped‐flow assay for CA activity developed in our Lab shows that this is not the case. We propose that a simple explanation for our data is that when NBCe1‐A is transporting Na+ + CO3=, it also acts as a new class of CO2 channel—the first that does not have a permanent pore. We speculate that conformational changes integral to Na+ + CO3= transport, create transient pathways within the NBCe1 molecule that allow CO2 to pass from the extra‐ to the intracellular fluid.

Document Details

Document Type

Pub Defense Publication

Publication Date

Apr 01, 2019

Source ID

10.1096/fasebj.2019.33.1_supplement.544.3

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