AUTHOR=Higgins John A. , Ramos Danielle Santiago , Gili Stefania , Spetea Cornelia , Kanoski Scott , Ha Darren , McDonough Alicia A. , Youn Jang H. 

TITLE=Stable potassium isotopes (41K/39K) track transcellular and paracellular potassium transport in biological systems

JOURNAL=Frontiers in Physiology

VOLUME=13

YEAR=2022

URL=https://www.frontiersin.org/journals/physiology/articles/10.3389/fphys.2022.1016242

DOI=10.3389/fphys.2022.1016242

ISSN=1664-042X

ABSTRACT=<p>As the most abundant cation in archaeal, bacterial, and eukaryotic cells, potassium (K<sup>+</sup>) is an essential element for life. While much is known about the machinery of transcellular and paracellular K transport–channels, pumps, co-transporters, and tight-junction proteins—many quantitative aspects of K homeostasis in biological systems remain poorly constrained. Here we present measurements of the stable isotope ratios of potassium (<sup>41</sup>K/<sup>39</sup>K) in three biological systems (algae, fish, and mammals). When considered in the context of our current understanding of plausible mechanisms of K isotope fractionation and K<sup>+</sup> transport in these biological systems, our results provide evidence that the fractionation of K isotopes depends on transport pathway and transmembrane transport machinery. Specifically, we find that passive transport of K<sup>+</sup> down its electrochemical potential through channels and pores in tight-junctions at favors <sup>39</sup>K, a result which we attribute to a kinetic isotope effect associated with dehydration and/or size selectivity at the channel/pore entrance. In contrast, we find that transport of K<sup>+</sup> against its electrochemical gradient <italic>via</italic> pumps and co-transporters is associated with less/no isotopic fractionation, a result that we attribute to small equilibrium isotope effects that are expressed in pumps/co-transporters due to their slower turnover rate and the relatively long residence time of K<sup>+</sup> in the ion pocket. These results indicate that stable K isotopes may be able to provide quantitative constraints on transporter-specific K<sup>+</sup> fluxes (e.g., the fraction of K efflux from a tissue by channels vs. co-transporters) and how these fluxes change in different physiological states. In addition, precise determination of K isotope effects associated with K<sup>+</sup> transport <italic>via</italic> channels, pumps, and co-transporters may provide unique constraints on the mechanisms of K transport that could be tested with steered molecular dynamic simulations.</p>