pH-Regulated Nonelectrogenic Anion Transport by Phenylthiosemicarbazones
Citations Over TimeTop 10% of 2016 papers
Abstract
Gated ion transport across biological membranes is an intrinsic process regulated by protein channels. Synthetic anion carriers (anionophores) have potential applications in biological research; however, previously reported examples are mostly nonspecific, capable of mediating both electrogenic and electroneutral (nonelectrogenic) transport processes. Here we show the transmembrane Cl(-) transport studies of synthetic phenylthiosemicarbazones mimicking the function of acid-sensing (proton-gated) ion channels. These anionophores have remarkable pH-switchable transport properties with up to 640-fold increase in transport efficacy on going from pH 7.2 to 4.0. This "gated" process is triggered by protonation of the imino nitrogen and concomitant conformational change of the anion-binding thiourea moiety from anti to syn. By using a combination of two cationophore-coupled transport assays, with either monensin or valinomycin, we have elucidated the fundamental transport mechanism of phenylthiosemicarbazones which is shown to be nonelectrogenic, inseparable H(+)/Cl(-) cotransport. This study demonstrates the first examples of pH-switchable nonelectrogenic anion transporters.
Related Papers
- → Studies on chemical modification of monensin VIII. Synthesis of 7-O-substituted-25-carboxymonensins and their Ca2+ ion transport activity(2001)11 cited
- → Ornithine/phosphate antiport in rat kidney mitochondria(1990)24 cited
- → Valinomycin-induced cation transport in vesicles does not reflect the activity of K+ transport systems in Escherichia coli(1986)10 cited
- → Mechanisms of Passive Potassium Influx in Corn Mitochondria(1981)8 cited
- → Na+-H+ antiport and monensin effects on cytosolic pH and iodide transport in FRTL-5 rat thyroid cells(1992)8 cited