Na+-coupled solute transport is crucial for the uptake of nutrients and metabolic precursors, such as myo-inositol, an important osmolyte and precursor for various cell signaling molecules. Here, we found that various solute transporters and potassium channel subunits formed complexes and reciprocally regulated each other in vitro and in vivo. Global metabolite profiling revealed that mice lacking KCNE2, a K+ channel β subunit, showed a reduction in the myo-inositol concentration in cerebrospinal fluid (CSF) but not in serum. Increased behavorial responsiveness to stress and seizure susceptibility in Kcne2−/− mice were alleviated by injections of myo-inositol. Suspecting a defect in myo-inositol transport, we found that KCNE2 and KCNQ1, a voltage-gated potassium channel α subunit, colocalized and coimmunoprecipitated with SMIT1, a Na+-coupled myo-inositol transporter, in the choroid plexus epithelium. Heterologous coexpression demonstrated that myo-inositol transport by SMIT1 was augmented by coexpression of KCNQ1 but inhibited by coexpression of both KCNQ1 and KCNE2, which form a constitutively active, heteromeric K+ channel. SMIT1 and the related transporter SMIT2 were also inhibited by a constitutively active mutant form of KCNQ1. The activity of KCNQ1 and KCNQ1-KCNE2 were augmented by SMIT1 and the glucose transporter SGLT1, but suppressed by SMIT2. Channel-transporter signaling complexes may be a widespread mechanism to facilitate solute transport and electrochemical crosstalk.
Voltage-gated potassium channels of the KCNQ (Kv7) subfamily are essential for control of cellular excitability and repolarization in a wide range of cell types. Recently, we and others found that some KCNQ channels functionally and physically interact with sodium-dependent solute transporters, including myo-inositol transporters SMIT1 and SMIT2, potentially facilitating various modes of channel-transporter signal integration. In contrast to indirect effects such as channel regulation by SMIT-transported, myo-inositol-derived phosphatidylinositol 4,5-bisphosphate (PIP), the mechanisms and functional consequences of the physical interaction of channels with transporters have been little studied. Here, using co-immunoprecipitation with different channel domains, we found that SMIT1 binds to the KCNQ2 pore module. We next tested the effects of SMIT1 co-expression, in the absence of extracellular myo-inositol or other SMIT1 substrates, on fundamental functional attributes of KCNQ2, KCNQ2/3, KCNQ1, and KCNQ1-KCNE1 channels. Without exception, SMIT1 altered KCNQ ion selectivity, sensitivity to extracellular K, and pharmacology, consistent with an impact on conformation of the KCNQ pore. SMIT1 also altered the gating kinetics and/or voltage dependence of KCNQ2, KCNQ2/3, and KCNQ1-KCNE1. In contrast, SMIT1 had no effect on Kv1.1 (KCNA1) gating, ion selectivity, or pharmacology. We conclude that, independent of its transport activity and indirect regulatory mechanisms involving inositol-derived increases in PIP, SMIT1, and likely other related sodium-dependent solute transporters, regulates KCNQ channel ion selectivity, gating, and pharmacology by direct physical interaction with the pore module.
Voltage-gated potassium channels formed by KCNQ2 and KCNQ3 are essential for normal neuronal excitability. KCNQ2/3 channel activity is augmented by phosphatidylinositol 4,5-bisphosphate (PIP), which is generated from -inositol, an osmolyte transported into cells by sodium-dependent-inositol transporters (SMITs). Here, we discovered that KCNQ2/3 channels isoform-specifically colocalize with SMIT1 and SMIT2 at sciatic nerve nodes of Ranvier and in axon initial segments, and form channel-transporter complexes and KCNQ2/3 coexpression protected SMIT1 activity from the otherwise inhibitory effects of cellular depolarization imposed by elevating extracellular [K], and KCNQ2 was required for potentiation of SMIT activity by -inositol preincubation. Cytoskeletal disruption, which speeds PIP dispersion, attenuated potentiation of KCNQ2/3 currents by SMIT1-mediated -inositol uptake, suggesting close channel-transporter juxtaposition ensures KCNQ2/3 exposure to locally high-inositol-derived PIP concentrations. Thus, KCNQ2/3-SMIT1/2 coassembly permits cross talk physical interaction, and may also be required for optimal, reciprocal indirect regulation membrane potential and PIP, especially within the specialized architecture of axons.-Neverisky, D. L., Abbott, G. W. KCNQ-SMIT complex formation facilitates ion channel-solute transporter cross talk.
All living cells require membrane proteins that act as conduits for the regulated transport of ions, solutes and other small molecules across the cell membrane. Ion channels provide a pore that permits often rapid, highly selective, and tightly regulated movement of ions down their electrochemical gradient. In contrast, active transporters can move moieties up their electrochemical gradient. The secondary active transporters (such as SLC superfamily solute transporters) achieve this by coupling uphill movement of the substrate to downhill movement of another ion, such as sodium. The primary active transporters (including H+/K+-ATPases and Na+/K+-ATPases) utilize ATP hydrolysis as an energy source to power uphill transport. It is well known that proteins in each of these classes work in concert with members of the other classes to ensure, for example, ion homeostasis, ion secretion, and restoration of ion balance following action potentials. More recently, evidence is emerging of direct physical interaction between true ion channels, and some primary or secondary active transporters. Here, we review the first known members of this new class of macromolecular complexes that we term “chansporters”, explore their biological roles, and discuss the pathophysiological consequences of their disruption. We compare functional and/or physical interactions between the ubiquitous KCNQ1 potassium channel and various active transporters, and examine other newly discovered chansporter complexes that suggest we may be seeing the tip of the iceberg in a newly emerging signaling modality.
The KCNQ1 voltage-gated potassium channel is essential for human ventricular repolarization, permitting potassium efflux from excited cardiomyocytes to end each action potential and repolarize the heart. In cardiomyocytes, KCNQ1 is modulated by interaction with beta-subunits from the KCNE gene family, each of which significantly alters KCNQ1 channel function. KCNQ1 mutations are the most common identified genetic basis for Long QT syndrome (LQTS) and are also associated with lone atrial fibrillation (AF). The sodium-dependent myo-inositol transporter 1 (SMIT1) mediates cellular uptake of myo-inositol, an essential osmolyte that also represents an important substrate for phosphatidylinositol signaling pathways that regulate a plethora of ion channels including those essential for human cardiac function. We recently discovered that KCNQ1 can form heteromeric, co-regulatory complexes with Na+-coupled solute transporters including SMIT1, SMIT2 and glucose transporter SGLT1. These findings represent the first reported example of formation of an ion channel-solute transporter complex. Having discovered KCNQ1-SMIT1 complexes in mouse choroid plexus epithelium, we are currently investigating whether these types of complexes occur in the heart, how their function is altered by the various cardiac-expressed KCNE regulatory subunits or by arrhythmia-associated mutations, and which parts of KCNQ1 coordinate complex formation. Here, we present evidence of KCNQ1-SMIT1 co-assembly in pig heart based on co-immunoprecipitation experiments. Using KCNQ1-KCNQ4 chimeras we also begin to define which specific regions of KCNQ1 are required for complex formation with SMIT1. Finally, we present data showing the effects of SMIT1 on complexes formed by KCNQ1 and KCNE1, 2 and 3. KCNQ1-transporter complexes provide a potential hub for electrochemical crosstalk in normal cardiac function and in arrhythmogenesis.
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