An affordable Three-Dimensional (3D) Printed Recording Chamber for Two-Electrode Voltage Clamp Electrophysiology.

Two electrode voltage-clamp (TEVC) electrophysiology in Xenopus oocytes is a common approach to studying the physiology and pharmacology of membrane transport proteins. Undergraduates may learn to use TEVC methodology in neuroscience or physiology courses and/or in faculty-mentored research experiences. Challenges with the methodology include the cost of commercially available recording chambers, especially when a lab needs multiple copies, and the additional time and expertise needed to use agar bridges and to stabilize solution flow and minimize noise from solution aspiration. Offering a low-cost and accessible recording chamber that overcomes these challenges would lower the barriers to success for undergraduates while also supporting publication-quality recordings. To address these issues, we developed a recording chamber using stereolithography, a 3D printing process. The physiology (PhISio) recording chamber features two options for solution aspiration that allow for individual preferences, optimizes placement of pre-made agar bridges to achieve laminar flow and reduce the time delays in initiating daily experiments, and minimizes the challenges of changing solution height and aspiration noise during perfusion. We compared the functionality of the PhISio chamber with a commercially available Warner Instruments RC-1Z chamber in electrophysiological recordings of inwardly rectifying potassium channels expressed in Xenopus oocytes. The PhISio chamber produced equivalent results to the RC-1Z chamber with respect to time-dependent solution changes and has several operational advantages for both new and experienced electrophysiologists, providing an affordable and convenient alternative to commercially available TEVC recording chambers.

Membrane Proteins Mediating Reception and Transduction in Chemosensory Neurons in Mosquitoes.

Mosquitoes use chemical cues to modulate important behaviors such as feeding, mating, and egg laying. The primary chemosensory organs comprising the paired antennae, maxillary palps and labial palps are adorned with porous sensilla that house primary sensory neurons. Dendrites of these neurons provide an interface between the chemical environment and higher order neuronal processing. Diverse proteins located on outer membranes interact with chemicals, ions, and soluble proteins outside the cell and within the lumen of sensilla. Here, we review the repertoire of chemosensory receptors and other membrane proteins involved in transduction and discuss the outlook for their functional characterization. We also provide a brief overview of select ion channels, their role in mammalian taste, and potential involvement in mosquito taste. These chemosensory proteins represent targets for the disruption of harmful biting behavior and disease transmission by mosquito vectors.

A Xenopus oocyte model system to study action potentials.

Action potentials (APs) are the functional units of fast electrical signaling in excitable cells. The upstroke and downstroke of an AP is generated by the competing and asynchronous action of Na+- and K+-selective voltage-gated conductances. Although a mixture of voltage-gated channels has been long recognized to contribute to the generation and temporal characteristics of the AP, understanding how each of these proteins function and are regulated during electrical signaling remains the subject of intense research. AP properties vary among different cellular types because of the expression diversity, subcellular location, and modulation of ion channels. These complexities, in addition to the functional coupling of these proteins by membrane potential, make it challenging to understand the roles of different channels in initiating and "temporally shaping" the AP. Here, to address this problem, we focus our efforts on finding conditions that allow reliable AP recordings from Xenopus laevis oocytes coexpressing Na+ and K+ channels. As a proof of principle, we show how the expression of a variety of K+ channel subtypes can modulate excitability in this minimal model system. This approach raises the prospect of studies on the modulation of APs by pharmacological or biological means with a controlled background of Na+ and K+ channel expression.

Mutations in Nature Conferred a High Affinity Phosphatidylinositol 4,5-Bisphosphate-binding Site in Vertebrate Inwardly Rectifying Potassium Channels.

All vertebrate inwardly rectifying potassium (Kir) channels are activated by phosphatidylinositol 4,5-bisphosphate (PIP2) (Logothetis, D. E., Petrou, V. I., Zhang, M., Mahajan, R., Meng, X. Y., Adney, S. K., Cui, M., and Baki, L. (2015) Annu. Rev. Physiol. 77, 81-104; Fürst, O., Mondou, B., and D'Avanzo, N. (2014) Front. Physiol. 4, 404-404). Structural components of a PIP2-binding site are conserved in vertebrate Kir channels but not in distantly related animals such as sponges and sea anemones. To expand our understanding of the structure-function relationships of PIP2 regulation of Kir channels, we studied AqKir, which was cloned from the marine sponge Amphimedon queenslandica, an animal that represents the phylogenetically oldest metazoans. A requirement for PIP2 in the maintenance of AqKir activity was examined in intact oocytes by activation of a co-expressed voltage-sensing phosphatase, application of wortmannin (at micromolar concentrations), and activation of a co-expressed muscarinic acetylcholine receptor. All three mechanisms to reduce the availability of PIP2 resulted in inhibition of AqKir current. However, time-dependent rundown of AqKir currents in inside-out patches could not be re-activated by direct application to the inside membrane surface of water-soluble dioctanoyl PIP2, and the current was incompletely re-activated by the more hydrophobic arachidonyl stearyl PIP2. When we introduced mutations to AqKir to restore two positive charges within the vertebrate PIP2-binding site, both forms of PIP2 strongly re-activated the mutant sponge channels in inside-out patches. Molecular dynamics simulations validate the additional hydrogen bonding potential of the sponge channel mutants. Thus, nature's mutations conferred a high affinity activation of vertebrate Kir channels by PIP2, and this is a more recent evolutionary development than the structures that explain ion channel selectivity and inward rectification.

Divalent cations modulate TMEM16A calcium-activated chloride channels by a common mechanism.

The gating of Ca²âº-activated Cl⁻ channels is controlled by a complex interplay among [Ca²âº](i), membrane potential and permeant anions. Besides Ca²âº, Ba²âº also can activate both TMEM16A and TMEM16B. This study reports the effects of several divalent cations as regulators of TMEM16A channels stably expressed in HEK293T cells. Among the divalent cations that activate TMEM16A, Ca²âº is most effective, followed by Sr²âº and Ni²âº, which have similar affinity, while Mg²âº is ineffective. Zn²âº does not activate TMEM16A but inhibits the Ca²âº-activated chloride currents. Maximally effective concentrations of Sr²âº and Ni²âº occluded activation of the TMEM16A current by Ca²âº, which suggests that Ca²âº, Sr²âº and Ni²âº all regulate the channel by the same mechanism.

Homology model and targeted mutagenesis identify critical residues for arachidonic acid inhibition of Kv4 channels.

Polyunsaturated fatty acids such as arachidonic acid (AA) exhibit inhibitory modulation of Kv4 potassium channels. Molecular docking approaches using a Kv4.2 homology model predicted a membrane-embedded binding pocket for AA comprised of the S4-S5 linker on one subunit and several hydrophobic residues within S3, S5 and S6 from an adjacent subunit. The pocket is conserved among Kv4 channels. We tested the hypothesis that modulatory effects of AA on Kv4.2/KChIP channels require access to this site. Targeted mutation of a polar residue (K318) and a nonpolar residue (G314) within the S4-S5 linker as well as a nonpolar residue in S3 (V261) significantly impaired the effects of AA on K (+) currents in Xenopus oocytes. These residues may be important in stabilizing (K318) or regulating access to (V261, G314) the negatively charged carboxylate moiety on the fatty acid. Structural specificity was supported by the lack of disruption of AA effects observed with mutations at residues located near, but not within the predicted binding pocket. Furthermore, we found that the crystal structure of the related Kv1.2/2.1 chimera lacks the structural features present in the proposed AA docking site of Kv4.2 and the Kv1.2/2.1 K (+) currents were unaffected by AA. We simulated the mutagenic substitutions in our Kv4.2 model to demonstrate how specific mutations may disrupt the putative AA binding pocket. We conclude that AA inhibits Kv4 channel currents and facilitates current decay by binding within a hydrophobic pocket in the channel in which K318 within the S4-S5 linker is a critical residue for AA interaction.

A unique alkaline pH-regulated and fatty acid-activated tandem pore domain potassium channel (K2P) from a marine sponge.

A cDNA encoding a potassium channel of the two-pore domain family (K(2P), KCNK) of leak channels was cloned from the marine sponge Amphimedon queenslandica. Phylogenetic analysis indicated that AquK(2P) cannot be placed into any of the established functional groups of mammalian K(2P) channels. We used the Xenopus oocyte expression system, a two-electrode voltage clamp and inside-out patch clamp electrophysiology to determine the physiological properties of AquK(2P). In whole cells, non-inactivating, voltage-independent, outwardly rectifying K(+) currents were generated by external application of micromolar concentrations of arachidonic acid (AA; EC(50) ∼30 µmol l(-1)), when applied in an alkaline solution (≥pH 8.0). Prior activation of channels facilitated the pH-regulated, AA-dependent activation of AquK(2P) but external pH changes alone did not activate the channels. Unlike certain mammalian fatty-acid-activated K(2P) channels, the sponge K(2P) channel was not activated by temperature and was insensitive to osmotically induced membrane distortion. In inside-out patch recordings, alkalinization of the internal pH (pK(a) 8.18) activated the AquK(2P) channels independently of AA and also facilitated activation by internally applied AA. The gating of the sponge K(2P) channel suggests that voltage-independent outward rectification and sensitivity to pH and AA are ancient and fundamental properties of animal K(2P) channels. In addition, the membrane potential of some poriferan cells may be dynamically regulated by pH and AA.

Inhibitory effects of polyunsaturated fatty acids on Kv4/KChIP potassium channels.

Kv4/K channel interacting protein (KChIP) potassium channels are a major class of rapidly inactivating K(+) channels in neurons and cardiac muscle. Modulation of Kv4/KChIP channels by polyunsaturated fatty acids (PUFAs) is important in the regulation of cellular excitability and the induction of activity-dependent synaptic plasticity. Using the Xenopus laevis oocyte expression system, we studied the inhibition by PUFAs of the peak outward K(+) current and the accompanying increase in the rate of current inactivation of rKv4.2/rKChIP1b. Inhibitory effects do not depend on KChIP coexpression since Kv4.2 channels lacking an NH(2)-terminal KChIP association region were substantially inhibited by PUFAs and showed strong kinetic modulation. PUFAs accelerated both the fast and slow time constants that describe the kinetics of Kv4/KChIP inactivation. The time course of entry into closed inactivated states was facilitated by PUFAs, but steady-state inactivation and recovery from inactivation were unaltered. PUFA inhibition of Kv4/KChIP current was not use dependent. The concentration-response relationship for arachidonic acid (AA) inhibition of Kv4/KChIP channels mimicked that for activation of TRAAK channels. Internal serum albumin largely prevents the inhibitory effects of externally applied AA, and the membrane-impermeant AA-CoA is inactive when applied externally. Overall, our data suggest that PUFAs inhibit Kv4/KChIP channels by facilitating inactivation from open and closed gating states and that access of the fatty acid to the internal leaflet of the membrane is important. These results improve our understanding of the mechanisms for the inhibitory effects of PUFAs on Kv4/KChIP channel function.

Expression of a poriferan potassium channel: insights into the evolution of ion channels in metazoans.

Ion channels establish and regulate membrane potentials in excitable and non-excitable cells. How functional diversification of ion channels contributed to the evolution of nervous systems may be understood by studying organisms at key positions in the evolution of animal multicellularity. We have carried out the first analysis of ion channels cloned from a marine sponge, Amphimedon queenslandica. Phylogenetic comparison of sequences encoding for poriferan inward-rectifier K(+) (Kir) channels suggests that Kir channels from sponges, cnidarians and triploblastic metazoans each arose from a single channel and that duplications arose independently in the different groups. In Xenopus oocytes, AmqKirA and AmqKirB produced K(+) currents with strong inward rectification, as seen in the mammalian Kir2 channels, which are found in excitable cells. The pore properties of AmqKir channels demonstrated strong K(+) selectivity and block by Cs(+) and Ba(2+). We present an original analysis of sponge ion channel physiology and an examination of the phylogenetic relationships of this channel with other cloned Kir channels.

Polyunsaturated fatty acid modulation of voltage-gated ion channels.

Arachidonic acid (AA) was found to inhibit the function of whole-cell voltage-gated (VG) calcium currents nearly 16 years ago. There are now numerous examples demonstrating that AA and other polyunsaturated fatty acids (PUFAs) modulate the function of VG ion channels, primarily in neurons and muscle cells. We will review and extract some common features about the modulation by PUFAs of VG calcium, sodium, and potassium channels and discuss the impact of this modulation on the excitability of neurons and cardiac myocytes. We will describe the fatty acid nature of the membrane, how fatty acids become available to function as modulators of VG channels, and the physiologic importance of this type of modulation. We will review the evidence for molecular mechanisms and assess our current understanding of the structural basis for modulation. With guidance from research on the structure of fatty acid binding proteins, the role of lipids in gating mechanosensitive (MS) channels, and the impact of membrane lipid composition on membrane-embedded proteins, we will highlight some avenues for future investigations.

Involvement of beta-site APP cleaving enzyme 1 (BACE1) in amyloid precursor protein-mediated enhancement of memory and activity-dependent synaptic plasticity.

The amyloid precursor protein (APP) undergoes sequential cleavages to generate various polypeptides, including the amyloid-beta protein (Abeta), which forms amyloid plaques in Alzheimer's disease (AD), secreted APPalpha (sAPPalpha) which enhances memory, and the APP intracellular domain (AICD), which has been implicated in the regulation of gene transcription and calcium signaling. The beta-site APP cleaving enzyme 1 (BACE1) cleaves APP in an activity-dependent manner to form Abeta, AICD, and secreted APPbeta. Because this neural activity was shown to diminish synaptic transmission in vitro [Kamenetz F, Tomita T, Hsieh H, Seabrook G, Borchelt D, Iwatsubo T, Sisodia S, Malinow R (2003) Neuron 37:925-937], the prevailing notion has been that this pathway diminishes synaptic function. Here we investigated the role of this pathway in vivo. We studied transgenic mice overproducing APP that do not develop AD pathology or memory deficits but instead exhibit enhanced spatial memory. We showed enhanced synaptic plasticity in the hippocampus that depends on prior synaptic activity. We found that the enhanced memory and synaptic plasticity are abolished by the ablation of one or both copies of the BACE1 gene, leading to a significant decrease in AICD but not of any other APP cleavage products. In contrast to the previously described negative effect of BACE1-mediated cleavage of APP on synaptic function in vitro, our in vivo work indicates that BACE1-mediated cleavage of APP can facilitate learning, memory, and synaptic plasticity.

Overexpression of CREB reduces CRE-mediated transcription: behavioral and cellular analyses in transgenic mice.

The CREB transcription factor mediates neuronal plasticity in many systems, but the relationship between CREB levels and CRE-mediated transcription in individual neurons in vivo is unclear. In FVB/N nontransgenic mice, we observed that Purkinje cells showed low basal levels of Ser(133)-phosphorylated CREB protein yet displayed strong CRE-directed transcription. Transgenic mice overexpressing CREB in Purkinje cells and dentate gyrus granule cells showed a decreased CRE-lacZ signal in the same cells, indicating repression of ATF/CREB family function. Dentate region long-term potentiation was not altered by these changes in CREB expression. CREB transgenic mice demonstrated an inability to perform the rotarod task, without signs of overt ataxia. Our results demonstrate that the level of phosphorylated CREB protein is not a reliable indicator of CRE-mediated function. Furthermore, we conclude that CRE-mediated transcription may be linked to only a subset of cerebellum-mediated motor behaviors and may not be universally required for long-lasting synaptic potentiation.

Functional properties of a brain-specific NH2-terminally spliced modulator of Kv4 channels.

Kv4/K channel-interacting protein (KChIP) potassium channels are a major class of rapidly inactivating K channels in brain and heart. Considering the importance of alternative splicing to the quantitative features of KChIP gating modulation, a previously uncharacterized splice form of KChIP1 was functionally characterized. The KChIP1b splice variant differs from the previously characterized KChIP1a splice form by the inclusion of a novel amino-terminal region that is encoded by an alternative exon that is conserved in mouse, rat, and human genes. The expression of KChIP1b mRNA was high in brain but undetectable in heart or liver by RT-PCR. In cerebellar tissue, KChIP1b and KChIP1a transcripts were expressed at nearly equal levels. Coexpression of KChIP1b or KChIP1a with Kv4.2 channels in oocytes slowed K current decay and destabilized open-inactivated channel gating. Like other KChIP subunits, KChIP1b increased Kv4.2 current amplitude and KChIP1b also shifted Kv4.2 conductance-voltage curves by -10 mV. The development of Kv4.2 channel inactivation accessed from closed gating states was faster with KChIP1b coexpression. Deletion of the novel amino-terminal region in KChIP1b selectively altered the subunit's modulation of Kv4.2 closed inactivation gating. The role of the KChIP1b NH2-terminal region was further confirmed by direct comparison of the properties of the NH2-terminal deletion mutant and the KChIP1a subunit, which is encoded by a transcript that lacks the novel exon. The features of KChIP1b modulation of Kv4 channels are likely to be conserved in mammals and demonstrate a role for the KChIP1 NH2-terminal region in the regulation of closed inactivation gating.

Altered short-term hippocampal synaptic plasticity in mutant alpha-synuclein transgenic mice.

Hippocampal synaptic plasticity was studied in transgenic mice over-expressing human alpha-synuclein containing the A30P Parkinson's disease mutation. Medial perforant path-dentate granule cell synapses showed enhanced paired-pulse depression (PPD) for short interpulse intervals (< 200 ms), without differences in basal transmission. Extracellular calcium reduction failed to rescue the enhanced PPD. Paired-pulse facilitation in the CA1 region was normal in slices from transgenic mice, but enhanced synaptic depression was revealed upon repetitive stimulation of the Schaffer collaterals. Long-term potentiation in the CA1 field was not impaired in slices from transgenic mice. These results suggest that mutant alpha-synuclein accumulation impairs short-term changes in synaptic strength when neurotransmitter availability is limited due to enhanced release probability or repetitive synaptic activity.

Computing transient gating charge movement of voltage-dependent ion channels.

The opening of voltage-gated sodium, potassium, and calcium ion channels has a steep relationship with voltage. In response to changes in the transmembrane voltage, structural movements of an ion channel that precede channel opening generate a capacitative gating current. The net gating charge displacement due to membrane depolarization is an index of the voltage sensitivity of the ion channel activation process. Understanding the molecular basis of voltage-dependent gating of ion channels requires the measurement and computation of the gating charge, Q. We derive a simple and accurate semianalytic approach to computing the voltage dependence of transient gating charge movement (Q-V relationship) of discrete Markov state models of ion channels using matrix methods. This approach allows rapid computation of Q-V curves for finite and infinite length step depolarizations and is consistent with experimentally measured transient gating charge. This computational approach was applied to Shaker potassium channel gating, including the impact of inactivating particles on potassium channel gating currents.

Interactions among toxins that inhibit N-type and P-type calcium channels.

A number of peptide toxins from venoms of spiders and cone snails are high affinity ligands for voltage-gated calcium channels and are useful tools for studying calcium channel function and structure. Using whole-cell recordings from rat sympathetic ganglion and cerebellar Purkinje neurons, we studied toxins that target neuronal N-type (Ca(V)2.2) and P-type (Ca(V)2.1) calcium channels. We asked whether different toxins targeting the same channels bind to the same or different sites on the channel. Five toxins (omega-conotoxin-GVIA, omega-conotoxin MVIIC, omega-agatoxin-IIIA, omega-grammotoxin-SIA, and omega-agatoxin-IVA) were applied in pairwise combinations to either N- or P-type channels. Differences in the characteristics of inhibition, including voltage dependence, reversal kinetics, and fractional inhibition of current, were used to detect additive or mutually occlusive effects of toxins. Results suggest at least two distinct toxin binding sites on the N-type channel and three on the P-type channel. On N-type channels, results are consistent with blockade of the channel pore by omega-CgTx-GVIA, omega-Aga-IIIA, and omega-CTx-MVIIC, whereas grammotoxin likely binds to a separate region coupled to channel gating. omega-Aga-IIIA produces partial channel block by decreasing single-channel conductance. On P-type channels, omega-CTx-MVIIC and omega-Aga-IIIA both likely bind near the mouth of the pore. omega-Aga-IVA and grammotoxin each bind to distinct regions associated with channel gating that do not overlap with the binding region of pore blockers. For both N- and P-type channels, omega-CTx-MVIIC binding produces complete channel block, but is prevented by previous partial channel block by omega-Aga-IIIA, suggesting that omega-CTx-MVIIC binds closer to the external mouth of the pore than does omega-Aga-IIIA.