RNA editing in eag potassium channels: Biophysical consequences of editing a conserved S6 residue

RNA editing at four sites in eag, a Drosophila voltage-gated potassium channel, results in the substitution of amino acids into the final protein product that are not encoded by the genome. These sites and the editing alterations introduced are K467R (Site 1, top of the S6 segment), Y548C, N567D and K699R (sites 2–4, within the cytoplasmic C-terminal domain). We mutated these residues individually and expressed the channels in Xenopus oocytes. A fully edited construct (all four sites) has the slowest activation kinetics and a paucity of inactivation, whereas the fully unedited channel exhibits the fastest activation and most dramatic inactivation. Editing Site 1 inhibits steady-state inactivation. Mutating Site 1 to the neutral residues resulted in intermediate inactivation phenotypes and a leftward shift of the peak current-voltage relationship. Activation kinetics display a Cole-Moore shift that is enhanced by RNA editing. Normalized open probability relationships for 467Q, 467R and 467K are superimposable, indicating little effect of the mutations on steady-state activation. 467Q and 467R enhance instantaneous inward rectification, indicating a role of this residue in ion permeation. Intracellular tetrabutylammonium blocks 467K significantly better than 467R. Block by intracellular, but not extracellular, tetraethylammonium interferes with inactivation. The fraction of inactivated current is reduced at higher extracellular Mg⁺² concentrations, and channels edited at Site 1 are more sensitive to changes in extracellular Mg⁺² than unedited channels. These results show that even a minor change in amino acid side-chain chemistry and size can have a dramatic impact on channel biophysics, and that RNA editing is important for fine-tuning the channel’s function.     

Regulation of ion channel/neurotransmitter receptor function by RNA editing

RNA editing by select adenosine deamination (A-to-I editing) alters functional determinants in certain ion channels and neurotransmitter receptors in vertebrates and invertebrates. In most cases, edited and unedited versions of a given receptor/channel co-exist to expand the functional space of the receptor population. Recent studies have characterized K(+) channels in squid that are edited at multiple positions, revealed a role for Q/R site editing in AMPA receptor assembly, and demonstrated a link between serotonin levels and the extent of editing of a mammalian serotonin receptor.     

Characterization of Five RNA Editing Sites in Shab Potassium Channels

RNA editing revises the genetic code at precise locations, creating single base changes in mRNA. These changes can result in altered coding potential and modifications to protein function. Sequence analysis of the Shab potassium channel of Drosophila melanogaster revealed five such RNA editing sites. Four are constitutively edited (I583V, T643A, Y660C and I681V) and one undergoes developmentally regulated editing (T671A). These sites are located in the S4, S5-S6 loop and the S6 segments of the channel. We examined the biophysical consequences of editing at these sites by creating point mutations, each containing the genomic (unedited) base at one of the five sites in the background of a channel in which all other sites are edited. We also created a completely unedited construct. The function of these constructs was characterized using two-microelectrode voltage clamp in Xenopus oocytes. Each individual 'unediting' mutation slowed the time course of deactivation and the rise time during channel activation. Two of the mutants exhibited significant hyperpolarized shifts in their midpoints of activation. Constructs that deactivated slowly also inactivated slowly, supporting a mechanism of closed-state inactivation. One of the editing sites, position 660, aligns with the Shaker 449 residue, which is known to be important in tetraethylammonium (TEA) block. The aromatic, genomically-encoded residue tyrosine at this position in Shab enhances TEA block 14 fold compared to the edited residue, cysteine. These results show that both the position of the RNA editing site and the identity of the substituted amino acid are important for channel function.     

Characterization of five RNA editing sites in Shab potassium channels

RNA editing revises the genetic code at precise locations, creating single base changes in mRNA. These changes can result in altered coding potential and modifications to protein function. Sequence analysis of the Shab potassium channel of Drosophila melanogaster revealed five such RNA editing sites. Four are constitutively edited (I583V, T643A, Y660C and I681V) and one undergoes developmentally regulated editing (T671A). These sites are located in the S4, S5-S6 loop and the S6 segments of the channel. We examined the biophysical consequences of editing at these sites by creating point mutations, each containing the genomic (unedited) base at one of the five sites in the background of a channel in which all other sites are edited. We also created a completely unedited construct. The function of these constructs was characterized using two-microelectrode voltage clamp in Xenopus oocytes. Each individual 'unediting' mutation slowed the time course of deactivation and the rise time during channel activation. Two of the mutants exhibited significant hyperpolarized shifts in their midpoints of activation. Constructs that deactivated slowly also inactivated slowly, supporting a mechanism of closed-state inactivation. One of the editing sites, position 660, aligns with the Shaker 449 residue, which is known to be important in tetraethylammonium (TEA) block. The aromatic, genomically-encoded residue tyrosine at this position in Shab enhances TEA block 14 fold compared to the edited residue, cysteine. These results show that both the position of the RNA editing site and the identity of the substituted amino acid are important for channel function.     

Divalent cations as probes for structure-function relationships of cloned voltage-dependent sodium channels

1. Several cloned sodium channels were expressed in oocytes and compared with respect to their sensitivity to internal Mg²⁺ concerning the open-channel block and to external Ca²⁺ concerning open-channel block and shifts in steady-state activation. 2. A quantitative comparison between wild-type II channels and a mutant with a positive charge in the S4 segment of repeat I neutralized (K226Q) revealed no significant differences in the Mg²⁺ block. 3. The blocking effect of extracellular Ca²⁺ ions on single-channel inward currents was studied for type II, mutant K226Q and type III. A quantitative comparison showed that all three channel types differ significantly in their Ca⁺ sensitivity. 4. The influence of extracellular Ca²⁺ on the voltage dependence of steady-state activation of macroscopic currents was compared for type II and K226Q channels. Extracellular Ca⁺ increases the voltage of half-maximal activation, V_1/2, more for K226Q than for wild-type II channels; a plot of V _1/2 against [Ca] _o , is twice as steep for the mutant K226Q as for the wild-type on a logarithmic concentration scale. 5. The differential effects of extracellular Ca⁺ and intracellular Mg²⁺ on wild-type II and K226Q channels are discussed in terms of structural models of the Na⁺ channel protein.Abbreviations [Na] _i intracellular Na⁺ concentration - [Mg] intracellular Mg²⁺ concentration - [Ca] _o extracellular Ca²⁺ concentration     

Control of human potassium channel inactivation by editing of a small mRNA hairpin

Genomic recoding by A-->I RNA editing plays an important role in diversifying the proteins involved in electrical excitability. Here, we describe editing of an intronless potassium channel gene. A small region of human K(V)1.1 mRNA sequence directs efficient modification of one adenosine by human adenosine deaminase acting on RNA 2 (hADAR2). Mutational analysis shows that this region adopts a hairpin structure. Electrophysiological characterization reveals that the editing event (I/V) profoundly affects channel inactivation conferred by accessory beta subunits. Drosophila melanogaster Shaker channels, mimicking this editing event through mutation, exhibit a similar effect. In addition, we demonstrate that mRNAs for the paralogous D. melanogaster Shab potassium channel are edited at the same position by fly ADAR-a clear example of convergent evolution driven by adenosine deamination. These results suggest an ancient and key regulatory role for this residue in K(V) channels.     

Partially edited RNAs are intermediates of RNA editing in plant mitochondria

RNA editing in flowering plant mitochondria addresses several hundred specific C nucleotides in individual sequence contexts in mRNAs and tRNAs. Many of the in vivo steady state RNAs are edited at some sites but not at others. It is still unclear whether such incompletely edited RNAs can either be completed or are aborted. To learn more about the dynamics of the substrate recognition process, we investigated in vitro RNA editing at a locus in the atp4 mRNA where three editing sites are clustered within four nucleotides. A single cis-element of about 20 nucleotides serves in the recognition of at least two sites. Competition with this sequence element suppresses in vitro editing. Surprisingly, unedited and edited competitors are equally effective. Experiments with partially pre-edited substrates indicate that indeed the editing status of a substrate RNA does not affect the binding affinity of the specificity factor(s). RNA molecules in which all editing sites are substituted by either A or G still compete, confirming that editing site recognition can occur independently of the actual editing site. These results show that incompletely edited mRNAs can be substrates for further rounds of RNA editing, resolving a long debated question.     

Role of Arginine Residues on the S4 Segment of the <Emphasis Type="Italic">Bacillus halodurans</Emphasis> Na<Superscript>+</Superscript> Channel in Voltage-sensing

The one-domain voltage-gated sodium channel of Bacillus halodurans (NaChBac) is composed of six transmembrane segments (S1–S6) comprising a pore-forming region flanked by segments S5 and S6 and a voltage-sensing element composed of segment S4. To investigate the role of the S4 segment in NaChBac channel activation, we used the cysteine mutagenesis approach where the positive charges of single and multiple arginine (R) residues of the S4 segment were replaced by the neutrally charged amino acid cysteine (C). To determine whether it was the arginine residue itself or its positive charge that was involved in channel activation, arginine to lysine (R to K) mutations were constructed. Wild-type (WT) and mutant NaChBac channels were expressed in tsA201 cells and Na⁺ currents were recorded using the whole-cell configuration of the patch-clamp technique. The current/voltage (I-V) and conductance/voltage (G-V) relationships steady-state inactivation (h _∞) and recovery from inactivation were evaluated to determine the effects of the S4 mutations on the biophysical properties of the NaChBac channel. R to C on the S4 segment resulted in a slowing of both activation and inactivation kinetics. Charge neutralization of arginine residues mostly resulted in a shift toward more positive potentials of G-V and h _∞ curves. The G-V curve shifts were associated with a decrease in slope, which may reflect a decrease in the gating charge involved in channel activation. Single neutralization of R114, R117, or R120 by C resulted in a very slow recovery from inactivation. Double neutralization of R111 and R129 confirmed the role of R111 in activation and suggested that R129 is most probably not part of the voltage sensor. Most of the R to K mutants retained WT-like current kinetics but exhibited an intermediate G-V curve, a steady-state inactivation shifted to more hyperpolarized potentials, and intermediate time constants of recovery from inactivation. This indicates that R, at several positions, plays an important role in channel activation. The data are consistent with the notion that the S4 is most probably the voltage sensor of the NaChBac channel and that both positive charges and the nature of the arginine residues are essential for channel activation.This revised version was published online in June 2005 with a corrected cover date.     

RNA editing modulates the binding of drugs and highly unsaturated fatty acids to the open pore of Kv potassium channels

The time course of inactivation of voltage‐activated potassium (Kv) channels is an important determinant of the firing rate of neurons. In many Kv channels highly unsaturated lipids as arachidonic acid, docosahexaenoic acid and anandamide can induce fast inactivation. We found that these lipids interact with hydrophobic residues lining the inner cavity of the pore. We analysed the effects of these lipids on Kv1.1 current kinetics and their competition with intracellular tetraethylammonium and Kvβ subunits. Our data suggest that inactivation most likely represents occlusion of the permeation pathway, similar to drugs that produce ‘open‐channel block’. Open‐channel block by drugs and lipids was strongly reduced in Kv1.1 channels whose amino acid sequence was altered by RNA editing in the pore cavity, and in Kv1.x heteromeric channels containing edited Kv1.1 subunits. We show that differential editing of Kv1.1 channels in different regions of the brain can profoundly alter the pharmacology of Kv1.x channels. Our findings provide a mechanistic understanding of lipid‐induced inactivation and establish RNA editing as a mechanism to induce drug and lipid resistance in Kv channels.     

Effects of intracellular magnesium on Kv1.5 and Kv2.1 potassium channels

We characterized the effects of intracellular Mg²⁺ (Mg²⁺_i) on potassium currents mediated by the Kv1.5 and Kv2.1 channels expressed in Xenopus oocytes. Increase in Mg²⁺_i caused a voltage-dependent block of the current amplitude, apparent acceleration of the current kinetics (explained by a corresponding shift in the steady-state activation) and leftward shifts in activation and inactivation dependencies for both channels. The voltage-dependent block was more potent for Kv2.1 [dissociation constant at 0 mV, K_d(0), was ~70 mM and the electric distance of the Mg²⁺ binding site, , was 0.2] than for the Kv1.5 channel [K_d(0)~40 mM and =0.1]. Similar shifts in the voltage-dependent parameters for both channels were described by the Gouy-Chapman formalism with the negative charge density of 1 e^–/100 Ų. Additionally, Mg²⁺_i selectively reduced a non-inactivating current and increased the accumulation of inactivation of the Kv1.5, but not the Kv2.1 channel. A potential functional role of the differential effects of Mg²⁺_i on the Kv channels is discussed.     

TbDSS-1, an essential Trypanosoma brucei exoribonuclease homolog that has pleiotropic effects on mitochondrial RNA metabolism

Mitochondrial gene expression in trypanosomes is controlled primarily at the levels of RNA processing and RNA stability. This regulation undoubtedly involves numerous ribonucleases. Here we characterize the Trypanosoma brucei homolog of the yeast DSS-1 mitochondrial exoribonuclease, which we term TbDSS-1. Biochemical fractionation indicates that TbDSS-1 is mitochondrially localized, as predicted by its N-terminal sequence. In contrast to its yeast homolog, TbDSS-1 does not appear to be associated with mitochondrial ribosomes. Targeted downregulation of TbDSS-1 by RNA interference in procyclic-form T. brucei results in a severe growth defect. In addition, TbDSS-1 depletion leads to a decrease in the levels of never edited cytochrome oxidase subunit I (COI) mRNA and both unedited and edited COIII mRNAs, indicating this enzyme functions in the control of mitochondrial RNA abundance. We also observe a considerable reduction in the level of edited apocytochrome b (CYb) mRNA and a corresponding increase in unedited CYb mRNA, suggesting that TbDSS-1 functions, either directly or indirectly, in the control of RNA editing. The abundance of both gCYb[560] and gA6[149] guide RNAs is reduced upon TbDSS-1 depletion, although the reduction in gCYb[560] is much more dramatic. The significant reduction in gCYb levels could potentially account for the observed decrease in CYb RNA editing. Western blot analyses of mitochondrial RNA editing and stability factors indicate that the perturbations of RNA levels observed in TbDSS-1 knock-downs do not result from secondary effects on other mitochondrial proteins. In all, these data demonstrate that TbDSS-1 is an essential protein that plays a role in mitochondrial RNA stability and RNA editing.