Infield DT , Lee EEL , Galpin JD , Galles GD , Bezanilla F , Ahern CA .

R01 GM030376 NIGMS NIH HHS , R01 GM106569 NIGMS NIH HHS , R24 NS104617 NINDS NIH HHS

	Figure 1. Crystal structure of the Kv 1.2/2.1 chimera suggests electrostatic accommodation of gating charges within the voltage sensing domain. Labels correspond to the residues at homologous positions in Shaker. Voltage-sensing arginine residues are shown in blue, conserved glutamate residues are shown in red, and hydrophobic residues, including the conserved phenylalanine in the hydrophobic plug (F290 in Shaker), are shown in green.
	Figure 2. Encoding of citrulline into Shaker. (A) Structural and electrostatic representations of the side chains of arginine, citrulline, and glutamine. (B) Currents generated from co-injection of cRNA encoding R1TAG, R3TAG, and R4TAG with CIT-tRNA compared with those injected with cRNA and full-length (pCA-ligated) tRNA in parallel. Lack of expressed current in the pCA condition for a given position is consistent with faithful encoding of citrulline. Error bars indicate SEM.
	Figure 3. Lack of effect on activation of encoding citrulline at R1 in Shaker. (A–C) Voltage-dependent ionic currents from oocytes expressing WT, R362CIT-, and R362Q-Shaker channels. Oocytes were held at −80 mV and subjected to 100-ms pulses in 10-mV steps, followed by 100-ms pulses to −50 mV (WT, Cit) or −40 mV (Q) before returning to the holding potential. (D) Normalized G-V values. Error bars represent ±SEM. At R1, a positive charge is apparently dispensable for activation, provided the shape of arginine is maintained.
	Figure 4. Effects on activation of encoding citrulline at R3 in Shaker. (A and B) Voltage-dependent ionic currents from oocytes expressing R368CIT- and R368Q-Shaker channels. Oocytes were held at −80 mV and subjected to 100-ms pulses in 10-mV steps, followed by 100-ms pulses to −40 mV (Cit) or −30 mV (Q) before returning to the holding potential. (C) Normalized G-V values. Error bars represent ±SEM. Note that the same WT data are used here and in Fig. 3 D. At R3, neutralization via citrulline resulted in a rightward shift and change in activation slope, suggesting that a positive charge at this position is necessary for normal activation. However, the effect on activation is modest compared with mutation to glutamine.
	Figure 5. Outsized electrostatic role for R4 in channel deactivation. (A–C) Normalized G-V curves from COVC of WT-, R371Q-, and R371Cit-Shaker. Oocytes were held at −80 mV, then prepulsed to −120 mV for 200 ms, before a variable pulse ranging from 80 mV to −120 mV, followed by a postpulse to −120 mV, before returning to the original holding potential. (D) Normalized G-V values. Error bars represent ±SEM. (E) A comparison of the activation rate (τ) between WT- and R371Cit-Shaker as derived from the same data used for the G-V curves. (F) Deactivation rate for WT- and R317Cit-Shaker. For these data, oocytes were held at −80 mV, prepulsed to −120 mV for 200 ms, then pulsed to 80 mV for 50 ms, followed by a variable pulse ranging from 80 mV to −120 mV for 350 ms, before returning to the original holding potential.

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