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Volume 37, Issue 1, Pages (January 2003)

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1 Volume 37, Issue 1, Pages 85-98 (January 2003)
A Fluorometric Approach to Local Electric Field Measurements in a Voltage-Gated Ion Channel  Osei Kwame Asamoah, Joseph P. Wuskell, Leslie M. Loew, Francisco Bezanilla  Neuron  Volume 37, Issue 1, Pages (January 2003) DOI: /S (02)

2 Figure 1 Structure and Properties of Cysteine-Reactive Electrochromic Fluorophores (A) Structure of Di-1-ANEPMI (top) and Di-1-ANEPIA (bottom). (B) The fluorescence emission spectra of Di-1-ANEPMI (black), Di-1-ANEPIA (orange), and Di-4-ANEPPS (blue). These spectra are not corrected for the wavelength dependence of the detector. (C) The molecular basis of the electrochromic process is depicted at the top. The perturbation of the electronic energy levels in the presence of an electric field produces a shift in the fluorescence spectra that is manifested as a rapid optical signal. P indicates a parallel orientation. (D) Evoked fluorescence from Xenopus oocytes expressing the cysteine-less Shaker mutant W434F. The cells were stained in 5 μM Di-1-ANEPMI or an equivalent concentration of Di-1-ANEPIA, then voltage clamped to the indicated potentials. Neuron  , 85-98DOI: ( /S (02) )

3 Figure 2 Optical Signals of Di-1-ANEPIA in the S3-S4 Linker (Residue 354C) and Near the S4 Segment (Residue 359C) of Shaker (A) The basic subunit of Shaker is depicted with the approximate locations of the cysteine residues in which the electrostatic field was measured. (B and C) Xenopus oocytes expressing a Shaker mutant with an introduced cysteine residue (354C) in the S3-S4 linker exhibit gating currents (Ig) and fluorescence signals (F) with depolarizing pulses to −60 mV (B) and 40 mV (C). (D) The magnitude of the electrochromic signals are plotted as a function of voltage to quantitate the electrostatic field at site 354C. The electrochromic on (circles) is linear (r2 = 0.994) with voltage while the electrochromic off (inverted triangles) is highly nonlinear. Inset: the evoked fluorescence with a depolarization pulse to 40 mV. (E) The electrochromic off (inverted triangles) exhibits linear voltage dependence (r2 = 0.997), while the electrochromic on (circles) is nonlinear with voltage with this pulse protocol. Inset: fluorescence response to voltage pulses from the activated state (0 mV) at site 359C. Eon is designated by the leftward arrow and Eoff denoted by rightward arrow. Neuron  , 85-98DOI: ( /S (02) )

4 Figure 3 Temporal Response of the Cysteine-Reactive Electrochromic Probe (A) The electrochromic on signal (arrowhead pointing to upward deflection of black trace), capacity charge (orange), and gating charge (blue) at site 354C (pulse to 40 mV, from a holding potential of −90 mV). (B) The time constants of the slow fluorescence (black squares) and gating charge (red circles). (C) The kinetics of electric field modulation during the gating process assayed by comparing the magnitude of the electrochromic on (rightward arrow) and electrochromic off (leftward arrow) as a function of pulse duration at 40 mV. (D) A time plot of the normalized electrochromic ratio (red trace) and slow fluorescence (black trace). Neuron  , 85-98DOI: ( /S (02) )

5 Figure 4 Electric Field Sensitivity of Di-1-ANEPIA in the N Terminus (Residue 359C) of the Fourth Transmembrane Segment (A) Voltage sensor displacement in 0.5 mM (inverted triangles) versus 70 mM [Ca2+] (squares). (B) Analysis of the change in the electric field strength for the oocyte shown in (A). The magnitude of the electrochromic off signal (given in units of pA, as recorded by a photodiode coupled to an integrating headstage of a patch-clamp amplifier) in the two extracellular calcium conditions. (C) Modulation of gating charge movement induced by increased proton concentration in the extracellular solution. (D) Electrostatic attributes near the S4 are very sensitive to changes in the pH of the extracellular solution with an average field modulation of 30.3% ± 5.4% (n = 4) observed in acidic conditions. All of the above data were obtained with the following voltage pulse protocol: HP = 0 mV, test pulse to indicated value, post-pulse = 0 mV. The off component of the gating current was integrated for (A) and (C) while the electrochromic off fluorescence was utilized for (B) and (D). Neuron  , 85-98DOI: ( /S (02) )

6 Figure 5 The Electrochromic Signals in the S4 Has Unique Attributes
(A) The rapid optical signals at site 365C exhibit an inverted orientation (relative to all other sites) such that the electrochromic on (right arrow) and electrochromic off (left arrow) are downward and upward, respectively. (B) The electrochromic on (circles) in the S4 demonstrates nonlinear voltage dependent behavior with an electric field sensitivity (slope) that is significantly attenuated with respect to the electrochromic off (inverted triangles). Neuron  , 85-98DOI: ( /S (02) )

7 Figure 6 The Electrostatic Field in Shaker Is Maximized in the Fourth Transmembrane Segment The electrostatic field profile in Shaker as determined from the average slope of the fluorescence versus voltage relationship measured at each site. The electrochromic on fluorescence signal was utilized for all residues with the exception of 365C, for which the electrochromic off was employed. In all cases, a voltage pulse protocol with HP = −90 mV, variable amplitude test pulse from −140 mV to 40 mV in increments of 20 mV, and a return pulse to −90 mV was used. The electric field strength in the protein was calculated using Di-4-ANEPPS as a calibration reference (see Experimental Procedures). Neuron  , 85-98DOI: ( /S (02) )

8 Figure 7 Models of Di-1-ANEPIA Attached to the S4
(A) A structural model depicting Di-1-ANEPIA conjugated to residue 365C. The orientation of the fluorophore was inferred from the polarity of the electrochromic signals recorded in the S4 relative to fluorescence signals observed in oocytes labeled with Di-4-ANEPPS. (B) A mechanistic model illustrating the origin of electrical hysteresis in the voltage sensor. Neuron  , 85-98DOI: ( /S (02) )

9 Figure 8 Synthesis of Thiol-Reactive Electrochromic Fluorophores
Di-1-ANEPMI (III) and Di-1-ANEPIA (IV) are synthesized from the precursor β-[2-(Dimethylamino)-6-naphthyl]-4-vinyl pyridine (I). Neuron  , 85-98DOI: ( /S (02) )

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