SUMOylation of NaV1.2 channels mediates the early response to acute hypoxia in central neurons

  1. Leigh D Plant
  2. Jeremy D Marks
  3. Steve AN Goldstein  Is a corresponding author
  1. Brandeis University, United States
  2. University of Chicago, United States
8 figures, 2 tables and 1 additional file

Figures

Figure 1 with 1 supplement
Acute hypoxia and SUMO1 augment INa in rat CGN.

INa in rat CGN was studied by whole-cell patch-clamp. Normalized activation (Act) and steady-state inactivation (SSI) relationships were obtained and fit as described in the Materials and methods. Measured values are noted in the text and listed in Table 1. The time-course of hypoxic modulation of INa was studied by steps from –100 mV to -20 mV every 10 s. Cells were studied with control solution (black), 100 pm SUMO1 (red), or 250 pm SENP1 (blue) in the recording pipette. To assess the relative contributions of NaV1.2 and NaV1.6 channel currents to INa, 250 nm µ-conotoxin TIIIA (CnTx) and 50 nm 4,9 anhydro-TTX (anTTX) were applied as indicated. Data are mean ± S.E.M. for 10 to 15 cells per group. Scale bars are 150 pA/pF and 5 ms for panels a to d, and 75 pA/pF and 5 ms in panel e. (a) Left, example traces showing INa at -20 mV increased when control perfusate at 21% O2 (black) was exchanged with a hypoxic solution at 5% O2 (- - - -). Right, the time-course for changes in the peak current in response to decreased O2, and on return to normoxia (washout), is shown normalized to the maximal current for each cell studied. Inset, The level of O2 was measured in real-time in the recording chamber and fell from 21 to 5% within 18 ± 1 s (o). Error bars are within the symbols. (b) Hypoxic solution (green dashes) left shifted the V½ of INa from control (black) for both Act (solid) and SSI (open). (c) Left, SUMO1 in the pipette (red) increased INa and no further augmentation was observed by subsequent hypoxia (red dashes). Right, SENP1 in the pipette (blue) decreased INa and suppressed the response to hypoxia (blue dashes). Dotted black lines indicate the mean peak values in control normoxic solutions from a. (d) SUMO1 left shifted the V½ of Act (red triangle) and SSI (open red triangle). The relationships were then insensitive to hypoxia (Act, red down triangle; SSI, open red down triangle). SENP1 right shifted the V½ of Act (blue triangle) and SSI (open blue triangle) and currents were then insensitive to hypoxia. Dashed black lines indicate mean peak values with control solutions from b. (e) Left; INa traces under control conditions and with toxins in the bath. Right; mean normalized peak current histograms showing 90 ± 0.8% inhibition by CnTx, 10 ± 0.3% inhibition by AnTTX and 98 ± 0.02% inhibition by both toxins with 21% O2 (black bars). (f) Mean normalized peak INa histograms. Left; 92 ± 1% inhibition by CnTx and 9 ± 1% inhibition by AnTTX with a drop to 5% O2 for 60 s (green). Right; 93 ± 2% inhibition by CnTx and 7 ± 1% inhibition by AnTTX with 100 pm SUMO1 in the pipette (red). (g) Mean normalized peak current histograms show that the INa remaining after inhibition of NaV1.2 by CnTx did not respond to acute hypoxia at 5% O2 (green), SUMO1 (red) or SENP1 (blue). (h) Mean normalized peak INa histograms with SENP1 in the pipette with 21% O2 (blue) showing 70 ± 4% inhibition by CnTx, 34 ± 8% inhibition by AnTTX and 96 ± 0.5% inhibition by both toxins consistent with the passage of much of the remaining current by NaV1.6.

https://doi.org/10.7554/eLife.20054.003
Figure 1—figure supplement 1
Recovery of INa and NaV1.2 from fast inactivation is not altered by hypoxia, SUMO1 or SENP1.

Neuronal INa or CHO cells expressing NaV1.2 or NaV1.2-Lys38Gln (NaV1.2-K38Q) were studied in whole-cell mode. To assess recovery from fast inactivation cells were held at −100 mV, depolarized to −20 mV for 30 ms and then held at −100 mV for increasing amounts of time before a second 30 ms, −20 mV test pulse to measure the fraction of current recovered. Data are mean ± S.E.M. for 6–10 cells per group. (a) The fraction of initial INa recovered in subsequent test pulses is plotted against the interpulse interval and fitted with a mono-exponential function to determine the time-constant (τ) of recovery. The mean time constant for control cells was 8 ± 0.36 (green) and did not differ when cells exposed to hypoxia (black) with or without 100 pm SUMO (red) or 250 pm SENP1 (blue) in the recording pipette. Inset; An example current, showing the recovery time course of INa recorded from a control neuron. (b) Histograms showing the mean τ of recovery, assessed as in (a), for neuronal INa or NaV1.2 or NaV1.2-K38Q expressed in CHO cells under the experimental conditions described. Neither the point mutation K38Q, nor treating cells with hypoxia, SUMO1 or SENP1 modulated recovery kinetics.

https://doi.org/10.7554/eLife.20054.004
Figure 2 with 1 supplement
NaV1.2 assembles with native SUMO1 at the surface in rat CGN.

The association of native NaV1.2 and SUMO1 in CGN was studied by amFRET and STORM per the Materials and methods. Data are mean ± S.E.M. The scale bar represents 5 µm. (a) Representative photomontage of amFRET of NaV1.2 and SUMO in cells exposed to normoxia, using Alexa Fluor 488 and Alexa Fluor 594-labeled secondary antibodies to anti-NaV1.2 and anti-SUMO1. The four smaller images show NaV1.2 (donor, top left), SUMO1 (acceptor, top middle), the acceptor after photobleaching (BLEACH, bottom right), and FRET (bottom left, FRET efficiency indicated in pseudo-colored scale); the calculated FRET ratio in voxels after acceptor photobleaching was 0.15 ± 0.01 (n = 10 neurons on six coverslips). The large panel is an overlay of the donor and resultant FRET. (b) Representative photomontage of amFRET of NaV1.2 and SUMO in cells exposed to hypoxia (1% O2), using the identical approach and image layout as in panel a showing a calculated FRET ratio after acceptor photobleaching of 0.28 ± 0.05 (n = 8 neurons on five coverslips). (c) Histogram showing a four-fold increase in the voxels with NaV1.2 demonstrating FRET from ambient conditions (7.8 ± 2.3%) with hypoxia (29.6 ± 7.6%, n = 8 on five coverslips); * indicates p<0.001. (d) Composite scatterplot of fluorophore localizations obtained with STORM imaging. Maximum z-projections of scatterplots of fluorophore events from Alexa 568-labeled anti-SUMO1 antibodies (red), Alexa 647-labeled anti-NaV1.2 antibodies, and Alexa 488-tagged streptavidin bound to extracellular membrane proteins are superimposed. Pixels are 20 nm square. (e) Mask of 20 nm square voxels in which fluorophore events from anti-SUMO1, anti-NaV1.2 and streptavidin co-localize for exemplar neurons (n = 5).

https://doi.org/10.7554/eLife.20054.006
Figure 2—figure supplement 1
FRET was not observed between native NaV1.2 and GAD67 in CGN.

Native protein amFRET was performed between NaV1.2 (green) and GAD67 (red) in ambient O2 as described in Figure 2 and the Materials and methods. Negligible FRET was observed. GAD67 was detected with a secondary antibody labeled with Alexa 594 (acceptor) and NaV1.2 with Alexa 488 (donor).

https://doi.org/10.7554/eLife.20054.007
Acute hypoxia at 1.5% O2 after culturing at 7% augments INa.

INa in rat CGN was studied following 5–7 days in culture at 7% O2 by whole-cell patch clamp, as per Figure 1. Normalized activation (Act) and steady-state inactivation (SSI) relationships were obtained and fit as described in the Materials and methods. Measured values are noted in the text and listed in Supplementary file 1b. Cells were studied with a control solution (black), 100 pm SUMO1 (red), or 250 pm SENP1 (blue) in the recording pipette. Sensitivity to CnTx and AnTTX was assessed as per Figure 1. Data are mean ± S.E.M. for six cells per group. Scale bars are 150 pA/pF and 5 ms. (a) Left, example traces showing INa at −20 mV increased when perfusate at 7% O2 (black) was exchanged with a hypoxic solution at 1.5% O2 (green dashes). Right, the time-course for changes in peak current in response to decreased O2 from 7 to 1.5%, normalized to the maximal current for each cell studied. (b) Hypoxic solution (green dashes) left shifted the V½ of INa from control (black) for both Act (solid) and SSI (open). (c) Left, SUMO1 in the pipette (red) increased INa and no further augmentation was observed by subsequent hypoxia (red dashes). Right, SENP1 in the pipette (blue) decreased INa and suppressed the response to hypoxia (blue dashes). Dotted black lines indicate the mean peak values obtained at 7% O2 in a. (d) SUMO1 left shifted the V½ of Act (red triangle) and SSI (open red triangle). The relationships were then insensitive to hypoxia (Act, red down triangle; SSI, open red down triangle). SENP1 right shifted the V½ of Act (blue triangle) and SSI (open blue triangle) and currents were then insensitive to hypoxia. Dashed black lines indicate mean peak values with control solutions from b. (e) Left; INa studied at 7% O2 then with toxins in the bath. Right; mean normalized peak current histograms showing 89 ± 1.2% inhibition by CnTx, 12 ± 2% inhibition by AnTTX and 99 ± 0.8% inhibition by both toxins (black bars). These ratios indicate that the relative contribution of NaV1.2 and NaV1.6 to INa is not altered when cells are cultured at 7% O2. (f) Mean normalized peak INa histograms. Left; 91 ± 1% inhibition by CnTx and 10 ± 1% inhibition by AnTTX with a drop to 1.5% O2 for 60 s (green). Middle; 90 ± 2% inhibition by CnTx and 9 ± 2% inhibition by AnTTX with 100 pm SUMO1 in the pipette (red). When SENP1 was included in the recording pipette (blue), INa was inhibited by 73 ± 3% by CnTx, 38 ± 8% by AnTTX and 95 ± 2% by both toxins consistent with the passage of much of the remaining current by NaV1.6. (g) Mean normalized peak current histograms show that the INa remaining after inhibition of NaV1.2 by CnTx did not respond to acute hypoxia at 1.5% O2 (green), SUMO1 (red), or SENP1 (blue).

https://doi.org/10.7554/eLife.20054.008
FRET between NaV1.2 and SUMO1 at the cell surface requires Lys38.

Rat NaV1.2 was expressed in CHO cells with the β1 subunit and studied in live cells per Materials and methods. FRET was assessed by measuring the time constant (τ) for CFP-photobleaching (donor) in the presence of YFP (acceptor) from 3 regions of 5–7 cells per group. Data are mean τ ± S.E.M. (a) CFP-NaV1.2 subunits (blue) and YFP-SUMO1 (yellow) reach the cell surface. Scale bar is 10 µm. (b) Exemplar photobleaching studies show the decay of fluorescence intensity for single cells expressing CFP-NaV1.2 (open) or CFP-NaV1.2-Lys38Gln (solid) with YFP-SUMO1 fit by an exponential to give τ. (c) FRET shows the assembly of CFP-NaV1.2 (grey bars) with YFP-SUMO1 and YFP-Ubc9 (τ = 29 ± 2* and 25 ± 3*, respectively) but not with linkage-incompetent YFP-SUMO195 or free YFP (τ = 6 ± 3 and 7 ± 3, respectively). In contrast, CFP-NaV1.2-Lys38Gln (white bars) did not show FRET with YFP-SUMO1, YFP-SUMO195, YFP-Ubc9 or free YFP (τ = 6 ± 3; 5.5 ± 3.5; 7.5 ± 3.5; and 6 ± 4, respectively). Significant changes in τ compared to free YFP are indicated (*, p<0.001).

https://doi.org/10.7554/eLife.20054.009
Acute hypoxia induces SUMOylation of NaV1.2 on Lys38.

Rat NaV1.2 was expressed in CHO cells with the β1 subunit and studied under normoxic and hypoxic conditions with control solution (black), 100 pm SUMO1 (red) or 250 pm SENP1 (blue) in the recording pipette, as indicated. Data are mean ± S.E.M. for 10 to 15 cells per group. Measured values are noted in the text and listed in Table 1. Scale bars are 5 ms and 50 pA/pF in a and 10 pA/pF in b. (a) Left, example traces show hypoxia (green dashes) increased NaV1.2 channel current from control conditions (black). SUMO1 in the pipette (red) increased the current to the same level and precluded further augmentation by hypoxia (red dashes). In contrast, SENP1 (blue) decreased the current by ~75% and suppressed sensitivity to hypoxia (blue dashes). Dotted black lines represent mean peak current under control conditions. Right, both Act (solid) and SSI (open) for NaV1.2 were left shifted when cells with hypoxia (green) or SUMO1 in the pipette (red) and were right-shifted with SENP in the pipette (blue). Hypoxia caused no further change to Act or SSI with SUMO1 or SENP1 in the pipette (dashed lines). (b) Left, NaV1.2-Lys38Gln channels passed smaller currents (black) that were not increased by hypoxia (green) or by SUMO1 in the pipette (red) or decreased by SENP1 (blue) in the pipette. Right, the normalized Act and SSI relationships for NaV1.2-Lys38Gln channels (black) are right-shifted compared to wild type NaV1.2 channels and do not change when cells are exposed to hypoxia (green) or are studied with SUMO1 (red) or SENP (blue) in the pipette.

https://doi.org/10.7554/eLife.20054.010
Mass spectroscopy shows SUMO1 conjugated to NaV1.2-Lys38.

For MS analysis, rat NaV1.21-125 and SUMO197T95K were expressed with mouse SUMOylation enzymes in E. coli, purified, subjected to trypsin cleavage, and analyzed by MS as described in the Materials and methods. (a) Left, schematic showing the product NaV1.21–125-SUMO (box) and the trypsin fragment of NaV1.2 carrying the Gly-Gly remnant of SUMO197T95K. Right, The sequence of the three-ended fragment with Lys38 and the Gly-Gly remnant. (b) A Coomassie blue-stained SDS–PAGE gel of the purified products. Unmodified NaV1.21–125 (NaV) migrates at ~25 kDa (star). Expression of SUMO197T95K (SUMO) and the SUMO enzymes yields SUMO on the overexpressed target as well as native proteins (Plant et al., 2011; Uchimura et al., 2004). The NaV1.21–125-SUMO conjugate migrates at ~40 kDa (arrow). Molecular weight markers are shown (MW). (c) Fourier transform mass spectrum after trypsin digestion of NaV1.21–125-SUMO expressed as relative abundance against time of capture. The predicted fragment of 422.27 Da was captured as a single peak at 24.62 min. (d) Tandem MS sequence analysis of the fragment with Lys38 and the Gly-Gly remnant indicating b and y ion species as annotated in a.

https://doi.org/10.7554/eLife.20054.011
Hypoxia recruits one SUMO1 monomer to each cell surface NaV1.2 channel.

Single CFP-NaV1.2 or CFP-NaV1.2-Lys38Gln (K38Q, blue) channels and SUMO1 tagged with mCherry (m-SUMO1, red) were studied in CHO cells by TIRFM as described in the Materials and methods. Data represent 5–8 cells in each case and biophysical parameters and single particles statistical analyses are summarized in Supplementary file 1a and Table 2, respectively. (a) Left, single co-localized particles with both mCherry and CFP fluorescence were observed at the surface of cells expressing NaV1.2 and SUMO1. Simultaneous continuous photobleaching time courses revealed complexes to have one subunit of each type. (b) Histogram of photobleaching steps showing that hypoxia increased single mCherry-SUMO1 (red) subunits at the cell surface co-localized with NaV1.2 channels (blue), without a change in subunit stoichiometry (Table 2). (c) Histogram of photobleaching steps showing that SENP suppresses hypoxia-induced increase in single mCherry-SUMO1 (red) subunits at the cell surface co-localized with NaV1.2 (blue). (d) Histogram of photobleaching steps showing that hypoxia does not increase in single mCherry-SUMO1 (red) subunits at the cell surface co-localized with NaV1.2-Lys38Gln channels (blue).

https://doi.org/10.7554/eLife.20054.012
Hypoxic SUMOylation of NaV1.2 and current density proceed concurrently.

CFP-NaV1.2 or CFP-NaV1.2-Lys38Gln (K38Q, blue) channels and SUMO1 tagged with mCherry (m-SUMO1, red) were studied in CHO cells by TIRFM and pixel-by-pixel analysis performed as described in the Materials and methods. Briefly, images were captured at 5 s intervals and data for each fluorophore saved as separate stacks; the background was subtracted and processed for misalignment in an identical manner. Manders’ coefficients were assessed post-hoc for 3–5 regions per cell. Co-localization was defined as the presence of both fluorophores at more than 30% of the maximum fluorescence level recorded in that stack (and their overlap is represented in the images as white pixels). The time-course of hypoxic modulation of NaV1.2 current in moving from O2 of 21% to 5% was studied with steps from –100 mV to −20 mV every 10 s and normalized to cell capacitance (pA/pF). Data represent 5–8 cells and biophysical parameters and single particles statistical analyses are summarized in Supplementary file 1a and Table 2, respectively. (a) Hypoxia rapidly recruits SUMO1 to the cell surface at sites with NaV1.2 channels. The images show that the surface density of m-SUMO1 (top, left) is low compared to CFP-NaV1.2 (top, middle) with little co-localization (top, right) in ambient O2. After 40 s of hypoxia, rapid recruitment of SUMO1 (bottom, left) to the surface is observed to be at sites with NaV1.2 channels (bottom, left). Surface levels of NaV1.2 were not observed to change when cells were exposed to hypoxia (bottom, middle). (b) Histogram of surface density summarizing seven cells studied as described in a and Table 2. The density of pixels per µm2 with SUMO1 alone (red) was 4 ± 5, with NaV1.2 alone (blue) was 340 ± 16, and with both subunits was 67 ± 6 (red/blue hatch). Hypoxia increased co-localization to 268 ± 12 pixels per µm2 and decreased the density of free NaV1.2 channels (139 ± 8) without altering the density of free SUMO1 (12 ± 2). (c) The hypoxia-induced increase in the surface density of single fluorescent particles with both SUMO1 and NaV1.2 was not observed in cells with 100 nm SENP1 in the pipette. (d) Hypoxia-induced increase in the surface density of SUMO1 was not observed in cells expressing CFP-tagged NaV1.2-Lys38Gln (K38Q). (e) The time-course for hypoxia-induced increase co-localization of NaV1.2 and SUMO1 (Manders’ coefficient, solid circle) and current-density (pA/pF, open circle) were coincident. The mean Manders’ coefficient of 0.22 ± 0.08 measured in ambient O2 increased to 0.72 ± 0.12 in less than 40 s of acute hypoxia. The current density increased from −120 ± 8 to 198 ± 10 pA/pF. Increases in the Manders’ coefficient and current density were unchanged 10 min after cells were restored to ambient O2. (f) Hypoxia-induced increase in the surface density of colocalized SUMO1 and NaV1.2 was also observed when cells were treated with 5 µm tetrodotoxin (TTX), a level that blocked over 95% of the Na+ current.

https://doi.org/10.7554/eLife.20054.014

Tables

Table 1

Effects of hypoxia, SUMO1 and SENP1 on native INa and cloned NaV1.2 channels. Neurons (Figures 1 and 3) or cloned channels in CHO cells (Figure 5) were studied in whole-cell mode. Stimulation protocols are described in the Materials and methods. V½, the voltage evoking half-maximal conductance; k, the slope of the curve were obtained by fitting the normalized current plotted against voltage to a Boltzmann function, I = Imax/(1+exp[−(V−V½)/k]), where Imax is maximum current; and SSI is the steady-state inactivation half voltage. For comparison between groups, current densities were measured both at −20 mV, to demonstrate the impact of the shifts in V½, and at 0 mV, a potential where the G-V relationships are saturated under all study conditions. The maximal current in CGN cultured at 21% O2 and studied in ambient O2 was at −5 ± 1 mV (and the current-density was 292 ± 15 pA/pF); when these neurons were studied with SUMO1 in the pipette or subjected to 5% O2, the maximal current was observed at −20 ± 2 mV and −20 ± 3 mV, respectively, shifts of ~15 mV analogous to those seen in V½. When the cells were studied with SENP1 in the pipette, the maximal current was measured at +5 ± 2 mV, a shift of ~10 mV, and the current-density was −288 ± 17 pA/pF. Data are means ± S.E.M. for 10 to 15 cells per group; * indicates p<0.05 compared with cells studied at ambient O2 under control conditions.

https://doi.org/10.7554/eLife.20054.005

INa

NaV1.2

NaV1.2-Lys38Gln

 

Activation

SSI

I-20 mV

I0 mV

Activation

SSI

I-20 mV

I0 mV

Activation

SSI

I-20 mV

 

V½

mV

k

V½

mV

k

pA/pF

pA/pF

V½

mV

k

V½

mV

k

pA/pF

pA/pF

V½

mV

k

V½

k

pA/pF

 

Cultured at

21% O2

 

−23

± 0.5

4.0 ± 

0.2

−67

± 2

6 ± 

1

−172

± 20

−293 ± 12

−18.7

± 0.2

3.7 ± 

0.1

−59

± 0.4

7 ± 2

−112

± 8

−194 ± 

10

−4.0

± 1.5

3.6 ± 

0.3

−50

± 1

6.5 ± 

1

−33

± 7

 

Lowering O2

21% to 5%

 

−34

± 1.5*

4.2 ± 

0.2

−78

± 2*

10 ± 

2

−294

± 25*

−287 ± 18

−30

± 0.5*

4 ± 1

−72

± 1.5*

7.5 ± 

1

−192

± 11*

−187 ± 9

−4.0

± 2

3 ± 

1

−49

± 1

6 ± 

1

−35

± 6*

 

SENP1

 

−7.5

± 1*

4.1 ± 

0.3

−53

± 1*

8 ± 

2

−42

± 12*

−285 ± 17

−2.5

± 0.3*

3.6 ± 

0.1

−48

± 0.5*

6 ± 1

−29

± 9*

−191 ± 

11

−3.5

± 1

3.2 ± 

0.4

−49

± 0.5

6.5 ± 

2

−35

± 7*

 

SUMO1

 

−36

± 1*

3.9 ± 

0.2

−77

± 3*

8.5 ± 

1

−303

± 17*

−289 ± 15

−30

± 0.3*

3.5 ± 

0.2

−69

± 0.5*

7.5 ± 

2

−196

± 17*

−193 ± 

12

−4.0

± 2

3.4 ± 

0.5

−50

± 1.5

6 ± 

2

−33

± 5*

Cultured at

7% O2

 

−42.9

± 1.5

3.5 ± 

0.5

−57 ± 

3

7 ± 

2

−162 ± 

12

 

 

N.D.

Lowering O2

7% to 1.5%

−49.5

± 1.0

3.2 ± 

0.8

−69 ± 

2

7 ± 

2

−267 ± 

18

 

 

N.D.

 

Table 2

Co-localization of SUMO1 with NaV1.2 in response to hypoxia. CFP-tagged NaV1.2 or NaV1.2-Lys38Gln subunits were expressed in CHO cells with mCherry-SUMO1 (m-SUMO1) and studied by TIRFM and whole-cell patch-clamp (Figures 7 and 8). The number of photobleaching steps observed for each fluorophore in each single fluorescent spot reports on the stoichiometry of the channel complex. NaV1.2 channels are monomers and show no more than one bleaching step when tagged with CFP (Figure 7). No more than one bleaching steps was observed for mCherry-tagged SUMO1 subunits (free or co-localized with the channel). A 1:1 stoichiometry is maintained when cells are exposed to hypoxia. SUMO1 was not observed to co-localize with NaV1.2-Lys38Gln channels. The surface density of subunits was quantified as the mean of four 100 by 100 pixel regions for 6–10 cells per group. Exposure to hypoxia increased the number of SUMO1 monomers observed at the cell surface within 40 s and almost all were co-localized with NaV1.2. Whole-cell, peak current-density, measured at −20 mV, increased by ~70% within 40 s of hypoxia and remained stable during 2 min of hypoxia and 20 min of recovery at ambient levels of O2. Pulse protocols to determine the activation (Act) and steady-state inactivation (SSI) V1/2 values (the voltage evoking half-maximal conductance) were obtained as described in the Materials and methods and the manuscript Table. Data are means ± S.E.M. for 5 to 8 cells per group; * indicates p<0.05 compared with cells studied in ambient O2 for each channel type studied.

https://doi.org/10.7554/eLife.20054.013

Subunits expressed

CFP-NaV1.2 + m-SUMO1

CFP-NaV1.2-Lys38Gln + m-SUMO1

Condition

Ambient O2

Hypoxia

40 s

Hypoxia

2 min

Recovery

5 min

Recovery

10 min

Recovery

20 min

SENP1

Ambient O2

Hypoxia

40 s

Recovery

5 min

Single particle stoichiometry

SUMO1: NaV1.2

1: 1

ND

1: 1

1: 1

ND

ND

0: 1

0: 1

0: 1

ND

Free CFP-NaV1.2 pixels / µm2

340 ± 16

139 ± 8

137 ± 11

134 ± 7

131 ± 6

129 ± 8

290 ± 10

309 + 12

303 + 15

305 + 12

Free mSUMO1 pixels / µm2

4 ± 5

12 ± 2

11 ± 3

10 ± 7

8 ± 6

8 ± 5

3 + 2

5 + 2

4 + 2

4 + 1

Co-localized pixels / µm2

67 ± 6

268 ± 12

265 ± 12

260 ± 11

245 ± 14

239 ± 8

3 + 2

2 + 1

2 + 2

1 + 2

Total CFP-NaV1.2 pixels / µm2

407 ± 10

407 ± 12

402 ± 10

394 ± 15

376 ± 14

362 ± 10

293 ± 8

311 ± 12

305 ± 16

306 ± 14

Act V½ (mV)

−22 ± 1.2

−31 ± 1.7

−32 ± 2

−29 + 2

−35 ± 1.4

−33 + 2

−3.5 ± 1.8

−4 + 2

−3.7 + 2.5

−3.1 ± 1.2

SSI V½ (mV)

−61 ± 2

−70 ± 3

−69 ± 4

−71 + 3

−70 ± 2

−68 + 3

−44 ± 1.5

−51 + 1.5

−53 + 3

−48 ± 2

IPeak (pA/pF)

−120 ± 8

−198 ± 10

−199 ± 13

−200 ± 14

−201 ± 13

−189 ± 17

−33 ± 12

−39 ± 13

−37 ± 9

−39 ± 14

Additional files

Supplementary file 1

The biophysical properties of INa and NaV1.2 channels.

(a) Biophysical properties of INa and NaV1.2 channels cultured at 21% O2. (b) Biophysical properties of INa cultured at 7% O2. (c) Biophysical properties of INa and NaV1.2 channels expressed without the β1-subunit.

https://doi.org/10.7554/eLife.20054.015

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  1. Leigh D Plant
  2. Jeremy D Marks
  3. Steve AN Goldstein
(2016)
SUMOylation of NaV1.2 channels mediates the early response to acute hypoxia in central neurons
eLife 5:e20054.
https://doi.org/10.7554/eLife.20054