| Literature DB >> 19858358 |
Tora Mitra-Ganguli1, Iuliia Vitko, Edward Perez-Reyes, Ann R Rittenhouse.
Abstract
The G(q)-coupled tachykinin receptor (<Entities:
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Year: 2009 PMID: 19858358 PMCID: PMC2768804 DOI: 10.1085/jgp.200910204
Source DB: PubMed Journal: J Gen Physiol ISSN: 0022-1295 Impact factor: 4.086
Figure 1.CaV2.2 model system to be tested by NK-1R activation. (A) Flow chart representing the signaling cascade used by SP to modulate N current. (B) Schematic of model to be tested: N channels consist of the pore-forming CaV2.2, which is made up of four homologous domains (I–IV) also referred to as pseudosubunits, α2δ-1, and a CaVβ. Palmitoylated CaVβ2a blocks endogenously liberated free AA from binding to CaV2.2's inhibitory sites after exposure of cells to SP. AA's enhancement site remains available and is shown here in the outer regions of CaV2.2, although the actual location of this site remains uncharacterized. (C) Topological organization of CaV2.2 showing the six transmembrane segments and pore loop (P) of each pseudosubunit. An intracellular linker tethers each pseudosubunit to the subsequent one. CaVβ binds the AID region on the I–II linker at a site (delineated by the dotted box) that overlaps with a binding site for Gβγ. (D) The amino acid deletions in the region proximal to the AID result in Bdel1 and Bdel2 mutant channels. (E) Cross-sectional views from the inner pore region of wt CaV2.2 and the two mutant channels. Sequential amino acid deletions in the IS6-AID segment of Bdel1 and Bdel2 are predicted to reorient CaVβ2a such that the two palmitoyl groups (small white circles) are displaced from their wt positions.
Figure 2.NK-1R activation enhances Cav2.2/CaVβ2a currents. HEK-M1 cells were transiently transfected with CaV2.2, α2δ-1, β2a, and NK-1R. (A) Individual traces taken before and 2 min after application of 5 nM SP. (left) 0.1 mM BAPTA was present in the internal solution. (right) 20 mM BAPTA in the internal solution. (B) Comparison of the mean percent enhancement for cells dialyzed with 0.1 or 20 mM BAPTA (n = 4–9); *, P < 0.05 compared with inhibition in the presence of 0.1 mM BAPTA. (C) Individual traces taken before and 2 min after application of SP. P1 and P2 represent current measured before and after a prepulse, respectively. (D) Summary of the percent enhancement by SP at 0 mV before and after a prepulse (n = 9); *, P < 0.05 compared with P1 and P2 control currents before SP application. (E) Averaged current–voltage relationships measured before (closed circles) and after (open circles) application of SP. (F) Summary of TTP before and after application of SP (n = 6); *, P < 0.05 compared with control. Error bars represent SEM. Bars, 10 ms and 200 pA.
Figure 3.Modulation of Bdel1 current by SP is modestly disrupted. HEK-M1 cells were transiently transfected with NK-1R, Bdel1, α2δ-1, β2a (A–C), or β3 (D and E). (A) Averaged current–voltage plots measured before and after application of SP (red). (B and C) Individual sweeps elicited at 20 mV (B) and summary of enhancement (C) taken before and 2 min after application of SP (red) before (P1) or after a prepulse (P2; n = 7). (D) Representative sweeps taken before and 2 min after application of SP. (E) Summary of the inhibition by SP at 20 mV caused by SP before (P1) and after a prepulse (P2; n = 4); *, P < 0.05 compared with control currents. Error bars represent SEM. Bars, 10 ms and 200 pA.
Figure 4.NK-1R activation inhibits Bdel2 currents. HEK-M1 cells were transiently transfected with Bdel2, α2δ-1, CaVβ2a, or CaVβ3 and NK-1R. (A) Averaged current–voltage plot measured before and after application of SP. (B and C) Individual traces from CaVβ2a-containing Bdel2 channels (B) or CaVβ3-containing wt channels (C) taken before and 2 min after application of SP (red) before (P1) or after a prepulse (P2). (D) Prepulse facilitation (ratio of P2/P1) for wt CaV2.2 (▪), Bdel1 (•), and Bdel2 with either CaVβ2a (▴) or CaVβ3 (▾); *, P < 0.05 compared with Bdel1. (E) Summary of modulation of wt CaV2.2 (▪), Bdel1 (•), and Bdel2 with either CaVβ2a (▴) or CaVβ3 (▾) by SP before (closed) and after (open) a prepulse; *, P < 0.05 compared with control currents (n = 4–9). Error bars represent SEM. Bars, 10 ms and 200 pA.
Figure 5.Bdel2 current inhibition by SP is voltage independent, BAPTA sensitive, and antagonized by BSA similar to slow pathway modulation of CaV2.2. HEK-M1 cells were transiently transfected with NK-1R, either Bdel2 or wt CaV2.2, α2δ-1, and either CaVβ2a or CaVβ3. (A and B) Individual traces from wt CaV2.2/β3 (left) and Bdel2/β2a currents (right) taken before and 90 s after application of SP with 0.1 mM BAPTA (A) or 20 mM BAPTA (B) in the pipette solution. (C) Schematic showing BSA's site of action. (D) 1 mg/ml BSA in the external bath medium. Left, wt CaV2.2/β3; right, Bdel2/β2a. (E) Summary of the percent current remaining after SP from CaV2.2/β3 and Bdel2/β2a channels; *, P < 0.05 compared with control currents (n = 6–9); †, P < 0.05 using a one-way paired t test compared with unstimulated current amplitudes. Error bars represent SEM. Bars, 10 ms and 200 pA.
Figure 6.Exogenously applied palmitic acid blocks Bdel2 current inhibition by SP. HEK-M1 cells were transiently transfected with Bdel2, α2δ-1, CaVβ2a, and NK-1R. (A) Schematic representing preincubation of cells with 10 µM palmitic acid blocks free AA, released after stimulation of NK-1R, from occupying the inhibitory site. Enhancement site, not depicted. The two exogenous palmitic acids (magenta) are shown bound to the inner region of Bdel2, antagonizing AA from binding to the inhibitory sites. (B and C) Individual traces taken before and 2 min after application of 5 nM SP alone (B) or in the presence of 10 µM palmitic acid (C). (D) Summary of Bdel2 inhibition by SP in the presence of 10 µM palmitic acid (PA). *, P < 0.05 compared with current amplitude before SP (n = 7) or compared with the presence of palmitic acid alone (n = 6). **, P < 0.05; percent inhibition by SP compared with percent inhibition by palmitic acid + SP. Error bars represent SEM. Bars, 10 ms and 200 pA.