Abstract
CaVβ subunits interact with the voltage-gated calcium channel CaV2.2 on a site in the intracellular loop between domains I and II (the I-II loop). This interaction influences the biophysical properties of the channel and leads to an increase in its trafficking to the plasma membrane. We have shown previously that a mutant CaV2.2 channel that is unable to bind CaVβ subunits (CaV2.2 W391A) was rapidly degraded (Waithe, D., Ferron, L., Page, K. M., Chaggar, K., and Dolphin, A. C. (2011) J. Biol. Chem. 286, 9598–9611). Here we show that, in the absence of CaVβ subunits, a construct consisting of the I-II loop of CaV2.2 was directly ubiquitinated and degraded by the proteasome system. Ubiquitination could be prevented by mutation of all 12 lysine residues in the I-II loop to arginines. Including a palmitoylation motif at the N terminus of CaV2.2 I-II loop was insufficient to target it to the plasma membrane in the absence of CaVβ subunits even when proteasomal degradation was inhibited with MG132 or ubiquitination was prevented by the lysine-to-arginine mutations. In the presence of CaVβ subunit, the palmitoylated CaV2.2 I-II loop was protected from degradation, although oligoubiquitination could still occur, and was efficiently trafficked to the plasma membrane. We propose that targeting to the plasma membrane requires a conformational change in the I-II loop that is induced by binding of the CaVβ subunit.
Highlights
Voltage-gated calcium channels have a crucial role in excitable cells, being involved in neurotransmitter release, gene transcription, muscle contraction, and calcium-induced calcium release from internal stores [2]
Trafficking of the Palmitoylated I-II Loop of CaV2.2 in tsA-201 Cells—To investigate the mechanism by which the CaV subunit protects CaV2.2 from degradation and is involved in trafficking it to the plasma membrane, a construct was made containing the intracellular I-II loop of CaV2.2, which is known to interact with the CaV via the as the ␣-interaction domain (AID) [7]
It is well established that the CaV subunit binds to the CaV␣1 channel via the AID in the intracellular I-II loop [7] and that this interaction is required for trafficking the CaV␣1 subunit to the plasma membrane [4]
Summary
Voltage-gated calcium channels have a crucial role in excitable cells, being involved in neurotransmitter release, gene transcription, muscle contraction, and calcium-induced calcium release from internal stores [2]. Quantification of band intensity for ubiquitinated I-II loops expressed as a percentage of total protein per lane for HA-stained Western blots showed that the ubiquitinated palm CaV2.2 I-II-HA represented a significantly lower proportion of total I-II loop protein in the absence of CaV than in the presence of CaV1b (Fig. 3D, columns 1 and 2).
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