Abstract
Recently we found that visual arrestin binds microtubules and that this interaction plays an important role in arrestin localization in photoreceptor cells. Here we use site-directed mutagenesis and spin labeling to explore the molecular mechanism of this novel regulatory interaction. The microtubule binding site maps to the concave sides of the two arrestin domains, overlapping with the rhodopsin binding site, which makes arrestin interactions with rhodopsin and microtubules mutually exclusive. Arrestin interaction with microtubules is enhanced by several "activating mutations" and involves multiple positive charges and hydrophobic elements. The comparable affinity of visual arrestin for microtubules and unpolymerized tubulin (K(D) > 40 mum and >65 mum, respectively) suggests that the arrestin binding site is largely localized on the individual alphabeta-dimer. The changes in the spin-spin interaction of a double-labeled arrestin indicate that the conformation of microtubule-bound arrestin differs from that of free arrestin in solution. In sharp contrast to rhodopsin, where tight binding requires an extended interdomain hinge, arrestin binding to microtubules is enhanced by deletions in this region, suggesting that in the process of microtubule binding the domains may move in the opposite direction. Thus, microtubule and rhodopsin binding induce different conformational changes in arrestin, suggesting that arrestin assumes three distinct conformations in the cell, likely with different functional properties.
Highlights
Tified microtubules (MTs)4 as an interaction partner of visual arrestin [4]
We tested the salt sensitivity of arrestin binding and found that it is not dramatically changed between 50 –1000 mM potassium acetate. These data suggest that both hydrophobic interactions and ionic interactions participate in arrestin binding to MTs
Arrestin binding to microtubules has recently been implicated in the light-dependent redistribution of visual arrestin in rod photoreceptor cells [6]
Summary
Materials [14C]Leucine and [3H]leucine were from PerkinElmer Life Sciences. All other chemicals were from sources previously described [7]. In Vitro Transcription, Translation, and Evaluation of the Stability of Mutants pGEM2-based plasmids with the arrestin coding sequence with the “idealized” 5Ј-UTR [8] under the control of the SP6 promoter were transcribed and translated in vitro as previously described [7]. Arrestins were labeled by the incorporation of [3H]leucine and [14C]leucine with the specific activity of the mix between 1.5–3 Ci/mmol, resulting in arrestin-specific activity of 66 – 85 Ci/mmol (150 –230 dpm/fmol). The translation of every mutant used in this study produced a single labeled protein band with the expected mobility on SDS-PAGE. The relative stability of all mutants (assessed as described in Ref. 9) exceeded 80%
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