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Vol. 61, Issue 6, 1444-1452, June 2002
-Opioid Receptor Sequestration
Institute of Pharmacology, Toxicology and Pharmacy, University of
Munich, Munich, Germany
G protein-coupled receptor kinases (GRKs) phosphorylate opioid
receptors, which eventually results in receptor sequestration. With
respect to 
-opioid receptors, it is known that internalization occurs in a species-specific manner. That is, the agonist-occupied human -receptors will sequester whereas murine receptors fail to do
so. This investigation concentrates on the internalization of
-opioid receptors, employing laser scanning microscopy as a
major technique to examine receptor internalization in living cells.
For this reason, we fused green fluorescence protein to -receptors,
and DsRed-fluorescent protein to GRK2 and GRK3. All fusion proteins
retained their biologic activities. Permanent cell lines (HEK 293, NG
108-15) were transfected to express either green fluorescent
-receptors or to coexpress the tagged receptor and a specific
GRK-DsRed construct. The localization of fluorescent receptors and GRKs
was monitored by confocal microscopy before and after opioid exposure
of transfected cells. Activation of the murine -receptors triggers
rapid translocation of tagged GRKs toward the cell membrane, but
receptor internalization was not observed. The agonist-occupied human
-receptor also causes translocation of GRK2- and GRK3-DsRed, which
was followed by the formation of vesicles carrying the green
fluorescent -receptors. Moreover, the green fluorescent vesicles
consistently harbour red fluorescent GRK2 and GRK3, respectively. The
phenomenon of -receptor internalization as well as cointernalization
of GRKs is blocked by phosducin, indicating a critical role of G
protein-
subunits for -receptor sequestration. Comparing the
effect of over-expressed GRK2 and GRK3 on sequestration of
-receptors, we conclude that GRK3 more strongly induces -receptor
internalization than GRK2.
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