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PDBsum entry 2ziy
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Signaling protein
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PDB id
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2ziy
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References listed in PDB file
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Key reference
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Title
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Crystal structure of squid rhodopsin with intracellularly extended cytoplasmic region.
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Authors
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T.Shimamura,
K.Hiraki,
N.Takahashi,
T.Hori,
H.Ago,
K.Masuda,
K.Takio,
M.Ishiguro,
M.Miyano.
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Ref.
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J Biol Chem, 2008,
283,
17753-17756.
[DOI no: ]
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PubMed id
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Abstract
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G-protein-coupled receptors play a key step in cellular signal transduction
cascades by transducing various extracellular signals via G-proteins. Rhodopsin
is a prototypical G-protein-coupled receptor involved in the retinal visual
signaling cascade. We determined the structure of squid rhodopsin at 3.7A
resolution, which transduces signals through the G(q) protein to the
phosphoinositol cascade. The structure showed seven transmembrane helices and an
amphipathic helix H8 has similar geometry to structures from bovine rhodopsin,
coupling to G(t), and human beta(2)-adrenergic receptor, coupling to G(s).
Notably, squid rhodopsin contains a well structured cytoplasmic region involved
in the interaction with G-proteins, and this region is flexible or disordered in
bovine rhodopsin and human beta(2)-adrenergic receptor. The transmembrane
helices 5 and 6 are longer and extrude into the cytoplasm. The distal C-terminal
tail contains a short hydrophilic alpha-helix CH after the palmitoylated
cysteine residues. The residues in the distal C-terminal tail interact with the
neighboring residues in the second cytoplasmic loop, the extruded transmembrane
helices 5 and 6, and the short helix H8. Additionally, the Tyr-111, Asn-87, and
Asn-185 residues are located within hydrogen-bonding distances from the nitrogen
atom of the Schiff base.
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Figure 1.
FIGURE 1. Structural sequence alignment of squid rhodopsin,
bovine rhodopsin and β[2]AR. The structural alignment was based
on the 3D-Coffee alignment (4). Residues on helix regions are
colored red, and residue(s) of helix bending are colored in
blue. Transmembrane helical regions (TH1–TH7) and helix H8
with extracellular (EL1–EL3) and cytoplasmic (CL1–CL3)
loops, and each helix in N- and C-terminal tails (NH and CH) are
indicated. Posttranslational modifications are shaded by the
following colors: cyan, N-glycosylation; a pair of pink or
green, disulfide bridge(s); yellow, palmitoylated cysteine;
blue, Schiff-based lysine with 11-cis-retinal; gold, N-terminal
methionine acetylation. Residues indicated by small letters are
not in models but in crystal protein samples, and residues
indicated by small letters in italic gray do not exist in the
crystal sample proteins due to expression processing, protease
digestion, or protein engineering. Squ_rhod, squid rhodopsin
(PDB code: 2ZIY in this study); Bov_rhod, bovine rhodopsin (1F88
(5) or 1GZM (17)); and ADRB2 (2RH1 (8)).
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Figure 2.
FIGURE 2. Crystal structure of squid rhodopsin. A,
schematic model of squid rhodopsin with multicolored cylindrical
helices. Transmembrane helices are indicated as TH1–TH7, and
amphipathic short helix H8 is indicated as H8. 11-cis-Retinal at
Lys-305 and palmitoylated cysteines Cys-336 and Cys-337 are
indicated by the yellow sphere-and-stick models. A hydrophilic
short helix in each N- and C-terminal tail is indicated as NH
and CH, respectively. N and C termini are indicated by the
letters N and C, and the cytoplasmic loop 3 is indicated as CL3.
Putative transmembrane-spanning regions are indicated by yellow
belts. B, superimposed schematic models and electrostatic
surfaces of known GPCR structures. Superimposed schematic
structures of squid and bovine rhodopsins, and β[2]AR are
shown. Squid rhodopsin in this study is shown in orange, bovine
rhodopsin in the trigonal crystal (1GZM) (17) is blue, and
β[2]AR (2RH1) excluding the T4 lysozyme part of CL3 (8) is sky
blue. The electrostatic surfaces of squid rhodopsin (Squ Rhod),
bovine rhodopsin in the trigonal crystal (Bov Rhod), and β[2]AR
(β2AR) are represented in blue (positive) to red (negative)
with the squid rhodopsin structure in an orange schematic. To
clarify the contribution of the distal C-terminal tail, the
electrostatic surface of squid rhodopsin without the C-terminal
tail after Glu-343 was also calculated (Squ C-trc). Different
TH5 regions are indicated by the red line.
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The above figures are
reprinted
by permission from the ASBMB:
J Biol Chem
(2008,
283,
17753-17756)
copyright 2008.
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