The phospho‐opsin Phosphatase from Bovine Rod Outer Segments

King, Alastair J.; Andjelković, Nataša; Hemmings, Brian A.; Akhtar, Muhammad

doi:10.1111/j.1432-1033.1994.00383.x

Cited by 32 publications

(28 citation statements)

References 34 publications

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“…These results support the identification of the GRP as an oligomeric form of PP-2A and suggest a potential subunit structure of ABaC. Interestingly, PP-2A of this subunit composition, the most prevalent soluble form of PP-2A in bovine brain extracts (27), was recently identified as the principle soluble rhodopsin phosphatase of rod outer segments (28). However, we observe negligible soluble GRP activity.…”

Section: Methodssupporting

confidence: 88%

The G-protein-coupled receptor phosphatase: a protein phosphatase type 2A with a distinct subcellular distribution and substrate specificity.

Pitcher

Payne

Csortos

et al. 1995

Proc. Natl. Acad. Sci. U.S.A.

169

138

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Phosphorylation of G-protein-coupled receptors plays an important role in regulating their function. In this study the G-protein-coupled receptor phosphatase (GRP) capable of dephosphorylating G-protein-coupled receptor kinase-phosphorylated receptors is described. The GRP activity of bovine brain is a latent oligomeric form of protein phosphatase type 2A (PP-2A) exclusively associated with the particulate fraction. GRP activity is observed only when assayed in the presence of protamine or when phosphatase-containing fractions are subjected to freeze/thaw treatment under reducing conditions. Consistent with its identification as a member of the PP-2A family, the GRP is potently inhibited by okadaic acid but not by 1-2, the specific inhibitor of protein phosphatase type 1. Solubilization of the membrane-associated GRP followed by gel filtration in the absence of detergent yields a 150-kDa peak of latent receptor phosphatase activity. Western blot analysis of this phosphatase reveals a likely subunit composition of ABaC. of this subunit composition has previously been characterized as a soluble enzyme, yet negligible soluble GRP activity was observed. The subcellular distribution and substrate specifi'city of the GRP suggests significant differences between it and previously characterized forms of PP-2A.Exposure of the f32-adrenergic receptor (,BAR) receptor to agonists results in a rapid decline in receptor responsiveness, a process that appears to involve receptor phosphorylation (1, 2). In addition to the second messenger-dependent protein kinases (1), agonist-specific phosphorylation of this receptor can also be effected by the P3AR kinase (PARK), a member of the family of second messenger-independent G-proteincoupled receptor kinases (GRKs).Despite the considerable progress that has been made in identifying and characterizing the mechanism of action of ,BARK, little is known of the phosphatases responsible for reversing this phosphorylation event. Resensitization, presumably due to dephosphorylation of the ,BAR, has been shown to occur rapidly upon removal of agonists (3). Regulation of receptor phosphatase activity, therefore, represents an important potential mechanism for modulating receptor function.In this study, we characterize the f3ARK-phosphorylated P3AR phosphatase present in extracts ofbovine brain. This phosphatase activity, which is also capable of dephosphorylating ,BARKphosphorylated a2C2-adrenergic receptors (a2C2ARs) and rhodopsin kinase (RK)-phosphorylated rhodopsin, is termed the G-protein-coupled receptor phosphatase (GRP). The enzyme, an oligomeric form of protein phosphatase type 2A (PP-2A), is latent and specifically associated with the particulate fraction. MATERIALS AND METHODSPreparation of 32P-Labeled Substrates. Purified reconstituted P3AR (200 nM) (4-6) was phosphorylated (500-,ul reaction volume) with purified PARK, PAR kinase 2 (I3ARK-2), RK (7), or cAMP-dependent protein kinase (PKA) (125 nM) as described (8). Reactions were terminated after incubation at 30°C for 20 m...

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Section: Methodssupporting

confidence: 88%

The G-protein-coupled receptor phosphatase: a protein phosphatase type 2A with a distinct subcellular distribution and substrate specificity.

Pitcher

Payne

Csortos

et al. 1995

Proc. Natl. Acad. Sci. U.S.A.

169

138

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“…The PP2A enzyme assay was optimized for phosducin dephosphorylation and may not have contained all the essential factors necessary for optimal opsin dephosphorylation. Protamine and dopamine have been shown to influence opsin dephosphorylation by PP2A (24,77). It has been suggested that, before Ser334 of opsin can be dephosphorylated, opsin must first be regenerated with 11-cis-retinal (78).…”

Section: Discussionmentioning

confidence: 99%

Light-Driven Translocation of the Protein Phosphatase 2A Complex Regulates Light/Dark Dephosphorylation of Phosducin and Rhodopsin

et al. 2002

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In steps of protein purification of bovine retinal protein phosphatase 2A (PP2A), phosducin dephosphorylation activity peaks coelute with a PP2A enzyme complex, shown by peptide sequence analysis to contain a B′ subunit, B56epsilon. Other PP2A complexes with a slightly larger (56.5 kDa) B′ subunit (sequenced to be B56alpha) or with the BR regulatory subunit have no phosducin dephosphorylation activity. Upon exposure to light, a significant increase in the immunoreactive protein level of the A, C, and B56epsilon PP2A subunits is observed in the cytosolic fraction of mouse retina, the phosducin dephosphorylation of which occurs rapidly. During dark exposure, these subunits translocate to the membrane fraction where rhodopsin is slowly dephosphorylated. This PP2A redistribution occurs in less than 1.5 min and is dependent upon light and not upon an intrinsic circadian rhythm. Forty times more of the A subunit (∼20 ng/mouse retina) and 9 times more of the C subunit (∼4 ng/mouse retina) than of the B56epsilon subunit (∼0.45 ng/mouse retina) redistribute, which suggests that the predominant form of the PP2A enzyme complex on the membrane in the dark is a dimer, consisting of only A and C subunits. We observe that the dimer favors phosphorylated opsin as a substrate, while the trimer, particularly the enzyme complex with the B56epsilon subunit, greatly prefers phosphorylated phosducin, with an activity several hundred times those of other substrates that were tested. This light-driven PP2A translocation provides a potential mechanism for efficient dephosphorylation of two critical photoreceptor transduction proteins, cytosolic phosducin and membrane-bound rhodopsin, by the same enzyme.

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“…The stimulation of PP2A activity by trifluoperazine observed in our experiments is in contrast with the observations of Stewart et al (1983) who found no effect of trifluoperazine on PP2A activity towards protein phosphatase inhibitor-I . Substrate-related effects, similar to those described for stimulation of PP2A activity towards phosphoopsin by protamine (King et al, 1994), could account for this discrepancy. Thus, some properties of CAOP resemble those of PP2B (activation by Ca'+, sensitivity to trifluoperazine).…”

Section: Identity Of Caopmentioning

confidence: 70%

Calcium‐activated Opsin Phosphatase Activity in Retinal Rod Outer Segments

Kutuzov

Bennett

1996

European Journal of Biochemistry

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We describe the presence in bovine retinal rod outer segments of a phosphatase which dephosphorylates phosphoopsin with an efficiency similar to that of PP2A, and which is stimulated by submicromolar levels of CaZ (half-maximal activation, 0.4-0.5 pM). This enzyme is designated Ca'+-activated opsin phosphatase (CAOP). CAOP has a molecular mass of 70-75 kDa as determined by gel filtration on Superose 12 and exhibits reversible Ca2+-dependent oligomerization. An unidentified protein of approximately 25 kDa is necessary for full activity of CAOP and for cooperative binding of Ca'+ ( h > 2). CAOP does not require MgZ+ and is inhibited by okadaic acid (median inhibitory concentration > 25 FM), which suggests that it is related to the PP1/2A/2B class of protein phosphatases. Like PP2B, CAOP is inhibited by trifluoperazine (median inhibitory concentration 40 pM), but calmodulin has no effect on CAOP activity, and CAOP is inhibited by mastoparan at much higher concentrations than PP2B. This combination of properties suggests that CAOP is not identical to any characterized protein phosphatase. Since the cytoplasmic concentration of Ca'+ in retinal rod outer segments is reduced upon excitation by light, the existence of a Ca2+-sensitive opsin phosphatase activity suggests that light-dependent Ca'' levels may control rhodopsin dephosphorylation.

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The phospho‐opsin Phosphatase from Bovine Rod Outer Segments

Cited by 32 publications

References 34 publications

The G-protein-coupled receptor phosphatase: a protein phosphatase type 2A with a distinct subcellular distribution and substrate specificity.

The G-protein-coupled receptor phosphatase: a protein phosphatase type 2A with a distinct subcellular distribution and substrate specificity.

Light-Driven Translocation of the Protein Phosphatase 2A Complex Regulates Light/Dark Dephosphorylation of Phosducin and Rhodopsin

Calcium‐activated Opsin Phosphatase Activity in Retinal Rod Outer Segments

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