Evidence against dopamine D1/D2 receptor heteromers.

Hetero-oligomers of G-protein-coupled receptors have become the subject of intense investigation, because their purported potential to manifest signaling and pharmacological properties that differ from the component receptors makes them highly attractive for the development of more selective pharmacological treatments. In particular, dopamine D1 and D2 receptors have been proposed to form hetero-oligomers that couple to Gαq proteins, and SKF83959 has been proposed to act as a biased agonist that selectively engages these receptor complexes to activate Gαq and thus phospholipase C. D1/D2 heteromers have been proposed as relevant to the pathophysiology and treatment of depression and schizophrenia. We used in vitro bioluminescence resonance energy transfer, ex vivo analyses of receptor localization and proximity in brain slices, and behavioral assays in mice to characterize signaling from these putative dimers/oligomers. We were unable to detect Gαq or Gα11 protein coupling to homomers or heteromers of D1 or D2 receptors using a variety of biosensors. SKF83959-induced locomotor and grooming behaviors were eliminated in D1 receptor knockout (KO) mice, verifying a key role for D1-like receptor activation. In contrast, SKF83959-induced motor responses were intact in D2 receptor and Gαq KO mice, as well as in knock-in mice expressing a mutant Ala(286)-CaMKIIα that cannot autophosphorylate to become active. Moreover, we found that, in the shell of the nucleus accumbens, even in neurons in which D1 and D2 receptor promoters are both active, the receptor proteins are segregated and do not form complexes. These data are not compatible with SKF83959 signaling through Gαq or through a D1/D2 heteromer and challenge the existence of such a signaling complex in the adult animals that we used for our studies.

Calmodulin kinase and a calmodulin-binding 'IQ' domain facilitate L-type Ca2+ current in rabbit ventricular myocytes by a common mechanism.

1. Ca2+-calmodulin-dependent protein kinase II (CaMK) and a calmodulin (CaM)-binding 'IQ' domain (IQ) are both implicated in Ca2+-dependent regulation of L-type Ca2+ current (I(Ca)). We used an IQ-mimetic peptide (IQmp), under conditions in which CaMK activity was controlled, to test the relationship between these CaM-activated signalling elements in the regulation of L-type Ca2+ channels (LTCCs) and I(Ca) in rabbit ventricular myocytes. 2. A specific CaMK inhibitory peptide nearly abolished I(Ca) facilitation, but the facilitation was 'rescued' by cell dialysis with IQmp. 3. IQmp significantly enhanced I(Ca) facilitation and slowed the fast component of I(Ca) inactivation, compared with an inactive control peptide. Neither effect could be elicited by a more avid CaM-binding peptide, suggesting that generalized CaM buffering did not account for the effects of IQmp. 4. I(Ca) facilitation was abolished and the fast component of inactivation eliminated by ryanodine, caffeine or thapsigargin, suggesting that the sarcoplasmic reticulum (SR) is an important source of Ca2+ for I(Ca) facilitation and inactivation. IQmp did not restore I(Ca) facilitation under these conditions. 5. Engineered Ca2+-independent CaMK and IQmp each markedly increased LTCC open probability (P(o)) in excised cell membrane patches. The LTCC P(o) increases with CaMK and IQmp were non-additive, suggesting that CaMK and IQmp are components of a shared signalling pathway. 6. Both CaMK and IQmp induced a modal gating shift in LTCCs that favoured prolonged openings, indicating that CaMK and IQmp affect LTCCs through a common biophysical mechanism. 7. These findings support the hypothesis that CaMK is required for physiological I(Ca) facilitation in cardiac myocytes. Both CaMK and IQmp were able to induce a modal gating shift in LTCCs, suggesting that each of these signalling elements is important for Ca2+-CaM-dependent LTCC facilitation in cardiac myocytes.

Is persistent activity of calcium/calmodulin-dependent kinase required for the maintenance of LTP?

Calcium/calmodulin-dependent protein kinase II (CaMKII) is concentrated in the postsynaptic density (PSD) and plays an important role in the induction of long-term potentiation (LTP). Because this kinase is persistently activated after the induction, its activity could also be important for LTP maintenance. Experimental tests of this hypothesis, however, have given conflicting results. In this paper we further explore the role of postsynaptic CaMKII in induction and maintenance of LTP. Postsynaptic application of a CaMKII inhibitor [autocamtide-3 derived peptide inhibitor (AC3-I), 2 mM] blocked LTP induction but had no detectable affect on N-methyl-D-aspartate (NMDA)-mediated synaptic transmission, indicating that the primary function of CaMKII in LTP is downstream from NMDA channel function. We next explored various methodological factors that could account for conflicting results on the effect of CaMKII inhibitors on LTP maintenance. In contrast to our previous work, we now carried out experiments at higher temperature (33 degrees C), used slices from adult animals, and induced LTP using a tetanic stimulation. However, we still found that LTP maintenance was not affected by postsynaptic application of AC3-I. Furthermore the inhibitor did not block LTP maintenance under conditions designed to enhance the Ca(2+)-dependent activity of protein phosphatases 1 and 2B (elevated Ca(2+), calmodulin, and an inhibitor of protein kinase A). We also tested the possibility that CaMKII inhibitor might not be able to affect CaMKII once it was inserted into the PSD. In whole-brain extracts, AC3-I blocked autophosphorylation of both soluble and particulate/PSD CaMKII with similar potencies although the potency of the inhibitor toward other CaMKII substrates varied. Thus we were unable to demonstrate a functional role of persistent Ca(2+)-independent CaMKII activity in LTP maintenance. Possible explanations of the data are discussed.

Calmodulin kinase is a molecular switch for cardiac excitation-contraction coupling.

Signaling between cell membrane-bound L-type Ca(2+) channels (LTCC) and ryanodine receptor Ca(2+) release channels (RyR) on sarcoplasmic reticulum (SR) stores grades excitation-contraction coupling (ECC) in striated muscle. A physical connection regulates LTCC and RyR in skeletal muscle, but the molecular mechanism for coordinating LTCC and RyR in cardiomyocytes, where this physical link is absent, is unknown. Calmodulin kinase (CaMK) has characteristics suitable for an ECC coordinating molecule: it is activated by Ca(2+)/calmodulin, it regulates LTCC and RyR, and it is enriched in the vicinity of LTCC and RyR. Intact cardiomyocytes were studied under conditions where CaMK activity could be controlled independently of intracellular Ca(2+) by using an engineered Ca(2+)-independent form of CaMK and a highly specific CaMK inhibitory peptide. CaMK reciprocally enhanced L-type Ca(2+) current and reduced release of Ca(2+) from the SR while increasing SR Ca(2+) content. These findings support the hypothesis that CaMK is required to functionally couple LTCC and RyR during cardiac ECC.

Agonist-regulated Interaction between alpha2-adrenergic receptors and spinophilin.

Previously, we demonstrated that the third intracellular (3i) loop of the heptahelical alpha2A-adrenergic receptor (alpha2A AR) is critical for retention at the basolateral surface of polarized Madin-Darby canine kidney II (MDCKII) cells following their direct targeting to this surface. Findings that the 3i loops of the D2 dopamine receptors interact with spinophilin (Smith, F. D., Oxford, G. S., and Milgram, S. L. (1999) J. Biol. Chem. 274, 19894-19900) and that spinophilin is enriched beneath the basolateral surface of polarized MDCK cells prompted us to assess whether alpha(2)AR subtypes might also interact with spinophilin. [35S]Met-labeled 3i loops of the alpha2A AR (Val(217)-Ala(377)), alpha2BAR (Lys(210)-Trp(354)), and alpha2CAR (Arg(248)-Val(363)) subtypes interacted with glutathione S-transferase-spinophilin fusion proteins. These interactions could be refined to spinophilin amino acid residues 169-255, in a region between spinophilin's F-actin binding and phosphatase 1 regulatory domains. Furthermore, these interactions occur in intact cells in an agonist-regulated fashion, because alpha2A AR and spinophilin coimmunoprecipitation from cells is enhanced by prior treatment with agonist. These findings suggest that spinophilin may contribute not only to alpha2 AR localization but also to agonist modulation of alpha2AR signaling.

Association of calcium/calmodulin-dependent kinase II with developmentally regulated splice variants of the postsynaptic density protein densin-180.

In a continuing search for proteins that target calcium/calmodulin-dependent protein kinase II (CaMKII) to postsynaptic density (PSD) substrates important in synaptic plasticity, we showed that the PSD protein densin-180 binds CaMKII. Four putative splice variants (A-D) of the cytosolic tail of densin-180 are shown to be differentially expressed during brain development. Densin-180 splicing affects CaMKII phosphorylation of specific serine residues. Variants A, B, and D, but not C, bind CaMKII stoichiometrically and with high affinity, mediated by a differentially spliced domain. Densin-180 differs from the previously identified CaMKII-binding protein NR2B in that binding does not strictly require CaMKII autophosphorylation. Binding of densin-180 and NR2B to CaMKII is noncompetitive, indicating different interaction sites on CaMKII. Expression of the membrane-targeted CaMKII-binding domain of densin-180 confers membrane localization to coexpressed CaMKII without requiring calcium mobilization, suggesting that densin-180 plays a role in the constitutive association of CaMKII with PSDs.

Mechanism and regulation of calcium/calmodulin-dependent protein kinase II targeting to the NR2B subunit of the N-methyl-D-aspartate receptor.

Calcium influx through the N-methyl-d-aspartate (NMDA)-type glutamate receptor and activation of calcium/calmodulin-dependent kinase II (CaMKII) are critical events in certain forms of synaptic plasticity. We have previously shown that autophosphorylation of CaMKII induces high-affinity binding to the NR2B subunit of the NMDA receptor (Strack, S., and Colbran, R. J. (1998) J. Biol. Chem. 273, 20689-20692). Here, we show that residues 1290-1309 in the cytosolic tail of NR2B are critical for CaMKII binding and identify by site-directed mutagenesis several key residues (Lys(1292), Leu(1298), Arg(1299), Arg(1300), Gln(1301), and Ser(1303)). Phosphorylation of NR2B at Ser(1303) by CaMKII inhibits binding and promotes slow dissociation of preformed CaMKII.NR2B complexes. Peptide competition studies imply a role for the CaMKII catalytic domain, but not the substrate-binding pocket, in the association with NR2B. However, analysis of monomeric CaMKII mutants indicates that the holoenzyme structure may also be important for stable association with NR2B. Residues 1260-1316 of NR2B are sufficient to direct the subcellular localization of CaMKII in intact cells and to confer dynamic regulation by calcium influx. Furthermore, mutation of residues in the CaMKII-binding domain in full-length NR2B bidirectionally modulates colocalization with CaMKII after NMDA receptor activation, suggesting a dynamic model for the translocation of CaMKII to postsynaptic targets.

Calmodulin kinase determines calcium-dependent facilitation of L-type calcium channels.

A dynamic positive feedback mechanism, known as 'facilitation', augments L-type calcium-ion currents (ICa) in response to increased intracellular Ca2+ concentrations. The Ca2+-binding protein calmodulin (CaM) has been implicated in facilitation, but the single-channel signature and the signalling events underlying Ca2+/CaM-dependent facilitation are unknown. Here we show that the Ca2+/CaM-dependent protein kinase II (CaMK) is necessary and possibly sufficient for ICa facilitation. CaMK induces a channel-gating mode that is characterized by frequent, long openings of L-type Ca2+ channels. We conclude that CaMK-mediated phosphorylation is an essential signalling event in triggering Ca2+/CaM-dependent ICa facilitation.

Protein phosphatases PP1 and PP2A are located in distinct positions in the Chlamydomonas flagellar axoneme.

We postulated that microcystin-sensitive protein phosphatases are integral components of the Chlamydomonas flagellar axoneme, positioned to regulate inner arm dynein activity. To test this, we took a direct biochemical approach. Microcystin-Sepharose affinity purification revealed a prominent 35-kDa axonemal protein, predicted to be the catalytic subunit of type-1 protein phosphatase (PP1c). We cloned the Chlamydomonas PP1c and produced specific polyclonal peptide antibodies. Based on western blot analysis, the 35-kDa PP1c is anchored in the axoneme. Moreover, analysis of flagella and axonemes from mutant strains revealed that PP1c is primarily, but not exclusively, anchored in the central pair apparatus, associated with the C1 microtubule. Thus, PP1 is part of the central pair mechanism that controls flagellar motility. Two additional axonemal proteins of 62 and 37 kDa were also isolated using microcystin-Sepharose affinity. Based on direct peptide sequence and western blots, these proteins are the A- and C-subunits of type 2A protein phosphatase (PP2A). The axonemal PP2A is not one of the previously identified components of the central pair apparatus, outer arm dynein, inner arm dynein, dynein regulatory complex or the radial spokes. We postulate PP2A is anchored on the doublet microtubules, possibly in position to directly control inner arm dynein activity.

Brain actin-associated protein phosphatase 1 holoenzymes containing spinophilin, neurabin, and selected catalytic subunit isoforms.

We previously characterized PP1bp134 and PP1bp175, two neuronal proteins that bind the protein phosphatase 1 catalytic subunit (PP1). Here we purify from rat brain actin-cytoskeletal extracts PP1(A) holoenzymes selectively enriched in PP1gamma(1) over PP1beta isoforms and also containing PP1bp134 and PP1bp175. PP1bp134 and PP1bp175 were identified as the synapse-localized F-actin-binding proteins spinophilin (Allen, P. B., Ouimet, C. C., and Greengard, P. (1997) Proc. Natl. Acad. Sci. U. S. A. 94, 9956-9561; Satoh, A., Nakanishi, H., Obaishi, H., Wada, M., Takahashi, K., Satoh, K., Hirao, K., Nishioka, H., Hata, Y., Mizoguchi, A., and Takai, Y. (1998) J. Biol. Chem. 273, 3470-3475) and neurabin (Nakanishi, H., Obaishi, H., Satoh, A., Wada, M., Mandai, K., Satoh, K., Nishioka, H. , Matsuura, Y., Mizoguchi, A., and Takai, Y. (1997) J. Cell Biol. 139, 951-961), respectively. Recombinant spinophilin and neurabin interacted with endogenous PP1 and also with each other when co-expressed in HEK293 cells. Spinophilin residues 427-470, or homologous neurabin residues 436-479, were sufficient to bind PP1 in gel overlay assays, and selectively bound PP1gamma(1) from a mixture of brain protein phosphatase catalytic subunits; additional N- and C-terminal sequences were required for potent inhibition of PP1. Immunoprecipitation of spinophilin or neurabin from crude brain extracts selectively coprecipitated PP1gamma(1) over PP1beta. Moreover, immunoprecipitation of PP1gamma(1) from brain extracts efficiently coprecipitated spinophilin and neurabin, whereas PP1beta immunoprecipitation did not. Thus, PP1(A) holoenzymes containing spinophilin and/or neurabin target specific neuronal PP1 isoforms, facilitating efficient regulation of synaptic phosphoproteins.

Cloning and characterization of B delta, a novel regulatory subunit of protein phosphatase 2A.

Variable regulatory subunits of protein phosphatase 2A (PP2A) modulate activity, substrate selectivity and subcellular targeting of the enzyme. We have cloned a novel member of the B type regulatory subunit family, B delta, which is most highly related to B alpha. B delta shares with B alpha epitopes previously used to generate subunit-specific antibodies. Like B alpha, but unlike B beta and B gamma which are highly brain-enriched, B delta mRNA and protein expression in tissues is widespread. B delta is a cytosolic subunit of PP2A with a subcellular localization different from B alpha and may therefore target a pool of PP2A holoenzymes to specific substrates.

Differential cellular and subcellular localization of protein phosphatase 1 isoforms in brain.

Protein phosphatase 1 (PP1) is a gene family with a number of important functions in brain. Association with a wide variety of regulatory/targeting subunits is thought to be instrumental in directing the phosphatase to specific subcellular locations and substrates. By using antibodies directed against specific PP1 isoforms, we asked whether PP1 isoforms are differentially distributed in brain. Immunoblotting detects in brain the PP1gamma2 isoform, which had previously been thought to be testis specific, in addition to alpha, beta, and gamma1 isoforms. PP1 isoform expression varies modestly in extracts from different subdissected brain regions and is relatively constant during postnatal development, except for an about twofold increase in PP1gamma2. By immunohistochemical analyses of rat brain, PP1beta and PP1gamma1 cellular expression is widespread but quite distinct from one another. Subcellular fractionation studies demonstrate that PP1beta and PP1gamma1 are selectively associated with different cytoskeletal elements: PP1beta with microtubules, PP1gamma1 with the actin cytoskeleton. Double-immunofluorescence labeling of cultured cortical neurons further reveals a strikingly different and nonoverlapping localization of PP1beta and PP1gamma1: whereas PP1beta localizes to a discrete area of the soma, PP1gamma1 is highly enriched in dendritic spines and presynaptic terminals of cultured neurons. These results show that PP1 isoforms are targeted to different neuronal cytoskeletal compartments with a high degree of specificity, presumably by isoform-specific association with regulatory/targeting proteins. Furthermore, the synaptic localization of PP1gamma1 indicates that it is this isoform that is involved in the regulation of synaptic phosphoproteins such as neurotransmitter receptors and ion channels implicated in synaptic plasticity.

CaM kinase augments cardiac L-type Ca2+ current: a cellular mechanism for long Q-T arrhythmias.

Early afterdepolarizations (EAD) caused by L-type Ca2+ current (ICa, L) are thought to initiate long Q-T arrhythmias, but the role of intracellular Ca2+ in these arrhythmias is controversial. Rabbit ventricular myocytes were stimulated with a prolonged EAD-containing action potential-clamp waveform to investigate the role of Ca2+/calmodulin-dependent protein kinase II (CaM kinase) in ICa,L during repolarization. ICa,L was initially augmented, and augmentation was dependent on Ca2+ from the sarcoplasmic reticulum because the augmentation was prevented by ryanodine or thapsigargin. ICa,L augmentation was also dependent on CaM kinase, because it was prevented by dialysis with the inhibitor peptide AC3-I and reconstituted by exogenous constitutively active CaM kinase when Ba2+ was substituted for bath Ca2+. Ultrastructural studies confirmed that endogenous CaM kinase, L-type Ca2+ channels, and ryanodine receptors colocalized near T tubules. EAD induction was significantly reduced in current-clamped cells dialyzed with AC3-I (4/15) compared with cells dialyzed with an inactive control peptide (11/15, P = 0.013). These findings support the hypothesis that EADs are facilitated by CaM kinase.

Autophosphorylation-dependent targeting of calcium/ calmodulin-dependent protein kinase II by the NR2B subunit of the N-methyl- D-aspartate receptor.

Activation and Thr286 autophosphorylation of calcium/calmodulindependent kinase II (CaMKII) following Ca2+ influx via N-methyl-D-aspartate (NMDA)-type glutamate receptors is essential for hippocampal long term potentiation (LTP), a widely investigated cellular model of learning and memory. Here, we show that NR2B, but not NR2A or NR1, subunits of NMDA receptors are responsible for autophosphorylation-dependent targeting of CaMKII. CaMKII and NMDA receptors colocalize in neuronal dendritic spines, and a CaMKII.NMDA receptor complex can be isolated from brain extracts. Autophosphorylation induces direct high-affinity binding of CaMKII to a 50 amino acid domain in the NR2B cytoplasmic tail; little or no binding is observed to NR2A and NR1 cytoplasmic tails. Specific colocalization of CaMKII with NR2B-containing NMDA receptors in transfected cells depends on receptor activation, Ca2+ influx, and Thr286 autophosphorylation. Translocation of CaMKII because of interaction with the NMDA receptor Ca2+ channel may potentiate kinase activity and provide exquisite spatial and temporal control of postsynaptic substrate phosphorylation.

Brain protein phosphatase 2A: developmental regulation and distinct cellular and subcellular localization by B subunits.

Protein phosphatase 2A (PP2A) is a heterotrimeric enzyme consisting of a catalytic subunit (C), a structural subunit (A), and a variable regulatory subunit (B). We have investigated the spatial and temporal expression patterns of three members of the B subunit family, Balpha, Bbeta, and Bgamma, both at the message level by using ribonuclease protection analysis and at the protein level by using specific antibodies. Although A, Balpha, and C protein are expressed in many tissues, Bbeta and Bgamma were detectable only in brain. Balpha, Bbeta, and Bgamma are components of the brain PP2A heterotrimer, because they copurified with A and C subunits on immobilized microcystin. Whereas Balpha and Bbeta are mainly cytosolic, Bgamma is enriched in the cytoskeletal fraction. In contrast to A, C, and Balpha, which are expressed at constant levels, Bbeta and Bgamma RNA and protein are developmentally regulated, with Bbeta levels decreasing and Bgamma levels increasing sharply after birth. RNA and immunoblot analyses of subdissected brain regions as well as immunohistochemistry demonstrated that B subunits are expressed in distinct but overlapping neuronal populations and cellular domains. These data indicate that B subunits confer tissue and cell specificity, subcellular localization, and developmental regulation to the PP2A holoenzyme. The Balpha-containing heterotrimer may be important in general neuronal functions that involve its partially nuclear localization. Holoenzymes containing B likely function in early brain development as well as in somata and processes of subsets of mature neurons. Bgamma may target PP2A to cytoskeletal substrates that are important in the establishment and maintenance of neuronal connections.

Protein serine/threonine phosphatase 1 and 2A associate with and dephosphorylate neurofilaments.

The phosphorylation state of neurofilaments plays an important role in the control of cytoskeletal integrity, axonal transport, and axon diameter. Immunocytochemical analyses of spinal cord revealed axonal localization of all protein phosphatase subunits. To determine whether protein phosphatases associate with axonal neurofilaments, neurofilament proteins were isolated from bovine spinal cord white matter by gel filtration. approximately 15% of the total phosphorylase a phosphatase activity was present in the neurofilament fraction. The catalytic subunits of PP1 and PP2A, as well as the A and B alpha regulatory subunits of PP2A, were detected in the neurofilament fraction by immunoblotting, whereas PP2B and PP2C were found exclusively in the low molecular weight soluble fractions. PP1 and PP2A subunits could be partially dissociated from neurofilaments by high salt but not by phosphatase inhibitors, indicating that the interaction does not involve the catalytic site. In both neurofilament and soluble fractions, 75% of the phosphatase activity towards exogenous phosphorylase a could be attributed to PP2A, and the remainder to PP1 as shown with specific inhibitors. Neurofilament proteins were phosphorylated in vitro by associated protein kinases which appeared to include protein kinase A, calcium/calmodulin-dependent protein kinase, and heparin-sensitive and -insensitive cofactor-independent kinases. Dephosphorylation of phosphorylated neurofilament subunits was mainly (60%) catalyzed by associated PP2A, with PP1 contributing minor activity (10-20%). These studies suggest that neurofilament-associated PP1 and PP2A play an important role in the regulation of neurofilament phosphorylation.

Carboxymethylation of nuclear protein serine/threonine phosphatase X.

Specific rabbit polyclonal antibodies against peptides corresponding to the highly homologous protein serine/threonine phosphatase 2A and X catalytic subunits (PP2A/C and PPX/C respectively) were used to investigate the cellular and subcellular distribution of PP2A/C and PPX/C, as well as their methylation state. Immunoblots of rat tissue extracts revealed a widespread distribution of these enzymes but particularly high levels of PP2A/C and PPX/C in brain and testes respectively. In addition, immunoblots of subcellular fractions and immunocytochemical analyses of rat brain sections demonstrated that PPX/C is predominantly localized to the nucleus, whereas PP2A/C is largely cytoplasmic. Treatment of nuclear extracts with alkali resulted in increased PPX/C immunoreactivity to a polyclonal antibody directed against the C-terminus; no change in PPX immunoreactivity was observed using an antibody against an internal peptide. Alkali treatment of brain and liver cytosolic and nuclear extracts did not change the molecular mass or the isoelectric point of PPX/C. Furthermore, tritiated PPX/C was immunoprecipitated from COS cell extracts incubated with the methyl donor S-adenosyl-l-[methyl-3H]methionine. Thus the increase in immunoreactivity probably results from removal of a carboxymethyl group from PPX/C, as has been shown previously for PP2A/C [Favre, Zolnierowicz, Turowski and Hemmings (1994) J. Biol. Chem. 269, 16311-16317]. Together, our results indicate that the PPX catalytic subunit is a predominantly nuclear phosphatase and is methylated at its C-terminus.

Association of brain protein phosphatase 1 with cytoskeletal targeting/regulatory subunits.

Protein phosphatase 1 catalytic subunit (PP1C) is highly enriched in isolated rat postsynaptic densities. Gel overlay analyses using digoxigenin (DIG)-labeled PP1C revealed four major rat brain PP1C-binding proteins (PP1bps) with molecular masses of approximately 216, 175, 134, and 75 kDa, which were (1) more abundant in brain than other rat tissues; (2) differentially expressed in microdissected brain regions; and (3) enriched in isolated cortex postsynaptic densities. PP1bp175, PP1bp134, PP1bp75, and PP1C were partially released from forebrain particulate extracts by incubation at low ionic strength, which destabilizes the actin cytoskeleton. Size-exclusion chromatography of solubilized extracts separated two main PP1 activities (approximately 600 and approximately 100 kDa). PP1bps and PP1C gamma1 were enriched in the approximately 600-kDa peak, but PP1C beta was enriched in the approximately 100-kDa peak. Furthermore, PP1bp175 and PP1bp134 exhibited lower binding of recombinant DIG-PP1C beta than recombinant DIG-PP1C gamma1 or DIG-PP1C alpha. Solubilized PP1bp175 and PP1bp134 interact with PP1C under native conditions, because they both (1) coeluted from size-exclusion and ion-exchange columns; (2) bound to microcystin-LR-Sepharose; and (3) coprecipitated using PP1C antibodies. Trypsinolysis of the approximately 600-kDa form of PP1 increased phosphorylase a phosphatase activity approximately fourfold, suggesting that interaction of PP1C with these PP1bps modulates its activity. Thus, brain PP1 activity is likely targeted to the cytoskeleton, including postsynaptic densities, by isoform-selective binding of PP1C to these targeting/regulatory subunits, contributing to the specificity of its physiological roles.

Differential inactivation of postsynaptic density-associated and soluble Ca2+/calmodulin-dependent protein kinase II by protein phosphatases 1 and 2A.

Autophosphorylation of Ca2+/calmodulin-dependent protein kinase II (CaMKII) at Thr286 generates Ca2+-independent activity. As an initial step toward understanding CaMKII inactivation, protein phosphatase classes (PP1, PP2A, PP2B, or PP2C) responsible for dephosphorylation of Thr286 in rat forebrain subcellular fractions were identified using phosphatase inhibitors/activators, by fractionation using ion exchange chromatography and by immunoblotting. PP2A-like enzymes account for >70% of activity toward exogenous soluble Thr286-autophosphorylated CaMKII in crude cytosol, membrane, and cytoskeletal extracts; PP1 and PP2C account for the remaining activity. CaMKII is present in particulate fractions, specifically associated with postsynaptic densities (PSDs); each protein phosphatase is also present in isolated PSDs, but only PP1 is enriched during PSD isolation. When isolated PSDs dephosphorylated exogenous soluble Thr286-autophosphorylated CaMKII, PP2A again made the major contribution. However, CaMKII endogenous to PSDs (32P autophosphorylated in the presence of Ca2+/calmodulin) was predominantly dephosphorylated by PP1. In addition, dephosphorylation of soluble and PSD-associated CaMKII in whole forebrain extracts was catalyzed predominantly by PP2A and PP1, respectively. Thus, soluble and PSD-associated forms of CaMKII appear to be dephosphorylated by distinct enzymes, suggesting that Ca2+-independent activity of CaMKII is differentially regulated by protein phosphatases in distinct subcellular compartments.

Translocation of autophosphorylated calcium/calmodulin-dependent protein kinase II to the postsynaptic density.

Calcium/calmodulin-dependent protein kinase II (CaMKII) undergoes calcium-dependent autophosphorylation, generating a calcium-independent form that may serve as a molecular substrate for memory. Here we show that calcium-independent CaMKII specifically binds to isolated postsynaptic densities (PSDs), leading to enhanced phosphorylation of many PSD proteins including the alpha-amino-3-hydroxy-5-methyl-4-isoxazole-propionic acid (AMPA)-type glutamate receptor. Furthermore, binding to PSDs changes CaMKII from a substrate for protein phosphatase 2A to a protein phosphatase 1 substrate. Translocation of CaMKII to PSDs occurs in hippocampal slices following treatments that induce CaMKII autophosphorylation and a form of long term potentiation. Thus, synaptic activation leads to accumulation of autophosphorylated, activated CaMKII in the PSD. This increases substrate phosphorylation and affects regulation of the kinase by protein phosphatases, which may contribute to enhancement of synaptic strength.