Phosphorylation at the Nuclear Localization Signal of Ca2+/Calmodulin-dependent Protein Kinase II Blocks Its Nuclear Targeting*

E. Kevin HeistDagger §, Mallika SrinivasanDagger , and Howard Schulman

From the Department of Neurobiology, Stanford University School of Medicine, Stanford, California 94305-5125

    ABSTRACT
Top
Abstract
Introduction
Procedures
Results
Discussion
References

Translocation of protein kinases with broad substrate specificities between different subcellular compartments by activation of signaling pathways is an established mechanism to direct the activity of these enzymes toward particular substrates. Recently, we identified two isoforms of Ca2+/calmodulin-dependent protein kinase II (CaM kinase II), which are targeted to the nucleus by an alternatively spliced nuclear localization signal (NLS). Here we report that cotransfection with constitutively active mutants of CaM kinase I or CaM kinase IV specifically blocks nuclear targeting of CaM kinase II as a result of phosphorylation of a Ser immediately adjacent to the NLS of CaM kinase II. Both CaM kinase I and CaM kinase IV are able to phosphorylate this Ser residue in vitro, and mutagenesis studies suggest that this phosphorylation is both necessary and sufficient to block nuclear targeting. Furthermore, we provide experimental evidence that introduction of a negatively charged residue at this phosphorylation site reduces binding of the kinase to an NLS receptor in vitro, thus providing a mechanism that may explain the blockade of nuclear targeting that we have observed in situ.

    INTRODUCTION
Top
Abstract
Introduction
Procedures
Results
Discussion
References

Phosphorylation and dephosphorylation reactions control a myriad of signal transduction processes within the cell including cell growth and differentiation, metabolic pathways, and gene expression. The specificity of some kinases mediating these reactions is attained by a strict substrate specificity that limits the action of these dedicated kinases to a single or limited number of potential targets. Other kinases, however, are able to phosphorylate a large number of proteins in vitro, so the in vivo specificity of these kinases must occur through a different mechanism. Examples of these multifunctional or general protein kinases include protein kinase A, protein kinase C, and the Ca2+/calmodulin-dependent protein kinase (CaM kinase)1 family consisting of CaM kinase I, CaM kinase II, and CaM kinase IV (reviewed in Refs. 1 and 2). All of these kinases are able to phosphorylate nuclear transcription factors in vitro at sites that either activate or repress gene expression and so all of these kinases have the capacity, at least theoretically, to alter cellular phenotype through changes in protein expression. Over the past decade, the evidence that this actually occurs in vivo is becoming increasingly strong; for example, there is now abundant evidence that protein kinase A mediates activation of the cyclic AMP response element-binding protein through phosphorylation of a key Ser residue (3, 4).

Nuclear localization of a kinase is necessary for phosphorylation of nuclear proteins such as transcription factors, although there are examples of transcription factors that are activated in the cytoplasm and then translocate to the nucleus (5, 6). The ability of the catalytic subunit of protein kinase A to be released from cytoplasmic tethering and then passively diffuse into the nucleus, where it can phosphorylate nuclear proteins such as cyclic AMP response element-binding protein, has been described (7). More recently, active export of protein kinase A out of the nucleus under certain conditions based on a nuclear export signal has also been reported (8). Regulation of protein kinase C localization appears to occur, at least in part, through isoform-specific targeting to anchoring proteins that are presumably located near its substrates (9). CaM kinase I has been localized predominantly to the cell cytoplasm, while CaM kinase IV is predominantly nuclear (10, 11), although the mechanisms governing the subcellular localization of these two kinases have not yet been elucidated.

Isoform-specific targeting of CaM kinase II to the nucleus based on an alternatively spliced nuclear localization sequence (NLS) has been described (12, 13). CaM kinase II is composed of a multigene family derived from four related genes: alpha , beta , gamma , and delta  (reviewed in Refs. 1 and 2). The alpha B, delta B, and gamma A isoforms of CaM kinase II all share a common core NLS amino acid sequence, KKRK, which is homologous to the NLS of the SV40 large T antigen (12). Nuclear localization of the delta B and alpha B isoforms of CaM kinase II both in situ and in vivo has been reported (12, 13); gamma A is also presumably a nuclear isoform, although this has not been investigated. Other isoforms of CaM kinase II do not contain any known NLS sequence and localize to the cytoplasm. Interestingly, CaM kinase II forms multimers of 8-12 subunits in situ and in vivo, and the final localization of the multimer to the nucleus or cytoplasm appears to be based on whether it is composed of predominantly nuclear or cytoplasmic isoforms (12). These multimers are of sufficient size (400-600 kDa) that any transport of intact holoenzyme across the nuclear membrane is likely to require an active, nuclear export signal or NLS-dependent process. Immunostaining of brain sections has demonstrated nuclear localization of CaM kinase II in regions with high expression levels of nuclear forms and cytoplasmic localization of the kinase in regions expressing predominantly cytoplasmic forms (13). Thus, like the other multifunctional protein kinases, CaM kinase II does appear to have access to the cell nucleus, but such access depends on the type and ratio of isoforms expressed.

Many different nuclear events have been ascribed to CaM kinase II. This kinase is capable of regulating nuclear envelope breakdown in sea urchin eggs (14), releasing Xenopus oocytes from meiotic metaphase arrest (15), promoting the maturation of oocytes (16), and blocking the cell cycle at the G2 to M transition (17). CaM kinase II has also been shown to activate the CCAAT enhancer element-binding protein beta  (C/EBPbeta ) (18) and recently has been shown to block activity of the transcription factor cyclic AMP response element-binding protein and either block or activate the related transcription factor ATF-1 through phosphorylation of both positive and negative regulatory sites (19-21). Many of these studies utilized a truncated mutant of CaM kinase II, which does not associate into holoenzymes and is able to diffuse freely between the nucleus and cytoplasm as a result of its small size. Presumably, nuclear localization of CaM kinase II would be required in order to mediate processes involving phosphorylation of nuclear transcription factors. A recent study demonstrates that, among three transfected isoforms of CaM kinase II, only the nuclear-targeted isoform is able to activate an atrial natriuretic factor promoter construct in cultured ventricular myocytes, while the two cytoplasmic isoforms of CaM kinase II do not affect expression of this construct (22).

Recently, autophosphorylation of cytoplasmic CaM kinase II was shown to cause translocation of the kinase to the postsynaptic density in cultured hippocampal neurons (23). We are interested in whether there are mechanisms other than isoform-specific expression that can affect the abililty of CaM kinase II to localize to the nucleus and, by doing so, be available to translate Ca2+ elevations into the processes described above. The capability of many NLS-containing proteins to translocate to the nucleus is affected either positively or negatively by phosphorylation (reviewed in Ref. 24). We have studied the ability of the other multifunctional kinases, protein kinase A, protein kinase C, CaM kinase I, and CaM kinase IV, to alter nuclear targeting of CaM kinase II through phosphorylation. We report here that CaM kinase I and CaM kinase IV are capable of phosphorylating a Ser residue immediately adjacent to the NLS of alpha B- and delta B-CaM kinase II and that this phosphorylation causes reduced binding to an NLS receptor and blocks targeting of CaM kinase II to the cell nucleus.

    EXPERIMENTAL PROCEDURES
Top
Abstract
Introduction
Procedures
Results
Discussion
References

Construction of CaM Kinase II Mutants-- The cloning of the alpha , alpha B, and delta B isoforms of CaM kinase II into the SRalpha eukaryotic expression vector has been described previously (12, 13, 25). Mutants of alpha B-CaM kinase II incorporating the following underlined Ser to Ala and Ser to Asp mutations adjacent to the NLS, KKRKAAAA (S332-335A), KKRKDDDD (S332-335D), KKRKSSSA (S335A) and KKRKSSAS (S334A) were generated by oligonucleotide-mediated, site-directed PCR mutagenesis of wild-type alpha B-CaM kinase II with subcloning of the amplified, mutant fragment back into its corresponding position in alpha B-CaM kinase II. The method for PCR site-directed mutagenesis has been described (26). Mutants of alpha B-CaM kinase II incorporating the following underlined Ser to Ala, Ser to Asp, and Ser to Glu mutants adjacent to the NLS, KKRKASSS (S332A), KKRKSASS (S333A), KKRKDSSS (S332D), KKRKESSS (S332E), KKRKSDSS (S333D), and KKRKSESS (S333E), were derived through oligonucleotide site-directed mutagenesis of alpha B-CaM kinase II according to the manufacturer's protocols (CLONTECH Transformer kit). All mutants described above code for proteins identical to full-length, wild-type alpha B-CaM kinase II except for the underlined mutations. A mutant incorporating the NLS of alpha B-CaM kinase II into the 5'-end of alpha -CaM kinase II was generated by annealing two 49-mers, 5'-GATGAATGATGGCGTGAAGAAAAGAAAGTCCAGTTCCAGCGTTGGAGCT-3' and 5'-CCAACGCTGGAACTGGACTTTCTTTTCTTCACGCCATCATTCATCTGCA-3', and then cloning this annealed multimer into the PstI and SacI sites of hemagglutinin-tagged alpha -CaM kinase II (27) (the tagged version of alpha -CaM kinase II was used because it contains 5'-cloning sites not present in untagged alpha -CaM kinase II). This produces a mutant that is identical to full-length alpha -CaM kinase II except for replacement of amino acid residues 2 and 3 from alpha -CaM kinase II with 13 amino acids encompassing residue numbers 324-336 of alpha B-CaM kinase II and four residues retained from the hemagglutinin tag. The 5'-sequence of this construct beginning with residue 1 is as follows: MNDGVKKRKSSSSVGAQLIT ... The underlined portion denotes the region derived from alpha B-CaM kinase II including the NLS, the portion in italics denotes the retained region from the hemagglutinin tag, and the portion in normal lettering following the italics resumes with residue 4 of alpha -CaM kinase II and continues uninterrupted through the remainder of the protein (not shown). All mutants were screened initially by restriction analysis and then verified by dideoxynucleotide sequencing. Restriction enzymes and oligonucleotides were obtained from Life Technologies, Inc.

Construction of CaM Kinase I, CaM Kinase IV, and Calmodulin Expression Constructs-- Human CaM kinase I clones, including 1) a full-length, wild-type clone, 2) a Ca2+/calmodulin-independent, truncated clone coding for residues 1-294, and 3) these same two constructs with an activating T177D mutation were a generous gift from A. Means (Duke University) (28). In order to clone these constructs into the SRalpha expression vector, the PstI site of SRalpha was cleaved and blunted with Klenow fragment, and an oligonucleotide linker containing a BglII site (Life Technologies, Inc.) was ligated into this site by standard techniques. The CaM kinase I clones were then cut with BamHI and EcoRI, producing fragments encoding the entire kinase reading frame, which was then cloned into the EcoRI and BglII sites of SRalpha . Rat CaM kinase IV, including a full-length, wild-type clone as well as a Ca2+-independent, truncated clone coding for residues 1-313 cloned into a pCMV expression vector was also a gift of A. Means (29). The full reading frame for CaM kinase IV was cloned out of this vector by cutting at the 5'-end of the coding region with NotI, blunting this site with T4 DNA polymerase, and then cutting the 3'-end with ApaI. This fragment was then cloned into the EcoRV and ApaI sites of SRalpha . A clone containing the entire reading frame of human calmodulin was a generous gift of P. Yaswen. SRalpha -calmodulin was created by cutting the 5'-end of this clone with NcoI, blunting with Klenow fragment, cutting the 3'-end with KpnI, and then cloning this fragment into the EcoRV and KpnI sites of SRalpha . All subcloning procedures were performed according to standard techniques, and all enzymes and buffers were obtained from Life Technologies and New England Biolabs Inc. SRalpha -protein kinase A was a gift of M. Muramatsu (DNAX, Palo Alto, CA). An expression vector for CaM kinase kinase was a generous gift of Thomas Soderling (30). SRalpha -protein kinase C and SRalpha -calcineurin have been described (31).

Cell Culture and Transfection-- COS-7 cells were maintained in Dulbecco's modified Eagle's medium with 10% supplemented calf serum (Hyclone Labs) in a 10% CO2 incubator as described previously (25). DNA was purified using the Qiagen and Merlin (Bio 101, Vista, CA) systems according to the manufacturer's protocols. Cells were plated onto 35-mm cell culture dishes (Falcon) on the day prior to transfection at a density such that they were approximately 70% confluent on the day of transfection. For each transfection, 1.5-1.75 µg of total DNA was combined with 5 µl of Lipofectamine (Life Technologies, Inc.), and transfection was carried out according to the manufacturer's recommendations. The transfection medium was replaced with Dulbecco's modified Eagle's medium plus 10% supplemented calf serum 5 h post-transfection, and the cells were then left in the incubator for a total of approximately 48 h post-transfection prior to fixation or harvest. For immunofluorescence studies, 0.25 µg of CaM kinase II was cotransfected with 1.25 µg of empty SRalpha vector, SRalpha -CaM kinase I, or SRalpha -CaM kinase IV. For cotransfections including calmodulin and/or CaM kinase kinase, 0.25 µg of CaM kinase II was cotransfected with 0.5 µg of CaM kinase I or IV with or without 0.5 µg of SRalpha -calmodulin with or without 0.5 µg of CaM kinase kinase. For NLS binding studies, 1.5 µg of CaM kinase II was used for transfection.

Immunocytofluorescence-- Fixation and staining of COS-7 cells were performed on 35-mm tissue culture dishes as described previously (12). Immunodetection of alpha -CaM kinase II and alpha B-CaM kinase II was performed with a monoclonal antibody that recognizes both isoforms of CaM kinase II. Immunodetection of hemagglutinin-tagged CaM kinase II was performed with a monoclonal antibody to this tag (Boehringer Mannheim). Secondary antibody detection with a rhodamine-linked goat anti-mouse antibody and fluorescence microscopy and photography were performed as described (12). In order to quantitate nuclear localization of the kinase, 100 transfected cells per plate were scored in a blinded fashion as to whether the kinase was predominantly nuclear or predominantly cytoplasmic. The identity of the nucleus was verified by comparative phase-contrast microscopy. Cells in which definitive localization of CaM kinase II staining could not be established (a small fraction of the total) were omitted from analysis.

Peptide Phosphorylation-- Purified CaM kinase I was a generous gift of A. Nairn (Rockefeller University), and purified CaM kinase IV was a generous gift of A. Means. Peptides with the amino acid sequences CGVKKRKSSSSVQMME and CGVKKRKASSSVQMME were generated on an automated peptide synthesizer. Phosphorylation of these peptides by CaM kinase I and CaM kinase IV was carried out for 5 min at 30 °C in a 50-µl reaction containing 50 mM PIPES, pH 7.5, 10 mM MgCl2, 0.5 mM CaCl2, 10 µg/ml calmodulin, 0.1 mg/ml bovine serum albumin, 20 µM [gamma -32P]ATP (2.5 Ci/mmol), and 50 µM peptide. Reactions were initiated by the addition of kinase and terminated by the addition of 10 µl of 30% trichloroacetic acid. Reaction mixes were then spotted onto P-81 phosphocellulose paper (Whatman), washed extensively with water, and then counted for Cerenkov radiation.

Protein Phosphorylation-- alpha B-CaM kinase II, made kinase-inactive with a K42M point mutation (referred to as alpha B-CaM kinase IIi) as well as alpha B-CaM kinase IIi with the S332A point mutation were expressed in COS-7 cells and purified as described (25, 31, 32). Phosphorylation of these two inactive mutants of alpha B-CaM kinase II by purified CaM kinase I was performed at 30 °C for 5 min in a 50-µl reaction mix containing 50 mM PIPES, pH 7.5, 1 mM dithiothreitol, 10 mM MgCl2, 50 µM [gamma -32P]ATP (2.5 Ci/mmol), 1 µM calmodulin, 1.2 mM CaCl2, and 0.1 mg/ml bovine serum albumin. Phosphorylation of these CaM kinase II mutants by purified CaM kinase IV was performed under similar conditions, except that bovine serum albumin was used at 1 mg/ml and the specific activity of [gamma -32P]ATP was 1.0 Ci/mmol. Equal amounts of purified alpha B-CaM kinase IIi with or without S332A were used in each reaction mix as verified by SDS-polyacrylamide gel electrophoresis and Coomassie staining of the CaM kinase II samples (data not shown). The concentration of CaM kinase II used between experiments ranged from 0.01 to 0.02 mg/ml. The phosphorylation reactions were initiated by adding either CaM kinase I or CaM kinase IV at a concentration of 5 µg/ml to the reaction mix and terminated by the addition of 5× Laemmli sample buffer. The reactions were then analyzed by SDS-polyacrylamide gel electrophoresis followed by autoradiography. Scanning densitometry was performed on an Arcus AGFA II scanner using NIH Image for data analysis. Phosphorylation of alpha B-CaM kinase IIi by either CaM kinase I or CaM kinase IV was quantified by densitometry and assigned the value of 100%; phosphorylation of alpha B-CaM kinase IIi S332A was divided by this value to determine its corresponding percentage of phosphorylation.

NLS Receptor Binding Experiments-- The NLS receptor (NLS-R) m-pendulin fused with a His6 tag within the bacterial expression vector pET-30a (Novagen) was a generous gift of S. Adam (Northwestern University, Chicago, IL) (33). The NLS-R construct was transformed into BL21 bacteria (Novagen) and grown in 200 ml of LB medium containing 50 µg/ml of kanamycin and amplified with 1 mM isopropyl beta -D-thiogalactopyranoside as described (33). The bacteria were pelleted, and the pellet was resuspended in 10 ml of 10% glycerol, 0.2% Nonidet P-40, 0.1 mM Tris (carboxyethyl)phosphine, 1 µg/ml leupeptin, 1 µg/ml aprotonin, 0.2 mM phenylmethylsulfonyl fluoride, 0.2 mM sodium metabisulfite and 1 µg/ml pepstatin A. The bacterial suspension was frozen with liquid nitrogen, thawed, and then sonicated for a total of 3 min on ice at a setting of 50 W. The lysate was then centrifuged for 30 min at 14,000 × g at 4 °C. The resulting supernatant was then filtered through a 0.45-µm filter, aliquoted, quick frozen with liquid N2, and then stored at -80 °C. The His6 NLS-R was complexed to Ni2+-containing agarose resin (Qiagen) at a ratio of 6 mg of NLS-R-containing lysate to 50 µl of resin for 60 min at 4 °C with tumbling in 1 ml of 20 mM Tris, pH 8.0, 500 mM NaCl, and 5 mM imidazole. The beads were then spun down and washed once in the same buffer and then three times in interaction buffer, a modification of a buffer used by Rexach and Blobel for NLS/NLS-R interaction (34) containing 40 mM Hepes, pH 7.0, 150 mM KOAc, 2 mM MgOAc, 20 mM imidazole, 0.1 mM TCEP, 0.1% Tween 20, 0.1% casaminoacids (Difco), 1 mM dithiothreitol, 0.1 mM phenylmethylsulfonyl fluoride, 1 µg/ml leupeptin, and 1 µg/ml pepstatin A. COS-7 cells transfected with alpha -CaM kinase II wild type, alpha B-CaM kinase II wild type, and mutants of alpha B-CaM kinase II containing the individual point mutations S332A, S332D, and S332E were lysed by sonication and centrifuged, and kinase activity in the soluble fraction was assayed as described (12). Kinase lysates were diluted in interaction buffer to produce equal concentrations of kinase based on the kinase activity assay, and these were then added to equal aliquots of the Ni2+-resin·NLS-R complexes (10 µl of resin per sample in 250 µl of interaction buffer) and tumbled at 4 °C for 60 min. After tumbling, the resin was spun down at 3,000 × g for 1 min and then washed four times over 15 min in interaction buffer. The resin pellets were then stripped of protein in 20 µl of buffer containing 40 mM Tris, pH 8.0, 100 mM EDTA, and 500 mM NaCl. The supernatants stripped from the beads were then run on a 9% denaturing polyacrylamide gel electrophoresis gel and transferred to nitrocellulose, and the resulting blots were subjected to Western blotting for alpha -isoforms of CaM kinase II as described previously (14). Each sample of kinase to be used for NLS-R binding was also subjected to Western blotting in parallel with the NLS-R-bound samples to ensure that kinase concentration as determined by kinase activity was equal to kinase level detected by Western blot. Densitometry and image analysis were performed as described above for phosphorylation experiments. For all quantitative analysis, the amount of each kinase that bound to the NLS-R·Ni2+-resin complex was divided by the amount of that kinase in the prebinding samples, and this ratio was compared for each kinase isoform and mutant analyzed, with the binding of wild type alpha B-CaM kinase II assigned the value of 100%. All chemicals used were obtained from Sigma except as indicated. For other NLS receptor constructs, His6-NPI-1 was a gift of S. Adam (33), GST-NPI-1 and GST-NPI-3 were gifts of R. O'Neil and P. Palese (35), and GST-karyopherin alpha  was a gift of M. Rexach and G. Blobel (Rockefeller University) (34).

    RESULTS
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Abstract
Introduction
Procedures
Results
Discussion
References

Cotransfection with CaM Kinase I or IV Blocks Nuclear Targeting of alpha B- and delta B-CaM Kinase II-- As we previously reported (12, 13), alpha -CaM kinase II, which lacks a functional NLS, localizes exclusively to the cytoplasm (Fig. 1A) when transfected into COS-7 cells, while alpha B-CaM kinase II, which contains an NLS, localizes almost entirely to the cell nucleus (Fig. 1B and Table I). We next sought to determine whether the activation of any known signal transduction pathway could alter the localization of alpha B-CaM kinase II to the nucleus. In order to do this, alpha B-CaM kinase II was cotransfected into COS-7 cells with cDNA constructs encoding several different protein kinases: the catalytic subunit of protein kinase A and constitutively active truncation mutants of CaM kinase I, CaM kinase IV, protein kinase Cbeta , and the protein phosphatase calcineurin. After 48 h, the localization of CaM kinase II was determined by immunofluorescence using a monoclonal antibody that recognizes alpha -CaM kinase II isoforms. No effect on the nuclear localization of alpha B-CaM kinase II was noted when cotransfected with protein kinase A, protein kinase C, or calcineurin (data not shown). However, when cotransfected with constitutive, Ca2+/calmodulin-independent mutants of CaM kinase I or CaM kinase IV, the localization of alpha B-CaM kinase II was almost completely cytoplasmic (Fig. 1, C and D, and Table I). In order to determine whether this effect was cell type-specific, we performed similar experiments in PC12 cells (a rat pheochromocytoma cell line) and HEK-293 cells (a human kidney cell line) and found a similar blockade of alpha B-CaM kinase II nuclear targeting by CaM kinase I and CaM kinase IV (data not shown). COS-7 cells transfected only with CaM kinase I or CaM kinase IV did not show any detectable immunofluorescence when stained with the CaM kinase II antibody, ruling out the possibility that antibody cross-reactivity with CaM kinase I or CaM kinase IV was the basis for this result (data not shown).


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Fig. 1.   Localization of wild-type alpha B-CaM kinase II cotransfected with vector, CaM kinase I, or CaM kinase IV. Wild-type alpha B-CaM kinase II was cotransfected into COS-7 cells at a 1:5 ratio with empty vector (B) or with Ca2+-independent mutants of CaM kinase I (C) or CaM kinase IV (D). Localization of wild-type alpha -CaM kinase II cotransfected with vector was included for comparison (A). The subcellular localization of the CaM kinase II was determined approximately 48 h post-transfection by immunostaining with an anti-alpha -CaM kinase II monoclonal antibody as described under "Experimental Procedures."

                              
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Table I
Nuclear localization of CaM kinase II mutants coexpressed with CaM kinase I and CaM kinase IV
Wild-type alpha B-CaM kinase II as well as the listed Ser to Ala mutants were cotransfected into COS-7 cells with vector alone or with constitutively active mutants of CaM kinase I or CaM kinase IV. The localization of CaM kinase II within the cell nucleus or cytoplasm was determined by immunostaining as described under "Experimental Procedures" 48 h after transfection. 100 cells were counted in a blinded fashion for each combination listed, and the percentage of transfected cells with predominantly nuclear staining is listed.

The effect of constitutive CaM kinase I and CaM kinase IV on nuclear targeting was seen with another nuclear isoform of CaM kinase II detected with the use of a different primary antibody. We tested the effect of these kinases on targeting of delta B-CaM kinase II, which also contains a functional NLS and has been shown to target to the nucleus when transfected into COS-7 cells (12). In this experiment, using epitope-tagged delta B-CaM kinase II and an anti-tag antibody for immunostaining, constitutively active CaM kinase I and CaM kinase IV were able to block nuclear targeting of delta B-CaM kinase II as effectively as was seen with alpha B-CaM kinase II (data not shown).

The Blockade of CaM Kinase II Nuclear Targeting Is Specific-- In order to determine whether CaM kinase I and CaM kinase IV exert a specific block on nuclear targeting of CaM kinase II or instead block nuclear import in a general fashion, we cotransfected constitutive CaM kinase I or CaM kinase IV into COS-7 cells with fos-LacZ, a fusion of the transcription factor fos with LacZ (beta -galactosidase) that localizes to the nucleus as a result of a bipartite NLS derived from the fos protein (36). We found that nuclear localization of the fos-LacZ fusion protein was preserved when cotransfected into COS-7 cells under conditions identical to those in the experiments involving blockade of CaM kinase II nuclear targeting (data not shown). This suggests that CaM kinase I and CaM kinase IV exert a specific blockade on nuclear localization of CaM kinase II rather than a generalized blockade of nuclear import.

The First Ser following the NLS Is Required for Blockade of Nuclear Targeting-- Blockade of nuclear import by phosphorylation of residues adjacent to an NLS has been seen for some but not all nuclear targeted proteins (Table II; reviewed in Ref. 24). We therefore sought to determine whether nuclear targeted isoforms of CaM kinase II have any possible phosphorylation sites adjacent to the NLS. As can be seen in Fig. 2, both alpha B-CaM kinase II and delta B-CaM kinase II, which have been shown to be targeted to the nucleus, as well as gamma A-CaM kinase II, which has an identical NLS, all have a string of four Ser residues immediately following the core NLS sequence KKRK. These four Ser residues correspond to residues 332-335 in both alpha B-CaM kinase II and delta B-CaM kinase II and to residues 355-358 in gamma A-CaM kinase II. In order to determine whether phosphorylation of one or more of these Ser residues is responsible for blockade in nuclear targeting by CaM kinase I and CaM kinase IV, we mutated all four Ser residues to Ala (S332-335A) in alpha B-CaM kinase II. Like wild-type alpha B-CaM kinase II, this mutant localizes almost entirely to the nucleus when transfected into COS-7 cells. Unlike alpha B-CaM kinase II, however, nuclear targeting of this quadruple Ser to Ala mutant is not blocked by cotransfection with constitutive CaM kinase I or CaM kinase IV (Fig. 3 and Table I). To determine if only one Ser is responsible for this effect, we next mutated each of the four Ser residues individually to Ala. The mutant in which the first Ser following the NLS was mutated to Ala (S332A) shows nuclear targeting that is not affected by coexpression with CaM kinase I or CaM kinase IV and is indistinguishable from the targeting of the mutant with all four Ser residues mutated to Ala. In contrast, the other three mutants with single Ser to Ala mutations two, three, and four residues following the NLS (S333A, S334A, and S335A, respectively) behave like wild-type alpha B-CaM kinase II and are blocked from entering the nucleus by CaM kinase I and CaM kinase IV. Immunostaining of the alpha B-CaM kinase II S332A and S333A mutants with and without CaM kinase I or CaM kinase IV is shown in Fig. 3, and compiled data for all mutants are displayed in Table I.

                              
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Table II
Examples of inhibition of NLS function by phosphorylation


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Fig. 2.   Comparison of the NLS sequences of nuclear targeted isoforms of CaM kinase II with the SV40 T antigen (T Ag). The nuclear localization sequence and neighboring residues of the SV40 large T antigen is compared with the three nuclear targeted isoforms of CaM kinase II: alpha B, delta B, and gamma A. The consensus NLS for these respective proteins with the amino acid sequence KKRK is highlighted in boldface type. These regions correspond to residues 124-137 of the SV40 large T antigen, residues 324-337 of both alpha B- and delta B-CaM kinase II, and residues 347-360 of gamma A-CaM kinase II.


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Fig. 3.   Effect of Ser to Ala mutations on the localization of alpha B-CaM kinase II cotransfected with CaM kinase I and CaM kinase IV. Mutants of alpha B-CaM kinase II containing the underlined Ser to Ala mutations (arranged by row) within the string of four Ser residues immediately following the NLS were cotransfected into COS-7 cells with a 1:5 ratio of vector alone (first column) or with Ca2+-independent mutants of CaM kinase I (second column) or CaM kinase IV (third column). Immunostaining for CaM kinase II was performed approximately 48 h post-transfection as described for Fig. 1.

A Negative Charge following the NLS Is Sufficient for Blockade of Nuclear Targeting-- The preceding experiments clearly show that the Ser immediately following the CaM kinase II NLS is essential for blockade of nuclear targeting by CaM kinase I and CaM kinase IV and might be a target for phosphorylation by these kinases. To determine if a negative charge adjacent to the NLS of CaM kinase II is sufficient to block nuclear targeting of the kinase, we generated a mutant of alpha B-CaM kinase II in which all four Ser resides following the NLS are mutated to Asp (S332-335D) to mimic the negative charge that phosphorylation of these residues would produce. When transfected into COS-7 cells, this mutant localized to the cytoplasm, consistent with the hypothesis that phosphorylation of one or more of these residues could block nuclear targeting of CaM kinase II (data not shown). In order to further examine this effect, we individually mutated Ser332 and Ser333 to both Asp and Glu. Mutation of Ser332 to either Asp or Glu caused the kinase to be localized entirely to the cytoplasm when transfected into COS-7 cells (Fig. 4, A and B), while mutation of Ser333 to Asp or Glu resulted in mutants with entirely normal nuclear localization (Fig. 4, C and D). 100 cells from each mutant were scored blindly for nuclear or cytoplasmic localization of the kinase as described for the experiments in Table I, and all 100 of the cells transfected with the S332D or S332E mutant of alpha B-CaM kinase II were scored as having cytoplasmic localization of the kinase, while all 100 of the cells transfected with the S333D or S333E mutant were scored as having nuclear localized kinase. Thus, a negatively charged residue replacing the first Ser following the NLS abolishes nuclear targeting of alpha B-CaMK II, while a negative charge at the second position does not appreciably alter nuclear targeting.


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Fig. 4.   Localization of alpha B-CaM kinase II mutants containing Ser to Asp and Ser to Glu mutations adjacent to the NLS. Mutants of alpha B-CaM kinase II containing the underlined Ser to Asp and Ser to Glu mutations within the two Ser residues immediately adjacent to the NLS were transfected into COS-7 cells. A, KKRKDSSS (S332D); B, KKRKESSS (S332E); C, KKRKSDSS (S333D); D, KKRKSESS (S333E). Localization of the kinase was determined by immunostaining 48 h after transfection as described under "Experimental Procedures."

CaM Kinases I and IV Can Phosphorylate the Ser Adjacent to the NLS of CaM Kinase II in Vitro-- A study by Miyano et al. (37), which did not address nuclear targeting, demonstrated that a peptide encompassing the NLS and four adjacent Ser residues of gamma A-CaM kinase II was a substrate for CaM kinase IV and that this phosphorylation was on the first Ser. In order to determine if CaM kinase I could also phosphorylate this site, we synthesized peptides derived from delta B-CaM kinase II with the amino acid sequence CGVKKRKSSSSVQMME (the S peptide) as well as an otherwise identical peptide with the first Ser mutated to Ala, CGVKKRKASSSVQMME (the A peptide). These peptides correspond to residues 326-340 of delta B-CaM kinase II; the initial Cys on each peptide was engineered for coupling purposes unrelated to these experiments. In agreement with the previous study, we found that purified wild type CaM kinase IV did phosphorylate the Ser-containing peptide in the presence of Ca2+ and calmodulin and that phosphorylation of the A peptide was more than 7-fold reduced compared with the S peptide. Additionally, we found that purified wild type CaM kinase I was also capable of phosphorylating the S peptide in the presence of Ca2+ and calmodulin and that phosphorylation of the A peptide was reduced by more than 4-fold compared with the S peptide (data not shown).

The ability of a kinase to phosphorylate a peptide does not ensure that the kinase will be able to phosphorylate that sequence within the structure of a large protein, however, and so we next sought to determine if CaM kinase I and CaM kinase IV could phosphorylate alpha B-CaM kinase II protein on this key Ser. We purified kinase-inactive mutants of alpha B-CaM kinase II and alpha B-CaM kinase II S332A (to avoid interference by autophosphorylation, alpha B-CaMK II and the S332A mutant were made kinase-inactive with a K42M mutation within the catalytic domain referred to as alpha B-CaM kinase IIi). We found that both purified wild-type CaM kinase I and CaM kinase IV were able to phosphorylate purified alpha B-CaMK IIi in the presence of Ca2+ and calmodulin, and that the level of phosphorylation was much less with the S332A mutant (Fig. 5B). Quantification by densitometry revealed that the level of phosphorylation of the S332A mutant of alpha B-CaM kinase IIi by CaM kinase I was 24.5 ± 3.6%, and the level of phosphorylation of this mutant by CaM kinase IV was 8.45 ± 4.99% as compared with the respective phosphorylation levels of alpha B-CaM kinase IIi containing Ser332, which were assigned the value of 100% (Fig. 5C). Omission of either CaM kinase I or CaM kinase IV or the inactive CaM kinase II substrate resulted in no detectable phosphorylated band at this position (data not shown).


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Fig. 5.   Phosphorylation of alpha B-CaM kinase II by CaM kinase I and CaM kinase IV. The NLS and surrounding residues from the three nuclear targeted isoforms of CaM kinase II (alpha B, delta B, and gamma A) is compared with the consensus sequences for phosphorylation by CaM kinase I and CaM kinase IV (A) (44, 56). Residues with variation between the three CaM kinase II isoforms are noted with both residues separated by a dash (see Fig. 2 for a comparison of the three nuclear CaM kinase II isoforms). The Ser that is phosphorylated by the kinases is highlighted in boldface type. Single amino acid codes are used. X represents any amino acid, and Hyd represents any hydrophobic residue. The ability of Lys to substitute for Arg at the -3-position for CaM kinase I phosphorylation has not been examined (A. Edelman, personal communication). Phosphorylation of alpha B-CaM kinase IIi ("i" refers to inactive kinase) versus mutant alpha B-CaMK IIi S332A by purified CaM kinase I and CaM kinase IV is shown (B). Lane 1, autophosphorylated CaM kinase II used as a size marker; lane 2, alpha B-CaM kinase IIi phosphorylated by CaM kinase I; lane 3, alpha B-CaM kinase IIi S332A phosphorylated by CaM kinase I; lane 4, alpha B-CaM kinase IIi phosphorylated by CaM kinase IV; lane 5, alpha B-CaM kinase IIi S332A phosphorylated by CaM kinase IV. The films were quantified by densitometry, and compiled results from four complete phosphorylation experiments are shown (C). Student's paired t test was used to compare phosphorylation of alpha B-CaM kinase IIi to phosphorylation of alpha B-CaM kinase IIi S332A by either CaM kinase I or CaM kinase IV (an asterisk indicates p < 0.001).

Blockade of Nuclear Targeting Is Not Dependent on the Position of the NLS within CaM Kinase II-- We sought to determine whether moving the NLS of CaM kinase II from the central region of the protein (based on primary structure) to the N terminus would alter the ability of CaM kinase I or CaM kinase IV to block nuclear targeting of the kinase. To accomplish this, we generated a mutant of alpha -CaM kinase II containing an N-terminal fusion of 13 amino acids derived from the NLS region of alpha B-CaM kinase II encompassing the KKRK sequence as well as the four adjacent serines and neighboring residues that complete the CaM kinase I and CaM kinase IV consensus phosphorylation sequences (Figs. 5A and 6A). When transfected into COS-7 cells, the NLS was able to function at the N terminus of normally cytoplasmic alpha -CaM kinase II, efficiently directing this protein to the nucleus. When cotransfected with constitutive CaM kinase I or CaM kinase IV, nuclear targeting of this protein was blocked as effectively as was found for wild type alpha B-CaM kinase II (Fig. 6B).


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Fig. 6.   Localization of alpha -CaM kinase II with an N-terminal NLS fusion alone and in the presence of CaM kinase I or CaM kinase IV. Thirteen amino acids containing the NLS and adjacent four Ser residues of alpha B-CaM kinase II were cloned into the N terminus of alpha -CaM kinase II, producing a full-length kinase with the N-terminal amino acid sequence shown (A). The 13 amino acids derived from alpha B-CaM kinase II are boxed; the NLS sequence is highlighted in boldface type, the four residues remaining from the hemagglutinin tag are underlined, and the alpha -CaM kinase II sequence continues in its entirety, beginning with residue 4 of the wild type protein. This construct was transfected into COS-7 cells (B) in the presence of vector alone (left) or constitutive mutants of CaM kinase I (middle) or CaM kinase IV (right) as indicated, and CaM kinase II localization was visualized with immunofluorescence as described for Fig. 1.

A Negative Charge Adjacent to the NLS of CaM Kinase II Reduces Binding to an NLS Receptor-- Does a negatively charged phosphate immediately adjacent to the positively charged NLS inhibit binding of this sequence to the NLS-R? To address this question, we developed an assay to assess binding of CaM kinase II to the NLS-R m-pendulin coupled via a His6 tag to Ni2+-complexed agarose resin. Other putative NLS receptor proteins including His6-tagged NPI-1, GST-tagged NPI-1, GST-tagged NPI-3, and GST-tagged karyopherin alpha  were used in similar resin binding experiments, but none bound to alpha B-CaM kinase II nearly as well as m-pendulin (data not shown), and so His6 m-pendulin was used for all subsequent NLS-R binding experiments. The NLS-R effectively bound NLS-containing alpha B-CaM kinase II wild-type but showed almost no binding to NLS-deficient alpha -CaM kinase II wild-type, thus demonstrating the specificity of the assay for NLS-containing proteins (Fig. 7, A and B). In addition, a previously described mutant of delta B-CaM kinase II in which the first two Lys residues of the NLS sequence were mutated to Asn (KKRK mutated to NNRK), disrupting nuclear targeting of the kinase (12), was similarly unable to bind to the NLS-R in this assay, while wild type delta B-CaM kinase II bound as well to the NLS-R as did alpha B-CaM kinase II (data not shown). Mutation of S332A in alpha B-CaM kinase II did not inhibit binding to the NLS-R, but the S332D and S332E mutants demonstrated substantially reduced binding to the NLS-R (Fig. 7A). The S333D mutant of alpha B-CaM kinase II did not show reduced binding to the NLS-R compared with wild-type alpha B-CaM kinase II (data not shown). Sufficient experimental trials were performed to allow statistical analysis comparing the binding to the NLS-R of wild-type alpha B-CaM kinase II (standardized to 100% binding) versus that of alpha -CaM kinase II wild type and of alpha B-CaM kinase II mutants S332A and S332D. There was negligible binding (4.2 ± 4.6%) of alpha -CaM kinase II to the NLS-R, while the binding of the S332D mutant of alpha B-CaM kinase II was 51.9 ± 5.7% of alpha B-CaM kinase II wild type, and the binding of the S333A mutant was not significantly different (115 ± 16%) from alpha B-CaM kinase II wild type (Fig. 7B). These results demonstrate that a negatively charged residue immediately downstream from the NLS of alpha B-CaM kinase II reduces binding of this protein to the NLS-R compared with wild-type alpha B-CaM kinase II.


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Fig. 7.   Differential binding of CaM kinase II isoforms and mutants to an NLS receptor. Bacterially expressed His6-tagged m-pendulin (NLS-R) complexed to Ni2+-containing beads was incubated separately with equal amounts of alpha B-CaM kinase II wild type (w.t.), alpha -CaM kinase II wild type, and three mutants of alpha B-CaM kinase II with replacement of the first Ser following the NLS with Ala, Asp, and Glu, respectively. The complexes were then washed and eluted from the beads with EDTA, and the eluate was then subjected to Western blotting for CaM kinase II with ECL detection as described under "Experimental Procedures" (A). Films from the blots were quantitated by densitometry, and the binding of alpha B-CaM kinase II to the NLS-R was defined as 100% for comparison with other CaM kinase II isoforms and mutants. The compiled results of 9-12 independent binding reactions are shown (B). Student's paired t test was used to compare the binding efficiency to the NLS-R of each corresponding isoform or mutant of CaM kinase II versus alpha B-CaM kinase II wild type (an asterisk indicates p < 0.001).

    DISCUSSION
Top
Abstract
Introduction
Procedures
Results
Discussion
References

This paper demonstrates that phosphorylation by CaM kinase I or CaM kinase IV of a Ser adjacent to the NLS of nuclear targeted isoforms of CaM kinase II can block its nuclear targeting. CaM kinases I and IV have widespread tissue distribution and have been detected in such locations as the thalamus, hypothalamus, and heart, where nuclear targeted isoforms of CaM kinase II are expressed (10, 13, 38, 39). Thus, the co-localization of CaM kinase I or IV with nuclear targeted CaM kinase II that we have produced in situ through transfection is likely to occur in vivo. We have also examined the effects on nuclear targeting of CaM kinase II when coexpressed with protein kinase A or protein kinase C, two other multifunctional protein kinases, as well as the protein phosphatase calcineurin, all three of which have been shown to alter targeting of certain other NLS-containing proteins (reviewed in Ref. 24). None of these three signal transduction mediators was able to appreciably alter nuclear targeting of CaM kinase II. CaM kinase I and CaM kinase IV are both capable of modifying the function of many proteins through phosphorylation, and this study adds another important potential function to the cellular effects ascribed to these kinases.

The block of nuclear targeting with constitutively active truncation mutants of CaM kinases I and IV summarized above was not observed with full-length, Ca2+/calmodulin-dependent CaM kinase I or IV, even when the CaM kinase I T177D mutant was used or when CaM kinases I and IV were cotransfected with calmodulin and/or CaM kinase kinase and combined with varying lengths of stimulation with Ca2+-ionophore (data not shown). Wild type CaM kinases I and IV stimulated with Ca2+/calmodulin were able to phosphorylate this key site in vitro (Fig. 5), however. Furthermore, phosphorylation of this site is likely to be sufficient to block nuclear targeting of CaM kinase II as mutant alpha B-CaM kinase II S332D and S332E are both completely cytoplasmic (Fig. 4). Activity-dependent modulation of CaM kinase II localization by phosphorylation in vivo may occur rather slowly during synthesis of nascent kinase or during cell division when the nuclear membrane is disrupted rather than as a rapid Ca2+-dependent shuttle for the kinase in and out of the nucleus. It may be difficult to recreate in situ the conditions that govern regulation of CaM kinase II nuclear targeting in vivo.

There are a number of possible factors that may hinder the ability of wild type CaM kinases I and IV coupled with Ca2+-elevating stimuli to effectively phosphorylate this site on CaM kinase II and block its nuclear targeting in the transfection system that we have used. The nature of our transfection experiments may require sustained phosphorylation of this site for as long as 48 h in order to see a block in nuclear targeting of the kinase. This is likely to occur with constitutive CaM kinase I or IV but may be difficult to achieve with wild type kinase. Activation of wild type CaM kinases I and IV in cultured cells is likely to be transient if it is like activation of CaM kinase II in these cells. In the case of CaM kinase II, we find that the in situ activation levels are low in the basal state and can be activated to higher levels only transiently. For example, the basal level of CaM kinase II autonomous activity (a measure of the activation state of the enzyme) is approximately 2% in PC12 cells (40, 41), and a similarly low basal level of CaM kinase II autonomy has been measured in COS-7 cells.2 In contrast, primary cultures of hippocampal neurons have a much higher basal level of CaM kinase II autonomy of 15.5% despite having a low resting [Ca2+]i of 15-43 nM (42), while homogenates of various brain regions have basal CaM kinase II autonomy values ranging from 4 to 10.5% (42, 43) and homogenates from cardiac muscle also have a relatively high basal level of CaM kinase II autonomy of approximately 8%.3 CaM kinase II autonomy can be increased by application of Ca2+-elevating agents to cultured cells but then returns to basal levels over several minutes despite continued application of stimulus. Although equivalent activation experiments for CaM kinases I and IV have not been performed, these enzymes may also be less active in cultured cell lines than in primary neuronal or cardiac cells. This may make it difficult to maintain phosphorylation of the Ser adjacent to the CaM kinase II NLS for the 48 h required in our transfection experiments. Furthermore, activation of CaM kinases I and IV requires a complex series of phosphorylation events including both autophosphorylation and phosphorylation by an additional CaM kinase I/IV kinase (28, 44-46), and it is possible that we are not able to fully activate wild type CaM kinase I and IV in our in situ cell system. The fact that neither cotransfection with CaM kinase kinase with or without calmodulin nor the use of mutant CaM kinase I T177D allowed full-length CaM kinases I or IV to block nuclear targeting of CaM kinase II makes this somewhat less likely, however.

It is also possible that a kinase other than CaM kinase I or IV may actually phosphorylate this key site on CaM kinase II in vivo. The study by Miyano et al. (37) examining phosphorylation of this site on the peptide derived from the NLS of gamma A-CaM kinase II found that extracts from all brain regions examined could phosphorylate this Ser in a Ca2+/calmodulin-dependent manner. It was not established whether this activity was the result of CaM kinase IV, CaM kinase I, or another kinase, although chromatography suggested that CaM kinase IV is the predominant Ca2+/calmodulin-dependent kinase with this activity in cerebellum. Kinetic analysis demonstrated that this peptide is in fact only a moderately good substrate for CaM kinase IV, with Km = 8.0 µM versus Km = 2.6 µM for synapsin I and a similar Vmax for both peptides (37). In vitro and in situ studies indicate the importance of the first Ser following the NLS for the regulation of nuclear targeting of CaM kinase II, and depending on the cell type, it may be CaM kinase I or IV or another as yet unidentified Ser/Thr kinase with similar specificity that phosphorylates this site in vivo.

Most NLS sequences can be moved within a protein and even fused onto completely different proteins and still retain their nuclear targeting function, although in some cases the position of an NLS relative to surrounding residues can have a profound impact on NLS function (47). We chose to move the NLS of alpha B-CaM kinase II from the central region of the protein's primary structure to its extreme N terminus. Based on the "flower and petal" structure which has been proposed by Kanaseki et al. (48) to describe the quaternary holoenzyme structure of CaM kinase II, this would move the NLS a substantial distance from the central globular core to the peripheral catalytic region of the holoenzyme. We found the NLS to be able in this position to efficiently target the kinase to the nucleus. This N-terminal NLS mutant was designed to contain all of the CaM kinase I and CaM kinase IV consensus requirements contained within alpha B-CaM kinase II, and we found that both of these kinases were also capable of blocking nuclear localization of this mutant. This suggests that the effect of CaM kinases I and IV on nuclear targeting of CaM kinase II is a local effect on the region surrounding the NLS and probably does not depend on any particular three-dimensional structure of the NLS within the kinase, i.e. phosphorylation causing the kinase to fold in such a way as to obscure the NLS.

Alteration in nuclear targeting of proteins by phosphorylation is not a new phenomenon; there are many examples of phosphorylation either enhancing or inhibiting nuclear translocation of a variety of NLS-containing proteins (reviewed in Ref. 24). One mechanism for inhibition of NLS function is phosphorylation-induced NLS "masking," which refers to the hypothesis that a phosphate adjacent to the NLS inhibits binding to the NLS-R as a result of its charge or a conformational effect (24). Given that negatively charged regions of the NLS-R are thought to bind to the positively charged NLS of nuclear targeted proteins for nuclear import to occur (49), it is not surprising that a negative charge immediately adjacent to this site may inhibit this interaction. Although this theory has been advanced to explain inhibition of nuclear targeting by phosphorylation of several NLS-containing proteins (Table II), this has never been demonstrated directly.

Using an NLS-R binding assay, we present evidence that the alternatively spliced 13-amino acid sequence containing the NLS consensus sequence KKRK is critical for binding of alpha B-CaM kinase II to the NLS-R m-pendulin. Additionally, we demonstrate that a negative charge adjacent to this NLS reduces binding to the NLS-R by approximately 50%, while mutation of this site to a neutral Ala does not significantly alter binding to the NLS-R. A recent study examining the enhancement of nuclear targeting of the SV40 large T antigen (a protein with multiple phosphorylation sites, some of which enhance while others inhibit nuclear targeting) by phosphorylation gave the first evidence that phosphorylation can affect binding of an NLS-containing protein to an NLS-R (50). In this study, the authors report that phosphorylation of SV40-LacZ fusions by casein kinase II, which causes a large increase in nuclear import rate, may be mediated by an observed 40% increase in binding of this protein to the NLS-R. Thus, the 50% decrease in NLS-R binding that we have observed with a negatively charged residue adjacent to the NLS appears to be in the range that can have a profound impact on nuclear targeting. Perhaps a doubly charged phosphate adjacent to the NLS will lead to an even larger decrease in NLS-R binding than we report here, but the stoichiometric phosphorylation of CaM kinase II by CaM kinase I or CaM kinase IV that will be required to examine this may be difficult to attain in vitro. Regardless, our mutational analysis demonstrates that a single negatively charged residue is able to completely block nuclear targeting; whether this is wholly or only partly mediated by the 50% decrease in binding to the NLS-R that we have observed has not been established.

The possibility that there is cross-talk within the family of multifunctional Ca2+/calmodulin-dependent protein kinases raises some very intriguing questions. It is known that different frequencies of Ca2+ stimuli can lead to completely opposite effects on cellular phenotype; for example, high frequency stimulation of neurons leads to long term synaptic potentiation, while the same stimulus delivered at lower frequencies causes long term synaptic depression (51). Furthermore, several studies have implicated CaM kinase II in the generation of long term synaptic potentiation (52, 53), which also requires new gene transcription in order to be maintained (54). The finding that CaM kinase II is capable of repressing activity of the transcription factors cyclic AMP response element-binding protein and ATF-1 while CaM kinase I and CaM kinase IV both activate these transcription factors (20) makes this long term synaptic potentiation/long term synaptic depression consideration especially provocative. Could different profiles of Ca2+ stimuli lead to altered nuclear targeting of CaM kinase II via Ca2+-dependent phosphorylation? The observation that nuclear isoforms of CaM kinase II have been found predominantly within the brain (alpha B) (13) and heart (delta B) (55), where alterations in cellular physiology are strongly tied to the frequency and amplitude of Ca2+ oscillations, lends support to the idea that the regulation of CaM kinase II nuclear targeting in this manner could have physiologic relevance. The fact that the three nuclear isoforms of CaM kinase II, each derived from a different gene, all contain this adjacent string of four Ser residues that has not been noted in any other nuclear targeted protein suggests that these are likely to be of biologic importance. The data presented here demonstrate that phosphorylation of the first of these Ser residues mediated by CaM kinases I and IV can decrease binding to the NLS-R and block access of CaM kinase II to the nucleus, where control of gene expression takes place. Through mechanisms such as this, cells may be able focus the action of multifunctional kinases to discrete periods of time and space.

    ACKNOWLEDGEMENTS

We thank Dr. A. Means for providing us with CaM kinase IV protein and CaM kinases I and IV expression constructs, Dr. A. Nairn for CaM kinase I protein, Dr. M. Muramatsu for the protein kinase A expression construct, Dr. T. Soderling for the CaM kinase kinase expression construct, Dr. P. Yaswen for the calmodulin construct, Drs. R. O'Neil and P. Palese for the NPI-1 and NPI-3 expression constructs, Drs. M. Rexach and G. Blobel for the karyopherin-alpha expression construct, and Dr. S. Adam for the m-pendulin expression construct as well as useful discussion on nuclear import.

    FOOTNOTES

* This work was supported by National Institutes of Health (NIH) Grants GM40600 and GM 30179.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger These authors contributed equally to this work.

§ Recipient of NIGMS, NIH, Grant 5T32 GM07365.

To whom correspondence should be addressed. Tel.: 650-723-7668; Fax: 650-725-3958; E-mail: schulman{at}cmgm.stanford.edu.

1 The abbreviations used are: CaM kinase, Ca2+/calmodulin-dependent protein kinase II; NLS, nuclear localization signal; NLS-R, NLS receptor; PIPES, 1,4-piperazinediethanesulfonic acid; GST, glutathione S-transferase.

2 E. K. Heist and H. Schulman, unpublished observations.

3 M. E. Anderson, A. P. Braun, T. Lu, Y. Wu, H. Schulman, and R. J. Sung, unpublished observations.

    REFERENCES
Top
Abstract
Introduction
Procedures
Results
Discussion
References

  1. Hanson, P. I., and Schulman, H. (1992) Annu. Rev. Biochem. 61, 559-601[CrossRef][Medline] [Order article via Infotrieve]
  2. Braun, A. P., and Schulman, H. (1995) Annu. Rev. Physiol. 57, 417-445[CrossRef][Medline] [Order article via Infotrieve]
  3. Chrivia, J. C., Kwok, R. P., Lamb, N., Hagiwara, M., Montminy, M. R., and Goodman, R. H. (1993) Nature 365, 855-859[CrossRef][Medline] [Order article via Infotrieve]
  4. Sassone-Corsi, P., Visvader, J., Ferland, L., Mellon, P., and Verma, I. (1988) Genes Dev. 2, 1529-1538[Abstract]
  5. Flanagan, W., Corthesy, B., Bram, R., and Crabtree, G. (1991) Nature 352, 803-807[CrossRef][Medline] [Order article via Infotrieve]
  6. Metz, R., and Ziff, E. (1991) Genes Dev. 5, 1754-1766[Abstract]
  7. Bacskai, B. J., Hochner, B., Mahaut-Smith, M., Adams, S. R., Kaang, B. K., Kandel, E. R., and Tsien, R. Y. (1993) Science 260, 222-226[Medline] [Order article via Infotrieve]
  8. Wen, W., Meinkoth, J. L., Tsien, R. Y., and Taylor, S. S. (1995) Cell 82, 463-473[Medline] [Order article via Infotrieve]
  9. Mochly-Rosen, D. (1995) Science 268, 247-251[Medline] [Order article via Infotrieve]
  10. Nakamura, Y., Okuno, S., Kitani, T., Otake, K., Sato, F., and Fujisawa, H. (1996) Neurosci. Lett. 204, 61-64[CrossRef][Medline] [Order article via Infotrieve]
  11. Nairn, A. C., and Greengard, P. (1987) J. Biol. Chem. 262, 7273-7281[Abstract/Free Full Text]
  12. Srinivasan, M., Edman, C., and Schulman, H. (1994) J. Cell Biol. 126, 839-852[Abstract]
  13. Brocke, L., Srinivasan, M., and Schulman, H. (1995) J. Neurosci. 15, 6797-6808[Medline] [Order article via Infotrieve]
  14. Baitinger, C., Alderton, J., Poenie, M., Schulman, H., and Steinhardt, R. A. (1990) J. Cell Biol. 111, 1763-1773[Abstract]
  15. Lorca, T., Cruzalegui, F. H., Fesquet, D., Cavadore, J.-C., Mery, J., Means, A., and Doree, M. (1993) Nature 366, 270-273[CrossRef][Medline] [Order article via Infotrieve]
  16. Waldmann, R., Hanson, P. I., and Schulman, H. (1990) Biochemistry 29, 1679-1684[Medline] [Order article via Infotrieve]
  17. Planas-Silva, M. D., and Means, A. R. (1992) EMBO J. 11, 507-517[Abstract]
  18. Wegner, M., Cao, Z., and Rosenfeld, M. G. (1992) Science 256, 370-373[Medline] [Order article via Infotrieve]
  19. Sun, P., Enslen, H., Myung, P. S., and Maurer, R. A. (1994) Genes Dev. 8, 2527-2539[Abstract]
  20. Sun, P., Lou, L., and Maurer, R. (1996) J. Biol. Chem. 271, 3066-3073[Abstract/Free Full Text]
  21. Shimomura, A., Ogawa, Y., Kitani, T., Fujisawa, H., and Hagiwara, M. (1996) J. Biol. Chem. 271, 17957-17960[Abstract/Free Full Text]
  22. Ramirez, M. T., Zhao, X., Schulman, H., and Brown, J. H. (1997) J. Biol. Chem. 272, 31203-31208[Abstract/Free Full Text]
  23. Strack, S., Choi, S., Lovinger, D. M., and Colbran, R. J. (1997) J. Biol. Chem. 272, 13467-13470[Abstract/Free Full Text]
  24. Jans, D., and Hubner, S. (1996) Physiol. Rev. 76, 651-685[Abstract/Free Full Text]
  25. Hanson, P. I., Kapiloff, M. S., Lou, L. L., Rosenfeld, M. G., and Schulman, H. (1989) Neuron 3, 59-70[Medline] [Order article via Infotrieve]
  26. Ho, S., Hunt, H., Horton, R., Pullen, J., and Pease, L. (1989) Gene (Amst.) 77, 51-59[CrossRef][Medline] [Order article via Infotrieve]
  27. Hanson, P. I., Meyer, T., Stryer, L., and Schulman, H. (1994) Neuron 12, 943-956[Medline] [Order article via Infotrieve]
  28. Haribabu, B., Hook, S. S., Selbert, M. A., Goldstein, E. G., Tomhave, E. D., Edelman, A. M., Snyderman, R., and Means, A. R. (1995) EMBO J. 14, 3679-3686[Abstract]
  29. Matthews, R. P., Guthrie, C. R., Wailes, L. M., Zhao, X., Means, A. R., and McKnight, G. S. (1994) Mol. Cell. Biol. 14, 6107-6116[Abstract]
  30. Tokumitsu, H., Enslen, H., and Soderling, T. R. (1995) J. Biol. Chem. 270, 19320-19324[Abstract/Free Full Text]
  31. Nghiem, P., Ollick, T., Gardner, P., and Schulman, H. (1994) Nature 371, 347-350[CrossRef][Medline] [Order article via Infotrieve]
  32. Kuret, J. A., and Schulman, H. (1984) Biochemistry 23, 5495-5504[Medline] [Order article via Infotrieve]
  33. Chi, N. C., and Adam, S. A. (1997) Mol. Biol. Cell 8, 945-956[Abstract]
  34. Rexach, M., and Blobel, G. (1995) Cell 83, 683-692[Medline] [Order article via Infotrieve]
  35. O'Neil, R., and Palese, P. (1995) Virology 206, 116-125[Medline] [Order article via Infotrieve]
  36. Schilling, K., Luk, D., Morgan, J., and Curran, T. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 5665-5669[Abstract]
  37. Miyano, O., Kameshita, I., and Fujisawa, H. (1992) J. Biol. Chem. 267, 1198-1203[Abstract/Free Full Text]
  38. Nakamura, Y., Okuno, S., Sato, F., and Fujisawa, H. (1995) Neuroscience 68, 181-194[CrossRef][Medline] [Order article via Infotrieve]
  39. Picciotto, M. R., Zoli, M., Bertuzzi, G., and Nairn, A. C. (1995) Synapse 20, 75-84[Medline] [Order article via Infotrieve]
  40. MacNicol, M., Jefferson, A. B., and Schulman, H. (1990) J. Biol. Chem. 265, 18055-18058[Abstract/Free Full Text]
  41. MacNicol, M., and Schulman, H. (1992) J. Biol. Chem. 267, 12197-12201[Abstract/Free Full Text]
  42. Molloy, S. S., and Kennedy, M. B. (1991) Proc. Natl. Acad. Sci. U. S. A. 88, 4756-4760[Abstract]
  43. Ocorr, K. A., and Schulman, H. (1991) Neuron 6, 907-914[Medline] [Order article via Infotrieve]
  44. Cruzalegui, F. H., and Means, A. R. (1993) J. Biol. Chem. 268, 26171-26178[Abstract/Free Full Text]
  45. Tokumitsu, H., Brickey, D. A., Glod, J., Hidaka, H., Sikela, J., and Soderling, T. R. (1994) J. Biol. Chem. 269, 28640-28647[Abstract/Free Full Text]
  46. Selbert, M. A., Anderson, K. A., Huang, Q.-H., Goldstein, E. G., Means, A. R., and Edelman, A. M. (1995) J. Biol. Chem. 270, 17616-17621[Abstract/Free Full Text]
  47. Rihs, H.-P., Jans, D. A., Fan, H., and Peters, R. (1991) EMBO J. 10, 633-639[Abstract]
  48. Kanaseki, T., Ikeuchi, Y., Sugiura, H., and Yamauchi, T. (1991) J. Cell Biol. 115, 1049-1060[Abstract]
  49. Silver, P. A. (1991) Cell 64, 489-497[Medline] [Order article via Infotrieve]
  50. Hubner, S., Xiao, C.-Y., and Jans, D. (1997) J. Biol. Chem. 272, 17191-17195[Abstract/Free Full Text]
  51. Linden, D. J., and Connor, J. A. (1993) Curr. Opin. Neurobiol. 3, 401-406[CrossRef][Medline] [Order article via Infotrieve]
  52. Malinow, R., Schulman, H., and Tsien, R. W. (1989) Science 245, 862-866[Medline] [Order article via Infotrieve]
  53. Lledo, P.-M., Hjelmstad, G. O., Mukherji, S., Soderling, T. R., Malenka, R. C., and Nicoll, R. A. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 11175-11179[Abstract]
  54. Madison, D., Malenka, R., and Nicoll, R. (1991) Annu. Rev. Neurosci. 14, 379-397[CrossRef][Medline] [Order article via Infotrieve]
  55. Edman, C. F., and Schulman, H. (1994) Biochim. Biophys. Acta 1221, 90-102
  56. Lee, J. C., Kwon, Y. G., Lawrence, D. S., and Edelman, A. M. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 6413-6417[Abstract]
  57. Hennekes, H., Peter, M., Weber, K., and Nigg, E. (1993) J. Cell Biol. 120, 1293-1304[Abstract]
  58. Ohta, Y., Nishida, E., Sakai, H., and Miyamoto, E. (1989) J. Biol. Chem. 264, 16143-16148[Abstract/Free Full Text]
  59. Abe, H., Nagaoka, R., and Obinata, T. (1993) Exp. Cell Res. 206, 1-10[CrossRef][Medline] [Order article via Infotrieve]
  60. Chida, K., and Vogt, P. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 4290-4294[Abstract]
  61. Tagawa, T., Kuroki, T., Vogt, P., and Chida, K. (1995) J. Cell Biol. 130, 255-263[Abstract]
  62. Jans, D., Moll, T., Nasmyth, K., and Jans, P. (1995) J. Biol. Chem. 270, 17064-17067[Abstract/Free Full Text]
  63. Moll, T., Tebb, G., Surana, U., Robitsch, H., and Nasmyth, K. (1991) Cell 66, 743-758[Medline] [Order article via Infotrieve]


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