Dictyostelium Myosin Heavy Chain Kinase A Subdomains
COILED-COIL AND WD REPEAT ROLES IN OLIGOMERIZATION AND SUBSTRATE TARGETING*

(Received for publication, February 11, 1997, and in revised form, April 3, 1997)

Michael F. Kolman Dagger and Thomas T. Egelhoff §

From the Department of Physiology and Biophysics, School of Medicine, Case Western Reserve University, Cleveland, Ohio 44106-4970

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

Myosin heavy chain kinase A (MHCK A) participates in the regulation of cytoskeletal myosin assembly in Dictyostelium, driving filament disassembly via phosphorylation of sites in the myosin tail. MHCK A contains an amino-terminal coiled-coil domain, a novel central catalytic domain, and a carboxyl-terminal domain containing a 7-fold WD repeat motif. We have overexpressed MHCK A truncation constructs to clarify the roles of each of these domains. Recombinant full-length MHCK A, MHCK A lacking the predicted coiled-coil domain, and MHCK A lacking the WD repeat domain were expressed at high levels in Dictyostelium cells lacking endogenous MHCK A. Biochemical analysis of the purified proteins demonstrates that the putative coiled-coil domain is responsible for the oligomerization of the MHCK A holoenzyme. Removal of the WD repeat domain had no effect on catalytic activity toward a synthetic peptide, but did result in a 95% loss of protein kinase activity when native myosin filaments were used as the substrate. Cellular analysis confirms that the same severe loss of activity against myosin occurs in vivo when the WD repeat domain is eliminated. These results suggest that the WD repeat domain of MHCK A serves to target this enzyme to its physiological substrate.


INTRODUCTION

Conventional myosin (myosin II) is involved in a wide range of contractile events in eukaryotic cells. In Dictyostelium, genetic and cellular analyses have demonstrated roles for myosin in the maintenance of cortical tension, cytokinesis, morphogenesis, capping of receptors, and cell locomotion (1-5). Although the roles of myosin II appear similar in many cell types, the in vivo mechanisms regulating myosin II assembly and activity in nonmuscle cells are not well understood.

Assembly of Dictyostelium myosin II bipolar filaments can be regulated by phosphorylation on the myosin II heavy chain (MHC).1 Two distinct MHC kinases (MHCKs) have been purified and cloned from Dictyostelium. A 130-kDa MHCK (MHCK A), discussed below, is expressed during both growth and development. An 84-kDa MHCK that is expressed only during development appears to contain two distinct catalytic domains, one related to protein kinase C (6-8) and one related to diacylglycerol kinases (9). Both MHCKs are capable of phosphorylating threonine residues on the myosin tail and can drive myosin bipolar filament disassembly in vitro. A third kinase, related to MHCK A, has recently been cloned from Dictyostelium (10), but is has not yet been established whether this protein regulates myosin assembly in vivo. The in vitro target sites of MHCK A have been mapped to threonines 1823, 1833, and 2029 in the tail region of the MHC (11, 12). The physiological significance of these sites was demonstrated by mutating the sites either to alanine (3X ALA myosin) to create a nonphosphorylatable MHC or to aspartic acid (3X ASP myosin) to mimic phosphorylated MHC (13). In vivo, cells expressing 3X ALA myosin display severe myosin II overassembly in the cytoskeleton, whereas cells expressing 3X ASP myosin display severely reduced myosin II assembly in the cytoskeleton, resulting in a block in cytokinesis and development. The 3X ASP cells are also unable to complete development. In all tested assays, the 3X ASP cells are phenotypically identical to MHC null cells (mhc-). These studies indicate that the MHCK A target sites play a critical role in regulated myosin II assembly in vitro and that filament assembly is required for myosin function in vivo.

Subsequent cellular analysis of Dictyostelium MHCK A null cells (mhck A-) and overexpressing cell lines (MHCK A+) indicated that MHCK A regulates the cytoskeletal myosin II assembly level during both growth and development (14). The mhck A- cells are viable, but display partial overassembly of myosin II in the cytoskeleton. MHCK A+ cells display reduced myosin II assembly in the cytoskeleton and reduced efficiency of growth in suspension and fail to complete development. The MHCK A+ cell phenotype resembles those of the mhc- cells and the 3X ASP cell lines, indicating that overexpressed MHCK A can drive myosin filament disassembly in vivo.

Molecular analysis of the MHCK A sequence (15) indicates that it has an amino-terminal domain that is predicted to have an alpha -helical coiled-coil structure, a catalytic domain that is not related to conventional protein kinases, and a carboxyl-terminal domain that contains the 7-fold WD repeat motif (16, 17) characteristic of beta -subunits of heterotrimeric G proteins. MHCK A is activated 50-fold by autophosphorylation (18), and autophosphorylation is increased by polyanions such as DNA, heparin, phosphatidylserine, and phosphatidylinositol (19).

It has been demonstrated recently that the MHCK A catalytic domain is a prototype for a completely novel family of protein kinases unrelated to the conventional eukaryotic protein kinase superfamily (10, 15, 20-22). This novel group includes mammalian elongation factor-2 kinase, also known as calcium/calmodulin-dependent protein kinase III. Given its novel structure and catalytic domain, we have performed a structure-function dissection of MHCK A to identify the biochemical and physiological roles of the domains that flank the catalytic domain. The results reported here indicate that the amino-terminal coiled-coil domain is responsible for MHCK A oligomerization and that the WD repeats are important for full activity against native myosin II.


EXPERIMENTAL PROCEDURES

Dictyostelium Growth and Development

Cells were cultured axenically as described previously (14). All cell lines described here are derivatives of the parental line JH10 (23). For developmental studies, cells were harvested in log phase growth and plated on starvation plates containing 20 mM MES, 0.2 mM CaCl2, 2 mM MgSO4, and 1.5% agar, pH 6.8.

Plasmid Constructs and Transformations

DNA manipulations were done according to standard procedures (24). The plasmid pLMHCK has been previously described (14). This construct expresses residues 8-1146 of the mhck A cDNA from the extrachromosomal vector pLittle, with constitutive expression driven by an actin-15 promoter. pLMHCK and other constructs were transfected into mhck A- as described previously (14). Initial selections for these transfections were done using 10 µg/ml G418. Once transfected cell lines were established, G418 was raised to 50 µg/ml for cell line maintenance. Truncation constructs were generated as modifications of pLMHCK, in the same vector. In each case, inserts were fused to an amino-terminal 6-histidine tag derived from the vector pDXA-HC (25). The Delta WD-MHCK construct also bears a carboxyl-terminal 6-histidine tag. Neither 6-histidine tag proved reliable for purification from Dictyostelium. Nickel chelation chromatography was therefore not used for the purification reported here. The insert for pLDelta Coil-MHCK expresses residues 499-1146 of mhck A and relies upon the native MHCK A stop codon for translation termination. The insert for pLDelta WD-MHCK expresses residues 8-844 of mhck A and includes 19 residues of vector-derived coding region at the carboxyl terminus.

Protein Purification and MHCK A Kinase Assay

MHCK A was purified from Dictyostelium MHCK A+ cells as described previously (26) with modifications described below. The location of MHCK A activity in column eluants was determined using a peptide phosphorylation assay. Assays for MHCK A activity were performed at 23 °C in assay buffer containing 10 mM TES, pH 7.0, 2 mM MgCl, 1 mM DTT, 500 µM [gamma -32P]ATP (100-500 cpm/pmol), and 30 µM peptide MH-1. The previously described peptide MH-1 (RKKFGESEKTKTKEFL) (18), which corresponds to amino acids 2020-2035 in the Dictyostelium myosin II heavy chain, was dissolved in 10 mM TES, pH 7.0. Protein purification column elution fractions were assayed by the addition of 2 µl of each fraction to 48 µl of assay buffer. The tube was vortexed and incubated for 2 min at 25 °C. The reaction was terminated by spotting a 25-µl aliquot onto phosphocellulose P-81 paper and washing as described previously (18). Dictyostelium myosin II used in this study was stored in 10 mM TES, pH 7.0, 2 mM EDTA, 0.5 mM DTT, and 20% sucrose.

Cells were harvested from HL5 suspension culture at late log phase (typically 4-6 liters). Cells were resuspended in buffer (2 ml/g of cells) containing 10 mM TES, 25 mM KCl, 30% sucrose, 2 mM EDTA, 2 mM EGTA, 1 mM DTT, 0.5 mg/ml leupeptin, 0.2 mg/ml phenylmethylsulfonyl fluoride, 0.05 mg/ml Nalpha -p-tosyl-L-lysine chloromethyl ketone, 0.1 mg/ml L-1-tosylamido-2-phenylethyl chloromethyl ketone, 1 mM benzamidine, and 1 mM Pefabloc. The cell suspension was sonicated for 3 min on ice using a Branson Sonifier 450 sonicator, and lysis was assessed by light microscopy.

The extract was centrifuged for 30 min at 45,000 rpm in a Beckman Ti-45 rotor. The supernatant from the spin was decanted and mixed with packed DE52 cellulose (2 ml of supernatant/ml of cellulose) and rotated at 4 °C. After 60 min, the DE52 cellulose was pelleted by centrifugation, and the supernatant was decanted. The DE52 supernatant was mixed with packed phosphocellulose (3 ml of supernatant/ml of phosphocellulose) and rotated at 4 °C for 60 min. The phosphocellulose was collected by centrifugation and washed two times with buffer A (10 mM TES, pH 7.0, 50 mM KCl, 20% sucrose, and 1 mM DTT). The resin was poured into a 3 × 20-cm column and washed with buffer A until the absorbance (A280) of the eluant reached base line. MHCK A was eluted from phosphocellulose by applying buffer A adjusted to 300 mM KCl. The resulting activity pool was applied to a hydroxylapatite column and washed until the A280 of the eluant reached base line. Kinase activity was eluted with 200 mM KPO4, 20% sucrose, and 1 mM DTT, pH 7.0. This pool was loaded onto a 3 × 100-cm Sephacryl S-300 gel filtration column equilibrated with 10 mM TES, 0.3 M KCl, 20% (w/v) sucrose, 1 mM EDTA, and 1 mM DTT, pH 7.0. Delta WD-MHCK A was purified as described above except an aminohexyl-Sepharose column step was added after gel filtration. The peak of activity off of gel filtration was diluted to 50 mM KCl; loaded onto a 1-ml aminohexyl-Sepharose column; and eluted with 300 mM KCl, 1 mM DTT, and 10 mM TES, pH 7.0. Delta Coil-MHCK A was purified as described above except that the peak of activity off of gel filtration was diluted to 50 mM KCl and loaded onto a 5-ml Mono-S column. Elution was performed with a 50-400 mM KCl gradient in 1 mM DTT and 10 mM TES, pH 7.0. Delta Coil-MHCK A eluted at ~150 mM KCl. Protein concentrations were determined throughout the purification using the method of Bradford (32) with bovine serum albumin as the standard. Purified MHCK A, Delta Coil-MHCK A, and Delta WD-MHCK A were concentrated by binding to a small volume of hydroxylapatite resin and eluting with 200 mM KPO4, 100 mM KCl, 20% sucrose, and 1 mM DTT. Eluants were immediately divided into 100-µl aliquots and frozen in liquid nitrogen until use. Final protein concentrations of purified protein kinases were determined by performing densitometry on Coomassie Blue-stained SDS-polyacrylamide gels using bovine serum albumin to generate a standard curve.

Western Blot Analysis and Quantitation of Expression

Total cell extracts from each of the cell lines were prepared for Western blot analysis as described previously (14). Quantitation of expression of MHCK A+, Delta Coil-MHCK A+, and Delta WD-MHCK A+ in each cell line was performed by Western blot analysis using affinity-purified anti-MHCK A polyclonal antibodies and 125I-labeled goat anti-rabbit secondary antibody. The relative level of expression was determined by performing parallel Western blotting of cell extracts and a series of known amounts of each purified kinase construct to generate a standard linear curve for each cell line. All signals were then quantitated by a PhosphorImager. Calculation of the cellular concentrations of each protein was performed by making the estimate that a single Dictyostelium cell is a sphere 5 µm in diameter. The concentration of myosin in Dictyostelium was determined by densitometry on SDS-polyacrylamide gels of cell extracts using bovine serum albumin to generate a standard linear curve.


RESULTS

Expression of MHCK A Constructs

A schematic representation of full-length MHCK A and constructs in which the amino-terminal coiled-coil (Delta Coil-MHCK A) or the carboxyl-terminal WD repeat (Delta WD-MHCK A) domains were truncated are shown in Fig. 1. The three MHCK A constructs were overexpressed in the Dictyostelium mhck A- cell line by fusing each cDNA segment to an actin-15 promoter in an extrachromosomal vector. Once established, transfected cell lines were maintained in a 50 µg/ml concentration of the selective antibiotic G418. This elevated G418 concentration resulted in significantly higher kinase expression (3-4-fold) relative to the previously described overexpression of full-length MHCK A (14). The expression of each kinase was quantified by phosphoimaging of Western blots performed with MHCK A polyclonal antibodies and 125I-labeled anti-rabbit secondary antibody using each of the three purified proteins (described below) to generate a standard curve for each corresponding cell line, including wild-type cells. Calculations were performed using this Western blot analysis to generate estimates of the in vivo expression levels of each recombinant kinase construct. Based upon this analysis, recombinant full-length MHCK A is expressed at 27 µM, Delta Coil-MHCK A is expressed at 46 µM, and Delta WD-MHCK A is expressed at 90 µM. MHCK A expression in the parental cell line JH10 was calculated to be 0.3 µM. These expression levels represent 90- and 153-fold overexpression of recombinant full-length MHCK A and Delta Coil-MHCK A, respectively, and 300-fold overexpression of Delta WD-MHCK A relative to that of MHCK A in the parental cell line (Fig. 1). By comparison, we calculate myosin II in Dictyostelium to be ~6 µM.


Fig. 1. Schematic of MHCK A truncation constructs. Full-length MHCK A and truncation constructs were expressed in Dictyostelium mhck A- cells. The approximate locations of MHCK A domains are indicated, and numbers above the scale denote amino acids. The molecular masses were calculated based on the predicted amino acid sequence of each recombinant protein. The level of expression of MHCK A in wild-type cells and other cell lines used in this study was determined by phosphoimaging Western blots using MHCK A antibodies and 125I-labeled goat anti-rabbit antibody and using each purified kinase construct to generate a standard curve.
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Cytokinesis

Previous studies have demonstrated that myosin II is essential for cytokinesis as assayed by growth of cells in suspension cultures (1). mhc- cells are unable to form a contractile ring, which results in the cells becoming large and multinucleated without any increase in cell number (1, 27). Similar phenotypes have been observed in 3X ASP cells and in MHCK A+ cells (13, 14). We compared growth rates of MHCK A truncation cell lines in suspension cultures as an in vivo test of myosin function (Fig. 2a). The mhck A- cell line, which was previously shown to grow at a similar rate compared with control cells (14), was used as a control (filled circles). Cells that overexpress full-length MHCK A (filled squares) and Delta Coil-MHCK A (open squares) in the mhck A- cell line were unable to grow in suspension. These MHCK A+ and Delta Coil-MHCK A+ cells increased in size, were multinucleated, and eventually lysed under suspension culture conditions. In contrast, these cells grew at relatively normal rates when maintained as attached cells in plastic Petri dishes. Interestingly, when the WD repeats of MHCK A were removed (Delta WD-MHCK A+) (open circles), these cells grew at a similar rate and final density as mhck A- cells, indicating that myosin function was not impaired during cytokinesis. The Delta WD-MHCK A+ cells also displayed normal cell size during growth in suspension (data not shown).


Fig. 2. a, suspension growth of cells expressing MHCK A truncation constructs. Cultures inoculated at 105 cells/ml were grown in suspension in HL5 with 50 µg/ml G418 (the mhck A- control cell line was transfected with vector pLittle for G418 resistance) and rotated at 200 rpm. b, synchronous morphogenesis of cells expressing MHCK A truncation constructs. Cells were harvested in log phase growth from Petri dishes and plated on agar starvation plates. Pictures were taken 48 h after plating.
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Development

Previous studies have shown that mhc- cells, 3X ASP cells, and MHCK A+ cells are unable to complete development (13, 14, 27). We therefore used development as an in vivo test for myosin function in the MHCK A truncation cell lines (Fig. 2b). MHCK A+ cells and Delta Coil-MHCK A+ cells arrested at mound stage and were unable to complete development, whereas control (mhck A-) and Delta WD-MHCK A+ cells completed development and formed spores at normal rates.

Overexpression of MHCK A and Delta Coil-MHCK A causes defects in myosin filament-dependent processes as assayed in vivo by cytokinesis and development, suggesting that these MHCK A constructs drive myosin filament disassembly in vivo. In contrast, no defects in cytokinesis or development were observed in the Delta WD-MHCK A cell line. Interestingly, Delta WD-MHCK A had the highest expression compared with the other MHCK A-expressing cell lines (Fig. 1), with 300-fold higher expression than wild-type cells. Lack of phenotypic defects in Delta WD-MHCK A+ cells therefore is not due to lower expression of the kinase. As reported previously (14), elevated MHC phosphorylation in crude cell lysates was observed in MHCK A+ cells. Similar behavior was observed in Delta Coil-MHCK A+ cells, whereas no detectable increase in MHC phosphorylation was observed in lysates of Delta WD-MHCK A+ cells (data not shown).

Elimination of Myosin-based Defects with 3X ALA Myosin

Further analysis was performed to confirm that the defects in cytokinesis and development in MHCK A+ and Delta Coil-MHCK A+ cell lines were due to phosphorylation of myosin II and disassembly of filaments. Cell lines were constructed in which either wild-type myosin or 3X ALA myosin was expressed in an mhc- background. The 3X ALA myosin bears mutations in the in vitro mapped target sites of MHCK A in the myosin II tail. This 3X ALA myosin is predicted to be resistant to disassembly in vivo by overexpressed MHCK A if the in vitro mapped target sites are also the physiologically relevant in vivo target sites. Clonal populations of these cells expressing either wild-type or 3X ALA MHC were transfected with cDNA encoding full-length mhck A or Delta coil-mhck A to test whether the 3X ALA myosin mutation relieves the defects induced by MHCK A or Delta Coil-MHCK A overexpression. When cDNA expressing MHCK A or Delta Coil-MHCK A was transfected into cells expressing wild-type myosin, they failed to grow in suspension (Fig. 3a, filled and open squares, respectively), as expected based upon results presented above. This defect in cytokinesis caused by overexpression of MHCK A or Delta Coil-MHCK A was eliminated in cells expressing 3X ALA myosin (Fig. 3a, filled and open triangles, respectively). Overexpression of MHCK A or Delta Coil-MHCK A in wild-type myosin cells caused the cells to become large and multinucleated in suspension culture, whereas 3X ALA myosin cell lines expressing these kinase constructs remained small and displayed no increase in size (Fig. 3b) in suspension culture. In addition, wild-type MHC cells that overexpress either full-length MHCK A or Delta Coil-MHCK A constructs were not able to complete development and arrest at the mound stage, whereas 3X ALA MHC cells that overexpress either kinase construct were able to complete development (data not shown). These results are consistent with the hypothesis that full-length MHCK A and Delta Coil-MHCK A hyperphosphorylate myosin on residues 1823, 1833, and 2029 in vivo (or a subset of these residues), resulting in myosin disassembly and consequently an mhc- phenotype.


Fig. 3. a, rescue of MHCK A+ or Delta Coil-MHCK A+ phenotypes with 3X ALA myosin. The cDNA encoding mhck A or Delta coil-mhck A was transfected into Dictyostelium cells expressing either wild-type MHC (WT) or nonphosphorylatable 3X ALA myosin. Cultures inoculated at 105 cells/ml were grown in suspension in HL5 with 50 µg/ml G418 and rotated at 200 rpm. b, micrographs of cells overexpressing either MHCK A or Delta Coil-MHCK A in cells containing either wild-type MHC or 3X ALA MHC. Notice that cells expressing MHCK A in a wild-type myosin II background are large and multinucleated, whereas cells expressing MHCK A in a 3X ALA myosin II background are not affected by MHCK A overexpression.
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Purification of Full-length MHCK A, Delta Coil-MHCK A, and Delta WD-MHCK A

To determine the activity of each construct, the proteins were purified from Dictyostelium cultures. The previously reported purification method for MHCK A (26) was modified to allow purification of each MHCK A construct using four to five column steps. A summary of the purification of MHCK A constructs is found in Table I, and details on the purification of each MHCK A construct are given under "Experimental Procedures." The purification table is presented as a guide to show relative purification during the purification process. A detailed comparison of the activities of the proteins under equivalent conditions is presented below. Fig. 4 shows purified MHCK A, Delta WD-MHCK A, and Delta Coil-MHCK A after SDS-polyacrylamide gel electrophoresis and Coomassie Blue staining (panel a) or Western blot analysis (panel b). MHCK A and Delta Coil-MHCK A ran at 130 and 73 kDa, respectively. Delta WD-MHCK A ran as a doublet at 96 and 90 kDa. This could represent autophosphorylation heterogeneity or a partial proteolytic clip. Both forms were recognized by polyclonal antisera, and both became radioactive in an autophosphorylation test performed with [gamma -32P]ATP.

Table I. Purification of MHCK A truncations from Dictyostelium


Volume Protein Specific activity Total activity

ml mg nmol/min/mg nmol/min
MHCK A
  Total extract 90 2160 0.03 65
  Supernatant 80 1280 0.04 52
  DE52 supernatant 80 640 0.6 384
  Phosphocellulose 22 77 5 385
  Hydroxylapatite 5 18 45 818
  Sephacryl S-300 23 4 60 238
 Delta Coil-MHCK A
  Total extract 90 2070 0.03 62
  Supernatant 80 1560 0.03 47
  DE52 supernatant 140 742 0.3 223
  Phosphocellulose 19 72 1.6 115
  Hydroxylapatite 5 31 3.6 112
  Sephacryl S-300 22 9 4.9 44
  Mono-S 7 1.2 14.4 17
 Delta WD-MHCK A
  Total extract 120 2070
  Supernatant 100 1000 0.08 80
  DE52 supernatant 170 425 1.4 595
  Phosphocellulose 43 108 3.6 388
  Hydroxylapatite 8 21 6.2 130
  Sephacryl S-300 18 1.35 18.3 11
  AH-Sepharosea 2.5 0.25 30 7.5

a AH-Sepharose, aminohexyl-Sepharose.


Fig. 4. MHCK A truncation constructs purified from Dictyostelium. a, Coomassie Blue staining of SDS-polyacrylamide gels; b, Western blot analysis.
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MHCK A Oligomerization and Rotary Shadowing

Several lines of evidence indicate that MHCK A is an oligomeric protein kinase, including gel filtration analysis of native protein (8), cross-linking studies (15), and coiled-coil predictive algorithms (15). Gel filtration chromatography performed as the final or penultimate step in each purification allowed us to test the hypothesis that the amino-terminal domain of MHCK A (residues 1-500) is responsible for oligomerization. The gel filtration analysis of full-length MHCK A and truncation constructs is presented in Fig. 5. Full-length MHCK A migrated at 130 kDa on SDS-polyacrylamide gel electrophoresis, but under native conditions, gel-filtered in the void volume with an estimated molecular mass >1000 kDa. This is consistent with the 130-kDa protein being oligomeric. Rod-shaped protein domains such as coiled-coil helices gel filter with larger apparent mass that globular protein of equivalent size, so the number of MHCK A monomers in each oligomer cannot be estimated accurately from this elution behavior.


Fig. 5. Gel filtration analysis of native molecular masses of MHCK A truncation constructs. Purified near-homogeneous preparations of MHCK A truncation constructs were applied to Sephacryl S-300 gel permeation chromatography, and elution position was determined by peptide phosphorylation and Western blot analysis.
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Deletion of the carboxyl-terminal WD repeats (Delta WD-MHCK A) resulted in gel filtration at a slightly smaller apparent mass than native MHCK A, but still >670 kDa, which is much larger than its predicted molecular size of 96 kDa. Elimination of the amino-terminal 500 amino acids caused Delta Coil-MHCK A to gel filter with an apparent molecular mass of 80 kDa, which is consistent with the predicted mass of 73 kDa. These results indicate that the amino-terminal 500 residues of MHCK A, which are predicted to form a coiled-coil structure, are responsible for MHCK A oligomerization. The computer algorithm SCORER, created by Woolfson and Alber (28), predicts whether a sequence is expected to form a two- or three-stranded coiled-coil. According to this algorithm, MHCK A is predicted to form a three-stranded coiled-coil (data not shown).

Full-length MHCK A was visualized by platinum rotary shadowing (Fig. 6). The majority of the rotary-shadowed images appeared globular or aggregated, as in the lower right panel of Fig. 6. However, a number of images were also observed that appeared to reveal a globular domain associated with an extended rod-like structure (all other panels in Fig. 6). Measurements of these images indicated an average length for the rod-like segments of ~50 nm. The average calculated pitch of coiled-coil helices from proteins such as myosin tails is 6.7 residues/nm. If MHCK A residues 100-500 were contained entirely in a coiled-coil structure (15), a rod domain of ~60 nm would be predicted. This value is agreement with the ~50-nm length of the rod structures observed by rotary shadowing. The apparent globular segment of the images was always observed at only one end of the rod segment, suggesting that MHCK A complexes form via parallel oligomerization rather antiparallel oligomerization.


Fig. 6. Full-length MHCK A prepared by rotary shadowing. Purified MHCK A was sprayed in a solution containing 20-50 µg/ml protein in 50% glycerol and plated with platinum as described previously (31). A composite of six micrographs shows the extended rod of MHCK A. Bar = 100 nm.
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Biochemical Characterization of MHCK A Constructs

Autophosphorylation

Previous studies showed that MHCK A is activated by autophosphorylation, incorporating up to 10 mol of phosphate/mol of enzyme. Incorporation of the first 3 mol of phosphate was shown to be sufficient for maximum activation (18). Autophosphorylation behavior was assessed for MHCK A truncation constructs. Full-length MHCK A, Delta Coil-MHCK A, and Delta WD-MHCK A all autophosphorylated to a similar range of 8-10 mol of phosphate/mol of enzyme (Fig. 7a). The autophosphorylation rates of each construct were independent of concentration, suggesting that autophosphorylation is an intramolecular process (data not shown).


Fig. 7. Protein kinase activity of recombinant MHCK A constructs (MHCK A (circles), Delta Coil-MHCK A (squares), and Delta WD-MHCK A (triangles). a, phosphate incorporation into MHCK A truncation constructs by autophosphorylation. Phosphate incorporation into MHCK A (final concentration of 200 nM) truncation constructs was performed in buffer containing 10 mM TES, 2 mM MgCl2, 1 mM DTT, and 0.5 mM ATP (1000 cpm/pmol). At the indicated times, aliquots (25 µl) were removed, and 32P incorporation was determined by phosphocellulose filter paper assay. b, phosphate incorporation into peptide MH-1 by MHCK A truncation constructs. MHCK A truncation constructs were preincubated in 0.5 mM MgATP for 20 min. Phosphorylation of peptide MH-1 was initiated by the addition of kinase (2 µg/ml) and incubation for 1 min at 25 °C. Reactions were stopped by the addition of 50 mM EDTA, and 32P incorporation into peptide MH-1 was determined by phosphocellulose filter paper assay. Error bars represent S.D. for triplicate samples. c, phosphate incorporation into Dictyostelium myosin II by MHCK A truncation constructs. MHCK A truncation constructs were preincubated in 0.5 mM MgATP for 20 min. Incorporation of 32P into myosin II was initiated by the addition of kinase (2.5 µg/ml) and incubation for 4 min at 25 °C. Reactions were stopped by the addition SDS sample buffer and electrophoresed on an SDS-polyacrylamide gel. Myosin bands were cut from the gel and counted in a scintillation counter. Symbols are an average of two samples.
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Activity of MHCK A Constructs toward Peptide

MHCK A has been shown to phosphorylate the myosin tail on threonines 1823, 1833, and 2029. We used a 16-residue peptide (MH-1) corresponding to the sequence around Thr-2029 in the myosin tail to test the enzymatic activity of each construct. Fig. 7b shows phosphorylation of the peptide by purified autophosphorylated MHCK A, Delta Coil-MHCK A, and Delta WD-MHCK A. The phosphorylation of the peptide obeys Michaelis-Menten kinetics; full-length recombinant MHCK A (circles) had a Km of 92 µM with a Vmax of 3.6 µmol × min-1 × mg-1 for the peptide, in close agreement with previous values reported for native MHCK A by Medley et al. (18) (Km = 105 µM and Vmax = 2.2 µmol × min-1 × mg-1). As indicated by the kinetic parameters (Table II), both truncation constructs displayed relatively similar activity against peptide MH-1 as compared with full-length MHCK A. 

Table II. Kinetic properties of recombinant MHCK A constructs determined for a peptide substrate

Phosphorylation assays were performed in triplicate using peptide MH-1.

Km Vmax Kcat

µM µmol × min-1 × mg-1 s-1
MHCK A 92  ± 10 3.6  ± 0.1 7.8
 Delta Coil-MHCK A 235  ± 31 5.4  ± 0.3 6.6
 Delta WD-MHCK A 125  ± 14 4.0  ± 0.1 6.4

Activity of MHCK A Constructs toward Myosin II

Autophosphorylated MHCK A, Delta Coil-MHCK A, and Delta WD-MHCK A were assayed for their ability to phosphorylate wild-type Dictyostelium myosin II (Fig. 7c). Delta Coil-MHCK A was able to phosphorylate myosin II at a rate similar to that of full-length MHCK A. In contrast, Delta WD-MHCK A showed a substantial decrease in activity against myosin as compared with MHCK A or Delta Coil-MHCK. While it is difficult to obtain accurate kinetic constants for myosin II because it is filamentous under the assay conditions, the specific activities of Delta WD-MHCK A measured with several concentrations of myosin were consistently 20-fold lower than those of MHCK A and Delta Coil-MHCK A. These results are consistent with the in vivo results and suggest that the WD repeat domain of MHCK A is required for efficient substrate recognition of myosin II both in vitro and in vivo.


DISCUSSION

In vitro and in vivo analyses of MHCK A truncation constructs have been used to identify the roles of the two domains that flank the catalytic domain of MHCK A. The earlier demonstration that full-length MHCK A overexpression leads to disassembly of cytoskeletal myosin II in vivo (14) provided a useful assay for in vivo activity of the expressed constructs.

Gel filtration analysis of the purified constructs demonstrated a loss of oligomerization in the Delta Coil-MHCK A construct. An extended rod-like domain was also observed in the rotary-shadowed images of native MHCK A. These results provide experimental evidence that the segment of MHCK A spanning residues 1-500 contains the oligomerization functions and that the oligomer formation probably occurs via formation of a parallel coiled-coil rod structure.

Elimination of this domain did not appear to significantly impair in vitro kinase activity against native myosin II or peptide MH-1. Although Delta Coil-MHCK A displayed a slightly elevated Km for peptide MH-1, its Vmax and Kcat values were similar to those of full-length MHCK A. The autophosphorylation stoichiometry in this construct also appeared similar to that in full-length MHCK A. Furthermore, Delta Coil-MHCK A appeared active in vivo, as assessed by its ability to impede myosin-based contractile events in vivo in the presence of wild-type myosin II. It can be speculated that the coiled-coil region of MHCK A could have other functions, such as annealing with bipolar myosin filaments or serving as a pseudosubstrate or autoinhibitory domain. Preliminary results in our laboratory have not found evidence to support either of these theories, however.

Expression of either Delta Coil-MHCK A or full-length MHCK A completely eliminated myosin contractile function in vivo in cells containing wild-type MHC. However, when these kinase constructs were overexpressed in cells containing 3X ALA MHC, no inhibition of myosin-based contractile function was observed. The relatively normal phenotype of these cells provides the first demonstration that the in vitro mapped target sites of MHCK A on the myosin tail are also the physiologically relevant in vivo target sites of MHCK A. The properties of these cell lines furthermore confirm the hypothesis that defects observed when MHCK A is overexpressed in wild-type MHC cells are due solely to the activity of the kinase against myosin II, as opposed to other in vivo substrates. All the phenotypic defects observed when MHCK A is overexpressed can be attributed to its activity toward residues 1823, 1833, and 2029 in the myosin II tail.

While overexpressing full-length MHCK A and Delta Coil-MHCK A resulted in striking phenotypes, the elimination of amino acids 842-1146, corresponding to the WD repeat domain, resulted in no increase in MHC phosphorylation in Triton extracts and no impairment of myosin II function in vivo during development or growth in suspension. This phenotype is interesting since Delta WD-MHCK A is expressed at a 3-fold higher level than full-length MHCK A in MHCK A+ cells. Purified Delta WD-MHCK A autophosphorylated to a similar extent as MHCK A and Delta Coil-MHCK A. More important, Delta WD-MHCK A also displayed similar kinetics as MHCK A and Delta Coil-MHCK A toward the MH-1 peptide substrate, which corresponds to the target site at residue 2029 on the myosin II tail.

Full catalytic activity against peptide MH-1 by Delta WD-MHCK A indicates that the peptide substrate-binding regions of MHCK A and all core catalytic functions are intact in this construct. Despite this, a 95% drop in activity against native myosin II was observed in vitro, and the overexpressed kinase did not interfere with myosin II function in vivo despite its high expression level. These results support the hypothesis that the WD repeat domain of MHCK A plays a critical role in substrate recognition with the native myosin II substrate. Attempts to measure the Km of each kinase construct for native myosin II are complicated by the filamentous nature of the substrate under assay conditions. Other methods are currently being explored to determine directly whether the WD repeats of MHCK A act as a myosin II-binding domain.

beta -Subunits of heterotrimeric GTP-binding proteins serve as the prototype for members of the WD repeat family of proteins (16, 17). This prototype class consists of an amino-terminal segment of ~50 residues, which is followed by seven repeats of ~40 residues, with each repeat containing a conserved "WD" motif. Although the number of WD repeats varies in different members of the WD repeat family of proteins, most members probably fold into a structure similar to the seven-blade "beta -propeller" structure identified for the human G protein beta -subunit via x-ray crystallography (29, 30).

Although beta -subunits of GTP-binding proteins have an established role in binding to and activating effector targets, the roles of WD repeat domains in other classes of WD repeat-containing proteins are not well characterized. To our knowledge, the work presented here is the first biochemical evidence for a WD repeat domain serving to target an attached catalytic domain to its substrate.

Neer et al. (16, 17) have suggested that the conserved residues of the WD repeats provide a rigid scaffold and that the variable residues between may specify the interactions with different proteins. A more detailed analysis of the MHCK A WD repeat domain will be necessary to determine which residues dictate the specificity toward myosin II filaments.


FOOTNOTES

*   This work was supported in part by National Institutes of Health Grant GM50009 (to T. T. E.).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    Supported by National Institutes of Health Training Grant HL07653.
§   Recipient of an American Cancer Society junior faculty research award. To whom correspondence should be addressed. Tel.: 216-368-6971; Fax: 216-368-1693.
1   The abbreviations used are: MHC, myosin II heavy chain; MHCK, MHC kinase; MES, 4-morpholineethanesulfonic acid; TES, 2-{[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]amino}ethanesulfonic acid; DTT, dithiothreitol.

ACKNOWLEDGEMENTS

We thank Dr. Graham Côté for advice and helpful discussions and Dr. Roger Craig for rotary shadowing MHCK A.


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