©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
35H, a Sequence Isolated as a Protein Kinase C Binding Protein, Is a Novel Member of the Adducin Family (*)

(Received for publication, May 31, 1995; and in revised form, July 20, 1995)

Liqun Dong Christine Chapline Betty Mousseau Lynn Fowler Katrina Ramsay James L. Stevens Susan Jaken (§)

From the W. Alton Jones Cell Science Center, Inc., Lake Placid, New York 12946-1099

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

We recently cloned a partial cDNA (35H) for a protein kinase C (PKC) binding protein from a rat kidney cDNA library and demonstrated that it is a PKC substrate in vitro (Chapline, C., Ramsay, K., Klauck, T., and Jaken, S.(1993) J. Biol. Chem. 268, 6858-6861). Additional library screening and 5` rapid amplification of cDNA ends were used to obtain the complete open reading frame. Amino acid sequence analysis, DNA sequence analysis, and Northern analysis indicate that 35H is a unique cDNA related to alpha- and beta-adducins. Antisera prepared to the 35H bacterial fusion protein recognized two polypeptides of 80 and 90 kDa on immunoblots of kidney homogenates and cultured renal proximal tubule epithelial cell extracts. The 35H-related proteins were similar to alpha- and beta-adducins in that they were preferentially recovered in the Triton X-100-insoluble (cytoskeletal, CSK) fraction of cell extracts and were predominantly localized to cell borders. Phorbol esters stimulated phosphorylation of CSK 35H proteins, thus emphasizing that sequences isolated according to PKC binding activity in vitro are also PKC substrates in vivo. The phosphorylated forms of the 35H proteins were preferentially recovered in the soluble fraction, thus demonstrating that phosphorylation regulates their CSK association and, thereby, their function in regulating cytoskeletal assemblies. We have isolated another PKC binding protein partial cDNA (clone 45) from a rat fibroblast library with substantial homology to alpha-adducin. Antisera raised against this expressed sequence recognized a protein of 120 kDa, the reported size of alpha-adducin, on immunoblots of renal proximal tubule epithelial cell extracts. A 120-kDa protein that cross-reacts with the clone 45 (alpha-adducin) antisera coprecipitated with 35H immunecomplexes, indicating that alpha-adducin associates with 35H proteins in vivo. Taken together, these results indicate that 35H is a new, widely expressed form of adducin capable of forming heterodimers with alpha-adducin. We propose naming this adducin homologue -adducin.


INTRODUCTION

Protein kinase Cs are a heterogeneous group of phospholipid-dependent kinases important for cell growth and differentiated functions (reviewed in (1) ). The family can be divided into three categories based on enzymatic properties. The conventional or Group A PKCs (^1)are calcium-dependent kinases whose activities are stimulated by diacylglycerol or phorbol esters. The novel or Group B PKCs are calcium-independent but still diacylglycerol-stimulatable. The atypical or Group C PKCs are calcium- and diacylglycerol-independent. Most cells express more than one type of PKC, which implies that PKCs have unique rather than overlapping functions.

Activation of Group A and B PKCs is regulated by receptor-mediated production of diacylglycerol through phospholipase C or D pathways(1) . In many cases, activation correlates with PKC redistribution from soluble to particulate fractions. However, in other cases, evidence for activation in the absence of measurable translocation has been noted (2, 3, 4, 5) . The correlation between translocation and activation is further confused by the fact that PKC inhibitors such as staurosporine can also cause PKC redistribution(6, 7) . Thus, redistribution does not necessarily reflect PKC activation under all conditions.

An alternative method for studying PKC activation is to monitor the phosphorylation state of PKC substrates. For example, phosphorylation of MARCKS, a major PKC substrate in many cells, has been useful for demonstrating PKC activation in response to a variety of physiological agonists(8) . Our goal has been to identify a panel of high affinity substrates for PKCs that can be used as reporter systems to monitor PKC activity in response to external stimuli and in pathological processes. To this end, we developed a blot overlay assay to identify PKC binding proteins. In subsequent studies, we demonstrated that MARCKS and other PKC substrates interact with PKCs in this in vitro assay (9, 10) and suggested that, in general, binding proteins are also substrates. The overlay assay is based on a phospholipid-dependent, high affinity interaction between PKCs and recognition sites on other proteins (substrates)(11) . With slight modifications, the assay can also be used in an interaction cloning strategy to isolate expressed cDNAs for PKC substrates (12) .

In our original report on interaction cloning of PKC substrates(12) , we identified two PKC binding sequences: MARCKS-related protein (clone 35A) and a unique partial cDNA sequence with homology to adducins (clone 35H). Both were shown to be PKC substrates in vitro. In the present study, we report the complete coding sequence for 35H, identify it as a novel form of adducin, and establish that it is also a PKC substrate in vivo. These results underscore the utility of the PKC interaction cloning approach for identifying novel PKC substrates.


EXPERIMENTAL PROCEDURES

Materials

Male Fisher 344 rats weighing 150-175 g were obtained from Taconic Farms (Germantown, NY). Collagen type I was purchased from Collaborative Biomedical Products (Bedford, MA). Phosphate-free Dulbecco's modified Eagle's medium, phorbol 12,13-dibutyrate (PDBu), insulin, and cholera toxin were from Sigma. Epidermal growth factor was from Upstate Biotechnology, Inc., Lake Placid, NY. Immunoprecipitin (Formalin-fixed Staph A cells), Dulbecco's modified Eagle's medium, Ham's F12 medium, and fetal bovine serum were from Life Technologies, Inc. [alpha-P]UTP (3000 Ci/mmol) and [P]orthophosphate (8500-9120 Ci/mmol) were purchased from DuPont NEN. In vitro transcription kit was purchased from Ambion (Austin, TX). Restriction enzymes and alkaline phosphatase-conjugated goat anti-rabbit IgG were obtained from Promega (Madison, WI). Fluorescein-conjugated goat anti-rabbit IgG was from Jackson ImmunoResearch Laboratories, Inc. (West Grove, PA). Aqua-Poly/Mount was from Polysciences, Inc. (Warrington, PA).

Cell Culture

Primary RPTE cultures were prepared from rat kidney proximal tubules and were grown on collagen type I coated plastic culture dishes as described(13, 14) .

5` Extensions of 35H Sequence

A partial cDNA containing the 3` end of the 35H sequence was originally isolated from a rat kidney oligo(dT)-primed cDNA library by PKC interaction cloning (12) . Since Northern analysis indicated substantial message expressed in brain, a rat brain random primed cDNA library (Clontech) was screened with the 35H partial cDNA clone in order to isolate more 5` regions of the open reading frame. This screen produced a clone that overlapped the original kidney clone but included no additional 5` sequence. The sequence of the brain clone was identical to that of the kidney clone. Two rounds of 5` rapid amplification of cDNA ends from rat kidney mRNA produced 800 base pairs of additional 5` sequence. These sequences were also isolated from a REF52 cell library using two rounds of 5` polymerase chain reaction. A third round of 5` polymerase chain reactions from either the kidney or the REF52 library or 5` rapid amplification of cDNA end reactions with kidney or REF52 mRNA did not yield products with additional 35H 5` sequence. However, 5` polymerase chain reaction from the rat brain library (Clontech) did produce an overlapping product, which included the 5` end of the 35H sequence.

Production of Anti-35H Antisera

35H cDNA was inserted in frame into a pQE bacterial expression vector (QIAGEN; Chatsworth, CA) to produce a recombinant protein containing 6 histidine residues at the N terminus. The fusion protein was expressed in Escherichia coli and purified on a nickel-agarose column (QIAGEN) according to the manufacturer's instructions. The purified fusion protein was used for production of rabbit antiserum. Anti-35H antiserum was affinity-purified against the corresponding bacterially expressed fusion protein.

Preparation of Clone 45 Fusion Protein and Antisera

Clone 45 is another partial cDNA isolated from a REF52 cell library on the basis of PKC binding activity as described(12) . Clone 45 is a 935-base pair fragment with 80% homology to human alpha-adducin, suggesting that clone 45 is the rat homologue of human alpha-adducin. Clone 45 cDNA was inserted into the pQE vector and expressed as the 6X His-tagged fusion protein as described above. Antisera were prepared to clone 45 fusion protein and immunopurified against the bacterially expressed fusion protein.

Preparation of Cell Lysates and Kidney Homogenates for Immunoblot Analysis

Cell lysates were prepared as described(24) . Freshly isolated rat kidneys were homogenized in homogenization buffer (20 mM Tris-Cl, pH 7.4, 0.25 M sucrose, 5 mM EDTA, 1 mM dithiothreitol, 10 µg/ml leupeptin, 10 µg/ml aprotinin, and 1 mM phenylmethylsulfonyl fluoride). Protein concentrations were determined according to the method of Bradford (15) using reagents from Bio-Rad. Immunoblot analysis was performed as described(24) .

Preparation of Triton X-100 Soluble and Cytoskeletal Fractions

Cells were washed twice with microtubule stabilization buffer (MSB; 0.1 M PIPES-NaOH, pH 6.9, 2 M glycerol, 1 mM EGTA, and 1 mM magnesium acetate)(16) . Soluble proteins were extracted with 0.2% Triton X-100 in MSB containing 10 µg/ml leupeptin and 10 µg/ml aprotinin for 4 min at room temperature. Triton X-100 insoluble proteins, referred to as the CSK fraction, were washed with MSB. For immunoblot analysis and immunoprecipitation, CSKs were scraped into MSB containing leupeptin and aprotinin and sonicated.

Metabolic Labeling

Cells grown on 35-mm dishes were washed with phosphate-free Dulbecco's modified Eagle's medium three times, labeled with 100 µCi/ml [P]orthophosphate (P(i)) in phosphate-free Dulbecco's modified Eagle's medium with supplements as described under ``Cell Culture'' for 4 h at 37 °C. During the final labeling period, cells were treated with PDBu for the indicated times. When PDBu treatment was longer than 4 h, the P(i) was added during the final 4 h. After labeling, cells were washed twice with phosphate-buffered saline and scraped into 1 ml of radioimmunoprecipitation assay buffer, which was 50 mM Tris-Cl, pH 7.4, 0.15 M NaCl, 1 mM EDTA, 1% sodium deoxycholate, 1% Triton X-100, 0.1% sodium dodecyl sulfate, 10 µg/ml leupeptin, 10 µg/ml aprotinin, 1 mM phenylmethylsulfonyl fluoride, 50 mM sodium fluoride, and 1 mM sodium vanadate. For soluble and CSK preparations, cells were washed twice with MSB after labeling, and the soluble and CSK fractions were prepared in 0.8 ml of MSB as described above. Samples were adjusted to 1 times radioimmunoprecipitation assay buffer for immunoprecipitation.

Immunoprecipitation of 35H

P-labeled samples (1 ml), prepared as described above, were precleared by incubating with 150 µl of formalin-fixed Staph A cells (10%, w/v) for 1 h. Precleared supernatants were collected and incubated with 10 µl of anti-35H antiserum or preimmune serum for 1 h. Protein A-Sepharose (40 µl, 50%, v/v) was added, and the incubation continued for another hour. All incubations were performed at 4 °C on a shaker. Immunecomplexes were collected by centrifugation and washed by centrifugation and resuspension twice in radioimmunoprecipitation assay buffer, once in low salt buffer (50 mM Hepes, pH 7.4, 0.15 M NaCl, 1 mM EDTA, and 0.1% Nonidet P-40), once in high salt buffer (50 mM Hepes, pH 7.4, 0.5 M NaCl, 1 mM EDTA, and 0.1% Nonidet P-40), and once in low salt buffer again. Immunoprecipitated proteins were eluted from protein A-Sepharose by boiling for 5 min in Laemmli buffer (17) and then separated on 7.5% denaturing polyacrylamide gels. Immunoprecipitated proteins were visualized by autoradiography. In some experiments, immunoprecipitates from nonradioactive cells were collected in parallel and blotted to nitrocellulose.

Immunocytofluorescence

Cells were grown on 12-mm glass coverslips as described under ``Cell Culture.'' Whole cell and CSK preparations were fixed with 3.7% formaldehyde in phosphate-buffered saline (whole cell) or in MSB (CSK) for 10 min at room temperature and permeabilized with absolute methanol for 6 min at -20 °C(18) . The coverslips were blocked with 1% bovine serum albumin in phosphate-buffered saline for 30 min and stained sequentially with 10 µg/ml affinity-purified anti-35H antibody for 1 h and with fluorescein-conjugated goat anti-rabbit IgG for 1 h. The coverslips were mounted with Aqua-Poly/Mount onto slides and observed under a Nikon fluorescence microscope with a 60 times objective lens.

Northern Blot Analysis

Blots containing 2.5 µg of poly(A) mRNA from multiple tissues were purchased from Clontech. Random labeled cDNA probes were prepared with [P]dCTP. Prehybridization conditions were 3 h at 42 °C in 5 times SSPE and 2 times Denhardt's in the presence of 100 µg/ml denatured salmon sperm DNA, 2% SDS, and 50% formamide. Blots were hybridized for 48 h at 42 °C in the prehybridization solution, washed three times in 2 times SSC containing 0.1% SDS at room temperature, and washed three more times in 0.1 SSC containing 0.1% SDS at 50 °C. Films shown were exposed for 6-7 days.


RESULTS

Relationship of 35H to Adducins

The original clone 35H, which is a partial cDNA from a rat kidney library, had substantial homology to the 3` end of human brain beta-adducin in defined areas (12) . However, since the sequences diverged significantly in other areas, the extent of the relationship to beta-adducin could not be determined. Both library screening and 5` rapid amplification of cDNA ends were used to obtain the entire 35H coding sequence. Alignments of the full-length 35H translated sequence with human alpha- and beta-adducins demonstrate that although 35H shares substantial homology with alpha- and beta-adducins, it is a unique sequence (Fig. 1). Overall, rat 35H is 50-60% homologous to human alpha- and beta-adducins. In contrast, rat and human beta-adducin sequences are nearly identical (90% homology with conservative substitutions except for the highly variable C terminus, which is truncated in the reported rat sequence(19) ). The high degree of homology between the rat and human beta-adducin sequences indicates that species differences alone do not account for the the difference between 35H and the human adducin sequences.


Figure 1: Alignment of 35H with alpha- and beta-adducins. Predicted amino acid sequences of 35H and alpha- and beta-adducins were aligned using DNAsis (Hitachi) software. Sequences containing 5 or more residues with >80% homology were manually identified and shaded to easily identify conserved domains.



In previous studies, alignments of human alpha-adducin with human and rat beta-adducins revealed that the adducins share a homologous N-terminal domain followed by a highly divergent region near the C terminus and a highly conserved polybasic region at the extreme C terminus (residues 696-726 in beta-adducin)(19, 20) . This overall pattern is also apparent in the 35H alignment. Within the relatively conserved N-terminal domains, divergent regions are separated by stretches with near identity and conservative substitutions (Fig. 1, shaded regions). In general, there is a good correlation in spacing of the variable and conserved domains within alpha-adducin, beta-adducin, and 35H sequences. This alignment suggests that adducins are a family of proteins with constant domains separated at defined intervals by isoform-specific sequences, and furthermore that 35H is a newly identified member of the adducin family.

35H shares homology to beta- but not alpha-adducin in two of the variable regions (437-447 and 472-484; numbers refer to beta-adducin residues shaded in Fig. 1). On the other hand, 35H shares homology to alpha-adducin in other variable regions (8-15, 19-27, 85-92; numbers refer to alpha-adducin residues shaded in Fig. 1). These results emphasize that 35H is a unique sequence distinct from previously identified forms of adducin. Both alpha-adducin and 35H diverge significantly from the beta-adducin putative calmodulin binding domain(446-454)(21) . Diversity in this sequence suggests a potentially significant difference in calmodulin regulation of 35H and beta-adducin functions. The conserved high positive charge density domains in the extreme C termini are identical with the exception of the change of a potential phosphorylatable Ser to Asn in 35H. 35H does not contain Tyr of alpha-adducin or Arg of beta-adducin, which have been identified as a potential tyrosine kinase phosphorylation site or a determinant of cAMP-dependent kinase phosphorylation, respectively(22) . Mutations in these sites have been linked to hypertension.

Tissue Distribution

Northern analysis was used to compare the tissue distribution of 35H with alpha- and beta-adducins. Previous studies have shown that alpha-adducin probes hybridized to a 4.0-kb mRNA with wide tissue distribution, whereas beta-adducin probes hybridized to an 8.1-kb mRNA in brain, which was not detectable in liver and kidney (20) . Three smaller messages (3.0-4.2 kb) were detected in spleen, kidney, and heart(19, 20) . In contrast, 35H probes hybridized to a 4.5-kb message in all rat and human tissues examined (Fig. 2), although message was less abundant in lung and liver. A second, less prominent band at 7.5 kb was also detected in spleen, kidney, and testis. In summary, differences in the primary amino acid sequence, message size, and tissue distribution clearly distinguish 35H from alpha- and beta-adducins.


Figure 2: Tissue distribution of 35H mRNA. Northern blots were hybridized with a radiolabeled 35H cDNA probe under stringent conditions. Blots shown were exposed to film for 24 h. Left, rat tissue mRNAs; right, human tissue mRNAs. H, heart; Br, brain; Sp, spleen; Lu, lung; Li, liver; Mu, muscle; Ki, kidney; Te, testes; Pl, placenta; Lu, lung; Pa, pancreas.



Expression of 35H Protein in Primary RPTE and Rat Kidney

Antiserum raised against the bacterially expressed 35H fusion protein was used to study 35H-related proteins in cultured RPTE and kidney extracts. Affinity-purified anti-35H antibody reacted strongly with an 80-kDa protein in cell lysates of primary growing RPTE (Fig. 3A). A weaker band at 90 kDa was also apparent. The 80- and 90-kDa immunoreactive proteins were also detected in kidney homogenates, although the 90-kDa band was more intense relative to RPTE. Neither the 80- nor the 90-kDa proteins were detected by preimmune serum (data not shown). The reason for the relative increase in 90-kDa 35H in whole kidney homogenates versus RPTE is not known; however, since kidney contains many cell types in addition to proximal tubules, it is possible that different kidney cell types express different forms of 35H. Thus, two immunoreactive forms of 35H are expressed in kidney, and the 80-kDa form is preferentially expressed in the cultured RPTE. Because of their cross-reactivity with affinity-purified antisera to the 35H fusion protein, they will be referred to as 35H proteins.


Figure 3: Immunoblot analysis of renal 35H and alpha-adducin (clone 45). Homogenates were prepared from primary growing renal proximal tubule epithelial cells (lane 1) and rat kidney tissue (lane 2). Aliquots (100 µg of protein) were separated on denaturing polyacrylamide gels and transferred to nitrocellulose paper. Blots were stained with affinity-purified anti-35H antibody (A) or with affinity-purified anti-45 antibody (B) at a concentration of 1 µg/ml. Results are representative of more than five experiments.



alpha-Adducin Is a PKC Binding Protein

The interaction cloning strategy was also used to screen a rat fibroblast gt11 library for PKC binding proteins. One product of this screen is a partial cDNA (clone 45) with a predicted translated sequence 77% identical to the carboxyl terminus of human alpha-adducin (Fig. 4). The sequences diverge significantly only in the C terminus, the region where rat and human beta-adducin sequences diverge from each other(19) . Antisera prepared to the expressed bacterial fusion protein and immunopurified against the cognate protein recognized a protein of 120 kDa, the reported size of alpha-adducin, in homogenates of cultured renal cells or tissue (Fig. 3B). The sequence identity and size similarity indicate that clone 45 is the rat homologue of human alpha-adducin.


Figure 4: Alignment of clone 45 and alpha-adducin. Predicted amino acid sequences of the open reading frame of the clone 45 partial cDNA and the corresponding region of human alpha-adducin were aligned using DNAsis (Hitachi) software. Dots indicate identical residues in the two sequences. Dashes indicate gaps.



Phosphorylation of 35H in Primary Growing RPTE

Previous studies demonstrated that the bacterially expressed 35H protein could be phosphorylated by purified PKC in vitro(12) . To determine if 35H proteins were PKC substrates in intact cells, primary growing RPTEs were prelabeled with orthophosphate, and the effect of PDBu on stimulating phosphate incorporation into proteins precipitated by 35H antiserum was determined (Fig. 5). In the absence of PDBu-treatment, three phosphoproteins of approximately 80, 90, and 120 kDa were specifically immunoprecipitated. PDBu increased phosphate incorporation into the 80- and 120-kDa bands approximately 6-fold (as quantitated by scanning densitometry), and into the 90-kDa band to a lesser extent (2-3-fold). The 80- and 90-kDa bands correspond to immunoreactive proteins detected on blots as shown in Fig. 3. The 120-kDa band was not detected on blots and represents a co-immunoprecipitating protein (see below).


Figure 5: Phosphorylation of 35H homologues in intact primary growing RPTE. Primary proliferating RPTE were labeled with P(i). Samples from control (-) and PDBu-treated (+) (200 nM PDBu for 10 min) cultures were prepared. Cell lysates were immunoprecipitated with anti-35H antiserum, nonimmune rabbit serum (non-i), or preimmune (pre-i) serum (Ig). Immune complexes were separated on denaturing polyacrylamide gels, and proteins were visualized by autoradiography. Similar results were obtained in two additional experiments.



Since beta-adducin is known to form heterocomplexes with 120-kDa alpha-adducin(23) , we hypothesized that the 120-kDa protein coprecipitating with 35H antibodies may be alpha-adducin (our clone 45). To determine if alpha-adducin was present in the 35H immunecomplexes, 35H immunoprecipitates of cell lysates were prepared and blotted to nitrocellulose. Antibodies to 35H recognized the 80- and 90-kDa 35H in the immunoprecipitates but did not recognize the 120-kDa phosphoprotein apparent on the autorads (Fig. 6A). In contrast, affinity-purified antibodies to clone 45 (alpha-adducin) fusion protein recognized a 120-kDa band in the 35H immunoprecipitates (Fig. 6B). Since antibody to recombinant clone 45 protein does not recognize recombinant clone 35H protein and vice versa (Fig. 7), these results strongly suggest that alpha-adducin is not directly precipitated with 35H antisera but that it coprecipitates with the 35H proteins.


Figure 6: Identification of an alpha-adducin homologue in 35H immunoprecipitates. Cell lysates were prepared from primary growing RPTE and immunoprecipitated with nonimmune serum (lane 1) or 35H antiserum (lane 2). Immune complexes were separated on denaturing polyacrylamide gels and transferred to nitrocellulose paper. Left, the blot was stained with affinity-purified anti-35H antibody. Right, the same blot was cut and stained with affinity-purified anti-45 antibodies. Similar results were obtained in two additional experiments.




Figure 7: Specificity of anti-35H antibodies. Aliquots of affinity-purified 35H and 45 protein were dot-blotted onto nitrocellulose at the concentrations shown. Blots were stained with affinity-purified anti-35H antisera (A) or anti-45 antisera (B) at a concentration of 1 µg/ml.



Regulation of 35H Cytoskeletal Association by Phosphorylation

The distribution of 35H proteins between Triton X-100-soluble and insoluble (CSK) fractions in resting and PDBu-stimulated cultures was analyzed by immunoblotting. Densitometric analysis indicated that in resting cultures, approximately 80% of the total 80- and 90-kDa proteins were recovered in the CSK fraction (Fig. 8). Activation of PKC by PDBu treatment increased soluble 35H proteins approximately 2-fold. It is likely that the increase in soluble 35H is due to redistribution from the CSK pool, although a corresponding decrease in the CSK 80- and 90-kDa proteins was more difficult to detect. These results suggest that only a small fraction of the total CSK 35H is redistributed to the soluble fraction with PDBu stimulation. After 16 h of PDBu treatment, which partially down-modulates PKC in these cells(24) , the distributions of both 80- and 90-kDa proteins between soluble and CSK fractions were similar to resting cultures.


Figure 8: Effects of PDBu on 35H subcellular distribution. Primary growing RPTEs were treated with PDBu (200 nM) for 0, 0.2, 1.5, or 16 h. Soluble (SOL) and cytoskeletal (CSK) fractions were prepared. Aliquots (50 µg of protein) were separated on denaturing polyacrylamide gels, blotted to nitrocellulose paper, and stained with affinity-purified anti-35H antibody at a concentration of 3 µg/ml. Similar results were obtained in two additional experiments.



PDBu-mediated changes in CSK 35H were more apparent by immunocytofluorescence than by immunoblot. In resting primary RPTE, 35H staining was concentrated in cell-cell junctions in detergent-extracted (CSK) preparations (Fig. 9). PDBu rapidly caused a decline in 35H staining concentrated at cell borders and an increase in staining in cytoplasmic dots (Fig. 9, B and C). The effect of PDBu was attenuated with prolonged PDBu treatment, which down-modulates PKC (Fig. 9D). Parallel studies with whole cell preparations indicated that the intensity and distribution of 35H staining were similar in CSK and whole cell preparations of resting cells (data not shown), consistent with the nearly quantitative recovery of 35H in the CSK fraction on immunoblots (Fig. 8). In whole cells, PDBu caused an increase in diffuse cytosolic staining and a decrease in cell border staining (data not shown) indicative of a redistribution from CSK to soluble fractions.


Figure 9: Immunocytochemical localization of 35H. Primary RPTE were grown on collagen-coated coverslips and treated with PDBu (200 nM) for the indicated times. Cells were extracted with Triton X-100, and the resulting cytoskeletal preparations were fixed and stained with affinity-purified anti-35H antibody followed by fluorescein-conjugated goat anti-rabbit antibody. PDBu treatment times were as follows: control (A), 0.2 h (B), 1.5 h (C), and 16 h (D).



The increase in soluble 35H (Fig. 8) and the decrease and reorganization of CSK 35H (Fig. 9) observed after PDBu treatment suggested that phosphorylation may regulate the distribution of 35H proteins between soluble and CSK compartments. To test the hypothesis, we immunoprecipitated 35H proteins from soluble and CSK fractions of P-labeled primary growing RPTE (Fig. 10). Basal phosphorylation levels of 35H proteins in both soluble and CSK fractions were low. PDBu stimulated phosphorylation of 80- and 90-kDa 35H proteins; these phosphoproteins were preferentially recovered in the soluble fraction. Increased phosphorylation of the coprecipitating 120-kDa protein was also limited to the soluble pool. PDBu did not stimulate phosphate incorporation into the CSK pool of these proteins. Thus, although 35H protein mass was preferentially recovered in the CSK fraction as demonstrated by immunoblots (Fig. 8), phosphorylated forms were preferentially recovered in the soluble fraction (Fig. 10). Phosphorylation of 80- and 90-kDa 35H was attenuated after 4-14 h of PDBu treatment, which correlates with the time course for PKC down-modulation in these cells(25) .


Figure 10: Subcellular localization of phosphorylated 35H. Primary RPTE were labeled with 32P(i) and treated with 200 nM PDBu for the indicated times. Soluble (SOL) and cytoskeletal (CSK) fractions were prepared and immunoprecipitated with anti-35H antiserum. Immune complexes were separated on denaturing polyacrylamide gels and autoradiographed. Similar results were obtained in two additional experiments.



To ensure proper quantitation of blots, we compared antibody recognition of native and phosphorylated 35H. 35H bacterial fusion protein was phosphorylated with purified PKC in vitro(12) . 35H antibody detected both native and phosphorylated forms with the same intensity on immunoblots (data not shown). Thus, the increase in soluble 35H proteins in response to PDBu treatment cannot be attributed to increased antibody recognition of the phosphorylated form. Furthermore, we verified that 35H proteins were efficiently immunoprecipitated from both the soluble and CSK fractions (Fig. 11). Thus, preferential recovery of phosphorylated 35H homologues in the soluble fraction cannot be attributed to more quantitative recovery of 35H proteins in this fraction. In summary, our results demonstrate that in response to PDBu, 35H proteins are phosphorylated and redistributed from CSK to soluble fractions and that the phospho-35H proteins are preferentially recovered in the soluble fraction.


Figure 11: Immunoprecipitation of soluble and cytoskeletal 35H. Soluble (SOL) and cytoskeletal (CSK) fractions were prepared from primary growing RPTE. Fractions were immunoprecipitated with preimmune serum (p.i.) or 35H antiserum. Immune complexes and proportional aliquots of starting material (total) were separated on denaturing polyacrylamide gels, transferred to nitrocellulose, and stained with affinity-purified anti-35H antibody. Similar results were obtained in one additional experiment.




DISCUSSION

We have used a PKC overlay assay to detect PKC binding proteins and demonstrated a close correlation between PKC binding proteins (detected by blot overlay) and PKC substrates (detected by in vitro and in vivo phosphorylation assays)(9, 10, 11) . We have also used the overlay assay in an interaction cloning strategy to isolate cDNAs for PKC binding proteins(12) . Many, if not all, of the expressed cDNAs are PKC substrates in vitro. In the present studies, we have focused on clone 35H to determine if proteins corresponding to the cDNAs isolated according to PKC binding activity are substrates in vivo. Antibodies prepared to 35H recognize 80- and 90-kDa PKC substrates in RPTE cells, thus providing additional evidence that PKC binding proteins are PKC substrates. Furthermore, PKC phosphorylation regulated the CSK association of 35H (and clone 45) proteins. Thus, phosphorylation has demonstrable consequences on the function of these proteins, which, by analogy to other adducins, involves the regulation of actin assembly in the subcortical CSK.

Several lines of evidence demonstrate that 35H is related to previously reported adducins. Like alpha- and beta-adducins, 35H proteins are insoluble in Triton X-100 and concentrated at cell-cell junctions, and they are PKC substrates(23, 26) . As previously reported for alpha-adducin(26) , phosphorylation of 35H proteins correlated with their redistribution from CSK to soluble fractions. Furthermore, alpha-adducin (our clone 45) co-immunoprecipitates with 35H, indicating that 35H proteins associate with alpha-adducin. Other evidence emphasizes that despite the similarity to adducins, 35H is a unique sequence. The alignment shown in Fig. 1indicates that 35H diverges significantly from alpha- and beta-adducins in discrete regions. Northern analysis demonstrates that the size and tissue distribution of 35H message are distinct from alpha- and beta-adducins. Taken together, these data demonstrate that 35H is a new member of the adducin family. We propose renaming it as -adducin. Since alpha- and beta-adducins are known to form heterodimers, the structure and organization of adducins in cells and tissues that express alpha-adducin but not beta-adducin (e.g. kidney(20) ) have been questioned. It seems likely that 35H proteins (or other as yet unidentified adducins) could fulfill the role of beta-adducin in forming heterodimers with alpha-adducin in these tissues.

Our original goal was to determine if sequences isolated according to PKC binding in vitro were substrates in vivo. Several known PKC substrates were isolated in our initial library screens for PKC binding proteins including MARCKS-related protein (clone 35A), alpha-adducin (clone 45), annexin I, and annexin II. The fact that 35H, a unique sequence isolated according to PKC binding activity, also appears to be a PKC substrate in vivo further confirms this conclusion. Additional studies are in progress to determine if PKC is directly responsible for the PDBu-stimulated 35H phosphorylation and if other kinases also participate in 35H phosphorylation. In other studies, we have determined that two other unique binding protein sequences (clones 72 and 35F) are PKC substrates in vitro and in vivo (data not shown). MARCKS, a major PKC substrate in many cells, is also a PKC binding protein(9) . Thus, there is a strong correlation between binding proteins detected in the overlay assay and PKC substrates. It should be noted that in addition to their roles as downstream targets and effectors of PKC activation, the apparent high affinity between PKC and the binding proteins also allows for the possibility that these sequences target PKCs to specific subcellular addresses in vivo, although we do not yet have direct evidence for this.

Each of the binding proteins we have tested binds phosphatidylserine (PS), and phosphorylation coordinately decreases PS and PKC binding(9, 11, 12) . Thus, PS bridging is an important component of PKC binding, and as described previously, it is also an important component for efficient trans-phosphorylation(27) . Thus, in our working model (Fig. 12), we propose that PKC and binding proteins are brought into close proximity due to their common affinity for PS. Since not all PS binding proteins are PKC binding proteins, additional protein-protein interactions appear to be required for formation of the high affinity ternary complex(28) . The model is drawn to indicate contact sites with the catalytic domain since the binding proteins are also substrates. PKC interactions with PS have been mapped to the regulatory domain, whereas MARCKS interactions with PS are due to electrostatic interactions with the high positive charge density domain containing the PKC phosphorylation site(8, 29, 30) .


Figure 12: Phosphorylation regulates ternary complex formation among PKCs, binding proteins, and phospholipid surfaces. PKC binding to substrates is dependent on the interactions of both PKC and the substrate with an anionic phospholipid surface such as PS (solid ribbon). PKC interactions with PS are mediated through PS binding sequences within the regulatory (Reg) domain, whereas substrate interactions with PS are mediated through electrostatic interactions with high positive charge density sequences (+++). The model is drawn to indicate that the substrates also interact with the catalytic (Cat) domain of PKC (in order for phosphorylation to occur). Phosphorylation coordinately attenuates the interaction between the substrate and both PS and PKC. In the case of MARCKS and 35H, decreased PS binding in vitro correlates with redistribution of the phosphorylated proteins from particulate to soluble fractions in vivo.



In addition to regulating PKC binding and phosphorylation, PS binding also regulates the association of MARCKS with cellular membranes(29, 31) . In MARCKS and 35H(^2), phosphorylated serine residues are located within high positive charge density domains that support electrostatic interactions with the negatively charged lipid surface. Thus, phosphorylation results in a coordinate loss of both PKC and PS binding. Dissociation of PKC from the binding protein represents a means for regulating the association of PKC with its binding proteins/substrates (Fig. 12). Loss of PS binding correlates with redistribution of binding proteins (such as MARCKS and adducins) from particulate to soluble fractions. This redistribution may be the means by which PKC alters the functions of the CSK-associated proteins and exerts the profound changes in cell shape elicited by phorbol ester treatment.


FOOTNOTES

*
This work was supported by NIH Grants ES05670 (to J. L. S. and S. J.), CA53841 and GM50152 (to S. J.), Council for Tobacco Research Grant 2375A (to S. J.), and American Cancer Society Grant CN-105A (to S. J.). Portions of this work were submitted in partial fulfillment of requirements for the Ph.D. degree awarded to L. D. from Clarkson University (Potsdam, NY). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The nucleotide sequence(s) reported in this paper has been submitted to the GenBank(TM)/EMBL Data Bank with accession number(s) U35775[GenBank].

§
To whom correspondence should be addressed: W. Alton Jones Cell Science Center, Inc., 10 Old Barn Rd., Lake Placid, NY 12946-1099. Tel.: 518-523-1260; Fax: 518-523-1849.

(^1)
Abbreviations used are: PKC, protein kinase C; CSK, cytoskeleton or cytoskeletal; MARCKS, myristoylated alanine-rich protein kinase C substrate; MSB, microtubule stabilization buffer; PDBu, phorbol 12,13-dibutyrate; RPTE, renal proximal tubule epithelial cells; PIPES, 1,4-piperazinediethanesulfonic acid; kb, kilobase pair(s); PS, phosphatidylserine.

(^2)
C. Chapline, personal communication.


REFERENCES

  1. Stabel, S. (1994) Semin. Cancer Biol. 5, 277-284 [Medline] [Order article via Infotrieve]
  2. Chakravarthy, B. R., Whitfield, J. F., and Durkin, J. P. (1994) Biochem. J. 304, 809-816 [Medline] [Order article via Infotrieve]
  3. Grabarek, J., and Ware, J. A. (1993) J. Biol. Chem. 268, 5543-5549 [Abstract/Free Full Text]
  4. Diaz-Guerra, M. J. M., and Bosca, L. (1990) Biochem. J. 269, 163-168 [Medline] [Order article via Infotrieve]
  5. Trilivas, I., McDonough, P. M., and Brown, J. H. (1991) J. Biol. Chem. 266, 8431-8438 [Abstract/Free Full Text]
  6. Wolf, M., and Baggiolini, M. (1988) Biochem. Biophys. Res. Commun. 154, 1273-1279 [Medline] [Order article via Infotrieve]
  7. Kiley, S. C., Parker, P. J., Fabbro, D., and Jaken, S. (1992) Carcinogenesis 13, 1997-2001 [Abstract]
  8. Aderem, A. (1992) Cell 71, 713-716 [Medline] [Order article via Infotrieve]
  9. Hyatt, S. L., Liao, L., Aderem, A., Nairn, A., and Jaken, S. (1994) Cell Growth & Differ. 5, 495-502
  10. Hyatt, S. L., Liao, L., Chapline, C., and Jaken, S. (1994) Biochemistry 33, 1223-1228 [Medline] [Order article via Infotrieve]
  11. Liao, L., Hyatt, S. L., Chapline, C., and Jaken, S. (1994) Biochemistry 33, 1229-1233 [Medline] [Order article via Infotrieve]
  12. Chapline, C., Ramsay, K., Klauck, T., and Jaken, S. (1993) J. Biol. Chem. 268, 6858-6861 [Abstract/Free Full Text]
  13. Wallin, A., Zhang, G., Jones, T. W., Jaken, S., and Stevens, J. L. (1992) Lab. Invest. 66, 474-484 [Medline] [Order article via Infotrieve]
  14. Zhang, G., Ichimura, T., Wallin, A., Kan, M., and Stevens, J. L. (1991) J. Cell. Physiol. 148, 295-305 [Medline] [Order article via Infotrieve]
  15. Bradford, M. M. (1976) Anal. Biochem. 72, 248-254 [CrossRef][Medline] [Order article via Infotrieve]
  16. Osborn, M., and Weber, K. (1982) Methods Cell Biol. 24, 97-132 [Medline] [Order article via Infotrieve]
  17. Laemmli, U. K. (1970) Nature 227, 680-685 [Medline] [Order article via Infotrieve]
  18. Jaken, S., Leach, K., and Klauck, T. (1989) J. Cell Biol. 109, 697-704 [Abstract]
  19. Tripodi, G., Piscone, A., Borsani, G., Tisminetzky, S., Salardi, S., Sidoli, A., James, P., Pongor, S., Bianchi, S., and Baralle, F. E. (1991) Biochem. Biophys. Res. Commun. 177, 939-947 [Medline] [Order article via Infotrieve]
  20. Joshi, R., Gilligan, D. M., Otto, E., McLaughlin, T., and Bennett, V. (1991) J. Cell Biol. 115, 665-675 [Abstract]
  21. Scaramuzzino, D. A., and Morrow, J. S. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 3398-3402 [Abstract]
  22. Bianchi, G., Tripodi, G., Casari, G., Salardi, S., Barber, B. R., Garcia, R., Leoni, P., Torielli, L., Cusi, D., Ferrandi, M., Pinna, L. A., and Ferrari, P. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 3999-4003 [Abstract]
  23. Waseem, A., and Palfrey, H. C. (1990) J. Cell Sci. 96, 93-98 [Abstract]
  24. Dong, L., Stevens, J. L., Fabbro, D., and Jaken, S. (1994) Cell Growth & Differ. 5, 881-890
  25. Claesson-Welsh, L. (1994) J. Biol. Chem. 269, 32023-32026 [Free Full Text]
  26. Kaiser, H. W., O'Keefe, E., and Bennett, V. (1989) J. Cell Biol. 109, 557-569 [Abstract]
  27. Bazzi, M. D., and Nelsestuen, G. L. (1987) Biochemistry 26, 1974-1982 [Medline] [Order article via Infotrieve]
  28. Hinrichsen, R. D., and Blackshear, P. J. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 1585-1589 [Abstract]
  29. Kim, J., Shishido, T., Jiang, S., Aderem, A., and McLaughlin, S. (1994) J. Biol. Chem. 269, 28214-28219 [Abstract/Free Full Text]
  30. Gnegy, M. E. (1993) Annu. Rev. Pharmacol. Toxicol. 33, 45-70 [CrossRef][Medline] [Order article via Infotrieve]
  31. Taniguchi, H., and Manenti, S. (1993) J. Biol. Chem. 268, 9960-9963 [Abstract/Free Full Text]

©1995 by The American Society for Biochemistry and Molecular Biology, Inc.