©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Drosophila Neurocalcin, a Fatty Acylated, Ca-binding Protein that Associates with Membranes and Inhibits in Vitro Phosphorylation of Bovine Rhodopsin (*)

(Received for publication, December 8, 1995; and in revised form, February 9, 1996)

Eva Faurobert Ching-Kang Chen James B. Hurley (§) David Heng-Fai Teng (¶)

From the Howard Hughes Medical Institute and the Department of Biochemistry, University of Washington, Box 357370, Seattle, Washington 98195

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

Neurocalcins belong to a family of neuronal specific EF hand Ca-binding proteins defined by recoverin. Previously, we reported the cloning and initial characterization of neurocalcin in Drosophila melanogaster (Teng, D. H.-F., Chen, C.-K., and Hurley, J. B.(1994) J. Biol. Chem. 269, 31900-31907). We showed that the Drosophila neurocalcin protein (DrosNCa) is expressed in neurons and that bacterially expressed recombinant DrosNCa (rDrosNCa) can be myristoylated. Here, we present two lines of evidence that DrosNCa is fatty acylated in vivo. First, the mobility of affinity-purified native DrosNCa on two-dimensional gel electrophoresis is identical to that of myristoylated rDrosNCa and distinct from that of nonacylated rDrosNCa. Second, the membrane binding properties of native DrosNCa are similar to those of myristoylated rDrosNCa; both of these proteins bind to membranes at 0.2 mM Ca, whereas nonacylated rDrosNCa always remains soluble. It has been shown that recoverin inhibits the phosphorylation of rhodopsin when Ca is present (Kawamura et al., 1993) and that a dependent recoverin/rhodopsin kinase interaction underlies the inhibitory effect of recoverin (Chen et al., 1995). Given the similarities between recoverin and neurocalcin, we examined the effect of DrosNCa on rhodopsin phosphorylation. We find that rDrosNCa is capable of inhibiting bovine rhodopsin phosphorylation in vitro in a Ca-dependent manner. The inhibitory activity of rDrosNCa is enhanced by myristoylation, and the potency of its effect is similar to that of recoverin. Two other related EF hand proteins, guanylate cyclase-activating protein-2 and calmodulin, are only poor inhibitors in these phosphorylation assays. in vitro inhibition of rhodopsin phosphorylation therefore appears to be an assayable property of a subset of recoverin-like proteins.


INTRODUCTION

Neurons are highly specialized cells that have evolved elaborate mechanisms to sense, integrate, and transmit signals. The calcium ion (Ca) is a universal second messenger that is a key player in neuronal signaling. Dynamic fluxes in the intracellular concentration of Ca during neuronal excitation, recovery, and adaptation or potentiation, are interpreted by Ca-binding proteins that act as transducers; the binding or release of Ca causes these proteins to switch into an ``on'' or ``off '' state in the regulation of effector activity.

Many Ca-sensing transducers are members of the EF hand superfamily of Ca-binding proteins (Moncrief et al., 1990), one of the best characterized being calmodulin. In the past few years, a new and rapidly expanding EF hand subfamily has been defined by recoverin and its cognates (Dizhoor et al., 1991; Hurley et al., 1993). Electrophysiological analyses on mammalian recoverin and frog S-modulin reveal that these photoreceptor proteins prolong photoexcitation in high free Ca concentrations (Gray-Keller et al., 1993; Kawamura, 1993). Accumulated biochemical evidence suggests that recoverin/S-modulin delays photorecovery by preventing rhodopsin kinase from phosphorylating rhodopsin in high Ca conditions (Kawamura et al., 1993; Chen et al., 1995; Klenchin et al., 1995). Indeed, Chen and co-workers(1995) have recently found that recoverin directly binds to rhodopsin kinase at high Ca levels. Recoverin is heterogeneously fatty acylated on its amino terminus (Dizhoor et al., 1992), and this posttranslational modification enhances the association of recoverin with membranes in high Ca conditions (Dizhoor et al., 1993). However, the presence of a fatty acyl moiety on recoverin is not necessary for its inhibition of rhodopsin kinase (Chen et al., 1995). Flaherty et al.(1993) have shown that the crystallographic structure of recoverin, with Ca bound in its EF3 site, is compact and that the protein is composed of two domains, each having one functional EF hand. The three-dimensional structure of recoverin also reveals the presence of a hydrophobic crevice composed of aromatic and aliphatic amino acid residues distributed in the N-terminal half of the protein that may be involved in interactions with a target factor(s). Interestingly, Polans et al.(1991) have found that recoverin is an antigen in the autoimmune response of people inflicted with cancer-associated retinopathy, but its role in this degenerative disease is unclear.

Numerous vertebrate cognates of recoverin have been identified including visinin (Yamagata et al., 1990), multiple isoforms of neurocalcin (Hidaka and Okazaki, 1993; Terasawa et al., 1992), hippocalcin (Kobayashi et al., 1992), and neuronal visinin-related proteins like Vilip (Lenz et al., 1992) and NVPs (Kajimoto et al., 1993). Protein sequence comparisons indicate that recoverin, S-modulin, and visinin define a distinct subclass that is expressed in photoreceptor cells. Another subclass of these neuronally expressed Ca-binding proteins is comprised of bovine neurocalcin, rat hippocalcin, rat NVPs, and chicken Vilip. The evolutionary diversity of these EF hand recoverin-like proteins is further exemplified by the recent discoveries of yet another subclass defined by GCAP-1 (Palczewski et al., 1994) and GCAP-2 (Dizhoor et al., 1995), two mammalian photoreceptor proteins that activate membrane guanylate cyclase when the free Ca levels are low.

Two invertebrate homologues of recoverin have been reported to date: Drosophila frequenin and neurocalcin. Pongs et al.(1994) identified frequenin from studies on the Shaker-like V7 mutants of D. melanogaster. They proposed that the overexpression of frequenin in V7 mutants causes the augmented facilitation of neurotransmitter release at neuromuscular junctions. In addition, Pongs et al. reported that recombinant frequenin is capable of activating bovine rod outer segment membrane guanylate cyclase in a Ca-dependent manner in vitro, but the in vivo target of frequenin has not been established. In a search for homologues of recoverin in D. melanogaster, we discovered Drosophila neurocalcin (nca), a gene coding for a protein that is 88% identical to the bovine neurocalcin isoform on the primary sequence level (Teng et al., 1994). Initial characterization revealed that the Drosophila neurocalcin protein (DrosNCa) is expressed in neurons and that bacterially expressed recombinant DrosNCa could be myristoylated by N-acyl transferase. Here, we present evidences that native DrosNCa is fatty acylated in vivo and that this modification significantly enhances its Ca-dependent association with Drosophila membranes. In addition, we have found that at high Ca concentrations in reconstituted assays, both recombinant myristoylated and nonacylated DrosNCa are capable of inhibiting the phosphorylation of bovine rhodopsin by rhodopsin kinase, but the recombinant DrosNCa proteins neither stimulate nor inhibit mammalian photoreceptor membrane guanylate cyclase in high or low Ca conditions.


EXPERIMENTAL PROCEDURES

Materials

Phenyl-Sepharose CL-4B and CNBr-Sepharose were purchased from Pharmacia Biotech Inc. Protein quantitation reagent, ampholytes, and two-dimensional gel protein standards were obtained from Bio-Rad. [-P]ATP (3000 Ci/mmol) was purchased from DuPont NEN. ECL detection kit for Western analyses was procured from Amersham Corp. Myristoylated recombinant GCAP-2 was kindly provided by R. Hughes and A. Dizhoor.

Methods

Native gel electrophoresis and Western analyses were performed as described by Teng et al.(1994). Two-dimensional gel electrophoresis was done according to the protocols of Bio-Rad. Anti-rDrosNCa rabbit antibodies 6094 and 6515 were generated and affinity-purified as described previously (Teng et al., 1994).

Purification of Recombinant Recoverin and Neurocalcin

Myristoylated and nonacylated recombinant bovine recoverin (rBovRv) (^1)and recombinant DrosNCa (rDrosNCa) were produced in Escherichia coli as described by Ray et al.(1992). rDrosNCa and rBovRv were isolated as described previously (Teng et al., 1994) with the following modification: proteins that were bound to phenyl-Sepharose CL-4B matrix in buffer containing 1 mM CaCl(2) were eluted with 10 mM Tris-HCl (pH 8.0), 1 mM MgCl(2), 1 mM DTT, 5 mM EGTA, and 0.2 mM PMSF. Protein concentrations were quantified by using a Bio-Rad protein assay and by densitometry of SDS-polyacrylamide gels stained with Coomassie Blue.

Isolation of Native DrosNCa

Native neurocalcin was purified from Canton-S Drosophila adult heads using an AP6515 antibody affinity column. Fly heads were homogenized at 200 mg of tissue/ml in 50 mM Tris (pH 7.5), 2 mM MgCl(2), 2 mM EGTA, 0.5 mM PMSF, 5 µg/ml aprotinin, and 5 µg/ml leupeptin. The homogenate was centrifuged at 1000 times g at 4 °C for 10 min. The supernatant was loaded onto an AP6515 column preequilibrated with TCMN buffer (50 mM Tris (pH7.5), 0.1 mM CaCl(2), 2 mM MgCl(2), 0.1 M NaCl, 0.2 mM PMSF). The column was washed with more than 20 volumes of TCMN, followed by 3 volumes of TCMN plus 0.5 M NaCl and a final wash of 3 volumes of TCMN. Proteins bound to the column were eluted with 2-3 volumes of 0.1 M glycine (pH 2.4) and immediately neutralized. The eluted proteins were examined on SDS-polyacrylamide gels and on immunoblots.

Fluorescence Emission Spectra

All fluorescence measurements were performed at 25 °C on an SLM 8000C spectrofluorimeter (SLM Aminco, Urbana, IL) using a 1 times 1-cm quartz cuvette containing 1.5 ml of sample extensively mixed. The excitation wavelength was set at 292 nm, and the emission spectrum was recorded from 300 to 410 nm with an emission scan speed of 1 nm/s. The bandwidths were 8 nm for both excitation and emission. The emission spectrum of 1 µM protein in 50 mM MOPS (pH 7.0), 50 mM KCl, and 1 mM HEDTA was recorded. CaCl(2) was then added to the sample to a free Ca concentration of 100 µM, and a second emission spectrum was recorded. Background fluorescence of the buffer in the absence of protein was subtracted from all of the spectra.

Ca-dependent Membrane Association

Native DrosNCa

Wild type Canton-S adult Drosophila heads were homogenized at 100 mg/ml in 10 mM NaCl, 25 mM Tris (pH 7.5), 2 mM MgCl(2), 0.2 mM PMSF, 5 mM beta-ME, 5 µg/ml aprotinin, and 5 µg/ml leupeptin containing either 2 mM EGTA or 0.2 mM CaCl(2). Each homogenate was placed on ice for 10 min and then spun at 100,000 times g for 30 min, 4 °C. The resulting supernatant and pellet fractions were analyzed on immunoblot probed with AP6094 antibodies.

Recombinant DrosNCa

Crude membranes were prepared from Canton-S Drosophila adult heads according to the method of Kobayashi et al.(1993). 200 ng of myr-rDrosNCa or non-rDrosNCa was reconstituted with 25 µl of membranes at 10 mg of protein/ml in membrane binding buffer (MBB; 25 mM Tris (pH 7.5), 0.1 M KCl, 2 mM MgCl(2), 0.2 mM PMSF, 5 mM beta-ME, 5 µg/ml aprotinin, 5 µg/ml leupeptin) containing either 1 mM EGTA or 0.2 mM CaCl(2). The suspensions were incubated at 37 °C for 30 min and spun at 100,000 times g for 30 min, 4 °C. The supernatant and particulate fractions were analyzed as described above for native DrosNCa.

Purification of Recombinant Bovine Rhodopsin Kinase

Rhodopsin kinase (RK) was affinity-purified from Sf9 cell extracts as described in Chen et al.(1995) with modifications. The RK eluate was dialyzed against Tris-HCl 20 mM (pH 7.5), 5 mM MgCl(2). The purified enzyme was examined by SDS-PAGE and estimated to be more than 90% pure. The concentration of the protein was determined by the Bio-Rad protein assay.

Rhodopsin Phosphorylation

Urea-washed rod outer segment membranes were prepared as described in Chen et al.(1995). The phosphorylation assay was performed according to the procedures of Chen et al.(1995) with some modifications. Purified recombinant RK and urea-washed membranes were mixed in 20 mM Tris-HCl (pH 7.5) under infrared illumination and kept on ice. Thirty seconds before a light flash that bleached 0.05% of rhodopsin, 5 µl of the RK-rod outer segment suspension was added to 5 µl of TCMN buffer containing [-P]ATP (800 dpm/pmol) and rDrosNCa or rBovRv. The final concentrations of rhodopsin, RK, and ATP were 20 µM, 200 nM, and 500 µM, respectively. The reaction was incubated for 60 min in the dark at room temperature and stopped by adding an equal volume of SDS-PAGE sample buffer. Reactions unexposed to light were used as dark controls. Each reaction was fractionated on a 12% polyacrylamide gel and autoradiographed. Rhodopsin bands were excised and counted. To quantify light-dependent phosphorylation, dark controls were substracted from the test samples.


RESULTS

Myristoylated and Nonacylated Recombinant Drosophila Neurocalcin

To investigate and compare the biochemical properties of the fatty acylated and unmodified forms of DrosNCa, milligram quantities of myr-rDrosNCa and non-rDrosNCa were expressed in E. coli and subsequently purified. The masses of myr-rDrosNCa and non-rDrosNCa were 21,975.51 and 21,764.17 Da, respectively, as determined by electrospray mass spectrometry, and are consistent with the calculated masses of acylated and unmodified polypeptide products of the nca gene. The isolated proteins were examined by native and SDS-polyacrylamide gel electrophoresis. Under native conditions (Fig. 1A), the Ca-free (EGTA) forms of the two proteins migrated faster than their Ca-bound forms, and myr-rDrosNCa (m) migrated further than non-rDrosNCa (n). As shown in Fig. 1B, in denaturing SDS-PAGE conditions with the addition of beta-ME, both proteins resolved as single bands that migrated more slowly in the absence of Ca than in its presence, and myr-rDrosNCa was slightly faster than non-rDrosNCa.


Figure 1: Analyses of myristoylated and nonacylated rDrosNCa by gel electrophoresis. A, native gel analysis. 2.5 µg of purified non-rDrosNCa (n) or myr-rDrosNCa (m), in the presence of 20 mM beta-mercaptoethanol and either 3 mM EGTA or 1 mM CaCl(2), was resolved on a 10% polyacrylamide gel. B, SDS-polyacrylamide gel electrophoresis in reducing conditions. 1.5 µg of non-rDrosNCa or myr-rDrosNCa, boiled in SDS sample buffer containing 200 mM beta-ME and either 3 mM EGTA or 1 mM CaCl(2), was resolved on a 15% SDS-polyacrylamide gel. Molecular weight (MW) standards are shown, and their corresponding sizes are indicated in kDa. C, SDS-PAGE in nonreducing conditions. 25 µg of recombinant protein was analyzed as described in B using SDS sample buffer without beta-ME. All of the protein bands were visualized by staining with Coomassie. Using liquid chromatography-coupled electrospray mass spectrometry, the extent of myristoylation of the purified recombinant protein preparations was determined to be greater than 90%.



When myr-rDrosNCa and non-rDrosNCa were subjected to SDS-PAGE without beta-mercaptoethanol, the formation of dimers was detected (Fig. 1C). Under these nonreducing conditions, multiple forms of monomeric (arrows) and dimeric (arrowhead) DrosNCa were observed, and their mobilities differed from those of the beta-ME-treated proteins (Fig. 1B). Considering that three cysteine residues are present in DrosNCa, these results suggest that rDrosNCa can form intra- and/or intermolecular disulfide bonds. Curiously, the distribution of the monomeric and dimeric species for myr- and non-rDrosNCa were different, suggesting that lipid modification could influence the formation of the disulfide linkages.

Tryptophan Fluorescence

DrosNCa, like bovine neurocalcin, has two tryptophan residues located at positions 30 and 103 in EF1 and EF3, respectively (Teng et al., 1994); these two tryptophans are conserved throughout the recoverin family. The fluorescence change of myr-rDrosNCa upon binding Ca is very similar to the change observed for myristoylated recombinant bovine neurocalcin (Ladant, 1995). Compared with the Ca free form (HEDTA), the maximum fluorescence intensity of myr-rDrosNCa in 0.1 mM free Ca was approximately 2-fold higher, but the emission maximum of 335 nm was not significantly different (Fig. 2A). This change in the amplitude of the signal was reversible and appeared to be Ca-specific because MgCl(2) did not induce any variation in the fluorescence spectrum of the protein (data not shown). The fluorescence of myr-rDrosNCa in its Ca-bound form was similar that of non-rDrosNCa. However, unlike myr-rDrosNCa, non-rDrosNCa did not show a substantial increase in fluorescence upon Ca binding (Fig. 2B), even when up to 1 mM free Ca was added (data not shown). In contrast, nonacylated bovine neurocalcin has been reported to undergo a 1.5-fold increase of its fluorescence when it binds Ca (Ladant, 1995). From these data, we infer that the Ca-induced variation of the fluorescence of myr-rDrosNCa is mainly due to a change in the position of its myristoyl group, which influences the environment of one or more of its tryptophan residues.


Figure 2: Tryptophan fluorescence. Fluorescence emission spectra of 1 µM of myr-rDrosNCa (A) and non-rDrosNCa (B), excited at 292 nm in buffers containing either 1 mM HEDTA (solid line) or 0.1 mM CaCl(2) (dashed line), are shown.



Native Drosophila Neurocalcin

We have previously shown that recombinant DrosNCa can be myristoylated by N-myristoyl transferase (Teng et al., 1994). Since lipid modification has yet not been demonstrated to occur on Drosophila proteins, we wondered if native DrosNCa was acylated. To address this issue, we purified the protein from wild type Canton-S Drosophila adult head extracts by affinity chromatography using a column of affinity-purified AP6515 anti-rDrosNCa antibodies. Fig. 3A shows a sample of the fly head extract (lane 2) that was loaded onto the antibody column and the proteins recovered in the low pH elution (lane 3). A band was detected in the eluted fraction that migrated with an apparent mass of 22 kDa, the expected size for DrosNCa. To ascertain that the eluted 22-kDa band was native DrosNCa, we performed Western blot analyses using AP6094, a different affinity-purified anti-rDrosNCa antibody. Fig. 3B shows that the 22-kDa protein was recognized by AP6094 (lane 3) but not detected by the mouse anti-rabbit secondary antibodies alone (data not shown) and that it was depleted from the flow-through fraction after passage over the AP6515-Sepharose column (lane 2).


Figure 3: Purification of native Drosophila neurocalcin. A, native DrosNCa was purified from a soluble extract of Canton-S adult heads by affinity chromatography using an AP6515 anti-DrosNCa antibody column. Fractions obtained from this purification scheme were subjected to SDS-PAGE on a 15% gel that was stained with Coomassie Blue. Lane 1, molecular mass standards (sizes indicated are in kDa); lane 2, 40 µg of protein from the Canton-S adult head extract; lane 3, approximately 1 µg of protein recovered in the low pH elution. B, Western blot. The following fractions were separated on a 15% SDS-polyacrylamide gel, transferred onto nitrocellulose, and probed with 0.2 nM AP6094. Lane 1, 40 µg of protein from the soluble Canton-S head extract; lane 2, 40 µg of protein from the flow-through fraction of the AP6515 column; lane 3, 4 µl of the low pH eluate. Based on densitometric scans and comparison to signals of rDrosNCa standards, it was estimated that there was originally 12.5 µg of DrosNCa in the 38 mg of protein in the Drosophila head extract, and approximately 1.7 µg of DrosNCa was recovered in the low pH elution. This corresponds to a yield of 14% from the antibody column.



Two-dimensional gel electrophoresis was performed to determine if native DrosNCa behaved like myr-rDrosNCa or non-rDrosNCa. As shown in Fig. 4A, myr-rDrosNCa resolved at a more acidic pH relative to non-rDrosNCa in the IEF dimension, and myr-rDrosNCa migrated slightly faster than non-rDrosNCa in the SDS-PAGE dimension as previously observed in Fig. 1. We found that in IEF gels having different gradients of ampholytes, myr-rDrosNCa consistently resolved at a more acidic pH relative to the 5.2 pI, 45-kDa standard (arrow), whereas non-rDrosNCa settled at a more basic pH. This result is consistent with the fact that a fatty acyl modification on DrosNCa results in the loss of one positive charge in the alpha-amine group of the N-terminal glycine residue. The apparent pI values of both rDrosNCa proteins are close to the calculated pI of 5.1 for the deduced nca polypeptide product.


Figure 4: Two-dimensional gel electrophoresis. A, a mixture of 1.5 µg of non-rDrosNCa (n), 1.5 µg of myr-rDrosNCa (m), and 8 µg of two-dimensional molecular mass standards was first resolved in an IEF gel and then separated on a 15% SDS-polyacrylamide gel; the proteins were stained with Coomassie Blue. B, two-dimensional Western blot of 40 µg of total protein from a soluble fraction of Canton-S adult heads homogenized in 0.5% SDS and 5 mM EGTA. C, two-dimensional immunoblot of a mixture of 5 ng of non-rDrosNCa, 5 ng of purified native DrosNCa, and 8 µg of two-dimensional molecular mass standards. D, a mixture of 5 ng of myr-rDrosNCa, 5 ng or purified native DrosNCa and 8 µg of two-dimensional standards. The blots shown in B-D were initially stained with Ponceau-S to visualize the proteins, and subsequently probed with AP6094 primary antibody and a goat anti-rabbit HRP-conjugated secondary antibody and detected by using chemiluminescence. All of the two-dimensional gels were resolved in the presence of 2.5 mM EGTA.



Previously, we had reported that AP6094 weakly cross-reacted to rat hippocalcin. This observation raised the possibility that these antibodies would detect homologues or different isoforms of DrosNCa in fly preparations. We therefore performed Western analysis on proteins extracted from Drosophila adult heads that had been separated on a two-dimensional gel. As shown in Fig. 4B, only one spot was recognized by AP6094 in the immunoblot. Under these two-dimensional gel conditions, rat hippocalcin was clearly separated from myr-rDrosNCa and non-rDrosNCa (data not shown). Thus, these data suggest that AP6094 specifically recognizes a single antigen in Drosophila adult heads, that being native DrosNCa.

To ascertain if the gel mobility of purified native DrosNCa was similar to either myr-rDrosNCa or non-rDrosNCa, mixtures of equivalent quantities of native and recombinant DrosNCa were separated on two-dimensional gels, transblotted, and probed with AP6094. Whereas non-rDrosNCa and the native protein resolved as two distinct spots (Fig. 4C), the immunoblot signal for myr-rDrosNCa and the native protein comigrated (Fig. 4D). From these results, we infer that DrosNCa is fatty acylated in vivo.

Ca-dependent Translocation of DrosNCa

Studies on recoverin (Dizhoor et al., 1993), hippocalcin (Kobayashi et al., 1993), and bovine neurocalcin (Ladant, 1995) have shown that the fatty acylated forms of these two proteins bind to membranes in high Ca concentrations. To determine if native DrosNCa undergoes Ca-dependent translocation, Canton-S adult heads were homogenized in 10 mM NaCl, Tris buffer with either 1 mM CaCl(2) or 2 mM EGTA and partitioned by centrifugation, and the resulting pellet and supernatant fractions were analyzed on immunoblots using AP6094 (Fig. 5A). In the presence of Ca, almost all of DrosNCa was found in the pellet, whereas 70% of the protein was present in the soluble fraction in the presence of EGTA. When a similar experiment was done using 100 mM NaCl, Tris buffer with EGTA, only 40% of DrosNCa was found in the supernatant (data not shown). The data reveal that native DrosNCa binds to membranes and/or cytoskeleton when the levels of free Ca are high and that its affinity for membranes increases with the ionic strength of its solvent environment. The translocation properties of DrosNCa are therefore similar to those of recoverin, hippocalcin, and bovine neurocalcin .


Figure 5: Ca-dependent translocation of DrosNCa. A, subcellular fractionation of native DrosNCa. Wild type Drosophila Canton-S heads were homogenized in 25 mM Tris (pH 7.5), 10 mM NaCl, 2 mM MgCl(2), 5 mM beta-ME, 0.2 mM PMSF containing either 2.5 mM EGTA or 0.2 mM CaCl(2). The homogenates were centrifuged, and the resulting pellet (P) and supernatant (S) fractions were analyzed on immunoblots using AP6094 anti-DrosNCa antibodies. Densitometric scans indicated that 70% of DrosNCa was present in the supernatant fraction of the EGTA sample. B, membrane association of myr- or non-rDrosNCa. Two hundred nanograms of recombinant protein was reconstituted with washed Canton-S head membranes in membrane binding buffer solution containing either 2 mM EGTA or 0.2 mM CaCl(2) and centrifuged, and the pellet (P) and supernatant (S) fractions were examined by Western analyses using AP6094 antibodies. As a control, 200 ng of myr-rDrosNCa in solution containing 0.2 mM CaCl2 without Drosophila head membranes remained soluble under these conditions (myr-control). To ensure that the immunoblot signals observed in the samples were solely from recombinant DrosNCa, the absence of detectable native DrosNCa in the washed Canton-S head membranes (M) was ascertained.



The involvement of the fatty acyl moiety of DrosNCa in translocation was investigated by comparing the membrane binding abilities of myr-rDrosNCa and non-rDrosNCa. Briefly, recombinant protein was reconstituted with washed Drosophila head membranes and centrifuged. The resulting pellet and supernatant fractions were examined by Western analysis (Fig. 5B). In the presence of 0.2 mM CaCl(2), most of the myr-rDrosNCa was located in the pellet, whereas it was almost completely soluble in the presence of EGTA. In contrast, non-rDrosNCa was always found in the supernatant in the presence or absence of Ca. These results show that the association of recombinant DrosNCa to the particulate fraction is dependent on its fatty acyl modification.

Ca-dependent Inhibition of Bovine Rhodopsin Phosphorylation

It has been shown that recoverin inhibits the in vitro phosphorylation of rhodopsin by rhodopsin kinase (Kawamura et al., 1993; Chen et al., 1995; Klenchin et al., 1995) and that recoverin directly interacts with rhodopsin kinase in a Ca-dependent manner (Chen et al., 1995). Since the primary sequences of DrosNCa and BovRv are 54% identical and the two proteins have similar Ca-dependent membrane binding properties, we examined if DrosNCa can affect rhodopsin phosphorylation in vitro. Urea-washed bovine rod outer segment membranes were reconstituted with purified recombinant bovine rhodopsin kinase in the presence or absence of myr- or non-rDrosNCa, and light-dependent rhodopsin phosphorylation was analyzed. When 5 µM of non- or myr-rDrosNCa were added in the assays, an inhibition of rhodopsin phosphorylation was observed in 0.1 mM Ca but not in the presence of 1 mM EGTA (Fig. 6A); 65 and 85% inhibitions were observed for nonacylated and myristoylated proteins, respectively, at 0.1 mM Ca. To analyze the potency of the Ca-dependent inhibition of rhodopsin phosphorylation by DrosNCa, we compared the activity of non- and myr-rDrosNCa to those of non- and myr-rBovRv. Increasing concentrations of the recombinant myristoylated or nonacylated forms of DrosNCa or BovRv were added to reactions in the presence of 0.1 mM Ca, and the percentage of inhibition of rhodopsin phosphorylation was determined. Surprisingly, DrosNCa showed inhibitory effect similar to that of BovRv. The plots of both myristoylated (closed squares) and nonacylated (open squares) DrosNCa were basically superimposed with those of myristoylated (closed circles) and nonacylated (open circles) BovRv, respectively (Fig. 6B). The EC values were approximately 0.8 µM for the myristoylated proteins and 4 µM for the nonacylated proteins. We wanted to determine if the inhibition of rhodopsin phosphorylation was an activity exhibited by other Ca-binding proteins related to recoverin and neurocalcin. We therefore examined the inhibitory activities of two other EF hand proteins: myristoylated recombinant GCAP-2, which has 29 and 38% identities with recoverin and neurocalcin, respectively; and calmodulin, which has 19 and 22% identities with recoverin and neurocalcin, respectively. In our reconstituted assays, both myr-rGCAP-2 and calmodulin displayed only weak inhibition of rhodopsin phosphorylation (Fig. 6B).


Figure 6: Ca-dependent inhibition of the phosphorylation of bovine rhodopsin. Phosphorylation assays were performed as described under ``Experimental Procedures.'' The final concentrations of ATP, recombinant bovine RK, and urea-stripped bovine rod outer segment membranes in the reactions were 500 µM, 200 nM, and 20 µM, respectively. The reaction contents were separated on a 12% polyacrylamide gel and autoradiographed, and the rhodopsin bands were cut and counted. Light-dependent phosphorylation was determined by substraction of the -light control to the +light sample. For normalization, the total number of phosphates incorporated into rhodopsin in the RK control (-rDrosNCa) was taken to be 100%, and rhodopsin phosphorylation in the presence of the test proteins was calculated relative to the control. A, autoradiograph showing the Ca-dependent inhibition of bovine rhodopsin phosphorylation by non- and myr-rDrosNCa. The phosphorylation reactions were performed in the presence of 1 mM EGTA (EGTA) or 0.1 mM CaCl(2) (Ca) with or without 5 µM of non- or myr-rDrosNCa. The RK band corresponds to autophosphorylated RK. B, the effect of increasing the concentration of myristoylated (closed shapes) and nonacylated (open shapes) rDrosNCa (squares) or rBovRv (circles) on rhodopsin phosphorylation. Calmodulin (open diamonds) and myristoylated recombinant GCAP-2 (closed triangles) were used as controls. The final concentration of Ca in these reactions was 0.1 mM. The data are the mean of at least three independent determinations, and error bars represent the standard deviation.




DISCUSSION

In this paper, we present two lines of evidence indicating that Drosophila neurocalcin is a Ca-binding protein that is fatty acylated in vivo. First, on two-dimensional gels, native DrosNCa comigrates with myristoylated rDrosNCa and is distinctly separated from nonacylated rDrosNCa. Second, the membrane binding properties of native DrosNCa are similar to those of myr-rDrosNCa; both proteins bind to membranes in high Ca conditions and become more soluble when free Ca levels decrease. This study therefore provides the first evidence of the existence of protein acylation in Drosophila. Definitive elucidation of the type of lipid modification(s) on DrosNCa in vivo will have to be obtained by mass spectrometry analyses.

The Ca-dependent membrane association ability of rDrosNCa is greatly enhanced by fatty acylation. It is likely that DrosNCa translocation occurs by the Ca-myristoyl switch mechanism that has been proposed for recoverin (Zozulya and Stryer, 1992; Dizhoor et al., 1993; Hughes et al., 1995; Tanaka et al., 1995). In this model, the fatty acyl moiety of the Ca-free form of the protein resides in a hydrophobic pocket composed of aromatic and aliphatic amino acid residues distributed in the N-terminal half of the protein. The binding of Ca to recoverin induces the extrusion of its lipid moiety and N-terminal alpha-helix into solution, thereby unmasking the hydrophobic pocket; this conformation favors interactions with membranes, cytoskeleton, and/or a target factor(s). The fluorescence of rDrosNCa in the presence and absence of Ca is consistent with the Ca-myristoyl switch model. First, the variation of fluorescence of myr-rDrosNCa seems to be mainly due to a movement of its myristoyl group, since no major fluorescence change occurs upon Ca-binding to non-acylated rDrosNCa. Second, the fluorescence of myr-rDrosNCa in its Ca-bound form is very similar to that of the protein lacking the myristoyl modification. Taken together, these observations suggest that the observed fluorescence change of myr-rDrosNCa upon Ca binding is due to the movement of its fatty acyl moiety from a protein environment into solution.

Function of Recoverin-like Ca Sensors

Like calmodulin, recoverin and its homologues appear to have descended from a common ancestor that had four EF hand sites. All of the recoverin-like proteins identified to date have sequence determinants in their N termini necessary for fatty acylation, a modification that appears to be important for their Ca-dependent translocation properties. The discovery of multiple subclasses of neuronal recoverin-like proteins suggest that these cognates perform specialized cellular functions. Several of these cognates are coexpressed in a given neuron. These EF hand proteins have varying affinities for Ca (Cox et al., 1994; Ladant, 1995; Chen et al., 1995; Klenchin et al., 1995; Palczewski et al., 1994; Dizhoor et al., 1995), suggesting that their regulatory activities would be performed in different ranges of Ca concentrations. It has been proposed that recoverin and S-modulin delay photorecovery by inhibiting the receptor-quenching activity of rhodopsin kinase at high Ca levels (Kawamura et al., 1993; Chen et al., 1995; Klenchin et al., 1995). In contrast, GCAP-1 and GCAP-2 appear to promote photorecovery by stimulating membrane guanylate cyclase at low Ca concentrations (Palczewski et al., 1994; Dizhoor et al., 1995). Drosophila frequenin has been reported to stimulate bovine photoreceptor membrane guanylate cyclase in low Ca conditions (Pongs et al., 1994); however, DrosNCa does not exhibit this activity in similar in vitro assays. (^2)

In this paper, we report that DrosNCa is capable of inhibiting the phosphorylation of bleached rhodopsin in reconstituted assays in a Ca-dependent manner. We show that its potency is similar to that of recoverin and that its inhibitory activity, like that of recoverin, is enhanced by myristoylation. Our results on BovRv are in agreement with the findings of Chen et al.(1995) but in contrast to Calvert et al.(1995), who report that myristoylated and nonacylated BovRv have similar inhibitory potencies. It seems plausible that differences between our experimental procedures and those of Calvert et al. may account for the discrepancies in results. Three experimental differences stand out in particular: (i) in Calvert et al., 100% of the rhodopsin was bleached during the experiment, whereas we bleached only 0.05% of the rhodopsin; (ii) we used recombinant rhodopsin kinase that is produced using the baculovirus-Sf9 expression system, whereas Calvert et al. extracted the enzyme from bovine photoreceptors; and (iii), the methods of purifying rhodopsin kinase differed, e.g. the rhodopsin kinase preparations of Calvert et al. included transducin, arrestin, and 0.4% Tween 20, whereas our protein preparations were highly purified and did not contain detergent. We have found that detergent can interfere with the Ca-dependent association of rhodopsin kinase and recoverin. (^3)

Although our experiments do not explore the mechanism by which DrosNCa inhibits rhodopsin phosphorylation by rhodopsin kinase, the similarity between the inhibitory effects of DrosNCa and recoverin suggests that these two proteins act through the same mechanism(s). It has been shown that recoverin and rhodopsin kinase associate in a Ca-dependent manner and that this interaction is required for the inhibitory effect of recoverin on rhodopsin phosphorylation (Chen et al., 1995). One might therefore postulate that a direct interaction between DrosNCa and rhodopsin kinase is necessary for the inhibition of rhodopsin phosphorylation by DrosNCa. Further investigations are required to test this hypothesis. Ca-dependent inhibition of rhodopsin phosphorylation has also been observed using another recoverin cognate, hippocalcin,^3 but other recoverin-related proteins like GCAP-2 or the more distant calmodulin are only poor inhibitors in these phosphorylation assays. As such, the capacity of in vitro inhibition of rhodopsin phosphorylation appears to be a newly discovered property of a subset of recoverin-like proteins including recoverin, neurocalcin, and hippocalcin. This is further supported by recent evidence that neuronal recoverin-like proteins of the neuronal calcium sensor family inhibit in vitro phosphorylation of rhodopsin (De Castro et al., 1995).

Rhodopsin kinase belongs to a subfamily of serine/threonine kinases that desensitize activated seven-transmembrane receptors involved in signal transduction. Cognates of rhodopsin kinase include mammalian betaARK1, betaARK2, and G protein-coupled receptor kinases 4-6, as well as Drosophila G protein-coupled receptor kinases 1-4 (Cassill et al., 1991; Inglese et al., 1993). Given that recoverin-like proteins colocalize with homologues of rhodopsin kinase in neuronal tissues and that several cognates of recoverin inhibit rhodopsin phosphorylation in a Ca-sensitive manner, it is tempting to speculate that members of these two protein subfamilies interact to confer Ca-dependent attenuation to seven-transmembrane receptor quenching events. However, at least two issues raise questions about the ability of recoverin-like proteins to control receptor activity in vivo. First, recoverin and its cognates appear to be exclusively expressed in neuronal tissues, whereas GRKs and seven-transmembrane receptors are present in non-neuronal cells as well. Second, the documented data on the inhibitory effects of recoverin and its cognates are based on in vitro studies using mammalian rhodopsin kinase. If the recoverin and rhodopsin kinase subfamilies interact as proposed, one should be able to demonstrate that recoverin-like proteins also inhibit betaARK1, betaARK2, and/or G protein-coupled receptor kinases 4-6. So far, Chen et al.(1995) have found that recoverin cannot inhibit betaARK1 in reconstituted assays.

Neuronal signaling is attenuated by mechanisms involving the universal second messenger Ca. Recoverin and its homologues probably function as Ca-sensing regulators in neuronal processes, but their precise mode(s) of action remains unresolved. It is plausible that each recoverin-like protein differentially controls a receptor kinase. Alternatively, it is conceivable that these EF hand proteins, like calmodulin, may interact with multiple targets. Indeed, multiple proteins have been reported to associate with recoverin and neurocalcin in a Ca-dependent manner (Chen et al., 1995; Okazaki et al., 1995). Further studies are therefore required to elucidate the physiological roles of this diverse class of Ca-binding proteins.


FOOTNOTES

*
This work was supported by National Institutes of Health Grant E406641. 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.

§
To whom correspondence should be addressed. Tel.: 206-543-2871; Fax: 206-543-0858.

Current address: Myriad Genetics, Inc., 390 Wakara Way, Salt Lake City, UT 84108. Tel.: 206-543-2871; Fax: 206-543-0858.

(^1)
The abbreviations used are: BovRv, bovine recoverin; beta-ME, beta-mercaptoethanol; GCAP, guanylate cyclase activating protein; non-rDrosNCa, nonacylated recombinant Drosophila neurocalcin; myr-rDrosNCa, myristoylated recombinant Drosophila neurocalcin; PMSF, phenylmethlysulfonyl fluoride; RK, rhodopsin kinase; PAGE, polyacrylamide gel electrophoresis; MOPS, 4-morpholinepropanesulfonic acid; IEF, isoelectric focusing; HEDTA, N-(2-hydroxyethyl)ethylenediamine-N,N-N`triacetic acid trisodium salt dihydrate.

(^2)
A. Dizhoor, personal communication.

(^3)
C.-K. Chen, unpublished observations.


ACKNOWLEDGEMENTS

We are indebted to Robert Hughes and Alexander Dizhoor for providing myristoylated recombinant GCAP-2. We are grateful to Lowell Erickson, Thomas Neubert, and Richard Johnson for performing mass spectrometry analyses and to William Atkins for helping with fluorescence analyses. We also thank Linda Munar and Nora Tan for excellent technical assistance.


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