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© The Rockefeller University Press, 0021-9525/2000//715 $5.00
The Journal of Cell Biology, Volume 148, Number 4, , 2000 715-726

Intracellular Distribution of Mammalian Protein Kinase a Catalytic Subunit Altered by Conserved Asn2 Deamidation

^a European Molecular Biology Laboratory, D-69012 Heidelberg, Germany
^b Department of Pathochemistry, German Cancer Research Center, D-69120 Heidelberg, Germany
Department of Pathochemistry, German Cancer Research Center, Im Neuenheimer Feld 280, D-69120 Heidelberg, Germany.49-6221-32425949-6221-423253

v.kinzel{at}dkfz-heidelberg.de

The catalytic (C) subunit of protein kinase A functions both in the cytoplasm and the nucleus. A major charge variant representing about one third of the enzyme in striated muscle results from deamidation in vivo of the Asn2 residue at the conserved NH₂-terminal sequence myrGly-Asn-Ala (Jedrzejewski, P.T., A. Girod, A. Tholey, N. König, S. Thullner, V. Kinzel, and D. Bossemeyer. 1998. Protein Sci. 7:457–469). Because of the increase of electronegativity by generation of Asp2, it is reminiscent of a myristoyl-electrostatic switch. To compare the intracellular distribution of the enzymes, both forms of porcine or bovine heart enzyme were microinjected into the cytoplasm of mouse NIH 3T3 cells after conjugation with fluorescein, rhodamine, or in unlabeled form. The nuclear/cytoplasmic fluorescence ratio (N/C) was analyzed in the presence of cAMP (in the case of unlabeled enzyme by antibodies). Under all circumstances, the N/C ratio obtained with the encoded Asn2 form was significantly higher than that with the deamidated, Asp2 form; i.e., the Asn2 form reached a larger nuclear concentration than the Asp2 form. Comparable data were obtained with a human cell line. The differential intracellular distribution of both enzyme forms is also reflected by functional data. It correlates with the degree of phosphorylation of the key serine in CREB family transcription factors in the nucleus. Microinjection of myristoylated recombinant bovine C and the Asn2 deletion mutant of it yielded N/C ratios in the same range as encoded native enzymes. Thus, Asn2 seems to serve as a potential site for modulating electronegativity. The data indicate that the NH₂-terminal domain of the PKA C-subunit contributes to the intracellular distribution of free enzyme, which can be altered by site-specific in vivo deamidation. The model character for other signaling proteins starting with myrGly-Asn is discussed.

Key Words: deamidation • myristoylated NH₂ terminus • microinjection • myristoyl-electrostatic switch • CREB phosphorylation

© 2000 The Rockefeller University Press

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
An increase in cellular cAMP represents a rapid early metabolic response to a variety of external stimuli. Cyclic AMP activates the cyclic AMP–dependent protein kinase A (PKA), an abundant multifunctional enzyme. By phosphorylation of key substrates, PKA transmits exogenous signals regulating a large number of cellular processes in the cytoplasm as well as in the nucleus (for review see Walsh and Van Patten 1994). Although different signaling pathways are propagated through the same protein kinase, the character as well as the time frame of cellular responses may differ widely. Whereas cAMP-triggered metabolic steps in the cytoplasm are initiated within less than a minute, cAMP-stimulated nuclear events proceed at a much slower pace with the maximum occurring only after 30 min (Hagiwara et al. 1993). Control of the intracellular distribution of the active enzyme is undoubtedly of great importance (for reviews see Lohmann and Walter 1984; Nigg 1990).

In the absence of cAMP, PKA exists largely as an inactive tetrameric holoenzyme consisting of two regulatory (R) subunits composed of a dimer and two catalytic (C) subunits (for review see Krebs and Beavo 1979). The holoenzyme is primarily localized in the cytoplasm or bound to specific cytoplasmic organelles via anchoring proteins, depending on the type of R-subunit (for review see Scott 1991; Hubbard and Cohen 1993). As sufficient amounts of cAMP become available, up to 4 mol of the nucleotide are bound to each R-subunit dimer, which in turn liberates two molecules of monomeric C-subunit. Evidence has been presented that the free C-subunit can translocate to the nucleus (Nigg et al. 1985; Meinkoth et al. 1990; Nigg 1990), although a classical nuclear localization sequence has not yet been identified. Moreover, it has been shown that cAMP-stimulated transcription is rate-limited by the nuclear entry of the enzyme (Hagiwara et al. 1993).

Quantitative data on nuclear entry have been obtained previously by microinjection of recombinant catalytic subunit C (mouse sequence), and were explained by diffusion (Harootunian et al. 1993). Native C-subunit isolated from tissues carries a long chain fatty acid at the NH₂ terminus, mostly myristate, which is absent from the recombinant form (Carr et al. 1982). From a comparison of recombinant with the native catalytic subunit it was assumed that myristoylation of the native enzyme was not obligatory for intracellular function, including nuclear entry of the enzyme (Clegg et al. 1989; Meinkoth et al. 1990).

Recent evidence shows that in the native catalytic subunit, an increase in electronegativity can occur close to the NH₂ terminus through a posttranslational mechanism. Preparations of the catalytic subunit from striated muscle of several mammalian species, although homogenous by SDS gel electrophoresis, have been separated into two chromatographic fractions, A and B, in many laboratories on the basis of charge differences. These are not due to differences in the molar phosphorylation rate (Kinzel et al. 1987). Based on earlier observations (Hotz et al. 1989), it recently has been shown by electrospray mass spectrometry and sequence analysis of the C-subunit from four different mammalian species (Jedrzejewski et al. 1998) that fraction B contains the catalytic subunit gene products C and Cβ in the encoded form with Asn at position two in both cases. Fraction A, which represents consistently about one third of routine enzyme preparations, contains C and Cβ at the same ratio as fraction B but exclusively in the Asp2 form. The fact that Asp2 is not encoded in C and Cβ, and even not allowed in substrates of the N-myristoyl transferase (NMT; for review see Towler et al. 1988), argues for a posttranslational conversion of Asn2 to Asp2 by deamidation, which is responsible for the 0.4-pH unit difference of the isoelectric values of the fractions A and B. Evidence has been presented that indicates that deamidation of Asn2 occurs in vivo, i.e., represents a natural modification (Jedrzejewski et al. 1998) that appears to be regulated since the deamidated fraction of C-subunit from striated muscle of different mammalian species represents reproducibly one third from the total. The regulation of deamidation of Asn2, however, remains to be elucidated.

The significance of the Asn2 to Asp2 conversion in the C-subunit is unknown. Effects on the enzyme activity in the test tube, its reassociation with R-subunits (Kinzel et al. 1987), or its association with protein kinase inhibitor (Van Patten et al. 1988) were not observed so far. This prompted us to ask if such a conserved deamidation of the C-subunit might influence the localization of the enzyme in living cells. We determined the nuclear/cytoplasmic distribution of both forms of porcine and bovine C-subunit after microinjection into the cytoplasm of cultured cells. The data show that the nuclear/cytoplasmic ratio approached by the Asp2 form of the enzyme is lower than that obtained with the encoded Asn2 form. Accordingly, the phosphorylation of substrate in the nucleus (CREB family transcription factors) through the deamidated form is smaller than with the encoded form. It seems that the partial deamidation of the C-subunit at the conserved Asn2 is aimed at modulating the intracellular distribution as well as the phosphorylation capacity of free enzyme among the major cellular compartments.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Catalytic Subunit of the cAMP-dependent Kinase Type II from Pig and Bovine Hearts
The catalytic subunit of the cAMP-dependent kinase type II from pig and bovine hearts was prepared as described earlier (Nelson and Taylor 1981; Kinzel et al. 1987; Bossemeyer et al. 1993) with minor modifications including a scaling up. In brief, hearts were homogenized in 50 mM potassium phosphate buffer, pH 6.5, containing 1 mM EDTA, 2 mM DTT, and the following protease inhibitors: 0.5 mM PMSF, 0.2 mM TPCK, 0.5 mg/l leupeptin, 0.7 mg/l pepstatin A, 0.5 mg/l E64, 0.5 mM N-NH₂-capronic acid, and 0.5 mg/trypsin inhibitor. The homogenate was cleared by centrifugation and filtration through glass wool and bound to DE-52 cellulose (Whatman). The DE cellulose was washed with 100 mM potassium phosphate buffer, pH 6.5, and the holoenzyme was eluted by 300 mM potassium phosphate buffer, pH 6.5. After dilution of the eluate (1:5) the holoenzyme was again bound to DE cellulose. After washes with potassium phosphate buffer (50 mM, pH 6.5, and 15 mM, pH 6.1), the C subunit was eluted by cAMP (0.2 mM in buffer A, 15 ml potassium phosphate, 1 mM EDTA, 0.1 mM DTT) and immediately bound to a small column with CM-52 cellulose (Whatman). The C-subunit was eluted by a gradient 0–60% buffer B (100 mM Mops, 150 mM KCl, l mM DTT, 0.l mM EDTA, pH 7) for the first 20 ml; 60–100% buffer B for the next 30 ml. Fractions of 10 ml were collected. From 4-kg hearts, typically, 15–20 mg of electrophoretically homogenous C subunit were obtained.

Separation of Fraction A and B
Up to 2 mg of C-subunit diluted 1:2 by H₂O was separated on a Mono S HR 5/5 column (FPLC-System; Pharmacia). The gradient was programmed to be 0–22% buffer B (10 mM bis-Tris propane, 1 M LiCl, pH 8.5) 0–12 ml; 22–26% buffer B 12–25 ml; 26–100% buffer B 25–26 ml; 100% buffer 26–50 ml. Flow rate was 0.75 ml/min. The two peaks, at 23% buffer B and 55% buffer B representing enzyme fraction A and B (see Fig. 1), were collected. Separation of fraction A and B was verified by isoelectric focusing. Protein kinase activity was assayed as described previously (Kinzel et al. 1987); the fractions had an equal specific enzyme activity. Details of the analysis of fraction A and B by mass spectrometry have been described elsewhere (Jedrzejewski et al. 1998).

View larger version (9K): [in this window] [in a new window] [Download PPT slide]   Figure 1 Separation of electrophoretically homogenous PKA C-subunit (porcine heart) on cation exchange resin into fractions A and B. (inset) Enzyme in SDS gel stained with Coomassie blue: (lane 2) molecular mass standard proteins ovalbumin 43 kD, and carboanhydrase 30 kD (lane 1).

Expression and Purification of Recombinant myr-rC and Mutants
Recombinant bovine catalytic C (Wiemann et al. 1992) was expressed using vector pT7-7 in the Escherichia coli strain BL21(DE3) and purified by affinity chromatography and FPLC separation on a Mono S column as described (Girod et al. 1996), except that the vector pBB131 for the expression of yeast NMT was coexpressed together with C (Duronio et al. 1990, Jedrzejewski et al. 1998), leading to virtually complete myristoylation of the catalytic subunit. The specific enzyme activity equaled that of native enzyme obtained from heart muscle. Site-directed mutagenesis was performed according to Kunkel 1985; the fragment was characterized by sequencing and cloned into the expression vector pT7-7, coexpressed with yeast NMT and purified as above.

Antibodies
Polyclonal antibodies against the C-subunit were raised in rabbits by two intramuscular injections (3- wk interval) of 0.4–0.5 mg C-subunit (isolated from bovine heart coupled to the same amount of hemocyanin by the use of glutaraldehyde 0.5%, 15 min at room temperature) and incomplete Freund adjuvants (1:1). After 2 mo, the serum reacted with C-subunit at a 4 x 10⁴ dilution in an ELISA. C-subunits from bovine and porcine origins were equally recognized by the antiserum. This was expected on the basis of the high degree of sequence homology (Buechler et al. 1989; Jedrzejewski et al. 1998). For some experiments, antibodies were purified by affinity chromatography using immobilized bovine C-subunit (3 mg coupled to 2 ml CNBr Sepharose; Pharmacia). Polyclonal rabbit antibodies against CREB and CREB-(p)Ser133 were a gift of Dr. W. Schmid (Division of Molecular Biology of the Cell I, German Cancer Center, Heidelberg, Germany). Recombinant CREB protein for in vitro phosphorylation was a gift from D. Gau (Division of Molecular Biology of the Cell I, German Cancer Center, Heidelberg, Germany).

Electrophoresis
Electrophoresis of fraction A and B in the presence of SDS was done in 11% polyacrylamide gels. The proteins were subsequently blotted to an Immobilon-P membrane. For immunostaining of proteins after Western blotting, the membrane was first soaked in TBS with 0.05% Tween 20 for 2 h, followed by incubation for at least 2 h with antibodies in TBS/0.05% Tween 20 (TBS/T). The blot was washed three times in TBS/T and incubated with peroxidase-coupled secondary antibody for 2 h. After another wash, the blot was finally stained according to Kobayashi and Tashima 1989.

Isoelectric Focusing of the C Subunit
Isoelectric focusing of the C-subunit was done in 1-mm ampholine gels, pH 3.5–9.5 (Pharmacia), prefocused at 8 W until 500 V was reached. 1–2 µg of the different C-subunits (labeled or unlabeled) diluted to 10 µl by water was spotted 3 cm away from the anode on the gel. The gel was run for 2 h at 1,500V, 8W, and stained by Coomassie blue. 2 µg myoglobin of horse and whale were used as pH markers.

Cell Culture and Microinjection
Mouse NIH 3T3 and HeLa cells were cultured as previously described (Kinzel et al. 1988; Pepperkok et al. 1988, Pepperkok et al. 1993a,Pepperkok et al. 1993b). For microinjection experiments, cells were plated onto glass coverslips (10 x 10 mm) or in glass bottom Microwell petri dishes (Mattek) and grown for 2 d (70% confluency). For microinjection, cells were transferred into carbonate-free culture medium containing 5% FCS and 20 mM Hepes. Microinjection was performed at room temperature using a Zeiss automated injection system (AIS; Ansorge and Pepperkok 1988). About 0.1 pl of sample was introduced into the cytoplasm of the cells representing 5–10% of the cell volume. The C-subunit samples to be microinjected were adjusted to identical concentration for fraction A and B in individual experiments as given in Results. Subsequently, microinjected cells were transferred into prewarmed carbonate-buffered culture medium and further incubated at 37°C and 5% CO₂ for various periods as indicated.

Immunofluorescence and Fluorescence Microscopy
Cells microinjected with fluorescently labeled C-subunits were fixed with 3.5% paraformaldehyde for 20 min on ice, washed with PBS/BSA, and mounted onto glass slides using 6 µl of Mowiol. In some experiments, injected cells plated on glass bottom microwells were directly transferred to the microscope for quantification of C-subunit fluorescence in living cells. Cells injected with unlabeled C-subunit were fixed with ice-cold 100% methanol for 4 min on ice. After fixation, they were washed extensively with PBS containing 0.1% BSA (PBS/BSA), incubated with polyclonal rabbit anti–PKA-AB (dilution 1:500) for 30 min at room temperature, subsequently washed with PBS/BSA, and incubated for another 30 min with rhodamine-conjugated goat anti–rabbit antibodies (Sigma Chemical Co.; dilution 1:100). Coverslips were finally washed in PBS/BSA and mounted onto glass coverslips as described above.

For immunostaining of CREB or phospho-CREB, injected cells were fixed with 3.5% paraformaldehyde as described above, permeabilized with 0.1% Triton X-100 in PBS for 4 min, and subsequently stained with anti–CREB or anti–phospho-CREB antibodies for 20 min, followed by incubation with ALEXA488-conjugated anti–rabbit antibodies (Molecular Probes). Coinjected mouse IgGs were stained with Alexa568-conjugated anti–mouse antibodies (Molecular Probes).

Images of stained cells were recorded either on a Zeiss inverted fluorescence microscope (model 135TV; Axiovert) equipped with a cooled slow scan CCD camera (model CH250; 1,317 x l,035 pixels; Photometrics) controlled by a Macintosh Quadra 900, or on a similar microimaging system recently described (Pepperkok et al. 1993a,Pepperkok et al. 1993b). Images were further processed and figures were arranged with the software package IPLab spectrum V3.1 (Signal Analytics Corp.) and Adobe Photoshop 3.0.

Quantification of compartment-specific cellular fluorescence was performed as described (Lorenz et al. 1993; Pepperkok et al. 1993a,Pepperkok et al. 1993b). Nuclear and cytoplasmic fluorescence intensities were determined separately in single cells and from these values was subtracted the local background intensity measured in neighboring uninjected cells by a background staining correction method described in Pepperkok et al. 1993a. The ratio of the corrected nuclear and cytoplasmic fluorescence intensities (N/C) was determined individually for each cell measured. In all experiments, C-subunit fractions, A and B, from the same preparation were compared directly.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Porcine PKA C-subunit Fraction A and B
To obtain the major fractions A and B of the C-subunit, porcine catalytic subunit from the heart (Fig. 1, inset, lane 2) was chromatographed as described in Materials and Methods and shown in Fig. 1. The fractions were characterized by mass spectrometry as reported in detail elsewhere (Jedrzejewski et al. 1998). The A/B ratio was 1:2, and the measured masses did not differ significantly: 40835.5 ± 1.6 D for fraction A; and 40833.5 ± 1.6 D for fraction B. The molar phosphate content was 1.91 ± 0.17 in fraction A and 1.98 ± 0.14 in fraction B, indicating two phosphorylation sites. For further characterization of both fractions, tryptic digests were analyzed for the myristoylated NH₂-terminal peptides by µLC-ESI-MS and by sequence analysis through tandem mass spectroscopy (summarized in Table ). Fraction B contains the isozymes C and Cβ (2.5:1) in the encoded form with Asn2; fraction A contains the isozymes exclusively in the Asp2 form with traces of isomers, which is indicative of a deamidation reaction by the β-aspartyl shift mechanism (for review see Wright 1991). Superimposable data were obtained in the same study with C-subunit fractions A and B from bovine heart (Jedrzejewski et al. 1998). Physical separation of C and Cβ is presently not possible. The data in Table indicate that C and Cβ were deamidated to a comparable extent. No further differences between fractions A and B were detectable. Therefore, it is reasonable to assume that it is the Asn2 to Asp2 conversion that causes the 0.4-pH unit difference in their isoelectric values and, thus, their separation on cation exchange resins.

Microinjected cells first emitted a strong fluorescence in the cytoplasm, followed by a subsequent increase in the nucleus. Cells fixed within 10 min after injection of the enzyme exhibited no morphological changes. However, beyond 10 min, injected cells started to develop morphological characteristics (see below) as if they had been treated with permeating cAMP derivatives or with agents causing an increase of cellular cAMP, thus, indicating a functional enzyme. No morphological changes were observed when cells were injected with purified mouse or rabbit IgGs in the injection buffer (data not shown).

For quantification of the cellular distribution of fractions A and B after microinjections, the cells were further incubated in the presence of 8-bromo-cAMP (1 mM; Byus and Fletcher 1982) to prevent reassociation with R-subunits. Quantification was obtained from images digitized with a slow scan cooled CCD camera at 12-bit resolution as described in Materials and Methods. At least 50 cells per group and time point were analyzed and the ratio of nuclear/cytoplasmic fluorescence (N/C) was determined. The results, given in Fig. 2, show that between 5 and 10 min after injection, the N/C ratios for A and B diverged and reached 2.8 and 4.8, respectively; i.e., the N/C ratio obtained with fraction B exceeded that of fraction A 1.7-fold. After 10 min, the curves seem to reach a plateau lasting for another 50 min at least, ruling out the possibility that the differences observed here for N/C ratios simply reflect different cytoplasmic to nuclear transport kinetics for fractions A and B. The data in Fig. 2 show that microinjected fraction B reaches a significantly higher nuclear concentration than microinjected fraction A. Moreover, the stability and duration of the plateau phase obtained with both enzyme fractions argues against a measurable interconversion of fraction B into fraction A, i.e., against a significant deamidation during the experiment.

View larger version (10K): [in this window] [in a new window] [Download PPT slide]   Figure 2 Cellular distribution of microinjected PKA C-subunit fractions A and B labeled with fluorescein. NIH 3T3 cells were microinjected at room temperature with fluorescein-conjugated C-subunit fraction A or B, both at 1 mg/ml. Immediately after injection, cells were transferred to prewarmed medium containing 1 mM 8-bromo-cAMP and incubated for the time indicated at 37°C. Thereafter, cells were fixed with paraformaldehyde, and the ratio of nuclear/cytoplasmic fluorescence was determined as described in Materials and Methods. The averages and SDs of at least two experiments with >50 cells quantified per time point each are shown.

If the minor molecular differences between fraction A and B are responsible for a differential intracellular distribution, the type of dye conjugated might influence the distribution as well. Therefore, fraction A and B were conjugated with a different dye, rhodamine (TRITC), and microinjected into the cytoplasm of NIH 3T3 cells held subsequently in the presence of 8-bromo-cAMP. The N/C ratios obtained with the TRITC-conjugated fraction A and B 10 min after injection in comparison with the data obtained with FITC-conjugated enzyme fractions are shown in Fig. 3. TRITC-conjugated fraction B reaches an N/C ratio 2.3 times larger than TRITC-conjugated fraction A. The comparable relationships of the N/C ratios indicate that the enzyme distribution approached a similar balance independent of the type of dye conjugated.

View larger version (11K): [in this window] [in a new window] [Download PPT slide]   Figure 3 Comparison of the cellular distribution of microinjected PKA C-subunit fractions A and B conjugated with rhodamine or fluorescein. NIH 3T3 cells were microinjected at room temperature with labeled C-subunit fractions adjusted to 1 mg/ml. After a 10-min postinjection incubation at 37°C in the presence of 1 mM 8-bromo-cAMP, cells were fixed and the nuclear to cytoplasmic fluorescence was determined as described in Materials and Methods. The averages and SDs of two experiments with at least 60 cells quantified per group are shown.

View larger version (27K): [in this window] [in a new window] [Download PPT slide]   Figure 4 Isoelectric focusing results obtained with native porcine PKA C-subunit, before (lane 1) and after separation in fraction A (lane 2) and fraction B (lane 3). Fluorescein-labeled fractions A and B are shown in lane 4 and 5 respectively. Arrows indicate the native and the predominantly labeled fraction A () and B ().

Purified fractions A or B (both at 4 mg/ml) were microinjected into the cytoplasm of NIH 3T3 fibroblasts. They were incubated for 30 min at 37°C, fixed with methanol, incubated with affinity-purified antibodies, and stained with the fluorescent secondary antibody. As shown in Fig. 5, for the antibody dilutions used, the microinjected cells showed a strong fluorescent signal. In contrast, little fluorescence (<25% of the signal of injected cells) was obtained in noninjected cells (marked by stars in Fig. 5). Discrimination between injected and noninjected cells was facilitated by the increased appearance of growth cones (Fig. 5A and Fig. B, arrows) in cells injected with either fraction A or B. At time points longer than 30 min after microinjection, rounding up of the cells was observed (not shown). Similar morphological changes upon microinjection of the C-subunit into living cells have been reported by others (e.g., see Lamb et al. 1988, Lamb et al. 1989). They seem to indicate that the injected enzyme is functional. In all injected cells, a significant fluorescence signal was obtained in the cytoplasm and the nucleus. For both microinjected fraction A and B, an increased nuclear fluorescence was observed (Fig. 5).

View larger version (23K): [in this window] [in a new window] [Download PPT slide]   Figure 5 Localization of microinjected PKA C-subunit fraction A and B by immunofluorescence. Purified porcine C-subunit fractions A and B (4 mg/ml each) were injected with 5 mM cAMP (in the pipette) into the cytoplasm of NIH 3T3 cells. After injection, cells were incubated at 37°C for different periods (30 min shown here) before they were fixed and stained for C-subunit using a polyclonal rabbit antibody and corresponding rhodamine-conjugated secondary antibodies (see Materials and Methods). The anti-PKA antibody was diluted sufficiently that only microinjected cells showed a significant fluorescent staining specific for microinjected C-subunit. Asterisks indicate the nucleus of neighboring noninjected cells. The image contrast was adjusted to better visualize growth cones in injected cells (marked by arrows). Therefore, the nucleus in the cell injected with fraction B appears to be saturated. As in the other experiments, for the quantification of N/C values, the original images were used where the gray values in all the images were always below the saturation level. The mean N/C ratio ± SD determined in this experiment from >100 cells was 1.9 ± 0.2 for fraction A and 3.3 ± 0.5 for fraction B at 30 min. Bar, 20 µm.

View larger version (9K): [in this window] [in a new window] [Download PPT slide]   Figure 6 Cellular distribution of PKA C-subunit fractions A and B detected by immunofluorescence. Cells were treated and injected as described in the legend of Fig. 5. The ratio of nuclear to cytoplasmic fluorescence was determined as described in Materials and Methods. The averages and SDs of six different experiments with at least 40 cells quantified for each value are shown.

To evaluate the possibility that the apparent differences of the N/C ratios obtained with the fractions A and B were caused by a preferential degradation of one of the fractions within a particular subcellular compartment, the total cellular amount of enzyme detectable by immunofluorescence was determined, and the results obtained for A and B were compared with each other. The data (Fig. 7) indicate that fractions A and B do not decay to a different extent. Injected dye-conjugated C-subunit fractions A and B decayed at a similar rate (not shown). Therefore, the N/C ratios indeed seem to reflect a different intracellular distribution.

View larger version (20K): [in this window] [in a new window] [Download PPT slide]   Figure 7 Decay of microinjected PKA C-subunit fraction A and B. NIH 3T3 cells were microinjected with purified PKA C-subunit fraction A or B at 4 mg/ml. At different time points after injection, cells were fixed and stained by immunofluorescence for injected PKA and subsequently mounted on glass slides. Images of injected cells were acquired as described in Materials and Methods. The average PKA-specific fluorescence intensity (including the nucleus and cytoplasm) in injected cells was determined, and the value obtained for cells fixed immediately after injection (t = 0) was set at 100%. The averages and SDs of two independent experiments with at least 65 cells measured are shown. Degradation of the injected PKA proteins appeared to be similar for the fraction A and B.

A control with a recombinant enzyme mimicking the Asp2 consensus form in fraction A was not possible since the NH₂-terminal sequence Gly-Asp-X unlike Gly-Asn-X is not a substrate of NMT (Towler et al. 1988). Coexpression of the rCAsn2Asp mutant with NMT in E. coli did not yield myristoylated enzyme (Jedrzejewski et al. 1998). Moreover, a procedure for specifically deamidating Asn2 of C in vitro is not available yet. Therefore, one is limited in this respect to the fraction A isolated from tissue. To evaluate a potential role of Asn2 for the intracellular distribution of the enzyme, Asn2 was deleted from bovine C, and the enzyme was coexpressed with NMT in E. coli. The resulting protein was myristoylated; the doubly phosphorylated form was isolated, concentrated, and injected into the cytoplasm of NIH 3T3 cells in the presence of cAMP. After a 10-min incubation at 37°C, the cells were fixed and the N/C ratio was analyzed by the use of antibodies. This deletion mutant reached 5.5 ± 0.5, a value well within the range of data obtained with fraction B, indicating that Asn2 per se is not a determinant for the nuclear/cytoplasmic distribution of the enzyme.

Functional Significance of C-subunit Deamidation
The cyclic AMP–responsive transcription factor CREB and related transcription factors (for simplicity subsequently referred to as CREB) can be regulated by phosphorylation of a key serine (Ser133 in CREB) within a conserved subdomain by a number of protein kinases including PKA (for reviews see De Cesare et al. 1999; Shaywitz and Greenberg 1999). To test if the microinjected enzyme fractions exhibit catalytic activity in vivo according to their differential intracellular distribution, the phosphorylation of the key serine residue was analyzed by the use of antibodies that specifically recognize the phospho form of this epitope, i.e., CREB-(p)Ser133. For comparison, in vitro studies with recombinant CREB were carried out. In the test tube, the phosphorylation of recombinant CREB by both fractions did not differ as the Western blot analysis of electrophoresed samples revealed (data not shown), thus, supporting earlier observations that different PKA substrates were phosphorylated in vitro by both enzyme fractions to the same extent (Kinzel et al. 1987). For the in vivo phosphorylation of the CREB enzyme, fractions A and B (1 mg/ml) were microinjected in the cytoplasm of NIH 3T3 cells; after a 25-min incubation at 37°C, the cells were fixed. Microinjected cells were identified by the detection of coinjected IgGs (Fig. 8B and Fig. D) and simultaneously stained with primary anti–CREB and anti–CREB-(p)Ser133 antibodies (Fig. 8A and Fig. C). The CREB signal as such was not altered by the microinjection of both enzyme fractions (data not shown). The phospho-CREB signal in cells injected with fraction B was stronger than in cells injected with the enzyme fraction A (Fig. 8A versus C). The quantified phospho-CREB–specific signals in the nuclei of cells injected with different amounts of the enzyme fractions are plotted as a percentage of the maximal response seen (Fig. 8 E). The data demonstrate that up to an enzyme concentration of 2 mg/ml (in the microinjection pipette) CREB phosphorylation by fraction B appears to be more efficient during 25 min than by fraction A. At 3.5 mg/ml, the 25-min period is sufficient for fraction A to phosphorylate CREB to the same extent as fraction B, possibly indicating substrate limitation. In contrast to the phosphorylation mediated by fraction B, that effected by fraction A exhibits an almost linear concentration dependence up to 1 mg/ml. In this range, the largest differences in the phosphorylation of CREB by fraction A and B were observed. It should be noted that the two smallest concentrations injected (0.25 and 0.5 mg/ml) lead to and represent enzyme levels that are within the physiological range (Hofmann et al. 1977; Lohmann and Walter 1984). A small concentration was chosen to test the time course of CREB phosphorylation by both enzyme fractions (Fig. 8 F). For this purpose, NIH 3T3 cells were microinjected with 0.5 mg/ml of fraction A or B at time zero, and incubated at 37°C for various periods as indicated before they were fixed and stained for phospho-CREB analysis. The data show again that fraction B causes a more pronounced phospho-CREB appearance than fraction A. The 25-min values agree with those seen with the same concentration in the previous analysis (Fig. 8 E). The onset of CREB phosphorylation by enzyme fraction B appears to be faster than that effected by fraction A. The intensity of CREB phosphorylation peaks at 20–25 min after the injection of both enzyme fractions with a subsequent takeover of dephosphorylation. Taken together, the data on CREB phosphorylation obtained with both enzyme fractions mirror the differential intracellular distribution of the encoded and the deamidated forms of the PKA catalytic subunit, and illustrate at the same time functional consequences of Asn2 deamidation.

View larger version (144K): [in this window] [in a new window] [Download PPT slide]   Figure 8 CREB phosphorylation by microinjected PKA C-subunit fraction A and B. (A–D) Purified PKA C-subunit fraction A (C and D) and B (A and B) were microinjected into the cytoplasm of NIH 3T3 cells at room temperature at a concentration of 1 mg/ml (for details see Fig. 5 legend). To identify injected cells, purified mouse IgGs (1 mg/ml) were coinjected. At 25 min after injection and incubation at 37°C, cells were fixed and stained for injected mouse IgGs and CREB-(p)Ser133 using primary anti–phospho-CREB antibodies. Arrows in A and C indicate the position of injected cells. (E) Different concentrations of purified PKA C-subunit fraction A or B, as indicated, were microinjected into the cytoplasm of NIH 3T3 cells together with purified mouse IgGs (1 mg/ml) to identify injected cells. Cells were incubated and stained for IgGs and CREB-(p)Ser133 as described in A–D. The phospho-CREB–specific signal in the nucleus of injected cells was quantified as described in Materials and Methods. (F) Purified PKA C-subunit fractions A or B (0.5 mg/ml) were microinjected at room temperature and subsequently incubated at 37°C for the periods indicated. The detection of microinjected cells, staining, and quantification of CREB phosphorylation was as above. In E and F, the means ± SDs of at least 60 cells are shown for each data point. The values have been normalized to the maximum average nuclear intensity obtained for cells injected with enzyme fraction B (at a concentration of 3.5 mg/ml; E, respectively incubated for 20 min; F). Bar, 20 µm.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

The relatively large amounts of microinjected C-subunit fractions required to measure the intracellular distribution may question the potential physiological significance of the results. However, the significance is supported by data on the site-specific phosphorylation of nuclear CREB, a reaction known to activate the transcription factor, elicited by the small enzyme amounts injected. The differential phosphorylation by fraction A and B is particularly well demonstrable at the small enzyme amounts, which yield intracellular concentrations in the physiological range. Under these conditions, nuclear substrate is probably not a limiting factor. The encoded, Asn 2 form of the PKA C-subunit is more efficient in that respect than the deamidated, Asp2 form. Since in vitro both enzyme fractions were shown to phosphorylate PKA substrates (Kinzel et al. 1987), including CREB equally effective, the data indicate that the differences observed in vivo are based on the uneven intracellular distribution; i.e., the larger nuclear level of the encoded C-subunit. The distribution data and the degree of protein phosphorylation in the nucleus correlate. Therefore, the differential distribution of both enzyme fractions observed at high concentrations is unlikely to be caused by this fact, but appears to reflect a physiological relevance.

The difference in the N/C ratios observed for fraction A and B might suggest in the first instance that it is the increase in electronegativity that causes a decrease of the nuclear enzyme level of fraction A. A simple charge difference as the driving force for the variant distribution of the Asn2 and the Asp2 form is unlikely, however, because of the fact that FITC labeling renders fraction B even more acidic than the unlabeled fraction A (Fig. 4), yet it, nevertheless, reaches larger N/C values than the latter. Therefore, it seems that a negative charge alone is not sufficient to explain the decrease in the nuclear level of the enzyme, but that it must probably be added at a specific site.

The Asn2 residue per se does not appear to constitute a determinant for the intracellular enzyme distribution as its deletion does not alter the N/C ratio of the deletion mutant when compared with the wild-type enzyme. It appears that Asn2 plays a role as a deamidation site only, conserved in C, Cβ, and C and, thus, as a potential source for increasing electronegativity at the NH₂ terminus, and perhaps with the further consequence of facilitating Ser10 autophosphorylation. Since a negatively charged residue next to Gly1 inhibits N-myristoylation (Towler et al. 1988), deamidation appears to be the only way to achieve the specific sequence myrGly1-Asp2 observed in fraction A.

The gain in electronegativity close to the NH₂-terminal myristoyl moiety in proteins is reminiscent of myristoyl-electrostatic switch proteins (for review see, McLaughlin and Aderem 1995) in which electronegativity is achieved through phosphorylation aimed at influencing the interaction of these proteins with membranes. This is usually mediated by the myristoyl moiety partitioning into the lipid bilayer with positively charged residues interacting with acidic phospholipid head groups. Thus, it is possible that a lipophilic entity of membranous or proteinaceous nature may participate in the recognition and in the determination of the intracellular distribution of the C-subunit. It has been shown that the NH₂ terminus of the PKA C-subunit in chimeric pp60^v-src can partially substitute for the wild-type NH₂ terminus in conferring membrane binding in vivo (Silverman and Resh 1992). However, this observation with the myristoylated NH₂ terminus of the C-subunit within the foreign structural context of another protein may not necessarily reflect its natural role in PKA. A PKA-specific significance of its myristoylated NH₂ terminus may be indicated by the finding that the rate of C-subunit binding to liposomes in vitro is dramatically increased on interaction with the regulatory subunit type II (RII) but not with type I (Gangal et al. 1999). Even these PKA-specific observations, however, are unlikely to play a role since the experiments in our study were carried out under saturating amounts of cAMP and with excess of free C-subunit sufficient to guarantee subunit dissociation and to exclude a role of R-subunit isoforms.

Results published so far on the cytoplasmic to nuclear translocation of the free C-subunit are compatible with a model in which the enzyme can traverse nuclear pores in either direction by diffusion (Harootunian et al. 1993). A functional nuclear localization signal has not been identified yet in C-subunits. In agreement with a diffusion model, the distribution is not particularly influenced by the concentration of the C-subunit. In our study, the unlabeled enzymes were injected at a four times larger concentration than the labeled enzymes. The N/C ratios of the plateau, however, reach comparable values characteristic for a specific isoform, indicating that it is not saturable, at least not within this range. However, the observation that both forms of the enzyme after 10 min reach an equilibrium which is different for the deamidated and the nondeamidated forms, seems to require supplementary assumptions for explanation.

Deamidation of Asn2 might, of course, result in changes of the higher ordered structure of the NH₂ terminus. No noticeable structural differences are apparent between the high resolution structure of the fraction A enzyme (Bossemeyer et al. 1993) and the recombinant bovine (Engh et al. 1996) or mouse (Knighton et al. 1991) enzyme; however, the immediate area around Asn2 is not well resolved in the ternary structure (Bossemeyer et al. 1993; Zheng et al. 1993). Comparative secondary structure studies of synthetic myristoylated hexadecapeptides representing the bovine C NH₂ terminus either in the Asn2 and the Asp2 form provided no evidence for significant structural differences at this level (Tholey, A., D. Bossemeyer, V. Kinzel, and J. Reed, unpublished data). This still does not mean that a different structure or flexibility might not occur. It could be induced by interaction with cellular target(s), a possibility indicated indirectly by RII-induced binding of C-subunits to liposomes in vitro, which was not seen with RI (Gangal et al. 1999). The charge shift to a more acidic character of the NH₂ terminus could be sufficient to result in a preference for cytoplasmic structures that would retain fraction A to a certain extent in the cytoplasm, or a more favorable environment for the less acidic fraction B in the nucleus. The described differences in the sensitivity of fraction A and B to a specific protease in vitro (Kinzel et al. 1987) suggests that such differences are in principle recognizable at the molecular level. A differential export from the nucleus (Schmidt-Zachmann et al. 1993), mediated in the case of the C-subunit by protein kinase inhibitor protein (PKI) (Fantozzi et al. 1994), represents another possibility that requires further attention.

The fact that the different N/C ratios for fraction A and B are seen in the presence of saturating amounts of cAMP seems to argue against R-subunits as a retaining principle. The interaction of enzyme fractions A and B with RI or RII appeared to be indistinguishable in vitro (Kinzel et al. 1987). However, it is not excluded that the affinity of type II R-subunits for C-subunits in situ may be modulated by association with anchor proteins (Scott 1991; Hubbard and Cohen 1993) in such a way that the isozymes are bound to a different extent. A preferential binding of cell-endogenous PKI to the Asp2 form of the enzyme seems unlikely, however, as the cause for differential nuclear uptake since both enzyme fractions appeared to interact equally well with PKI, at least in vitro (Kinzel et al. 1987; Van Patten et al. 1988). Again, the isozymes might bind to cytoplasmic substrates to a different extent. The finding that the phosphorylation by fraction A and B of standard substrates including CREB in vitro was identical does not reflect the situation in the living cell (Lamb et al. 1988, Lamb et al. 1989; this study).

The example of the C-subunit may be typical of cases where proteins fulfill nuclear as well as cytoplasmic functions. Such proteins may adapt intermediate states of intracellular distribution by different mechanisms. One of them seems to be site-specific deamidation, as shown in this study. The circumstances in cells that control the partial deamidation of certain proteins are unknown and may even differ among candidate proteins; those for the C-subunit are unknown as well. However, they may play an important role in those cells or tissues in which the C-subunit is required to fulfill specific cytoplasmic functions. A preferentially deamidated state of the C-subunit may explain the lack of a significant redistribution of the enzyme to the nucleus upon treatment of certain cells with 8-bromo-cAMP (Murtaugh et al. 1982). The occurrence of comparable fraction A/fraction B ratios in muscle tissues of different mammalian species (Kinzel et al. 1987; Jedrzejewski et al. 1998) seems to point to a physiological significance of this modification. An example of protein-mediated deamidation of a cellular protein at a specific glutamine residue caused by a bacterial toxin has been described recently (Flatau et al. 1997; Schmidt et al. 1997). Moreover, several myristoylated proteins involved in signal transduction share the NH₂-terminal myr-Gly-Asn sequence and, thus, may be candidates for partial deamidation (listed by Jedrzejewski et al. 1998).

Although the isoAsp2 form of the enzyme cannot be evaluated separately, its presence in trace amounts in fraction A is worth mentioning in the context of this study. The occurrence of isoAsp2 in the C-subunit fraction A points to a mechanism of deamidation through the so-called β-aspartyl-shift mechanism (for review see Wright 1991). It involves the formation of a cyclic succinimide intermediate that opens to yield preferentially the isoAsp form (to a lesser extent the Asp form) (for reviews see Bornstein and Balian 1977; Aswad and Johnson 1987; Geiger and Clarke 1987; Lura and Schirch 1988; Artigues et al. 1990), which carries the original Cβ-methylene of Asn2 now in the peptide backbone. The inverse ratio of isoAsp/Asp in tissues, with a clear-cut surplus of the Asp form, is probably due to the action of a ubiquitous repair enzyme, protein carboxyl methyltransferase, which methylates the atypical -carboxyl group of L-isoAsp residues (Aswad 1984; Murray and Clarke, 1989) as a part of a mechanism aimed at the reconstitution of the regular peptide backbone. For a more detailed discussion of this relation with respect to the C-subunit see Jedrzejewski et al. 1998. Cases of site-specific nonenzymatic deamidation of proteins have been reported, which appear to be involved in aging and subsequent degradation of proteins. However, in certain proteins, this type of modification appears to be part of their physiological program (for review see Wright 1991). The conserved Asn2 deamidation of the PKA C-subunit with signs of ample repair (to yield predominantly the Asp 2 form) may belong to the latter group. This appears to be supported by the differential in vivo phosphorylation of the CREB family transcription factor(s) effected by the encoded and the deamidated C-subunit.

In conclusion, this study with living cells allows for the first time to consider different physiological functions of the major C-subunit isozymes of PKA (generated by deamidation of Asn2) on the basis of their differential distribution within cells, and points to a potential physiological significance of the NH₂-terminal domain of this enzyme, and possibly of other proteins with a similar NH₂ terminus for which the C-subunit may represent a model system. Further studies are aimed at the elucidation of the control of deamidation and of the molecular mechanism responsible for the altered intracellular distribution of Asn2 deamidated catalytic subunit.

	Acknowledgments

 
We thank Dr. Wolfgang Schmid and Daniel Gau (both from Division of Molecular Biology of the Cell I, German Cancer Research Center, Heidelberg, Germany) for anti-CREB and anti–CREB-(p)Ser133 antibodies as well as for recombinant CREB protein, Dr. Jennifer Reed for critically reading the manuscript and semantic assistance, and Angelika Lampe-Gegenheimer (both from Department of Pathochemistry, German Cancer Research Center, Heidelberg, Germany) for expert secretarial assistance.

The work was supported by the Deutsche Forschungsgemeinschaft.

Submitted: 22 December 1999

Accepted: 12 January 2000

Abbreviations used in this paper: C, catalytic; CREB, cAMP-responsive element binding protein; N/C, nuclear/cytoplasmic fluorescence; NMT, N-myristoyl transferase; PKA, protein kinase A or cAMP-dependent protein kinase; PKI, protein kinase inhibitor; R, regulatory.

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