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The Journal of Neuroscience, August 15, 2002, 22(16):6972-6979
Protective Role of Phosphorylation in Turnover of Glial Fibrillary Acidic Protein in Mice
Masaaki Takemura1, 3, Hiroshi Gomi1, Emma Colucci-Guyon2, and Shigeyoshi Itohara1 1 Laboratory for Behavioral Genetics, RIKEN Brain Science Institute, Wako 351-0198, Japan, 2 Unité de Biologie du Développement, Institut Pasteur, Centre National de la Recherche Scientifique Unité de Recherche Associée 1960, 75015 Paris, France, and 3 Institute for Virus Research, Kyoto University, Sakyo-ku, Kyoto 606-8507, Japan
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
Glial fibrillary acidic protein (GFAP), the principal intermediate filament (IF) protein of mature astrocytes in the CNS, plays specific roles in astrocyte functions. GFAP has multiple phosphorylation sites at its N-terminal head domain. To examine the role of phosphorylation at these sites, we generated a series of substitution mutant mice in which phosphorylation sites (Ser/Thr) were replaced by Ala, in different combinations. Gfaphm3/hm3 mice carrying substitutions at all five phosphorylation sites showed extensive decrease in both filament formation and amounts of GFAP. Gfaphm1/hm1 and Gfaphm2/hm2 mice, which carry substitutions at three of five sites and in different combinations, showed differential phenotypes. Although Gfaphm3/hm3 mice retained GFAP filaments in Bergmann glia in the cerebellum, the (Gfaphm3/hm3:Vim
/
Key words: glial fibrillary acidic protein; GFAP; vimentin; phosphorylation; intermediate filament; astrocyte; filament formation; degradation; knock-in mice; gene targeting
INTRODUCTION
There is a large family of intermediate filament (IF) proteins, the expression of which has a high degree of cell-type specificity. Glial fibrillary acidic protein (GFAP) is the principal IF protein of mature astrocytes in the CNS. Cumulative evidence from studies using GFAP null mutant mice underscored the importance of this protein in astrocyte functions (for review, see Pekny 2001
) (Gomi et al., 1995
IF proteins are composed of the N-terminal head, central rod, and C-terminal tail domains (for review, see Steinert and Roop, 1988
We examined previously the distribution of phosphorylated GFAP in the mouse brain, and we suggested a role for phosphorylation in nondividing astrocytes (Takemura et al., 2002
MATERIALS AND METHODS
Generation of mutant mice
Substitution mutations were introduced at the Gfap locus by gene targeting using embryonic day 14 (E14) embryonic stem (ES) cells, as described previously (Takemura et al., 2002Immunohistochemistry
Brains of mice were fixed by intracardiac perfusion with 4% paraformaldehyde in 0.1 M phosphate buffer, pH 7.4, paraffin embedded, and sectioned (4-6 µm). Tissue sections were dewaxed and rehydrated. Immunohistochemistry for GFAP or vimentin. Tissue sections in PBS were autoclaved for 5 min at 120°C and then were incubated for 1 hr at room temperature or overnight at 4°C with mouse monoclonal antibody against GFAP (1:100; GF12.24; Progen, Heidelberg, Germany) or vimentin (4H4; a kind gift from Dr. M. Inagaki). The primary antibodies were detected using Vectastain ABC kits (Vector Laboratories, Burlingame, CA) according to the recommendation of the manufacturer, followed by staining with 3,3'-diaminobenzidine tetrahydrochloride (Vector Laboratories). After halting the reaction, the sections were counterstained with hematoxylin (Merck, Darmstadt, Germany). Immunohistochemistry for S100B. The rehydrated sections were treated in 0.1% trypsin in PBS for 30 min at 37°C and then were incubated overnight at 4°C with mouse monoclonal antibody against S100B (1:3000; SH-B1; Sigma, St. Louis, MO).Northern blot analyses
Total mouse brain RNA was isolated from wild-type and mutant mice using RNeasy mini kits (Qiagen, Valencia, CA) according to the recommendation of the manufacturer. The RNA was electrophoresed on formaldehyde gels and transferred to nylon membrane (NEN, Boston, MA). Hybridization was done using as a probe 0.8 kb NheI digested fragment from mouse Gfap cDNA.Quantification of GFAP from mouse brains
Mouse brains were homogenized in ice-cold buffer consisting of 50 mM phosphate buffer, pH 7.4, 2 mM EDTA, 2 mM EGTA, and a protease inhibitor cocktail ("Complete"; Roche Products, Hertforshire, UK). An equal volume of 2× SDS-sample buffer (0.25 M Tris-Cl, pH 6.8, 10% SDS, 20% glycerol, 10% 2-mercaptoethanol, and 0.02% bromophenol blue) was added. Protein (3 µg) was subjected to SDS-PAGE (10% polyacrylamide gel) and transferred to a polyvinylidene difluoride membrane (Millipore, Bedford, MA). After blocking with 5% skim milk in Tris-buffered saline, the membrane was immersed in primary antibodies against GFAP [1:500 (GF12.24; Progen) or 1:10,000 (Dako, Glostrup, Denmark)] or-actin (1:2000; MAB1501; Chemicon, Temecula, CA), followed by immersion in peroxidase-conjugated rat anti-mouse IgG (1:5000; Zymed, San Francisco, CA) or anti-rabbit IgG (1:5000; Zymed). Signals were detected using the ECL (Amersham Biosciences, Little Chalfont, UK). Densitometry to quantify GFAP was done using the public domain NIH Image program (developed at the U.S. National Institutes of Health and available at http://rsb.info.nih.gov/nih-image/).
Preparation of astrocyte-enriched primary cultures and immunocytochemistry
Cerebral astrocyte cultures were prepared from E18.5 embryos, as described previously (Kato et al., 197930°C. The cells were then incubated for 2 hr at room temperature with an anti-GFAP antibody (1:500; Dako). After washing in PBS, slides were incubated for 1 hr at room temperature with Alexa546 dye-conjugated secondary antibodies diluted at 1:1000 (Molecular Probes, Eugene, OR).
Pulse-chase experiments
Metabolic labeling with 35S-Met/Cys (100 µCi/ml, 15 min) was done in DMEM lacking Met/Cys (Invitrogen) and containing 10% FBS. Labeled cells were either processed immediately or cultured in normal medium for various chase periods (0, 1, 24, and 48 hr). The cells were scraped off with 171 mM NaCl, 6 mM sodium phosphate, pH 7.4, 600 mM KCl, 0.5% (w/v) Triton X-100, 1 mM EDTA, and protease inhibitor cocktail ("Complete;" Roche). Fractionation into cytosolic and residual cytoskeletal fractions was done by centrifugation: 15,000 × g for 15 min at 4°C. The cytosolic fractions were used for immunoprecipitation with an anti-GFAP antibody (Dako). Immunoprecipitates and cytoskeletal fractions were subjected to SDS-PAGE. Quantification of 35S-GFAP was done using a Fujifilm (Tokyo, Japan) BAS-2500 image analyzer. Amounts of GFAP were quantified by immunoblotting using an anti-pan GFAP antibody GF12.24 and ECL.Generation of antibodies against the human GFAP head domain
Antibodies specific to humanized GFAP were raised in a rabbit using a synthetic peptide corresponding to human GFAP head domain H2N-CGGLAPGRRLGPGT-CONH coupled to keyhole limpet hemocyanin. Antigen solution was injected every 28 d using the RIBI adjuvant system (Ribi ImmunoChem Research, Hamilton, MT). The rabbit was bled 3 months after the initial injection.
RESULTS
Generation of GFAP phosphorylation site-substitution mutant mice
The N-terminal head domain of GFAP contains multiple phosphorylation sites (Thr7, Ser8, Ser13, Ser17, and Ser38 in the numbering system for human GFAP). Our evidence shows that the head domain of human GFAP is compatible with mice in terms of phosphorylation (Takemura et al., 2002
-actin cDNA fragments as a probe showed that relative amounts of Gfap mRNA in mutant mice were equal to those in the wild-type mice (Fig. 1C).
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Figure 1. Generation of Gfap substitution mutant mice. A, Schemes showing GFAP phosphorylation sites and mutant forms of GFAP. N-terminal amino acid sequences of human, mouse, and chimeric GFAP (Hwt-GFAP) are aligned. Combinations of GFAP phosphorylation sites and substitution mutations are aligned below. Only substituted sites are indicated. Asterisks indicate phosphorylation sites identified. B, Knock-in strategy of the human head domain sequence into the mouse Gfap locus. Open boxes denote exons 1-9. The gray line in the exon 1 represents the human sequence containing mutations in phosphorylation sites. Filled triangles denote loxP sites. The pgk-neo cassette (neo) was removed by the Cre-loxP system to give rise to the Gfaphmx allele. hmx represents hm1, hm2, or hm3. A, ApaI. C, Northern blot analysis of the total brain RNA from adult wild-type (wt), Gfaphm1/hm1 (hm1), Gfaphm2/hm2 (hm2), Gfaphm3/hm3 (hm3), Vim
To verify the mutations in these mice, genomic sequences encoding the head domain were PCR amplified and sequenced. We also examined reactivity of the optic nerves from Gfaphm1/hm1, Gfaphm2/hm2, and Gfaphm3/hm3 to anti-phospho-GFAP monoclonal antibodies, as described previously (Takemura et al., 2002
Distribution of GFAP filaments in mutant brains
When brain sections from adult wild-type and mutant animals were processed for immunohistochemistry, we found no significant differences regarding distribution and density of the cells labeled with anti-S100B antibodies (Fig. 2C,F,I,L; Table 1), which suggested the normal development of astrocytes in all substitution mutants. In the immunohistochemistry for GFAP, we found no differences between wild-type and Gfaphwt/hwt mouse brains, as noted previously (Takemura et al., 2002
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Figure 2. Immunohistochemical detection of GFAP and S100B in mutant mouse brains. Sections of the hippocampus and cerebellum from adult animal brains were stained with anti-GFAP or anti-S100B antibody. A, B, D, E, G, H, J, and K were counterstained with diluted hematoxylin. Note that GFAP immunoreactivity was greatly reduced in the hippocampus but not in the cerebellum of Gfaphm3/hm3 mice. Arrows indicate GFAP signals surrounding blood vessels. S100B immunoreactivity was not changed in the hippocampi of all genotypes (C, F, I, L). py, Pyramidal cell layer; gr, granule cell layer; ml, molecular layer. Scale bar, 200 µm.
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Table 1. Number of astrocytes bearing S100B-positive or GFAP-positive processes in corresponding hippocampal sections of mutant mice Compensation of Hm3-GFAP by vimentin
Subventricular zone astrocytes and Bergmann glia express vimentin, which assembles together with GFAP into glial filaments. We predicted that vimentin masked the deficits of Hm3-GFAP in these subsets, although the mutations did not alter expression of vimentin, as was similar to the case for GFAP null mutant mice (Gomi et al., 1995
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Figure 3. Vimentin-dependent Hm3-GFAP filament formation in the mouse brain. Sections of the hippocampus and cerebellum from adult animal brains of indicated genotypes were stained with anti-GFAP, anti-vimentin, or anti-S100B antibody. B-D, F-H, J-L, and N-P were counterstained with diluted hematoxylin. Note that Hm3-GFAP does not form filaments in the cerebellar cortex in the absence of vimentin. py, Pyramidal cell layer; gr, granule cell layer; ml, molecular layer. Scale bar: A, B, E, F, I, J, M, N, 200 µm; C, D, G, H, K, L, O, P, 100 µm.
Amounts of GFAP were decreased in Gfaphm1/hm1and Gfaphm3/hm3 but not in Gfaphm2/hm2 mice
Results of immunohistochemical analyses showed that the quantity of GFAP changed in brains of mutant mice. We estimated amounts of GFAP by immunoblotting of total protein samples prepared from whole brains of these mice. The same blots were subjected to analysis with an anti-actin antibody to normalize the amounts of loaded proteins. Immunoblots with a pan-GFAP antibody detected lower molecular weight products in substitution mutants in addition to intact GFAP. As discussed below, the lower molecular weight products were proteins lacking N-terminal sequences. The ratio of truncated/intact products was small in Gfaphm1/hm1 (7.6% of total) and Gfaphm2/hm2 (8.5% of total) mice but relatively large (21.2% of total) in Gfaphm3/hm3 mice. The amount of intact GFAP in Gfaphm2/hm2 and Vim
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Figure 4. Effects of the mutations on GFAP amounts in brains. A, Immunoblot with anti-GFAP or actin antibody using total protein from whole brains of adult wild-type (wt), Gfaphm1/hm1 (hm1), Gfaphm2/hm2 (hm2), Gfaphm3/hm3 (hm3), Vim
Glial filaments in primary cultured astrocytes
To further characterize the substituted GFAP in glial filament formation, we prepared primary cultured astrocytes from wild-type, Gfaphm3/hm3, Gfaphm3/hm3:Vim
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Figure 5. Abnormal aggregate formation of Hm3-GFAP in vimentin-deficient astrocytes. Primary cultured astrocytes were prepared from wild-type (A), Gfaphm3/hm3 (B), Vim
Cultured astrocytes as well as reactive astrocytes in injured brains express nestin as the third component of astroglial IF. Immunohistochemistry using anti-nestin antibodies revealed unaltered nestin filaments in Gfaphm3/hm3 astrocytes but a disappearance in Vim
Metabolism of Hm3-GFAP
We compared the turnover of 35S-methionine pulse-labeled wild-type, Hwt-GFAP and Hm3-GFAP in primary cultured astrocytes. After 15 min of pulse labeling, cells were cultured for different periods in nonradioactive medium. The labeled cells were fractionated into cytoskeletal and cytosolic components. Cytoskeletal fractions and immunoprecipitates with anti-GFAP antibodies from cytosolic fractions were analyzed using SDS-PAGE and then autoradiography (Fig. 6). The same samples were also subjected to immunoblots using anti-pan GFAP antibodies to assess total amounts of GFAP. Because significant differences between wild-type and Hwt-GFAP were not observed, data from both samples were combined for statistical analysis. Turnover of Hm3-GFAP tended to be more rapid than that of wild-type GFAP (Fig. 7A), albeit with no statistical significance. In both types of cultures, amounts of radioactive GFAP in cytoskeletal fractions were larger at 1 hr after labeling than at 0 hr. In contrast, amounts of GFAP immunoprecipitated from cytosolic fractions were smaller at 1 hr after labeling than at 0 hr. These results suggested that a large population of newly synthesized GFAP was integrated into glial filaments over a 1 hr period. When we analyzed the influence of substitution mutation in the absence of vimentin, we observed a huge difference between Hm3-GFAP and wild-type GFAP. In the absence of vimentin, turnover of Hm3-GFAP was rapid compared with that of wild-type GFAP in both cytoskeletal and cytosolic fractions (Figs. 6, 7). The ratios of de novo synthesized GFAP to original GFAP in cytosolic and in cytoskeletal fractions (Fig. 7B) were higher in Gfaphm3/hm3:Vim
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Figure 6. Pulse-chase experiments of GFAP. Primary cultured astrocytes prepared from wild-type (A, F), Gfaphwt/hwt (B, G), Gfaphm3/hm3 (C, H), Vim
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Figure 7. Rapid turnover of Hm3-GFAP in the absence of vimentin. Data from pulse-chase experiments using primary cultured astrocytes of control (diamonds; n = 10), Gfaphm3/hm3 (squares; n = 6), Vim
DISCUSSION
To gain insight into the role of GFAP phosphorylation in the brain, we generated three lines of knock-in mice, all of which expressed mutated forms of GFAP carrying the human head domain sequence containing different combinations of substitution of Ala for Ser/Thr at phosphorylation sites. These mutations differentially affected the stability of the proteins and of filament formation, indicating the role of GFAP phosphorylation in dynamics of glial filaments.
The Gfaphm1/hm1 mouse has substitution mutations at Rho kinase-dependent phosphorylation sites. This combination of mutations was reported to impair segregation of glial filaments into daughter cells in cytokinesis (Yasui et al., 1998
We observed severe reductions in GFAP immunoreactivity, indicating poor filament formation, and in amounts of GFAP in the brains of Gfaphm3/hm3 mice, which carry substitutions in all phosphorylation sites at the head domain. Because the mutation in Gfaphm3/hm3 mice did not alter the levels of Gfap mRNA (Fig. 1C), either the slowing of translation and/or accelerating degradation might lead to a decrease in amounts of GFAP. However, it should be noted that GFAP immunoreactivity was not affected in cerebellar Bergmann glia and some other subsets of astrocytes in Gfaphm3/hm3 mice. Thus, it was unlikely that the decrease of GFAP was caused by the general translational problem of the mutated gene. Bergmann glia and other cells that showed significant GFAP-immunoreactivities in the Gfaphm3/hm3 mice coexpress vimentin. Vimentin, as well as GFAP, belongs to the type III IF protein subfamily and can form glial filaments together with GFAP. This suggested that vimentin in part compensated for deficits in Hm3-GFAP in filament formation and stability. To test this possibility, we prepared double-mutant (Gfaphm3/hm3:Vim
Cooperation between vimentin and GFAP was further emphasized in cell culture studies of double-mutant astrocytes. Most cultured astrocytes coexpress vimentin and GFAP. Hm3-GFAP formed filaments indistinguishable from those in wild-type astrocytes, in the presence of vimentin (Fig. 7A). On the contrary, in the absence of vimentin, wild-type GFAP formed slightly irregularly shaped and sometimes truncated filaments (Fig. 5C), as reported previously (Galou et al., 1996
It has been reported that two types of proteolytic mechanisms are involved in the degradation of IF proteins. There is evidence that ubiquitination is involved in degradation of keratin 8 and 18 and that phosphorylation of keratin 8 regulates ubiquitination-mediated turnover of keratins (Ku et al., 2000
Interestingly, Gfaphm1/hm1 and Gfaphm2/hm2 mice showed milder and differential phenotypes. Gfaphm1/hm1 mice, which carried substitutions at Thr7, Ser13, and Ser38, showed a decrease in amounts of GFAP but unaltered immunoreactivity in histochemistry. On the contrary, Gfaphm2/hm2 mice, which carried substitutions at Ser13, Ser17, and Ser38, did not show significant decreases in amounts of GFAP but did show abnormality in immunohistochemistry. These results suggest that Thr7 and Ser17 and perhaps each of other phosphorylation sites has a differential impact on distinct dynamic states of GFAP, i.e., degradation, filament formation, and probably also intracellular transportation. Combinations of these distinct phospho-residues might determine the entire dynamics of GFAP.
The present findings suggest that phosphorylation contributes to stabilization of GFAP in both cytosolic and cytoskeletal fractions. Data on in vitro reconstruction experiments suggested that phosphorylation disassembles GFAP filaments and dephosphorylated forms have a greater potential to assemble (Inagaki et al., 1990
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Figure 8. A proposed model for the role of GFAP phosphorylation. GFAP phosphorylation may play a dual role. The phosphorylation protects GFAP from proteolysis and contributes to shift soluble-filament equilibrium to the left. The larger pool of soluble subunits protected by phosphorylation and partial depolymerization of filamentous subunits triggered by phosphorylation will synergistically accelerate the structural plasticity of glial filaments.
FOOTNOTES Received March 20, 2002; revised May 15, 2002; accepted May 24, 2002.
This work was supported in part by a grant from the Ministry of Welfare (S.I.). M.T. is supported by the Junior Research Associate Program at RIKEN. We thank M. Inagaki for providing human GFAP cDNA and anti-phospho-GFAP and anti-vimentin monoclonal antibodies, M. Hooper, M. Rudnicki, S. Aizawa, and J.-I. Miyazaki for providing E14 ES cell line, pgk-neo, pMC1-DTA, and CAG-Cre transgenic mice, respectively, and T. Yamanaka for assistance in the early stage of this work. We thank all members of our laboratories and M. Murate for helpful discussions and technical advice, K. Inoue, T. Iwasato, H. Nishiyama, and H. Kanki for critical comments on this manuscript, and M. Ohara for editing and language assistance. M.T. thanks K. Ito for continuous encouragement.
Correspondence should be address to Dr. Shigeyoshi Itohara, Laboratory for Behavioral Genetics, RIKEN Brain Science Institute, 2-1 Hirosawa, Wako 351-0198, Japan. E-mail: sitohara{at}brain.riken.go.jp.
H. Gomi's present address: Institute for Molecular and Cellular Regulation, Gunma University, 3-39-15 Showa, Maebashi 371-8512, Japan.
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