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J Biol Chem, Vol. 274, Issue 52, 37200-37209, December 24, 1999
From the GAD67, the larger isoform of the Glutamic acid decarboxylase
(GAD)1 (EC 4.1.1.15) is the
key enzyme in the synthesis of Mammalian species express two isoforms of GAD designated GAD65 and
GAD67 in accordance with their relative molecular masses in kDa (3, 5,
6). GAD65 and GAD67 are highly conserved in evolution. Although the two
proteins differ substantially in the first 95 NH2-terminal
amino acids, they share a significant homology in the remaining part of
the molecule, which contains the catalytic portion of the enzyme
(~78% identity, ~95% similarity). GAD65 and GAD67 show
significant differences in their levels of expression in different
brain regions and steady state saturation with the co-enzyme pyridoxal
5'-phosphate (PLP) (1). More than half of GAD in rat brain is present
as the PLP-free apoenzyme (7, 8), and GAD65 constitutes the majority of
this reservoir (9-11). GAD67 constitutes a small fraction of the
apo-GAD reservoir in the brain (11) and is predominantly found as a
holoenzyme tightly associated with PLP (9-11). GAD65, but not GAD67,
is a major target of autoimmune responses directed against pancreatic Most biochemical studies on the quaternary structure of purified GAD
are consistent with the idea that the basic subunit structure is
dimeric (1, 15). High resolution mapping of conformational epitopes in
GAD65, together with two- and three-dimensional structure prediction
and alignment of structural folds with decarboxylases of known
structure, resulted in a model of the GAD65 dimer (16). In this model,
the two GAD65 subunits are joined in the middle region (amino acids
201-461) and related by a P21 symmetry. In a separate
analysis, several residues in the middle domain were predicted to reach
into the cofactor-binding site of the other subunit and interact
directly with the phosphate group of PLP and with residues in the other
subunit of the enzyme (17). Thus, the middle domains of GAD65 and GAD67
seem to be responsible for the basic homodimeric structure of the
enzyme. GAD65 and GAD67 can also associate with each other to form
heterodimers (9, 18, 19), and this association has been attributed to
the NH2-terminal domain of GAD65 (18). It is estimated that
GAD65/GAD67 heterodimers constitute ~28% of the total GAD activity
in cerebellar membranes (19).
Both GAD65 and GAD67 are synthesized in the cytosol as hydrophilic and
soluble molecules (20). GAD65 undergoes a stepwise post-translational
modification in the NH2-terminal domain to become
hydrophobic and then reversibly membrane-anchored to synaptic-like microvesicles in GAD67 has both distinct and similar subcellular localizations. In rat
In the present study, we have addressed the role of GAD65-GAD67
heterodimerization in the subcellular targeting and membrane anchoring
of GAD67. We demonstrate that formation of GAD65/67 heterodimers is
specific and does not involve nonspecific formation of disulfide-linked
bridges between any domains of the proteins. Furthermore, a soluble
mutant of GAD65 can be targeted to membranes by dimerization with
wild-type protein, suggesting that membrane anchoring of one GAD65
subunit is sufficient for membrane localization of the GAD65 dimer and
supporting the notion that membrane anchoring of soluble GAD67 can be
mediated by its association with GAD65. Analyses of GAD65 Antibodies
The GAD65-specific mouse monoclonal antibodies, GAD6 (27), which
recognizes a linear epitope localized in the last 41 amino acids of
GAD65 (28), and FL-17 (a gift from Dr. Manfred Ziegler), which
recognizes a linear epitope in the first 8 amino acids of GAD65,2 were used in the
immunoprecipitation experiments. The 1701 rabbit antiserum was raised
against a 19-amino acid peptide in the COOH terminus of rat GAD67 and
recognizes GAD65 and GAD67 equally well on Western blots (28). The
following antibodies were used in immunofluorescence experiments: (i)
the GAD65-specific human monoclonal antibodies MICA 2, 3, and 6, derived from islet cell antibody positive patients, were a gift from
Dr. Wiltrud Richter (29); (ii) K2 rabbit antiserum, which recognizes
primarily GAD67 on Western blots (9), was purchased from Chemicon
(Temecule, CA); (iii) a mouse monoclonal antibody against the SV2
antigen in synaptic vesicle membrane (30) was kindly donated by Drs.
Peter Sargent and Regis Kelly (University of California, San
Francisco). All secondary antibodies used in immunofluorescence
experiments were purchased from Jackson Immunoresearch Laboratories
(West Grove, PA).
Expression of Wild-type and Mutant Proteins in COS-7 Cells
Wild-type rat GAD65, a deletion mutant of rGAD65 lacking amino
acids 1-38 and having the palmitoylation site, Cys45,
mutated to Ala (rGAD65/45A Detergent Extraction of COS-7 Cells and Brain
Transfected COS-7 cells from an 80-90% confluent 10-cm plate
were washed twice in ice-cold cell harvesting buffer (20 mM
Hepes/NaOH, pH 7.4, 150 mM NaCl, 10 mM
benzamidine/HCl) and extracted by incubation on a shaker for 1 h
at 4 °C in 0.5 ml of hypotonic Hepes buffer (HMAP buffer) (10 mM Hepes/NaOH, pH 7.4, 1 mM MgCl2,
1 mM 2-aminoethylisothiouronium bromide, 0.2 mM
PLP, 5 mM EDTA, 0.1 mM
p-chloromercuriphenyl sulfonic acid, 1 µg/ml leupeptin, 1 mM phenylmethylsulfonyl fluoride, 10 mM
benzamidine, 0.1 mM Na3VO4, 5 mM NaF, and 5 mM N-ethylmaleimide (NEM)) containing 1% Triton X-114. The lysate was centrifuged at
150,000 × g for 30 min to remove insoluble debris.
Subcellular Fractionation
Subcellular fractionation of cells was carried out using a
modification of methods described previously (26). All procedures were
carried out at 4 °C. Transfected COS-7 cells, grown to 80-90% confluency in a 10-cm plate, were washed twice in ice-cold cell harvesting buffer and homogenized on ice using a glass homogenizer with
0.5 ml of HMAP buffer. The homogenate was centrifuged at 800 g for 10 min to remove nuclei and cellular debris. The
postnuclear supernatant was centrifuged at 150,000 × g
for 1 h in a TLA 100.3 rotor using a Beckman tabletop
ultracentrifuge (Beckman, Palo Alto, CA) to separate cytosol and crude
membrane fractions. Sedimented membranes were resuspended in 0.5 ml of
membrane washing buffer (HMAP buffer containing 0.5 M NaCl)
and incubated for 1 h, followed by ultracentrifugation at
150,000 × g for 1 h to pellet the washed membranes. Washed membranes were extracted for 1 h with 0.5 ml of
extraction buffer (HMAP buffer containing 150 mM NaCl and
1% Triton X-114) followed by centrifugation for 1 h at
150,000 × g to separate particulate extract from
insoluble debris.
For the subcellular fractionation of rat and mouse brain, Harlan
Sprague Dawley male rats (250-300 g) were anesthetized with metofane,
and the cerebral cortex and cerebellum were dissected quickly. A 15%
(w/v) portion of tissue in HMAP buffer was homogenized with the use of
a Tissumizer polytron (Tekmar, Cincinnati, OH). The rest of the
procedure was carried out as described above for COS-7 cells.
Triton X-114 Phase Separations
Triton X-114 partitioning assays were performed on the
subcellular fractions of mouse brain using a modification of the
procedure of Bordier (31). For comparative analyses of the amphiphilic properties of GAD65 and GAD67 in subcellular fractions, buffer compositions were adjusted to achieve identical conditions in each
fraction. Aliquots of each fraction were subjected to three rounds of
temperature-induced phase transitions using 1% Triton X-114. Following
the incubation at 37 °C for 5 min, the detergent and aqueous phases
were separated by centrifugation at 12,000 × g for 2 min at room temperature. The detergent phase from the first and second
rounds of phase separations was washed carefully with HMAP buffer
containing 150 mM NaCl and resuspended with the same buffer
to the original volume. Triton X-114 was added to the aqueous phase
obtained after the third round of phase separation to a final
concentration of 1%.
Immunoprecipitations
For the immunoprecipitation of GAD65 from cell-free extracts of
transfected COS-7 cells, an aliquot of 250 µl from each extract was
incubated with 30 µl of the GAD65-specific monoclonal antibody, FL-17, for 2 h at 4 °C with constant shaking. Immunocomplexes were isolated by incubation for 1 h at 4 °C with 50 µl of
50% solution of protein G-Sepharose (PGS; Amersham Pharmacia Biotech, Uppsala, Sweden) in immunoprecipitation buffer (IP buffer, 10 mM Hepes/NaOH, pH 7.4, 150 mM NaCl, 5 mM EDTA, 0.1 g/liter bovine serum albumin, 10 mM benzamidine, and 0.5% Triton X-114). For the
immunoprecipitation of GAD65 from rat brain subcellular fractions, 100-µl aliquots from each of the cytosol and membrane extracts were
diluted 5-fold in HMAP buffer containing 1% Triton X-114 and 150 mM NaCl and precleared by incubation for 30 min at 4 °C with 100 µl of preswollen protein A-Sepharose (PAS; Amersham
Pharmacia Biotech) in IP buffer. Samples were then centrifuged at
750 × g for 1 min, and the resulting supernatants were
incubated with 5 µl of GAD6 ascites. After 3 h of incubation at
4 °C with constant shaking, immunocomplexes were isolated by
incubation with 100 µl of preswollen PAS for 1 h at 4 °C. The
PGS- or PAS-bound immunocomplexes were washed five times with IP
buffer, and proteins were eluted from PGS or PAS by boiling for 5 min
in SDS-sample buffer followed by centrifugation to remove PAS or
PGS.
Electrophoresis and Immunoblotting
To estimate the subunit composition of native GAD65 transiently
expressed in COS-7 cells, samples from the cell lysate obtained after
removing the cell debris were pretreated in nondenaturing and
nonreducing sample buffer (0.3 M Tris-HCl, pH 8.8, 0.003% bromphenol blue, 10% glycerol) and then analyzed by electrophoresis on
a native precast 10 or 4-20% linear gradient of polyacrylamide gels
(Novex, San Diego, CA). Standard molecular mass proteins for native
gels were from Amersham Pharmacia Biotech and consisted of
thyroglobulin (669 kDa), ferritin (440 kDa), catalase (232 kDa),
lactate dehydrogenase (140 kDa), and albumin (67 kDa). For the analysis
under nonreducing conditions to test the presence of disulfide-linked
multimers of GAD65, samples were boiled for 3 min in sample buffer
containing 2% SDS without reducing agent and then analyzed by SDS-PAGE
on 10% polyacrylamide gels. For quantitative analyses of the ratio of
GAD65 and GAD67 in immunoprecipitates and in cytosol and membrane
fractions of brain, serial dilutions of each fraction were subjected to
SDS-PAGE.
Resolved proteins were transferred from gels by Western blotting to
Protran BA nitrocellulose transfer membranes (Schleicher and Schuell).
All procedures were carried out at room temperature. The blots were
blocked for 1 h in 10% nonfat dry milk, TBST buffer (20 mM Tris buffer, pH 7.4, 150 mM NaCl, and 0.1%
Tween 20). After two 5-min washes with TBST, the blots were probed for
1 h with the 1701 antibody (1:5000 dilution in 5% milk, TBST),
followed by three 5-min washes with TBST. The blots were then incubated for 30 min with horseradish peroxidase-conjugated donkey anti-rabbit IgG (Amersham Pharmacia Biotech) at a 1:8000 dilution in TBST. After
three 5-min washes with TBS, 0.3% Tween 20 and three 5-min washes with
TBST, bands were detected using enhanced chemiluminescence reagent
(ECL; Amersham Pharmacia Biotech). For quantitative analyses, images
made on Kodak X-Omat film were obtained at various times of exposure,
and the percentages of GAD65 and GAD67 were determined from the linear
range of the standard curve. Scanning of autoradiograms was performed
using the DeskScan II program on a Hewlett Packard ScanJet IIcx.
Densitometric analysis was performed using NIH Image software.
Cell Cultures of Cortical and Hippocampal Neurons
Cortical Neurons--
Primary cultures of dissociated cerebral
cortical neurons were prepared from the brains of 18-day-old mouse
fetuses, which were recovered by caesarean section under metofane
anesthetic. Heterozygous (GAD65+/ Hippocampal Neurons--
Hippocampi of P0 Harlan Sprague Dawley
rat pups were removed, and the dentate gyri were grossly dissected.
Cells derived from the remaining tissue were plated as described by
Lester et al. (33) except that papain was not used.
B27-supplemented primary hippocampal cultures were prepared as
described by Brewer et al. (32), and a 50 units/ml
concentration of both streptomycin and penicillin were added. One-half
of the growth medium was exchanged 1 day after plating and weekly thereafter.
Immunofluorescence Analyses
After 2 weeks of growth, cultures were fixed with 4%
paraformaldehyde in phosphate-buffered saline for 15 min at room
temperature. All of the subsequent steps were carried out at room
temperature. Permeabilization of the cells and blocking of nonspecific
binding were performed by incubation for 20 min with 1% bovine serum
albumin, 0.1% Triton X-100 in phosphate-buffered saline (blocking
buffer). For co-localization of both GAD65 and GAD67 in rat hippocampal neurons, the human monoclonal antibodies to GAD65 (MICA 2, 3, and 6, diluted 1:250) along with rabbit antibodies to GAD67 (K2, diluted
1:250) were applied in blocking buffer. After 1 h of incubation, immunoreactivity was visualized by secondary antibody staining using
donkey anti-human IgG conjugated to Cy3 and goat anti-rabbit IgG
conjugated to fluorescein isothiocyanate. For co-localization of GAD65
and GAD67 proteins with the synaptic marker SV2, triple immunostaining
was performed using mouse monoclonal anti-SV2 (diluted 1:200) in
addition to the antibodies to GAD65 and GAD67. SV2 was visualized using
donkey anti-mouse IgG conjugated to
7-amino-4-methylcoumarin-3- acetic acid. For the
localization of GAD67 and SV2 in mouse cortical neurons, the rabbit
antibodies to GAD67 along with the mouse antibodies to SV2 were applied
in blocking buffer, followed by the donkey anti-rabbit IgG conjugated
to Cy3 and goat anti-mouse IgG conjugated to fluorescein
isothiocyanate. Identification of GAD clusters and their
co-localization with synaptic markers was accomplished with dual color
microscopy using a Nikon × 100 objective (NA 1.4), mercury arc
lamp illumination and standard fluorescein and Cy3 filter sets (Omega).
Fluorescent images were acquired using a cooled digital CCD camera
(Princeton Instruments, Inc.). Minimal bleed-through between channels
was confirmed by imaging single-labeled specimens. 12-bit images were
linearly written to 8-bit data set after normalizing images to maximize
usable contrast range using IPLAP Spectrum software (Sygnal Analytics).
For display in figures, monochrome and merged colors were processed
using Adobe Photoshop software (Adobe Systems, San Jose, CA). In
unprocessed raw 8-bit data, synaptic structures (identified as
SV2-positive puncta) were considered co-localized with GAD if the
intensity of immunoreactivity was >2-fold higher than the background
level. Most GAD-positive synaptic structures had fluorescence
intensities >4-fold higher than background.
Genotyping of mGAD65 Mice
DNA extracted from tail biopsies was used as a template for PCR.
The following PCR primers were used in one reaction to look simultaneously at the endogenous and targeted alleles: GAD65 promoter sense primer (5'-CAA ACA CGC ACG AGC ACT GGC-3'), GAD65 intron 1 antisense primer (5'-CAG TTA CGG ACT TAA CCC AGA G-3'), and phosphoglycerate kinase promoter antisense primer (5'-GAA AAG CGC CTC
CCC TAC CCG GTA G-3'). The expected polymerase chain reaction products
are as follows: (i) endogenous allele fragment of 430 bp (wild type,
+/+); (ii) endogenous allele fragment of 430 bp plus targeted allele
fragment of 260 bp (heterozygous, +/ Specific and Nonspecific Oligomerization of GAD65 and
GAD67--
Each of the GAD isoforms contains a large number of
cysteine residues, suggesting a propensity for forming nonspecific
disulfide bridges in nonreducing in vitro environment. It
was therefore important to establish conditions for maintaining the
native structure of the proteins during analysis.
In analyses of the oligomerization state of GAD65 expressed in COS-7
cells using SDS-gel electrophoresis in the presence or absence of
Since the presence of alkylating reagents during the preparation of
samples inhibited the formation of nonspecific disulfide bridges, all
subsequent studies of GAD oligomerization were performed in the
presence of 5 mM NEM. In these conditions, the native form of wild-type rGAD65 is a noncovalently linked dimer in both the cytosol
and membrane fractions of COS-7 cells, as revealed by nondenaturing gel
electrophoresis under nonreducing (Fig. 1D) and reducing
conditions (results not shown). The native subunit structure of rGAD65
expressed in COS-7 cells did not change when lysis of cells was
performed in the presence or absence of 200 µM of the
coenzyme PLP or in the presence or absence of 10 mM L-glutamate (data not shown). This is in contrast to
results obtained for Escherichia coli GAD65, in which the
dimer assembly to form a hexamer is enhanced by the addition of PLP
(35).
A Membrane-anchoring GAD65 Subunit Mediates a Robust Membrane
Association of a Soluble Subunit by Dimerization--
If soluble GAD67
associates with membranes by heterodimerization with a
membrane-anchored GAD65 subunit as suggested by Dirkx et al.
(18), this would imply that membrane anchoring of only one GAD65
subunit suffices to achieve membrane association of a homo- or
heterodimer. To test this possibility, we first addressed the question
whether soluble mutants of GAD65, lacking the membrane-anchoring NH2-terminal region, can form dimers. As shown in Fig.
1D (lanes 4 and 5), the deletion
mutants rGAD65/45A
We next addressed the question whether wild-type rGAD65 and the
rGAD65/45A
These results show that a firm membrane anchoring of a dimer only
requires tethering of one GAD65 subunit to membranes. We have
previously shown that the two subunits in a GAD65 dimer undergo distinct post-translational modifications and that only one is phosphorylated in membranes (25). Thus, the two subunits in the GAD65
dimer are not identical and probably serve distinct roles in regulation
of membrane trafficking of the protein.
A Pool of Rat Brain GAD67 Forms a Noncovalently Linked Dimer with
GAD65 in the Cytosol and Membrane Fractions, and Dimerization Does Not
Involve the NH2-terminal Region of GAD65--
The
formation of heterodimers between GAD65 and GAD67 (18, 19) was
suggested to involve the NH2-terminal region of GAD65 (18).
Thus, dimerization with and membrane tethering of soluble GAD67 was
suggested to be mediated by the same region of GAD65 (18).
Dirkx et al. (18) showed that heterodimerization with GAD67
does not involve formation of nonspecific disulfide bridges through
cysteines in the NH2-terminal region of GAD65. However, the
possibility that a population of GAD65/GAD67 heterodimers detected
in vitro is formed by nonspecific formation of disulfide bridges involving other regions of GAD65 was not addressed. We therefore studied the heterodimerization of GAD65 and GAD67 in the
presence of 5 mM NEM during lysis and subcellular
fractionation of cells and subsequent immunoprecipitation to prevent
the formation of nonspecific disulfide bridges between any parts of the
two proteins.
GAD67 was detected in both cytosol and membrane fractions of rat brain
(Fig. 3A, lanes 1 and 5), confirming that in neurons both GAD65 and GAD67 are
associated with membranes (18, 19). Furthermore, GAD67 was recovered in
immunoprecipitates with a GAD65-specific antibody, GAD6, in both
cytosol and membrane fractions, demonstrating that the two proteins
specifically associate into dimers (Fig. 3A, lanes
2-4 and 6-8). Similar results were obtained using the
anti-GAD65-specific monoclonal antibody FL-17, which is directed
against the first 8 amino acids of GAD65 (data not shown). The identity
of the two isoforms in the Western blot (Fig. 3A) was
confirmed by stripping bound antibodies and reprobing the blot first
with the anti-GAD67-specific antibody, K2, and then with the
anti-GAD65-specific antibody, FL-27 (data not shown).
To study the role of the NH2-terminal region of GAD65 in
the formation of heterodimers, we tested whether the
NH2-terminal deletion mutants of this isoform can associate
with GAD67. The rGAD65/45A GAD67 Is Associated with Membrane Fractions Independent of
GAD65--
The results shown above are consistent with an ability of
GAD65 to mediate membrane anchoring of GAD67 in a heterodimer.
Densitometric analyses of total GAD67 and GAD67 in a complex with GAD65
(GAD6 immunoprecipitate) obtained from three independent rat brain
extracts (a representative immunoblot is shown in Fig. 3A),
however, indicate that while the ratio between GAD65 and GAD67 is about
1:1 in membrane fractions prepared from rat cerebellum/cerebral cortex
(Fig. 3A, lanes 1 and 5), the ratio in
immunoprecipitates of GAD65 from those fractions (Fig. 3A,
lanes 4 and 8) is approximately 3:1. Similar
ratios between GAD65 and GAD67 were obtained for membrane fractions
prepared from three extracts of mouse cerebellum/cerebral cortex (a
representative blot is shown in Fig. 4,
lanes 1 and 3). These results suggest that
approximately 33% of GAD67 in membrane fractions of rat and mouse
brain is present as a heterodimer with GAD65, consistent with results
obtained with rat cerebellar membranes in the absence of alkylating
reagents (19). Thus, the majority of GAD67 appears to reside in
membranes as a homodimer independent of dimerization with GAD65,
suggesting that GAD67 can become membrane-anchored by a mechanism
distinct from dimerization with GAD65.
To clarify whether GAD67 is strictly dependent on GAD65 for its
localization to membranes, the subcellular distribution of GAD67 was
analyzed in the brains of GAD65 knock-out mice (GAD65
GAD67 is hydrophilic in rat islets and transfected fibroblasts (20, 22,
23). To test whether the membrane association of GAD67 is mediated by a
specific hydrophobic modification of the protein in neurons, we
assessed the ability of GAD67 in cytosol and membrane fractions of
mouse brain to partition into the detergent phase following a
temperature-induced Triton X-114 phase separation. Whereas a portion of
GAD67 in both cytosolic and membrane fractions prepared from wild-type
(GAD65+/+) mouse brains partitioned into the detergent phase (Fig.
5, lanes 2 and 6),
all GAD67 remained in the aqueous phase in the absence of GAD65 (Fig.
5, lanes 3, 7, and 11), suggesting (i)
that the partition of GAD67 into the detergent phase is mediated by its
association with GAD65 in a heterodimer and (ii) that GAD67 is not by
itself hydrophobic. Densitometric analysis of the immunoblot (Fig. 5,
lanes 2 and 6) demonstrates that the ratio
between GAD65 and GAD67 is approximately 3:1 and 2.6:1 in the detergent
phase of the cytosolic and membrane fractions, respectively. Since
these ratios are similar to that obtained for immunoprecipitates of
GAD65 from cytosolic and membrane fractions of rat brain (Fig.
3A, lanes 4 and 8), we conclude that association with GAD65 accounts for approximately all GAD67 found in
the detergent phase of the cytosol and membrane fractions prepared from
wild-type mouse brain. These results suggest that the association of
GAD67 to membranes in the GAD65 knock-out mouse brain is not mediated
by its own hydrophobicity but rather by interaction with membrane
components that are distinct from GAD65 and do not confer hydrophobicity upon GAD67.
We next addressed the question whether GAD67 can mediate membrane
association of GAD65 mutants (rGAD65/45A GAD67 Localization to Nerve Terminals in Primary Cultures of
Neurons Is Independent of GAD65--
It has been suggested that the
association of GAD67 with synaptic vesicles from rat brain and its
localization to nerve terminals of GABA-ergic neurons, where synaptic
vesicles are clustered, is mediated by its interaction with GAD65 (18,
36). However, GAD67 was also found to localize to the terminals of
dentate granule cells of the hippocampus, which contain little or no
GAD65 (37). To examine the role of GAD65 in targeting GAD67 to nerve
terminals, we studied the localization of GAD67 in cultured rat
hippocampal neurons and mouse cortical neurons prepared from wild-type
embryos, where GAD67 is expressed together with GAD65, and in cultured cortical neurons prepared from GAD65 deficient mouse embryos, where
GAD67 is expressed alone.
Double immunostaining of 2-week-old primary cultured rat hippocampal
neurons with anti-GAD67 and anti-GAD65 antibodies revealed that in
addition to its diffuse distribution in the cell body and proximal
dendrites, a pool of GAD67 co-localized with GAD65 in the perinuclear
region and in punctate structures (Fig.
6). The punctate structure localization
of GAD65 and GAD67 was demonstrated to correspond to axon terminals by
triple labeling with the antibodies directed against the synaptic
vesicle protein SV2 (Fig. 7,
white color). Immunostaining of 2-week-old
primary cultured cortical neurons prepared from homozygous mutant mouse
embryos (GAD65
We also performed immunostaining of primary cultures of cortical
neurons obtained from homozygous mutant GAD67 Targeting to Nerve Terminals and Membrane Anchoring Is an Intrinsic
Property of GAD67--
The evolution of two different isoforms of
glutamic acid decarboxylase in mammals provides a fundamental aspect of
regulation of GABA-ergic neurotransmission. This is best evidenced by
the distinct phenotypes of GAD65 GAD65 and GAD67 Form Specific Noncovalently Linked
Heterodimers--
The native forms of both GAD65 and GAD67 are
noncovalently linked homodimers (Ref. 19 and results presented here).
However, because of the large number of cysteines, each isoform has a
tendency to form nonspecific disulfide-linked dimers and multimers
in vitro (Ref. 34 and results presented here). In view of
this phenomenon, it was important to establish whether the formation of
heterodimers of the two forms (18, 19) was specific or due to an
in vitro formation of disulfide bridges. Although Dirkx
et al. (18) presented evidence that -SH groups in the
NH2-terminal region of GAD65 were not involved in the
dimerization with GAD67, a role of other sulfhydryl groups was not
assessed. In the present study, the tendency of recombinant GAD65 and
endogenous GAD65 and GAD67 to form disulfide-linked multimers was
almost completely prevented by blocking the reactive cysteines in both
isoforms with the alkylating reagents NEM or iodoacetamide. Under
alkylating conditions, a significant fraction of GAD65 and GAD67 was
still detected as heterodimers, demonstrating that the association
between the two isoforms is specific and does not require nonspecific
formation of disulfides. We therefore conclude that heterodimers of
GAD65/GAD67 are formed in vivo.
Homo- and Heterodimerization of GAD65 Does Not Involve the
NH2-terminal Membrane-anchoring Region--
Molecular
modeling studies have suggested that the middle domain of each subunit
is involved in GAD65 dimerization (16, 17). Since there are no proteins
of known structure that share sequence homology with GAD65 in the first
100 amino acids at the NH2 terminus of GAD65 (16), a
structure prediction is not available for this region. The results
presented here show that the GAD65
Furthermore, the GAD65
The first 101 amino acids of GAD65 are demonstrably not necessary for
heterodimerization. Therefore, in light of the high homology between
GAD65 and GAD67 in the remainder of the molecule, we propose that the
structural interactions involved in heterodimerization may be similar
to those for homodimerization (19).
What Is the Role of GAD65/GAD67 Heterodimerization?--
The
results presented here establish that the two enzymes GAD65 and GAD67
specifically form noncovalently linked heterodimers in addition to
homodimers and that each homodimer associates with membranes. Firm
membrane association of a dimer can be achieved by only one membrane
anchoring-competent GAD65 subunit. This infers that a heterodimer
between a hydrophilic GAD67 subunit and a membrane-anchoring GAD65
subunit can localize to membranes. In contrast, a heterodimer between a
soluble GAD65 subunit and a membrane anchoring-competent GAD67 subunit
does not anchor to membranes. The realization that GAD67 can mediate
its own association to membranes but cannot do so for soluble GAD65
implicates a homodimer-dependent association that is
distinct from that of GAD65. We suggest that the GAD67/GAD67 homodimer
has a distinct microlocalization within membrane compartments of nerve
terminals to the GAD65/GAD65 and GAD65/GAD67 dimers and that this form
can therefore impart different GABA secretion responses.
We thank Dr. Roger Nicoll and Christian
Billante for help in establishing cultures of primary neurons, Dr. Mark
von Zastrow for help with the immunofluorescence analyses, Dr. Wiltrud
Richter for donating the MICA 2, 4, and 6 supernatants, Dr. Mannfred
Ziegler for donating the FL 17 antibody, Dr. Ronald Tisch for mGAD65
cDNA, and Dr. Allan Tobin for a human GAD65 cDNA.
*
This work was supported by National Institutes of Health
Grants DK41822 and DK47043 and an American Diabetes Association Mentor Based Postdoctoral Fellowship (to S. B.).The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
¶
To whom correspondence should be addressed: Hormone
Research Inst., University of California, 513 Parnassus Ave., San
Francisco, CA 94143-0534. Tel.: 415-476-6267; Fax: 415-502-1447;
E-mail: s_baekkeskov@biochem.ucsf.edu.
2
H. Schwartz, F. Lühder, J. Kim, C. Turck,
and S. Baekkeskov, unpublished results.
The abbreviations used are:
GAD, glutamic acid
decarboxylase;
mGAD67, mouse GAD67;
rGAD65, rat GAD65;
GABA,
The Hydrophilic Isoform of Glutamate Decarboxylase, GAD67, Is
Targeted to Membranes and Nerve Terminals Independent of Dimerization
with the Hydrophobic Membrane-anchored Isoform, GAD65*
,, and¶
Hormone Research Institute and Departments
of Medicine and Microbiology/Immunology and the § Department
of Psychiatry, University of California,
San Francisco, California 94143
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-aminobutyric
acid-synthesizing enzyme glutamic acid decarboxylase, is a hydrophilic
soluble molecule, postulated to localize at nerve terminals and
membrane compartments by heterodimerization with the smaller
membrane-anchored isoform GAD65. We here show that the dimerization
region in GAD65 is distinct from the NH2-terminal
membrane-anchoring region and that a membrane anchoring GAD65 subunit
can indeed target a soluble subunit to membrane compartments by
dimerization. However, only a fraction of membrane-bound GAD67 is
engaged in a heterodimer with GAD65 in rat brain. Furthermore, in
GAD65
/ mouse brain, GAD67, which no longer partitions into the
Triton X-114 detergent phase, still anchors to membranes at similar
levels as in wild-type mice. Similarly, in primary cultures of neurons
derived from GAD65/ mice, GAD67 is targeted to nerve terminals,
where it co-localizes with the synaptic vesicle marker SV2. Thus,
axonal targeting and membrane anchoring is an intrinsic property of
GAD67 and does not require GAD65. The results suggest that three
distinct moieties of glutamate decarboxylase localize to membrane
compartments, an amphiphilic GAD65 homodimer, an amphiphilic GAD65/67
heterodimer, tethered to membranes via the GAD65 subunit, and a
hydrophilic GAD67 homodimer, which associates with membranes by a
distinct mechanism.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-aminobutyric acid (GABA) (1). GAD is
expressed at comparable levels in GABA-ergic neurons in the central
nervous system and in the insulin-producing 
cells in the islets of
Langerhans (2, 3). GABA has been established as the major inhibitory
neurotransmitter in the central nervous system, whereas its role in
islet cell function remains elusive (4).
cells in type 1 diabetes (12, 13) and toward GABA-ergic neurons in
a rare disease of the central nervous system, stiff-man syndrome
(14).
cells and synaptic vesicles in neurons (21, 22). A
pool of GAD65 is also detected in the Golgi complex region of neurons,
pancreatic cells, and transfected CHO and COS-7 cells (23, 24). The
nature and significance of the association of GAD65 with membranes is
not well understood. The NH2-terminal domain in GAD65 is
required for membrane anchoring and is the site of two hydrophobic
modifications. One of them involves the thiopalmitoylation of cysteines
30 and 45 (22), whereas the other modification (20) has remained
undefined. GAD65 also undergoes phosphorylation of serines 3, 6, 10, and 13 (25). Although both palmitoylation and phosphorylation
distinguish the membrane-associated from the soluble forms of GAD65,
neither modification is required for membrane anchoring of GAD65 in
COS-7 cells (25, 26). It was also shown that targeting of GAD65 to the
Golgi complex region in transfected CHO cells requires a signal located
in the NH2-terminal region, which is different from
palmitoylation (24).
cells and in transfected rat fibroblasts, GAD67 was found to remain
distributed homogeneously throughout the cell cytosol and was recovered
only in soluble fractions (20, 23). In neurons, GAD67 was detected in
cell bodies and proximal dendrites but also appeared concentrated in
nerve terminals (9) and in the Golgi complex region (18). Furthermore,
a pool of GAD67 was found to be associated with rat brain membrane
fractions and distribute into the Triton X-114 detergent phase (18).
Because GAD67 was only detected as a soluble hydrophilic protein in rat pancreatic islets (20, 22) and in fibroblasts transfected with rat
GAD67 (23), the association of GAD65 and GAD67 into heterodimers was
suggested to confer association of GAD67 with membranes (18, 19).
/ mice,
however, reveal that membrane anchoring and targeting of GAD67 to nerve
terminals is not affected by loss of GAD65 and therefore can also be
effected independently of the GAD65 isoform.
EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1-38), and a deletion mutant of rGAD65 lacking amino acids 1-101 (rGAD651-101) in the COS expression vector pSV-SPORT were described previously (26). A 2.0-kb cDNA for
mouse GAD67 (a gift from Dr. Roland Tisch, University of North Carolina, Chapel Hill) containing the entire coding region and 93 and
181 bp of 5'- and 3'-untranslated sequences, respectively, was excised
from Bluescript II SK± (Stratagene, La Jolla, CA) as an
XhoI-XhoI fragment and subcloned into the
SalI site of the pSV-SPORT vector. COS-7 cells were cultured
and transiently transfected with LipofectAMINE (Life Technologies,
Inc.) as described previously (25).
) and homozygous mutant (GAD65/)
mouse fetuses were obtained by breeding homozygous male (GAD65/)
and heterozygous female (GAD65+/) mice on the 129 × NOD
background as described previously (11). The cortex was dissected from the brains of five fetuses out of seven, and the cultures were prepared
from each cortex separately. In parallel, DNA was extracted from tail
biopsies of the five fetuses and was used later for genotyping (see
below). The cortex was dissected on ice in 2 ml of dissection buffer
(160 mM NaCl, 5 mM KCl, 0.5 mM
MgSO4, 2.9 mM CaCl2, 5 mM Hepes, 5.5 mM glucose, 2 mg/liter phenol
red, pH 7.4). Tissue fragments were added to 5 ml of dissection buffer containing papain (100 units; Worthington), L-cysteine (1 mg), CaCl2 (1 mM), and EDTA (0.5 mM) and incubated for 30 min with constant shaking at
37 °C. Papain digestion was terminated by resuspension of the tissue
fragments in 5 ml of B27/Neurobasal culture medium (Life Technologies,
Inc.) supplemented with 1 mM GlutaMAX I, a 50 units/ml
concentration of both streptomycin and penicillin (32), 12.5 mg of
bovine serum albumin, and 12.5 mg of soybean trypsin inhibitor. After
the tissue had settled, the supernatant was replaced with 1 ml of
culture medium. Individual cells were generated by trituration of the
tissue seven times, each time in 1 ml of culture medium. After the
nondispersed tissue had settled, the supernatants were transferred to a
15-ml tube and centrifuged at 200 × g for 3 min. The
pellet was gently resuspended in culture medium containing 1%
heat-inactivated fetal calf serum to reach a density of 1.7 × 106 cells/ml. Cells were plated on sterile glass coverslips
(2 × 105 cells/coverslip) precoated with
poly-D-lysine (Mr >300,000; Sigma) and collagen (Vitrogen 100, Collagen Corp., Fremont, CA) in 24-well plastic culture dishes (32). Cells were cultured at 37 °C in a
humidified atmosphere of 5% CO2, 95% air. One-half of
the growth medium was exchanged 1 day after plating and every 3 days thereafter.
); (iii) targeted allele fragment
only of 260 bp (homozygous mutant, /).
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-mercaptoethanol (-ME), the protein was detected as a
monomer, dimer, and trimer under nonreducing but denaturing conditions,
whereas under reducing and denaturing conditions all of the protein was
detected as a monomer (Fig.
1A), suggesting the presence
of disulfide-linked bridges. The formation of disulfide-linked dimers
and sometimes trimers was also observed for GAD65 and GAD67 expressed
in mouse and rat brain (Fig. 1C and data not shown). The
formation of disulfide-linked oligomers was, however, significantly diminished or prevented when lysis of COS-7 cells and homogenization of
rat brain was performed in the presence of alkylating reagents (Fig. 1,
B and C). These results strongly suggest that the
formation of disulfide-linked multimers of GAD65 and GAD67 shown here
and described earlier (34) is an artifact generated in
vitro.
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Fig. 1.
Formation of specific and nonspecific
oligomers of recombinant GAD65 and endogenous GAD65 and GAD67.
A, formation of disulfide-linked multimers of GAD65 in COS-7
cell lysates under nonreducing conditions. COS-7 cells expressing
rGAD65 were incubated in SDS-sample buffer with (lanes 1 and
2) or without (lanes 3 and 4) 2.5%
-mercaptoethanol (-ME) either at room temperature
(lanes 2 and 4) or at 100 °C (lanes
1 and 3) for 3 min. The samples were analyzed by
SDS-PAGE followed by immunoblotting using the 1701 antibody.
B, alkylating reagents prevent the formation of
disulfide-linked multimers of GAD65 in COS-7 cell lysates under
nonreducing conditions. COS-7 cells expressing rGAD65 were harvested
from a 10-cm plate and lysed in 0.5 ml of HMAP buffer containing 1%
TX-114 in the absence (lane 1) or presence of either 5 mM NEM (lane 2) or 100 mM
iodoacetamide (lane 3). Aliquots (5 µl) of a 1:20 dilution
of the cell lysate were boiled for 3 min in sample buffer containing
1% SDS without reducing agent and then analyzed by SDS-PAGE.
Immunoblotting was performed with the 1701 antibody. C,
alkylating reagents prevent the formation of disulfide-linked multimers
of GAD65 and GAD67 in brain membranes. Rat cerebellum and cerebrum
(15%, w/v) were homogenized in HMAP buffer in the absence (lane
1) and presence of 5 mM NEM (lane 2) or 50 mM iodoacetamide (lane 3), and membranes were
prepared as described under "Experimental Procedures." Aliquots of
a TX-114 membrane extract were pretreated in sample buffer containing
1% SDS without reducing agent and analyzed by SDS-PAGE. Immunoblotting
was performed with the 1701 antibody that recognizes both GAD65 and
GAD67. Similar results were obtained for the cytosol fractions.
D, wild-type rGAD65, rGAD65/45A1-38, and rGAD651-101
form noncovalently linked dimers in native conditions. Lanes
1 and 2, cytosol and membrane fractions of COS-7 cells
expressing wild-type rGAD65 prepared in the presence of 5 mM NEM. Lanes 3-5, TX-114 extract of COS-7
cells expressing wild-type rGAD65, rGAD65/45A1-38, or
rGAD651-101. Aliquots of cytosol fraction (lane 1),
membrane fraction (lane 2), or TX-114 extract (lanes
3-5) were boiled for 3 min in nonreducing and nondenaturing
(native) sample buffer and analyzed by electrophoresis on a native 10%
polyacrylamide gel followed by immunoblotting with the 1701 antibody.
1-38 and rGAD651-101, which are soluble when
expressed in COS-7 cells (22, 26), are detected exclusively as
noncovalently linked dimers in native conditions. Thus, the
NH2-terminal 101 amino acids are not involved in the
dimerization of GAD65.
1-38 mutant can form heterodimers when co-expressed in
COS-7 cells. As shown in Fig.
2A, a fraction of
rGAD65/45A1-38 protein was co-immunoprecipitated with wild-type
rGAD65 from lysates of COS-7 cells expressing both proteins using an
antibody that only recognizes wild-type rGAD65, demonstrating that the
two proteins can form a heterodimer. To assess whether the heterodimer
can associate with membranes, subcellular fractions of COS-7 cells expressing one or both proteins were prepared in the presence of
alkylating reagents to prevent formation of nonspecific disulfide bridges following lyses of cells. Densitometric analyses of immunoblots (a representative immunoblot is shown in Fig. 2B) revealed
that while the rGAD65/45A1-38 protein expressed alone is
exclusively localized to the cytosol and membrane wash fractions,
approximately 26% of the mutant protein becomes localized to membrane
fractions in the presence of wild-type rGAD65. Thus, the heterodimer
between the rGAD65/45A1-38 protein and wild-type rGAD65 can become
membrane-anchored.
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Fig. 2.
A fraction of the soluble
rGAD65/45A 1-38 mutant is localized to
membranes by heterodimerization with wild-type rGAD65 in COS-7
cells. A, association of rGAD65/45A1-38 with
wild-type rGAD65. Immunoblotting analysis of wild-type rGAD65 and
rGAD65/45A1-38 in COS-7 cell extracts (lanes 1,
3, and 5) and in immunoprecipitates
(IP, lanes 2, 4, and 6)
with the monoclonal antibody FL-17, which recognizes wild-type rGAD65
but not the deletion mutant. Proteins were resolved by SDS-PAGE and
then subjected to Western blotting and immunostaining using the 1701 antibody. A fraction of rGAD65/45A1-38 is detected in
immunoprecipitates of wild-type rGAD65. B, analyses of
subcellular distribution of rGAD65/45A1-38 in the presence and
absence of wild-type rGAD65. The cytosol proteins, proteins washed from
membranes, and proteins extracted from membranes of COS-7 cells
expressing the wild-type rGAD65, the mutant rGAD65/45A1-38, or both
proteins were boiled for 3 min with SDS-sample buffer and then analyzed
by 10% SDS-PAGE followed by immunoblotting with the 1701 antibody.
rGAD65/45A1-38 is only detected in the cytosol and membrane wash
fractions in the absence of wild-type rGAD65, but it is
membrane-associated in the presence of wild-type rGAD65.
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Fig. 3.
GAD67 forms noncovalently linked heterodimers
with GAD65, and the association does not involve the
NH2-terminal region of GAD65. A, GAD67 is
associated with GAD65 in cytosol and membrane fractions of rat brain.
Immunoblotting analysis of immunoprecipitates of cytosol and membrane
fractions of rat brain using the GAD65-specific monoclonal antibody
GAD6 is shown. Proteins were resolved by SDS-PAGE. Immunoblotting was
performed with the 1701 antibody, which recognizes both GAD65 and
GAD67. IP, immunoprecipitation. GAD67 is co-precipitated
with GAD65 in both cytosol and membrane fractions. B,
heterodimerization does not involve the NH2-terminal region
of GAD65. Immunoblotting analysis of immunoprecipitates of TX-114
extracts of COS-7 cells expressing the deletion mutants
rGAD65/45A 1-38 or rGAD651-101 using the GAD6 antibody is shown.
Proteins were resolved by SDS-PAGE. Immunoblotting was performed with
the 1701 antibody. GAD67 is co-precipitated with both
rGAD65/45A1-38 (lane 6) and rGAD651-101 (lane
10).
1-38 and rGAD651-101 mutants were
each coexpressed with mGAD67 in COS-7 cells and immunoprecipitated with
the GAD65-specific monoclonal antibody GAD6. As shown in Fig.
3B, mGAD67 was co-precipitated with both rGAD65/45A1-38
(lane 6) and rGAD651-101 (lane 10), demonstrating that the NH2-terminal 101 amino acids of
GAD65 are not involved in the heterodimerization with GAD67. Thus,
hetero-/homodimerization and membrane anchoring are mediated by
distinct GAD65 regions.
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Fig. 4.
GAD67 association with membranes in mouse
brain is independent of GAD65. Immunoblotting analysis of cytosol
and membrane fractions prepared from the brain (cerebrum and
cerebellum) of wild-type (GAD65+/+) and GAD65 knockout (GAD65 /)
mice. Before extraction with 1% TX-114, membranes were washed three
times by incubation on ice for 1 h with HMAP buffer containing 0.5 M NaCl. Proteins were resolved by SDS-PAGE. Immunoblotting
was performed using the 1701 antibody.
/). As shown
in Fig. 4, GAD67 was recovered in the extensively washed membrane
fractions prepared from both GAD65-deficient mice (lane 4)
and their wild-type littermates (lane 3). A similar recovery of GAD67 was observed in membranes after three successive washes with
either hypotonic Hepes buffer (not shown), isotonic Hepes buffer
containing 150 mM NaCl (not shown), or hypertonic Hepes buffer containing 500 mM NaCl (Fig. 4). The distribution of
GAD67 between cytosol and membrane fractions from wild-type mice
(2.3:1) was not significantly different for GAD65-deficient mice in all conditions of membrane washing. Thus, GAD67 associates with high avidity to membranes independent of GAD65.
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Fig. 5.
Membrane-associated GAD67 is hydrophilic, but
heterodimerization with GAD65 can mediate its partition into the TX-114
detergent phase. Immunoblotting analysis of TX-114 detergent and
aqueous phases of cytosol, membrane extract, and membrane wash
fractions prepared from the brain of wild-type (+/+) and GAD65
knock-out ( /) mice. Proteins were resolved by SDS-PAGE.
Immunoblotting was performed using the 1701 antibody. GAD67 is
hydrophilic but partitions into the TX-114 phase by association with
GAD65.
1-38 and rGAD651-101) that cannot by themselves localize to membranes. Membrane and cytosol
fractions of COS-7 cells coexpressing these mutants together with
mGAD67 were subjected to immunoprecipitation with the GAD65-specific antibody GAD6. In these experiments, the heterodimers between GAD67 and
the soluble mutant subunits were only detected in the cytosol fraction
(results not shown). Therefore, although GAD67 can associate with
membranes, it cannot mediate membrane association of a soluble GAD65 subunit.
/) and their heterozygous littermates (GAD65+/),
demonstrated that GAD67 is localized to nerve terminals both in the
presence (Fig. 8A) and absence
of GAD65 (Fig. 8B).
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Fig. 6.
Co-localization of GAD67 and GAD65 in rat
hippocampal neurons in culture. Double immunofluorescence analysis
of GAD65 and GAD67 in rat hippocampal neurons using a mixture of
GAD65-specific human monoclonal antibodies MICA 2, 3, and 6 (red fluorescence) and the GAD67-specific rabbit
polyclonal antibody K2 (green fluorescence).
GAD67 is evenly distributed in the cell body but also co-localizes with
GAD65 in the perinuclear region and in punctate structures
(orange color), representing boutons in nerve
terminals.
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Fig. 7.
Co-localization of GAD65 and GAD67 with SV2
in nerve terminals of rat hippocampal neurons in culture. Triple
immunofluorescence analyses are shown of neurons prepared from a rat
hippocampus and stained for GAD65 (MICA 2, 3, and 6, red
fluorescence), GAD67 (K2 antibody, green
fluorescence), and the synaptic vesicle marker SV2 (anti-SV2
mouse monoclonal antibody, blue fluorescence).
GAD65 and GAD67 immunoreactivities precisely coincide with that of SV2
(white color), consistent with their accumulation
at nerve terminals of GABA-ergic neurons.
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Fig. 8.
GAD67 localization to axon terminals of mouse
cortical neurons in culture is independent of GAD65 expression.
A, immunofluorescence analysis of primary cultures of
cortical neurons prepared from the brains of 18-day embryonic
heterozygous (GAD65+/ ) mice, which express similar levels of GAD65 as
wild-type mice (11). After 2 weeks in culture, the neurons were double
immunostained for SV2 (green fluorescence) and
GAD67 (red fluorescence). B,
immunofluorescence analysis of cortical neurons prepared from the
brains of 18-day embryonic GAD65/ mice and double immunostained for
SV2 (green fluorescence) and GAD67
(red fluorescence). No staining for GAD65 can be
observed in those mice (Ref. 11 and data not shown). GAD67 is targeted
to nerve terminals (axons) in the absence of GAD65.
/ mouse embryos and
their wild-type GAD67+/+ littermates. In those cultures, GAD65 was
localized to nerve terminals in the presence and absence of GAD67 (data
not shown). Taken together, these results indicate that although the
nerve terminals of neurons obtained from wild-type mouse embryos were
always positive for both GAD67 and GAD65, the two isoforms localize
independently to nerve terminals.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
/ and GAD67/ mice. GAD67
provides >90% of brain GABA, and GAD67 deficiency results in neonatal
death (38, 39). In contrast, GAD65/ mice are viable and have near normal GABA levels in brain but develop spontaneous seizures and are
deficient in the fine tuning of inhibitory neurotransmission involved
in responses to a number of stimuli (11, 40, 41). Both forms are
synthesized as soluble hydrophilic molecules (20). Based on experiments
in pancreatic cells, hydrophobic modifications and anchoring to the
membrane of synaptic vesicles in neurons and synaptic-like
microvesicles in pancreatic cells was described to be an exclusive
characteristic of GAD65 (20-22). Thus, targeting of GAD67 to membrane
compartments was attributed to heterodimerization with GAD65 (18, 19).
We and others have proposed that the anchoring of GAD65 to the membrane
of synaptic vesicles distinguishes it from GAD67 and provides a
mechanism by which GAD65-generated GABA is more rapidly available for
secretion (26). The results presented here, however, show that
targeting to nerve terminals and anchoring to membranes are also
intrinsic properties of GAD67 and occur independent of an association
with GAD65. Thus, the two isoforms share properties previously
attributed to GAD65. It will be important to establish whether the
dynamics, location, and control of membrane anchoring differ for the
two isoforms and how these properties translate to the differences in
their function.
1-101 mutant is exclusively
detected as a dimer in nondenaturing gels and therefore provide the
first evidence that the NH2-terminal region of GAD65 is not
important for homodimerization. Thus, the predicted interactions of
several residues in the middle domain of one subunit with PLP in the
active site of the second subunit may represent the main bonds between
the subunits (17).
1-101 mutant forms a heterodimer with GAD67,
demonstrating that the NH2-terminal region of GAD65 is not
required for heterodimerization. Dirkx et al. (18) linked the first 83 amino acids of GAD65 to -galactosidase and suggested based on immunofluorescence studies that this protein could mediate localization of GAD67 to the Golgi complex region when the two proteins
were co-expressed in CHO cells. Based on this indirect evidence, it was
concluded that the NH2-terminal region of GAD65 mediates
heterodimerization with GAD67. However, as demonstrated in this study,
GAD67 can associate with membranes independent of GAD65. It is,
therefore, possible that the localization of GAD67 to the Golgi region
observed in CHO cells (18) occurred independent of the
GAD65-(1-83)/-gal protein.
ACKNOWLEDGEMENTS
FOOTNOTES
ABBREVIATIONS
-aminobutyric acid;
PLP, pyridoxal 5'-phosphate;
NEM, N-ethylmaleimide;
PAS, protein A-Sepharose;
PGS, protein
G-Sepharose;
bp, base pair(s);
IP buffer, immunoprecipitation buffer;
PAGE, polyacrylamide gel electrophoresis;
TBS, Tris-buffered
saline.
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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